diff --git a/Makefile b/Makefile index 68d203ac774..efa1ec1e59c 100644 --- a/Makefile +++ b/Makefile @@ -45,15 +45,15 @@ gen-endpoints: build: @echo "go build SDK and vendor packages" - @go build $(SDK_WITH_VENDOR_PKGS) + @go build ${SDK_ONLY_PKGS} unit: get-deps-tests build verify @echo "go test SDK and vendor packages" - @go test $(SDK_WITH_VENDOR_PKGS) + @go test $(SDK_ONLY_PKGS) unit-with-race-cover: get-deps-tests build verify @echo "go test SDK and vendor packages" - @go test -v -race -cpu=1,2,4 -covermode=atomic $(SDK_WITH_VENDOR_PKGS) + @go test -v -race -cpu=1,2,4 -covermode=atomic $(SDK_ONLY_PKGS) integration: get-deps-tests integ-custom smoke-tests performance @@ -78,13 +78,13 @@ verify: get-deps-verify lint vet lint: @echo "go lint SDK and vendor packages" - @lint=`if [ -z "${SDK_GO_1_4}" ]; then golint ./...; else echo "skipped"; fi`; \ + @lint=`if [ -z "${SDK_GO_1_4}" ]; then golint ./...; else echo "skipping golint"; fi`; \ lint=`echo "$$lint" | grep -E -v -e ${LINTIGNOREDOT} -e ${LINTIGNOREDOC} -e ${LINTIGNORECONST} -e ${LINTIGNORESTUTTER} -e ${LINTIGNOREINFLECT} -e ${LINTIGNOREDEPS} -e ${LINTIGNOREINFLECTS3UPLOAD}`; \ echo "$$lint"; \ - if [ "$$lint" != "" ] && [ "$$lint" != "skipped" ]; then exit 1; fi + if [ "$$lint" != "" ] && [ "$$lint" != "skipping golint" ]; then exit 1; fi vet: - go tool vet -all -shadow $(shell if go version | grep -v 1.5 | grep -v 1.4 >> /dev/null; then echo "-example=false" | tr -d '\n'; fi) $(shell ls -d */ | grep -v vendor | grep -v awsmigrate) + @if [ -z "${SDK_GO_1_4}" ]; then go tool vet -all -shadow $(shell if go version | grep -v 1.5 | grep -v 1.4 >> /dev/null; then echo "-example=false" | tr -d '\n'; fi) $(shell ls -d */ | grep -v vendor | grep -v awsmigrate); else echo "skipping vet"; fi get-deps: get-deps-tests get-deps-verify @echo "go get SDK dependencies" @@ -99,7 +99,6 @@ get-deps-tests: get-deps-verify: @echo "go get SDK verification utilities" @if [ -z "${SDK_GO_1_4}" ]; then go get github.com/golang/lint/golint; else echo "skipped getting golint"; fi - go get golang.org/x/tools/cmd/vet bench: @echo "go bench SDK packages" diff --git a/awsmigrate/awsmigrate-renamer/Godeps/Godeps.json b/awsmigrate/awsmigrate-renamer/Godeps/Godeps.json new file mode 100644 index 00000000000..65d753cac8a --- /dev/null +++ b/awsmigrate/awsmigrate-renamer/Godeps/Godeps.json @@ -0,0 +1,19 @@ +{ + "ImportPath": "github.com/aws/aws-sdk-go/awsmigrate/awsmigrate-renamer", + "GoVersion": "go1.6", + "GodepVersion": "v60", + "Deps": [ + { + "ImportPath": "golang.org/x/tools/go/ast/astutil", + "Rev": "b75b3f5cd5d50fbb1fb88ce784d2e7cca17bba8a" + }, + { + "ImportPath": "golang.org/x/tools/go/buildutil", + "Rev": "b75b3f5cd5d50fbb1fb88ce784d2e7cca17bba8a" + }, + { + "ImportPath": "golang.org/x/tools/go/loader", + "Rev": "b75b3f5cd5d50fbb1fb88ce784d2e7cca17bba8a" + } + ] +} diff --git a/awsmigrate/awsmigrate-renamer/Godeps/Readme b/awsmigrate/awsmigrate-renamer/Godeps/Readme new file mode 100644 index 00000000000..4cdaa53d56d --- /dev/null +++ b/awsmigrate/awsmigrate-renamer/Godeps/Readme @@ -0,0 +1,5 @@ +This directory tree is generated automatically by godep. + +Please do not edit. + +See https://github.com/tools/godep for more information. diff --git a/awsmigrate/awsmigrate-renamer/vendor/Godeps.json b/awsmigrate/awsmigrate-renamer/vendor/Godeps.json deleted file mode 100644 index 4d810883b31..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/Godeps.json +++ /dev/null @@ -1,27 +0,0 @@ -{ - "ImportPath": "github.com/aws/aws-sdk-go/awsmigrate/awsmigrate-renamer", - "GoVersion": "go1.6", - "GodepVersion": "v60", - "Deps": [ - { - "ImportPath": "golang.org/x/tools/go/ast/astutil", - "Rev": "093d7650abf0a26882924de03a6c840a00356572" - }, - { - "ImportPath": "golang.org/x/tools/go/buildutil", - "Rev": "093d7650abf0a26882924de03a6c840a00356572" - }, - { - "ImportPath": "golang.org/x/tools/go/exact", - "Rev": "093d7650abf0a26882924de03a6c840a00356572" - }, - { - "ImportPath": "golang.org/x/tools/go/loader", - "Rev": "093d7650abf0a26882924de03a6c840a00356572" - }, - { - "ImportPath": "golang.org/x/tools/go/types", - "Rev": "093d7650abf0a26882924de03a6c840a00356572" - } - ] -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/ast/astutil/imports.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/ast/astutil/imports.go index c2e2b58e677..a47bcfa3fb0 100644 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/ast/astutil/imports.go +++ b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/ast/astutil/imports.go @@ -143,6 +143,30 @@ func AddNamedImport(fset *token.FileSet, f *ast.File, name, ipath string) (added } f.Imports = append(f.Imports, newImport) + + if len(f.Decls) <= 1 { + return true + } + + // Merge all the import declarations into the first one. + var first *ast.GenDecl + for i, decl := range f.Decls { + gen, ok := decl.(*ast.GenDecl) + if !ok || gen.Tok != token.IMPORT || declImports(gen, "C") { + continue + } + if first == nil { + first = gen + continue // Don't touch the first one. + } + // Move the imports of the other import declaration to the first one. + for _, spec := range gen.Specs { + spec.(*ast.ImportSpec).Path.ValuePos = first.Pos() + first.Specs = append(first.Specs, spec) + } + f.Decls = append(f.Decls[:i], f.Decls[i+1:]...) + } + return true } diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/exact.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/exact.go deleted file mode 100644 index e8fbfe974a2..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/exact.go +++ /dev/null @@ -1,920 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// Package exact implements Values representing untyped -// Go constants and the corresponding operations. Values -// and operations have unlimited precision. -// -// A special Unknown value may be used when a value -// is unknown due to an error. Operations on unknown -// values produce unknown values unless specified -// otherwise. -// -package exact - -import ( - "fmt" - "go/token" - "math/big" - "strconv" -) - -// Kind specifies the kind of value represented by a Value. -type Kind int - -// Implementation note: Kinds must be enumerated in -// order of increasing "complexity" (used by match). - -const ( - // unknown values - Unknown Kind = iota - - // non-numeric values - Bool - String - - // numeric values - Int - Float - Complex -) - -// A Value represents a mathematically exact value of a given Kind. -type Value interface { - // Kind returns the value kind; it is always the smallest - // kind in which the value can be represented exactly. - Kind() Kind - - // String returns a human-readable form of the value. - String() string - - // Prevent external implementations. - implementsValue() -} - -// ---------------------------------------------------------------------------- -// Implementations - -type ( - unknownVal struct{} - boolVal bool - stringVal string - int64Val int64 - intVal struct{ val *big.Int } - floatVal struct{ val *big.Rat } - complexVal struct{ re, im *big.Rat } -) - -func (unknownVal) Kind() Kind { return Unknown } -func (boolVal) Kind() Kind { return Bool } -func (stringVal) Kind() Kind { return String } -func (int64Val) Kind() Kind { return Int } -func (intVal) Kind() Kind { return Int } -func (floatVal) Kind() Kind { return Float } -func (complexVal) Kind() Kind { return Complex } - -func (unknownVal) String() string { return "unknown" } -func (x boolVal) String() string { return fmt.Sprintf("%v", bool(x)) } -func (x stringVal) String() string { return strconv.Quote(string(x)) } -func (x int64Val) String() string { return strconv.FormatInt(int64(x), 10) } -func (x intVal) String() string { return x.val.String() } -func (x floatVal) String() string { return x.val.String() } -func (x complexVal) String() string { return fmt.Sprintf("(%s + %si)", x.re, x.im) } - -func (unknownVal) implementsValue() {} -func (boolVal) implementsValue() {} -func (stringVal) implementsValue() {} -func (int64Val) implementsValue() {} -func (intVal) implementsValue() {} -func (floatVal) implementsValue() {} -func (complexVal) implementsValue() {} - -// int64 bounds -var ( - minInt64 = big.NewInt(-1 << 63) - maxInt64 = big.NewInt(1<<63 - 1) -) - -func normInt(x *big.Int) Value { - if minInt64.Cmp(x) <= 0 && x.Cmp(maxInt64) <= 0 { - return int64Val(x.Int64()) - } - return intVal{x} -} - -func normFloat(x *big.Rat) Value { - if x.IsInt() { - return normInt(x.Num()) - } - return floatVal{x} -} - -func normComplex(re, im *big.Rat) Value { - if im.Sign() == 0 { - return normFloat(re) - } - return complexVal{re, im} -} - -// ---------------------------------------------------------------------------- -// Factories - -// MakeUnknown returns the Unknown value. -func MakeUnknown() Value { return unknownVal{} } - -// MakeBool returns the Bool value for x. -func MakeBool(b bool) Value { return boolVal(b) } - -// MakeString returns the String value for x. -func MakeString(s string) Value { return stringVal(s) } - -// MakeInt64 returns the Int value for x. -func MakeInt64(x int64) Value { return int64Val(x) } - -// MakeUint64 returns the Int value for x. -func MakeUint64(x uint64) Value { return normInt(new(big.Int).SetUint64(x)) } - -// MakeFloat64 returns the numeric value for x. -// If x is not finite, the result is unknown. -func MakeFloat64(x float64) Value { - if f := new(big.Rat).SetFloat64(x); f != nil { - return normFloat(f) - } - return unknownVal{} -} - -// MakeFromLiteral returns the corresponding integer, floating-point, -// imaginary, character, or string value for a Go literal string. The -// result is nil if the literal string is invalid. -func MakeFromLiteral(lit string, tok token.Token) Value { - switch tok { - case token.INT: - if x, err := strconv.ParseInt(lit, 0, 64); err == nil { - return int64Val(x) - } - if x, ok := new(big.Int).SetString(lit, 0); ok { - return intVal{x} - } - - case token.FLOAT: - if x, ok := new(big.Rat).SetString(lit); ok { - return normFloat(x) - } - - case token.IMAG: - if n := len(lit); n > 0 && lit[n-1] == 'i' { - if im, ok := new(big.Rat).SetString(lit[0 : n-1]); ok { - return normComplex(big.NewRat(0, 1), im) - } - } - - case token.CHAR: - if n := len(lit); n >= 2 { - if code, _, _, err := strconv.UnquoteChar(lit[1:n-1], '\''); err == nil { - return int64Val(code) - } - } - - case token.STRING: - if s, err := strconv.Unquote(lit); err == nil { - return stringVal(s) - } - } - - return nil -} - -// ---------------------------------------------------------------------------- -// Accessors -// -// For unknown arguments the result is the zero value for the respective -// accessor type, except for Sign, where the result is 1. - -// BoolVal returns the Go boolean value of x, which must be a Bool or an Unknown. -// If x is Unknown, the result is false. -func BoolVal(x Value) bool { - switch x := x.(type) { - case boolVal: - return bool(x) - case unknownVal: - return false - } - panic(fmt.Sprintf("%v not a Bool", x)) -} - -// StringVal returns the Go string value of x, which must be a String or an Unknown. -// If x is Unknown, the result is "". -func StringVal(x Value) string { - switch x := x.(type) { - case stringVal: - return string(x) - case unknownVal: - return "" - } - panic(fmt.Sprintf("%v not a String", x)) -} - -// Int64Val returns the Go int64 value of x and whether the result is exact; -// x must be an Int or an Unknown. If the result is not exact, its value is undefined. -// If x is Unknown, the result is (0, false). -func Int64Val(x Value) (int64, bool) { - switch x := x.(type) { - case int64Val: - return int64(x), true - case intVal: - return x.val.Int64(), x.val.BitLen() <= 63 - case unknownVal: - return 0, false - } - panic(fmt.Sprintf("%v not an Int", x)) -} - -// Uint64Val returns the Go uint64 value of x and whether the result is exact; -// x must be an Int or an Unknown. If the result is not exact, its value is undefined. -// If x is Unknown, the result is (0, false). -func Uint64Val(x Value) (uint64, bool) { - switch x := x.(type) { - case int64Val: - return uint64(x), x >= 0 - case intVal: - return x.val.Uint64(), x.val.Sign() >= 0 && x.val.BitLen() <= 64 - case unknownVal: - return 0, false - } - panic(fmt.Sprintf("%v not an Int", x)) -} - -// Float32Val is like Float64Val but for float32 instead of float64. -func Float32Val(x Value) (float32, bool) { - switch x := x.(type) { - case int64Val: - f := float32(x) - return f, int64Val(f) == x - case intVal: - return ratToFloat32(new(big.Rat).SetFrac(x.val, int1)) - case floatVal: - return ratToFloat32(x.val) - case unknownVal: - return 0, false - } - panic(fmt.Sprintf("%v not a Float", x)) -} - -// Float64Val returns the nearest Go float64 value of x and whether the result is exact; -// x must be numeric but not Complex, or Unknown. For values too small (too close to 0) -// to represent as float64, Float64Val silently underflows to 0. The result sign always -// matches the sign of x, even for 0. -// If x is Unknown, the result is (0, false). -func Float64Val(x Value) (float64, bool) { - switch x := x.(type) { - case int64Val: - f := float64(int64(x)) - return f, int64Val(f) == x - case intVal: - return new(big.Rat).SetFrac(x.val, int1).Float64() - case floatVal: - return x.val.Float64() - case unknownVal: - return 0, false - } - panic(fmt.Sprintf("%v not a Float", x)) -} - -// BitLen returns the number of bits required to represent -// the absolute value x in binary representation; x must be an Int or an Unknown. -// If x is Unknown, the result is 0. -func BitLen(x Value) int { - switch x := x.(type) { - case int64Val: - return new(big.Int).SetInt64(int64(x)).BitLen() - case intVal: - return x.val.BitLen() - case unknownVal: - return 0 - } - panic(fmt.Sprintf("%v not an Int", x)) -} - -// Sign returns -1, 0, or 1 depending on whether x < 0, x == 0, or x > 0; -// x must be numeric or Unknown. For complex values x, the sign is 0 if x == 0, -// otherwise it is != 0. If x is Unknown, the result is 1. -func Sign(x Value) int { - switch x := x.(type) { - case int64Val: - switch { - case x < 0: - return -1 - case x > 0: - return 1 - } - return 0 - case intVal: - return x.val.Sign() - case floatVal: - return x.val.Sign() - case complexVal: - return x.re.Sign() | x.im.Sign() - case unknownVal: - return 1 // avoid spurious division by zero errors - } - panic(fmt.Sprintf("%v not numeric", x)) -} - -// ---------------------------------------------------------------------------- -// Support for serializing/deserializing integers - -const ( - // Compute the size of a Word in bytes. - _m = ^big.Word(0) - _log = _m>>8&1 + _m>>16&1 + _m>>32&1 - wordSize = 1 << _log -) - -// Bytes returns the bytes for the absolute value of x in little- -// endian binary representation; x must be an Int. -func Bytes(x Value) []byte { - var val *big.Int - switch x := x.(type) { - case int64Val: - val = new(big.Int).SetInt64(int64(x)) - case intVal: - val = x.val - default: - panic(fmt.Sprintf("%v not an Int", x)) - } - - words := val.Bits() - bytes := make([]byte, len(words)*wordSize) - - i := 0 - for _, w := range words { - for j := 0; j < wordSize; j++ { - bytes[i] = byte(w) - w >>= 8 - i++ - } - } - // remove leading 0's - for i > 0 && bytes[i-1] == 0 { - i-- - } - - return bytes[:i] -} - -// MakeFromBytes returns the Int value given the bytes of its little-endian -// binary representation. An empty byte slice argument represents 0. -func MakeFromBytes(bytes []byte) Value { - words := make([]big.Word, (len(bytes)+(wordSize-1))/wordSize) - - i := 0 - var w big.Word - var s uint - for _, b := range bytes { - w |= big.Word(b) << s - if s += 8; s == wordSize*8 { - words[i] = w - i++ - w = 0 - s = 0 - } - } - // store last word - if i < len(words) { - words[i] = w - i++ - } - // remove leading 0's - for i > 0 && words[i-1] == 0 { - i-- - } - - return normInt(new(big.Int).SetBits(words[:i])) -} - -// ---------------------------------------------------------------------------- -// Support for disassembling fractions - -// Num returns the numerator of x; x must be Int, Float, or Unknown. -// If x is Unknown, the result is Unknown, otherwise it is an Int -// with the same sign as x. -func Num(x Value) Value { - switch x := x.(type) { - case unknownVal, int64Val, intVal: - return x - case floatVal: - return normInt(x.val.Num()) - } - panic(fmt.Sprintf("%v not Int or Float", x)) -} - -// Denom returns the denominator of x; x must be Int, Float, or Unknown. -// If x is Unknown, the result is Unknown, otherwise it is an Int >= 1. -func Denom(x Value) Value { - switch x := x.(type) { - case unknownVal: - return x - case int64Val, intVal: - return int64Val(1) - case floatVal: - return normInt(x.val.Denom()) - } - panic(fmt.Sprintf("%v not Int or Float", x)) -} - -// ---------------------------------------------------------------------------- -// Support for assembling/disassembling complex numbers - -// MakeImag returns the numeric value x*i (possibly 0); -// x must be Int, Float, or Unknown. -// If x is Unknown, the result is Unknown. -func MakeImag(x Value) Value { - var im *big.Rat - switch x := x.(type) { - case unknownVal: - return x - case int64Val: - im = big.NewRat(int64(x), 1) - case intVal: - im = new(big.Rat).SetFrac(x.val, int1) - case floatVal: - im = x.val - default: - panic(fmt.Sprintf("%v not Int or Float", x)) - } - return normComplex(rat0, im) -} - -// Real returns the real part of x, which must be a numeric or unknown value. -// If x is Unknown, the result is Unknown. -func Real(x Value) Value { - switch x := x.(type) { - case unknownVal, int64Val, intVal, floatVal: - return x - case complexVal: - return normFloat(x.re) - } - panic(fmt.Sprintf("%v not numeric", x)) -} - -// Imag returns the imaginary part of x, which must be a numeric or unknown value. -// If x is Unknown, the result is Unknown. -func Imag(x Value) Value { - switch x := x.(type) { - case unknownVal: - return x - case int64Val, intVal, floatVal: - return int64Val(0) - case complexVal: - return normFloat(x.im) - } - panic(fmt.Sprintf("%v not numeric", x)) -} - -// ---------------------------------------------------------------------------- -// Operations - -// is32bit reports whether x can be represented using 32 bits. -func is32bit(x int64) bool { - const s = 32 - return -1<<(s-1) <= x && x <= 1<<(s-1)-1 -} - -// is63bit reports whether x can be represented using 63 bits. -func is63bit(x int64) bool { - const s = 63 - return -1<<(s-1) <= x && x <= 1<<(s-1)-1 -} - -// UnaryOp returns the result of the unary expression op y. -// The operation must be defined for the operand. -// If size >= 0 it specifies the ^ (xor) result size in bytes. -// If y is Unknown, the result is Unknown. -// -func UnaryOp(op token.Token, y Value, size int) Value { - switch op { - case token.ADD: - switch y.(type) { - case unknownVal, int64Val, intVal, floatVal, complexVal: - return y - } - - case token.SUB: - switch y := y.(type) { - case unknownVal: - return y - case int64Val: - if z := -y; z != y { - return z // no overflow - } - return normInt(new(big.Int).Neg(big.NewInt(int64(y)))) - case intVal: - return normInt(new(big.Int).Neg(y.val)) - case floatVal: - return normFloat(new(big.Rat).Neg(y.val)) - case complexVal: - return normComplex(new(big.Rat).Neg(y.re), new(big.Rat).Neg(y.im)) - } - - case token.XOR: - var z big.Int - switch y := y.(type) { - case unknownVal: - return y - case int64Val: - z.Not(big.NewInt(int64(y))) - case intVal: - z.Not(y.val) - default: - goto Error - } - // For unsigned types, the result will be negative and - // thus "too large": We must limit the result size to - // the type's size. - if size >= 0 { - s := uint(size) * 8 - z.AndNot(&z, new(big.Int).Lsh(big.NewInt(-1), s)) // z &^= (-1)< ord(y) { - y, x = match(y, x) - return x, y - } - // ord(x) <= ord(y) - - switch x := x.(type) { - case unknownVal: - return x, x - - case boolVal, stringVal, complexVal: - return x, y - - case int64Val: - switch y := y.(type) { - case int64Val: - return x, y - case intVal: - return intVal{big.NewInt(int64(x))}, y - case floatVal: - return floatVal{big.NewRat(int64(x), 1)}, y - case complexVal: - return complexVal{big.NewRat(int64(x), 1), rat0}, y - } - - case intVal: - switch y := y.(type) { - case intVal: - return x, y - case floatVal: - return floatVal{new(big.Rat).SetFrac(x.val, int1)}, y - case complexVal: - return complexVal{new(big.Rat).SetFrac(x.val, int1), rat0}, y - } - - case floatVal: - switch y := y.(type) { - case floatVal: - return x, y - case complexVal: - return complexVal{x.val, rat0}, y - } - } - - panic("unreachable") -} - -// BinaryOp returns the result of the binary expression x op y. -// The operation must be defined for the operands. If one of the -// operands is Unknown, the result is Unknown. -// To force integer division of Int operands, use op == token.QUO_ASSIGN -// instead of token.QUO; the result is guaranteed to be Int in this case. -// Division by zero leads to a run-time panic. -// -func BinaryOp(x Value, op token.Token, y Value) Value { - x, y = match(x, y) - - switch x := x.(type) { - case unknownVal: - return x - - case boolVal: - y := y.(boolVal) - switch op { - case token.LAND: - return x && y - case token.LOR: - return x || y - } - - case int64Val: - a := int64(x) - b := int64(y.(int64Val)) - var c int64 - switch op { - case token.ADD: - if !is63bit(a) || !is63bit(b) { - return normInt(new(big.Int).Add(big.NewInt(a), big.NewInt(b))) - } - c = a + b - case token.SUB: - if !is63bit(a) || !is63bit(b) { - return normInt(new(big.Int).Sub(big.NewInt(a), big.NewInt(b))) - } - c = a - b - case token.MUL: - if !is32bit(a) || !is32bit(b) { - return normInt(new(big.Int).Mul(big.NewInt(a), big.NewInt(b))) - } - c = a * b - case token.QUO: - return normFloat(new(big.Rat).SetFrac(big.NewInt(a), big.NewInt(b))) - case token.QUO_ASSIGN: // force integer division - c = a / b - case token.REM: - c = a % b - case token.AND: - c = a & b - case token.OR: - c = a | b - case token.XOR: - c = a ^ b - case token.AND_NOT: - c = a &^ b - default: - goto Error - } - return int64Val(c) - - case intVal: - a := x.val - b := y.(intVal).val - var c big.Int - switch op { - case token.ADD: - c.Add(a, b) - case token.SUB: - c.Sub(a, b) - case token.MUL: - c.Mul(a, b) - case token.QUO: - return normFloat(new(big.Rat).SetFrac(a, b)) - case token.QUO_ASSIGN: // force integer division - c.Quo(a, b) - case token.REM: - c.Rem(a, b) - case token.AND: - c.And(a, b) - case token.OR: - c.Or(a, b) - case token.XOR: - c.Xor(a, b) - case token.AND_NOT: - c.AndNot(a, b) - default: - goto Error - } - return normInt(&c) - - case floatVal: - a := x.val - b := y.(floatVal).val - var c big.Rat - switch op { - case token.ADD: - c.Add(a, b) - case token.SUB: - c.Sub(a, b) - case token.MUL: - c.Mul(a, b) - case token.QUO: - c.Quo(a, b) - default: - goto Error - } - return normFloat(&c) - - case complexVal: - y := y.(complexVal) - a, b := x.re, x.im - c, d := y.re, y.im - var re, im big.Rat - switch op { - case token.ADD: - // (a+c) + i(b+d) - re.Add(a, c) - im.Add(b, d) - case token.SUB: - // (a-c) + i(b-d) - re.Sub(a, c) - im.Sub(b, d) - case token.MUL: - // (ac-bd) + i(bc+ad) - var ac, bd, bc, ad big.Rat - ac.Mul(a, c) - bd.Mul(b, d) - bc.Mul(b, c) - ad.Mul(a, d) - re.Sub(&ac, &bd) - im.Add(&bc, &ad) - case token.QUO: - // (ac+bd)/s + i(bc-ad)/s, with s = cc + dd - var ac, bd, bc, ad, s, cc, dd big.Rat - ac.Mul(a, c) - bd.Mul(b, d) - bc.Mul(b, c) - ad.Mul(a, d) - cc.Mul(c, c) - dd.Mul(d, d) - s.Add(&cc, &dd) - re.Add(&ac, &bd) - re.Quo(&re, &s) - im.Sub(&bc, &ad) - im.Quo(&im, &s) - default: - goto Error - } - return normComplex(&re, &im) - - case stringVal: - if op == token.ADD { - return x + y.(stringVal) - } - } - -Error: - panic(fmt.Sprintf("invalid binary operation %v %s %v", x, op, y)) -} - -// Shift returns the result of the shift expression x op s -// with op == token.SHL or token.SHR (<< or >>). x must be -// an Int or an Unknown. If x is Unknown, the result is x. -// -func Shift(x Value, op token.Token, s uint) Value { - switch x := x.(type) { - case unknownVal: - return x - - case int64Val: - if s == 0 { - return x - } - switch op { - case token.SHL: - z := big.NewInt(int64(x)) - return normInt(z.Lsh(z, s)) - case token.SHR: - return x >> s - } - - case intVal: - if s == 0 { - return x - } - var z big.Int - switch op { - case token.SHL: - return normInt(z.Lsh(x.val, s)) - case token.SHR: - return normInt(z.Rsh(x.val, s)) - } - } - - panic(fmt.Sprintf("invalid shift %v %s %d", x, op, s)) -} - -func cmpZero(x int, op token.Token) bool { - switch op { - case token.EQL: - return x == 0 - case token.NEQ: - return x != 0 - case token.LSS: - return x < 0 - case token.LEQ: - return x <= 0 - case token.GTR: - return x > 0 - case token.GEQ: - return x >= 0 - } - panic("unreachable") -} - -// Compare returns the result of the comparison x op y. -// The comparison must be defined for the operands. -// If one of the operands is Unknown, the result is -// false. -// -func Compare(x Value, op token.Token, y Value) bool { - x, y = match(x, y) - - switch x := x.(type) { - case unknownVal: - return false - - case boolVal: - y := y.(boolVal) - switch op { - case token.EQL: - return x == y - case token.NEQ: - return x != y - } - - case int64Val: - y := y.(int64Val) - switch op { - case token.EQL: - return x == y - case token.NEQ: - return x != y - case token.LSS: - return x < y - case token.LEQ: - return x <= y - case token.GTR: - return x > y - case token.GEQ: - return x >= y - } - - case intVal: - return cmpZero(x.val.Cmp(y.(intVal).val), op) - - case floatVal: - return cmpZero(x.val.Cmp(y.(floatVal).val), op) - - case complexVal: - y := y.(complexVal) - re := x.re.Cmp(y.re) - im := x.im.Cmp(y.im) - switch op { - case token.EQL: - return re == 0 && im == 0 - case token.NEQ: - return re != 0 || im != 0 - } - - case stringVal: - y := y.(stringVal) - switch op { - case token.EQL: - return x == y - case token.NEQ: - return x != y - case token.LSS: - return x < y - case token.LEQ: - return x <= y - case token.GTR: - return x > y - case token.GEQ: - return x >= y - } - } - - panic(fmt.Sprintf("invalid comparison %v %s %v", x, op, y)) -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/go13.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/go13.go deleted file mode 100644 index 1016c141507..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/go13.go +++ /dev/null @@ -1,24 +0,0 @@ -// Copyright 2014 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// +build !go1.4 - -package exact - -import ( - "math" - "math/big" -) - -func ratToFloat32(x *big.Rat) (float32, bool) { - // Before 1.4, there's no Rat.Float32. - // Emulate it, albeit at the cost of - // imprecision in corner cases. - x64, exact := x.Float64() - x32 := float32(x64) - if math.IsInf(float64(x32), 0) { - exact = false - } - return x32, exact -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/go14.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/go14.go deleted file mode 100644 index b86e5d26097..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/exact/go14.go +++ /dev/null @@ -1,13 +0,0 @@ -// Copyright 2014 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// +build go1.4 - -package exact - -import "math/big" - -func ratToFloat32(x *big.Rat) (float32, bool) { - return x.Float32() -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo.go index f698197c941..245b914914a 100644 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo.go +++ b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo.go @@ -112,14 +112,18 @@ var cgoRe = regexp.MustCompile(`[/\\:]`) // // runCgo is adapted from (*builder).cgo in // $GOROOT/src/cmd/go/build.go, but these features are unsupported: -// pkg-config, Objective C, CGOPKGPATH, CGO_FLAGS. +// Objective C, CGOPKGPATH, CGO_FLAGS. // func runCgo(bp *build.Package, pkgdir, tmpdir string) (files, displayFiles []string, err error) { cgoCPPFLAGS, _, _, _ := cflags(bp, true) _, cgoexeCFLAGS, _, _ := cflags(bp, false) if len(bp.CgoPkgConfig) > 0 { - return nil, nil, fmt.Errorf("cgo pkg-config not supported") + pcCFLAGS, err := pkgConfigFlags(bp) + if err != nil { + return nil, nil, err + } + cgoCPPFLAGS = append(cgoCPPFLAGS, pcCFLAGS...) } // Allows including _cgo_export.h from .[ch] files in the package. diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo14.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo14.go deleted file mode 100644 index 1dac420faf8..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo14.go +++ /dev/null @@ -1,205 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// +build !go1.5 - -package loader - -// This file handles cgo preprocessing of files containing `import "C"`. -// -// DESIGN -// -// The approach taken is to run the cgo processor on the package's -// CgoFiles and parse the output, faking the filenames of the -// resulting ASTs so that the synthetic file containing the C types is -// called "C" (e.g. "~/go/src/net/C") and the preprocessed files -// have their original names (e.g. "~/go/src/net/cgo_unix.go"), -// not the names of the actual temporary files. -// -// The advantage of this approach is its fidelity to 'go build'. The -// downside is that the token.Position.Offset for each AST node is -// incorrect, being an offset within the temporary file. Line numbers -// should still be correct because of the //line comments. -// -// The logic of this file is mostly plundered from the 'go build' -// tool, which also invokes the cgo preprocessor. -// -// -// REJECTED ALTERNATIVE -// -// An alternative approach that we explored is to extend go/types' -// Importer mechanism to provide the identity of the importing package -// so that each time `import "C"` appears it resolves to a different -// synthetic package containing just the objects needed in that case. -// The loader would invoke cgo but parse only the cgo_types.go file -// defining the package-level objects, discarding the other files -// resulting from preprocessing. -// -// The benefit of this approach would have been that source-level -// syntax information would correspond exactly to the original cgo -// file, with no preprocessing involved, making source tools like -// godoc, oracle, and eg happy. However, the approach was rejected -// due to the additional complexity it would impose on go/types. (It -// made for a beautiful demo, though.) -// -// cgo files, despite their *.go extension, are not legal Go source -// files per the specification since they may refer to unexported -// members of package "C" such as C.int. Also, a function such as -// C.getpwent has in effect two types, one matching its C type and one -// which additionally returns (errno C.int). The cgo preprocessor -// uses name mangling to distinguish these two functions in the -// processed code, but go/types would need to duplicate this logic in -// its handling of function calls, analogous to the treatment of map -// lookups in which y=m[k] and y,ok=m[k] are both legal. - -import ( - "fmt" - "go/ast" - "go/build" - "go/parser" - "go/token" - "io/ioutil" - "log" - "os" - "os/exec" - "path/filepath" - "regexp" - "strings" -) - -// processCgoFiles invokes the cgo preprocessor on bp.CgoFiles, parses -// the output and returns the resulting ASTs. -// -func processCgoFiles(bp *build.Package, fset *token.FileSet, DisplayPath func(path string) string, mode parser.Mode) ([]*ast.File, error) { - tmpdir, err := ioutil.TempDir("", strings.Replace(bp.ImportPath, "/", "_", -1)+"_C") - if err != nil { - return nil, err - } - defer os.RemoveAll(tmpdir) - - pkgdir := bp.Dir - if DisplayPath != nil { - pkgdir = DisplayPath(pkgdir) - } - - cgoFiles, cgoDisplayFiles, err := runCgo(bp, pkgdir, tmpdir) - if err != nil { - return nil, err - } - var files []*ast.File - for i := range cgoFiles { - rd, err := os.Open(cgoFiles[i]) - if err != nil { - return nil, err - } - display := filepath.Join(bp.Dir, cgoDisplayFiles[i]) - f, err := parser.ParseFile(fset, display, rd, mode) - rd.Close() - if err != nil { - return nil, err - } - files = append(files, f) - } - return files, nil -} - -var cgoRe = regexp.MustCompile(`[/\\:]`) - -// runCgo invokes the cgo preprocessor on bp.CgoFiles and returns two -// lists of files: the resulting processed files (in temporary -// directory tmpdir) and the corresponding names of the unprocessed files. -// -// runCgo is adapted from (*builder).cgo in -// $GOROOT/src/cmd/go/build.go, but these features are unsupported: -// pkg-config, Objective C, CGOPKGPATH, CGO_FLAGS. -// -func runCgo(bp *build.Package, pkgdir, tmpdir string) (files, displayFiles []string, err error) { - cgoCPPFLAGS, _, _, _ := cflags(bp, true) - _, cgoexeCFLAGS, _, _ := cflags(bp, false) - - if len(bp.CgoPkgConfig) > 0 { - return nil, nil, fmt.Errorf("cgo pkg-config not supported") - } - - // Allows including _cgo_export.h from .[ch] files in the package. - cgoCPPFLAGS = append(cgoCPPFLAGS, "-I", tmpdir) - - // _cgo_gotypes.go (displayed "C") contains the type definitions. - files = append(files, filepath.Join(tmpdir, "_cgo_gotypes.go")) - displayFiles = append(displayFiles, "C") - for _, fn := range bp.CgoFiles { - // "foo.cgo1.go" (displayed "foo.go") is the processed Go source. - f := cgoRe.ReplaceAllString(fn[:len(fn)-len("go")], "_") - files = append(files, filepath.Join(tmpdir, f+"cgo1.go")) - displayFiles = append(displayFiles, fn) - } - - var cgoflags []string - if bp.Goroot && bp.ImportPath == "runtime/cgo" { - cgoflags = append(cgoflags, "-import_runtime_cgo=false") - } - if bp.Goroot && bp.ImportPath == "runtime/race" || bp.ImportPath == "runtime/cgo" { - cgoflags = append(cgoflags, "-import_syscall=false") - } - - args := stringList( - "go", "tool", "cgo", "-objdir", tmpdir, cgoflags, "--", - cgoCPPFLAGS, cgoexeCFLAGS, bp.CgoFiles, - ) - if false { - log.Printf("Running cgo for package %q: %s (dir=%s)", bp.ImportPath, args, pkgdir) - } - cmd := exec.Command(args[0], args[1:]...) - cmd.Dir = pkgdir - cmd.Stdout = os.Stderr - cmd.Stderr = os.Stderr - if err := cmd.Run(); err != nil { - return nil, nil, fmt.Errorf("cgo failed: %s: %s", args, err) - } - - return files, displayFiles, nil -} - -// -- unmodified from 'go build' --------------------------------------- - -// Return the flags to use when invoking the C or C++ compilers, or cgo. -func cflags(p *build.Package, def bool) (cppflags, cflags, cxxflags, ldflags []string) { - var defaults string - if def { - defaults = "-g -O2" - } - - cppflags = stringList(envList("CGO_CPPFLAGS", ""), p.CgoCPPFLAGS) - cflags = stringList(envList("CGO_CFLAGS", defaults), p.CgoCFLAGS) - cxxflags = stringList(envList("CGO_CXXFLAGS", defaults), p.CgoCXXFLAGS) - ldflags = stringList(envList("CGO_LDFLAGS", defaults), p.CgoLDFLAGS) - return -} - -// envList returns the value of the given environment variable broken -// into fields, using the default value when the variable is empty. -func envList(key, def string) []string { - v := os.Getenv(key) - if v == "" { - v = def - } - return strings.Fields(v) -} - -// stringList's arguments should be a sequence of string or []string values. -// stringList flattens them into a single []string. -func stringList(args ...interface{}) []string { - var x []string - for _, arg := range args { - switch arg := arg.(type) { - case []string: - x = append(x, arg...) - case string: - x = append(x, arg) - default: - panic("stringList: invalid argument") - } - } - return x -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo_pkgconfig.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo_pkgconfig.go new file mode 100644 index 00000000000..de57422df22 --- /dev/null +++ b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/cgo_pkgconfig.go @@ -0,0 +1,39 @@ +// Copyright 2013 The Go Authors. All rights reserved. +// Use of this source code is governed by a BSD-style +// license that can be found in the LICENSE file. + +package loader + +import ( + "errors" + "fmt" + "go/build" + "os/exec" + "strings" +) + +// pkgConfig runs pkg-config with the specified arguments and returns the flags it prints. +func pkgConfig(mode string, pkgs []string) (flags []string, err error) { + cmd := exec.Command("pkg-config", append([]string{mode}, pkgs...)...) + out, err := cmd.CombinedOutput() + if err != nil { + s := fmt.Sprintf("%s failed: %v", strings.Join(cmd.Args, " "), err) + if len(out) > 0 { + s = fmt.Sprintf("%s: %s", s, out) + } + return nil, errors.New(s) + } + if len(out) > 0 { + flags = strings.Fields(string(out)) + } + return +} + +// pkgConfigFlags calls pkg-config if needed and returns the cflags +// needed to build the package. +func pkgConfigFlags(p *build.Package) (cflags []string, err error) { + if len(p.CgoPkgConfig) == 0 { + return nil, nil + } + return pkgConfig("--cflags", p.CgoPkgConfig) +} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader.go index 1ed0d3e2370..f0171fc998a 100644 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader.go +++ b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader.go @@ -899,7 +899,7 @@ func (imp *importer) importAll(fromPath, fromDir string, imports map[string]bool // (Also it would complicate the // invariants of importPath completion.) if trace { - fmt.Fprintln(os.Stderr, "import cycle: %q", cycle) + fmt.Fprintf(os.Stderr, "import cycle: %q\n", cycle) } continue } diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader14.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader14.go deleted file mode 100644 index 4fd4b2a69bb..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/loader/loader14.go +++ /dev/null @@ -1,1019 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// +build !go1.5 - -package loader - -// See doc.go for package documentation and implementation notes. - -import ( - "errors" - "fmt" - "go/ast" - "go/build" - "go/parser" - "go/token" - "os" - "sort" - "strings" - "sync" - "time" - - "golang.org/x/tools/go/ast/astutil" - "golang.org/x/tools/go/types" -) - -const trace = false // show timing info for type-checking - -// Config specifies the configuration for loading a whole program from -// Go source code. -// The zero value for Config is a ready-to-use default configuration. -type Config struct { - // Fset is the file set for the parser to use when loading the - // program. If nil, it may be lazily initialized by any - // method of Config. - Fset *token.FileSet - - // ParserMode specifies the mode to be used by the parser when - // loading source packages. - ParserMode parser.Mode - - // TypeChecker contains options relating to the type checker. - // - // The supplied IgnoreFuncBodies is not used; the effective - // value comes from the TypeCheckFuncBodies func below. - // The supplied Import function is not used either. - TypeChecker types.Config - - // TypeCheckFuncBodies is a predicate over package paths. - // A package for which the predicate is false will - // have its package-level declarations type checked, but not - // its function bodies; this can be used to quickly load - // dependencies from source. If nil, all func bodies are type - // checked. - TypeCheckFuncBodies func(path string) bool - - // If Build is non-nil, it is used to locate source packages. - // Otherwise &build.Default is used. - // - // By default, cgo is invoked to preprocess Go files that - // import the fake package "C". This behaviour can be - // disabled by setting CGO_ENABLED=0 in the environment prior - // to startup, or by setting Build.CgoEnabled=false. - Build *build.Context - - // The current directory, used for resolving relative package - // references such as "./go/loader". If empty, os.Getwd will be - // used instead. - Cwd string - - // If DisplayPath is non-nil, it is used to transform each - // file name obtained from Build.Import(). This can be used - // to prevent a virtualized build.Config's file names from - // leaking into the user interface. - DisplayPath func(path string) string - - // If AllowErrors is true, Load will return a Program even - // if some of the its packages contained I/O, parser or type - // errors; such errors are accessible via PackageInfo.Errors. If - // false, Load will fail if any package had an error. - AllowErrors bool - - // CreatePkgs specifies a list of non-importable initial - // packages to create. The resulting packages will appear in - // the corresponding elements of the Program.Created slice. - CreatePkgs []PkgSpec - - // ImportPkgs specifies a set of initial packages to load. - // The map keys are package paths. - // - // The map value indicates whether to load tests. If true, Load - // will add and type-check two lists of files to the package: - // non-test files followed by in-package *_test.go files. In - // addition, it will append the external test package (if any) - // to Program.Created. - ImportPkgs map[string]bool - - // FindPackage is called during Load to create the build.Package - // for a given import path from a given directory. - // If FindPackage is nil, a default implementation - // based on ctxt.Import is used. A client may use this hook to - // adapt to a proprietary build system that does not follow the - // "go build" layout conventions, for example. - // - // It must be safe to call concurrently from multiple goroutines. - FindPackage func(ctxt *build.Context, fromDir, importPath string, mode build.ImportMode) (*build.Package, error) -} - -// A PkgSpec specifies a non-importable package to be created by Load. -// Files are processed first, but typically only one of Files and -// Filenames is provided. The path needn't be globally unique. -// -type PkgSpec struct { - Path string // package path ("" => use package declaration) - Files []*ast.File // ASTs of already-parsed files - Filenames []string // names of files to be parsed -} - -// A Program is a Go program loaded from source as specified by a Config. -type Program struct { - Fset *token.FileSet // the file set for this program - - // Created[i] contains the initial package whose ASTs or - // filenames were supplied by Config.CreatePkgs[i], followed by - // the external test package, if any, of each package in - // Config.ImportPkgs ordered by ImportPath. - // - // NOTE: these files must not import "C". Cgo preprocessing is - // only performed on imported packages, not ad hoc packages. - // - // TODO(adonovan): we need to copy and adapt the logic of - // goFilesPackage (from $GOROOT/src/cmd/go/build.go) and make - // Config.Import and Config.Create methods return the same kind - // of entity, essentially a build.Package. - // Perhaps we can even reuse that type directly. - Created []*PackageInfo - - // Imported contains the initially imported packages, - // as specified by Config.ImportPkgs. - Imported map[string]*PackageInfo - - // AllPackages contains the PackageInfo of every package - // encountered by Load: all initial packages and all - // dependencies, including incomplete ones. - AllPackages map[*types.Package]*PackageInfo - - // importMap is the canonical mapping of package paths to - // packages. It contains all Imported initial packages, but not - // Created ones, and all imported dependencies. - importMap map[string]*types.Package -} - -// PackageInfo holds the ASTs and facts derived by the type-checker -// for a single package. -// -// Not mutated once exposed via the API. -// -type PackageInfo struct { - Pkg *types.Package - Importable bool // true if 'import "Pkg.Path()"' would resolve to this - TransitivelyErrorFree bool // true if Pkg and all its dependencies are free of errors - Files []*ast.File // syntax trees for the package's files - Errors []error // non-nil if the package had errors - types.Info // type-checker deductions. - dir string // package directory - - checker *types.Checker // transient type-checker state - errorFunc func(error) -} - -func (info *PackageInfo) String() string { return info.Pkg.Path() } - -func (info *PackageInfo) appendError(err error) { - if info.errorFunc != nil { - info.errorFunc(err) - } else { - fmt.Fprintln(os.Stderr, err) - } - info.Errors = append(info.Errors, err) -} - -func (conf *Config) fset() *token.FileSet { - if conf.Fset == nil { - conf.Fset = token.NewFileSet() - } - return conf.Fset -} - -// ParseFile is a convenience function (intended for testing) that invokes -// the parser using the Config's FileSet, which is initialized if nil. -// -// src specifies the parser input as a string, []byte, or io.Reader, and -// filename is its apparent name. If src is nil, the contents of -// filename are read from the file system. -// -func (conf *Config) ParseFile(filename string, src interface{}) (*ast.File, error) { - // TODO(adonovan): use conf.build() etc like parseFiles does. - return parser.ParseFile(conf.fset(), filename, src, conf.ParserMode) -} - -// FromArgsUsage is a partial usage message that applications calling -// FromArgs may wish to include in their -help output. -const FromArgsUsage = ` - is a list of arguments denoting a set of initial packages. -It may take one of two forms: - -1. A list of *.go source files. - - All of the specified files are loaded, parsed and type-checked - as a single package. All the files must belong to the same directory. - -2. A list of import paths, each denoting a package. - - The package's directory is found relative to the $GOROOT and - $GOPATH using similar logic to 'go build', and the *.go files in - that directory are loaded, parsed and type-checked as a single - package. - - In addition, all *_test.go files in the directory are then loaded - and parsed. Those files whose package declaration equals that of - the non-*_test.go files are included in the primary package. Test - files whose package declaration ends with "_test" are type-checked - as another package, the 'external' test package, so that a single - import path may denote two packages. (Whether this behaviour is - enabled is tool-specific, and may depend on additional flags.) - -A '--' argument terminates the list of packages. -` - -// FromArgs interprets args as a set of initial packages to load from -// source and updates the configuration. It returns the list of -// unconsumed arguments. -// -// It is intended for use in command-line interfaces that require a -// set of initial packages to be specified; see FromArgsUsage message -// for details. -// -// Only superficial errors are reported at this stage; errors dependent -// on I/O are detected during Load. -// -func (conf *Config) FromArgs(args []string, xtest bool) ([]string, error) { - var rest []string - for i, arg := range args { - if arg == "--" { - rest = args[i+1:] - args = args[:i] - break // consume "--" and return the remaining args - } - } - - if len(args) > 0 && strings.HasSuffix(args[0], ".go") { - // Assume args is a list of a *.go files - // denoting a single ad hoc package. - for _, arg := range args { - if !strings.HasSuffix(arg, ".go") { - return nil, fmt.Errorf("named files must be .go files: %s", arg) - } - } - conf.CreateFromFilenames("", args...) - } else { - // Assume args are directories each denoting a - // package and (perhaps) an external test, iff xtest. - for _, arg := range args { - if xtest { - conf.ImportWithTests(arg) - } else { - conf.Import(arg) - } - } - } - - return rest, nil -} - -// CreateFromFilenames is a convenience function that adds -// a conf.CreatePkgs entry to create a package of the specified *.go -// files. -// -func (conf *Config) CreateFromFilenames(path string, filenames ...string) { - conf.CreatePkgs = append(conf.CreatePkgs, PkgSpec{Path: path, Filenames: filenames}) -} - -// CreateFromFiles is a convenience function that adds a conf.CreatePkgs -// entry to create package of the specified path and parsed files. -// -func (conf *Config) CreateFromFiles(path string, files ...*ast.File) { - conf.CreatePkgs = append(conf.CreatePkgs, PkgSpec{Path: path, Files: files}) -} - -// ImportWithTests is a convenience function that adds path to -// ImportPkgs, the set of initial source packages located relative to -// $GOPATH. The package will be augmented by any *_test.go files in -// its directory that contain a "package x" (not "package x_test") -// declaration. -// -// In addition, if any *_test.go files contain a "package x_test" -// declaration, an additional package comprising just those files will -// be added to CreatePkgs. -// -func (conf *Config) ImportWithTests(path string) { conf.addImport(path, true) } - -// Import is a convenience function that adds path to ImportPkgs, the -// set of initial packages that will be imported from source. -// -func (conf *Config) Import(path string) { conf.addImport(path, false) } - -func (conf *Config) addImport(path string, tests bool) { - if path == "C" { - return // ignore; not a real package - } - if conf.ImportPkgs == nil { - conf.ImportPkgs = make(map[string]bool) - } - conf.ImportPkgs[path] = conf.ImportPkgs[path] || tests -} - -// PathEnclosingInterval returns the PackageInfo and ast.Node that -// contain source interval [start, end), and all the node's ancestors -// up to the AST root. It searches all ast.Files of all packages in prog. -// exact is defined as for astutil.PathEnclosingInterval. -// -// The zero value is returned if not found. -// -func (prog *Program) PathEnclosingInterval(start, end token.Pos) (pkg *PackageInfo, path []ast.Node, exact bool) { - for _, info := range prog.AllPackages { - for _, f := range info.Files { - if f.Pos() == token.NoPos { - // This can happen if the parser saw - // too many errors and bailed out. - // (Use parser.AllErrors to prevent that.) - continue - } - if !tokenFileContainsPos(prog.Fset.File(f.Pos()), start) { - continue - } - if path, exact := astutil.PathEnclosingInterval(f, start, end); path != nil { - return info, path, exact - } - } - } - return nil, nil, false -} - -// InitialPackages returns a new slice containing the set of initial -// packages (Created + Imported) in unspecified order. -// -func (prog *Program) InitialPackages() []*PackageInfo { - infos := make([]*PackageInfo, 0, len(prog.Created)+len(prog.Imported)) - infos = append(infos, prog.Created...) - for _, info := range prog.Imported { - infos = append(infos, info) - } - return infos -} - -// Package returns the ASTs and results of type checking for the -// specified package. -func (prog *Program) Package(path string) *PackageInfo { - if info, ok := prog.AllPackages[prog.importMap[path]]; ok { - return info - } - for _, info := range prog.Created { - if path == info.Pkg.Path() { - return info - } - } - return nil -} - -// ---------- Implementation ---------- - -// importer holds the working state of the algorithm. -type importer struct { - conf *Config // the client configuration - start time.Time // for logging - - progMu sync.Mutex // guards prog - prog *Program // the resulting program - - // findpkg is a memoization of FindPackage. - findpkgMu sync.Mutex // guards findpkg - findpkg map[findpkgKey]findpkgValue - - importedMu sync.Mutex // guards imported - imported map[string]*importInfo // all imported packages (incl. failures) by import path - - // import dependency graph: graph[x][y] => x imports y - // - // Since non-importable packages cannot be cyclic, we ignore - // their imports, thus we only need the subgraph over importable - // packages. Nodes are identified by their import paths. - graphMu sync.Mutex - graph map[string]map[string]bool -} - -type findpkgKey struct { - importPath string - fromDir string - mode build.ImportMode -} - -type findpkgValue struct { - bp *build.Package - err error -} - -// importInfo tracks the success or failure of a single import. -// -// Upon completion, exactly one of info and err is non-nil: -// info on successful creation of a package, err otherwise. -// A successful package may still contain type errors. -// -type importInfo struct { - path string // import path - info *PackageInfo // results of typechecking (including errors) - complete chan struct{} // closed to broadcast that info is set. -} - -// awaitCompletion blocks until ii is complete, -// i.e. the info field is safe to inspect. -func (ii *importInfo) awaitCompletion() { - <-ii.complete // wait for close -} - -// Complete marks ii as complete. -// Its info and err fields will not be subsequently updated. -func (ii *importInfo) Complete(info *PackageInfo) { - if info == nil { - panic("info == nil") - } - ii.info = info - close(ii.complete) -} - -type importError struct { - path string // import path - err error // reason for failure to create a package -} - -// Load creates the initial packages specified by conf.{Create,Import}Pkgs, -// loading their dependencies packages as needed. -// -// On success, Load returns a Program containing a PackageInfo for -// each package. On failure, it returns an error. -// -// If AllowErrors is true, Load will return a Program even if some -// packages contained I/O, parser or type errors, or if dependencies -// were missing. (Such errors are accessible via PackageInfo.Errors. If -// false, Load will fail if any package had an error. -// -// It is an error if no packages were loaded. -// -func (conf *Config) Load() (*Program, error) { - // Create a simple default error handler for parse/type errors. - if conf.TypeChecker.Error == nil { - conf.TypeChecker.Error = func(e error) { fmt.Fprintln(os.Stderr, e) } - } - - // Set default working directory for relative package references. - if conf.Cwd == "" { - var err error - conf.Cwd, err = os.Getwd() - if err != nil { - return nil, err - } - } - - // Install default FindPackage hook using go/build logic. - if conf.FindPackage == nil { - conf.FindPackage = func(ctxt *build.Context, path, fromDir string, mode build.ImportMode) (*build.Package, error) { - ioLimit <- true - bp, err := ctxt.Import(path, fromDir, mode) - <-ioLimit - if _, ok := err.(*build.NoGoError); ok { - return bp, nil // empty directory is not an error - } - return bp, err - } - } - - prog := &Program{ - Fset: conf.fset(), - Imported: make(map[string]*PackageInfo), - importMap: make(map[string]*types.Package), - AllPackages: make(map[*types.Package]*PackageInfo), - } - - imp := importer{ - conf: conf, - prog: prog, - findpkg: make(map[findpkgKey]findpkgValue), - imported: make(map[string]*importInfo), - start: time.Now(), - graph: make(map[string]map[string]bool), - } - - // -- loading proper (concurrent phase) -------------------------------- - - var errpkgs []string // packages that contained errors - - // Load the initially imported packages and their dependencies, - // in parallel. - infos, importErrors := imp.importAll("", conf.Cwd, conf.ImportPkgs, 0) - for _, ie := range importErrors { - conf.TypeChecker.Error(ie.err) // failed to create package - errpkgs = append(errpkgs, ie.path) - } - for _, info := range infos { - prog.Imported[info.Pkg.Path()] = info - } - - // Augment the designated initial packages by their tests. - // Dependencies are loaded in parallel. - var xtestPkgs []*build.Package - for importPath, augment := range conf.ImportPkgs { - if !augment { - continue - } - - bp, err := imp.findPackage(importPath, conf.Cwd, 0) - if err != nil { - // Package not found, or can't even parse package declaration. - // Already reported by previous loop; ignore it. - continue - } - - // Needs external test package? - if len(bp.XTestGoFiles) > 0 { - xtestPkgs = append(xtestPkgs, bp) - } - - // Consult the cache using the canonical package path. - path := bp.ImportPath - imp.importedMu.Lock() // (unnecessary, we're sequential here) - ii, ok := imp.imported[path] - // Paranoid checks added due to issue #11012. - if !ok { - // Unreachable. - // The previous loop called importAll and thus - // startLoad for each path in ImportPkgs, which - // populates imp.imported[path] with a non-zero value. - panic(fmt.Sprintf("imported[%q] not found", path)) - } - if ii == nil { - // Unreachable. - // The ii values in this loop are the same as in - // the previous loop, which enforced the invariant - // that at least one of ii.err and ii.info is non-nil. - panic(fmt.Sprintf("imported[%q] == nil", path)) - } - if ii.info == nil { - // Unreachable. - // awaitCompletion has the postcondition - // ii.info != nil. - panic(fmt.Sprintf("imported[%q].info = nil", path)) - } - info := ii.info - imp.importedMu.Unlock() - - // Parse the in-package test files. - files, errs := imp.conf.parsePackageFiles(bp, 't') - for _, err := range errs { - info.appendError(err) - } - - // The test files augmenting package P cannot be imported, - // but may import packages that import P, - // so we must disable the cycle check. - imp.addFiles(info, files, false) - } - - createPkg := func(path string, files []*ast.File, errs []error) { - // TODO(adonovan): fix: use dirname of files, not cwd. - info := imp.newPackageInfo(path, conf.Cwd) - for _, err := range errs { - info.appendError(err) - } - - // Ad hoc packages are non-importable, - // so no cycle check is needed. - // addFiles loads dependencies in parallel. - imp.addFiles(info, files, false) - prog.Created = append(prog.Created, info) - } - - // Create packages specified by conf.CreatePkgs. - for _, cp := range conf.CreatePkgs { - files, errs := parseFiles(conf.fset(), conf.build(), nil, ".", cp.Filenames, conf.ParserMode) - files = append(files, cp.Files...) - - path := cp.Path - if path == "" { - if len(files) > 0 { - path = files[0].Name.Name - } else { - path = "(unnamed)" - } - } - createPkg(path, files, errs) - } - - // Create external test packages. - sort.Sort(byImportPath(xtestPkgs)) - for _, bp := range xtestPkgs { - files, errs := imp.conf.parsePackageFiles(bp, 'x') - createPkg(bp.ImportPath+"_test", files, errs) - } - - // -- finishing up (sequential) ---------------------------------------- - - if len(prog.Imported)+len(prog.Created) == 0 { - return nil, errors.New("no initial packages were loaded") - } - - // Create infos for indirectly imported packages. - // e.g. incomplete packages without syntax, loaded from export data. - for _, obj := range prog.importMap { - info := prog.AllPackages[obj] - if info == nil { - prog.AllPackages[obj] = &PackageInfo{Pkg: obj, Importable: true} - } else { - // finished - info.checker = nil - info.errorFunc = nil - } - } - - if !conf.AllowErrors { - // Report errors in indirectly imported packages. - for _, info := range prog.AllPackages { - if len(info.Errors) > 0 { - errpkgs = append(errpkgs, info.Pkg.Path()) - } - } - if errpkgs != nil { - var more string - if len(errpkgs) > 3 { - more = fmt.Sprintf(" and %d more", len(errpkgs)-3) - errpkgs = errpkgs[:3] - } - return nil, fmt.Errorf("couldn't load packages due to errors: %s%s", - strings.Join(errpkgs, ", "), more) - } - } - - markErrorFreePackages(prog.AllPackages) - - return prog, nil -} - -type byImportPath []*build.Package - -func (b byImportPath) Len() int { return len(b) } -func (b byImportPath) Less(i, j int) bool { return b[i].ImportPath < b[j].ImportPath } -func (b byImportPath) Swap(i, j int) { b[i], b[j] = b[j], b[i] } - -// markErrorFreePackages sets the TransitivelyErrorFree flag on all -// applicable packages. -func markErrorFreePackages(allPackages map[*types.Package]*PackageInfo) { - // Build the transpose of the import graph. - importedBy := make(map[*types.Package]map[*types.Package]bool) - for P := range allPackages { - for _, Q := range P.Imports() { - clients, ok := importedBy[Q] - if !ok { - clients = make(map[*types.Package]bool) - importedBy[Q] = clients - } - clients[P] = true - } - } - - // Find all packages reachable from some error package. - reachable := make(map[*types.Package]bool) - var visit func(*types.Package) - visit = func(p *types.Package) { - if !reachable[p] { - reachable[p] = true - for q := range importedBy[p] { - visit(q) - } - } - } - for _, info := range allPackages { - if len(info.Errors) > 0 { - visit(info.Pkg) - } - } - - // Mark the others as "transitively error-free". - for _, info := range allPackages { - if !reachable[info.Pkg] { - info.TransitivelyErrorFree = true - } - } -} - -// build returns the effective build context. -func (conf *Config) build() *build.Context { - if conf.Build != nil { - return conf.Build - } - return &build.Default -} - -// parsePackageFiles enumerates the files belonging to package path, -// then loads, parses and returns them, plus a list of I/O or parse -// errors that were encountered. -// -// 'which' indicates which files to include: -// 'g': include non-test *.go source files (GoFiles + processed CgoFiles) -// 't': include in-package *_test.go source files (TestGoFiles) -// 'x': include external *_test.go source files. (XTestGoFiles) -// -func (conf *Config) parsePackageFiles(bp *build.Package, which rune) ([]*ast.File, []error) { - if bp.ImportPath == "unsafe" { - return nil, nil - } - var filenames []string - switch which { - case 'g': - filenames = bp.GoFiles - case 't': - filenames = bp.TestGoFiles - case 'x': - filenames = bp.XTestGoFiles - default: - panic(which) - } - - files, errs := parseFiles(conf.fset(), conf.build(), conf.DisplayPath, bp.Dir, filenames, conf.ParserMode) - - // Preprocess CgoFiles and parse the outputs (sequentially). - if which == 'g' && bp.CgoFiles != nil { - cgofiles, err := processCgoFiles(bp, conf.fset(), conf.DisplayPath, conf.ParserMode) - if err != nil { - errs = append(errs, err) - } else { - files = append(files, cgofiles...) - } - } - - return files, errs -} - -// doImport imports the package denoted by path. -// It implements the types.Importer signature. -// -// It returns an error if a package could not be created -// (e.g. go/build or parse error), but type errors are reported via -// the types.Config.Error callback (the first of which is also saved -// in the package's PackageInfo). -// -// Idempotent. -// -func (imp *importer) doImport(from *PackageInfo, to string) (*types.Package, error) { - if to == "C" { - // This should be unreachable, but ad hoc packages are - // not currently subject to cgo preprocessing. - // See https://github.com/golang/go/issues/11627. - return nil, fmt.Errorf(`the loader doesn't cgo-process ad hoc packages like %q; see Go issue 11627`, - from.Pkg.Path()) - } - - bp, err := imp.findPackage(to, from.dir, 0) - if err != nil { - return nil, err - } - - // The standard unsafe package is handled specially, - // and has no PackageInfo. - if bp.ImportPath == "unsafe" { - return types.Unsafe, nil - } - - // Look for the package in the cache using its canonical path. - path := bp.ImportPath - imp.importedMu.Lock() - ii := imp.imported[path] - imp.importedMu.Unlock() - if ii == nil { - panic("internal error: unexpected import: " + path) - } - if ii.info != nil { - return ii.info.Pkg, nil - } - - // Import of incomplete package: this indicates a cycle. - fromPath := from.Pkg.Path() - if cycle := imp.findPath(path, fromPath); cycle != nil { - cycle = append([]string{fromPath}, cycle...) - return nil, fmt.Errorf("import cycle: %s", strings.Join(cycle, " -> ")) - } - - panic("internal error: import of incomplete (yet acyclic) package: " + fromPath) -} - -// findPackage locates the package denoted by the importPath in the -// specified directory. -func (imp *importer) findPackage(importPath, fromDir string, mode build.ImportMode) (*build.Package, error) { - // TODO(adonovan): opt: non-blocking duplicate-suppressing cache. - // i.e. don't hold the lock around FindPackage. - key := findpkgKey{importPath, fromDir, mode} - imp.findpkgMu.Lock() - defer imp.findpkgMu.Unlock() - v, ok := imp.findpkg[key] - if !ok { - bp, err := imp.conf.FindPackage(imp.conf.build(), importPath, fromDir, mode) - v = findpkgValue{bp, err} - imp.findpkg[key] = v - } - return v.bp, v.err -} - -// importAll loads, parses, and type-checks the specified packages in -// parallel and returns their completed importInfos in unspecified order. -// -// fromPath is the package path of the importing package, if it is -// importable, "" otherwise. It is used for cycle detection. -// -// fromDir is the directory containing the import declaration that -// caused these imports. -// -func (imp *importer) importAll(fromPath, fromDir string, imports map[string]bool, mode build.ImportMode) (infos []*PackageInfo, errors []importError) { - // TODO(adonovan): opt: do the loop in parallel once - // findPackage is non-blocking. - var pending []*importInfo - for importPath := range imports { - bp, err := imp.findPackage(importPath, fromDir, mode) - if err != nil { - errors = append(errors, importError{ - path: importPath, - err: err, - }) - continue - } - pending = append(pending, imp.startLoad(bp)) - } - - if fromPath != "" { - // We're loading a set of imports. - // - // We must record graph edges from the importing package - // to its dependencies, and check for cycles. - imp.graphMu.Lock() - deps, ok := imp.graph[fromPath] - if !ok { - deps = make(map[string]bool) - imp.graph[fromPath] = deps - } - for _, ii := range pending { - deps[ii.path] = true - } - imp.graphMu.Unlock() - } - - for _, ii := range pending { - if fromPath != "" { - if cycle := imp.findPath(ii.path, fromPath); cycle != nil { - // Cycle-forming import: we must not await its - // completion since it would deadlock. - // - // We don't record the error in ii since - // the error is really associated with the - // cycle-forming edge, not the package itself. - // (Also it would complicate the - // invariants of importPath completion.) - if trace { - fmt.Fprintln(os.Stderr, "import cycle: %q", cycle) - } - continue - } - } - ii.awaitCompletion() - infos = append(infos, ii.info) - } - - return infos, errors -} - -// findPath returns an arbitrary path from 'from' to 'to' in the import -// graph, or nil if there was none. -func (imp *importer) findPath(from, to string) []string { - imp.graphMu.Lock() - defer imp.graphMu.Unlock() - - seen := make(map[string]bool) - var search func(stack []string, importPath string) []string - search = func(stack []string, importPath string) []string { - if !seen[importPath] { - seen[importPath] = true - stack = append(stack, importPath) - if importPath == to { - return stack - } - for x := range imp.graph[importPath] { - if p := search(stack, x); p != nil { - return p - } - } - } - return nil - } - return search(make([]string, 0, 20), from) -} - -// startLoad initiates the loading, parsing and type-checking of the -// specified package and its dependencies, if it has not already begun. -// -// It returns an importInfo, not necessarily in a completed state. The -// caller must call awaitCompletion() before accessing its info field. -// -// startLoad is concurrency-safe and idempotent. -// -func (imp *importer) startLoad(bp *build.Package) *importInfo { - path := bp.ImportPath - imp.importedMu.Lock() - ii, ok := imp.imported[path] - if !ok { - ii = &importInfo{path: path, complete: make(chan struct{})} - imp.imported[path] = ii - go func() { - info := imp.load(bp) - ii.Complete(info) - }() - } - imp.importedMu.Unlock() - - return ii -} - -// load implements package loading by parsing Go source files -// located by go/build. -func (imp *importer) load(bp *build.Package) *PackageInfo { - info := imp.newPackageInfo(bp.ImportPath, bp.Dir) - info.Importable = true - files, errs := imp.conf.parsePackageFiles(bp, 'g') - for _, err := range errs { - info.appendError(err) - } - - imp.addFiles(info, files, true) - - imp.progMu.Lock() - imp.prog.importMap[bp.ImportPath] = info.Pkg - imp.progMu.Unlock() - - return info -} - -// addFiles adds and type-checks the specified files to info, loading -// their dependencies if needed. The order of files determines the -// package initialization order. It may be called multiple times on the -// same package. Errors are appended to the info.Errors field. -// -// cycleCheck determines whether the imports within files create -// dependency edges that should be checked for potential cycles. -// -func (imp *importer) addFiles(info *PackageInfo, files []*ast.File, cycleCheck bool) { - info.Files = append(info.Files, files...) - - // Ensure the dependencies are loaded, in parallel. - var fromPath string - if cycleCheck { - fromPath = info.Pkg.Path() - } - // TODO(adonovan): opt: make the caller do scanImports. - // Callers with a build.Package can skip it. - imp.importAll(fromPath, info.dir, scanImports(files), 0) - - if trace { - fmt.Fprintf(os.Stderr, "%s: start %q (%d)\n", - time.Since(imp.start), info.Pkg.Path(), len(files)) - } - - // Ignore the returned (first) error since we - // already collect them all in the PackageInfo. - info.checker.Files(files) - - if trace { - fmt.Fprintf(os.Stderr, "%s: stop %q\n", - time.Since(imp.start), info.Pkg.Path()) - } -} - -func (imp *importer) newPackageInfo(path, dir string) *PackageInfo { - pkg := types.NewPackage(path, "") - info := &PackageInfo{ - Pkg: pkg, - Info: types.Info{ - Types: make(map[ast.Expr]types.TypeAndValue), - Defs: make(map[*ast.Ident]types.Object), - Uses: make(map[*ast.Ident]types.Object), - Implicits: make(map[ast.Node]types.Object), - Scopes: make(map[ast.Node]*types.Scope), - Selections: make(map[*ast.SelectorExpr]*types.Selection), - }, - errorFunc: imp.conf.TypeChecker.Error, - dir: dir, - } - - // Copy the types.Config so we can vary it across PackageInfos. - tc := imp.conf.TypeChecker - tc.IgnoreFuncBodies = false - if f := imp.conf.TypeCheckFuncBodies; f != nil { - tc.IgnoreFuncBodies = !f(path) - } - tc.Import = func(_ map[string]*types.Package, to string) (*types.Package, error) { - return imp.doImport(info, to) - } - tc.Error = info.appendError // appendError wraps the user's Error function - - info.checker = types.NewChecker(&tc, imp.conf.fset(), pkg, &info.Info) - imp.progMu.Lock() - imp.prog.AllPackages[pkg] = info - imp.progMu.Unlock() - return info -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/api.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/api.go deleted file mode 100644 index 27bafef389a..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/api.go +++ /dev/null @@ -1,365 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// Package types declares the data types and implements -// the algorithms for type-checking of Go packages. -// Use Check and Config.Check to invoke the type-checker. -// -// Type-checking consists of several interdependent phases: -// -// Name resolution maps each identifier (ast.Ident) in the program to the -// language object (Object) it denotes. -// Use Info.{Defs,Uses,Implicits} for the results of name resolution. -// -// Constant folding computes the exact constant value (exact.Value) for -// every expression (ast.Expr) that is a compile-time constant. -// Use Info.Types[expr].Value for the results of constant folding. -// -// Type inference computes the type (Type) of every expression (ast.Expr) -// and checks for compliance with the language specification. -// Use Info.Types[expr].Type for the results of type inference. -// -package types - -import ( - "bytes" - "fmt" - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -// Check type-checks a package and returns the resulting complete package -// object, or a nil package and the first error. The package is specified -// by a list of *ast.Files and corresponding file set, and the import path -// the package is identified with. The clean path must not be empty or dot ("."). -// -// For more control over type-checking and results, use Config.Check. -func Check(path string, fset *token.FileSet, files []*ast.File) (*Package, error) { - var conf Config - pkg, err := conf.Check(path, fset, files, nil) - if err != nil { - return nil, err - } - return pkg, nil -} - -// An Error describes a type-checking error; it implements the error interface. -// A "soft" error is an error that still permits a valid interpretation of a -// package (such as "unused variable"); "hard" errors may lead to unpredictable -// behavior if ignored. -type Error struct { - Fset *token.FileSet // file set for interpretation of Pos - Pos token.Pos // error position - Msg string // error message - Soft bool // if set, error is "soft" -} - -// Error returns an error string formatted as follows: -// filename:line:column: message -func (err Error) Error() string { - return fmt.Sprintf("%s: %s", err.Fset.Position(err.Pos), err.Msg) -} - -// An importer resolves import paths to Packages. -// The imports map records packages already known, -// indexed by package path. The type-checker -// will invoke Import with Config.Packages. -// An importer must determine the canonical package path and -// check imports to see if it is already present in the map. -// If so, the Importer can return the map entry. Otherwise, -// the importer must load the package data for the given path -// into a new *Package, record it in imports map, and return -// the package. -// TODO(gri) Need to be clearer about requirements of completeness. -type Importer func(map[string]*Package, string) (*Package, error) - -// A Config specifies the configuration for type checking. -// The zero value for Config is a ready-to-use default configuration. -type Config struct { - // If IgnoreFuncBodies is set, function bodies are not - // type-checked. - IgnoreFuncBodies bool - - // If FakeImportC is set, `import "C"` (for packages requiring Cgo) - // declares an empty "C" package and errors are omitted for qualified - // identifiers referring to package C (which won't find an object). - // This feature is intended for the standard library cmd/api tool. - // - // Caution: Effects may be unpredictable due to follow-up errors. - // Do not use casually! - FakeImportC bool - - // Packages is used to look up (and thus canonicalize) packages by - // package path. If Packages is nil, it is set to a new empty map. - // During type-checking, imported packages are added to the map. - Packages map[string]*Package - - // If Error != nil, it is called with each error found - // during type checking; err has dynamic type Error. - // Secondary errors (for instance, to enumerate all types - // involved in an invalid recursive type declaration) have - // error strings that start with a '\t' character. - // If Error == nil, type-checking stops with the first - // error found. - Error func(err error) - - // If Import != nil, it is called for each imported package. - // Otherwise, DefaultImport is called. - Import Importer - - // If Sizes != nil, it provides the sizing functions for package unsafe. - // Otherwise &StdSizes{WordSize: 8, MaxAlign: 8} is used instead. - Sizes Sizes - - // If DisableUnusedImportCheck is set, packages are not checked - // for unused imports. - DisableUnusedImportCheck bool -} - -// DefaultImport is the default importer invoked if Config.Import == nil. -// The declaration: -// -// import _ "golang.org/x/tools/go/gcimporter" -// -// in a client of go/types will initialize DefaultImport to gcimporter.Import. -var DefaultImport Importer - -// Info holds result type information for a type-checked package. -// Only the information for which a map is provided is collected. -// If the package has type errors, the collected information may -// be incomplete. -type Info struct { - // Types maps expressions to their types, and for constant - // expressions, their values. Invalid expressions are omitted. - // - // For (possibly parenthesized) identifiers denoting built-in - // functions, the recorded signatures are call-site specific: - // if the call result is not a constant, the recorded type is - // an argument-specific signature. Otherwise, the recorded type - // is invalid. - // - // Identifiers on the lhs of declarations (i.e., the identifiers - // which are being declared) are collected in the Defs map. - // Identifiers denoting packages are collected in the Uses maps. - Types map[ast.Expr]TypeAndValue - - // Defs maps identifiers to the objects they define (including - // package names, dots "." of dot-imports, and blank "_" identifiers). - // For identifiers that do not denote objects (e.g., the package name - // in package clauses, or symbolic variables t in t := x.(type) of - // type switch headers), the corresponding objects are nil. - // - // For an anonymous field, Defs returns the field *Var it defines. - // - // Invariant: Defs[id] == nil || Defs[id].Pos() == id.Pos() - Defs map[*ast.Ident]Object - - // Uses maps identifiers to the objects they denote. - // - // For an anonymous field, Uses returns the *TypeName it denotes. - // - // Invariant: Uses[id].Pos() != id.Pos() - Uses map[*ast.Ident]Object - - // Implicits maps nodes to their implicitly declared objects, if any. - // The following node and object types may appear: - // - // node declared object - // - // *ast.ImportSpec *PkgName for dot-imports and imports without renames - // *ast.CaseClause type-specific *Var for each type switch case clause (incl. default) - // *ast.Field anonymous struct field or parameter *Var - // - Implicits map[ast.Node]Object - - // Selections maps selector expressions (excluding qualified identifiers) - // to their corresponding selections. - Selections map[*ast.SelectorExpr]*Selection - - // Scopes maps ast.Nodes to the scopes they define. Package scopes are not - // associated with a specific node but with all files belonging to a package. - // Thus, the package scope can be found in the type-checked Package object. - // Scopes nest, with the Universe scope being the outermost scope, enclosing - // the package scope, which contains (one or more) files scopes, which enclose - // function scopes which in turn enclose statement and function literal scopes. - // Note that even though package-level functions are declared in the package - // scope, the function scopes are embedded in the file scope of the file - // containing the function declaration. - // - // The following node types may appear in Scopes: - // - // *ast.File - // *ast.FuncType - // *ast.BlockStmt - // *ast.IfStmt - // *ast.SwitchStmt - // *ast.TypeSwitchStmt - // *ast.CaseClause - // *ast.CommClause - // *ast.ForStmt - // *ast.RangeStmt - // - Scopes map[ast.Node]*Scope - - // InitOrder is the list of package-level initializers in the order in which - // they must be executed. Initializers referring to variables related by an - // initialization dependency appear in topological order, the others appear - // in source order. Variables without an initialization expression do not - // appear in this list. - InitOrder []*Initializer -} - -// TypeOf returns the type of expression e, or nil if not found. -// Precondition: the Types, Uses and Defs maps are populated. -// -func (info *Info) TypeOf(e ast.Expr) Type { - if t, ok := info.Types[e]; ok { - return t.Type - } - if id, _ := e.(*ast.Ident); id != nil { - if obj := info.ObjectOf(id); obj != nil { - return obj.Type() - } - } - return nil -} - -// ObjectOf returns the object denoted by the specified id, -// or nil if not found. -// -// If id is an anonymous struct field, ObjectOf returns the field (*Var) -// it uses, not the type (*TypeName) it defines. -// -// Precondition: the Uses and Defs maps are populated. -// -func (info *Info) ObjectOf(id *ast.Ident) Object { - if obj, _ := info.Defs[id]; obj != nil { - return obj - } - return info.Uses[id] -} - -// TypeAndValue reports the type and value (for constants) -// of the corresponding expression. -type TypeAndValue struct { - mode operandMode - Type Type - Value exact.Value -} - -// TODO(gri) Consider eliminating the IsVoid predicate. Instead, report -// "void" values as regular values but with the empty tuple type. - -// IsVoid reports whether the corresponding expression -// is a function call without results. -func (tv TypeAndValue) IsVoid() bool { - return tv.mode == novalue -} - -// IsType reports whether the corresponding expression specifies a type. -func (tv TypeAndValue) IsType() bool { - return tv.mode == typexpr -} - -// IsBuiltin reports whether the corresponding expression denotes -// a (possibly parenthesized) built-in function. -func (tv TypeAndValue) IsBuiltin() bool { - return tv.mode == builtin -} - -// IsValue reports whether the corresponding expression is a value. -// Builtins are not considered values. Constant values have a non- -// nil Value. -func (tv TypeAndValue) IsValue() bool { - switch tv.mode { - case constant, variable, mapindex, value, commaok: - return true - } - return false -} - -// IsNil reports whether the corresponding expression denotes the -// predeclared value nil. -func (tv TypeAndValue) IsNil() bool { - return tv.mode == value && tv.Type == Typ[UntypedNil] -} - -// Addressable reports whether the corresponding expression -// is addressable (http://golang.org/ref/spec#Address_operators). -func (tv TypeAndValue) Addressable() bool { - return tv.mode == variable -} - -// Assignable reports whether the corresponding expression -// is assignable to (provided a value of the right type). -func (tv TypeAndValue) Assignable() bool { - return tv.mode == variable || tv.mode == mapindex -} - -// HasOk reports whether the corresponding expression may be -// used on the lhs of a comma-ok assignment. -func (tv TypeAndValue) HasOk() bool { - return tv.mode == commaok || tv.mode == mapindex -} - -// An Initializer describes a package-level variable, or a list of variables in case -// of a multi-valued initialization expression, and the corresponding initialization -// expression. -type Initializer struct { - Lhs []*Var // var Lhs = Rhs - Rhs ast.Expr -} - -func (init *Initializer) String() string { - var buf bytes.Buffer - for i, lhs := range init.Lhs { - if i > 0 { - buf.WriteString(", ") - } - buf.WriteString(lhs.Name()) - } - buf.WriteString(" = ") - WriteExpr(&buf, init.Rhs) - return buf.String() -} - -// Check type-checks a package and returns the resulting package object, -// the first error if any, and if info != nil, additional type information. -// The package is marked as complete if no errors occurred, otherwise it is -// incomplete. See Config.Error for controlling behavior in the presence of -// errors. -// -// The package is specified by a list of *ast.Files and corresponding -// file set, and the package path the package is identified with. -// The clean path must not be empty or dot ("."). -func (conf *Config) Check(path string, fset *token.FileSet, files []*ast.File, info *Info) (*Package, error) { - pkg := NewPackage(path, "") - return pkg, NewChecker(conf, fset, pkg, info).Files(files) -} - -// AssertableTo reports whether a value of type V can be asserted to have type T. -func AssertableTo(V *Interface, T Type) bool { - m, _ := assertableTo(V, T) - return m == nil -} - -// AssignableTo reports whether a value of type V is assignable to a variable of type T. -func AssignableTo(V, T Type) bool { - x := operand{mode: value, typ: V} - return x.assignableTo(nil, T) // config not needed for non-constant x -} - -// ConvertibleTo reports whether a value of type V is convertible to a value of type T. -func ConvertibleTo(V, T Type) bool { - x := operand{mode: value, typ: V} - return x.convertibleTo(nil, T) // config not needed for non-constant x -} - -// Implements reports whether type V implements interface T. -func Implements(V Type, T *Interface) bool { - f, _ := MissingMethod(V, T, true) - return f == nil -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/assignments.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/assignments.go deleted file mode 100644 index 93b842eaa01..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/assignments.go +++ /dev/null @@ -1,328 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements initialization and assignment checks. - -package types - -import ( - "go/ast" - "go/token" -) - -// assignment reports whether x can be assigned to a variable of type T, -// if necessary by attempting to convert untyped values to the appropriate -// type. If x.mode == invalid upon return, then assignment has already -// issued an error message and the caller doesn't have to report another. -// Use T == nil to indicate assignment to an untyped blank identifier. -// -// TODO(gri) Should find a better way to handle in-band errors. -// -func (check *Checker) assignment(x *operand, T Type) bool { - switch x.mode { - case invalid: - return true // error reported before - case constant, variable, mapindex, value, commaok: - // ok - default: - unreachable() - } - - // x must be a single value - // (tuple types are never named - no need for underlying type) - if t, _ := x.typ.(*Tuple); t != nil { - assert(t.Len() > 1) - check.errorf(x.pos(), "%d-valued expression %s used as single value", t.Len(), x) - x.mode = invalid - return false - } - - if isUntyped(x.typ) { - target := T - // spec: "If an untyped constant is assigned to a variable of interface - // type or the blank identifier, the constant is first converted to type - // bool, rune, int, float64, complex128 or string respectively, depending - // on whether the value is a boolean, rune, integer, floating-point, complex, - // or string constant." - if T == nil || IsInterface(T) { - if T == nil && x.typ == Typ[UntypedNil] { - check.errorf(x.pos(), "use of untyped nil") - x.mode = invalid - return false - } - target = defaultType(x.typ) - } - check.convertUntyped(x, target) - if x.mode == invalid { - return false - } - } - - // spec: "If a left-hand side is the blank identifier, any typed or - // non-constant value except for the predeclared identifier nil may - // be assigned to it." - return T == nil || x.assignableTo(check.conf, T) -} - -func (check *Checker) initConst(lhs *Const, x *operand) { - if x.mode == invalid || x.typ == Typ[Invalid] || lhs.typ == Typ[Invalid] { - if lhs.typ == nil { - lhs.typ = Typ[Invalid] - } - return - } - - // rhs must be a constant - if x.mode != constant { - check.errorf(x.pos(), "%s is not constant", x) - if lhs.typ == nil { - lhs.typ = Typ[Invalid] - } - return - } - assert(isConstType(x.typ)) - - // If the lhs doesn't have a type yet, use the type of x. - if lhs.typ == nil { - lhs.typ = x.typ - } - - if !check.assignment(x, lhs.typ) { - if x.mode != invalid { - check.errorf(x.pos(), "cannot define constant %s (type %s) as %s", lhs.Name(), lhs.typ, x) - } - return - } - - lhs.val = x.val -} - -// If result is set, lhs is a function result parameter and x is a return result. -func (check *Checker) initVar(lhs *Var, x *operand, result bool) Type { - if x.mode == invalid || x.typ == Typ[Invalid] || lhs.typ == Typ[Invalid] { - if lhs.typ == nil { - lhs.typ = Typ[Invalid] - } - return nil - } - - // If the lhs doesn't have a type yet, use the type of x. - if lhs.typ == nil { - typ := x.typ - if isUntyped(typ) { - // convert untyped types to default types - if typ == Typ[UntypedNil] { - check.errorf(x.pos(), "use of untyped nil") - lhs.typ = Typ[Invalid] - return nil - } - typ = defaultType(typ) - } - lhs.typ = typ - } - - if !check.assignment(x, lhs.typ) { - if x.mode != invalid { - if result { - // don't refer to lhs.name because it may be an anonymous result parameter - check.errorf(x.pos(), "cannot return %s as value of type %s", x, lhs.typ) - } else { - check.errorf(x.pos(), "cannot initialize %s with %s", lhs, x) - } - } - return nil - } - - return x.typ -} - -func (check *Checker) assignVar(lhs ast.Expr, x *operand) Type { - if x.mode == invalid || x.typ == Typ[Invalid] { - return nil - } - - // Determine if the lhs is a (possibly parenthesized) identifier. - ident, _ := unparen(lhs).(*ast.Ident) - - // Don't evaluate lhs if it is the blank identifier. - if ident != nil && ident.Name == "_" { - check.recordDef(ident, nil) - if !check.assignment(x, nil) { - assert(x.mode == invalid) - x.typ = nil - } - return x.typ - } - - // If the lhs is an identifier denoting a variable v, this assignment - // is not a 'use' of v. Remember current value of v.used and restore - // after evaluating the lhs via check.expr. - var v *Var - var v_used bool - if ident != nil { - if _, obj := check.scope.LookupParent(ident.Name, token.NoPos); obj != nil { - v, _ = obj.(*Var) - if v != nil { - v_used = v.used - } - } - } - - var z operand - check.expr(&z, lhs) - if v != nil { - v.used = v_used // restore v.used - } - - if z.mode == invalid || z.typ == Typ[Invalid] { - return nil - } - - // spec: "Each left-hand side operand must be addressable, a map index - // expression, or the blank identifier. Operands may be parenthesized." - switch z.mode { - case invalid: - return nil - case variable, mapindex: - // ok - default: - check.errorf(z.pos(), "cannot assign to %s", &z) - return nil - } - - if !check.assignment(x, z.typ) { - if x.mode != invalid { - check.errorf(x.pos(), "cannot assign %s to %s", x, &z) - } - return nil - } - - return x.typ -} - -// If returnPos is valid, initVars is called to type-check the assignment of -// return expressions, and returnPos is the position of the return statement. -func (check *Checker) initVars(lhs []*Var, rhs []ast.Expr, returnPos token.Pos) { - l := len(lhs) - get, r, commaOk := unpack(func(x *operand, i int) { check.expr(x, rhs[i]) }, len(rhs), l == 2 && !returnPos.IsValid()) - if get == nil || l != r { - // invalidate lhs and use rhs - for _, obj := range lhs { - if obj.typ == nil { - obj.typ = Typ[Invalid] - } - } - if get == nil { - return // error reported by unpack - } - check.useGetter(get, r) - if returnPos.IsValid() { - check.errorf(returnPos, "wrong number of return values (want %d, got %d)", l, r) - return - } - check.errorf(rhs[0].Pos(), "assignment count mismatch (%d vs %d)", l, r) - return - } - - var x operand - if commaOk { - var a [2]Type - for i := range a { - get(&x, i) - a[i] = check.initVar(lhs[i], &x, returnPos.IsValid()) - } - check.recordCommaOkTypes(rhs[0], a) - return - } - - for i, lhs := range lhs { - get(&x, i) - check.initVar(lhs, &x, returnPos.IsValid()) - } -} - -func (check *Checker) assignVars(lhs, rhs []ast.Expr) { - l := len(lhs) - get, r, commaOk := unpack(func(x *operand, i int) { check.expr(x, rhs[i]) }, len(rhs), l == 2) - if get == nil { - return // error reported by unpack - } - if l != r { - check.useGetter(get, r) - check.errorf(rhs[0].Pos(), "assignment count mismatch (%d vs %d)", l, r) - return - } - - var x operand - if commaOk { - var a [2]Type - for i := range a { - get(&x, i) - a[i] = check.assignVar(lhs[i], &x) - } - check.recordCommaOkTypes(rhs[0], a) - return - } - - for i, lhs := range lhs { - get(&x, i) - check.assignVar(lhs, &x) - } -} - -func (check *Checker) shortVarDecl(pos token.Pos, lhs, rhs []ast.Expr) { - scope := check.scope - - // collect lhs variables - var newVars []*Var - var lhsVars = make([]*Var, len(lhs)) - for i, lhs := range lhs { - var obj *Var - if ident, _ := lhs.(*ast.Ident); ident != nil { - // Use the correct obj if the ident is redeclared. The - // variable's scope starts after the declaration; so we - // must use Scope.Lookup here and call Scope.Insert - // (via check.declare) later. - name := ident.Name - if alt := scope.Lookup(name); alt != nil { - // redeclared object must be a variable - if alt, _ := alt.(*Var); alt != nil { - obj = alt - } else { - check.errorf(lhs.Pos(), "cannot assign to %s", lhs) - } - check.recordUse(ident, alt) - } else { - // declare new variable, possibly a blank (_) variable - obj = NewVar(ident.Pos(), check.pkg, name, nil) - if name != "_" { - newVars = append(newVars, obj) - } - check.recordDef(ident, obj) - } - } else { - check.errorf(lhs.Pos(), "cannot declare %s", lhs) - } - if obj == nil { - obj = NewVar(lhs.Pos(), check.pkg, "_", nil) // dummy variable - } - lhsVars[i] = obj - } - - check.initVars(lhsVars, rhs, token.NoPos) - - // declare new variables - if len(newVars) > 0 { - // spec: "The scope of a constant or variable identifier declared inside - // a function begins at the end of the ConstSpec or VarSpec (ShortVarDecl - // for short variable declarations) and ends at the end of the innermost - // containing block." - scopePos := rhs[len(rhs)-1].End() - for _, obj := range newVars { - check.declare(scope, nil, obj, scopePos) // recordObject already called - } - } else { - check.softErrorf(pos, "no new variables on left side of :=") - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/builtins.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/builtins.go deleted file mode 100644 index f45f930a42d..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/builtins.go +++ /dev/null @@ -1,628 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements typechecking of builtin function calls. - -package types - -import ( - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -// builtin type-checks a call to the built-in specified by id and -// returns true if the call is valid, with *x holding the result; -// but x.expr is not set. If the call is invalid, the result is -// false, and *x is undefined. -// -func (check *Checker) builtin(x *operand, call *ast.CallExpr, id builtinId) (_ bool) { - // append is the only built-in that permits the use of ... for the last argument - bin := predeclaredFuncs[id] - if call.Ellipsis.IsValid() && id != _Append { - check.invalidOp(call.Ellipsis, "invalid use of ... with built-in %s", bin.name) - check.use(call.Args...) - return - } - - // For len(x) and cap(x) we need to know if x contains any function calls or - // receive operations. Save/restore current setting and set hasCallOrRecv to - // false for the evaluation of x so that we can check it afterwards. - // Note: We must do this _before_ calling unpack because unpack evaluates the - // first argument before we even call arg(x, 0)! - if id == _Len || id == _Cap { - defer func(b bool) { - check.hasCallOrRecv = b - }(check.hasCallOrRecv) - check.hasCallOrRecv = false - } - - // determine actual arguments - var arg getter - nargs := len(call.Args) - switch id { - default: - // make argument getter - arg, nargs, _ = unpack(func(x *operand, i int) { check.expr(x, call.Args[i]) }, nargs, false) - if arg == nil { - return - } - // evaluate first argument, if present - if nargs > 0 { - arg(x, 0) - if x.mode == invalid { - return - } - } - case _Make, _New, _Offsetof, _Trace: - // arguments require special handling - } - - // check argument count - { - msg := "" - if nargs < bin.nargs { - msg = "not enough" - } else if !bin.variadic && nargs > bin.nargs { - msg = "too many" - } - if msg != "" { - check.invalidOp(call.Rparen, "%s arguments for %s (expected %d, found %d)", msg, call, bin.nargs, nargs) - return - } - } - - switch id { - case _Append: - // append(s S, x ...T) S, where T is the element type of S - // spec: "The variadic function append appends zero or more values x to s of type - // S, which must be a slice type, and returns the resulting slice, also of type S. - // The values x are passed to a parameter of type ...T where T is the element type - // of S and the respective parameter passing rules apply." - S := x.typ - var T Type - if s, _ := S.Underlying().(*Slice); s != nil { - T = s.elem - } else { - check.invalidArg(x.pos(), "%s is not a slice", x) - return - } - - // remember arguments that have been evaluated already - alist := []operand{*x} - - // spec: "As a special case, append also accepts a first argument assignable - // to type []byte with a second argument of string type followed by ... . - // This form appends the bytes of the string. - if nargs == 2 && call.Ellipsis.IsValid() && x.assignableTo(check.conf, NewSlice(universeByte)) { - arg(x, 1) - if x.mode == invalid { - return - } - if isString(x.typ) { - if check.Types != nil { - sig := makeSig(S, S, x.typ) - sig.variadic = true - check.recordBuiltinType(call.Fun, sig) - } - x.mode = value - x.typ = S - break - } - alist = append(alist, *x) - // fallthrough - } - - // check general case by creating custom signature - sig := makeSig(S, S, NewSlice(T)) // []T required for variadic signature - sig.variadic = true - check.arguments(x, call, sig, func(x *operand, i int) { - // only evaluate arguments that have not been evaluated before - if i < len(alist) { - *x = alist[i] - return - } - arg(x, i) - }, nargs) - // ok to continue even if check.arguments reported errors - - x.mode = value - x.typ = S - if check.Types != nil { - check.recordBuiltinType(call.Fun, sig) - } - - case _Cap, _Len: - // cap(x) - // len(x) - mode := invalid - var typ Type - var val exact.Value - switch typ = implicitArrayDeref(x.typ.Underlying()); t := typ.(type) { - case *Basic: - if isString(t) && id == _Len { - if x.mode == constant { - mode = constant - val = exact.MakeInt64(int64(len(exact.StringVal(x.val)))) - } else { - mode = value - } - } - - case *Array: - mode = value - // spec: "The expressions len(s) and cap(s) are constants - // if the type of s is an array or pointer to an array and - // the expression s does not contain channel receives or - // function calls; in this case s is not evaluated." - if !check.hasCallOrRecv { - mode = constant - val = exact.MakeInt64(t.len) - } - - case *Slice, *Chan: - mode = value - - case *Map: - if id == _Len { - mode = value - } - } - - if mode == invalid { - check.invalidArg(x.pos(), "%s for %s", x, bin.name) - return - } - - x.mode = mode - x.typ = Typ[Int] - x.val = val - if check.Types != nil && mode != constant { - check.recordBuiltinType(call.Fun, makeSig(x.typ, typ)) - } - - case _Close: - // close(c) - c, _ := x.typ.Underlying().(*Chan) - if c == nil { - check.invalidArg(x.pos(), "%s is not a channel", x) - return - } - if c.dir == RecvOnly { - check.invalidArg(x.pos(), "%s must not be a receive-only channel", x) - return - } - - x.mode = novalue - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(nil, c)) - } - - case _Complex: - // complex(x, y realT) complexT - if !check.complexArg(x) { - return - } - - var y operand - arg(&y, 1) - if y.mode == invalid { - return - } - if !check.complexArg(&y) { - return - } - - check.convertUntyped(x, y.typ) - if x.mode == invalid { - return - } - check.convertUntyped(&y, x.typ) - if y.mode == invalid { - return - } - - if !Identical(x.typ, y.typ) { - check.invalidArg(x.pos(), "mismatched types %s and %s", x.typ, y.typ) - return - } - - if x.mode == constant && y.mode == constant { - x.val = exact.BinaryOp(x.val, token.ADD, exact.MakeImag(y.val)) - } else { - x.mode = value - } - - realT := x.typ - complexT := Typ[Invalid] - switch realT.Underlying().(*Basic).kind { - case Float32: - complexT = Typ[Complex64] - case Float64: - complexT = Typ[Complex128] - case UntypedInt, UntypedRune, UntypedFloat: - if x.mode == constant { - realT = defaultType(realT).(*Basic) - complexT = Typ[UntypedComplex] - } else { - // untyped but not constant; probably because one - // operand is a non-constant shift of untyped lhs - realT = Typ[Float64] - complexT = Typ[Complex128] - } - default: - check.invalidArg(x.pos(), "float32 or float64 arguments expected") - return - } - - x.typ = complexT - if check.Types != nil && x.mode != constant { - check.recordBuiltinType(call.Fun, makeSig(complexT, realT, realT)) - } - - if x.mode != constant { - // The arguments have now their final types, which at run- - // time will be materialized. Update the expression trees. - // If the current types are untyped, the materialized type - // is the respective default type. - // (If the result is constant, the arguments are never - // materialized and there is nothing to do.) - check.updateExprType(x.expr, realT, true) - check.updateExprType(y.expr, realT, true) - } - - case _Copy: - // copy(x, y []T) int - var dst Type - if t, _ := x.typ.Underlying().(*Slice); t != nil { - dst = t.elem - } - - var y operand - arg(&y, 1) - if y.mode == invalid { - return - } - var src Type - switch t := y.typ.Underlying().(type) { - case *Basic: - if isString(y.typ) { - src = universeByte - } - case *Slice: - src = t.elem - } - - if dst == nil || src == nil { - check.invalidArg(x.pos(), "copy expects slice arguments; found %s and %s", x, &y) - return - } - - if !Identical(dst, src) { - check.invalidArg(x.pos(), "arguments to copy %s and %s have different element types %s and %s", x, &y, dst, src) - return - } - - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(Typ[Int], x.typ, y.typ)) - } - x.mode = value - x.typ = Typ[Int] - - case _Delete: - // delete(m, k) - m, _ := x.typ.Underlying().(*Map) - if m == nil { - check.invalidArg(x.pos(), "%s is not a map", x) - return - } - arg(x, 1) // k - if x.mode == invalid { - return - } - - if !x.assignableTo(check.conf, m.key) { - check.invalidArg(x.pos(), "%s is not assignable to %s", x, m.key) - return - } - - x.mode = novalue - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(nil, m, m.key)) - } - - case _Imag, _Real: - // imag(complexT) realT - // real(complexT) realT - if !isComplex(x.typ) { - check.invalidArg(x.pos(), "%s must be a complex number", x) - return - } - if x.mode == constant { - if id == _Real { - x.val = exact.Real(x.val) - } else { - x.val = exact.Imag(x.val) - } - } else { - x.mode = value - } - var k BasicKind - switch x.typ.Underlying().(*Basic).kind { - case Complex64: - k = Float32 - case Complex128: - k = Float64 - case UntypedComplex: - k = UntypedFloat - default: - unreachable() - } - - if check.Types != nil && x.mode != constant { - check.recordBuiltinType(call.Fun, makeSig(Typ[k], x.typ)) - } - x.typ = Typ[k] - - case _Make: - // make(T, n) - // make(T, n, m) - // (no argument evaluated yet) - arg0 := call.Args[0] - T := check.typ(arg0) - if T == Typ[Invalid] { - return - } - - var min int // minimum number of arguments - switch T.Underlying().(type) { - case *Slice: - min = 2 - case *Map, *Chan: - min = 1 - default: - check.invalidArg(arg0.Pos(), "cannot make %s; type must be slice, map, or channel", arg0) - return - } - if nargs < min || min+1 < nargs { - check.errorf(call.Pos(), "%s expects %d or %d arguments; found %d", call, min, min+1, nargs) - return - } - var sizes []int64 // constant integer arguments, if any - for _, arg := range call.Args[1:] { - if s, ok := check.index(arg, -1); ok && s >= 0 { - sizes = append(sizes, s) - } - } - if len(sizes) == 2 && sizes[0] > sizes[1] { - check.invalidArg(call.Args[1].Pos(), "length and capacity swapped") - // safe to continue - } - x.mode = value - x.typ = T - if check.Types != nil { - params := [...]Type{T, Typ[Int], Typ[Int]} - check.recordBuiltinType(call.Fun, makeSig(x.typ, params[:1+len(sizes)]...)) - } - - case _New: - // new(T) - // (no argument evaluated yet) - T := check.typ(call.Args[0]) - if T == Typ[Invalid] { - return - } - - x.mode = value - x.typ = &Pointer{base: T} - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(x.typ, T)) - } - - case _Panic: - // panic(x) - T := new(Interface) - if !check.assignment(x, T) { - assert(x.mode == invalid) - return - } - - x.mode = novalue - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(nil, T)) - } - - case _Print, _Println: - // print(x, y, ...) - // println(x, y, ...) - var params []Type - if nargs > 0 { - params = make([]Type, nargs) - for i := 0; i < nargs; i++ { - if i > 0 { - arg(x, i) // first argument already evaluated - } - if !check.assignment(x, nil) { - assert(x.mode == invalid) - return - } - params[i] = x.typ - } - } - - x.mode = novalue - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(nil, params...)) - } - - case _Recover: - // recover() interface{} - x.mode = value - x.typ = new(Interface) - if check.Types != nil { - check.recordBuiltinType(call.Fun, makeSig(x.typ)) - } - - case _Alignof: - // unsafe.Alignof(x T) uintptr - if !check.assignment(x, nil) { - assert(x.mode == invalid) - return - } - - x.mode = constant - x.val = exact.MakeInt64(check.conf.alignof(x.typ)) - x.typ = Typ[Uintptr] - // result is constant - no need to record signature - - case _Offsetof: - // unsafe.Offsetof(x T) uintptr, where x must be a selector - // (no argument evaluated yet) - arg0 := call.Args[0] - selx, _ := unparen(arg0).(*ast.SelectorExpr) - if selx == nil { - check.invalidArg(arg0.Pos(), "%s is not a selector expression", arg0) - check.use(arg0) - return - } - - check.expr(x, selx.X) - if x.mode == invalid { - return - } - - base := derefStructPtr(x.typ) - sel := selx.Sel.Name - obj, index, indirect := LookupFieldOrMethod(base, false, check.pkg, sel) - switch obj.(type) { - case nil: - check.invalidArg(x.pos(), "%s has no single field %s", base, sel) - return - case *Func: - // TODO(gri) Using derefStructPtr may result in methods being found - // that don't actually exist. An error either way, but the error - // message is confusing. See: http://play.golang.org/p/al75v23kUy , - // but go/types reports: "invalid argument: x.m is a method value". - check.invalidArg(arg0.Pos(), "%s is a method value", arg0) - return - } - if indirect { - check.invalidArg(x.pos(), "field %s is embedded via a pointer in %s", sel, base) - return - } - - // TODO(gri) Should we pass x.typ instead of base (and indirect report if derefStructPtr indirected)? - check.recordSelection(selx, FieldVal, base, obj, index, false) - - offs := check.conf.offsetof(base, index) - x.mode = constant - x.val = exact.MakeInt64(offs) - x.typ = Typ[Uintptr] - // result is constant - no need to record signature - - case _Sizeof: - // unsafe.Sizeof(x T) uintptr - if !check.assignment(x, nil) { - assert(x.mode == invalid) - return - } - - x.mode = constant - x.val = exact.MakeInt64(check.conf.sizeof(x.typ)) - x.typ = Typ[Uintptr] - // result is constant - no need to record signature - - case _Assert: - // assert(pred) causes a typechecker error if pred is false. - // The result of assert is the value of pred if there is no error. - // Note: assert is only available in self-test mode. - if x.mode != constant || !isBoolean(x.typ) { - check.invalidArg(x.pos(), "%s is not a boolean constant", x) - return - } - if x.val.Kind() != exact.Bool { - check.errorf(x.pos(), "internal error: value of %s should be a boolean constant", x) - return - } - if !exact.BoolVal(x.val) { - check.errorf(call.Pos(), "%s failed", call) - // compile-time assertion failure - safe to continue - } - // result is constant - no need to record signature - - case _Trace: - // trace(x, y, z, ...) dumps the positions, expressions, and - // values of its arguments. The result of trace is the value - // of the first argument. - // Note: trace is only available in self-test mode. - // (no argument evaluated yet) - if nargs == 0 { - check.dump("%s: trace() without arguments", call.Pos()) - x.mode = novalue - break - } - var t operand - x1 := x - for _, arg := range call.Args { - check.rawExpr(x1, arg, nil) // permit trace for types, e.g.: new(trace(T)) - check.dump("%s: %s", x1.pos(), x1) - x1 = &t // use incoming x only for first argument - } - // trace is only available in test mode - no need to record signature - - default: - unreachable() - } - - return true -} - -// makeSig makes a signature for the given argument and result types. -// Default types are used for untyped arguments, and res may be nil. -func makeSig(res Type, args ...Type) *Signature { - list := make([]*Var, len(args)) - for i, param := range args { - list[i] = NewVar(token.NoPos, nil, "", defaultType(param)) - } - params := NewTuple(list...) - var result *Tuple - if res != nil { - assert(!isUntyped(res)) - result = NewTuple(NewVar(token.NoPos, nil, "", res)) - } - return &Signature{params: params, results: result} -} - -// implicitArrayDeref returns A if typ is of the form *A and A is an array; -// otherwise it returns typ. -// -func implicitArrayDeref(typ Type) Type { - if p, ok := typ.(*Pointer); ok { - if a, ok := p.base.Underlying().(*Array); ok { - return a - } - } - return typ -} - -// unparen returns e with any enclosing parentheses stripped. -func unparen(e ast.Expr) ast.Expr { - for { - p, ok := e.(*ast.ParenExpr) - if !ok { - return e - } - e = p.X - } -} - -func (check *Checker) complexArg(x *operand) bool { - t, _ := x.typ.Underlying().(*Basic) - if t != nil && (t.info&IsFloat != 0 || t.kind == UntypedInt || t.kind == UntypedRune) { - return true - } - check.invalidArg(x.pos(), "%s must be a float32, float64, or an untyped non-complex numeric constant", x) - return false -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/call.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/call.go deleted file mode 100644 index 1e94212398e..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/call.go +++ /dev/null @@ -1,441 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements typechecking of call and selector expressions. - -package types - -import ( - "go/ast" - "go/token" -) - -func (check *Checker) call(x *operand, e *ast.CallExpr) exprKind { - check.exprOrType(x, e.Fun) - - switch x.mode { - case invalid: - check.use(e.Args...) - x.mode = invalid - x.expr = e - return statement - - case typexpr: - // conversion - T := x.typ - x.mode = invalid - switch n := len(e.Args); n { - case 0: - check.errorf(e.Rparen, "missing argument in conversion to %s", T) - case 1: - check.expr(x, e.Args[0]) - if x.mode != invalid { - check.conversion(x, T) - } - default: - check.errorf(e.Args[n-1].Pos(), "too many arguments in conversion to %s", T) - } - x.expr = e - return conversion - - case builtin: - id := x.id - if !check.builtin(x, e, id) { - x.mode = invalid - } - x.expr = e - // a non-constant result implies a function call - if x.mode != invalid && x.mode != constant { - check.hasCallOrRecv = true - } - return predeclaredFuncs[id].kind - - default: - // function/method call - sig, _ := x.typ.Underlying().(*Signature) - if sig == nil { - check.invalidOp(x.pos(), "cannot call non-function %s", x) - x.mode = invalid - x.expr = e - return statement - } - - arg, n, _ := unpack(func(x *operand, i int) { check.expr(x, e.Args[i]) }, len(e.Args), false) - if arg == nil { - x.mode = invalid - x.expr = e - return statement - } - - check.arguments(x, e, sig, arg, n) - - // determine result - switch sig.results.Len() { - case 0: - x.mode = novalue - case 1: - x.mode = value - x.typ = sig.results.vars[0].typ // unpack tuple - default: - x.mode = value - x.typ = sig.results - } - x.expr = e - check.hasCallOrRecv = true - - return statement - } -} - -// use type-checks each argument. -// Useful to make sure expressions are evaluated -// (and variables are "used") in the presence of other errors. -func (check *Checker) use(arg ...ast.Expr) { - var x operand - for _, e := range arg { - check.rawExpr(&x, e, nil) - } -} - -// useGetter is like use, but takes a getter instead of a list of expressions. -// It should be called instead of use if a getter is present to avoid repeated -// evaluation of the first argument (since the getter was likely obtained via -// unpack, which may have evaluated the first argument already). -func (check *Checker) useGetter(get getter, n int) { - var x operand - for i := 0; i < n; i++ { - get(&x, i) - } -} - -// A getter sets x as the i'th operand, where 0 <= i < n and n is the total -// number of operands (context-specific, and maintained elsewhere). A getter -// type-checks the i'th operand; the details of the actual check are getter- -// specific. -type getter func(x *operand, i int) - -// unpack takes a getter get and a number of operands n. If n == 1, unpack -// calls the incoming getter for the first operand. If that operand is -// invalid, unpack returns (nil, 0, false). Otherwise, if that operand is a -// function call, or a comma-ok expression and allowCommaOk is set, the result -// is a new getter and operand count providing access to the function results, -// or comma-ok values, respectively. The third result value reports if it -// is indeed the comma-ok case. In all other cases, the incoming getter and -// operand count are returned unchanged, and the third result value is false. -// -// In other words, if there's exactly one operand that - after type-checking -// by calling get - stands for multiple operands, the resulting getter provides -// access to those operands instead. -// -// If the returned getter is called at most once for a given operand index i -// (including i == 0), that operand is guaranteed to cause only one call of -// the incoming getter with that i. -// -func unpack(get getter, n int, allowCommaOk bool) (getter, int, bool) { - if n == 1 { - // possibly result of an n-valued function call or comma,ok value - var x0 operand - get(&x0, 0) - if x0.mode == invalid { - return nil, 0, false - } - - if t, ok := x0.typ.(*Tuple); ok { - // result of an n-valued function call - return func(x *operand, i int) { - x.mode = value - x.expr = x0.expr - x.typ = t.At(i).typ - }, t.Len(), false - } - - if x0.mode == mapindex || x0.mode == commaok { - // comma-ok value - if allowCommaOk { - a := [2]Type{x0.typ, Typ[UntypedBool]} - return func(x *operand, i int) { - x.mode = value - x.expr = x0.expr - x.typ = a[i] - }, 2, true - } - x0.mode = value - } - - // single value - return func(x *operand, i int) { - if i != 0 { - unreachable() - } - *x = x0 - }, 1, false - } - - // zero or multiple values - return get, n, false -} - -// arguments checks argument passing for the call with the given signature. -// The arg function provides the operand for the i'th argument. -func (check *Checker) arguments(x *operand, call *ast.CallExpr, sig *Signature, arg getter, n int) { - if call.Ellipsis.IsValid() { - // last argument is of the form x... - if len(call.Args) == 1 && n > 1 { - // f()... is not permitted if f() is multi-valued - check.errorf(call.Ellipsis, "cannot use ... with %d-valued expression %s", n, call.Args[0]) - check.useGetter(arg, n) - return - } - if !sig.variadic { - check.errorf(call.Ellipsis, "cannot use ... in call to non-variadic %s", call.Fun) - check.useGetter(arg, n) - return - } - } - - // evaluate arguments - for i := 0; i < n; i++ { - arg(x, i) - if x.mode != invalid { - var ellipsis token.Pos - if i == n-1 && call.Ellipsis.IsValid() { - ellipsis = call.Ellipsis - } - check.argument(sig, i, x, ellipsis) - } - } - - // check argument count - if sig.variadic { - // a variadic function accepts an "empty" - // last argument: count one extra - n++ - } - if n < sig.params.Len() { - check.errorf(call.Rparen, "too few arguments in call to %s", call.Fun) - // ok to continue - } -} - -// argument checks passing of argument x to the i'th parameter of the given signature. -// If ellipsis is valid, the argument is followed by ... at that position in the call. -func (check *Checker) argument(sig *Signature, i int, x *operand, ellipsis token.Pos) { - n := sig.params.Len() - - // determine parameter type - var typ Type - switch { - case i < n: - typ = sig.params.vars[i].typ - case sig.variadic: - typ = sig.params.vars[n-1].typ - if debug { - if _, ok := typ.(*Slice); !ok { - check.dump("%s: expected unnamed slice type, got %s", sig.params.vars[n-1].Pos(), typ) - } - } - default: - check.errorf(x.pos(), "too many arguments") - return - } - - if ellipsis.IsValid() { - // argument is of the form x... - if i != n-1 { - check.errorf(ellipsis, "can only use ... with matching parameter") - return - } - switch t := x.typ.Underlying().(type) { - case *Slice: - // ok - case *Tuple: - check.errorf(ellipsis, "cannot use ... with %d-valued expression %s", t.Len(), x) - return - default: - check.errorf(x.pos(), "cannot use %s as parameter of type %s", x, typ) - return - } - } else if sig.variadic && i >= n-1 { - // use the variadic parameter slice's element type - typ = typ.(*Slice).elem - } - - if !check.assignment(x, typ) && x.mode != invalid { - check.errorf(x.pos(), "cannot pass argument %s to parameter of type %s", x, typ) - } -} - -func (check *Checker) selector(x *operand, e *ast.SelectorExpr) { - // these must be declared before the "goto Error" statements - var ( - obj Object - index []int - indirect bool - ) - - sel := e.Sel.Name - // If the identifier refers to a package, handle everything here - // so we don't need a "package" mode for operands: package names - // can only appear in qualified identifiers which are mapped to - // selector expressions. - if ident, ok := e.X.(*ast.Ident); ok { - _, obj := check.scope.LookupParent(ident.Name, check.pos) - if pkg, _ := obj.(*PkgName); pkg != nil { - assert(pkg.pkg == check.pkg) - check.recordUse(ident, pkg) - pkg.used = true - exp := pkg.imported.scope.Lookup(sel) - if exp == nil { - if !pkg.imported.fake { - check.errorf(e.Pos(), "%s not declared by package %s", sel, ident) - } - goto Error - } - if !exp.Exported() { - check.errorf(e.Pos(), "%s not exported by package %s", sel, ident) - // ok to continue - } - check.recordUse(e.Sel, exp) - // Simplified version of the code for *ast.Idents: - // - imported objects are always fully initialized - switch exp := exp.(type) { - case *Const: - assert(exp.Val() != nil) - x.mode = constant - x.typ = exp.typ - x.val = exp.val - case *TypeName: - x.mode = typexpr - x.typ = exp.typ - case *Var: - x.mode = variable - x.typ = exp.typ - case *Func: - x.mode = value - x.typ = exp.typ - case *Builtin: - x.mode = builtin - x.typ = exp.typ - x.id = exp.id - default: - unreachable() - } - x.expr = e - return - } - } - - check.exprOrType(x, e.X) - if x.mode == invalid { - goto Error - } - - obj, index, indirect = LookupFieldOrMethod(x.typ, x.mode == variable, check.pkg, sel) - if obj == nil { - switch { - case index != nil: - // TODO(gri) should provide actual type where the conflict happens - check.invalidOp(e.Pos(), "ambiguous selector %s", sel) - case indirect: - check.invalidOp(e.Pos(), "%s is not in method set of %s", sel, x.typ) - default: - check.invalidOp(e.Pos(), "%s has no field or method %s", x, sel) - } - goto Error - } - - if x.mode == typexpr { - // method expression - m, _ := obj.(*Func) - if m == nil { - check.invalidOp(e.Pos(), "%s has no method %s", x, sel) - goto Error - } - - check.recordSelection(e, MethodExpr, x.typ, m, index, indirect) - - // the receiver type becomes the type of the first function - // argument of the method expression's function type - var params []*Var - sig := m.typ.(*Signature) - if sig.params != nil { - params = sig.params.vars - } - x.mode = value - x.typ = &Signature{ - params: NewTuple(append([]*Var{NewVar(token.NoPos, check.pkg, "", x.typ)}, params...)...), - results: sig.results, - variadic: sig.variadic, - } - - check.addDeclDep(m) - - } else { - // regular selector - switch obj := obj.(type) { - case *Var: - check.recordSelection(e, FieldVal, x.typ, obj, index, indirect) - if x.mode == variable || indirect { - x.mode = variable - } else { - x.mode = value - } - x.typ = obj.typ - - case *Func: - // TODO(gri) If we needed to take into account the receiver's - // addressability, should we report the type &(x.typ) instead? - check.recordSelection(e, MethodVal, x.typ, obj, index, indirect) - - if debug { - // Verify that LookupFieldOrMethod and MethodSet.Lookup agree. - typ := x.typ - if x.mode == variable { - // If typ is not an (unnamed) pointer or an interface, - // use *typ instead, because the method set of *typ - // includes the methods of typ. - // Variables are addressable, so we can always take their - // address. - if _, ok := typ.(*Pointer); !ok && !IsInterface(typ) { - typ = &Pointer{base: typ} - } - } - // If we created a synthetic pointer type above, we will throw - // away the method set computed here after use. - // TODO(gri) Method set computation should probably always compute - // both, the value and the pointer receiver method set and represent - // them in a single structure. - // TODO(gri) Consider also using a method set cache for the lifetime - // of checker once we rely on MethodSet lookup instead of individual - // lookup. - mset := NewMethodSet(typ) - if m := mset.Lookup(check.pkg, sel); m == nil || m.obj != obj { - check.dump("%s: (%s).%v -> %s", e.Pos(), typ, obj.name, m) - check.dump("%s\n", mset) - panic("method sets and lookup don't agree") - } - } - - x.mode = value - - // remove receiver - sig := *obj.typ.(*Signature) - sig.recv = nil - x.typ = &sig - - check.addDeclDep(obj) - - default: - unreachable() - } - } - - // everything went well - x.expr = e - return - -Error: - x.mode = invalid - x.expr = e -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/check.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/check.go deleted file mode 100644 index 964d2bde032..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/check.go +++ /dev/null @@ -1,364 +0,0 @@ -// Copyright 2011 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements the Check function, which drives type-checking. - -package types - -import ( - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -// debugging/development support -const ( - debug = false // leave on during development - trace = false // turn on for detailed type resolution traces -) - -// If Strict is set, the type-checker enforces additional -// rules not specified by the Go 1 spec, but which will -// catch guaranteed run-time errors if the respective -// code is executed. In other words, programs passing in -// Strict mode are Go 1 compliant, but not all Go 1 programs -// will pass in Strict mode. The additional rules are: -// -// - A type assertion x.(T) where T is an interface type -// is invalid if any (statically known) method that exists -// for both x and T have different signatures. -// -const strict = false - -// exprInfo stores information about an untyped expression. -type exprInfo struct { - isLhs bool // expression is lhs operand of a shift with delayed type-check - mode operandMode - typ *Basic - val exact.Value // constant value; or nil (if not a constant) -} - -// funcInfo stores the information required for type-checking a function. -type funcInfo struct { - name string // for debugging/tracing only - decl *declInfo // for cycle detection - sig *Signature - body *ast.BlockStmt -} - -// A context represents the context within which an object is type-checked. -type context struct { - decl *declInfo // package-level declaration whose init expression/function body is checked - scope *Scope // top-most scope for lookups - iota exact.Value // value of iota in a constant declaration; nil otherwise - sig *Signature // function signature if inside a function; nil otherwise - hasLabel bool // set if a function makes use of labels (only ~1% of functions); unused outside functions - hasCallOrRecv bool // set if an expression contains a function call or channel receive operation -} - -// A Checker maintains the state of the type checker. -// It must be created with NewChecker. -type Checker struct { - // package information - // (initialized by NewChecker, valid for the life-time of checker) - conf *Config - fset *token.FileSet - pkg *Package - *Info - objMap map[Object]*declInfo // maps package-level object to declaration info - - // information collected during type-checking of a set of package files - // (initialized by Files, valid only for the duration of check.Files; - // maps and lists are allocated on demand) - files []*ast.File // package files - unusedDotImports map[*Scope]map[*Package]token.Pos // positions of unused dot-imported packages for each file scope - - firstErr error // first error encountered - methods map[string][]*Func // maps type names to associated methods - untyped map[ast.Expr]exprInfo // map of expressions without final type - funcs []funcInfo // list of functions to type-check - delayed []func() // delayed checks requiring fully setup types - - // context within which the current object is type-checked - // (valid only for the duration of type-checking a specific object) - context - pos token.Pos // if valid, identifiers are looked up as if at position pos (used by Eval) - - // debugging - indent int // indentation for tracing -} - -// addUnusedImport adds the position of a dot-imported package -// pkg to the map of dot imports for the given file scope. -func (check *Checker) addUnusedDotImport(scope *Scope, pkg *Package, pos token.Pos) { - mm := check.unusedDotImports - if mm == nil { - mm = make(map[*Scope]map[*Package]token.Pos) - check.unusedDotImports = mm - } - m := mm[scope] - if m == nil { - m = make(map[*Package]token.Pos) - mm[scope] = m - } - m[pkg] = pos -} - -// addDeclDep adds the dependency edge (check.decl -> to) if check.decl exists -func (check *Checker) addDeclDep(to Object) { - from := check.decl - if from == nil { - return // not in a package-level init expression - } - if _, found := check.objMap[to]; !found { - return // to is not a package-level object - } - from.addDep(to) -} - -func (check *Checker) assocMethod(tname string, meth *Func) { - m := check.methods - if m == nil { - m = make(map[string][]*Func) - check.methods = m - } - m[tname] = append(m[tname], meth) -} - -func (check *Checker) rememberUntyped(e ast.Expr, lhs bool, mode operandMode, typ *Basic, val exact.Value) { - m := check.untyped - if m == nil { - m = make(map[ast.Expr]exprInfo) - check.untyped = m - } - m[e] = exprInfo{lhs, mode, typ, val} -} - -func (check *Checker) later(name string, decl *declInfo, sig *Signature, body *ast.BlockStmt) { - check.funcs = append(check.funcs, funcInfo{name, decl, sig, body}) -} - -func (check *Checker) delay(f func()) { - check.delayed = append(check.delayed, f) -} - -// NewChecker returns a new Checker instance for a given package. -// Package files may be added incrementally via checker.Files. -func NewChecker(conf *Config, fset *token.FileSet, pkg *Package, info *Info) *Checker { - // make sure we have a configuration - if conf == nil { - conf = new(Config) - } - - // make sure we have a package canonicalization map - if conf.Packages == nil { - conf.Packages = make(map[string]*Package) - } - - // make sure we have an info struct - if info == nil { - info = new(Info) - } - - return &Checker{ - conf: conf, - fset: fset, - pkg: pkg, - Info: info, - objMap: make(map[Object]*declInfo), - } -} - -// initFiles initializes the files-specific portion of checker. -// The provided files must all belong to the same package. -func (check *Checker) initFiles(files []*ast.File) { - // start with a clean slate (check.Files may be called multiple times) - check.files = nil - check.unusedDotImports = nil - - check.firstErr = nil - check.methods = nil - check.untyped = nil - check.funcs = nil - check.delayed = nil - - // determine package name and collect valid files - pkg := check.pkg - for _, file := range files { - switch name := file.Name.Name; pkg.name { - case "": - if name != "_" { - pkg.name = name - } else { - check.errorf(file.Name.Pos(), "invalid package name _") - } - fallthrough - - case name: - check.files = append(check.files, file) - - default: - check.errorf(file.Package, "package %s; expected %s", name, pkg.name) - // ignore this file - } - } -} - -// A bailout panic is used for early termination. -type bailout struct{} - -func (check *Checker) handleBailout(err *error) { - switch p := recover().(type) { - case nil, bailout: - // normal return or early exit - *err = check.firstErr - default: - // re-panic - panic(p) - } -} - -// Files checks the provided files as part of the checker's package. -func (check *Checker) Files(files []*ast.File) (err error) { - defer check.handleBailout(&err) - - check.initFiles(files) - - check.collectObjects() - - check.packageObjects(check.resolveOrder()) - - check.functionBodies() - - check.initOrder() - - if !check.conf.DisableUnusedImportCheck { - check.unusedImports() - } - - // perform delayed checks - for _, f := range check.delayed { - f() - } - - check.recordUntyped() - - check.pkg.complete = true - return -} - -func (check *Checker) recordUntyped() { - if !debug && check.Types == nil { - return // nothing to do - } - - for x, info := range check.untyped { - if debug && isTyped(info.typ) { - check.dump("%s: %s (type %s) is typed", x.Pos(), x, info.typ) - unreachable() - } - check.recordTypeAndValue(x, info.mode, info.typ, info.val) - } -} - -func (check *Checker) recordTypeAndValue(x ast.Expr, mode operandMode, typ Type, val exact.Value) { - assert(x != nil) - assert(typ != nil) - if mode == invalid { - return // omit - } - assert(typ != nil) - if mode == constant { - assert(val != nil) - assert(typ == Typ[Invalid] || isConstType(typ)) - } - if m := check.Types; m != nil { - m[x] = TypeAndValue{mode, typ, val} - } -} - -func (check *Checker) recordBuiltinType(f ast.Expr, sig *Signature) { - // f must be a (possibly parenthesized) identifier denoting a built-in - // (built-ins in package unsafe always produce a constant result and - // we don't record their signatures, so we don't see qualified idents - // here): record the signature for f and possible children. - for { - check.recordTypeAndValue(f, builtin, sig, nil) - switch p := f.(type) { - case *ast.Ident: - return // we're done - case *ast.ParenExpr: - f = p.X - default: - unreachable() - } - } -} - -func (check *Checker) recordCommaOkTypes(x ast.Expr, a [2]Type) { - assert(x != nil) - if a[0] == nil || a[1] == nil { - return - } - assert(isTyped(a[0]) && isTyped(a[1]) && isBoolean(a[1])) - if m := check.Types; m != nil { - for { - tv := m[x] - assert(tv.Type != nil) // should have been recorded already - pos := x.Pos() - tv.Type = NewTuple( - NewVar(pos, check.pkg, "", a[0]), - NewVar(pos, check.pkg, "", a[1]), - ) - m[x] = tv - // if x is a parenthesized expression (p.X), update p.X - p, _ := x.(*ast.ParenExpr) - if p == nil { - break - } - x = p.X - } - } -} - -func (check *Checker) recordDef(id *ast.Ident, obj Object) { - assert(id != nil) - if m := check.Defs; m != nil { - m[id] = obj - } -} - -func (check *Checker) recordUse(id *ast.Ident, obj Object) { - assert(id != nil) - assert(obj != nil) - if m := check.Uses; m != nil { - m[id] = obj - } -} - -func (check *Checker) recordImplicit(node ast.Node, obj Object) { - assert(node != nil) - assert(obj != nil) - if m := check.Implicits; m != nil { - m[node] = obj - } -} - -func (check *Checker) recordSelection(x *ast.SelectorExpr, kind SelectionKind, recv Type, obj Object, index []int, indirect bool) { - assert(obj != nil && (recv == nil || len(index) > 0)) - check.recordUse(x.Sel, obj) - // TODO(gri) Should we also call recordTypeAndValue? - if m := check.Selections; m != nil { - m[x] = &Selection{kind, recv, obj, index, indirect} - } -} - -func (check *Checker) recordScope(node ast.Node, scope *Scope) { - assert(node != nil) - assert(scope != nil) - if m := check.Scopes; m != nil { - m[node] = scope - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/conversions.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/conversions.go deleted file mode 100644 index 6e279ca3ee5..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/conversions.go +++ /dev/null @@ -1,146 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements typechecking of conversions. - -package types - -import "golang.org/x/tools/go/exact" - -// Conversion type-checks the conversion T(x). -// The result is in x. -func (check *Checker) conversion(x *operand, T Type) { - constArg := x.mode == constant - - var ok bool - switch { - case constArg && isConstType(T): - // constant conversion - switch t := T.Underlying().(*Basic); { - case representableConst(x.val, check.conf, t.kind, &x.val): - ok = true - case isInteger(x.typ) && isString(t): - codepoint := int64(-1) - if i, ok := exact.Int64Val(x.val); ok { - codepoint = i - } - // If codepoint < 0 the absolute value is too large (or unknown) for - // conversion. This is the same as converting any other out-of-range - // value - let string(codepoint) do the work. - x.val = exact.MakeString(string(codepoint)) - ok = true - } - case x.convertibleTo(check.conf, T): - // non-constant conversion - x.mode = value - ok = true - } - - if !ok { - check.errorf(x.pos(), "cannot convert %s to %s", x, T) - x.mode = invalid - return - } - - // The conversion argument types are final. For untyped values the - // conversion provides the type, per the spec: "A constant may be - // given a type explicitly by a constant declaration or conversion,...". - final := x.typ - if isUntyped(x.typ) { - final = T - // - For conversions to interfaces, use the argument's default type. - // - For conversions of untyped constants to non-constant types, also - // use the default type (e.g., []byte("foo") should report string - // not []byte as type for the constant "foo"). - // - Keep untyped nil for untyped nil arguments. - if IsInterface(T) || constArg && !isConstType(T) { - final = defaultType(x.typ) - } - check.updateExprType(x.expr, final, true) - } - - x.typ = T -} - -func (x *operand) convertibleTo(conf *Config, T Type) bool { - // "x is assignable to T" - if x.assignableTo(conf, T) { - return true - } - - // "x's type and T have identical underlying types" - V := x.typ - Vu := V.Underlying() - Tu := T.Underlying() - if Identical(Vu, Tu) { - return true - } - - // "x's type and T are unnamed pointer types and their pointer base types have identical underlying types" - if V, ok := V.(*Pointer); ok { - if T, ok := T.(*Pointer); ok { - if Identical(V.base.Underlying(), T.base.Underlying()) { - return true - } - } - } - - // "x's type and T are both integer or floating point types" - if (isInteger(V) || isFloat(V)) && (isInteger(T) || isFloat(T)) { - return true - } - - // "x's type and T are both complex types" - if isComplex(V) && isComplex(T) { - return true - } - - // "x is an integer or a slice of bytes or runes and T is a string type" - if (isInteger(V) || isBytesOrRunes(Vu)) && isString(T) { - return true - } - - // "x is a string and T is a slice of bytes or runes" - if isString(V) && isBytesOrRunes(Tu) { - return true - } - - // package unsafe: - // "any pointer or value of underlying type uintptr can be converted into a unsafe.Pointer" - if (isPointer(Vu) || isUintptr(Vu)) && isUnsafePointer(T) { - return true - } - // "and vice versa" - if isUnsafePointer(V) && (isPointer(Tu) || isUintptr(Tu)) { - return true - } - - return false -} - -func isUintptr(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.kind == Uintptr -} - -func isUnsafePointer(typ Type) bool { - // TODO(gri): Is this (typ.Underlying() instead of just typ) correct? - // The spec does not say so, but gc claims it is. See also - // issue 6326. - t, ok := typ.Underlying().(*Basic) - return ok && t.kind == UnsafePointer -} - -func isPointer(typ Type) bool { - _, ok := typ.Underlying().(*Pointer) - return ok -} - -func isBytesOrRunes(typ Type) bool { - if s, ok := typ.(*Slice); ok { - t, ok := s.elem.Underlying().(*Basic) - return ok && (t.kind == Byte || t.kind == Rune) - } - return false -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/decl.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/decl.go deleted file mode 100644 index 9eba85c1c3b..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/decl.go +++ /dev/null @@ -1,431 +0,0 @@ -// Copyright 2014 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -func (check *Checker) reportAltDecl(obj Object) { - if pos := obj.Pos(); pos.IsValid() { - // We use "other" rather than "previous" here because - // the first declaration seen may not be textually - // earlier in the source. - check.errorf(pos, "\tother declaration of %s", obj.Name()) // secondary error, \t indented - } -} - -func (check *Checker) declare(scope *Scope, id *ast.Ident, obj Object, pos token.Pos) { - // spec: "The blank identifier, represented by the underscore - // character _, may be used in a declaration like any other - // identifier but the declaration does not introduce a new - // binding." - if obj.Name() != "_" { - if alt := scope.Insert(obj); alt != nil { - check.errorf(obj.Pos(), "%s redeclared in this block", obj.Name()) - check.reportAltDecl(alt) - return - } - obj.setScopePos(pos) - } - if id != nil { - check.recordDef(id, obj) - } -} - -// objDecl type-checks the declaration of obj in its respective (file) context. -// See check.typ for the details on def and path. -func (check *Checker) objDecl(obj Object, def *Named, path []*TypeName) { - if obj.Type() != nil { - return // already checked - nothing to do - } - - if trace { - check.trace(obj.Pos(), "-- declaring %s", obj.Name()) - check.indent++ - defer func() { - check.indent-- - check.trace(obj.Pos(), "=> %s", obj) - }() - } - - d := check.objMap[obj] - if d == nil { - check.dump("%s: %s should have been declared", obj.Pos(), obj.Name()) - unreachable() - } - - // save/restore current context and setup object context - defer func(ctxt context) { - check.context = ctxt - }(check.context) - check.context = context{ - scope: d.file, - } - - // Const and var declarations must not have initialization - // cycles. We track them by remembering the current declaration - // in check.decl. Initialization expressions depending on other - // consts, vars, or functions, add dependencies to the current - // check.decl. - switch obj := obj.(type) { - case *Const: - check.decl = d // new package-level const decl - check.constDecl(obj, d.typ, d.init) - case *Var: - check.decl = d // new package-level var decl - check.varDecl(obj, d.lhs, d.typ, d.init) - case *TypeName: - // invalid recursive types are detected via path - check.typeDecl(obj, d.typ, def, path) - case *Func: - // functions may be recursive - no need to track dependencies - check.funcDecl(obj, d) - default: - unreachable() - } -} - -func (check *Checker) constDecl(obj *Const, typ, init ast.Expr) { - assert(obj.typ == nil) - - if obj.visited { - obj.typ = Typ[Invalid] - return - } - obj.visited = true - - // use the correct value of iota - assert(check.iota == nil) - check.iota = obj.val - defer func() { check.iota = nil }() - - // provide valid constant value under all circumstances - obj.val = exact.MakeUnknown() - - // determine type, if any - if typ != nil { - t := check.typ(typ) - if !isConstType(t) { - check.errorf(typ.Pos(), "invalid constant type %s", t) - obj.typ = Typ[Invalid] - return - } - obj.typ = t - } - - // check initialization - var x operand - if init != nil { - check.expr(&x, init) - } - check.initConst(obj, &x) -} - -func (check *Checker) varDecl(obj *Var, lhs []*Var, typ, init ast.Expr) { - assert(obj.typ == nil) - - if obj.visited { - obj.typ = Typ[Invalid] - return - } - obj.visited = true - - // var declarations cannot use iota - assert(check.iota == nil) - - // determine type, if any - if typ != nil { - obj.typ = check.typ(typ) - } - - // check initialization - if init == nil { - if typ == nil { - // error reported before by arityMatch - obj.typ = Typ[Invalid] - } - return - } - - if lhs == nil || len(lhs) == 1 { - assert(lhs == nil || lhs[0] == obj) - var x operand - check.expr(&x, init) - check.initVar(obj, &x, false) - return - } - - if debug { - // obj must be one of lhs - found := false - for _, lhs := range lhs { - if obj == lhs { - found = true - break - } - } - if !found { - panic("inconsistent lhs") - } - } - check.initVars(lhs, []ast.Expr{init}, token.NoPos) -} - -// underlying returns the underlying type of typ; possibly by following -// forward chains of named types. Such chains only exist while named types -// are incomplete. -func underlying(typ Type) Type { - for { - n, _ := typ.(*Named) - if n == nil { - break - } - typ = n.underlying - } - return typ -} - -func (n *Named) setUnderlying(typ Type) { - if n != nil { - n.underlying = typ - } -} - -func (check *Checker) typeDecl(obj *TypeName, typ ast.Expr, def *Named, path []*TypeName) { - assert(obj.typ == nil) - - // type declarations cannot use iota - assert(check.iota == nil) - - named := &Named{obj: obj} - def.setUnderlying(named) - obj.typ = named // make sure recursive type declarations terminate - - // determine underlying type of named - check.typExpr(typ, named, append(path, obj)) - - // The underlying type of named may be itself a named type that is - // incomplete: - // - // type ( - // A B - // B *C - // C A - // ) - // - // The type of C is the (named) type of A which is incomplete, - // and which has as its underlying type the named type B. - // Determine the (final, unnamed) underlying type by resolving - // any forward chain (they always end in an unnamed type). - named.underlying = underlying(named.underlying) - - // check and add associated methods - // TODO(gri) It's easy to create pathological cases where the - // current approach is incorrect: In general we need to know - // and add all methods _before_ type-checking the type. - // See http://play.golang.org/p/WMpE0q2wK8 - check.addMethodDecls(obj) -} - -func (check *Checker) addMethodDecls(obj *TypeName) { - // get associated methods - methods := check.methods[obj.name] - if len(methods) == 0 { - return // no methods - } - delete(check.methods, obj.name) - - // use an objset to check for name conflicts - var mset objset - - // spec: "If the base type is a struct type, the non-blank method - // and field names must be distinct." - base := obj.typ.(*Named) - if t, _ := base.underlying.(*Struct); t != nil { - for _, fld := range t.fields { - if fld.name != "_" { - assert(mset.insert(fld) == nil) - } - } - } - - // Checker.Files may be called multiple times; additional package files - // may add methods to already type-checked types. Add pre-existing methods - // so that we can detect redeclarations. - for _, m := range base.methods { - assert(m.name != "_") - assert(mset.insert(m) == nil) - } - - // type-check methods - for _, m := range methods { - // spec: "For a base type, the non-blank names of methods bound - // to it must be unique." - if m.name != "_" { - if alt := mset.insert(m); alt != nil { - switch alt.(type) { - case *Var: - check.errorf(m.pos, "field and method with the same name %s", m.name) - case *Func: - check.errorf(m.pos, "method %s already declared for %s", m.name, base) - default: - unreachable() - } - check.reportAltDecl(alt) - continue - } - } - check.objDecl(m, nil, nil) - // methods with blank _ names cannot be found - don't keep them - if m.name != "_" { - base.methods = append(base.methods, m) - } - } -} - -func (check *Checker) funcDecl(obj *Func, decl *declInfo) { - assert(obj.typ == nil) - - // func declarations cannot use iota - assert(check.iota == nil) - - sig := new(Signature) - obj.typ = sig // guard against cycles - fdecl := decl.fdecl - check.funcType(sig, fdecl.Recv, fdecl.Type) - if sig.recv == nil && obj.name == "init" && (sig.params.Len() > 0 || sig.results.Len() > 0) { - check.errorf(fdecl.Pos(), "func init must have no arguments and no return values") - // ok to continue - } - - // function body must be type-checked after global declarations - // (functions implemented elsewhere have no body) - if !check.conf.IgnoreFuncBodies && fdecl.Body != nil { - check.later(obj.name, decl, sig, fdecl.Body) - } -} - -func (check *Checker) declStmt(decl ast.Decl) { - pkg := check.pkg - - switch d := decl.(type) { - case *ast.BadDecl: - // ignore - - case *ast.GenDecl: - var last *ast.ValueSpec // last ValueSpec with type or init exprs seen - for iota, spec := range d.Specs { - switch s := spec.(type) { - case *ast.ValueSpec: - switch d.Tok { - case token.CONST: - // determine which init exprs to use - switch { - case s.Type != nil || len(s.Values) > 0: - last = s - case last == nil: - last = new(ast.ValueSpec) // make sure last exists - } - - // declare all constants - lhs := make([]*Const, len(s.Names)) - for i, name := range s.Names { - obj := NewConst(name.Pos(), pkg, name.Name, nil, exact.MakeInt64(int64(iota))) - lhs[i] = obj - - var init ast.Expr - if i < len(last.Values) { - init = last.Values[i] - } - - check.constDecl(obj, last.Type, init) - } - - check.arityMatch(s, last) - - // spec: "The scope of a constant or variable identifier declared - // inside a function begins at the end of the ConstSpec or VarSpec - // (ShortVarDecl for short variable declarations) and ends at the - // end of the innermost containing block." - scopePos := s.End() - for i, name := range s.Names { - check.declare(check.scope, name, lhs[i], scopePos) - } - - case token.VAR: - lhs0 := make([]*Var, len(s.Names)) - for i, name := range s.Names { - lhs0[i] = NewVar(name.Pos(), pkg, name.Name, nil) - } - - // initialize all variables - for i, obj := range lhs0 { - var lhs []*Var - var init ast.Expr - switch len(s.Values) { - case len(s.Names): - // lhs and rhs match - init = s.Values[i] - case 1: - // rhs is expected to be a multi-valued expression - lhs = lhs0 - init = s.Values[0] - default: - if i < len(s.Values) { - init = s.Values[i] - } - } - check.varDecl(obj, lhs, s.Type, init) - if len(s.Values) == 1 { - // If we have a single lhs variable we are done either way. - // If we have a single rhs expression, it must be a multi- - // valued expression, in which case handling the first lhs - // variable will cause all lhs variables to have a type - // assigned, and we are done as well. - if debug { - for _, obj := range lhs0 { - assert(obj.typ != nil) - } - } - break - } - } - - check.arityMatch(s, nil) - - // declare all variables - // (only at this point are the variable scopes (parents) set) - scopePos := s.End() // see constant declarations - for i, name := range s.Names { - // see constant declarations - check.declare(check.scope, name, lhs0[i], scopePos) - } - - default: - check.invalidAST(s.Pos(), "invalid token %s", d.Tok) - } - - case *ast.TypeSpec: - obj := NewTypeName(s.Name.Pos(), pkg, s.Name.Name, nil) - // spec: "The scope of a type identifier declared inside a function - // begins at the identifier in the TypeSpec and ends at the end of - // the innermost containing block." - scopePos := s.Name.Pos() - check.declare(check.scope, s.Name, obj, scopePos) - check.typeDecl(obj, s.Type, nil, nil) - - default: - check.invalidAST(s.Pos(), "const, type, or var declaration expected") - } - } - - default: - check.invalidAST(d.Pos(), "unknown ast.Decl node %T", d) - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/errors.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/errors.go deleted file mode 100644 index 0c0049b1f3e..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/errors.go +++ /dev/null @@ -1,103 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements various error reporters. - -package types - -import ( - "fmt" - "go/ast" - "go/token" - "strings" -) - -func assert(p bool) { - if !p { - panic("assertion failed") - } -} - -func unreachable() { - panic("unreachable") -} - -func (check *Checker) qualifier(pkg *Package) string { - if pkg != check.pkg { - return pkg.path - } - return "" -} - -func (check *Checker) sprintf(format string, args ...interface{}) string { - for i, arg := range args { - switch a := arg.(type) { - case nil: - arg = "" - case operand: - panic("internal error: should always pass *operand") - case *operand: - arg = operandString(a, check.qualifier) - case token.Pos: - arg = check.fset.Position(a).String() - case ast.Expr: - arg = ExprString(a) - case Object: - arg = ObjectString(a, check.qualifier) - case Type: - arg = TypeString(a, check.qualifier) - } - args[i] = arg - } - return fmt.Sprintf(format, args...) -} - -func (check *Checker) trace(pos token.Pos, format string, args ...interface{}) { - fmt.Printf("%s:\t%s%s\n", - check.fset.Position(pos), - strings.Repeat(". ", check.indent), - check.sprintf(format, args...), - ) -} - -// dump is only needed for debugging -func (check *Checker) dump(format string, args ...interface{}) { - fmt.Println(check.sprintf(format, args...)) -} - -func (check *Checker) err(pos token.Pos, msg string, soft bool) { - err := Error{check.fset, pos, msg, soft} - if check.firstErr == nil { - check.firstErr = err - } - f := check.conf.Error - if f == nil { - panic(bailout{}) // report only first error - } - f(err) -} - -func (check *Checker) error(pos token.Pos, msg string) { - check.err(pos, msg, false) -} - -func (check *Checker) errorf(pos token.Pos, format string, args ...interface{}) { - check.err(pos, check.sprintf(format, args...), false) -} - -func (check *Checker) softErrorf(pos token.Pos, format string, args ...interface{}) { - check.err(pos, check.sprintf(format, args...), true) -} - -func (check *Checker) invalidAST(pos token.Pos, format string, args ...interface{}) { - check.errorf(pos, "invalid AST: "+format, args...) -} - -func (check *Checker) invalidArg(pos token.Pos, format string, args ...interface{}) { - check.errorf(pos, "invalid argument: "+format, args...) -} - -func (check *Checker) invalidOp(pos token.Pos, format string, args ...interface{}) { - check.errorf(pos, "invalid operation: "+format, args...) -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/eval.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/eval.go deleted file mode 100644 index c09f2a3ba4e..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/eval.go +++ /dev/null @@ -1,87 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "fmt" - "go/parser" - "go/token" -) - -// Eval returns the type and, if constant, the value for the -// expression expr, evaluated at position pos of package pkg, -// which must have been derived from type-checking an AST with -// complete position information relative to the provided file -// set. -// -// If the expression contains function literals, their bodies -// are ignored (i.e., the bodies are not type-checked). -// -// If pkg == nil, the Universe scope is used and the provided -// position pos is ignored. If pkg != nil, and pos is invalid, -// the package scope is used. Otherwise, pos must belong to the -// package. -// -// An error is returned if pos is not within the package or -// if the node cannot be evaluated. -// -// Note: Eval should not be used instead of running Check to compute -// types and values, but in addition to Check. Eval will re-evaluate -// its argument each time, and it also does not know about the context -// in which an expression is used (e.g., an assignment). Thus, top- -// level untyped constants will return an untyped type rather then the -// respective context-specific type. -// -func Eval(fset *token.FileSet, pkg *Package, pos token.Pos, expr string) (tv TypeAndValue, err error) { - // determine scope - var scope *Scope - if pkg == nil { - scope = Universe - pos = token.NoPos - } else if !pos.IsValid() { - scope = pkg.scope - } else { - // The package scope extent (position information) may be - // incorrect (files spread accross a wide range of fset - // positions) - ignore it and just consider its children - // (file scopes). - for _, fscope := range pkg.scope.children { - if scope = fscope.Innermost(pos); scope != nil { - break - } - } - if scope == nil || debug { - s := scope - for s != nil && s != pkg.scope { - s = s.parent - } - // s == nil || s == pkg.scope - if s == nil { - return TypeAndValue{}, fmt.Errorf("no position %s found in package %s", fset.Position(pos), pkg.name) - } - } - } - - // parse expressions - // BUG(gri) In case of type-checking errors below, the type checker - // doesn't have the correct file set for expr. The correct - // solution requires a ParseExpr that uses the incoming - // file set fset. - node, err := parser.ParseExpr(expr) - if err != nil { - return TypeAndValue{}, err - } - - // initialize checker - check := NewChecker(nil, fset, pkg, nil) - check.scope = scope - check.pos = pos - defer check.handleBailout(&err) - - // evaluate node - var x operand - check.rawExpr(&x, node, nil) - return TypeAndValue{x.mode, x.typ, x.val}, err -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/expr.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/expr.go deleted file mode 100644 index 79dad12e063..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/expr.go +++ /dev/null @@ -1,1497 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements typechecking of expressions. - -package types - -import ( - "fmt" - "go/ast" - "go/token" - "math" - - "golang.org/x/tools/go/exact" -) - -/* -Basic algorithm: - -Expressions are checked recursively, top down. Expression checker functions -are generally of the form: - - func f(x *operand, e *ast.Expr, ...) - -where e is the expression to be checked, and x is the result of the check. -The check performed by f may fail in which case x.mode == invalid, and -related error messages will have been issued by f. - -If a hint argument is present, it is the composite literal element type -of an outer composite literal; it is used to type-check composite literal -elements that have no explicit type specification in the source -(e.g.: []T{{...}, {...}}, the hint is the type T in this case). - -All expressions are checked via rawExpr, which dispatches according -to expression kind. Upon returning, rawExpr is recording the types and -constant values for all expressions that have an untyped type (those types -may change on the way up in the expression tree). Usually these are constants, -but the results of comparisons or non-constant shifts of untyped constants -may also be untyped, but not constant. - -Untyped expressions may eventually become fully typed (i.e., not untyped), -typically when the value is assigned to a variable, or is used otherwise. -The updateExprType method is used to record this final type and update -the recorded types: the type-checked expression tree is again traversed down, -and the new type is propagated as needed. Untyped constant expression values -that become fully typed must now be representable by the full type (constant -sub-expression trees are left alone except for their roots). This mechanism -ensures that a client sees the actual (run-time) type an untyped value would -have. It also permits type-checking of lhs shift operands "as if the shift -were not present": when updateExprType visits an untyped lhs shift operand -and assigns it it's final type, that type must be an integer type, and a -constant lhs must be representable as an integer. - -When an expression gets its final type, either on the way out from rawExpr, -on the way down in updateExprType, or at the end of the type checker run, -the type (and constant value, if any) is recorded via Info.Types, if present. -*/ - -type opPredicates map[token.Token]func(Type) bool - -var unaryOpPredicates = opPredicates{ - token.ADD: isNumeric, - token.SUB: isNumeric, - token.XOR: isInteger, - token.NOT: isBoolean, -} - -func (check *Checker) op(m opPredicates, x *operand, op token.Token) bool { - if pred := m[op]; pred != nil { - if !pred(x.typ) { - check.invalidOp(x.pos(), "operator %s not defined for %s", op, x) - return false - } - } else { - check.invalidAST(x.pos(), "unknown operator %s", op) - return false - } - return true -} - -// The unary expression e may be nil. It's passed in for better error messages only. -func (check *Checker) unary(x *operand, e *ast.UnaryExpr, op token.Token) { - switch op { - case token.AND: - // spec: "As an exception to the addressability - // requirement x may also be a composite literal." - if _, ok := unparen(x.expr).(*ast.CompositeLit); !ok && x.mode != variable { - check.invalidOp(x.pos(), "cannot take address of %s", x) - x.mode = invalid - return - } - x.mode = value - x.typ = &Pointer{base: x.typ} - return - - case token.ARROW: - typ, ok := x.typ.Underlying().(*Chan) - if !ok { - check.invalidOp(x.pos(), "cannot receive from non-channel %s", x) - x.mode = invalid - return - } - if typ.dir == SendOnly { - check.invalidOp(x.pos(), "cannot receive from send-only channel %s", x) - x.mode = invalid - return - } - x.mode = commaok - x.typ = typ.elem - check.hasCallOrRecv = true - return - } - - if !check.op(unaryOpPredicates, x, op) { - x.mode = invalid - return - } - - if x.mode == constant { - typ := x.typ.Underlying().(*Basic) - size := -1 - if isUnsigned(typ) { - size = int(check.conf.sizeof(typ)) - } - x.val = exact.UnaryOp(op, x.val, size) - // Typed constants must be representable in - // their type after each constant operation. - if isTyped(typ) { - if e != nil { - x.expr = e // for better error message - } - check.representable(x, typ) - } - return - } - - x.mode = value - // x.typ remains unchanged -} - -func isShift(op token.Token) bool { - return op == token.SHL || op == token.SHR -} - -func isComparison(op token.Token) bool { - // Note: tokens are not ordered well to make this much easier - switch op { - case token.EQL, token.NEQ, token.LSS, token.LEQ, token.GTR, token.GEQ: - return true - } - return false -} - -func fitsFloat32(x exact.Value) bool { - f32, _ := exact.Float32Val(x) - f := float64(f32) - return !math.IsInf(f, 0) -} - -func roundFloat32(x exact.Value) exact.Value { - f32, _ := exact.Float32Val(x) - f := float64(f32) - if !math.IsInf(f, 0) { - return exact.MakeFloat64(f) - } - return nil -} - -func fitsFloat64(x exact.Value) bool { - f, _ := exact.Float64Val(x) - return !math.IsInf(f, 0) -} - -func roundFloat64(x exact.Value) exact.Value { - f, _ := exact.Float64Val(x) - if !math.IsInf(f, 0) { - return exact.MakeFloat64(f) - } - return nil -} - -// representableConst reports whether x can be represented as -// value of the given basic type kind and for the configuration -// provided (only needed for int/uint sizes). -// -// If rounded != nil, *rounded is set to the rounded value of x for -// representable floating-point values; it is left alone otherwise. -// It is ok to provide the addressof the first argument for rounded. -func representableConst(x exact.Value, conf *Config, as BasicKind, rounded *exact.Value) bool { - switch x.Kind() { - case exact.Unknown: - return true - - case exact.Bool: - return as == Bool || as == UntypedBool - - case exact.Int: - if x, ok := exact.Int64Val(x); ok { - switch as { - case Int: - var s = uint(conf.sizeof(Typ[as])) * 8 - return int64(-1)<<(s-1) <= x && x <= int64(1)<<(s-1)-1 - case Int8: - const s = 8 - return -1<<(s-1) <= x && x <= 1<<(s-1)-1 - case Int16: - const s = 16 - return -1<<(s-1) <= x && x <= 1<<(s-1)-1 - case Int32: - const s = 32 - return -1<<(s-1) <= x && x <= 1<<(s-1)-1 - case Int64: - return true - case Uint, Uintptr: - if s := uint(conf.sizeof(Typ[as])) * 8; s < 64 { - return 0 <= x && x <= int64(1)<= 0 && n <= int(s) - case Uint64: - return exact.Sign(x) >= 0 && n <= 64 - case Float32, Complex64: - if rounded == nil { - return fitsFloat32(x) - } - r := roundFloat32(x) - if r != nil { - *rounded = r - return true - } - case Float64, Complex128: - if rounded == nil { - return fitsFloat64(x) - } - r := roundFloat64(x) - if r != nil { - *rounded = r - return true - } - case UntypedInt, UntypedFloat, UntypedComplex: - return true - } - - case exact.Float: - switch as { - case Float32, Complex64: - if rounded == nil { - return fitsFloat32(x) - } - r := roundFloat32(x) - if r != nil { - *rounded = r - return true - } - case Float64, Complex128: - if rounded == nil { - return fitsFloat64(x) - } - r := roundFloat64(x) - if r != nil { - *rounded = r - return true - } - case UntypedFloat, UntypedComplex: - return true - } - - case exact.Complex: - switch as { - case Complex64: - if rounded == nil { - return fitsFloat32(exact.Real(x)) && fitsFloat32(exact.Imag(x)) - } - re := roundFloat32(exact.Real(x)) - im := roundFloat32(exact.Imag(x)) - if re != nil && im != nil { - *rounded = exact.BinaryOp(re, token.ADD, exact.MakeImag(im)) - return true - } - case Complex128: - if rounded == nil { - return fitsFloat64(exact.Real(x)) && fitsFloat64(exact.Imag(x)) - } - re := roundFloat64(exact.Real(x)) - im := roundFloat64(exact.Imag(x)) - if re != nil && im != nil { - *rounded = exact.BinaryOp(re, token.ADD, exact.MakeImag(im)) - return true - } - case UntypedComplex: - return true - } - - case exact.String: - return as == String || as == UntypedString - - default: - unreachable() - } - - return false -} - -// representable checks that a constant operand is representable in the given basic type. -func (check *Checker) representable(x *operand, typ *Basic) { - assert(x.mode == constant) - if !representableConst(x.val, check.conf, typ.kind, &x.val) { - var msg string - if isNumeric(x.typ) && isNumeric(typ) { - // numeric conversion : error msg - // - // integer -> integer : overflows - // integer -> float : overflows (actually not possible) - // float -> integer : truncated - // float -> float : overflows - // - if !isInteger(x.typ) && isInteger(typ) { - msg = "%s truncated to %s" - } else { - msg = "%s overflows %s" - } - } else { - msg = "cannot convert %s to %s" - } - check.errorf(x.pos(), msg, x, typ) - x.mode = invalid - } -} - -// updateExprType updates the type of x to typ and invokes itself -// recursively for the operands of x, depending on expression kind. -// If typ is still an untyped and not the final type, updateExprType -// only updates the recorded untyped type for x and possibly its -// operands. Otherwise (i.e., typ is not an untyped type anymore, -// or it is the final type for x), the type and value are recorded. -// Also, if x is a constant, it must be representable as a value of typ, -// and if x is the (formerly untyped) lhs operand of a non-constant -// shift, it must be an integer value. -// -func (check *Checker) updateExprType(x ast.Expr, typ Type, final bool) { - old, found := check.untyped[x] - if !found { - return // nothing to do - } - - // update operands of x if necessary - switch x := x.(type) { - case *ast.BadExpr, - *ast.FuncLit, - *ast.CompositeLit, - *ast.IndexExpr, - *ast.SliceExpr, - *ast.TypeAssertExpr, - *ast.StarExpr, - *ast.KeyValueExpr, - *ast.ArrayType, - *ast.StructType, - *ast.FuncType, - *ast.InterfaceType, - *ast.MapType, - *ast.ChanType: - // These expression are never untyped - nothing to do. - // The respective sub-expressions got their final types - // upon assignment or use. - if debug { - check.dump("%s: found old type(%s): %s (new: %s)", x.Pos(), x, old.typ, typ) - unreachable() - } - return - - case *ast.CallExpr: - // Resulting in an untyped constant (e.g., built-in complex). - // The respective calls take care of calling updateExprType - // for the arguments if necessary. - - case *ast.Ident, *ast.BasicLit, *ast.SelectorExpr: - // An identifier denoting a constant, a constant literal, - // or a qualified identifier (imported untyped constant). - // No operands to take care of. - - case *ast.ParenExpr: - check.updateExprType(x.X, typ, final) - - case *ast.UnaryExpr: - // If x is a constant, the operands were constants. - // They don't need to be updated since they never - // get "materialized" into a typed value; and they - // will be processed at the end of the type check. - if old.val != nil { - break - } - check.updateExprType(x.X, typ, final) - - case *ast.BinaryExpr: - if old.val != nil { - break // see comment for unary expressions - } - if isComparison(x.Op) { - // The result type is independent of operand types - // and the operand types must have final types. - } else if isShift(x.Op) { - // The result type depends only on lhs operand. - // The rhs type was updated when checking the shift. - check.updateExprType(x.X, typ, final) - } else { - // The operand types match the result type. - check.updateExprType(x.X, typ, final) - check.updateExprType(x.Y, typ, final) - } - - default: - unreachable() - } - - // If the new type is not final and still untyped, just - // update the recorded type. - if !final && isUntyped(typ) { - old.typ = typ.Underlying().(*Basic) - check.untyped[x] = old - return - } - - // Otherwise we have the final (typed or untyped type). - // Remove it from the map of yet untyped expressions. - delete(check.untyped, x) - - // If x is the lhs of a shift, its final type must be integer. - // We already know from the shift check that it is representable - // as an integer if it is a constant. - if old.isLhs && !isInteger(typ) { - check.invalidOp(x.Pos(), "shifted operand %s (type %s) must be integer", x, typ) - return - } - - // Everything's fine, record final type and value for x. - check.recordTypeAndValue(x, old.mode, typ, old.val) -} - -// updateExprVal updates the value of x to val. -func (check *Checker) updateExprVal(x ast.Expr, val exact.Value) { - if info, ok := check.untyped[x]; ok { - info.val = val - check.untyped[x] = info - } -} - -// convertUntyped attempts to set the type of an untyped value to the target type. -func (check *Checker) convertUntyped(x *operand, target Type) { - if x.mode == invalid || isTyped(x.typ) || target == Typ[Invalid] { - return - } - - // TODO(gri) Sloppy code - clean up. This function is central - // to assignment and expression checking. - - if isUntyped(target) { - // both x and target are untyped - xkind := x.typ.(*Basic).kind - tkind := target.(*Basic).kind - if isNumeric(x.typ) && isNumeric(target) { - if xkind < tkind { - x.typ = target - check.updateExprType(x.expr, target, false) - } - } else if xkind != tkind { - goto Error - } - return - } - - // typed target - switch t := target.Underlying().(type) { - case *Basic: - if x.mode == constant { - check.representable(x, t) - if x.mode == invalid { - return - } - // expression value may have been rounded - update if needed - // TODO(gri) A floating-point value may silently underflow to - // zero. If it was negative, the sign is lost. See issue 6898. - check.updateExprVal(x.expr, x.val) - } else { - // Non-constant untyped values may appear as the - // result of comparisons (untyped bool), intermediate - // (delayed-checked) rhs operands of shifts, and as - // the value nil. - switch x.typ.(*Basic).kind { - case UntypedBool: - if !isBoolean(target) { - goto Error - } - case UntypedInt, UntypedRune, UntypedFloat, UntypedComplex: - if !isNumeric(target) { - goto Error - } - case UntypedString: - // Non-constant untyped string values are not - // permitted by the spec and should not occur. - unreachable() - case UntypedNil: - // Unsafe.Pointer is a basic type that includes nil. - if !hasNil(target) { - goto Error - } - default: - goto Error - } - } - case *Interface: - if !x.isNil() && !t.Empty() /* empty interfaces are ok */ { - goto Error - } - // Update operand types to the default type rather then - // the target (interface) type: values must have concrete - // dynamic types. If the value is nil, keep it untyped - // (this is important for tools such as go vet which need - // the dynamic type for argument checking of say, print - // functions) - if x.isNil() { - target = Typ[UntypedNil] - } else { - // cannot assign untyped values to non-empty interfaces - if !t.Empty() { - goto Error - } - target = defaultType(x.typ) - } - case *Pointer, *Signature, *Slice, *Map, *Chan: - if !x.isNil() { - goto Error - } - // keep nil untyped - see comment for interfaces, above - target = Typ[UntypedNil] - default: - goto Error - } - - x.typ = target - check.updateExprType(x.expr, target, true) // UntypedNils are final - return - -Error: - check.errorf(x.pos(), "cannot convert %s to %s", x, target) - x.mode = invalid -} - -func (check *Checker) comparison(x, y *operand, op token.Token) { - // spec: "In any comparison, the first operand must be assignable - // to the type of the second operand, or vice versa." - err := "" - if x.assignableTo(check.conf, y.typ) || y.assignableTo(check.conf, x.typ) { - defined := false - switch op { - case token.EQL, token.NEQ: - // spec: "The equality operators == and != apply to operands that are comparable." - defined = Comparable(x.typ) || x.isNil() && hasNil(y.typ) || y.isNil() && hasNil(x.typ) - case token.LSS, token.LEQ, token.GTR, token.GEQ: - // spec: The ordering operators <, <=, >, and >= apply to operands that are ordered." - defined = isOrdered(x.typ) - default: - unreachable() - } - if !defined { - typ := x.typ - if x.isNil() { - typ = y.typ - } - err = check.sprintf("operator %s not defined for %s", op, typ) - } - } else { - err = check.sprintf("mismatched types %s and %s", x.typ, y.typ) - } - - if err != "" { - check.errorf(x.pos(), "cannot compare %s %s %s (%s)", x.expr, op, y.expr, err) - x.mode = invalid - return - } - - if x.mode == constant && y.mode == constant { - x.val = exact.MakeBool(exact.Compare(x.val, op, y.val)) - // The operands are never materialized; no need to update - // their types. - } else { - x.mode = value - // The operands have now their final types, which at run- - // time will be materialized. Update the expression trees. - // If the current types are untyped, the materialized type - // is the respective default type. - check.updateExprType(x.expr, defaultType(x.typ), true) - check.updateExprType(y.expr, defaultType(y.typ), true) - } - - // spec: "Comparison operators compare two operands and yield - // an untyped boolean value." - x.typ = Typ[UntypedBool] -} - -func (check *Checker) shift(x, y *operand, op token.Token) { - untypedx := isUntyped(x.typ) - - // The lhs must be of integer type or be representable - // as an integer; otherwise the shift has no chance. - if !x.isInteger() { - check.invalidOp(x.pos(), "shifted operand %s must be integer", x) - x.mode = invalid - return - } - - // spec: "The right operand in a shift expression must have unsigned - // integer type or be an untyped constant that can be converted to - // unsigned integer type." - switch { - case isInteger(y.typ) && isUnsigned(y.typ): - // nothing to do - case isUntyped(y.typ): - check.convertUntyped(y, Typ[UntypedInt]) - if y.mode == invalid { - x.mode = invalid - return - } - default: - check.invalidOp(y.pos(), "shift count %s must be unsigned integer", y) - x.mode = invalid - return - } - - if x.mode == constant { - if y.mode == constant { - // rhs must be an integer value - if !y.isInteger() { - check.invalidOp(y.pos(), "shift count %s must be unsigned integer", y) - x.mode = invalid - return - } - // rhs must be within reasonable bounds - const stupidShift = 1023 - 1 + 52 // so we can express smallestFloat64 - s, ok := exact.Uint64Val(y.val) - if !ok || s > stupidShift { - check.invalidOp(y.pos(), "stupid shift count %s", y) - x.mode = invalid - return - } - // The lhs is representable as an integer but may not be an integer - // (e.g., 2.0, an untyped float) - this can only happen for untyped - // non-integer numeric constants. Correct the type so that the shift - // result is of integer type. - if !isInteger(x.typ) { - x.typ = Typ[UntypedInt] - } - x.val = exact.Shift(x.val, op, uint(s)) - return - } - - // non-constant shift with constant lhs - if untypedx { - // spec: "If the left operand of a non-constant shift - // expression is an untyped constant, the type of the - // constant is what it would be if the shift expression - // were replaced by its left operand alone.". - // - // Delay operand checking until we know the final type: - // The lhs expression must be in the untyped map, mark - // the entry as lhs shift operand. - info, found := check.untyped[x.expr] - assert(found) - info.isLhs = true - check.untyped[x.expr] = info - // keep x's type - x.mode = value - return - } - } - - // constant rhs must be >= 0 - if y.mode == constant && exact.Sign(y.val) < 0 { - check.invalidOp(y.pos(), "shift count %s must not be negative", y) - } - - // non-constant shift - lhs must be an integer - if !isInteger(x.typ) { - check.invalidOp(x.pos(), "shifted operand %s must be integer", x) - x.mode = invalid - return - } - - x.mode = value -} - -var binaryOpPredicates = opPredicates{ - token.ADD: func(typ Type) bool { return isNumeric(typ) || isString(typ) }, - token.SUB: isNumeric, - token.MUL: isNumeric, - token.QUO: isNumeric, - token.REM: isInteger, - - token.AND: isInteger, - token.OR: isInteger, - token.XOR: isInteger, - token.AND_NOT: isInteger, - - token.LAND: isBoolean, - token.LOR: isBoolean, -} - -// The binary expression e may be nil. It's passed in for better error messages only. -func (check *Checker) binary(x *operand, e *ast.BinaryExpr, lhs, rhs ast.Expr, op token.Token) { - var y operand - - check.expr(x, lhs) - check.expr(&y, rhs) - - if x.mode == invalid { - return - } - if y.mode == invalid { - x.mode = invalid - x.expr = y.expr - return - } - - if isShift(op) { - check.shift(x, &y, op) - return - } - - check.convertUntyped(x, y.typ) - if x.mode == invalid { - return - } - check.convertUntyped(&y, x.typ) - if y.mode == invalid { - x.mode = invalid - return - } - - if isComparison(op) { - check.comparison(x, &y, op) - return - } - - if !Identical(x.typ, y.typ) { - // only report an error if we have valid types - // (otherwise we had an error reported elsewhere already) - if x.typ != Typ[Invalid] && y.typ != Typ[Invalid] { - check.invalidOp(x.pos(), "mismatched types %s and %s", x.typ, y.typ) - } - x.mode = invalid - return - } - - if !check.op(binaryOpPredicates, x, op) { - x.mode = invalid - return - } - - if (op == token.QUO || op == token.REM) && (x.mode == constant || isInteger(x.typ)) && y.mode == constant && exact.Sign(y.val) == 0 { - check.invalidOp(y.pos(), "division by zero") - x.mode = invalid - return - } - - if x.mode == constant && y.mode == constant { - typ := x.typ.Underlying().(*Basic) - // force integer division of integer operands - if op == token.QUO && isInteger(typ) { - op = token.QUO_ASSIGN - } - x.val = exact.BinaryOp(x.val, op, y.val) - // Typed constants must be representable in - // their type after each constant operation. - if isTyped(typ) { - if e != nil { - x.expr = e // for better error message - } - check.representable(x, typ) - } - return - } - - x.mode = value - // x.typ is unchanged -} - -// index checks an index expression for validity. -// If max >= 0, it is the upper bound for index. -// If index is valid and the result i >= 0, then i is the constant value of index. -func (check *Checker) index(index ast.Expr, max int64) (i int64, valid bool) { - var x operand - check.expr(&x, index) - if x.mode == invalid { - return - } - - // an untyped constant must be representable as Int - check.convertUntyped(&x, Typ[Int]) - if x.mode == invalid { - return - } - - // the index must be of integer type - if !isInteger(x.typ) { - check.invalidArg(x.pos(), "index %s must be integer", &x) - return - } - - // a constant index i must be in bounds - if x.mode == constant { - if exact.Sign(x.val) < 0 { - check.invalidArg(x.pos(), "index %s must not be negative", &x) - return - } - i, valid = exact.Int64Val(x.val) - if !valid || max >= 0 && i >= max { - check.errorf(x.pos(), "index %s is out of bounds", &x) - return i, false - } - // 0 <= i [ && i < max ] - return i, true - } - - return -1, true -} - -// indexElts checks the elements (elts) of an array or slice composite literal -// against the literal's element type (typ), and the element indices against -// the literal length if known (length >= 0). It returns the length of the -// literal (maximum index value + 1). -// -func (check *Checker) indexedElts(elts []ast.Expr, typ Type, length int64) int64 { - visited := make(map[int64]bool, len(elts)) - var index, max int64 - for _, e := range elts { - // determine and check index - validIndex := false - eval := e - if kv, _ := e.(*ast.KeyValueExpr); kv != nil { - if i, ok := check.index(kv.Key, length); ok { - if i >= 0 { - index = i - validIndex = true - } else { - check.errorf(e.Pos(), "index %s must be integer constant", kv.Key) - } - } - eval = kv.Value - } else if length >= 0 && index >= length { - check.errorf(e.Pos(), "index %d is out of bounds (>= %d)", index, length) - } else { - validIndex = true - } - - // if we have a valid index, check for duplicate entries - if validIndex { - if visited[index] { - check.errorf(e.Pos(), "duplicate index %d in array or slice literal", index) - } - visited[index] = true - } - index++ - if index > max { - max = index - } - - // check element against composite literal element type - var x operand - check.exprWithHint(&x, eval, typ) - if !check.assignment(&x, typ) && x.mode != invalid { - check.errorf(x.pos(), "cannot use %s as %s value in array or slice literal", &x, typ) - } - } - return max -} - -// exprKind describes the kind of an expression; the kind -// determines if an expression is valid in 'statement context'. -type exprKind int - -const ( - conversion exprKind = iota - expression - statement -) - -// rawExpr typechecks expression e and initializes x with the expression -// value or type. If an error occurred, x.mode is set to invalid. -// If hint != nil, it is the type of a composite literal element. -// -func (check *Checker) rawExpr(x *operand, e ast.Expr, hint Type) exprKind { - if trace { - check.trace(e.Pos(), "%s", e) - check.indent++ - defer func() { - check.indent-- - check.trace(e.Pos(), "=> %s", x) - }() - } - - kind := check.exprInternal(x, e, hint) - - // convert x into a user-friendly set of values - // TODO(gri) this code can be simplified - var typ Type - var val exact.Value - switch x.mode { - case invalid: - typ = Typ[Invalid] - case novalue: - typ = (*Tuple)(nil) - case constant: - typ = x.typ - val = x.val - default: - typ = x.typ - } - assert(x.expr != nil && typ != nil) - - if isUntyped(typ) { - // delay type and value recording until we know the type - // or until the end of type checking - check.rememberUntyped(x.expr, false, x.mode, typ.(*Basic), val) - } else { - check.recordTypeAndValue(e, x.mode, typ, val) - } - - return kind -} - -// exprInternal contains the core of type checking of expressions. -// Must only be called by rawExpr. -// -func (check *Checker) exprInternal(x *operand, e ast.Expr, hint Type) exprKind { - // make sure x has a valid state in case of bailout - // (was issue 5770) - x.mode = invalid - x.typ = Typ[Invalid] - - switch e := e.(type) { - case *ast.BadExpr: - goto Error // error was reported before - - case *ast.Ident: - check.ident(x, e, nil, nil) - - case *ast.Ellipsis: - // ellipses are handled explicitly where they are legal - // (array composite literals and parameter lists) - check.error(e.Pos(), "invalid use of '...'") - goto Error - - case *ast.BasicLit: - x.setConst(e.Kind, e.Value) - if x.mode == invalid { - check.invalidAST(e.Pos(), "invalid literal %v", e.Value) - goto Error - } - - case *ast.FuncLit: - if sig, ok := check.typ(e.Type).(*Signature); ok { - // Anonymous functions are considered part of the - // init expression/func declaration which contains - // them: use existing package-level declaration info. - check.funcBody(check.decl, "", sig, e.Body) - x.mode = value - x.typ = sig - } else { - check.invalidAST(e.Pos(), "invalid function literal %s", e) - goto Error - } - - case *ast.CompositeLit: - typ := hint - openArray := false - if e.Type != nil { - // [...]T array types may only appear with composite literals. - // Check for them here so we don't have to handle ... in general. - typ = nil - if atyp, _ := e.Type.(*ast.ArrayType); atyp != nil && atyp.Len != nil { - if ellip, _ := atyp.Len.(*ast.Ellipsis); ellip != nil && ellip.Elt == nil { - // We have an "open" [...]T array type. - // Create a new ArrayType with unknown length (-1) - // and finish setting it up after analyzing the literal. - typ = &Array{len: -1, elem: check.typ(atyp.Elt)} - openArray = true - } - } - if typ == nil { - typ = check.typ(e.Type) - } - } - if typ == nil { - // TODO(gri) provide better error messages depending on context - check.error(e.Pos(), "missing type in composite literal") - goto Error - } - - switch typ, _ := deref(typ); utyp := typ.Underlying().(type) { - case *Struct: - if len(e.Elts) == 0 { - break - } - fields := utyp.fields - if _, ok := e.Elts[0].(*ast.KeyValueExpr); ok { - // all elements must have keys - visited := make([]bool, len(fields)) - for _, e := range e.Elts { - kv, _ := e.(*ast.KeyValueExpr) - if kv == nil { - check.error(e.Pos(), "mixture of field:value and value elements in struct literal") - continue - } - key, _ := kv.Key.(*ast.Ident) - if key == nil { - check.errorf(kv.Pos(), "invalid field name %s in struct literal", kv.Key) - continue - } - i := fieldIndex(utyp.fields, check.pkg, key.Name) - if i < 0 { - check.errorf(kv.Pos(), "unknown field %s in struct literal", key.Name) - continue - } - fld := fields[i] - check.recordUse(key, fld) - // 0 <= i < len(fields) - if visited[i] { - check.errorf(kv.Pos(), "duplicate field name %s in struct literal", key.Name) - continue - } - visited[i] = true - check.expr(x, kv.Value) - etyp := fld.typ - if !check.assignment(x, etyp) { - if x.mode != invalid { - check.errorf(x.pos(), "cannot use %s as %s value in struct literal", x, etyp) - } - continue - } - } - } else { - // no element must have a key - for i, e := range e.Elts { - if kv, _ := e.(*ast.KeyValueExpr); kv != nil { - check.error(kv.Pos(), "mixture of field:value and value elements in struct literal") - continue - } - check.expr(x, e) - if i >= len(fields) { - check.error(x.pos(), "too many values in struct literal") - break // cannot continue - } - // i < len(fields) - fld := fields[i] - if !fld.Exported() && fld.pkg != check.pkg { - check.errorf(x.pos(), "implicit assignment to unexported field %s in %s literal", fld.name, typ) - continue - } - etyp := fld.typ - if !check.assignment(x, etyp) { - if x.mode != invalid { - check.errorf(x.pos(), "cannot use %s as %s value in struct literal", x, etyp) - } - continue - } - } - if len(e.Elts) < len(fields) { - check.error(e.Rbrace, "too few values in struct literal") - // ok to continue - } - } - - case *Array: - n := check.indexedElts(e.Elts, utyp.elem, utyp.len) - // if we have an "open" [...]T array, set the length now that we know it - if openArray { - utyp.len = n - } - - case *Slice: - check.indexedElts(e.Elts, utyp.elem, -1) - - case *Map: - visited := make(map[interface{}][]Type, len(e.Elts)) - for _, e := range e.Elts { - kv, _ := e.(*ast.KeyValueExpr) - if kv == nil { - check.error(e.Pos(), "missing key in map literal") - continue - } - check.exprWithHint(x, kv.Key, utyp.key) - if !check.assignment(x, utyp.key) { - if x.mode != invalid { - check.errorf(x.pos(), "cannot use %s as %s key in map literal", x, utyp.key) - } - continue - } - if x.mode == constant { - duplicate := false - // if the key is of interface type, the type is also significant when checking for duplicates - if _, ok := utyp.key.Underlying().(*Interface); ok { - for _, vtyp := range visited[x.val] { - if Identical(vtyp, x.typ) { - duplicate = true - break - } - } - visited[x.val] = append(visited[x.val], x.typ) - } else { - _, duplicate = visited[x.val] - visited[x.val] = nil - } - if duplicate { - check.errorf(x.pos(), "duplicate key %s in map literal", x.val) - continue - } - } - check.exprWithHint(x, kv.Value, utyp.elem) - if !check.assignment(x, utyp.elem) { - if x.mode != invalid { - check.errorf(x.pos(), "cannot use %s as %s value in map literal", x, utyp.elem) - } - continue - } - } - - default: - // if utyp is invalid, an error was reported before - if utyp != Typ[Invalid] { - check.errorf(e.Pos(), "invalid composite literal type %s", typ) - goto Error - } - } - - x.mode = value - x.typ = typ - - case *ast.ParenExpr: - kind := check.rawExpr(x, e.X, nil) - x.expr = e - return kind - - case *ast.SelectorExpr: - check.selector(x, e) - - case *ast.IndexExpr: - check.expr(x, e.X) - if x.mode == invalid { - goto Error - } - - valid := false - length := int64(-1) // valid if >= 0 - switch typ := x.typ.Underlying().(type) { - case *Basic: - if isString(typ) { - valid = true - if x.mode == constant { - length = int64(len(exact.StringVal(x.val))) - } - // an indexed string always yields a byte value - // (not a constant) even if the string and the - // index are constant - x.mode = value - x.typ = universeByte // use 'byte' name - } - - case *Array: - valid = true - length = typ.len - if x.mode != variable { - x.mode = value - } - x.typ = typ.elem - - case *Pointer: - if typ, _ := typ.base.Underlying().(*Array); typ != nil { - valid = true - length = typ.len - x.mode = variable - x.typ = typ.elem - } - - case *Slice: - valid = true - x.mode = variable - x.typ = typ.elem - - case *Map: - var key operand - check.expr(&key, e.Index) - if !check.assignment(&key, typ.key) { - if key.mode != invalid { - check.invalidOp(key.pos(), "cannot use %s as map index of type %s", &key, typ.key) - } - goto Error - } - x.mode = mapindex - x.typ = typ.elem - x.expr = e - return expression - } - - if !valid { - check.invalidOp(x.pos(), "cannot index %s", x) - goto Error - } - - if e.Index == nil { - check.invalidAST(e.Pos(), "missing index for %s", x) - goto Error - } - - check.index(e.Index, length) - // ok to continue - - case *ast.SliceExpr: - check.expr(x, e.X) - if x.mode == invalid { - goto Error - } - - valid := false - length := int64(-1) // valid if >= 0 - switch typ := x.typ.Underlying().(type) { - case *Basic: - if isString(typ) { - if e.Slice3 { - check.invalidOp(x.pos(), "3-index slice of string") - goto Error - } - valid = true - if x.mode == constant { - length = int64(len(exact.StringVal(x.val))) - } - // spec: "For untyped string operands the result - // is a non-constant value of type string." - if typ.kind == UntypedString { - x.typ = Typ[String] - } - } - - case *Array: - valid = true - length = typ.len - if x.mode != variable { - check.invalidOp(x.pos(), "cannot slice %s (value not addressable)", x) - goto Error - } - x.typ = &Slice{elem: typ.elem} - - case *Pointer: - if typ, _ := typ.base.Underlying().(*Array); typ != nil { - valid = true - length = typ.len - x.typ = &Slice{elem: typ.elem} - } - - case *Slice: - valid = true - // x.typ doesn't change - } - - if !valid { - check.invalidOp(x.pos(), "cannot slice %s", x) - goto Error - } - - x.mode = value - - // spec: "Only the first index may be omitted; it defaults to 0." - if e.Slice3 && (e.High == nil || e.Max == nil) { - check.error(e.Rbrack, "2nd and 3rd index required in 3-index slice") - goto Error - } - - // check indices - var ind [3]int64 - for i, expr := range []ast.Expr{e.Low, e.High, e.Max} { - x := int64(-1) - switch { - case expr != nil: - // The "capacity" is only known statically for strings, arrays, - // and pointers to arrays, and it is the same as the length for - // those types. - max := int64(-1) - if length >= 0 { - max = length + 1 - } - if t, ok := check.index(expr, max); ok && t >= 0 { - x = t - } - case i == 0: - // default is 0 for the first index - x = 0 - case length >= 0: - // default is length (== capacity) otherwise - x = length - } - ind[i] = x - } - - // constant indices must be in range - // (check.index already checks that existing indices >= 0) - L: - for i, x := range ind[:len(ind)-1] { - if x > 0 { - for _, y := range ind[i+1:] { - if y >= 0 && x > y { - check.errorf(e.Rbrack, "invalid slice indices: %d > %d", x, y) - break L // only report one error, ok to continue - } - } - } - } - - case *ast.TypeAssertExpr: - check.expr(x, e.X) - if x.mode == invalid { - goto Error - } - xtyp, _ := x.typ.Underlying().(*Interface) - if xtyp == nil { - check.invalidOp(x.pos(), "%s is not an interface", x) - goto Error - } - // x.(type) expressions are handled explicitly in type switches - if e.Type == nil { - check.invalidAST(e.Pos(), "use of .(type) outside type switch") - goto Error - } - T := check.typ(e.Type) - if T == Typ[Invalid] { - goto Error - } - check.typeAssertion(x.pos(), x, xtyp, T) - x.mode = commaok - x.typ = T - - case *ast.CallExpr: - return check.call(x, e) - - case *ast.StarExpr: - check.exprOrType(x, e.X) - switch x.mode { - case invalid: - goto Error - case typexpr: - x.typ = &Pointer{base: x.typ} - default: - if typ, ok := x.typ.Underlying().(*Pointer); ok { - x.mode = variable - x.typ = typ.base - } else { - check.invalidOp(x.pos(), "cannot indirect %s", x) - goto Error - } - } - - case *ast.UnaryExpr: - check.expr(x, e.X) - if x.mode == invalid { - goto Error - } - check.unary(x, e, e.Op) - if x.mode == invalid { - goto Error - } - if e.Op == token.ARROW { - x.expr = e - return statement // receive operations may appear in statement context - } - - case *ast.BinaryExpr: - check.binary(x, e, e.X, e.Y, e.Op) - if x.mode == invalid { - goto Error - } - - case *ast.KeyValueExpr: - // key:value expressions are handled in composite literals - check.invalidAST(e.Pos(), "no key:value expected") - goto Error - - case *ast.ArrayType, *ast.StructType, *ast.FuncType, - *ast.InterfaceType, *ast.MapType, *ast.ChanType: - x.mode = typexpr - x.typ = check.typ(e) - // Note: rawExpr (caller of exprInternal) will call check.recordTypeAndValue - // even though check.typ has already called it. This is fine as both - // times the same expression and type are recorded. It is also not a - // performance issue because we only reach here for composite literal - // types, which are comparatively rare. - - default: - panic(fmt.Sprintf("%s: unknown expression type %T", check.fset.Position(e.Pos()), e)) - } - - // everything went well - x.expr = e - return expression - -Error: - x.mode = invalid - x.expr = e - return statement // avoid follow-up errors -} - -// typeAssertion checks that x.(T) is legal; xtyp must be the type of x. -func (check *Checker) typeAssertion(pos token.Pos, x *operand, xtyp *Interface, T Type) { - method, wrongType := assertableTo(xtyp, T) - if method == nil { - return - } - - var msg string - if wrongType { - msg = "wrong type for method" - } else { - msg = "missing method" - } - check.errorf(pos, "%s cannot have dynamic type %s (%s %s)", x, T, msg, method.name) -} - -// expr typechecks expression e and initializes x with the expression value. -// If an error occurred, x.mode is set to invalid. -// -func (check *Checker) expr(x *operand, e ast.Expr) { - check.rawExpr(x, e, nil) - var msg string - switch x.mode { - default: - return - case novalue: - msg = "used as value" - case builtin: - msg = "must be called" - case typexpr: - msg = "is not an expression" - } - check.errorf(x.pos(), "%s %s", x, msg) - x.mode = invalid -} - -// exprWithHint typechecks expression e and initializes x with the expression value. -// If an error occurred, x.mode is set to invalid. -// If hint != nil, it is the type of a composite literal element. -// -func (check *Checker) exprWithHint(x *operand, e ast.Expr, hint Type) { - assert(hint != nil) - check.rawExpr(x, e, hint) - var msg string - switch x.mode { - default: - return - case novalue: - msg = "used as value" - case builtin: - msg = "must be called" - case typexpr: - msg = "is not an expression" - } - check.errorf(x.pos(), "%s %s", x, msg) - x.mode = invalid -} - -// exprOrType typechecks expression or type e and initializes x with the expression value or type. -// If an error occurred, x.mode is set to invalid. -// -func (check *Checker) exprOrType(x *operand, e ast.Expr) { - check.rawExpr(x, e, nil) - if x.mode == novalue { - check.errorf(x.pos(), "%s used as value or type", x) - x.mode = invalid - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/exprstring.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/exprstring.go deleted file mode 100644 index 370bdf35324..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/exprstring.go +++ /dev/null @@ -1,220 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements printing of expressions. - -package types - -import ( - "bytes" - "go/ast" -) - -// ExprString returns the (possibly simplified) string representation for x. -func ExprString(x ast.Expr) string { - var buf bytes.Buffer - WriteExpr(&buf, x) - return buf.String() -} - -// WriteExpr writes the (possibly simplified) string representation for x to buf. -func WriteExpr(buf *bytes.Buffer, x ast.Expr) { - // The AST preserves source-level parentheses so there is - // no need to introduce them here to correct for different - // operator precedences. (This assumes that the AST was - // generated by a Go parser.) - - switch x := x.(type) { - default: - buf.WriteString("(bad expr)") // nil, ast.BadExpr, ast.KeyValueExpr - - case *ast.Ident: - buf.WriteString(x.Name) - - case *ast.Ellipsis: - buf.WriteString("...") - if x.Elt != nil { - WriteExpr(buf, x.Elt) - } - - case *ast.BasicLit: - buf.WriteString(x.Value) - - case *ast.FuncLit: - buf.WriteByte('(') - WriteExpr(buf, x.Type) - buf.WriteString(" literal)") // simplified - - case *ast.CompositeLit: - buf.WriteByte('(') - WriteExpr(buf, x.Type) - buf.WriteString(" literal)") // simplified - - case *ast.ParenExpr: - buf.WriteByte('(') - WriteExpr(buf, x.X) - buf.WriteByte(')') - - case *ast.SelectorExpr: - WriteExpr(buf, x.X) - buf.WriteByte('.') - buf.WriteString(x.Sel.Name) - - case *ast.IndexExpr: - WriteExpr(buf, x.X) - buf.WriteByte('[') - WriteExpr(buf, x.Index) - buf.WriteByte(']') - - case *ast.SliceExpr: - WriteExpr(buf, x.X) - buf.WriteByte('[') - if x.Low != nil { - WriteExpr(buf, x.Low) - } - buf.WriteByte(':') - if x.High != nil { - WriteExpr(buf, x.High) - } - if x.Slice3 { - buf.WriteByte(':') - if x.Max != nil { - WriteExpr(buf, x.Max) - } - } - buf.WriteByte(']') - - case *ast.TypeAssertExpr: - WriteExpr(buf, x.X) - buf.WriteString(".(") - WriteExpr(buf, x.Type) - buf.WriteByte(')') - - case *ast.CallExpr: - WriteExpr(buf, x.Fun) - buf.WriteByte('(') - for i, arg := range x.Args { - if i > 0 { - buf.WriteString(", ") - } - WriteExpr(buf, arg) - } - if x.Ellipsis.IsValid() { - buf.WriteString("...") - } - buf.WriteByte(')') - - case *ast.StarExpr: - buf.WriteByte('*') - WriteExpr(buf, x.X) - - case *ast.UnaryExpr: - buf.WriteString(x.Op.String()) - WriteExpr(buf, x.X) - - case *ast.BinaryExpr: - WriteExpr(buf, x.X) - buf.WriteByte(' ') - buf.WriteString(x.Op.String()) - buf.WriteByte(' ') - WriteExpr(buf, x.Y) - - case *ast.ArrayType: - buf.WriteByte('[') - if x.Len != nil { - WriteExpr(buf, x.Len) - } - buf.WriteByte(']') - WriteExpr(buf, x.Elt) - - case *ast.StructType: - buf.WriteString("struct{") - writeFieldList(buf, x.Fields, "; ", false) - buf.WriteByte('}') - - case *ast.FuncType: - buf.WriteString("func") - writeSigExpr(buf, x) - - case *ast.InterfaceType: - buf.WriteString("interface{") - writeFieldList(buf, x.Methods, "; ", true) - buf.WriteByte('}') - - case *ast.MapType: - buf.WriteString("map[") - WriteExpr(buf, x.Key) - buf.WriteByte(']') - WriteExpr(buf, x.Value) - - case *ast.ChanType: - var s string - switch x.Dir { - case ast.SEND: - s = "chan<- " - case ast.RECV: - s = "<-chan " - default: - s = "chan " - } - buf.WriteString(s) - WriteExpr(buf, x.Value) - } -} - -func writeSigExpr(buf *bytes.Buffer, sig *ast.FuncType) { - buf.WriteByte('(') - writeFieldList(buf, sig.Params, ", ", false) - buf.WriteByte(')') - - res := sig.Results - n := res.NumFields() - if n == 0 { - // no result - return - } - - buf.WriteByte(' ') - if n == 1 && len(res.List[0].Names) == 0 { - // single unnamed result - WriteExpr(buf, res.List[0].Type) - return - } - - // multiple or named result(s) - buf.WriteByte('(') - writeFieldList(buf, res, ", ", false) - buf.WriteByte(')') -} - -func writeFieldList(buf *bytes.Buffer, fields *ast.FieldList, sep string, iface bool) { - for i, f := range fields.List { - if i > 0 { - buf.WriteString(sep) - } - - // field list names - for i, name := range f.Names { - if i > 0 { - buf.WriteString(", ") - } - buf.WriteString(name.Name) - } - - // types of interface methods consist of signatures only - if sig, _ := f.Type.(*ast.FuncType); sig != nil && iface { - writeSigExpr(buf, sig) - continue - } - - // named fields are separated with a blank from the field type - if len(f.Names) > 0 { - buf.WriteByte(' ') - } - - WriteExpr(buf, f.Type) - - // ignore tag - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/initorder.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/initorder.go deleted file mode 100644 index 0fd567b2691..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/initorder.go +++ /dev/null @@ -1,222 +0,0 @@ -// Copyright 2014 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "container/heap" - "fmt" -) - -// initOrder computes the Info.InitOrder for package variables. -func (check *Checker) initOrder() { - // An InitOrder may already have been computed if a package is - // built from several calls to (*Checker).Files. Clear it. - check.Info.InitOrder = check.Info.InitOrder[:0] - - // compute the object dependency graph and - // initialize a priority queue with the list - // of graph nodes - pq := nodeQueue(dependencyGraph(check.objMap)) - heap.Init(&pq) - - const debug = false - if debug { - fmt.Printf("package %s: object dependency graph\n", check.pkg.Name()) - for _, n := range pq { - for _, o := range n.out { - fmt.Printf("\t%s -> %s\n", n.obj.Name(), o.obj.Name()) - } - } - fmt.Println() - fmt.Printf("package %s: initialization order\n", check.pkg.Name()) - } - - // determine initialization order by removing the highest priority node - // (the one with the fewest dependencies) and its edges from the graph, - // repeatedly, until there are no nodes left. - // In a valid Go program, those nodes always have zero dependencies (after - // removing all incoming dependencies), otherwise there are initialization - // cycles. - mark := 0 - emitted := make(map[*declInfo]bool) - for len(pq) > 0 { - // get the next node - n := heap.Pop(&pq).(*objNode) - - // if n still depends on other nodes, we have a cycle - if n.in > 0 { - mark++ // mark nodes using a different value each time - cycle := findPath(n, n, mark) - if i := valIndex(cycle); i >= 0 { - check.reportCycle(cycle, i) - } - // ok to continue, but the variable initialization order - // will be incorrect at this point since it assumes no - // cycle errors - } - - // reduce dependency count of all dependent nodes - // and update priority queue - for _, out := range n.out { - out.in-- - heap.Fix(&pq, out.index) - } - - // record the init order for variables with initializers only - v, _ := n.obj.(*Var) - info := check.objMap[v] - if v == nil || !info.hasInitializer() { - continue - } - - // n:1 variable declarations such as: a, b = f() - // introduce a node for each lhs variable (here: a, b); - // but they all have the same initializer - emit only - // one, for the first variable seen - if emitted[info] { - continue // initializer already emitted, if any - } - emitted[info] = true - - infoLhs := info.lhs // possibly nil (see declInfo.lhs field comment) - if infoLhs == nil { - infoLhs = []*Var{v} - } - init := &Initializer{infoLhs, info.init} - check.Info.InitOrder = append(check.Info.InitOrder, init) - - if debug { - fmt.Printf("\t%s\n", init) - } - } - - if debug { - fmt.Println() - } -} - -// findPath returns the (reversed) list of nodes z, ... c, b, a, -// such that there is a path (list of edges) from a to z. -// If there is no such path, the result is nil. -// Nodes marked with the value mark are considered "visited"; -// unvisited nodes are marked during the graph search. -func findPath(a, z *objNode, mark int) []*objNode { - if a.mark == mark { - return nil // node already seen - } - a.mark = mark - - for _, n := range a.out { - if n == z { - return []*objNode{z} - } - if P := findPath(n, z, mark); P != nil { - return append(P, n) - } - } - - return nil -} - -// valIndex returns the index of the first constant or variable in a, -// if any; or a value < 0. -func valIndex(a []*objNode) int { - for i, n := range a { - switch n.obj.(type) { - case *Const, *Var: - return i - } - } - return -1 -} - -// reportCycle reports an error for the cycle starting at i. -func (check *Checker) reportCycle(cycle []*objNode, i int) { - obj := cycle[i].obj - check.errorf(obj.Pos(), "initialization cycle for %s", obj.Name()) - // print cycle - for _ = range cycle { - check.errorf(obj.Pos(), "\t%s refers to", obj.Name()) // secondary error, \t indented - i++ - if i >= len(cycle) { - i = 0 - } - obj = cycle[i].obj - } - check.errorf(obj.Pos(), "\t%s", obj.Name()) -} - -// An objNode represents a node in the object dependency graph. -// Each node b in a.out represents an edge a->b indicating that -// b depends on a. -// Nodes may be marked for cycle detection. A node n is marked -// if n.mark corresponds to the current mark value. -type objNode struct { - obj Object // object represented by this node - in int // number of nodes this node depends on - out []*objNode // list of nodes that depend on this node - index int // node index in list of nodes - mark int // for cycle detection -} - -// dependencyGraph computes the transposed object dependency graph -// from the given objMap. The transposed graph is returned as a list -// of nodes; an edge d->n indicates that node n depends on node d. -func dependencyGraph(objMap map[Object]*declInfo) []*objNode { - // M maps each object to its corresponding node - M := make(map[Object]*objNode, len(objMap)) - for obj := range objMap { - M[obj] = &objNode{obj: obj} - } - - // G is the graph of nodes n - G := make([]*objNode, len(M)) - i := 0 - for obj, n := range M { - deps := objMap[obj].deps - n.in = len(deps) - for d := range deps { - d := M[d] // node n depends on node d - d.out = append(d.out, n) // add edge d->n - } - - G[i] = n - n.index = i - i++ - } - - return G -} - -// nodeQueue implements the container/heap interface; -// a nodeQueue may be used as a priority queue. -type nodeQueue []*objNode - -func (a nodeQueue) Len() int { return len(a) } - -func (a nodeQueue) Swap(i, j int) { - x, y := a[i], a[j] - a[i], a[j] = y, x - x.index, y.index = j, i -} - -func (a nodeQueue) Less(i, j int) bool { - x, y := a[i], a[j] - // nodes are prioritized by number of incoming dependencies (1st key) - // and source order (2nd key) - return x.in < y.in || x.in == y.in && x.obj.order() < y.obj.order() -} - -func (a *nodeQueue) Push(x interface{}) { - panic("unreachable") -} - -func (a *nodeQueue) Pop() interface{} { - n := len(*a) - x := (*a)[n-1] - x.index = -1 // for safety - *a = (*a)[:n-1] - return x -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/labels.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/labels.go deleted file mode 100644 index 7364d4dbe68..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/labels.go +++ /dev/null @@ -1,268 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "go/ast" - "go/token" -) - -// labels checks correct label use in body. -func (check *Checker) labels(body *ast.BlockStmt) { - // set of all labels in this body - all := NewScope(nil, body.Pos(), body.End(), "label") - - fwdJumps := check.blockBranches(all, nil, nil, body.List) - - // If there are any forward jumps left, no label was found for - // the corresponding goto statements. Either those labels were - // never defined, or they are inside blocks and not reachable - // for the respective gotos. - for _, jmp := range fwdJumps { - var msg string - name := jmp.Label.Name - if alt := all.Lookup(name); alt != nil { - msg = "goto %s jumps into block" - alt.(*Label).used = true // avoid another error - } else { - msg = "label %s not declared" - } - check.errorf(jmp.Label.Pos(), msg, name) - } - - // spec: "It is illegal to define a label that is never used." - for _, obj := range all.elems { - if lbl := obj.(*Label); !lbl.used { - check.softErrorf(lbl.pos, "label %s declared but not used", lbl.name) - } - } -} - -// A block tracks label declarations in a block and its enclosing blocks. -type block struct { - parent *block // enclosing block - lstmt *ast.LabeledStmt // labeled statement to which this block belongs, or nil - labels map[string]*ast.LabeledStmt // allocated lazily -} - -// insert records a new label declaration for the current block. -// The label must not have been declared before in any block. -func (b *block) insert(s *ast.LabeledStmt) { - name := s.Label.Name - if debug { - assert(b.gotoTarget(name) == nil) - } - labels := b.labels - if labels == nil { - labels = make(map[string]*ast.LabeledStmt) - b.labels = labels - } - labels[name] = s -} - -// gotoTarget returns the labeled statement in the current -// or an enclosing block with the given label name, or nil. -func (b *block) gotoTarget(name string) *ast.LabeledStmt { - for s := b; s != nil; s = s.parent { - if t := s.labels[name]; t != nil { - return t - } - } - return nil -} - -// enclosingTarget returns the innermost enclosing labeled -// statement with the given label name, or nil. -func (b *block) enclosingTarget(name string) *ast.LabeledStmt { - for s := b; s != nil; s = s.parent { - if t := s.lstmt; t != nil && t.Label.Name == name { - return t - } - } - return nil -} - -// blockBranches processes a block's statement list and returns the set of outgoing forward jumps. -// all is the scope of all declared labels, parent the set of labels declared in the immediately -// enclosing block, and lstmt is the labeled statement this block is associated with (or nil). -func (check *Checker) blockBranches(all *Scope, parent *block, lstmt *ast.LabeledStmt, list []ast.Stmt) []*ast.BranchStmt { - b := &block{parent: parent, lstmt: lstmt} - - var ( - varDeclPos token.Pos - fwdJumps, badJumps []*ast.BranchStmt - ) - - // All forward jumps jumping over a variable declaration are possibly - // invalid (they may still jump out of the block and be ok). - // recordVarDecl records them for the given position. - recordVarDecl := func(pos token.Pos) { - varDeclPos = pos - badJumps = append(badJumps[:0], fwdJumps...) // copy fwdJumps to badJumps - } - - jumpsOverVarDecl := func(jmp *ast.BranchStmt) bool { - if varDeclPos.IsValid() { - for _, bad := range badJumps { - if jmp == bad { - return true - } - } - } - return false - } - - blockBranches := func(lstmt *ast.LabeledStmt, list []ast.Stmt) { - // Unresolved forward jumps inside the nested block - // become forward jumps in the current block. - fwdJumps = append(fwdJumps, check.blockBranches(all, b, lstmt, list)...) - } - - var stmtBranches func(ast.Stmt) - stmtBranches = func(s ast.Stmt) { - switch s := s.(type) { - case *ast.DeclStmt: - if d, _ := s.Decl.(*ast.GenDecl); d != nil && d.Tok == token.VAR { - recordVarDecl(d.Pos()) - } - - case *ast.LabeledStmt: - // declare non-blank label - if name := s.Label.Name; name != "_" { - lbl := NewLabel(s.Label.Pos(), check.pkg, name) - if alt := all.Insert(lbl); alt != nil { - check.softErrorf(lbl.pos, "label %s already declared", name) - check.reportAltDecl(alt) - // ok to continue - } else { - b.insert(s) - check.recordDef(s.Label, lbl) - } - // resolve matching forward jumps and remove them from fwdJumps - i := 0 - for _, jmp := range fwdJumps { - if jmp.Label.Name == name { - // match - lbl.used = true - check.recordUse(jmp.Label, lbl) - if jumpsOverVarDecl(jmp) { - check.softErrorf( - jmp.Label.Pos(), - "goto %s jumps over variable declaration at line %d", - name, - check.fset.Position(varDeclPos).Line, - ) - // ok to continue - } - } else { - // no match - record new forward jump - fwdJumps[i] = jmp - i++ - } - } - fwdJumps = fwdJumps[:i] - lstmt = s - } - stmtBranches(s.Stmt) - - case *ast.BranchStmt: - if s.Label == nil { - return // checked in 1st pass (check.stmt) - } - - // determine and validate target - name := s.Label.Name - switch s.Tok { - case token.BREAK: - // spec: "If there is a label, it must be that of an enclosing - // "for", "switch", or "select" statement, and that is the one - // whose execution terminates." - valid := false - if t := b.enclosingTarget(name); t != nil { - switch t.Stmt.(type) { - case *ast.SwitchStmt, *ast.TypeSwitchStmt, *ast.SelectStmt, *ast.ForStmt, *ast.RangeStmt: - valid = true - } - } - if !valid { - check.errorf(s.Label.Pos(), "invalid break label %s", name) - return - } - - case token.CONTINUE: - // spec: "If there is a label, it must be that of an enclosing - // "for" statement, and that is the one whose execution advances." - valid := false - if t := b.enclosingTarget(name); t != nil { - switch t.Stmt.(type) { - case *ast.ForStmt, *ast.RangeStmt: - valid = true - } - } - if !valid { - check.errorf(s.Label.Pos(), "invalid continue label %s", name) - return - } - - case token.GOTO: - if b.gotoTarget(name) == nil { - // label may be declared later - add branch to forward jumps - fwdJumps = append(fwdJumps, s) - return - } - - default: - check.invalidAST(s.Pos(), "branch statement: %s %s", s.Tok, name) - return - } - - // record label use - obj := all.Lookup(name) - obj.(*Label).used = true - check.recordUse(s.Label, obj) - - case *ast.AssignStmt: - if s.Tok == token.DEFINE { - recordVarDecl(s.Pos()) - } - - case *ast.BlockStmt: - blockBranches(lstmt, s.List) - - case *ast.IfStmt: - stmtBranches(s.Body) - if s.Else != nil { - stmtBranches(s.Else) - } - - case *ast.CaseClause: - blockBranches(nil, s.Body) - - case *ast.SwitchStmt: - stmtBranches(s.Body) - - case *ast.TypeSwitchStmt: - stmtBranches(s.Body) - - case *ast.CommClause: - blockBranches(nil, s.Body) - - case *ast.SelectStmt: - stmtBranches(s.Body) - - case *ast.ForStmt: - stmtBranches(s.Body) - - case *ast.RangeStmt: - stmtBranches(s.Body) - } - } - - for _, s := range list { - stmtBranches(s) - } - - return fwdJumps -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/lookup.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/lookup.go deleted file mode 100644 index 3caca5519b6..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/lookup.go +++ /dev/null @@ -1,341 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements various field and method lookup functions. - -package types - -// LookupFieldOrMethod looks up a field or method with given package and name -// in T and returns the corresponding *Var or *Func, an index sequence, and a -// bool indicating if there were any pointer indirections on the path to the -// field or method. If addressable is set, T is the type of an addressable -// variable (only matters for method lookups). -// -// The last index entry is the field or method index in the (possibly embedded) -// type where the entry was found, either: -// -// 1) the list of declared methods of a named type; or -// 2) the list of all methods (method set) of an interface type; or -// 3) the list of fields of a struct type. -// -// The earlier index entries are the indices of the anonymous struct fields -// traversed to get to the found entry, starting at depth 0. -// -// If no entry is found, a nil object is returned. In this case, the returned -// index and indirect values have the following meaning: -// -// - If index != nil, the index sequence points to an ambiguous entry -// (the same name appeared more than once at the same embedding level). -// -// - If indirect is set, a method with a pointer receiver type was found -// but there was no pointer on the path from the actual receiver type to -// the method's formal receiver base type, nor was the receiver addressable. -// -func LookupFieldOrMethod(T Type, addressable bool, pkg *Package, name string) (obj Object, index []int, indirect bool) { - // Methods cannot be associated to a named pointer type - // (spec: "The type denoted by T is called the receiver base type; - // it must not be a pointer or interface type and it must be declared - // in the same package as the method."). - // Thus, if we have a named pointer type, proceed with the underlying - // pointer type but discard the result if it is a method since we would - // not have found it for T (see also issue 8590). - if t, _ := T.(*Named); t != nil { - if p, _ := t.underlying.(*Pointer); p != nil { - obj, index, indirect = lookupFieldOrMethod(p, false, pkg, name) - if _, ok := obj.(*Func); ok { - return nil, nil, false - } - return - } - } - - return lookupFieldOrMethod(T, addressable, pkg, name) -} - -// TODO(gri) The named type consolidation and seen maps below must be -// indexed by unique keys for a given type. Verify that named -// types always have only one representation (even when imported -// indirectly via different packages.) - -func lookupFieldOrMethod(T Type, addressable bool, pkg *Package, name string) (obj Object, index []int, indirect bool) { - // WARNING: The code in this function is extremely subtle - do not modify casually! - // This function and NewMethodSet should be kept in sync. - - if name == "_" { - return // blank fields/methods are never found - } - - typ, isPtr := deref(T) - named, _ := typ.(*Named) - - // *typ where typ is an interface has no methods. - if isPtr { - utyp := typ - if named != nil { - utyp = named.underlying - } - if _, ok := utyp.(*Interface); ok { - return - } - } - - // Start with typ as single entry at shallowest depth. - // If typ is not a named type, insert a nil type instead. - current := []embeddedType{{named, nil, isPtr, false}} - - // named types that we have seen already, allocated lazily - var seen map[*Named]bool - - // search current depth - for len(current) > 0 { - var next []embeddedType // embedded types found at current depth - - // look for (pkg, name) in all types at current depth - for _, e := range current { - // The very first time only, e.typ may be nil. - // In this case, we don't have a named type and - // we simply continue with the underlying type. - if e.typ != nil { - if seen[e.typ] { - // We have seen this type before, at a more shallow depth - // (note that multiples of this type at the current depth - // were consolidated before). The type at that depth shadows - // this same type at the current depth, so we can ignore - // this one. - continue - } - if seen == nil { - seen = make(map[*Named]bool) - } - seen[e.typ] = true - - // look for a matching attached method - if i, m := lookupMethod(e.typ.methods, pkg, name); m != nil { - // potential match - assert(m.typ != nil) - index = concat(e.index, i) - if obj != nil || e.multiples { - return nil, index, false // collision - } - obj = m - indirect = e.indirect - continue // we can't have a matching field or interface method - } - - // continue with underlying type - typ = e.typ.underlying - } - - switch t := typ.(type) { - case *Struct: - // look for a matching field and collect embedded types - for i, f := range t.fields { - if f.sameId(pkg, name) { - assert(f.typ != nil) - index = concat(e.index, i) - if obj != nil || e.multiples { - return nil, index, false // collision - } - obj = f - indirect = e.indirect - continue // we can't have a matching interface method - } - // Collect embedded struct fields for searching the next - // lower depth, but only if we have not seen a match yet - // (if we have a match it is either the desired field or - // we have a name collision on the same depth; in either - // case we don't need to look further). - // Embedded fields are always of the form T or *T where - // T is a named type. If e.typ appeared multiple times at - // this depth, f.typ appears multiple times at the next - // depth. - if obj == nil && f.anonymous { - // Ignore embedded basic types - only user-defined - // named types can have methods or struct fields. - typ, isPtr := deref(f.typ) - if t, _ := typ.(*Named); t != nil { - next = append(next, embeddedType{t, concat(e.index, i), e.indirect || isPtr, e.multiples}) - } - } - } - - case *Interface: - // look for a matching method - // TODO(gri) t.allMethods is sorted - use binary search - if i, m := lookupMethod(t.allMethods, pkg, name); m != nil { - assert(m.typ != nil) - index = concat(e.index, i) - if obj != nil || e.multiples { - return nil, index, false // collision - } - obj = m - indirect = e.indirect - } - } - } - - if obj != nil { - // found a potential match - // spec: "A method call x.m() is valid if the method set of (the type of) x - // contains m and the argument list can be assigned to the parameter - // list of m. If x is addressable and &x's method set contains m, x.m() - // is shorthand for (&x).m()". - if f, _ := obj.(*Func); f != nil && ptrRecv(f) && !indirect && !addressable { - return nil, nil, true // pointer/addressable receiver required - } - return - } - - current = consolidateMultiples(next) - } - - return nil, nil, false // not found -} - -// embeddedType represents an embedded named type -type embeddedType struct { - typ *Named // nil means use the outer typ variable instead - index []int // embedded field indices, starting with index at depth 0 - indirect bool // if set, there was a pointer indirection on the path to this field - multiples bool // if set, typ appears multiple times at this depth -} - -// consolidateMultiples collects multiple list entries with the same type -// into a single entry marked as containing multiples. The result is the -// consolidated list. -func consolidateMultiples(list []embeddedType) []embeddedType { - if len(list) <= 1 { - return list // at most one entry - nothing to do - } - - n := 0 // number of entries w/ unique type - prev := make(map[*Named]int) // index at which type was previously seen - for _, e := range list { - if i, found := prev[e.typ]; found { - list[i].multiples = true - // ignore this entry - } else { - prev[e.typ] = n - list[n] = e - n++ - } - } - return list[:n] -} - -// MissingMethod returns (nil, false) if V implements T, otherwise it -// returns a missing method required by T and whether it is missing or -// just has the wrong type. -// -// For non-interface types V, or if static is set, V implements T if all -// methods of T are present in V. Otherwise (V is an interface and static -// is not set), MissingMethod only checks that methods of T which are also -// present in V have matching types (e.g., for a type assertion x.(T) where -// x is of interface type V). -// -func MissingMethod(V Type, T *Interface, static bool) (method *Func, wrongType bool) { - // fast path for common case - if T.Empty() { - return - } - - // TODO(gri) Consider using method sets here. Might be more efficient. - - if ityp, _ := V.Underlying().(*Interface); ityp != nil { - // TODO(gri) allMethods is sorted - can do this more efficiently - for _, m := range T.allMethods { - _, obj := lookupMethod(ityp.allMethods, m.pkg, m.name) - switch { - case obj == nil: - if static { - return m, false - } - case !Identical(obj.Type(), m.typ): - return m, true - } - } - return - } - - // A concrete type implements T if it implements all methods of T. - for _, m := range T.allMethods { - obj, _, _ := lookupFieldOrMethod(V, false, m.pkg, m.name) - - f, _ := obj.(*Func) - if f == nil { - return m, false - } - - if !Identical(f.typ, m.typ) { - return m, true - } - } - - return -} - -// assertableTo reports whether a value of type V can be asserted to have type T. -// It returns (nil, false) as affirmative answer. Otherwise it returns a missing -// method required by V and whether it is missing or just has the wrong type. -func assertableTo(V *Interface, T Type) (method *Func, wrongType bool) { - // no static check is required if T is an interface - // spec: "If T is an interface type, x.(T) asserts that the - // dynamic type of x implements the interface T." - if _, ok := T.Underlying().(*Interface); ok && !strict { - return - } - return MissingMethod(T, V, false) -} - -// deref dereferences typ if it is a *Pointer and returns its base and true. -// Otherwise it returns (typ, false). -func deref(typ Type) (Type, bool) { - if p, _ := typ.(*Pointer); p != nil { - return p.base, true - } - return typ, false -} - -// derefStructPtr dereferences typ if it is a (named or unnamed) pointer to a -// (named or unnamed) struct and returns its base. Otherwise it returns typ. -func derefStructPtr(typ Type) Type { - if p, _ := typ.Underlying().(*Pointer); p != nil { - if _, ok := p.base.Underlying().(*Struct); ok { - return p.base - } - } - return typ -} - -// concat returns the result of concatenating list and i. -// The result does not share its underlying array with list. -func concat(list []int, i int) []int { - var t []int - t = append(t, list...) - return append(t, i) -} - -// fieldIndex returns the index for the field with matching package and name, or a value < 0. -func fieldIndex(fields []*Var, pkg *Package, name string) int { - if name != "_" { - for i, f := range fields { - if f.sameId(pkg, name) { - return i - } - } - } - return -1 -} - -// lookupMethod returns the index of and method with matching package and name, or (-1, nil). -func lookupMethod(methods []*Func, pkg *Package, name string) (int, *Func) { - if name != "_" { - for i, m := range methods { - if m.sameId(pkg, name) { - return i, m - } - } - } - return -1, nil -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/methodset.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/methodset.go deleted file mode 100644 index 8aff6f9ba4f..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/methodset.go +++ /dev/null @@ -1,271 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements method sets. - -package types - -import ( - "bytes" - "fmt" - "sort" -) - -// A MethodSet is an ordered set of concrete or abstract (interface) methods; -// a method is a MethodVal selection, and they are ordered by ascending m.Obj().Id(). -// The zero value for a MethodSet is a ready-to-use empty method set. -type MethodSet struct { - list []*Selection -} - -func (s *MethodSet) String() string { - if s.Len() == 0 { - return "MethodSet {}" - } - - var buf bytes.Buffer - fmt.Fprintln(&buf, "MethodSet {") - for _, f := range s.list { - fmt.Fprintf(&buf, "\t%s\n", f) - } - fmt.Fprintln(&buf, "}") - return buf.String() -} - -// Len returns the number of methods in s. -func (s *MethodSet) Len() int { return len(s.list) } - -// At returns the i'th method in s for 0 <= i < s.Len(). -func (s *MethodSet) At(i int) *Selection { return s.list[i] } - -// Lookup returns the method with matching package and name, or nil if not found. -func (s *MethodSet) Lookup(pkg *Package, name string) *Selection { - if s.Len() == 0 { - return nil - } - - key := Id(pkg, name) - i := sort.Search(len(s.list), func(i int) bool { - m := s.list[i] - return m.obj.Id() >= key - }) - if i < len(s.list) { - m := s.list[i] - if m.obj.Id() == key { - return m - } - } - return nil -} - -// Shared empty method set. -var emptyMethodSet MethodSet - -// NewMethodSet returns the method set for the given type T. It -// always returns a non-nil method set, even if it is empty. -// -// A MethodSetCache handles repeat queries more efficiently. -// -func NewMethodSet(T Type) *MethodSet { - // WARNING: The code in this function is extremely subtle - do not modify casually! - // This function and lookupFieldOrMethod should be kept in sync. - - // method set up to the current depth, allocated lazily - var base methodSet - - typ, isPtr := deref(T) - named, _ := typ.(*Named) - - // *typ where typ is an interface has no methods. - if isPtr { - utyp := typ - if named != nil { - utyp = named.underlying - } - if _, ok := utyp.(*Interface); ok { - return &emptyMethodSet - } - } - - // Start with typ as single entry at shallowest depth. - // If typ is not a named type, insert a nil type instead. - current := []embeddedType{{named, nil, isPtr, false}} - - // named types that we have seen already, allocated lazily - var seen map[*Named]bool - - // collect methods at current depth - for len(current) > 0 { - var next []embeddedType // embedded types found at current depth - - // field and method sets at current depth, allocated lazily - var fset fieldSet - var mset methodSet - - for _, e := range current { - // The very first time only, e.typ may be nil. - // In this case, we don't have a named type and - // we simply continue with the underlying type. - if e.typ != nil { - if seen[e.typ] { - // We have seen this type before, at a more shallow depth - // (note that multiples of this type at the current depth - // were consolidated before). The type at that depth shadows - // this same type at the current depth, so we can ignore - // this one. - continue - } - if seen == nil { - seen = make(map[*Named]bool) - } - seen[e.typ] = true - - mset = mset.add(e.typ.methods, e.index, e.indirect, e.multiples) - - // continue with underlying type - typ = e.typ.underlying - } - - switch t := typ.(type) { - case *Struct: - for i, f := range t.fields { - fset = fset.add(f, e.multiples) - - // Embedded fields are always of the form T or *T where - // T is a named type. If typ appeared multiple times at - // this depth, f.Type appears multiple times at the next - // depth. - if f.anonymous { - // Ignore embedded basic types - only user-defined - // named types can have methods or struct fields. - typ, isPtr := deref(f.typ) - if t, _ := typ.(*Named); t != nil { - next = append(next, embeddedType{t, concat(e.index, i), e.indirect || isPtr, e.multiples}) - } - } - } - - case *Interface: - mset = mset.add(t.allMethods, e.index, true, e.multiples) - } - } - - // Add methods and collisions at this depth to base if no entries with matching - // names exist already. - for k, m := range mset { - if _, found := base[k]; !found { - // Fields collide with methods of the same name at this depth. - if _, found := fset[k]; found { - m = nil // collision - } - if base == nil { - base = make(methodSet) - } - base[k] = m - } - } - - // Multiple fields with matching names collide at this depth and shadow all - // entries further down; add them as collisions to base if no entries with - // matching names exist already. - for k, f := range fset { - if f == nil { - if _, found := base[k]; !found { - if base == nil { - base = make(methodSet) - } - base[k] = nil // collision - } - } - } - - current = consolidateMultiples(next) - } - - if len(base) == 0 { - return &emptyMethodSet - } - - // collect methods - var list []*Selection - for _, m := range base { - if m != nil { - m.recv = T - list = append(list, m) - } - } - sort.Sort(byUniqueName(list)) - return &MethodSet{list} -} - -// A fieldSet is a set of fields and name collisions. -// A collision indicates that multiple fields with the -// same unique id appeared. -type fieldSet map[string]*Var // a nil entry indicates a name collision - -// Add adds field f to the field set s. -// If multiples is set, f appears multiple times -// and is treated as a collision. -func (s fieldSet) add(f *Var, multiples bool) fieldSet { - if s == nil { - s = make(fieldSet) - } - key := f.Id() - // if f is not in the set, add it - if !multiples { - if _, found := s[key]; !found { - s[key] = f - return s - } - } - s[key] = nil // collision - return s -} - -// A methodSet is a set of methods and name collisions. -// A collision indicates that multiple methods with the -// same unique id appeared. -type methodSet map[string]*Selection // a nil entry indicates a name collision - -// Add adds all functions in list to the method set s. -// If multiples is set, every function in list appears multiple times -// and is treated as a collision. -func (s methodSet) add(list []*Func, index []int, indirect bool, multiples bool) methodSet { - if len(list) == 0 { - return s - } - if s == nil { - s = make(methodSet) - } - for i, f := range list { - key := f.Id() - // if f is not in the set, add it - if !multiples { - // TODO(gri) A found method may not be added because it's not in the method set - // (!indirect && ptrRecv(f)). A 2nd method on the same level may be in the method - // set and may not collide with the first one, thus leading to a false positive. - // Is that possible? Investigate. - if _, found := s[key]; !found && (indirect || !ptrRecv(f)) { - s[key] = &Selection{MethodVal, nil, f, concat(index, i), indirect} - continue - } - } - s[key] = nil // collision - } - return s -} - -// ptrRecv reports whether the receiver is of the form *T. -// The receiver must exist. -func ptrRecv(f *Func) bool { - _, isPtr := deref(f.typ.(*Signature).recv.typ) - return isPtr -} - -// byUniqueName function lists can be sorted by their unique names. -type byUniqueName []*Selection - -func (a byUniqueName) Len() int { return len(a) } -func (a byUniqueName) Less(i, j int) bool { return a[i].obj.Id() < a[j].obj.Id() } -func (a byUniqueName) Swap(i, j int) { a[i], a[j] = a[j], a[i] } diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/object.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/object.go deleted file mode 100644 index a9b6c43f5a0..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/object.go +++ /dev/null @@ -1,361 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "bytes" - "fmt" - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -// TODO(gri) Document factory, accessor methods, and fields. General clean-up. - -// An Object describes a named language entity such as a package, -// constant, type, variable, function (incl. methods), or label. -// All objects implement the Object interface. -// -type Object interface { - Parent() *Scope // scope in which this object is declared - Pos() token.Pos // position of object identifier in declaration - Pkg() *Package // nil for objects in the Universe scope and labels - Name() string // package local object name - Type() Type // object type - Exported() bool // reports whether the name starts with a capital letter - Id() string // object id (see Id below) - - // String returns a human-readable string of the object. - String() string - - // order reflects a package-level object's source order: if object - // a is before object b in the source, then a.order() < b.order(). - // order returns a value > 0 for package-level objects; it returns - // 0 for all other objects (including objects in file scopes). - order() uint32 - - // setOrder sets the order number of the object. It must be > 0. - setOrder(uint32) - - // setParent sets the parent scope of the object. - setParent(*Scope) - - // sameId reports whether obj.Id() and Id(pkg, name) are the same. - sameId(pkg *Package, name string) bool - - // scopePos returns the start position of the scope of this Object - scopePos() token.Pos - - // setScopePos sets the start position of the scope for this Object. - setScopePos(pos token.Pos) -} - -// Id returns name if it is exported, otherwise it -// returns the name qualified with the package path. -func Id(pkg *Package, name string) string { - if ast.IsExported(name) { - return name - } - // unexported names need the package path for differentiation - // (if there's no package, make sure we don't start with '.' - // as that may change the order of methods between a setup - // inside a package and outside a package - which breaks some - // tests) - path := "_" - // TODO(gri): shouldn't !ast.IsExported(name) => pkg != nil be an precondition? - // if pkg == nil { - // panic("nil package in lookup of unexported name") - // } - if pkg != nil { - path = pkg.path - if path == "" { - path = "_" - } - } - return path + "." + name -} - -// An object implements the common parts of an Object. -type object struct { - parent *Scope - pos token.Pos - pkg *Package - name string - typ Type - order_ uint32 - scopePos_ token.Pos -} - -func (obj *object) Parent() *Scope { return obj.parent } -func (obj *object) Pos() token.Pos { return obj.pos } -func (obj *object) Pkg() *Package { return obj.pkg } -func (obj *object) Name() string { return obj.name } -func (obj *object) Type() Type { return obj.typ } -func (obj *object) Exported() bool { return ast.IsExported(obj.name) } -func (obj *object) Id() string { return Id(obj.pkg, obj.name) } -func (obj *object) String() string { panic("abstract") } -func (obj *object) order() uint32 { return obj.order_ } -func (obj *object) scopePos() token.Pos { return obj.scopePos_ } - -func (obj *object) setParent(parent *Scope) { obj.parent = parent } -func (obj *object) setOrder(order uint32) { assert(order > 0); obj.order_ = order } -func (obj *object) setScopePos(pos token.Pos) { obj.scopePos_ = pos } - -func (obj *object) sameId(pkg *Package, name string) bool { - // spec: - // "Two identifiers are different if they are spelled differently, - // or if they appear in different packages and are not exported. - // Otherwise, they are the same." - if name != obj.name { - return false - } - // obj.Name == name - if obj.Exported() { - return true - } - // not exported, so packages must be the same (pkg == nil for - // fields in Universe scope; this can only happen for types - // introduced via Eval) - if pkg == nil || obj.pkg == nil { - return pkg == obj.pkg - } - // pkg != nil && obj.pkg != nil - return pkg.path == obj.pkg.path -} - -// A PkgName represents an imported Go package. -type PkgName struct { - object - imported *Package - used bool // set if the package was used -} - -func NewPkgName(pos token.Pos, pkg *Package, name string, imported *Package) *PkgName { - return &PkgName{object{nil, pos, pkg, name, Typ[Invalid], 0, token.NoPos}, imported, false} -} - -// Imported returns the package that was imported. -// It is distinct from Pkg(), which is the package containing the import statement. -func (obj *PkgName) Imported() *Package { return obj.imported } - -// A Const represents a declared constant. -type Const struct { - object - val exact.Value - visited bool // for initialization cycle detection -} - -func NewConst(pos token.Pos, pkg *Package, name string, typ Type, val exact.Value) *Const { - return &Const{object{nil, pos, pkg, name, typ, 0, token.NoPos}, val, false} -} - -func (obj *Const) Val() exact.Value { return obj.val } - -// A TypeName represents a declared type. -type TypeName struct { - object -} - -func NewTypeName(pos token.Pos, pkg *Package, name string, typ Type) *TypeName { - return &TypeName{object{nil, pos, pkg, name, typ, 0, token.NoPos}} -} - -// A Variable represents a declared variable (including function parameters and results, and struct fields). -type Var struct { - object - anonymous bool // if set, the variable is an anonymous struct field, and name is the type name - visited bool // for initialization cycle detection - isField bool // var is struct field - used bool // set if the variable was used -} - -func NewVar(pos token.Pos, pkg *Package, name string, typ Type) *Var { - return &Var{object: object{nil, pos, pkg, name, typ, 0, token.NoPos}} -} - -func NewParam(pos token.Pos, pkg *Package, name string, typ Type) *Var { - return &Var{object: object{nil, pos, pkg, name, typ, 0, token.NoPos}, used: true} // parameters are always 'used' -} - -func NewField(pos token.Pos, pkg *Package, name string, typ Type, anonymous bool) *Var { - return &Var{object: object{nil, pos, pkg, name, typ, 0, token.NoPos}, anonymous: anonymous, isField: true} -} - -func (obj *Var) Anonymous() bool { return obj.anonymous } - -func (obj *Var) IsField() bool { return obj.isField } - -// A Func represents a declared function, concrete method, or abstract -// (interface) method. Its Type() is always a *Signature. -// An abstract method may belong to many interfaces due to embedding. -type Func struct { - object -} - -func NewFunc(pos token.Pos, pkg *Package, name string, sig *Signature) *Func { - // don't store a nil signature - var typ Type - if sig != nil { - typ = sig - } - return &Func{object{nil, pos, pkg, name, typ, 0, token.NoPos}} -} - -// FullName returns the package- or receiver-type-qualified name of -// function or method obj. -func (obj *Func) FullName() string { - var buf bytes.Buffer - writeFuncName(&buf, obj, nil) - return buf.String() -} - -func (obj *Func) Scope() *Scope { - return obj.typ.(*Signature).scope -} - -// A Label represents a declared label. -type Label struct { - object - used bool // set if the label was used -} - -func NewLabel(pos token.Pos, pkg *Package, name string) *Label { - return &Label{object{pos: pos, pkg: pkg, name: name, typ: Typ[Invalid]}, false} -} - -// A Builtin represents a built-in function. -// Builtins don't have a valid type. -type Builtin struct { - object - id builtinId -} - -func newBuiltin(id builtinId) *Builtin { - return &Builtin{object{name: predeclaredFuncs[id].name, typ: Typ[Invalid]}, id} -} - -// Nil represents the predeclared value nil. -type Nil struct { - object -} - -func writeObject(buf *bytes.Buffer, obj Object, qf Qualifier) { - typ := obj.Type() - switch obj := obj.(type) { - case *PkgName: - fmt.Fprintf(buf, "package %s", obj.Name()) - if path := obj.imported.path; path != "" && path != obj.name { - fmt.Fprintf(buf, " (%q)", path) - } - return - - case *Const: - buf.WriteString("const") - - case *TypeName: - buf.WriteString("type") - typ = typ.Underlying() - - case *Var: - if obj.isField { - buf.WriteString("field") - } else { - buf.WriteString("var") - } - - case *Func: - buf.WriteString("func ") - writeFuncName(buf, obj, qf) - if typ != nil { - WriteSignature(buf, typ.(*Signature), qf) - } - return - - case *Label: - buf.WriteString("label") - typ = nil - - case *Builtin: - buf.WriteString("builtin") - typ = nil - - case *Nil: - buf.WriteString("nil") - return - - default: - panic(fmt.Sprintf("writeObject(%T)", obj)) - } - - buf.WriteByte(' ') - - // For package-level objects, qualify the name. - if obj.Pkg() != nil && obj.Pkg().scope.Lookup(obj.Name()) == obj { - writePackage(buf, obj.Pkg(), qf) - } - buf.WriteString(obj.Name()) - if typ != nil { - buf.WriteByte(' ') - WriteType(buf, typ, qf) - } -} - -func writePackage(buf *bytes.Buffer, pkg *Package, qf Qualifier) { - if pkg == nil { - return - } - var s string - if qf != nil { - s = qf(pkg) - } else { - s = pkg.Path() - } - if s != "" { - buf.WriteString(s) - buf.WriteByte('.') - } -} - -// ObjectString returns the string form of obj. -// The Qualifier controls the printing of -// package-level objects, and may be nil. -func ObjectString(obj Object, qf Qualifier) string { - var buf bytes.Buffer - writeObject(&buf, obj, qf) - return buf.String() -} - -func (obj *PkgName) String() string { return ObjectString(obj, nil) } -func (obj *Const) String() string { return ObjectString(obj, nil) } -func (obj *TypeName) String() string { return ObjectString(obj, nil) } -func (obj *Var) String() string { return ObjectString(obj, nil) } -func (obj *Func) String() string { return ObjectString(obj, nil) } -func (obj *Label) String() string { return ObjectString(obj, nil) } -func (obj *Builtin) String() string { return ObjectString(obj, nil) } -func (obj *Nil) String() string { return ObjectString(obj, nil) } - -func writeFuncName(buf *bytes.Buffer, f *Func, qf Qualifier) { - if f.typ != nil { - sig := f.typ.(*Signature) - if recv := sig.Recv(); recv != nil { - buf.WriteByte('(') - if _, ok := recv.Type().(*Interface); ok { - // gcimporter creates abstract methods of - // named interfaces using the interface type - // (not the named type) as the receiver. - // Don't print it in full. - buf.WriteString("interface") - } else { - WriteType(buf, recv.Type(), qf) - } - buf.WriteByte(')') - buf.WriteByte('.') - } else if f.pkg != nil { - writePackage(buf, f.pkg, qf) - } - } - buf.WriteString(f.name) -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/objset.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/objset.go deleted file mode 100644 index 55eb74addba..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/objset.go +++ /dev/null @@ -1,31 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements objsets. -// -// An objset is similar to a Scope but objset elements -// are identified by their unique id, instead of their -// object name. - -package types - -// An objset is a set of objects identified by their unique id. -// The zero value for objset is a ready-to-use empty objset. -type objset map[string]Object // initialized lazily - -// insert attempts to insert an object obj into objset s. -// If s already contains an alternative object alt with -// the same name, insert leaves s unchanged and returns alt. -// Otherwise it inserts obj and returns nil. -func (s *objset) insert(obj Object) Object { - id := obj.Id() - if alt := (*s)[id]; alt != nil { - return alt - } - if *s == nil { - *s = make(map[string]Object) - } - (*s)[id] = obj - return nil -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/operand.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/operand.go deleted file mode 100644 index d52b30e1618..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/operand.go +++ /dev/null @@ -1,288 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file defines operands and associated operations. - -package types - -import ( - "bytes" - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -// An operandMode specifies the (addressing) mode of an operand. -type operandMode byte - -const ( - invalid operandMode = iota // operand is invalid - novalue // operand represents no value (result of a function call w/o result) - builtin // operand is a built-in function - typexpr // operand is a type - constant // operand is a constant; the operand's typ is a Basic type - variable // operand is an addressable variable - mapindex // operand is a map index expression (acts like a variable on lhs, commaok on rhs of an assignment) - value // operand is a computed value - commaok // like value, but operand may be used in a comma,ok expression -) - -var operandModeString = [...]string{ - invalid: "invalid operand", - novalue: "no value", - builtin: "built-in", - typexpr: "type", - constant: "constant", - variable: "variable", - mapindex: "map index expression", - value: "value", - commaok: "comma, ok expression", -} - -// An operand represents an intermediate value during type checking. -// Operands have an (addressing) mode, the expression evaluating to -// the operand, the operand's type, a value for constants, and an id -// for built-in functions. -// The zero value of operand is a ready to use invalid operand. -// -type operand struct { - mode operandMode - expr ast.Expr - typ Type - val exact.Value - id builtinId -} - -// pos returns the position of the expression corresponding to x. -// If x is invalid the position is token.NoPos. -// -func (x *operand) pos() token.Pos { - // x.expr may not be set if x is invalid - if x.expr == nil { - return token.NoPos - } - return x.expr.Pos() -} - -// Operand string formats -// (not all "untyped" cases can appear due to the type system, -// but they fall out naturally here) -// -// mode format -// -// invalid ( ) -// novalue ( ) -// builtin ( ) -// typexpr ( ) -// -// constant ( ) -// constant ( of type ) -// constant ( ) -// constant ( of type ) -// -// variable ( ) -// variable ( of type ) -// -// mapindex ( ) -// mapindex ( of type ) -// -// value ( ) -// value ( of type ) -// -// commaok ( ) -// commaok ( of type ) -// -func operandString(x *operand, qf Qualifier) string { - var buf bytes.Buffer - - var expr string - if x.expr != nil { - expr = ExprString(x.expr) - } else { - switch x.mode { - case builtin: - expr = predeclaredFuncs[x.id].name - case typexpr: - expr = TypeString(x.typ, qf) - case constant: - expr = x.val.String() - } - } - - // ( - if expr != "" { - buf.WriteString(expr) - buf.WriteString(" (") - } - - // - hasType := false - switch x.mode { - case invalid, novalue, builtin, typexpr: - // no type - default: - // has type - if isUntyped(x.typ) { - buf.WriteString(x.typ.(*Basic).name) - buf.WriteByte(' ') - break - } - hasType = true - } - - // - buf.WriteString(operandModeString[x.mode]) - - // - if x.mode == constant { - if s := x.val.String(); s != expr { - buf.WriteByte(' ') - buf.WriteString(s) - } - } - - // - if hasType { - if x.typ != Typ[Invalid] { - buf.WriteString(" of type ") - WriteType(&buf, x.typ, qf) - } else { - buf.WriteString(" with invalid type") - } - } - - // ) - if expr != "" { - buf.WriteByte(')') - } - - return buf.String() -} - -func (x *operand) String() string { - return operandString(x, nil) -} - -// setConst sets x to the untyped constant for literal lit. -func (x *operand) setConst(tok token.Token, lit string) { - val := exact.MakeFromLiteral(lit, tok) - if val == nil { - // TODO(gri) Should we make it an unknown constant instead? - x.mode = invalid - return - } - - var kind BasicKind - switch tok { - case token.INT: - kind = UntypedInt - case token.FLOAT: - kind = UntypedFloat - case token.IMAG: - kind = UntypedComplex - case token.CHAR: - kind = UntypedRune - case token.STRING: - kind = UntypedString - } - - x.mode = constant - x.typ = Typ[kind] - x.val = val -} - -// isNil reports whether x is the nil value. -func (x *operand) isNil() bool { - return x.mode == value && x.typ == Typ[UntypedNil] -} - -// TODO(gri) The functions operand.assignableTo, checker.convertUntyped, -// checker.representable, and checker.assignment are -// overlapping in functionality. Need to simplify and clean up. - -// assignableTo reports whether x is assignable to a variable of type T. -func (x *operand) assignableTo(conf *Config, T Type) bool { - if x.mode == invalid || T == Typ[Invalid] { - return true // avoid spurious errors - } - - V := x.typ - - // x's type is identical to T - if Identical(V, T) { - return true - } - - Vu := V.Underlying() - Tu := T.Underlying() - - // T is an interface type and x implements T - // (Do this check first as it might succeed early.) - if Ti, ok := Tu.(*Interface); ok { - if Implements(x.typ, Ti) { - return true - } - } - - // x's type V and T have identical underlying types - // and at least one of V or T is not a named type - if Identical(Vu, Tu) && (!isNamed(V) || !isNamed(T)) { - return true - } - - // x is a bidirectional channel value, T is a channel - // type, x's type V and T have identical element types, - // and at least one of V or T is not a named type - if Vc, ok := Vu.(*Chan); ok && Vc.dir == SendRecv { - if Tc, ok := Tu.(*Chan); ok && Identical(Vc.elem, Tc.elem) { - return !isNamed(V) || !isNamed(T) - } - } - - // x is the predeclared identifier nil and T is a pointer, - // function, slice, map, channel, or interface type - if x.isNil() { - switch t := Tu.(type) { - case *Basic: - if t.kind == UnsafePointer { - return true - } - case *Pointer, *Signature, *Slice, *Map, *Chan, *Interface: - return true - } - return false - } - - // x is an untyped constant representable by a value of type T - // TODO(gri) This is borrowing from checker.convertUntyped and - // checker.representable. Need to clean up. - if isUntyped(Vu) { - switch t := Tu.(type) { - case *Basic: - if x.mode == constant { - return representableConst(x.val, conf, t.kind, nil) - } - // The result of a comparison is an untyped boolean, - // but may not be a constant. - if Vb, _ := Vu.(*Basic); Vb != nil { - return Vb.kind == UntypedBool && isBoolean(Tu) - } - case *Interface: - return x.isNil() || t.Empty() - case *Pointer, *Signature, *Slice, *Map, *Chan: - return x.isNil() - } - } - - return false -} - -// isInteger reports whether x is a value of integer type -// or an untyped constant representable as an integer. -func (x *operand) isInteger() bool { - return x.mode == invalid || - isInteger(x.typ) || - isUntyped(x.typ) && x.mode == constant && representableConst(x.val, nil, UntypedInt, nil) // no *Config required for UntypedInt -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/ordering.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/ordering.go deleted file mode 100644 index 6bb98f2dc10..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/ordering.go +++ /dev/null @@ -1,127 +0,0 @@ -// Copyright 2014 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements resolveOrder. - -package types - -import ( - "go/ast" - "sort" -) - -// resolveOrder computes the order in which package-level objects -// must be type-checked. -// -// Interface types appear first in the list, sorted topologically -// by dependencies on embedded interfaces that are also declared -// in this package, followed by all other objects sorted in source -// order. -// -// TODO(gri) Consider sorting all types by dependencies here, and -// in the process check _and_ report type cycles. This may simplify -// the full type-checking phase. -// -func (check *Checker) resolveOrder() []Object { - var ifaces, others []Object - - // collect interface types with their dependencies, and all other objects - for obj := range check.objMap { - if ityp := check.interfaceFor(obj); ityp != nil { - ifaces = append(ifaces, obj) - // determine dependencies on embedded interfaces - for _, f := range ityp.Methods.List { - if len(f.Names) == 0 { - // Embedded interface: The type must be a (possibly - // qualified) identifier denoting another interface. - // Imported interfaces are already fully resolved, - // so we can ignore qualified identifiers. - if ident, _ := f.Type.(*ast.Ident); ident != nil { - embedded := check.pkg.scope.Lookup(ident.Name) - if check.interfaceFor(embedded) != nil { - check.objMap[obj].addDep(embedded) - } - } - } - } - } else { - others = append(others, obj) - } - } - - // final object order - var order []Object - - // sort interface types topologically by dependencies, - // and in source order if there are no dependencies - sort.Sort(inSourceOrder(ifaces)) - if debug { - for _, obj := range ifaces { - assert(check.objMap[obj].mark == 0) - } - } - for _, obj := range ifaces { - check.appendInPostOrder(&order, obj) - } - - // sort everything else in source order - sort.Sort(inSourceOrder(others)) - - return append(order, others...) -} - -// interfaceFor returns the AST interface denoted by obj, or nil. -func (check *Checker) interfaceFor(obj Object) *ast.InterfaceType { - tname, _ := obj.(*TypeName) - if tname == nil { - return nil // not a type - } - d := check.objMap[obj] - if d == nil { - check.dump("%s: %s should have been declared", obj.Pos(), obj.Name()) - unreachable() - } - if d.typ == nil { - return nil // invalid AST - ignore (will be handled later) - } - ityp, _ := d.typ.(*ast.InterfaceType) - return ityp -} - -func (check *Checker) appendInPostOrder(order *[]Object, obj Object) { - d := check.objMap[obj] - if d.mark != 0 { - // We've already seen this object; either because it's - // already added to order, or because we have a cycle. - // In both cases we stop. Cycle errors are reported - // when type-checking types. - return - } - d.mark = 1 - - for _, obj := range orderedSetObjects(d.deps) { - check.appendInPostOrder(order, obj) - } - - *order = append(*order, obj) -} - -func orderedSetObjects(set map[Object]bool) []Object { - list := make([]Object, len(set)) - i := 0 - for obj := range set { - // we don't care about the map element value - list[i] = obj - i++ - } - sort.Sort(inSourceOrder(list)) - return list -} - -// inSourceOrder implements the sort.Sort interface. -type inSourceOrder []Object - -func (a inSourceOrder) Len() int { return len(a) } -func (a inSourceOrder) Less(i, j int) bool { return a[i].order() < a[j].order() } -func (a inSourceOrder) Swap(i, j int) { a[i], a[j] = a[j], a[i] } diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/package.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/package.go deleted file mode 100644 index 48fe8398fe6..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/package.go +++ /dev/null @@ -1,65 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "fmt" - "go/token" -) - -// A Package describes a Go package. -type Package struct { - path string - name string - scope *Scope - complete bool - imports []*Package - fake bool // scope lookup errors are silently dropped if package is fake (internal use only) -} - -// NewPackage returns a new Package for the given package path and name; -// the name must not be the blank identifier. -// The package is not complete and contains no explicit imports. -func NewPackage(path, name string) *Package { - if name == "_" { - panic("invalid package name _") - } - scope := NewScope(Universe, token.NoPos, token.NoPos, fmt.Sprintf("package %q", path)) - return &Package{path: path, name: name, scope: scope} -} - -// Path returns the package path. -func (pkg *Package) Path() string { return pkg.path } - -// Name returns the package name. -func (pkg *Package) Name() string { return pkg.name } - -// Scope returns the (complete or incomplete) package scope -// holding the objects declared at package level (TypeNames, -// Consts, Vars, and Funcs). -func (pkg *Package) Scope() *Scope { return pkg.scope } - -// A package is complete if its scope contains (at least) all -// exported objects; otherwise it is incomplete. -func (pkg *Package) Complete() bool { return pkg.complete } - -// MarkComplete marks a package as complete. -func (pkg *Package) MarkComplete() { pkg.complete = true } - -// Imports returns the list of packages directly imported by -// pkg; the list is in source order. Package unsafe is excluded. -// -// If pkg was loaded from export data, Imports includes packages that -// provide package-level objects referenced by pkg. This may be more or -// less than the set of packages directly imported by pkg's source code. -func (pkg *Package) Imports() []*Package { return pkg.imports } - -// SetImports sets the list of explicitly imported packages to list. -// It is the caller's responsibility to make sure list elements are unique. -func (pkg *Package) SetImports(list []*Package) { pkg.imports = list } - -func (pkg *Package) String() string { - return fmt.Sprintf("package %s (%q)", pkg.name, pkg.path) -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/predicates.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/predicates.go deleted file mode 100644 index 993c6d290b1..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/predicates.go +++ /dev/null @@ -1,309 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements commonly used type predicates. - -package types - -import "sort" - -func isNamed(typ Type) bool { - if _, ok := typ.(*Basic); ok { - return ok - } - _, ok := typ.(*Named) - return ok -} - -func isBoolean(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsBoolean != 0 -} - -func isInteger(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsInteger != 0 -} - -func isUnsigned(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsUnsigned != 0 -} - -func isFloat(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsFloat != 0 -} - -func isComplex(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsComplex != 0 -} - -func isNumeric(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsNumeric != 0 -} - -func isString(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsString != 0 -} - -func isTyped(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return !ok || t.info&IsUntyped == 0 -} - -func isUntyped(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsUntyped != 0 -} - -func isOrdered(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsOrdered != 0 -} - -func isConstType(typ Type) bool { - t, ok := typ.Underlying().(*Basic) - return ok && t.info&IsConstType != 0 -} - -// IsInterface reports whether typ is an interface type. -func IsInterface(typ Type) bool { - _, ok := typ.Underlying().(*Interface) - return ok -} - -// Comparable reports whether values of type T are comparable. -func Comparable(T Type) bool { - switch t := T.Underlying().(type) { - case *Basic: - // assume invalid types to be comparable - // to avoid follow-up errors - return t.kind != UntypedNil - case *Pointer, *Interface, *Chan: - return true - case *Struct: - for _, f := range t.fields { - if !Comparable(f.typ) { - return false - } - } - return true - case *Array: - return Comparable(t.elem) - } - return false -} - -// hasNil reports whether a type includes the nil value. -func hasNil(typ Type) bool { - switch t := typ.Underlying().(type) { - case *Basic: - return t.kind == UnsafePointer - case *Slice, *Pointer, *Signature, *Interface, *Map, *Chan: - return true - } - return false -} - -// Identical reports whether x and y are identical. -func Identical(x, y Type) bool { - return identical(x, y, nil) -} - -// An ifacePair is a node in a stack of interface type pairs compared for identity. -type ifacePair struct { - x, y *Interface - prev *ifacePair -} - -func (p *ifacePair) identical(q *ifacePair) bool { - return p.x == q.x && p.y == q.y || p.x == q.y && p.y == q.x -} - -func identical(x, y Type, p *ifacePair) bool { - if x == y { - return true - } - - switch x := x.(type) { - case *Basic: - // Basic types are singletons except for the rune and byte - // aliases, thus we cannot solely rely on the x == y check - // above. - if y, ok := y.(*Basic); ok { - return x.kind == y.kind - } - - case *Array: - // Two array types are identical if they have identical element types - // and the same array length. - if y, ok := y.(*Array); ok { - return x.len == y.len && identical(x.elem, y.elem, p) - } - - case *Slice: - // Two slice types are identical if they have identical element types. - if y, ok := y.(*Slice); ok { - return identical(x.elem, y.elem, p) - } - - case *Struct: - // Two struct types are identical if they have the same sequence of fields, - // and if corresponding fields have the same names, and identical types, - // and identical tags. Two anonymous fields are considered to have the same - // name. Lower-case field names from different packages are always different. - if y, ok := y.(*Struct); ok { - if x.NumFields() == y.NumFields() { - for i, f := range x.fields { - g := y.fields[i] - if f.anonymous != g.anonymous || - x.Tag(i) != y.Tag(i) || - !f.sameId(g.pkg, g.name) || - !identical(f.typ, g.typ, p) { - return false - } - } - return true - } - } - - case *Pointer: - // Two pointer types are identical if they have identical base types. - if y, ok := y.(*Pointer); ok { - return identical(x.base, y.base, p) - } - - case *Tuple: - // Two tuples types are identical if they have the same number of elements - // and corresponding elements have identical types. - if y, ok := y.(*Tuple); ok { - if x.Len() == y.Len() { - if x != nil { - for i, v := range x.vars { - w := y.vars[i] - if !identical(v.typ, w.typ, p) { - return false - } - } - } - return true - } - } - - case *Signature: - // Two function types are identical if they have the same number of parameters - // and result values, corresponding parameter and result types are identical, - // and either both functions are variadic or neither is. Parameter and result - // names are not required to match. - if y, ok := y.(*Signature); ok { - return x.variadic == y.variadic && - identical(x.params, y.params, p) && - identical(x.results, y.results, p) - } - - case *Interface: - // Two interface types are identical if they have the same set of methods with - // the same names and identical function types. Lower-case method names from - // different packages are always different. The order of the methods is irrelevant. - if y, ok := y.(*Interface); ok { - a := x.allMethods - b := y.allMethods - if len(a) == len(b) { - // Interface types are the only types where cycles can occur - // that are not "terminated" via named types; and such cycles - // can only be created via method parameter types that are - // anonymous interfaces (directly or indirectly) embedding - // the current interface. Example: - // - // type T interface { - // m() interface{T} - // } - // - // If two such (differently named) interfaces are compared, - // endless recursion occurs if the cycle is not detected. - // - // If x and y were compared before, they must be equal - // (if they were not, the recursion would have stopped); - // search the ifacePair stack for the same pair. - // - // This is a quadratic algorithm, but in practice these stacks - // are extremely short (bounded by the nesting depth of interface - // type declarations that recur via parameter types, an extremely - // rare occurrence). An alternative implementation might use a - // "visited" map, but that is probably less efficient overall. - q := &ifacePair{x, y, p} - for p != nil { - if p.identical(q) { - return true // same pair was compared before - } - p = p.prev - } - if debug { - assert(sort.IsSorted(byUniqueMethodName(a))) - assert(sort.IsSorted(byUniqueMethodName(b))) - } - for i, f := range a { - g := b[i] - if f.Id() != g.Id() || !identical(f.typ, g.typ, q) { - return false - } - } - return true - } - } - - case *Map: - // Two map types are identical if they have identical key and value types. - if y, ok := y.(*Map); ok { - return identical(x.key, y.key, p) && identical(x.elem, y.elem, p) - } - - case *Chan: - // Two channel types are identical if they have identical value types - // and the same direction. - if y, ok := y.(*Chan); ok { - return x.dir == y.dir && identical(x.elem, y.elem, p) - } - - case *Named: - // Two named types are identical if their type names originate - // in the same type declaration. - if y, ok := y.(*Named); ok { - return x.obj == y.obj - } - - default: - unreachable() - } - - return false -} - -// defaultType returns the default "typed" type for an "untyped" type; -// it returns the incoming type for all other types. The default type -// for untyped nil is untyped nil. -// -func defaultType(typ Type) Type { - if t, ok := typ.(*Basic); ok { - switch t.kind { - case UntypedBool: - return Typ[Bool] - case UntypedInt: - return Typ[Int] - case UntypedRune: - return universeRune // use 'rune' name - case UntypedFloat: - return Typ[Float64] - case UntypedComplex: - return Typ[Complex128] - case UntypedString: - return Typ[String] - } - } - return typ -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/resolver.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/resolver.go deleted file mode 100644 index 374ffc28005..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/resolver.go +++ /dev/null @@ -1,453 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import ( - "errors" - "fmt" - "go/ast" - "go/token" - pathLib "path" - "strconv" - "strings" - "unicode" - - "golang.org/x/tools/go/exact" -) - -// A declInfo describes a package-level const, type, var, or func declaration. -type declInfo struct { - file *Scope // scope of file containing this declaration - lhs []*Var // lhs of n:1 variable declarations, or nil - typ ast.Expr // type, or nil - init ast.Expr // init expression, or nil - fdecl *ast.FuncDecl // func declaration, or nil - - deps map[Object]bool // type and init dependencies; lazily allocated - mark int // for dependency analysis -} - -// hasInitializer reports whether the declared object has an initialization -// expression or function body. -func (d *declInfo) hasInitializer() bool { - return d.init != nil || d.fdecl != nil && d.fdecl.Body != nil -} - -// addDep adds obj as a dependency to d. -func (d *declInfo) addDep(obj Object) { - m := d.deps - if m == nil { - m = make(map[Object]bool) - d.deps = m - } - m[obj] = true -} - -// arityMatch checks that the lhs and rhs of a const or var decl -// have the appropriate number of names and init exprs. For const -// decls, init is the value spec providing the init exprs; for -// var decls, init is nil (the init exprs are in s in this case). -func (check *Checker) arityMatch(s, init *ast.ValueSpec) { - l := len(s.Names) - r := len(s.Values) - if init != nil { - r = len(init.Values) - } - - switch { - case init == nil && r == 0: - // var decl w/o init expr - if s.Type == nil { - check.errorf(s.Pos(), "missing type or init expr") - } - case l < r: - if l < len(s.Values) { - // init exprs from s - n := s.Values[l] - check.errorf(n.Pos(), "extra init expr %s", n) - // TODO(gri) avoid declared but not used error here - } else { - // init exprs "inherited" - check.errorf(s.Pos(), "extra init expr at %s", init.Pos()) - // TODO(gri) avoid declared but not used error here - } - case l > r && (init != nil || r != 1): - n := s.Names[r] - check.errorf(n.Pos(), "missing init expr for %s", n) - } -} - -func validatedImportPath(path string) (string, error) { - s, err := strconv.Unquote(path) - if err != nil { - return "", err - } - if s == "" { - return "", fmt.Errorf("empty string") - } - const illegalChars = `!"#$%&'()*,:;<=>?[\]^{|}` + "`\uFFFD" - for _, r := range s { - if !unicode.IsGraphic(r) || unicode.IsSpace(r) || strings.ContainsRune(illegalChars, r) { - return s, fmt.Errorf("invalid character %#U", r) - } - } - return s, nil -} - -// declarePkgObj declares obj in the package scope, records its ident -> obj mapping, -// and updates check.objMap. The object must not be a function or method. -func (check *Checker) declarePkgObj(ident *ast.Ident, obj Object, d *declInfo) { - assert(ident.Name == obj.Name()) - - // spec: "A package-scope or file-scope identifier with name init - // may only be declared to be a function with this (func()) signature." - if ident.Name == "init" { - check.errorf(ident.Pos(), "cannot declare init - must be func") - return - } - - check.declare(check.pkg.scope, ident, obj, token.NoPos) - check.objMap[obj] = d - obj.setOrder(uint32(len(check.objMap))) -} - -// filename returns a filename suitable for debugging output. -func (check *Checker) filename(fileNo int) string { - file := check.files[fileNo] - if pos := file.Pos(); pos.IsValid() { - return check.fset.File(pos).Name() - } - return fmt.Sprintf("file[%d]", fileNo) -} - -// collectObjects collects all file and package objects and inserts them -// into their respective scopes. It also performs imports and associates -// methods with receiver base type names. -func (check *Checker) collectObjects() { - pkg := check.pkg - - importer := check.conf.Import - if importer == nil { - if DefaultImport != nil { - importer = DefaultImport - } else { - // Panic if we encounter an import. - importer = func(map[string]*Package, string) (*Package, error) { - panic(`no Config.Import or DefaultImport (missing import _ "golang.org/x/tools/go/gcimporter"?)`) - } - } - } - - // pkgImports is the set of packages already imported by any package file seen - // so far. Used to avoid duplicate entries in pkg.imports. Allocate and populate - // it (pkg.imports may not be empty if we are checking test files incrementally). - var pkgImports = make(map[*Package]bool) - for _, imp := range pkg.imports { - pkgImports[imp] = true - } - - for fileNo, file := range check.files { - // The package identifier denotes the current package, - // but there is no corresponding package object. - check.recordDef(file.Name, nil) - - // Use the actual source file extent rather than *ast.File extent since the - // latter doesn't include comments which appear at the start or end of the file. - // Be conservative and use the *ast.File extent if we don't have a *token.File. - pos, end := file.Pos(), file.End() - if f := check.fset.File(file.Pos()); f != nil { - pos, end = token.Pos(f.Base()), token.Pos(f.Base()+f.Size()) - } - fileScope := NewScope(check.pkg.scope, pos, end, check.filename(fileNo)) - check.recordScope(file, fileScope) - - for _, decl := range file.Decls { - switch d := decl.(type) { - case *ast.BadDecl: - // ignore - - case *ast.GenDecl: - var last *ast.ValueSpec // last ValueSpec with type or init exprs seen - for iota, spec := range d.Specs { - switch s := spec.(type) { - case *ast.ImportSpec: - // import package - var imp *Package - path, err := validatedImportPath(s.Path.Value) - if err != nil { - check.errorf(s.Path.Pos(), "invalid import path (%s)", err) - continue - } - if path == "C" && check.conf.FakeImportC { - // TODO(gri) shouldn't create a new one each time - imp = NewPackage("C", "C") - imp.fake = true - } else { - var err error - imp, err = importer(check.conf.Packages, path) - if imp == nil && err == nil { - err = errors.New("Config.Import returned nil but no error") - } - if err != nil { - check.errorf(s.Path.Pos(), "could not import %s (%s)", path, err) - continue - } - } - - // add package to list of explicit imports - // (this functionality is provided as a convenience - // for clients; it is not needed for type-checking) - if !pkgImports[imp] { - pkgImports[imp] = true - if imp != Unsafe { - pkg.imports = append(pkg.imports, imp) - } - } - - // local name overrides imported package name - name := imp.name - if s.Name != nil { - name = s.Name.Name - if name == "init" { - check.errorf(s.Name.Pos(), "cannot declare init - must be func") - continue - } - } - - obj := NewPkgName(s.Pos(), pkg, name, imp) - if s.Name != nil { - // in a dot-import, the dot represents the package - check.recordDef(s.Name, obj) - } else { - check.recordImplicit(s, obj) - } - - // add import to file scope - if name == "." { - // merge imported scope with file scope - for _, obj := range imp.scope.elems { - // A package scope may contain non-exported objects, - // do not import them! - if obj.Exported() { - // TODO(gri) When we import a package, we create - // a new local package object. We should do the - // same for each dot-imported object. That way - // they can have correct position information. - // (We must not modify their existing position - // information because the same package - found - // via Config.Packages - may be dot-imported in - // another package!) - check.declare(fileScope, nil, obj, token.NoPos) - check.recordImplicit(s, obj) - } - } - // add position to set of dot-import positions for this file - // (this is only needed for "imported but not used" errors) - check.addUnusedDotImport(fileScope, imp, s.Pos()) - } else { - // declare imported package object in file scope - check.declare(fileScope, nil, obj, token.NoPos) - } - - case *ast.ValueSpec: - switch d.Tok { - case token.CONST: - // determine which initialization expressions to use - switch { - case s.Type != nil || len(s.Values) > 0: - last = s - case last == nil: - last = new(ast.ValueSpec) // make sure last exists - } - - // declare all constants - for i, name := range s.Names { - obj := NewConst(name.Pos(), pkg, name.Name, nil, exact.MakeInt64(int64(iota))) - - var init ast.Expr - if i < len(last.Values) { - init = last.Values[i] - } - - d := &declInfo{file: fileScope, typ: last.Type, init: init} - check.declarePkgObj(name, obj, d) - } - - check.arityMatch(s, last) - - case token.VAR: - lhs := make([]*Var, len(s.Names)) - // If there's exactly one rhs initializer, use - // the same declInfo d1 for all lhs variables - // so that each lhs variable depends on the same - // rhs initializer (n:1 var declaration). - var d1 *declInfo - if len(s.Values) == 1 { - // The lhs elements are only set up after the for loop below, - // but that's ok because declareVar only collects the declInfo - // for a later phase. - d1 = &declInfo{file: fileScope, lhs: lhs, typ: s.Type, init: s.Values[0]} - } - - // declare all variables - for i, name := range s.Names { - obj := NewVar(name.Pos(), pkg, name.Name, nil) - lhs[i] = obj - - d := d1 - if d == nil { - // individual assignments - var init ast.Expr - if i < len(s.Values) { - init = s.Values[i] - } - d = &declInfo{file: fileScope, typ: s.Type, init: init} - } - - check.declarePkgObj(name, obj, d) - } - - check.arityMatch(s, nil) - - default: - check.invalidAST(s.Pos(), "invalid token %s", d.Tok) - } - - case *ast.TypeSpec: - obj := NewTypeName(s.Name.Pos(), pkg, s.Name.Name, nil) - check.declarePkgObj(s.Name, obj, &declInfo{file: fileScope, typ: s.Type}) - - default: - check.invalidAST(s.Pos(), "unknown ast.Spec node %T", s) - } - } - - case *ast.FuncDecl: - name := d.Name.Name - obj := NewFunc(d.Name.Pos(), pkg, name, nil) - if d.Recv == nil { - // regular function - if name == "init" { - // don't declare init functions in the package scope - they are invisible - obj.parent = pkg.scope - check.recordDef(d.Name, obj) - // init functions must have a body - if d.Body == nil { - check.softErrorf(obj.pos, "missing function body") - } - } else { - check.declare(pkg.scope, d.Name, obj, token.NoPos) - } - } else { - // method - check.recordDef(d.Name, obj) - // Associate method with receiver base type name, if possible. - // Ignore methods that have an invalid receiver, or a blank _ - // receiver name. They will be type-checked later, with regular - // functions. - if list := d.Recv.List; len(list) > 0 { - typ := list[0].Type - if ptr, _ := typ.(*ast.StarExpr); ptr != nil { - typ = ptr.X - } - if base, _ := typ.(*ast.Ident); base != nil && base.Name != "_" { - check.assocMethod(base.Name, obj) - } - } - } - info := &declInfo{file: fileScope, fdecl: d} - check.objMap[obj] = info - obj.setOrder(uint32(len(check.objMap))) - - default: - check.invalidAST(d.Pos(), "unknown ast.Decl node %T", d) - } - } - } - - // verify that objects in package and file scopes have different names - for _, scope := range check.pkg.scope.children /* file scopes */ { - for _, obj := range scope.elems { - if alt := pkg.scope.Lookup(obj.Name()); alt != nil { - if pkg, ok := obj.(*PkgName); ok { - check.errorf(alt.Pos(), "%s already declared through import of %s", alt.Name(), pkg.Imported()) - check.reportAltDecl(pkg) - } else { - check.errorf(alt.Pos(), "%s already declared through dot-import of %s", alt.Name(), obj.Pkg()) - // TODO(gri) dot-imported objects don't have a position; reportAltDecl won't print anything - check.reportAltDecl(obj) - } - } - } - } -} - -// packageObjects typechecks all package objects in objList, but not function bodies. -func (check *Checker) packageObjects(objList []Object) { - // add new methods to already type-checked types (from a prior Checker.Files call) - for _, obj := range objList { - if obj, _ := obj.(*TypeName); obj != nil && obj.typ != nil { - check.addMethodDecls(obj) - } - } - - // pre-allocate space for type declaration paths so that the underlying array is reused - typePath := make([]*TypeName, 0, 8) - - for _, obj := range objList { - check.objDecl(obj, nil, typePath) - } - - // At this point we may have a non-empty check.methods map; this means that not all - // entries were deleted at the end of typeDecl because the respective receiver base - // types were not found. In that case, an error was reported when declaring those - // methods. We can now safely discard this map. - check.methods = nil -} - -// functionBodies typechecks all function bodies. -func (check *Checker) functionBodies() { - for _, f := range check.funcs { - check.funcBody(f.decl, f.name, f.sig, f.body) - } -} - -// unusedImports checks for unused imports. -func (check *Checker) unusedImports() { - // if function bodies are not checked, packages' uses are likely missing - don't check - if check.conf.IgnoreFuncBodies { - return - } - - // spec: "It is illegal (...) to directly import a package without referring to - // any of its exported identifiers. To import a package solely for its side-effects - // (initialization), use the blank identifier as explicit package name." - - // check use of regular imported packages - for _, scope := range check.pkg.scope.children /* file scopes */ { - for _, obj := range scope.elems { - if obj, ok := obj.(*PkgName); ok { - // Unused "blank imports" are automatically ignored - // since _ identifiers are not entered into scopes. - if !obj.used { - path := obj.imported.path - base := pathLib.Base(path) - if obj.name == base { - check.softErrorf(obj.pos, "%q imported but not used", path) - } else { - check.softErrorf(obj.pos, "%q imported but not used as %s", path, obj.name) - } - } - } - } - } - - // check use of dot-imported packages - for _, unusedDotImports := range check.unusedDotImports { - for pkg, pos := range unusedDotImports { - check.softErrorf(pos, "%q imported but not used", pkg.path) - } - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/return.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/return.go deleted file mode 100644 index 66289852147..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/return.go +++ /dev/null @@ -1,185 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements isTerminating. - -package types - -import ( - "go/ast" - "go/token" -) - -// isTerminating reports if s is a terminating statement. -// If s is labeled, label is the label name; otherwise s -// is "". -func (check *Checker) isTerminating(s ast.Stmt, label string) bool { - switch s := s.(type) { - default: - unreachable() - - case *ast.BadStmt, *ast.DeclStmt, *ast.EmptyStmt, *ast.SendStmt, - *ast.IncDecStmt, *ast.AssignStmt, *ast.GoStmt, *ast.DeferStmt, - *ast.RangeStmt: - // no chance - - case *ast.LabeledStmt: - return check.isTerminating(s.Stmt, s.Label.Name) - - case *ast.ExprStmt: - // the predeclared (possibly parenthesized) panic() function is terminating - if call, _ := unparen(s.X).(*ast.CallExpr); call != nil { - if id, _ := call.Fun.(*ast.Ident); id != nil { - if _, obj := check.scope.LookupParent(id.Name, token.NoPos); obj != nil { - if b, _ := obj.(*Builtin); b != nil && b.id == _Panic { - return true - } - } - } - } - - case *ast.ReturnStmt: - return true - - case *ast.BranchStmt: - if s.Tok == token.GOTO || s.Tok == token.FALLTHROUGH { - return true - } - - case *ast.BlockStmt: - return check.isTerminatingList(s.List, "") - - case *ast.IfStmt: - if s.Else != nil && - check.isTerminating(s.Body, "") && - check.isTerminating(s.Else, "") { - return true - } - - case *ast.SwitchStmt: - return check.isTerminatingSwitch(s.Body, label) - - case *ast.TypeSwitchStmt: - return check.isTerminatingSwitch(s.Body, label) - - case *ast.SelectStmt: - for _, s := range s.Body.List { - cc := s.(*ast.CommClause) - if !check.isTerminatingList(cc.Body, "") || hasBreakList(cc.Body, label, true) { - return false - } - - } - return true - - case *ast.ForStmt: - if s.Cond == nil && !hasBreak(s.Body, label, true) { - return true - } - } - - return false -} - -func (check *Checker) isTerminatingList(list []ast.Stmt, label string) bool { - n := len(list) - return n > 0 && check.isTerminating(list[n-1], label) -} - -func (check *Checker) isTerminatingSwitch(body *ast.BlockStmt, label string) bool { - hasDefault := false - for _, s := range body.List { - cc := s.(*ast.CaseClause) - if cc.List == nil { - hasDefault = true - } - if !check.isTerminatingList(cc.Body, "") || hasBreakList(cc.Body, label, true) { - return false - } - } - return hasDefault -} - -// TODO(gri) For nested breakable statements, the current implementation of hasBreak -// will traverse the same subtree repeatedly, once for each label. Replace -// with a single-pass label/break matching phase. - -// hasBreak reports if s is or contains a break statement -// referring to the label-ed statement or implicit-ly the -// closest outer breakable statement. -func hasBreak(s ast.Stmt, label string, implicit bool) bool { - switch s := s.(type) { - default: - unreachable() - - case *ast.BadStmt, *ast.DeclStmt, *ast.EmptyStmt, *ast.ExprStmt, - *ast.SendStmt, *ast.IncDecStmt, *ast.AssignStmt, *ast.GoStmt, - *ast.DeferStmt, *ast.ReturnStmt: - // no chance - - case *ast.LabeledStmt: - return hasBreak(s.Stmt, label, implicit) - - case *ast.BranchStmt: - if s.Tok == token.BREAK { - if s.Label == nil { - return implicit - } - if s.Label.Name == label { - return true - } - } - - case *ast.BlockStmt: - return hasBreakList(s.List, label, implicit) - - case *ast.IfStmt: - if hasBreak(s.Body, label, implicit) || - s.Else != nil && hasBreak(s.Else, label, implicit) { - return true - } - - case *ast.CaseClause: - return hasBreakList(s.Body, label, implicit) - - case *ast.SwitchStmt: - if label != "" && hasBreak(s.Body, label, false) { - return true - } - - case *ast.TypeSwitchStmt: - if label != "" && hasBreak(s.Body, label, false) { - return true - } - - case *ast.CommClause: - return hasBreakList(s.Body, label, implicit) - - case *ast.SelectStmt: - if label != "" && hasBreak(s.Body, label, false) { - return true - } - - case *ast.ForStmt: - if label != "" && hasBreak(s.Body, label, false) { - return true - } - - case *ast.RangeStmt: - if label != "" && hasBreak(s.Body, label, false) { - return true - } - } - - return false -} - -func hasBreakList(list []ast.Stmt, label string, implicit bool) bool { - for _, s := range list { - if hasBreak(s, label, implicit) { - return true - } - } - return false -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/scope.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/scope.go deleted file mode 100644 index 3502840225f..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/scope.go +++ /dev/null @@ -1,190 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements Scopes. - -package types - -import ( - "bytes" - "fmt" - "go/token" - "io" - "sort" - "strings" -) - -// TODO(gri) Provide scopes with a name or other mechanism so that -// objects can use that information for better printing. - -// A Scope maintains a set of objects and links to its containing -// (parent) and contained (children) scopes. Objects may be inserted -// and looked up by name. The zero value for Scope is a ready-to-use -// empty scope. -type Scope struct { - parent *Scope - children []*Scope - elems map[string]Object // lazily allocated - pos, end token.Pos // scope extent; may be invalid - comment string // for debugging only -} - -// NewScope returns a new, empty scope contained in the given parent -// scope, if any. The comment is for debugging only. -func NewScope(parent *Scope, pos, end token.Pos, comment string) *Scope { - s := &Scope{parent, nil, nil, pos, end, comment} - // don't add children to Universe scope! - if parent != nil && parent != Universe { - parent.children = append(parent.children, s) - } - return s -} - -// Parent returns the scope's containing (parent) scope. -func (s *Scope) Parent() *Scope { return s.parent } - -// Len() returns the number of scope elements. -func (s *Scope) Len() int { return len(s.elems) } - -// Names returns the scope's element names in sorted order. -func (s *Scope) Names() []string { - names := make([]string, len(s.elems)) - i := 0 - for name := range s.elems { - names[i] = name - i++ - } - sort.Strings(names) - return names -} - -// NumChildren() returns the number of scopes nested in s. -func (s *Scope) NumChildren() int { return len(s.children) } - -// Child returns the i'th child scope for 0 <= i < NumChildren(). -func (s *Scope) Child(i int) *Scope { return s.children[i] } - -// Lookup returns the object in scope s with the given name if such an -// object exists; otherwise the result is nil. -func (s *Scope) Lookup(name string) Object { - return s.elems[name] -} - -// LookupParent follows the parent chain of scopes starting with s until -// it finds a scope where Lookup(name) returns a non-nil object, and then -// returns that scope and object. If a valid position pos is provided, -// only objects that were declared at or before pos are considered. -// If no such scope and object exists, the result is (nil, nil). -// -// Note that obj.Parent() may be different from the returned scope if the -// object was inserted into the scope and already had a parent at that -// time (see Insert, below). This can only happen for dot-imported objects -// whose scope is the scope of the package that exported them. -func (s *Scope) LookupParent(name string, pos token.Pos) (*Scope, Object) { - for ; s != nil; s = s.parent { - if obj := s.elems[name]; obj != nil && (!pos.IsValid() || obj.scopePos() <= pos) { - return s, obj - } - } - return nil, nil -} - -// Insert attempts to insert an object obj into scope s. -// If s already contains an alternative object alt with -// the same name, Insert leaves s unchanged and returns alt. -// Otherwise it inserts obj, sets the object's parent scope -// if not already set, and returns nil. -func (s *Scope) Insert(obj Object) Object { - name := obj.Name() - if alt := s.elems[name]; alt != nil { - return alt - } - if s.elems == nil { - s.elems = make(map[string]Object) - } - s.elems[name] = obj - if obj.Parent() == nil { - obj.setParent(s) - } - return nil -} - -// Pos and End describe the scope's source code extent [pos, end). -// The results are guaranteed to be valid only if the type-checked -// AST has complete position information. The extent is undefined -// for Universe and package scopes. -func (s *Scope) Pos() token.Pos { return s.pos } -func (s *Scope) End() token.Pos { return s.end } - -// Contains returns true if pos is within the scope's extent. -// The result is guaranteed to be valid only if the type-checked -// AST has complete position information. -func (s *Scope) Contains(pos token.Pos) bool { - return s.pos <= pos && pos < s.end -} - -// Innermost returns the innermost (child) scope containing -// pos. If pos is not within any scope, the result is nil. -// The result is also nil for the Universe scope. -// The result is guaranteed to be valid only if the type-checked -// AST has complete position information. -func (s *Scope) Innermost(pos token.Pos) *Scope { - // Package scopes do not have extents since they may be - // discontiguous, so iterate over the package's files. - if s.parent == Universe { - for _, s := range s.children { - if inner := s.Innermost(pos); inner != nil { - return inner - } - } - } - - if s.Contains(pos) { - for _, s := range s.children { - if s.Contains(pos) { - return s.Innermost(pos) - } - } - return s - } - return nil -} - -// WriteTo writes a string representation of the scope to w, -// with the scope elements sorted by name. -// The level of indentation is controlled by n >= 0, with -// n == 0 for no indentation. -// If recurse is set, it also writes nested (children) scopes. -func (s *Scope) WriteTo(w io.Writer, n int, recurse bool) { - const ind = ". " - indn := strings.Repeat(ind, n) - - fmt.Fprintf(w, "%s%s scope %p {", indn, s.comment, s) - if len(s.elems) == 0 { - fmt.Fprintf(w, "}\n") - return - } - - fmt.Fprintln(w) - indn1 := indn + ind - for _, name := range s.Names() { - fmt.Fprintf(w, "%s%s\n", indn1, s.elems[name]) - } - - if recurse { - for _, s := range s.children { - fmt.Fprintln(w) - s.WriteTo(w, n+1, recurse) - } - } - - fmt.Fprintf(w, "%s}", indn) -} - -// String returns a string representation of the scope, for debugging. -func (s *Scope) String() string { - var buf bytes.Buffer - s.WriteTo(&buf, 0, false) - return buf.String() -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/selection.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/selection.go deleted file mode 100644 index 124e0d39f02..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/selection.go +++ /dev/null @@ -1,143 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements Selections. - -package types - -import ( - "bytes" - "fmt" -) - -// SelectionKind describes the kind of a selector expression x.f -// (excluding qualified identifiers). -type SelectionKind int - -const ( - FieldVal SelectionKind = iota // x.f is a struct field selector - MethodVal // x.f is a method selector - MethodExpr // x.f is a method expression -) - -// A Selection describes a selector expression x.f. -// For the declarations: -// -// type T struct{ x int; E } -// type E struct{} -// func (e E) m() {} -// var p *T -// -// the following relations exist: -// -// Selector Kind Recv Obj Type Index Indirect -// -// p.x FieldVal T x int {0} true -// p.m MethodVal *T m func (e *T) m() {1, 0} true -// T.m MethodExpr T m func m(_ T) {1, 0} false -// -type Selection struct { - kind SelectionKind - recv Type // type of x - obj Object // object denoted by x.f - index []int // path from x to x.f - indirect bool // set if there was any pointer indirection on the path -} - -// Kind returns the selection kind. -func (s *Selection) Kind() SelectionKind { return s.kind } - -// Recv returns the type of x in x.f. -func (s *Selection) Recv() Type { return s.recv } - -// Obj returns the object denoted by x.f; a *Var for -// a field selection, and a *Func in all other cases. -func (s *Selection) Obj() Object { return s.obj } - -// Type returns the type of x.f, which may be different from the type of f. -// See Selection for more information. -func (s *Selection) Type() Type { - switch s.kind { - case MethodVal: - // The type of x.f is a method with its receiver type set - // to the type of x. - sig := *s.obj.(*Func).typ.(*Signature) - recv := *sig.recv - recv.typ = s.recv - sig.recv = &recv - return &sig - - case MethodExpr: - // The type of x.f is a function (without receiver) - // and an additional first argument with the same type as x. - // TODO(gri) Similar code is already in call.go - factor! - // TODO(gri) Compute this eagerly to avoid allocations. - sig := *s.obj.(*Func).typ.(*Signature) - arg0 := *sig.recv - sig.recv = nil - arg0.typ = s.recv - var params []*Var - if sig.params != nil { - params = sig.params.vars - } - sig.params = NewTuple(append([]*Var{&arg0}, params...)...) - return &sig - } - - // In all other cases, the type of x.f is the type of x. - return s.obj.Type() -} - -// Index describes the path from x to f in x.f. -// The last index entry is the field or method index of the type declaring f; -// either: -// -// 1) the list of declared methods of a named type; or -// 2) the list of methods of an interface type; or -// 3) the list of fields of a struct type. -// -// The earlier index entries are the indices of the embedded fields implicitly -// traversed to get from (the type of) x to f, starting at embedding depth 0. -func (s *Selection) Index() []int { return s.index } - -// Indirect reports whether any pointer indirection was required to get from -// x to f in x.f. -func (s *Selection) Indirect() bool { return s.indirect } - -func (s *Selection) String() string { return SelectionString(s, nil) } - -// SelectionString returns the string form of s. -// The Qualifier controls the printing of -// package-level objects, and may be nil. -// -// Examples: -// "field (T) f int" -// "method (T) f(X) Y" -// "method expr (T) f(X) Y" -// -func SelectionString(s *Selection, qf Qualifier) string { - var k string - switch s.kind { - case FieldVal: - k = "field " - case MethodVal: - k = "method " - case MethodExpr: - k = "method expr " - default: - unreachable() - } - var buf bytes.Buffer - buf.WriteString(k) - buf.WriteByte('(') - WriteType(&buf, s.Recv(), qf) - fmt.Fprintf(&buf, ") %s", s.obj.Name()) - if T := s.Type(); s.kind == FieldVal { - buf.WriteByte(' ') - WriteType(&buf, T, qf) - } else { - WriteSignature(&buf, T.(*Signature), qf) - } - return buf.String() -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/sizes.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/sizes.go deleted file mode 100644 index 56fb310c294..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/sizes.go +++ /dev/null @@ -1,211 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements Sizes. - -package types - -// Sizes defines the sizing functions for package unsafe. -type Sizes interface { - // Alignof returns the alignment of a variable of type T. - // Alignof must implement the alignment guarantees required by the spec. - Alignof(T Type) int64 - - // Offsetsof returns the offsets of the given struct fields, in bytes. - // Offsetsof must implement the offset guarantees required by the spec. - Offsetsof(fields []*Var) []int64 - - // Sizeof returns the size of a variable of type T. - // Sizeof must implement the size guarantees required by the spec. - Sizeof(T Type) int64 -} - -// StdSizes is a convenience type for creating commonly used Sizes. -// It makes the following simplifying assumptions: -// -// - The size of explicitly sized basic types (int16, etc.) is the -// specified size. -// - The size of strings and interfaces is 2*WordSize. -// - The size of slices is 3*WordSize. -// - The size of an array of n elements corresponds to the size of -// a struct of n consecutive fields of the array's element type. -// - The size of a struct is the offset of the last field plus that -// field's size. As with all element types, if the struct is used -// in an array its size must first be aligned to a multiple of the -// struct's alignment. -// - All other types have size WordSize. -// - Arrays and structs are aligned per spec definition; all other -// types are naturally aligned with a maximum alignment MaxAlign. -// -// *StdSizes implements Sizes. -// -type StdSizes struct { - WordSize int64 // word size in bytes - must be >= 4 (32bits) - MaxAlign int64 // maximum alignment in bytes - must be >= 1 -} - -func (s *StdSizes) Alignof(T Type) int64 { - // For arrays and structs, alignment is defined in terms - // of alignment of the elements and fields, respectively. - switch t := T.Underlying().(type) { - case *Array: - // spec: "For a variable x of array type: unsafe.Alignof(x) - // is the same as unsafe.Alignof(x[0]), but at least 1." - return s.Alignof(t.elem) - case *Struct: - // spec: "For a variable x of struct type: unsafe.Alignof(x) - // is the largest of the values unsafe.Alignof(x.f) for each - // field f of x, but at least 1." - max := int64(1) - for _, f := range t.fields { - if a := s.Alignof(f.typ); a > max { - max = a - } - } - return max - } - a := s.Sizeof(T) // may be 0 - // spec: "For a variable x of any type: unsafe.Alignof(x) is at least 1." - if a < 1 { - return 1 - } - if a > s.MaxAlign { - return s.MaxAlign - } - return a -} - -func (s *StdSizes) Offsetsof(fields []*Var) []int64 { - offsets := make([]int64, len(fields)) - var o int64 - for i, f := range fields { - a := s.Alignof(f.typ) - o = align(o, a) - offsets[i] = o - o += s.Sizeof(f.typ) - } - return offsets -} - -var basicSizes = [...]byte{ - Bool: 1, - Int8: 1, - Int16: 2, - Int32: 4, - Int64: 8, - Uint8: 1, - Uint16: 2, - Uint32: 4, - Uint64: 8, - Float32: 4, - Float64: 8, - Complex64: 8, - Complex128: 16, -} - -func (s *StdSizes) Sizeof(T Type) int64 { - switch t := T.Underlying().(type) { - case *Basic: - assert(isTyped(T)) - k := t.kind - if int(k) < len(basicSizes) { - if s := basicSizes[k]; s > 0 { - return int64(s) - } - } - if k == String { - return s.WordSize * 2 - } - case *Array: - n := t.len - if n == 0 { - return 0 - } - a := s.Alignof(t.elem) - z := s.Sizeof(t.elem) - return align(z, a)*(n-1) + z - case *Slice: - return s.WordSize * 3 - case *Struct: - n := t.NumFields() - if n == 0 { - return 0 - } - offsets := t.offsets - if t.offsets == nil { - // compute offsets on demand - offsets = s.Offsetsof(t.fields) - t.offsets = offsets - } - return offsets[n-1] + s.Sizeof(t.fields[n-1].typ) - case *Interface: - return s.WordSize * 2 - } - return s.WordSize // catch-all -} - -// stdSizes is used if Config.Sizes == nil. -var stdSizes = StdSizes{8, 8} - -func (conf *Config) alignof(T Type) int64 { - if s := conf.Sizes; s != nil { - if a := s.Alignof(T); a >= 1 { - return a - } - panic("Config.Sizes.Alignof returned an alignment < 1") - } - return stdSizes.Alignof(T) -} - -func (conf *Config) offsetsof(T *Struct) []int64 { - offsets := T.offsets - if offsets == nil && T.NumFields() > 0 { - // compute offsets on demand - if s := conf.Sizes; s != nil { - offsets = s.Offsetsof(T.fields) - // sanity checks - if len(offsets) != T.NumFields() { - panic("Config.Sizes.Offsetsof returned the wrong number of offsets") - } - for _, o := range offsets { - if o < 0 { - panic("Config.Sizes.Offsetsof returned an offset < 0") - } - } - } else { - offsets = stdSizes.Offsetsof(T.fields) - } - T.offsets = offsets - } - return offsets -} - -// offsetof returns the offset of the field specified via -// the index sequence relative to typ. All embedded fields -// must be structs (rather than pointer to structs). -func (conf *Config) offsetof(typ Type, index []int) int64 { - var o int64 - for _, i := range index { - s := typ.Underlying().(*Struct) - o += conf.offsetsof(s)[i] - typ = s.fields[i].typ - } - return o -} - -func (conf *Config) sizeof(T Type) int64 { - if s := conf.Sizes; s != nil { - if z := s.Sizeof(T); z >= 0 { - return z - } - panic("Config.Sizes.Sizeof returned a size < 0") - } - return stdSizes.Sizeof(T) -} - -// align returns the smallest y >= x such that y % a == 0. -func align(x, a int64) int64 { - y := x + a - 1 - return y - y%a -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/stmt.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/stmt.go deleted file mode 100644 index eeb2c31730c..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/stmt.go +++ /dev/null @@ -1,745 +0,0 @@ -// Copyright 2012 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements typechecking of statements. - -package types - -import ( - "fmt" - "go/ast" - "go/token" - - "golang.org/x/tools/go/exact" -) - -func (check *Checker) funcBody(decl *declInfo, name string, sig *Signature, body *ast.BlockStmt) { - if trace { - if name == "" { - name = "" - } - fmt.Printf("--- %s: %s {\n", name, sig) - defer fmt.Println("--- ") - } - - // set function scope extent - sig.scope.pos = body.Pos() - sig.scope.end = body.End() - - // save/restore current context and setup function context - // (and use 0 indentation at function start) - defer func(ctxt context, indent int) { - check.context = ctxt - check.indent = indent - }(check.context, check.indent) - check.context = context{ - decl: decl, - scope: sig.scope, - sig: sig, - } - check.indent = 0 - - check.stmtList(0, body.List) - - if check.hasLabel { - check.labels(body) - } - - if sig.results.Len() > 0 && !check.isTerminating(body, "") { - check.error(body.Rbrace, "missing return") - } - - // spec: "Implementation restriction: A compiler may make it illegal to - // declare a variable inside a function body if the variable is never used." - // (One could check each scope after use, but that distributes this check - // over several places because CloseScope is not always called explicitly.) - check.usage(sig.scope) -} - -func (check *Checker) usage(scope *Scope) { - for _, obj := range scope.elems { - if v, _ := obj.(*Var); v != nil && !v.used { - check.softErrorf(v.pos, "%s declared but not used", v.name) - } - } - for _, scope := range scope.children { - check.usage(scope) - } -} - -// stmtContext is a bitset describing which -// control-flow statements are permissible. -type stmtContext uint - -const ( - breakOk stmtContext = 1 << iota - continueOk - fallthroughOk -) - -func (check *Checker) simpleStmt(s ast.Stmt) { - if s != nil { - check.stmt(0, s) - } -} - -func (check *Checker) stmtList(ctxt stmtContext, list []ast.Stmt) { - ok := ctxt&fallthroughOk != 0 - inner := ctxt &^ fallthroughOk - for i, s := range list { - inner := inner - if ok && i+1 == len(list) { - inner |= fallthroughOk - } - check.stmt(inner, s) - } -} - -func (check *Checker) multipleDefaults(list []ast.Stmt) { - var first ast.Stmt - for _, s := range list { - var d ast.Stmt - switch c := s.(type) { - case *ast.CaseClause: - if len(c.List) == 0 { - d = s - } - case *ast.CommClause: - if c.Comm == nil { - d = s - } - default: - check.invalidAST(s.Pos(), "case/communication clause expected") - } - if d != nil { - if first != nil { - check.errorf(d.Pos(), "multiple defaults (first at %s)", first.Pos()) - } else { - first = d - } - } - } -} - -func (check *Checker) openScope(s ast.Stmt, comment string) { - scope := NewScope(check.scope, s.Pos(), s.End(), comment) - check.recordScope(s, scope) - check.scope = scope -} - -func (check *Checker) closeScope() { - check.scope = check.scope.Parent() -} - -func assignOp(op token.Token) token.Token { - // token_test.go verifies the token ordering this function relies on - if token.ADD_ASSIGN <= op && op <= token.AND_NOT_ASSIGN { - return op + (token.ADD - token.ADD_ASSIGN) - } - return token.ILLEGAL -} - -func (check *Checker) suspendedCall(keyword string, call *ast.CallExpr) { - var x operand - var msg string - switch check.rawExpr(&x, call, nil) { - case conversion: - msg = "requires function call, not conversion" - case expression: - msg = "discards result of" - case statement: - return - default: - unreachable() - } - check.errorf(x.pos(), "%s %s %s", keyword, msg, &x) -} - -func (check *Checker) caseValues(x operand /* copy argument (not *operand!) */, values []ast.Expr) { - // No duplicate checking for now. See issue 4524. - for _, e := range values { - var y operand - check.expr(&y, e) - if y.mode == invalid { - return - } - // TODO(gri) The convertUntyped call pair below appears in other places. Factor! - // Order matters: By comparing y against x, error positions are at the case values. - check.convertUntyped(&y, x.typ) - if y.mode == invalid { - return - } - check.convertUntyped(&x, y.typ) - if x.mode == invalid { - return - } - check.comparison(&y, &x, token.EQL) - } -} - -func (check *Checker) caseTypes(x *operand, xtyp *Interface, types []ast.Expr, seen map[Type]token.Pos) (T Type) { -L: - for _, e := range types { - T = check.typOrNil(e) - if T == Typ[Invalid] { - continue - } - // complain about duplicate types - // TODO(gri) use a type hash to avoid quadratic algorithm - for t, pos := range seen { - if T == nil && t == nil || T != nil && t != nil && Identical(T, t) { - // talk about "case" rather than "type" because of nil case - check.error(e.Pos(), "duplicate case in type switch") - check.errorf(pos, "\tprevious case %s", T) // secondary error, \t indented - continue L - } - } - seen[T] = e.Pos() - if T != nil { - check.typeAssertion(e.Pos(), x, xtyp, T) - } - } - return -} - -// stmt typechecks statement s. -func (check *Checker) stmt(ctxt stmtContext, s ast.Stmt) { - // statements cannot use iota in general - // (constant declarations set it explicitly) - assert(check.iota == nil) - - // statements must end with the same top scope as they started with - if debug { - defer func(scope *Scope) { - // don't check if code is panicking - if p := recover(); p != nil { - panic(p) - } - assert(scope == check.scope) - }(check.scope) - } - - inner := ctxt &^ fallthroughOk - switch s := s.(type) { - case *ast.BadStmt, *ast.EmptyStmt: - // ignore - - case *ast.DeclStmt: - check.declStmt(s.Decl) - - case *ast.LabeledStmt: - check.hasLabel = true - check.stmt(ctxt, s.Stmt) - - case *ast.ExprStmt: - // spec: "With the exception of specific built-in functions, - // function and method calls and receive operations can appear - // in statement context. Such statements may be parenthesized." - var x operand - kind := check.rawExpr(&x, s.X, nil) - var msg string - switch x.mode { - default: - if kind == statement { - return - } - msg = "is not used" - case builtin: - msg = "must be called" - case typexpr: - msg = "is not an expression" - } - check.errorf(x.pos(), "%s %s", &x, msg) - - case *ast.SendStmt: - var ch, x operand - check.expr(&ch, s.Chan) - check.expr(&x, s.Value) - if ch.mode == invalid || x.mode == invalid { - return - } - if tch, ok := ch.typ.Underlying().(*Chan); !ok || tch.dir == RecvOnly || !check.assignment(&x, tch.elem) { - if x.mode != invalid { - check.invalidOp(ch.pos(), "cannot send %s to channel %s", &x, &ch) - } - } - - case *ast.IncDecStmt: - var op token.Token - switch s.Tok { - case token.INC: - op = token.ADD - case token.DEC: - op = token.SUB - default: - check.invalidAST(s.TokPos, "unknown inc/dec operation %s", s.Tok) - return - } - var x operand - Y := &ast.BasicLit{ValuePos: s.X.Pos(), Kind: token.INT, Value: "1"} // use x's position - check.binary(&x, nil, s.X, Y, op) - if x.mode == invalid { - return - } - check.assignVar(s.X, &x) - - case *ast.AssignStmt: - switch s.Tok { - case token.ASSIGN, token.DEFINE: - if len(s.Lhs) == 0 { - check.invalidAST(s.Pos(), "missing lhs in assignment") - return - } - if s.Tok == token.DEFINE { - check.shortVarDecl(s.TokPos, s.Lhs, s.Rhs) - } else { - // regular assignment - check.assignVars(s.Lhs, s.Rhs) - } - - default: - // assignment operations - if len(s.Lhs) != 1 || len(s.Rhs) != 1 { - check.errorf(s.TokPos, "assignment operation %s requires single-valued expressions", s.Tok) - return - } - op := assignOp(s.Tok) - if op == token.ILLEGAL { - check.invalidAST(s.TokPos, "unknown assignment operation %s", s.Tok) - return - } - var x operand - check.binary(&x, nil, s.Lhs[0], s.Rhs[0], op) - if x.mode == invalid { - return - } - check.assignVar(s.Lhs[0], &x) - } - - case *ast.GoStmt: - check.suspendedCall("go", s.Call) - - case *ast.DeferStmt: - check.suspendedCall("defer", s.Call) - - case *ast.ReturnStmt: - res := check.sig.results - if res.Len() > 0 { - // function returns results - // (if one, say the first, result parameter is named, all of them are named) - if len(s.Results) == 0 && res.vars[0].name != "" { - // spec: "Implementation restriction: A compiler may disallow an empty expression - // list in a "return" statement if a different entity (constant, type, or variable) - // with the same name as a result parameter is in scope at the place of the return." - for _, obj := range res.vars { - if _, alt := check.scope.LookupParent(obj.name, check.pos); alt != nil && alt != obj { - check.errorf(s.Pos(), "result parameter %s not in scope at return", obj.name) - check.errorf(alt.Pos(), "\tinner declaration of %s", obj) - // ok to continue - } - } - } else { - // return has results or result parameters are unnamed - check.initVars(res.vars, s.Results, s.Return) - } - } else if len(s.Results) > 0 { - check.error(s.Results[0].Pos(), "no result values expected") - check.use(s.Results...) - } - - case *ast.BranchStmt: - if s.Label != nil { - check.hasLabel = true - return // checked in 2nd pass (check.labels) - } - switch s.Tok { - case token.BREAK: - if ctxt&breakOk == 0 { - check.error(s.Pos(), "break not in for, switch, or select statement") - } - case token.CONTINUE: - if ctxt&continueOk == 0 { - check.error(s.Pos(), "continue not in for statement") - } - case token.FALLTHROUGH: - if ctxt&fallthroughOk == 0 { - check.error(s.Pos(), "fallthrough statement out of place") - } - default: - check.invalidAST(s.Pos(), "branch statement: %s", s.Tok) - } - - case *ast.BlockStmt: - check.openScope(s, "block") - defer check.closeScope() - - check.stmtList(inner, s.List) - - case *ast.IfStmt: - check.openScope(s, "if") - defer check.closeScope() - - check.simpleStmt(s.Init) - var x operand - check.expr(&x, s.Cond) - if x.mode != invalid && !isBoolean(x.typ) { - check.error(s.Cond.Pos(), "non-boolean condition in if statement") - } - check.stmt(inner, s.Body) - if s.Else != nil { - check.stmt(inner, s.Else) - } - - case *ast.SwitchStmt: - inner |= breakOk - check.openScope(s, "switch") - defer check.closeScope() - - check.simpleStmt(s.Init) - var x operand - if s.Tag != nil { - check.expr(&x, s.Tag) - } else { - // spec: "A missing switch expression is - // equivalent to the boolean value true." - x.mode = constant - x.typ = Typ[Bool] - x.val = exact.MakeBool(true) - x.expr = &ast.Ident{NamePos: s.Body.Lbrace, Name: "true"} - } - - check.multipleDefaults(s.Body.List) - - for i, c := range s.Body.List { - clause, _ := c.(*ast.CaseClause) - if clause == nil { - check.invalidAST(c.Pos(), "incorrect expression switch case") - continue - } - if x.mode != invalid { - check.caseValues(x, clause.List) - } - check.openScope(clause, "case") - inner := inner - if i+1 < len(s.Body.List) { - inner |= fallthroughOk - } - check.stmtList(inner, clause.Body) - check.closeScope() - } - - case *ast.TypeSwitchStmt: - inner |= breakOk - check.openScope(s, "type switch") - defer check.closeScope() - - check.simpleStmt(s.Init) - - // A type switch guard must be of the form: - // - // TypeSwitchGuard = [ identifier ":=" ] PrimaryExpr "." "(" "type" ")" . - // - // The parser is checking syntactic correctness; - // remaining syntactic errors are considered AST errors here. - // TODO(gri) better factoring of error handling (invalid ASTs) - // - var lhs *ast.Ident // lhs identifier or nil - var rhs ast.Expr - switch guard := s.Assign.(type) { - case *ast.ExprStmt: - rhs = guard.X - case *ast.AssignStmt: - if len(guard.Lhs) != 1 || guard.Tok != token.DEFINE || len(guard.Rhs) != 1 { - check.invalidAST(s.Pos(), "incorrect form of type switch guard") - return - } - - lhs, _ = guard.Lhs[0].(*ast.Ident) - if lhs == nil { - check.invalidAST(s.Pos(), "incorrect form of type switch guard") - return - } - - if lhs.Name == "_" { - // _ := x.(type) is an invalid short variable declaration - check.softErrorf(lhs.Pos(), "no new variable on left side of :=") - lhs = nil // avoid declared but not used error below - } else { - check.recordDef(lhs, nil) // lhs variable is implicitly declared in each cause clause - } - - rhs = guard.Rhs[0] - - default: - check.invalidAST(s.Pos(), "incorrect form of type switch guard") - return - } - - // rhs must be of the form: expr.(type) and expr must be an interface - expr, _ := rhs.(*ast.TypeAssertExpr) - if expr == nil || expr.Type != nil { - check.invalidAST(s.Pos(), "incorrect form of type switch guard") - return - } - var x operand - check.expr(&x, expr.X) - if x.mode == invalid { - return - } - xtyp, _ := x.typ.Underlying().(*Interface) - if xtyp == nil { - check.errorf(x.pos(), "%s is not an interface", &x) - return - } - - check.multipleDefaults(s.Body.List) - - var lhsVars []*Var // list of implicitly declared lhs variables - seen := make(map[Type]token.Pos) // map of seen types to positions - for _, s := range s.Body.List { - clause, _ := s.(*ast.CaseClause) - if clause == nil { - check.invalidAST(s.Pos(), "incorrect type switch case") - continue - } - // Check each type in this type switch case. - T := check.caseTypes(&x, xtyp, clause.List, seen) - check.openScope(clause, "case") - // If lhs exists, declare a corresponding variable in the case-local scope. - if lhs != nil { - // spec: "The TypeSwitchGuard may include a short variable declaration. - // When that form is used, the variable is declared at the beginning of - // the implicit block in each clause. In clauses with a case listing - // exactly one type, the variable has that type; otherwise, the variable - // has the type of the expression in the TypeSwitchGuard." - if len(clause.List) != 1 || T == nil { - T = x.typ - } - obj := NewVar(lhs.Pos(), check.pkg, lhs.Name, T) - scopePos := clause.End() - if len(clause.Body) > 0 { - scopePos = clause.Body[0].Pos() - } - check.declare(check.scope, nil, obj, scopePos) - check.recordImplicit(clause, obj) - // For the "declared but not used" error, all lhs variables act as - // one; i.e., if any one of them is 'used', all of them are 'used'. - // Collect them for later analysis. - lhsVars = append(lhsVars, obj) - } - check.stmtList(inner, clause.Body) - check.closeScope() - } - - // If lhs exists, we must have at least one lhs variable that was used. - if lhs != nil { - var used bool - for _, v := range lhsVars { - if v.used { - used = true - } - v.used = true // avoid usage error when checking entire function - } - if !used { - check.softErrorf(lhs.Pos(), "%s declared but not used", lhs.Name) - } - } - - case *ast.SelectStmt: - inner |= breakOk - - check.multipleDefaults(s.Body.List) - - for _, s := range s.Body.List { - clause, _ := s.(*ast.CommClause) - if clause == nil { - continue // error reported before - } - - // clause.Comm must be a SendStmt, RecvStmt, or default case - valid := false - var rhs ast.Expr // rhs of RecvStmt, or nil - switch s := clause.Comm.(type) { - case nil, *ast.SendStmt: - valid = true - case *ast.AssignStmt: - if len(s.Rhs) == 1 { - rhs = s.Rhs[0] - } - case *ast.ExprStmt: - rhs = s.X - } - - // if present, rhs must be a receive operation - if rhs != nil { - if x, _ := unparen(rhs).(*ast.UnaryExpr); x != nil && x.Op == token.ARROW { - valid = true - } - } - - if !valid { - check.error(clause.Comm.Pos(), "select case must be send or receive (possibly with assignment)") - continue - } - - check.openScope(s, "case") - if clause.Comm != nil { - check.stmt(inner, clause.Comm) - } - check.stmtList(inner, clause.Body) - check.closeScope() - } - - case *ast.ForStmt: - inner |= breakOk | continueOk - check.openScope(s, "for") - defer check.closeScope() - - check.simpleStmt(s.Init) - if s.Cond != nil { - var x operand - check.expr(&x, s.Cond) - if x.mode != invalid && !isBoolean(x.typ) { - check.error(s.Cond.Pos(), "non-boolean condition in for statement") - } - } - check.simpleStmt(s.Post) - // spec: "The init statement may be a short variable - // declaration, but the post statement must not." - if s, _ := s.Post.(*ast.AssignStmt); s != nil && s.Tok == token.DEFINE { - check.softErrorf(s.Pos(), "cannot declare in post statement") - check.use(s.Lhs...) // avoid follow-up errors - } - check.stmt(inner, s.Body) - - case *ast.RangeStmt: - inner |= breakOk | continueOk - check.openScope(s, "for") - defer check.closeScope() - - // check expression to iterate over - var x operand - check.expr(&x, s.X) - - // determine key/value types - var key, val Type - if x.mode != invalid { - switch typ := x.typ.Underlying().(type) { - case *Basic: - if isString(typ) { - key = Typ[Int] - val = universeRune // use 'rune' name - } - case *Array: - key = Typ[Int] - val = typ.elem - case *Slice: - key = Typ[Int] - val = typ.elem - case *Pointer: - if typ, _ := typ.base.Underlying().(*Array); typ != nil { - key = Typ[Int] - val = typ.elem - } - case *Map: - key = typ.key - val = typ.elem - case *Chan: - key = typ.elem - val = Typ[Invalid] - if typ.dir == SendOnly { - check.errorf(x.pos(), "cannot range over send-only channel %s", &x) - // ok to continue - } - if s.Value != nil { - check.errorf(s.Value.Pos(), "iteration over %s permits only one iteration variable", &x) - // ok to continue - } - } - } - - if key == nil { - check.errorf(x.pos(), "cannot range over %s", &x) - // ok to continue - } - - // check assignment to/declaration of iteration variables - // (irregular assignment, cannot easily map to existing assignment checks) - - // lhs expressions and initialization value (rhs) types - lhs := [2]ast.Expr{s.Key, s.Value} - rhs := [2]Type{key, val} // key, val may be nil - - if s.Tok == token.DEFINE { - // short variable declaration; variable scope starts after the range clause - // (the for loop opens a new scope, so variables on the lhs never redeclare - // previously declared variables) - var vars []*Var - for i, lhs := range lhs { - if lhs == nil { - continue - } - - // determine lhs variable - var obj *Var - if ident, _ := lhs.(*ast.Ident); ident != nil { - // declare new variable - name := ident.Name - obj = NewVar(ident.Pos(), check.pkg, name, nil) - check.recordDef(ident, obj) - // _ variables don't count as new variables - if name != "_" { - vars = append(vars, obj) - } - } else { - check.errorf(lhs.Pos(), "cannot declare %s", lhs) - obj = NewVar(lhs.Pos(), check.pkg, "_", nil) // dummy variable - } - - // initialize lhs variable - if typ := rhs[i]; typ != nil { - x.mode = value - x.expr = lhs // we don't have a better rhs expression to use here - x.typ = typ - check.initVar(obj, &x, false) - } else { - obj.typ = Typ[Invalid] - obj.used = true // don't complain about unused variable - } - } - - // declare variables - if len(vars) > 0 { - for _, obj := range vars { - // spec: "The scope of a constant or variable identifier declared inside - // a function begins at the end of the ConstSpec or VarSpec (ShortVarDecl - // for short variable declarations) and ends at the end of the innermost - // containing block." - scopePos := s.End() - check.declare(check.scope, nil /* recordDef already called */, obj, scopePos) - } - } else { - check.error(s.TokPos, "no new variables on left side of :=") - } - } else { - // ordinary assignment - for i, lhs := range lhs { - if lhs == nil { - continue - } - if typ := rhs[i]; typ != nil { - x.mode = value - x.expr = lhs // we don't have a better rhs expression to use here - x.typ = typ - check.assignVar(lhs, &x) - } - } - } - - check.stmt(inner, s.Body) - - default: - check.error(s.Pos(), "invalid statement") - } -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/type.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/type.go deleted file mode 100644 index 8e24b54d3ba..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/type.go +++ /dev/null @@ -1,454 +0,0 @@ -// Copyright 2011 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -package types - -import "sort" - -// TODO(gri) Revisit factory functions - make sure they have all relevant parameters. - -// A Type represents a type of Go. -// All types implement the Type interface. -type Type interface { - // Underlying returns the underlying type of a type. - Underlying() Type - - // String returns a string representation of a type. - String() string -} - -// BasicKind describes the kind of basic type. -type BasicKind int - -const ( - Invalid BasicKind = iota // type is invalid - - // predeclared types - Bool - Int - Int8 - Int16 - Int32 - Int64 - Uint - Uint8 - Uint16 - Uint32 - Uint64 - Uintptr - Float32 - Float64 - Complex64 - Complex128 - String - UnsafePointer - - // types for untyped values - UntypedBool - UntypedInt - UntypedRune - UntypedFloat - UntypedComplex - UntypedString - UntypedNil - - // aliases - Byte = Uint8 - Rune = Int32 -) - -// BasicInfo is a set of flags describing properties of a basic type. -type BasicInfo int - -// Properties of basic types. -const ( - IsBoolean BasicInfo = 1 << iota - IsInteger - IsUnsigned - IsFloat - IsComplex - IsString - IsUntyped - - IsOrdered = IsInteger | IsFloat | IsString - IsNumeric = IsInteger | IsFloat | IsComplex - IsConstType = IsBoolean | IsNumeric | IsString -) - -// A Basic represents a basic type. -type Basic struct { - kind BasicKind - info BasicInfo - name string -} - -// Kind returns the kind of basic type b. -func (b *Basic) Kind() BasicKind { return b.kind } - -// Info returns information about properties of basic type b. -func (b *Basic) Info() BasicInfo { return b.info } - -// Name returns the name of basic type b. -func (b *Basic) Name() string { return b.name } - -// An Array represents an array type. -type Array struct { - len int64 - elem Type -} - -// NewArray returns a new array type for the given element type and length. -func NewArray(elem Type, len int64) *Array { return &Array{len, elem} } - -// Len returns the length of array a. -func (a *Array) Len() int64 { return a.len } - -// Elem returns element type of array a. -func (a *Array) Elem() Type { return a.elem } - -// A Slice represents a slice type. -type Slice struct { - elem Type -} - -// NewSlice returns a new slice type for the given element type. -func NewSlice(elem Type) *Slice { return &Slice{elem} } - -// Elem returns the element type of slice s. -func (s *Slice) Elem() Type { return s.elem } - -// A Struct represents a struct type. -type Struct struct { - fields []*Var - tags []string // field tags; nil if there are no tags - // TODO(gri) access to offsets is not threadsafe - fix this - offsets []int64 // field offsets in bytes, lazily initialized -} - -// NewStruct returns a new struct with the given fields and corresponding field tags. -// If a field with index i has a tag, tags[i] must be that tag, but len(tags) may be -// only as long as required to hold the tag with the largest index i. Consequently, -// if no field has a tag, tags may be nil. -func NewStruct(fields []*Var, tags []string) *Struct { - var fset objset - for _, f := range fields { - if f.name != "_" && fset.insert(f) != nil { - panic("multiple fields with the same name") - } - } - if len(tags) > len(fields) { - panic("more tags than fields") - } - return &Struct{fields: fields, tags: tags} -} - -// NumFields returns the number of fields in the struct (including blank and anonymous fields). -func (s *Struct) NumFields() int { return len(s.fields) } - -// Field returns the i'th field for 0 <= i < NumFields(). -func (s *Struct) Field(i int) *Var { return s.fields[i] } - -// Tag returns the i'th field tag for 0 <= i < NumFields(). -func (s *Struct) Tag(i int) string { - if i < len(s.tags) { - return s.tags[i] - } - return "" -} - -// A Pointer represents a pointer type. -type Pointer struct { - base Type // element type -} - -// NewPointer returns a new pointer type for the given element (base) type. -func NewPointer(elem Type) *Pointer { return &Pointer{base: elem} } - -// Elem returns the element type for the given pointer p. -func (p *Pointer) Elem() Type { return p.base } - -// A Tuple represents an ordered list of variables; a nil *Tuple is a valid (empty) tuple. -// Tuples are used as components of signatures and to represent the type of multiple -// assignments; they are not first class types of Go. -type Tuple struct { - vars []*Var -} - -// NewTuple returns a new tuple for the given variables. -func NewTuple(x ...*Var) *Tuple { - if len(x) > 0 { - return &Tuple{x} - } - return nil -} - -// Len returns the number variables of tuple t. -func (t *Tuple) Len() int { - if t != nil { - return len(t.vars) - } - return 0 -} - -// At returns the i'th variable of tuple t. -func (t *Tuple) At(i int) *Var { return t.vars[i] } - -// A Signature represents a (non-builtin) function or method type. -type Signature struct { - // We need to keep the scope in Signature (rather than passing it around - // and store it in the Func Object) because when type-checking a function - // literal we call the general type checker which returns a general Type. - // We then unpack the *Signature and use the scope for the literal body. - scope *Scope // function scope, present for package-local signatures - recv *Var // nil if not a method - params *Tuple // (incoming) parameters from left to right; or nil - results *Tuple // (outgoing) results from left to right; or nil - variadic bool // true if the last parameter's type is of the form ...T (or string, for append built-in only) -} - -// NewSignature returns a new function type for the given receiver, parameters, -// and results, either of which may be nil. If variadic is set, the function -// is variadic, it must have at least one parameter, and the last parameter -// must be of unnamed slice type. -func NewSignature(recv *Var, params, results *Tuple, variadic bool) *Signature { - if variadic { - n := params.Len() - if n == 0 { - panic("types.NewSignature: variadic function must have at least one parameter") - } - if _, ok := params.At(n - 1).typ.(*Slice); !ok { - panic("types.NewSignature: variadic parameter must be of unnamed slice type") - } - } - return &Signature{nil, recv, params, results, variadic} -} - -// Recv returns the receiver of signature s (if a method), or nil if a -// function. -// -// For an abstract method, Recv returns the enclosing interface either -// as a *Named or an *Interface. Due to embedding, an interface may -// contain methods whose receiver type is a different interface. -func (s *Signature) Recv() *Var { return s.recv } - -// Params returns the parameters of signature s, or nil. -func (s *Signature) Params() *Tuple { return s.params } - -// Results returns the results of signature s, or nil. -func (s *Signature) Results() *Tuple { return s.results } - -// Variadic reports whether the signature s is variadic. -func (s *Signature) Variadic() bool { return s.variadic } - -// An Interface represents an interface type. -type Interface struct { - methods []*Func // ordered list of explicitly declared methods - embeddeds []*Named // ordered list of explicitly embedded types - - allMethods []*Func // ordered list of methods declared with or embedded in this interface (TODO(gri): replace with mset) -} - -// NewInterface returns a new interface for the given methods and embedded types. -func NewInterface(methods []*Func, embeddeds []*Named) *Interface { - typ := new(Interface) - - var mset objset - for _, m := range methods { - if mset.insert(m) != nil { - panic("multiple methods with the same name") - } - // set receiver - // TODO(gri) Ideally, we should use a named type here instead of - // typ, for less verbose printing of interface method signatures. - m.typ.(*Signature).recv = NewVar(m.pos, m.pkg, "", typ) - } - sort.Sort(byUniqueMethodName(methods)) - - if embeddeds == nil { - sort.Sort(byUniqueTypeName(embeddeds)) - } - - typ.methods = methods - typ.embeddeds = embeddeds - return typ -} - -// NumExplicitMethods returns the number of explicitly declared methods of interface t. -func (t *Interface) NumExplicitMethods() int { return len(t.methods) } - -// ExplicitMethod returns the i'th explicitly declared method of interface t for 0 <= i < t.NumExplicitMethods(). -// The methods are ordered by their unique Id. -func (t *Interface) ExplicitMethod(i int) *Func { return t.methods[i] } - -// NumEmbeddeds returns the number of embedded types in interface t. -func (t *Interface) NumEmbeddeds() int { return len(t.embeddeds) } - -// Embedded returns the i'th embedded type of interface t for 0 <= i < t.NumEmbeddeds(). -// The types are ordered by the corresponding TypeName's unique Id. -func (t *Interface) Embedded(i int) *Named { return t.embeddeds[i] } - -// NumMethods returns the total number of methods of interface t. -func (t *Interface) NumMethods() int { return len(t.allMethods) } - -// Method returns the i'th method of interface t for 0 <= i < t.NumMethods(). -// The methods are ordered by their unique Id. -func (t *Interface) Method(i int) *Func { return t.allMethods[i] } - -// Empty returns true if t is the empty interface. -func (t *Interface) Empty() bool { return len(t.allMethods) == 0 } - -// Complete computes the interface's method set. It must be called by users of -// NewInterface after the interface's embedded types are fully defined and -// before using the interface type in any way other than to form other types. -// Complete returns the receiver. -func (t *Interface) Complete() *Interface { - if t.allMethods != nil { - return t - } - - var allMethods []*Func - if t.embeddeds == nil { - if t.methods == nil { - allMethods = make([]*Func, 0, 1) - } else { - allMethods = t.methods - } - } else { - allMethods = append(allMethods, t.methods...) - for _, et := range t.embeddeds { - it := et.Underlying().(*Interface) - it.Complete() - for _, tm := range it.allMethods { - // Make a copy of the method and adjust its receiver type. - newm := *tm - newmtyp := *tm.typ.(*Signature) - newm.typ = &newmtyp - newmtyp.recv = NewVar(newm.pos, newm.pkg, "", t) - allMethods = append(allMethods, &newm) - } - } - sort.Sort(byUniqueMethodName(allMethods)) - } - t.allMethods = allMethods - - return t -} - -// A Map represents a map type. -type Map struct { - key, elem Type -} - -// NewMap returns a new map for the given key and element types. -func NewMap(key, elem Type) *Map { - return &Map{key, elem} -} - -// Key returns the key type of map m. -func (m *Map) Key() Type { return m.key } - -// Elem returns the element type of map m. -func (m *Map) Elem() Type { return m.elem } - -// A Chan represents a channel type. -type Chan struct { - dir ChanDir - elem Type -} - -// A ChanDir value indicates a channel direction. -type ChanDir int - -// The direction of a channel is indicated by one of the following constants. -const ( - SendRecv ChanDir = iota - SendOnly - RecvOnly -) - -// NewChan returns a new channel type for the given direction and element type. -func NewChan(dir ChanDir, elem Type) *Chan { - return &Chan{dir, elem} -} - -// Dir returns the direction of channel c. -func (c *Chan) Dir() ChanDir { return c.dir } - -// Elem returns the element type of channel c. -func (c *Chan) Elem() Type { return c.elem } - -// A Named represents a named type. -type Named struct { - obj *TypeName // corresponding declared object - underlying Type // possibly a *Named during setup; never a *Named once set up completely - methods []*Func // methods declared for this type (not the method set of this type) -} - -// NewNamed returns a new named type for the given type name, underlying type, and associated methods. -// The underlying type must not be a *Named. -func NewNamed(obj *TypeName, underlying Type, methods []*Func) *Named { - if _, ok := underlying.(*Named); ok { - panic("types.NewNamed: underlying type must not be *Named") - } - typ := &Named{obj: obj, underlying: underlying, methods: methods} - if obj.typ == nil { - obj.typ = typ - } - return typ -} - -// Obj returns the type name for the named type t. -func (t *Named) Obj() *TypeName { return t.obj } - -// NumMethods returns the number of explicit methods whose receiver is named type t. -func (t *Named) NumMethods() int { return len(t.methods) } - -// Method returns the i'th method of named type t for 0 <= i < t.NumMethods(). -func (t *Named) Method(i int) *Func { return t.methods[i] } - -// SetUnderlying sets the underlying type and marks t as complete. -// TODO(gri) determine if there's a better solution rather than providing this function -func (t *Named) SetUnderlying(underlying Type) { - if underlying == nil { - panic("types.Named.SetUnderlying: underlying type must not be nil") - } - if _, ok := underlying.(*Named); ok { - panic("types.Named.SetUnderlying: underlying type must not be *Named") - } - t.underlying = underlying -} - -// AddMethod adds method m unless it is already in the method list. -// TODO(gri) find a better solution instead of providing this function -func (t *Named) AddMethod(m *Func) { - if i, _ := lookupMethod(t.methods, m.pkg, m.name); i < 0 { - t.methods = append(t.methods, m) - } -} - -// Implementations for Type methods. - -func (t *Basic) Underlying() Type { return t } -func (t *Array) Underlying() Type { return t } -func (t *Slice) Underlying() Type { return t } -func (t *Struct) Underlying() Type { return t } -func (t *Pointer) Underlying() Type { return t } -func (t *Tuple) Underlying() Type { return t } -func (t *Signature) Underlying() Type { return t } -func (t *Interface) Underlying() Type { return t } -func (t *Map) Underlying() Type { return t } -func (t *Chan) Underlying() Type { return t } -func (t *Named) Underlying() Type { return t.underlying } - -func (t *Basic) String() string { return TypeString(t, nil) } -func (t *Array) String() string { return TypeString(t, nil) } -func (t *Slice) String() string { return TypeString(t, nil) } -func (t *Struct) String() string { return TypeString(t, nil) } -func (t *Pointer) String() string { return TypeString(t, nil) } -func (t *Tuple) String() string { return TypeString(t, nil) } -func (t *Signature) String() string { return TypeString(t, nil) } -func (t *Interface) String() string { return TypeString(t, nil) } -func (t *Map) String() string { return TypeString(t, nil) } -func (t *Chan) String() string { return TypeString(t, nil) } -func (t *Named) String() string { return TypeString(t, nil) } diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/typestring.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/typestring.go deleted file mode 100644 index abee8abb567..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/typestring.go +++ /dev/null @@ -1,292 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements printing of types. - -package types - -import ( - "bytes" - "fmt" -) - -// A Qualifier controls how named package-level objects are printed in -// calls to TypeString, ObjectString, and SelectionString. -// -// These three formatting routines call the Qualifier for each -// package-level object O, and if the Qualifier returns a non-empty -// string p, the object is printed in the form p.O. -// If it returns an empty string, only the object name O is printed. -// -// Using a nil Qualifier is equivalent to using (*Package).Path: the -// object is qualified by the import path, e.g., "encoding/json.Marshal". -// -type Qualifier func(*Package) string - -// RelativeTo(pkg) returns a Qualifier that fully qualifies members of -// all packages other than pkg. -func RelativeTo(pkg *Package) Qualifier { - if pkg == nil { - return nil - } - return func(other *Package) string { - if pkg == other { - return "" // same package; unqualified - } - return other.Path() - } -} - -// If GcCompatibilityMode is set, printing of types is modified -// to match the representation of some types in the gc compiler: -// -// - byte and rune lose their alias name and simply stand for -// uint8 and int32 respectively -// - embedded interfaces get flattened (the embedding info is lost, -// and certain recursive interface types cannot be printed anymore) -// -// This makes it easier to compare packages computed with the type- -// checker vs packages imported from gc export data. -// -// Caution: This flag affects all uses of WriteType, globally. -// It is only provided for testing in conjunction with -// gc-generated data. It may be removed at any time. -var GcCompatibilityMode bool - -// TypeString returns the string representation of typ. -// The Qualifier controls the printing of -// package-level objects, and may be nil. -func TypeString(typ Type, qf Qualifier) string { - var buf bytes.Buffer - WriteType(&buf, typ, qf) - return buf.String() -} - -// WriteType writes the string representation of typ to buf. -// The Qualifier controls the printing of -// package-level objects, and may be nil. -func WriteType(buf *bytes.Buffer, typ Type, qf Qualifier) { - writeType(buf, typ, qf, make([]Type, 8)) -} - -func writeType(buf *bytes.Buffer, typ Type, qf Qualifier, visited []Type) { - // Theoretically, this is a quadratic lookup algorithm, but in - // practice deeply nested composite types with unnamed component - // types are uncommon. This code is likely more efficient than - // using a map. - for _, t := range visited { - if t == typ { - fmt.Fprintf(buf, "○%T", typ) // cycle to typ - return - } - } - visited = append(visited, typ) - - switch t := typ.(type) { - case nil: - buf.WriteString("") - - case *Basic: - if t.kind == UnsafePointer { - buf.WriteString("unsafe.") - } - if GcCompatibilityMode { - // forget the alias names - switch t.kind { - case Byte: - t = Typ[Uint8] - case Rune: - t = Typ[Int32] - } - } - buf.WriteString(t.name) - - case *Array: - fmt.Fprintf(buf, "[%d]", t.len) - writeType(buf, t.elem, qf, visited) - - case *Slice: - buf.WriteString("[]") - writeType(buf, t.elem, qf, visited) - - case *Struct: - buf.WriteString("struct{") - for i, f := range t.fields { - if i > 0 { - buf.WriteString("; ") - } - if !f.anonymous { - buf.WriteString(f.name) - buf.WriteByte(' ') - } - writeType(buf, f.typ, qf, visited) - if tag := t.Tag(i); tag != "" { - fmt.Fprintf(buf, " %q", tag) - } - } - buf.WriteByte('}') - - case *Pointer: - buf.WriteByte('*') - writeType(buf, t.base, qf, visited) - - case *Tuple: - writeTuple(buf, t, false, qf, visited) - - case *Signature: - buf.WriteString("func") - writeSignature(buf, t, qf, visited) - - case *Interface: - // We write the source-level methods and embedded types rather - // than the actual method set since resolved method signatures - // may have non-printable cycles if parameters have anonymous - // interface types that (directly or indirectly) embed the - // current interface. For instance, consider the result type - // of m: - // - // type T interface{ - // m() interface{ T } - // } - // - buf.WriteString("interface{") - if GcCompatibilityMode { - // print flattened interface - // (useful to compare against gc-generated interfaces) - for i, m := range t.allMethods { - if i > 0 { - buf.WriteString("; ") - } - buf.WriteString(m.name) - writeSignature(buf, m.typ.(*Signature), qf, visited) - } - } else { - // print explicit interface methods and embedded types - for i, m := range t.methods { - if i > 0 { - buf.WriteString("; ") - } - buf.WriteString(m.name) - writeSignature(buf, m.typ.(*Signature), qf, visited) - } - for i, typ := range t.embeddeds { - if i > 0 || len(t.methods) > 0 { - buf.WriteString("; ") - } - writeType(buf, typ, qf, visited) - } - } - buf.WriteByte('}') - - case *Map: - buf.WriteString("map[") - writeType(buf, t.key, qf, visited) - buf.WriteByte(']') - writeType(buf, t.elem, qf, visited) - - case *Chan: - var s string - var parens bool - switch t.dir { - case SendRecv: - s = "chan " - // chan (<-chan T) requires parentheses - if c, _ := t.elem.(*Chan); c != nil && c.dir == RecvOnly { - parens = true - } - case SendOnly: - s = "chan<- " - case RecvOnly: - s = "<-chan " - default: - panic("unreachable") - } - buf.WriteString(s) - if parens { - buf.WriteByte('(') - } - writeType(buf, t.elem, qf, visited) - if parens { - buf.WriteByte(')') - } - - case *Named: - s := "" - if obj := t.obj; obj != nil { - if obj.pkg != nil { - writePackage(buf, obj.pkg, qf) - } - // TODO(gri): function-local named types should be displayed - // differently from named types at package level to avoid - // ambiguity. - s = obj.name - } - buf.WriteString(s) - - default: - // For externally defined implementations of Type. - buf.WriteString(t.String()) - } -} - -func writeTuple(buf *bytes.Buffer, tup *Tuple, variadic bool, qf Qualifier, visited []Type) { - buf.WriteByte('(') - if tup != nil { - for i, v := range tup.vars { - if i > 0 { - buf.WriteString(", ") - } - if v.name != "" { - buf.WriteString(v.name) - buf.WriteByte(' ') - } - typ := v.typ - if variadic && i == len(tup.vars)-1 { - if s, ok := typ.(*Slice); ok { - buf.WriteString("...") - typ = s.elem - } else { - // special case: - // append(s, "foo"...) leads to signature func([]byte, string...) - if t, ok := typ.Underlying().(*Basic); !ok || t.kind != String { - panic("internal error: string type expected") - } - writeType(buf, typ, qf, visited) - buf.WriteString("...") - continue - } - } - writeType(buf, typ, qf, visited) - } - } - buf.WriteByte(')') -} - -// WriteSignature writes the representation of the signature sig to buf, -// without a leading "func" keyword. -// The Qualifier controls the printing of -// package-level objects, and may be nil. -func WriteSignature(buf *bytes.Buffer, sig *Signature, qf Qualifier) { - writeSignature(buf, sig, qf, make([]Type, 8)) -} - -func writeSignature(buf *bytes.Buffer, sig *Signature, qf Qualifier, visited []Type) { - writeTuple(buf, sig.params, sig.variadic, qf, visited) - - n := sig.results.Len() - if n == 0 { - // no result - return - } - - buf.WriteByte(' ') - if n == 1 && sig.results.vars[0].name == "" { - // single unnamed result - writeType(buf, sig.results.vars[0].typ, qf, visited) - return - } - - // multiple or named result(s) - writeTuple(buf, sig.results, false, qf, visited) -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/typexpr.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/typexpr.go deleted file mode 100644 index bd2d7ba272e..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/typexpr.go +++ /dev/null @@ -1,713 +0,0 @@ -// Copyright 2013 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file implements type-checking of identifiers and type expressions. - -package types - -import ( - "go/ast" - "go/token" - "sort" - "strconv" - - "golang.org/x/tools/go/exact" -) - -// ident type-checks identifier e and initializes x with the value or type of e. -// If an error occurred, x.mode is set to invalid. -// For the meaning of def and path, see check.typ, below. -// -func (check *Checker) ident(x *operand, e *ast.Ident, def *Named, path []*TypeName) { - x.mode = invalid - x.expr = e - - scope, obj := check.scope.LookupParent(e.Name, check.pos) - if obj == nil { - if e.Name == "_" { - check.errorf(e.Pos(), "cannot use _ as value or type") - } else { - check.errorf(e.Pos(), "undeclared name: %s", e.Name) - } - return - } - check.recordUse(e, obj) - - check.objDecl(obj, def, path) - typ := obj.Type() - assert(typ != nil) - - // The object may be dot-imported: If so, remove its package from - // the map of unused dot imports for the respective file scope. - // (This code is only needed for dot-imports. Without them, - // we only have to mark variables, see *Var case below). - if pkg := obj.Pkg(); pkg != check.pkg && pkg != nil { - delete(check.unusedDotImports[scope], pkg) - } - - switch obj := obj.(type) { - case *PkgName: - check.errorf(e.Pos(), "use of package %s not in selector", obj.name) - return - - case *Const: - check.addDeclDep(obj) - if typ == Typ[Invalid] { - return - } - if obj == universeIota { - if check.iota == nil { - check.errorf(e.Pos(), "cannot use iota outside constant declaration") - return - } - x.val = check.iota - } else { - x.val = obj.val - } - assert(x.val != nil) - x.mode = constant - - case *TypeName: - x.mode = typexpr - // check for cycle - // (it's ok to iterate forward because each named type appears at most once in path) - for i, prev := range path { - if prev == obj { - check.errorf(obj.pos, "illegal cycle in declaration of %s", obj.name) - // print cycle - for _, obj := range path[i:] { - check.errorf(obj.Pos(), "\t%s refers to", obj.Name()) // secondary error, \t indented - } - check.errorf(obj.Pos(), "\t%s", obj.Name()) - // maintain x.mode == typexpr despite error - typ = Typ[Invalid] - break - } - } - - case *Var: - if obj.pkg == check.pkg { - obj.used = true - } - check.addDeclDep(obj) - if typ == Typ[Invalid] { - return - } - x.mode = variable - - case *Func: - check.addDeclDep(obj) - x.mode = value - - case *Builtin: - x.id = obj.id - x.mode = builtin - - case *Nil: - x.mode = value - - default: - unreachable() - } - - x.typ = typ -} - -// typExpr type-checks the type expression e and returns its type, or Typ[Invalid]. -// If def != nil, e is the type specification for the named type def, declared -// in a type declaration, and def.underlying will be set to the type of e before -// any components of e are type-checked. Path contains the path of named types -// referring to this type. -// -func (check *Checker) typExpr(e ast.Expr, def *Named, path []*TypeName) (T Type) { - if trace { - check.trace(e.Pos(), "%s", e) - check.indent++ - defer func() { - check.indent-- - check.trace(e.Pos(), "=> %s", T) - }() - } - - T = check.typExprInternal(e, def, path) - assert(isTyped(T)) - check.recordTypeAndValue(e, typexpr, T, nil) - - return -} - -func (check *Checker) typ(e ast.Expr) Type { - return check.typExpr(e, nil, nil) -} - -// funcType type-checks a function or method type. -func (check *Checker) funcType(sig *Signature, recvPar *ast.FieldList, ftyp *ast.FuncType) { - scope := NewScope(check.scope, token.NoPos, token.NoPos, "function") - check.recordScope(ftyp, scope) - - recvList, _ := check.collectParams(scope, recvPar, false) - params, variadic := check.collectParams(scope, ftyp.Params, true) - results, _ := check.collectParams(scope, ftyp.Results, false) - - if recvPar != nil { - // recv parameter list present (may be empty) - // spec: "The receiver is specified via an extra parameter section preceeding the - // method name. That parameter section must declare a single parameter, the receiver." - var recv *Var - switch len(recvList) { - case 0: - check.error(recvPar.Pos(), "method is missing receiver") - recv = NewParam(0, nil, "", Typ[Invalid]) // ignore recv below - default: - // more than one receiver - check.error(recvList[len(recvList)-1].Pos(), "method must have exactly one receiver") - fallthrough // continue with first receiver - case 1: - recv = recvList[0] - } - // spec: "The receiver type must be of the form T or *T where T is a type name." - // (ignore invalid types - error was reported before) - if t, _ := deref(recv.typ); t != Typ[Invalid] { - var err string - if T, _ := t.(*Named); T != nil { - // spec: "The type denoted by T is called the receiver base type; it must not - // be a pointer or interface type and it must be declared in the same package - // as the method." - if T.obj.pkg != check.pkg { - err = "type not defined in this package" - } else { - // TODO(gri) This is not correct if the underlying type is unknown yet. - switch u := T.underlying.(type) { - case *Basic: - // unsafe.Pointer is treated like a regular pointer - if u.kind == UnsafePointer { - err = "unsafe.Pointer" - } - case *Pointer, *Interface: - err = "pointer or interface type" - } - } - } else { - err = "basic or unnamed type" - } - if err != "" { - check.errorf(recv.pos, "invalid receiver %s (%s)", recv.typ, err) - // ok to continue - } - } - sig.recv = recv - } - - sig.scope = scope - sig.params = NewTuple(params...) - sig.results = NewTuple(results...) - sig.variadic = variadic -} - -// typExprInternal drives type checking of types. -// Must only be called by typExpr. -// -func (check *Checker) typExprInternal(e ast.Expr, def *Named, path []*TypeName) Type { - switch e := e.(type) { - case *ast.BadExpr: - // ignore - error reported before - - case *ast.Ident: - var x operand - check.ident(&x, e, def, path) - - switch x.mode { - case typexpr: - typ := x.typ - def.setUnderlying(typ) - return typ - case invalid: - // ignore - error reported before - case novalue: - check.errorf(x.pos(), "%s used as type", &x) - default: - check.errorf(x.pos(), "%s is not a type", &x) - } - - case *ast.SelectorExpr: - var x operand - check.selector(&x, e) - - switch x.mode { - case typexpr: - typ := x.typ - def.setUnderlying(typ) - return typ - case invalid: - // ignore - error reported before - case novalue: - check.errorf(x.pos(), "%s used as type", &x) - default: - check.errorf(x.pos(), "%s is not a type", &x) - } - - case *ast.ParenExpr: - return check.typExpr(e.X, def, path) - - case *ast.ArrayType: - if e.Len != nil { - typ := new(Array) - def.setUnderlying(typ) - typ.len = check.arrayLength(e.Len) - typ.elem = check.typExpr(e.Elt, nil, path) - return typ - - } else { - typ := new(Slice) - def.setUnderlying(typ) - typ.elem = check.typ(e.Elt) - return typ - } - - case *ast.StructType: - typ := new(Struct) - def.setUnderlying(typ) - check.structType(typ, e, path) - return typ - - case *ast.StarExpr: - typ := new(Pointer) - def.setUnderlying(typ) - typ.base = check.typ(e.X) - return typ - - case *ast.FuncType: - typ := new(Signature) - def.setUnderlying(typ) - check.funcType(typ, nil, e) - return typ - - case *ast.InterfaceType: - typ := new(Interface) - def.setUnderlying(typ) - check.interfaceType(typ, e, def, path) - return typ - - case *ast.MapType: - typ := new(Map) - def.setUnderlying(typ) - - typ.key = check.typ(e.Key) - typ.elem = check.typ(e.Value) - - // spec: "The comparison operators == and != must be fully defined - // for operands of the key type; thus the key type must not be a - // function, map, or slice." - // - // Delay this check because it requires fully setup types; - // it is safe to continue in any case (was issue 6667). - check.delay(func() { - if !Comparable(typ.key) { - check.errorf(e.Key.Pos(), "invalid map key type %s", typ.key) - } - }) - - return typ - - case *ast.ChanType: - typ := new(Chan) - def.setUnderlying(typ) - - dir := SendRecv - switch e.Dir { - case ast.SEND | ast.RECV: - // nothing to do - case ast.SEND: - dir = SendOnly - case ast.RECV: - dir = RecvOnly - default: - check.invalidAST(e.Pos(), "unknown channel direction %d", e.Dir) - // ok to continue - } - - typ.dir = dir - typ.elem = check.typ(e.Value) - return typ - - default: - check.errorf(e.Pos(), "%s is not a type", e) - } - - typ := Typ[Invalid] - def.setUnderlying(typ) - return typ -} - -// typeOrNil type-checks the type expression (or nil value) e -// and returns the typ of e, or nil. -// If e is neither a type nor nil, typOrNil returns Typ[Invalid]. -// -func (check *Checker) typOrNil(e ast.Expr) Type { - var x operand - check.rawExpr(&x, e, nil) - switch x.mode { - case invalid: - // ignore - error reported before - case novalue: - check.errorf(x.pos(), "%s used as type", &x) - case typexpr: - return x.typ - case value: - if x.isNil() { - return nil - } - fallthrough - default: - check.errorf(x.pos(), "%s is not a type", &x) - } - return Typ[Invalid] -} - -func (check *Checker) arrayLength(e ast.Expr) int64 { - var x operand - check.expr(&x, e) - if x.mode != constant { - if x.mode != invalid { - check.errorf(x.pos(), "array length %s must be constant", &x) - } - return 0 - } - if !x.isInteger() { - check.errorf(x.pos(), "array length %s must be integer", &x) - return 0 - } - n, ok := exact.Int64Val(x.val) - if !ok || n < 0 { - check.errorf(x.pos(), "invalid array length %s", &x) - return 0 - } - return n -} - -func (check *Checker) collectParams(scope *Scope, list *ast.FieldList, variadicOk bool) (params []*Var, variadic bool) { - if list == nil { - return - } - - var named, anonymous bool - for i, field := range list.List { - ftype := field.Type - if t, _ := ftype.(*ast.Ellipsis); t != nil { - ftype = t.Elt - if variadicOk && i == len(list.List)-1 { - variadic = true - } else { - check.invalidAST(field.Pos(), "... not permitted") - // ignore ... and continue - } - } - typ := check.typ(ftype) - // The parser ensures that f.Tag is nil and we don't - // care if a constructed AST contains a non-nil tag. - if len(field.Names) > 0 { - // named parameter - for _, name := range field.Names { - if name.Name == "" { - check.invalidAST(name.Pos(), "anonymous parameter") - // ok to continue - } - par := NewParam(name.Pos(), check.pkg, name.Name, typ) - check.declare(scope, name, par, scope.pos) - params = append(params, par) - } - named = true - } else { - // anonymous parameter - par := NewParam(ftype.Pos(), check.pkg, "", typ) - check.recordImplicit(field, par) - params = append(params, par) - anonymous = true - } - } - - if named && anonymous { - check.invalidAST(list.Pos(), "list contains both named and anonymous parameters") - // ok to continue - } - - // For a variadic function, change the last parameter's type from T to []T. - if variadic && len(params) > 0 { - last := params[len(params)-1] - last.typ = &Slice{elem: last.typ} - } - - return -} - -func (check *Checker) declareInSet(oset *objset, pos token.Pos, obj Object) bool { - if alt := oset.insert(obj); alt != nil { - check.errorf(pos, "%s redeclared", obj.Name()) - check.reportAltDecl(alt) - return false - } - return true -} - -func (check *Checker) interfaceType(iface *Interface, ityp *ast.InterfaceType, def *Named, path []*TypeName) { - // empty interface: common case - if ityp.Methods == nil { - return - } - - // The parser ensures that field tags are nil and we don't - // care if a constructed AST contains non-nil tags. - - // use named receiver type if available (for better error messages) - var recvTyp Type = iface - if def != nil { - recvTyp = def - } - - // Phase 1: Collect explicitly declared methods, the corresponding - // signature (AST) expressions, and the list of embedded - // type (AST) expressions. Do not resolve signatures or - // embedded types yet to avoid cycles referring to this - // interface. - - var ( - mset objset - signatures []ast.Expr // list of corresponding method signatures - embedded []ast.Expr // list of embedded types - ) - for _, f := range ityp.Methods.List { - if len(f.Names) > 0 { - // The parser ensures that there's only one method - // and we don't care if a constructed AST has more. - name := f.Names[0] - pos := name.Pos() - // spec: "As with all method sets, in an interface type, - // each method must have a unique non-blank name." - if name.Name == "_" { - check.errorf(pos, "invalid method name _") - continue - } - // Don't type-check signature yet - use an - // empty signature now and update it later. - // Since we know the receiver, set it up now - // (required to avoid crash in ptrRecv; see - // e.g. test case for issue 6638). - // TODO(gri) Consider marking methods signatures - // as incomplete, for better error messages. See - // also the T4 and T5 tests in testdata/cycles2.src. - sig := new(Signature) - sig.recv = NewVar(pos, check.pkg, "", recvTyp) - m := NewFunc(pos, check.pkg, name.Name, sig) - if check.declareInSet(&mset, pos, m) { - iface.methods = append(iface.methods, m) - iface.allMethods = append(iface.allMethods, m) - signatures = append(signatures, f.Type) - check.recordDef(name, m) - } - } else { - // embedded type - embedded = append(embedded, f.Type) - } - } - - // Phase 2: Resolve embedded interfaces. Because an interface must not - // embed itself (directly or indirectly), each embedded interface - // can be fully resolved without depending on any method of this - // interface (if there is a cycle or another error, the embedded - // type resolves to an invalid type and is ignored). - // In particular, the list of methods for each embedded interface - // must be complete (it cannot depend on this interface), and so - // those methods can be added to the list of all methods of this - // interface. - - for _, e := range embedded { - pos := e.Pos() - typ := check.typExpr(e, nil, path) - // Determine underlying embedded (possibly incomplete) type - // by following its forward chain. - named, _ := typ.(*Named) - under := underlying(named) - embed, _ := under.(*Interface) - if embed == nil { - if typ != Typ[Invalid] { - check.errorf(pos, "%s is not an interface", typ) - } - continue - } - iface.embeddeds = append(iface.embeddeds, named) - // collect embedded methods - for _, m := range embed.allMethods { - if check.declareInSet(&mset, pos, m) { - iface.allMethods = append(iface.allMethods, m) - } - } - } - - // Phase 3: At this point all methods have been collected for this interface. - // It is now safe to type-check the signatures of all explicitly - // declared methods, even if they refer to this interface via a cycle - // and embed the methods of this interface in a parameter of interface - // type. - - for i, m := range iface.methods { - expr := signatures[i] - typ := check.typ(expr) - sig, _ := typ.(*Signature) - if sig == nil { - if typ != Typ[Invalid] { - check.invalidAST(expr.Pos(), "%s is not a method signature", typ) - } - continue // keep method with empty method signature - } - // update signature, but keep recv that was set up before - old := m.typ.(*Signature) - sig.recv = old.recv - *old = *sig // update signature (don't replace it!) - } - - // TODO(gri) The list of explicit methods is only sorted for now to - // produce the same Interface as NewInterface. We may be able to - // claim source order in the future. Revisit. - sort.Sort(byUniqueMethodName(iface.methods)) - - // TODO(gri) The list of embedded types is only sorted for now to - // produce the same Interface as NewInterface. We may be able to - // claim source order in the future. Revisit. - sort.Sort(byUniqueTypeName(iface.embeddeds)) - - sort.Sort(byUniqueMethodName(iface.allMethods)) -} - -// byUniqueTypeName named type lists can be sorted by their unique type names. -type byUniqueTypeName []*Named - -func (a byUniqueTypeName) Len() int { return len(a) } -func (a byUniqueTypeName) Less(i, j int) bool { return a[i].obj.Id() < a[j].obj.Id() } -func (a byUniqueTypeName) Swap(i, j int) { a[i], a[j] = a[j], a[i] } - -// byUniqueMethodName method lists can be sorted by their unique method names. -type byUniqueMethodName []*Func - -func (a byUniqueMethodName) Len() int { return len(a) } -func (a byUniqueMethodName) Less(i, j int) bool { return a[i].Id() < a[j].Id() } -func (a byUniqueMethodName) Swap(i, j int) { a[i], a[j] = a[j], a[i] } - -func (check *Checker) tag(t *ast.BasicLit) string { - if t != nil { - if t.Kind == token.STRING { - if val, err := strconv.Unquote(t.Value); err == nil { - return val - } - } - check.invalidAST(t.Pos(), "incorrect tag syntax: %q", t.Value) - } - return "" -} - -func (check *Checker) structType(styp *Struct, e *ast.StructType, path []*TypeName) { - list := e.Fields - if list == nil { - return - } - - // struct fields and tags - var fields []*Var - var tags []string - - // for double-declaration checks - var fset objset - - // current field typ and tag - var typ Type - var tag string - // anonymous != nil indicates an anonymous field. - add := func(field *ast.Field, ident *ast.Ident, anonymous *TypeName, pos token.Pos) { - if tag != "" && tags == nil { - tags = make([]string, len(fields)) - } - if tags != nil { - tags = append(tags, tag) - } - - name := ident.Name - fld := NewField(pos, check.pkg, name, typ, anonymous != nil) - // spec: "Within a struct, non-blank field names must be unique." - if name == "_" || check.declareInSet(&fset, pos, fld) { - fields = append(fields, fld) - check.recordDef(ident, fld) - } - if anonymous != nil { - check.recordUse(ident, anonymous) - } - } - - for _, f := range list.List { - typ = check.typExpr(f.Type, nil, path) - tag = check.tag(f.Tag) - if len(f.Names) > 0 { - // named fields - for _, name := range f.Names { - add(f, name, nil, name.Pos()) - } - } else { - // anonymous field - name := anonymousFieldIdent(f.Type) - pos := f.Type.Pos() - t, isPtr := deref(typ) - switch t := t.(type) { - case *Basic: - if t == Typ[Invalid] { - // error was reported before - continue - } - // unsafe.Pointer is treated like a regular pointer - if t.kind == UnsafePointer { - check.errorf(pos, "anonymous field type cannot be unsafe.Pointer") - continue - } - add(f, name, Universe.Lookup(t.name).(*TypeName), pos) - - case *Named: - // spec: "An embedded type must be specified as a type name - // T or as a pointer to a non-interface type name *T, and T - // itself may not be a pointer type." - switch u := t.underlying.(type) { - case *Basic: - // unsafe.Pointer is treated like a regular pointer - if u.kind == UnsafePointer { - check.errorf(pos, "anonymous field type cannot be unsafe.Pointer") - continue - } - case *Pointer: - check.errorf(pos, "anonymous field type cannot be a pointer") - continue - case *Interface: - if isPtr { - check.errorf(pos, "anonymous field type cannot be a pointer to an interface") - continue - } - } - add(f, name, t.obj, pos) - - default: - check.invalidAST(pos, "anonymous field type %s must be named", typ) - } - } - } - - styp.fields = fields - styp.tags = tags -} - -func anonymousFieldIdent(e ast.Expr) *ast.Ident { - switch e := e.(type) { - case *ast.Ident: - return e - case *ast.StarExpr: - return anonymousFieldIdent(e.X) - case *ast.SelectorExpr: - return e.Sel - } - return nil // invalid anonymous field -} diff --git a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/universe.go b/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/universe.go deleted file mode 100644 index 12a34ef8539..00000000000 --- a/awsmigrate/awsmigrate-renamer/vendor/golang.org/x/tools/go/types/universe.go +++ /dev/null @@ -1,224 +0,0 @@ -// Copyright 2011 The Go Authors. All rights reserved. -// Use of this source code is governed by a BSD-style -// license that can be found in the LICENSE file. - -// This file sets up the universe scope and the unsafe package. - -package types - -import ( - "go/token" - "strings" - - "golang.org/x/tools/go/exact" -) - -var ( - Universe *Scope - Unsafe *Package - universeIota *Const - universeByte *Basic // uint8 alias, but has name "byte" - universeRune *Basic // int32 alias, but has name "rune" -) - -var Typ = []*Basic{ - Invalid: {Invalid, 0, "invalid type"}, - - Bool: {Bool, IsBoolean, "bool"}, - Int: {Int, IsInteger, "int"}, - Int8: {Int8, IsInteger, "int8"}, - Int16: {Int16, IsInteger, "int16"}, - Int32: {Int32, IsInteger, "int32"}, - Int64: {Int64, IsInteger, "int64"}, - Uint: {Uint, IsInteger | IsUnsigned, "uint"}, - Uint8: {Uint8, IsInteger | IsUnsigned, "uint8"}, - Uint16: {Uint16, IsInteger | IsUnsigned, "uint16"}, - Uint32: {Uint32, IsInteger | IsUnsigned, "uint32"}, - Uint64: {Uint64, IsInteger | IsUnsigned, "uint64"}, - Uintptr: {Uintptr, IsInteger | IsUnsigned, "uintptr"}, - Float32: {Float32, IsFloat, "float32"}, - Float64: {Float64, IsFloat, "float64"}, - Complex64: {Complex64, IsComplex, "complex64"}, - Complex128: {Complex128, IsComplex, "complex128"}, - String: {String, IsString, "string"}, - UnsafePointer: {UnsafePointer, 0, "Pointer"}, - - UntypedBool: {UntypedBool, IsBoolean | IsUntyped, "untyped bool"}, - UntypedInt: {UntypedInt, IsInteger | IsUntyped, "untyped int"}, - UntypedRune: {UntypedRune, IsInteger | IsUntyped, "untyped rune"}, - UntypedFloat: {UntypedFloat, IsFloat | IsUntyped, "untyped float"}, - UntypedComplex: {UntypedComplex, IsComplex | IsUntyped, "untyped complex"}, - UntypedString: {UntypedString, IsString | IsUntyped, "untyped string"}, - UntypedNil: {UntypedNil, IsUntyped, "untyped nil"}, -} - -var aliases = [...]*Basic{ - {Byte, IsInteger | IsUnsigned, "byte"}, - {Rune, IsInteger, "rune"}, -} - -func defPredeclaredTypes() { - for _, t := range Typ { - def(NewTypeName(token.NoPos, nil, t.name, t)) - } - for _, t := range aliases { - def(NewTypeName(token.NoPos, nil, t.name, t)) - } - - // Error has a nil package in its qualified name since it is in no package - res := NewVar(token.NoPos, nil, "", Typ[String]) - sig := &Signature{results: NewTuple(res)} - err := NewFunc(token.NoPos, nil, "Error", sig) - typ := &Named{underlying: NewInterface([]*Func{err}, nil).Complete()} - sig.recv = NewVar(token.NoPos, nil, "", typ) - def(NewTypeName(token.NoPos, nil, "error", typ)) -} - -var predeclaredConsts = [...]struct { - name string - kind BasicKind - val exact.Value -}{ - {"true", UntypedBool, exact.MakeBool(true)}, - {"false", UntypedBool, exact.MakeBool(false)}, - {"iota", UntypedInt, exact.MakeInt64(0)}, -} - -func defPredeclaredConsts() { - for _, c := range predeclaredConsts { - def(NewConst(token.NoPos, nil, c.name, Typ[c.kind], c.val)) - } -} - -func defPredeclaredNil() { - def(&Nil{object{name: "nil", typ: Typ[UntypedNil]}}) -} - -// A builtinId is the id of a builtin function. -type builtinId int - -const ( - // universe scope - _Append builtinId = iota - _Cap - _Close - _Complex - _Copy - _Delete - _Imag - _Len - _Make - _New - _Panic - _Print - _Println - _Real - _Recover - - // package unsafe - _Alignof - _Offsetof - _Sizeof - - // testing support - _Assert - _Trace -) - -var predeclaredFuncs = [...]struct { - name string - nargs int - variadic bool - kind exprKind -}{ - _Append: {"append", 1, true, expression}, - _Cap: {"cap", 1, false, expression}, - _Close: {"close", 1, false, statement}, - _Complex: {"complex", 2, false, expression}, - _Copy: {"copy", 2, false, statement}, - _Delete: {"delete", 2, false, statement}, - _Imag: {"imag", 1, false, expression}, - _Len: {"len", 1, false, expression}, - _Make: {"make", 1, true, expression}, - _New: {"new", 1, false, expression}, - _Panic: {"panic", 1, false, statement}, - _Print: {"print", 0, true, statement}, - _Println: {"println", 0, true, statement}, - _Real: {"real", 1, false, expression}, - _Recover: {"recover", 0, false, statement}, - - _Alignof: {"Alignof", 1, false, expression}, - _Offsetof: {"Offsetof", 1, false, expression}, - _Sizeof: {"Sizeof", 1, false, expression}, - - _Assert: {"assert", 1, false, statement}, - _Trace: {"trace", 0, true, statement}, -} - -func defPredeclaredFuncs() { - for i := range predeclaredFuncs { - id := builtinId(i) - if id == _Assert || id == _Trace { - continue // only define these in testing environment - } - def(newBuiltin(id)) - } -} - -// DefPredeclaredTestFuncs defines the assert and trace built-ins. -// These built-ins are intended for debugging and testing of this -// package only. -func DefPredeclaredTestFuncs() { - if Universe.Lookup("assert") != nil { - return // already defined - } - def(newBuiltin(_Assert)) - def(newBuiltin(_Trace)) -} - -func init() { - Universe = NewScope(nil, token.NoPos, token.NoPos, "universe") - Unsafe = NewPackage("unsafe", "unsafe") - Unsafe.complete = true - - defPredeclaredTypes() - defPredeclaredConsts() - defPredeclaredNil() - defPredeclaredFuncs() - - universeIota = Universe.Lookup("iota").(*Const) - universeByte = Universe.Lookup("byte").(*TypeName).typ.(*Basic) - universeRune = Universe.Lookup("rune").(*TypeName).typ.(*Basic) -} - -// Objects with names containing blanks are internal and not entered into -// a scope. Objects with exported names are inserted in the unsafe package -// scope; other objects are inserted in the universe scope. -// -func def(obj Object) { - name := obj.Name() - if strings.Index(name, " ") >= 0 { - return // nothing to do - } - // fix Obj link for named types - if typ, ok := obj.Type().(*Named); ok { - typ.obj = obj.(*TypeName) - } - // exported identifiers go into package unsafe - scope := Universe - if obj.Exported() { - scope = Unsafe.scope - // set Pkg field - switch obj := obj.(type) { - case *TypeName: - obj.pkg = Unsafe - case *Builtin: - obj.pkg = Unsafe - default: - unreachable() - } - } - if scope.Insert(obj) != nil { - panic("internal error: double declaration") - } -} diff --git a/awstesting/sandbox/Dockerfile.test-no15exp.go1.5 b/awstesting/sandbox/Dockerfile.test-no15exp.go1.5 new file mode 100644 index 00000000000..9ec9f169d72 --- /dev/null +++ b/awstesting/sandbox/Dockerfile.test-no15exp.go1.5 @@ -0,0 +1,7 @@ +FROM ubuntu:12.04 +FROM golang:1.5 + +ADD . /go/src/github.com/aws/aws-sdk-go + +WORKDIR /go/src/github.com/aws/aws-sdk-go +CMD ["make", "get-deps", "unit"]