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c_api_sample.rs
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c_api_sample.rs
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#![allow(non_snake_case)]
use std::env::args;
#[cfg(not(target_family = "windows"))]
use std::os::unix::ffi::OsStrExt;
#[cfg(target_family = "windows")]
use std::os::windows::ffi::OsStrExt;
use onnxruntime_sys::{
onnxruntime, GraphOptimizationLevel, ONNXTensorElementDataType, OrtAllocator, OrtAllocatorType,
OrtApi, OrtEnv, OrtLoggingLevel, OrtMemType, OrtMemoryInfo, OrtRunOptions, OrtSession,
OrtSessionOptions, OrtStatus, OrtTensorTypeAndShapeInfo, OrtTypeInfo, OrtValue,
ORT_API_VERSION,
};
// https://github.com/microsoft/onnxruntime/blob/v1.4.0/csharp/test/Microsoft.ML.OnnxRuntime.EndToEndTests.Capi/C_Api_Sample.cpp
fn main() {
let onnxruntime_path = args()
.nth(1)
.expect("This example expects a path to the ONNXRuntime shared library");
let (_, g_ort) = unsafe {
let ort = onnxruntime::new(onnxruntime_path);
let ort = ort.expect("Error initializing onnxruntime");
let g_ort = ort.OrtGetApiBase().as_ref().unwrap().GetApi.unwrap()(ORT_API_VERSION);
(ort, g_ort)
};
assert_ne!(g_ort, std::ptr::null_mut());
//*************************************************************************
// initialize enviroment...one enviroment per process
// enviroment maintains thread pools and other state info
let mut env_ptr: *mut OrtEnv = std::ptr::null_mut();
let env_name = std::ffi::CString::new("test").unwrap();
let status = unsafe {
g_ort.as_ref().unwrap().CreateEnv.unwrap()(
OrtLoggingLevel::ORT_LOGGING_LEVEL_VERBOSE,
env_name.as_ptr(),
&mut env_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(env_ptr, std::ptr::null_mut());
// initialize session options if needed
let mut session_options_ptr: *mut OrtSessionOptions = std::ptr::null_mut();
let status =
unsafe { g_ort.as_ref().unwrap().CreateSessionOptions.unwrap()(&mut session_options_ptr) };
CheckStatus(g_ort, status).unwrap();
unsafe { g_ort.as_ref().unwrap().SetIntraOpNumThreads.unwrap()(session_options_ptr, 1) };
assert_ne!(session_options_ptr, std::ptr::null_mut());
// Sets graph optimization level
unsafe {
g_ort
.as_ref()
.unwrap()
.SetSessionGraphOptimizationLevel
.unwrap()(
session_options_ptr,
GraphOptimizationLevel::ORT_ENABLE_BASIC,
)
};
// Optionally add more execution providers via session_options
// E.g. for CUDA include cuda_provider_factory.h and uncomment the following line:
// OrtSessionOptionsAppendExecutionProvider_CUDA(sessionOptions, 0);
//*************************************************************************
// create session and load model into memory
// NOTE: Original C version loaded SqueezeNet 1.0 (ONNX version: 1.3, Opset version: 8,
// https://github.com/onnx/models/blob/main/vision/classification/squeezenet/model/squeezenet1.0-8.onnx)
// Download it:
// curl -LO "https://github.com/onnx/models/raw/main/vision/classification/squeezenet/model/squeezenet1.0-8.onnx"
// Reference: https://github.com/onnx/models/tree/main/vision/classification/squeezenet#model
let model_path = std::ffi::OsString::from("squeezenet1.0-8.onnx");
#[cfg(target_family = "windows")]
let model_path: Vec<u16> = model_path
.encode_wide()
.chain(std::iter::once(0)) // Make sure we have a null terminated string
.collect();
#[cfg(not(target_family = "windows"))]
let model_path: Vec<std::os::raw::c_char> = model_path
.as_bytes()
.iter()
.chain(std::iter::once(&b'\0')) // Make sure we have a null terminated string
.map(|b| *b as std::os::raw::c_char)
.collect();
let mut session_ptr: *mut OrtSession = std::ptr::null_mut();
println!("Using Onnxruntime C API");
let status = unsafe {
g_ort.as_ref().unwrap().CreateSession.unwrap()(
env_ptr,
model_path.as_ptr(),
session_options_ptr,
&mut session_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(session_ptr, std::ptr::null_mut());
//*************************************************************************
// print model input layer (node names, types, shape etc.)
// size_t num_input_nodes;
let mut allocator_ptr: *mut OrtAllocator = std::ptr::null_mut();
let status = unsafe {
g_ort
.as_ref()
.unwrap()
.GetAllocatorWithDefaultOptions
.unwrap()(&mut allocator_ptr)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(allocator_ptr, std::ptr::null_mut());
// print number of model input nodes
let mut num_input_nodes: usize = 0;
let status = unsafe {
g_ort.as_ref().unwrap().SessionGetInputCount.unwrap()(session_ptr, &mut num_input_nodes)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(num_input_nodes, 0);
println!("Number of inputs = {:?}", num_input_nodes);
let mut input_node_names: Vec<&str> = Vec::new();
let mut input_node_dims: Vec<i64> = Vec::new(); // simplify... this model has only 1 input node {1, 3, 224, 224}.
// Otherwise need vector<vector<>>
// iterate over all input nodes
for i in 0..num_input_nodes {
// print input node names
let mut input_name: *mut i8 = std::ptr::null_mut();
let status = unsafe {
g_ort.as_ref().unwrap().SessionGetInputName.unwrap()(
session_ptr,
i,
allocator_ptr,
&mut input_name,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(input_name, std::ptr::null_mut());
// WARNING: The C function SessionGetInputName allocates memory for the string.
// We cannot let Rust free that string, the C side must free the string.
// We thus convert the pointer to a string slice (&str).
let input_name = char_p_to_str(input_name).unwrap();
println!("Input {} : name={}", i, input_name);
input_node_names.push(input_name);
// print input node types
let mut typeinfo_ptr: *mut OrtTypeInfo = std::ptr::null_mut();
let status = unsafe {
g_ort.as_ref().unwrap().SessionGetInputTypeInfo.unwrap()(
session_ptr,
i,
&mut typeinfo_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(typeinfo_ptr, std::ptr::null_mut());
let mut tensor_info_ptr: *const OrtTensorTypeAndShapeInfo = std::ptr::null_mut();
let status = unsafe {
g_ort.as_ref().unwrap().CastTypeInfoToTensorInfo.unwrap()(
typeinfo_ptr,
&mut tensor_info_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(tensor_info_ptr, std::ptr::null_mut());
let mut type_: ONNXTensorElementDataType =
ONNXTensorElementDataType::ONNX_TENSOR_ELEMENT_DATA_TYPE_UNDEFINED;
let status = unsafe {
g_ort.as_ref().unwrap().GetTensorElementType.unwrap()(tensor_info_ptr, &mut type_)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(
type_,
ONNXTensorElementDataType::ONNX_TENSOR_ELEMENT_DATA_TYPE_UNDEFINED
);
println!("Input {} : type={}", i, type_ as i32);
// print input shapes/dims
let mut num_dims = 0;
let status = unsafe {
g_ort.as_ref().unwrap().GetDimensionsCount.unwrap()(tensor_info_ptr, &mut num_dims)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(num_dims, 0);
println!("Input {} : num_dims={}", i, num_dims);
input_node_dims.resize_with(num_dims as usize, Default::default);
let status = unsafe {
g_ort.as_ref().unwrap().GetDimensions.unwrap()(
tensor_info_ptr,
input_node_dims.as_mut_ptr(),
num_dims,
)
};
CheckStatus(g_ort, status).unwrap();
for j in 0..num_dims {
println!("Input {} : dim {}={}", i, j, input_node_dims[j as usize]);
}
unsafe { g_ort.as_ref().unwrap().ReleaseTypeInfo.unwrap()(typeinfo_ptr) };
}
// Results should be...
// Number of inputs = 1
// Input 0 : name = data_0
// Input 0 : type = 1
// Input 0 : num_dims = 4
// Input 0 : dim 0 = 1
// Input 0 : dim 1 = 3
// Input 0 : dim 2 = 224
// Input 0 : dim 3 = 224
//*************************************************************************
// Similar operations to get output node information.
// Use OrtSessionGetOutputCount(), OrtSessionGetOutputName()
// OrtSessionGetOutputTypeInfo() as shown above.
//*************************************************************************
// Score the model using sample data, and inspect values
let input_tensor_size = 224 * 224 * 3; // simplify ... using known dim values to calculate size
// use OrtGetTensorShapeElementCount() to get official size!
let output_node_names = &["softmaxout_1"];
// initialize input data with values in [0.0, 1.0]
let mut input_tensor_values: Vec<f32> = (0..input_tensor_size)
.map(|i| (i as f32) / ((input_tensor_size + 1) as f32))
.collect();
// create input tensor object from data values
let mut memory_info_ptr: *mut OrtMemoryInfo = std::ptr::null_mut();
let status = unsafe {
g_ort.as_ref().unwrap().CreateCpuMemoryInfo.unwrap()(
OrtAllocatorType::OrtArenaAllocator,
OrtMemType::OrtMemTypeDefault,
&mut memory_info_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(memory_info_ptr, std::ptr::null_mut());
// FIXME: Check me!
let mut input_tensor_ptr: *mut OrtValue = std::ptr::null_mut();
let input_tensor_ptr_ptr: *mut *mut OrtValue = &mut input_tensor_ptr;
let input_tensor_values_ptr: *mut std::ffi::c_void =
input_tensor_values.as_mut_ptr().cast::<std::ffi::c_void>();
assert_ne!(input_tensor_values_ptr, std::ptr::null_mut());
let shape: *const i64 = input_node_dims.as_ptr();
assert_ne!(shape, std::ptr::null_mut());
let status = unsafe {
g_ort
.as_ref()
.unwrap()
.CreateTensorWithDataAsOrtValue
.unwrap()(
memory_info_ptr,
input_tensor_values_ptr,
input_tensor_size * std::mem::size_of::<f32>(),
shape,
4,
ONNXTensorElementDataType::ONNX_TENSOR_ELEMENT_DATA_TYPE_FLOAT,
input_tensor_ptr_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(input_tensor_ptr, std::ptr::null_mut());
let mut is_tensor = 0;
let status =
unsafe { g_ort.as_ref().unwrap().IsTensor.unwrap()(input_tensor_ptr, &mut is_tensor) };
CheckStatus(g_ort, status).unwrap();
assert_eq!(is_tensor, 1);
let input_tensor_ptr2: *const OrtValue = input_tensor_ptr as *const OrtValue;
let input_tensor_ptr3: *const *const OrtValue = &input_tensor_ptr2;
unsafe { g_ort.as_ref().unwrap().ReleaseMemoryInfo.unwrap()(memory_info_ptr) };
// score model & input tensor, get back output tensor
let input_node_names_cstring: Vec<std::ffi::CString> = input_node_names
.into_iter()
.map(|n| std::ffi::CString::new(n).unwrap())
.collect();
let input_node_names_ptr: Vec<*const i8> = input_node_names_cstring
.into_iter()
.map(|n| n.into_raw() as *const i8)
.collect();
let input_node_names_ptr_ptr: *const *const i8 = input_node_names_ptr.as_ptr();
let output_node_names_cstring: Vec<std::ffi::CString> = output_node_names
.iter()
.map(|n| std::ffi::CString::new(*n).unwrap())
.collect();
let output_node_names_ptr: Vec<*const i8> = output_node_names_cstring
.iter()
.map(|n| n.as_ptr().cast::<i8>())
.collect();
let output_node_names_ptr_ptr: *const *const i8 = output_node_names_ptr.as_ptr();
let _input_node_names_cstring =
unsafe { std::ffi::CString::from_raw(input_node_names_ptr[0] as *mut i8) };
let run_options_ptr: *const OrtRunOptions = std::ptr::null();
let mut output_tensor_ptr: *mut OrtValue = std::ptr::null_mut();
let output_tensor_ptr_ptr: *mut *mut OrtValue = &mut output_tensor_ptr;
let status = unsafe {
g_ort.as_ref().unwrap().Run.unwrap()(
session_ptr,
run_options_ptr,
input_node_names_ptr_ptr,
input_tensor_ptr3,
1,
output_node_names_ptr_ptr,
1,
output_tensor_ptr_ptr,
)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(output_tensor_ptr, std::ptr::null_mut());
let mut is_tensor = 0;
let status =
unsafe { g_ort.as_ref().unwrap().IsTensor.unwrap()(output_tensor_ptr, &mut is_tensor) };
CheckStatus(g_ort, status).unwrap();
assert_eq!(is_tensor, 1);
// Get pointer to output tensor float values
let mut floatarr: *mut f32 = std::ptr::null_mut();
let floatarr_ptr: *mut *mut f32 = &mut floatarr;
let floatarr_ptr_void: *mut *mut std::ffi::c_void =
floatarr_ptr.cast::<*mut std::ffi::c_void>();
let status = unsafe {
g_ort.as_ref().unwrap().GetTensorMutableData.unwrap()(output_tensor_ptr, floatarr_ptr_void)
};
CheckStatus(g_ort, status).unwrap();
assert_ne!(floatarr, std::ptr::null_mut());
assert!((unsafe { *floatarr.offset(0) } - 0.000_045).abs() < 1e-6);
// score the model, and print scores for first 5 classes
// NOTE: The C ONNX Runtime allocated the array, we shouldn't drop the vec
// but let C de-allocate instead.
let floatarr_vec: Vec<f32> = unsafe { Vec::from_raw_parts(floatarr, 5, 5) };
for i in 0..5 {
println!("Score for class [{}] = {}", i, floatarr_vec[i]);
}
std::mem::forget(floatarr_vec);
// Results should be as below...
// Score for class[0] = 0.000045
// Score for class[1] = 0.003846
// Score for class[2] = 0.000125
// Score for class[3] = 0.001180
// Score for class[4] = 0.001317
unsafe { g_ort.as_ref().unwrap().ReleaseValue.unwrap()(output_tensor_ptr) };
unsafe { g_ort.as_ref().unwrap().ReleaseValue.unwrap()(input_tensor_ptr) };
unsafe { g_ort.as_ref().unwrap().ReleaseSession.unwrap()(session_ptr) };
unsafe { g_ort.as_ref().unwrap().ReleaseSessionOptions.unwrap()(session_options_ptr) };
unsafe { g_ort.as_ref().unwrap().ReleaseEnv.unwrap()(env_ptr) };
println!("Done!");
}
fn CheckStatus(g_ort: *const OrtApi, status: *const OrtStatus) -> Result<(), String> {
if status != std::ptr::null() {
let raw = unsafe { g_ort.as_ref().unwrap().GetErrorMessage.unwrap()(status) };
Err(char_p_to_str(raw).unwrap().to_string())
} else {
Ok(())
}
}
fn char_p_to_str<'a>(raw: *const i8) -> Result<&'a str, std::str::Utf8Error> {
let c_str = unsafe { std::ffi::CStr::from_ptr(raw as *mut i8) };
c_str.to_str()
}