All this workspace has been moved into https://github.com/0xPolygonZero/zk_evm.
Please refer to this new location for inquiries or contributions.
A composition of paladin
and plonky-block-proof-gen
. Given the proof generation protocol as input, generate a proof. The project is instrumented with paladin
, and as such can distribute proof generation across multiple worker machines.
- Zero Bin
ops
├── Cargo.toml
└── src
└── lib.rs
worker
├── Cargo.toml
└── src
└── main.rs
leader
├── Cargo.toml
└── src
└── main.rs
rpc
├── Cargo.toml
└── src
└── main.rs
verifier
├── Cargo.toml
└── src
└── main.rs
Defines the proof operations that can be distributed to workers.
The worker process. Receives proof operations from the leader, and returns the result.
The leader process. Receives proof generation requests, and distributes them to workers.
A binary to generate the block trace format expected by the leader.
A binary to verify the correctness of the generated proof.
The leader has various subcommands for different io modes. The leader binary arguments are as follows:
cargo r --release --bin leader -- --help
Usage: leader [OPTIONS] <COMMAND>
Commands:
stdio Reads input from stdin and writes output to stdout
jerigon Reads input from a Jerigon node and writes output to stdout
native Reads input from a native node and writes output to stdout
http Reads input from HTTP and writes output to a directory
help Print this message or the help of the given subcommand(s)
Options:
-h, --help
Print help (see a summary with '-h')
Paladin options:
-t, --task-bus-routing-key <TASK_BUS_ROUTING_KEY>
Specifies the routing key for publishing task messages. In most cases, the default value should suffice
[default: task]
-s, --serializer <SERIALIZER>
Determines the serialization format to be used
[default: postcard]
[possible values: postcard, cbor]
-r, --runtime <RUNTIME>
Specifies the runtime environment to use
[default: amqp]
[possible values: amqp, in-memory]
-n, --num-workers <NUM_WORKERS>
Specifies the number of worker threads to spawn (in memory runtime only)
--amqp-uri <AMQP_URI>
Provides the URI for the AMQP broker, if the AMQP runtime is selected
[env: AMQP_URI=amqp://localhost:5672]
Table circuit sizes:
--persistence <PERSISTENCE>
[default: disk]
Possible values:
- none: Do not persist the processed circuits
- disk: Persist the processed circuits to disk
--arithmetic <CIRCUIT_BIT_RANGE>
The min/max size for the arithmetic table circuit.
[env: ARITHMETIC_CIRCUIT_SIZE=16..22]
--byte-packing <CIRCUIT_BIT_RANGE>
The min/max size for the byte packing table circuit.
[env: BYTE_PACKING_CIRCUIT_SIZE=10..22]
--cpu <CIRCUIT_BIT_RANGE>
The min/max size for the cpu table circuit.
[env: CPU_CIRCUIT_SIZE=15..22]
--keccak <CIRCUIT_BIT_RANGE>
The min/max size for the keccak table circuit.
[env: KECCAK_CIRCUIT_SIZE=14..22]
--keccak-sponge <CIRCUIT_BIT_RANGE>
The min/max size for the keccak sponge table circuit.
[env: KECCAK_SPONGE_CIRCUIT_SIZE=9..22]
--logic <CIRCUIT_BIT_RANGE>
The min/max size for the logic table circuit.
[env: LOGIC_CIRCUIT_SIZE=12..22]
--memory <CIRCUIT_BIT_RANGE>
The min/max size for the memory table circuit.
[env: MEMORY_CIRCUIT_SIZE=18..22]
Note that both paladin and plonky2 table circuit sizes are configurable via command line arguments and environment variables. The command line arguments take precedence over the environment variables.
TABLE CIRCUIT SIZES ARE ONLY RELEVANT FOR THE LEADER WHEN RUNNING IN in-memory
MODE.
If you want to configure the table circuit sizes when running in a distributed environment, you must configure the table circuit sizes on the worker processes (the command line arguments are the same).
The stdio command reads proof input from stdin and writes output to stdout.
cargo r --release --bin leader stdio --help
Reads input from stdin and writes output to stdout
Usage: leader stdio [OPTIONS]
Options:
-f, --previous-proof <PREVIOUS_PROOF> The previous proof output
-h, --help Print help
Pull prover input from the rpc binary.
cargo r --release --bin rpc fetch --rpc-url <RPC_URL> -b 6 > ./input/block_6.json
Pipe the block input to the leader binary.
cat ./input/block_6.json | cargo r --release --bin leader -- -r in-memory stdio > ./output/proof_6.json
The Jerigon command reads proof input from a Jerigon node and writes output to stdout.
cargo r --release --bin leader jerigon --help
Reads input from a Jerigon node and writes output to stdout
Usage: leader jerigon [OPTIONS] --rpc-url <RPC_URL> --block-interval <BLOCK_INTERVAL>
Options:
-u, --rpc-url <RPC_URL>
-i, --block-interval <BLOCK_INTERVAL>
The block interval for which to generate a proof
-c, --checkpoint-block-number <CHECKPOINT_BLOCK_NUMBER>
The checkpoint block number [default: 0]
-f, --previous-proof <PREVIOUS_PROOF>
The previous proof output
-o, --proof-output-dir <PROOF_OUTPUT_DIR>
If provided, write the generated proofs to this directory instead of stdout
-s, --save-inputs-on-error
If true, save the public inputs to disk on error
-b, --block-time <BLOCK_TIME>
Network block time in milliseconds. This value is used to determine the blockchain node polling interval [env: ZERO_BIN_BLOCK_TIME=] [default: 2000]
-k, --keep-intermediate-proofs
Keep intermediate proofs. Default action is to delete them after the final proof is generated [env: ZERO_BIN_KEEP_INTERMEDIATE_PROOFS=]
--backoff <BACKOFF>
Backoff in milliseconds for request retries [default: 0]
--max-retries <MAX_RETRIES>
The maximum number of retries [default: 0]
-h, --help
Print help
Prove a block.
cargo r --release --bin leader -- -r in-memory jerigon -u <RPC_URL> -b 16 > ./output/proof_16.json
The native command reads proof input from a native node and writes output to stdout.
cargo r --release --bin leader native --help
Reads input from a native node and writes output to stdout
Usage: leader native [OPTIONS] --rpc-url <RPC_URL> --block-interval <BLOCK_INTERVAL>
Options:
-u, --rpc-url <RPC_URL>
-i, --block-interval <BLOCK_INTERVAL>
The block interval for which to generate a proof
-c, --checkpoint-block-number <CHECKPOINT_BLOCK_NUMBER>
The checkpoint block number [default: 0]
-f, --previous-proof <PREVIOUS_PROOF>
The previous proof output
-o, --proof-output-dir <PROOF_OUTPUT_DIR>
If provided, write the generated proofs to this directory instead of stdout
-s, --save-inputs-on-error
If true, save the public inputs to disk on error
-b, --block-time <BLOCK_TIME>
Network block time in milliseconds. This value is used to determine the blockchain node polling interval [env: ZERO_BIN_BLOCK_TIME=] [default: 2000]
-k, --keep-intermediate-proofs
Keep intermediate proofs. Default action is to delete them after the final proof is generated [env: ZERO_BIN_KEEP_INTERMEDIATE_PROOFS=]
--backoff <BACKOFF>
Backoff in milliseconds for request retries [default: 0]
--max-retries <MAX_RETRIES>
The maximum number of retries [default: 0]
-h, --help
Print help
Prove a block.
cargo r --release --bin leader -- -r in-memory native -u <RPC_URL> -b 16 > ./output/proof_16.json
The HTTP command reads proof input from HTTP and writes output to a directory.
cargo r --release --bin leader http --help
Reads input from HTTP and writes output to a directory
Usage: leader http [OPTIONS] --output-dir <OUTPUT_DIR>
Options:
-p, --port <PORT> The port on which to listen [default: 8080]
-o, --output-dir <OUTPUT_DIR> The directory to which output should be written
-h, --help Print help
Pull prover input from the rpc binary.
cargo r --release --bin rpc fetch -u <RPC_URL> -b 6 > ./input/block_6.json
Start the server.
RUST_LOG=debug cargo r --release --bin leader http --output-dir ./output
Note that HTTP mode requires a slightly modified input format from the rest of the commands. In particular, the previous proof is expected to be part of the payload. This is due to the fact that the HTTP mode may handle multiple requests concurrently, and thus the previous proof cannot reasonably be given by a command line argument like the other modes.
Using jq
we can merge the previous proof and the block input into a single JSON object.
jq -s '{prover_input: .[0], previous: .[1]}' ./input/block_6.json ./output/proof_5.json | curl -X POST -H "Content-Type: application/json" -d @- http://localhost:8080/prove
Paladin supports both an AMQP and in-memory runtime. The in-memory runtime will emulate a cluster in memory within a single process, and is useful for testing. The AMQP runtime is geared for a production environment. The AMQP runtime requires a running AMQP broker and spinning up worker processes. The AMQP uri can be specified with the --amqp-uri
flag or be set with the AMQP_URI
environment variable.
Start rabbitmq
docker run --name rabbitmq -p 5672:5672 -p 15672:15672 rabbitmq:3-management
Start worker process(es). The default paladin runtime is AMQP, so no additional flags are required to enable it.
RUST_LOG=debug cargo r --release --bin worker
Start the leader process with the desired command. The default paladin runtime is AMQP, so no additional flags are required to enable it.
RUST_LOG=debug cargo r --release --bin leader jerigon -u <RPC_URL> -b 16 > ./output/proof_16.json
Paladin can emulate a cluster in memory within a single process. Useful for testing purposes.
cat ./input/block_6.json | cargo r --release --bin leader -- -r in-memory stdio > ./output/proof_6.json
A verifier binary is provided to verify the correctness of the generated proof. The verifier expects output in the format generated by the leader. The verifier binary arguments are as follows:
cargo r --bin verifier -- --help
Usage: verifier --file-path <FILE_PATH>
Options:
-f, --file-path <FILE_PATH> The file containing the proof to verify
-h, --help Print help
Example:
cargo r --release --bin verifier -- -f ./output/proof_16.json
An rpc binary is provided to generate the block trace format expected by the leader.
cargo r --bin rpc -- --help
Usage: rpc <COMMAND>
Commands:
fetch Fetch and generate prover input from the RPC endpoint
help Print this message or the help of the given subcommand(s)
Options:
-h, --help Print help
Example:
cargo r --release --bin rpc fetch --start-block <START_BLOCK> --end-block <END_BLOCK> --rpc-url <RPC_URL> --block-number 16 > ./output/block-16.json
Docker images are provided for both the leader and worker binaries.
There are three branches that are used for development:
main
--> Always points to the latest production releasedevelop
--> All PRs should be merged into this branchtesting
--> For testing against the latest changes. Should always point to thedevelop
branch for thezk_evm
deps
For testing proof generation for blocks, the testing
branch should be used.
If you want to generate a full block proof, you can use tools/prove_rpc.sh
:
./prove_rpc.sh <BLOCK_START> <BLOCK_END> <FULL_NODE_ENDPOINT> <RPC_TYPE> <IGNORE_PREVIOUS_PROOFS>
Which may look like this:
./prove_rpc.sh 17 18 http://127.0.0.1:8545 jerigon false
Which will attempt to generate proofs for blocks 17
& 18
consecutively and incorporate the previous block proof during generation.
A few other notes:
- Proving blocks is very resource intensive in terms of both CPU and memory. You can also only generate the witness for a block instead (see Generating Witnesses Only) to significantly reduce the CPU and memory requirements.
- Because incorporating the previous block proof requires a chain of proofs back to the last checkpoint height, you can also disable this requirement by passing
true
for<IGNORE_PREVIOUS_PROOFS>
(which internally just sets the current checkpoint height to the previous block height).
If you want to test a block without the high CPU & memory requirements that come with creating a full proof, you can instead generate only the witness using tools/prove_rpc.sh
in the test_only
mode:
./prove_rpc.sh <START_BLOCK> <END_BLOCK> <FULL_NODE_ENDPOINT> <RPC_TYPE> <IGNORE_PREVIOUS_PROOFS> <BACKOFF> <RETRIES> test_only
Filled in:
./prove_rpc.sh 18299898 18299899 http://34.89.57.138:8545 jerigon true 0 0 test_only
Finally, note that both of these testing scripts force proof generation to be sequential by allowing only one worker. Because of this, this is not a realistic representation of performance but makes the debugging logs much easier to follow.
Licensed under either of
- Apache License, Version 2.0, (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or http://opensource.org/licenses/MIT)
at your option.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.