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package cubic
import (
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"fmt"
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"math"
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"os"
"path/filepath"
"testing"
"github.com/consensys/gnark-crypto/ecc"
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curve "github.com/consensys/gnark-crypto/ecc/bls12-381"
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"github.com/consensys/gnark/backend/groth16"
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"github.com/consensys/gnark/backend/groth16/bls12-381/mpcsetup"
"github.com/consensys/gnark/constraint"
cs "github.com/consensys/gnark/constraint/bls12-381"
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"github.com/consensys/gnark/frontend"
"github.com/consensys/gnark/frontend/cs/r1cs"
"github.com/consensys/gnark/test"
"github.com/nspcc-dev/neo-go/pkg/neotest"
"github.com/nspcc-dev/neo-go/pkg/neotest/chain"
"github.com/nspcc-dev/neo-go/pkg/smartcontract/zkpbinding"
"github.com/stretchr/testify/require"
)
// First of all, you'll need to ensure that your circuit is properly constructed.
// Use unit tests to test execute the circuit and verify it against a various set
// of curves and backends with gnark/test package.
// More about circuit testing using gnark/test package: https://pkg.go.dev/github.com/consensys/gnark/test@v0.7.0
// TestCubicCircuit_TestExecution runs the provided circuit in the test execution engine.
func TestCubicCircuit_TestExecution ( t * testing . T ) {
var (
circuit CubicCircuit
assignment = CubicCircuit { X : 3 , Y : 35 }
)
// Test executing the circuit without running a ZK-SNARK prover (with the
// help of test engine). It can be useful for the circuit debugging, see
// https://docs.gnark.consensys.net/HowTo/debug_test#common-errors.
err := test . IsSolved ( & circuit , & assignment , ecc . BLS12_381 . ScalarField ( ) )
require . NoError ( t , err )
}
// TestCubicCircuit_Verification performs the circuit correctness testing over a
// set of all supported curves and backends and over a specified curve with a
// set of exact input and output values.
func TestCubicCircuit_Verification ( t * testing . T ) {
// Assert object wrapping testing.T.
assert := test . NewAssert ( t )
// Declare the circuit.
var cubicCircuit CubicCircuit
// The default behavior of the assert helper is to test the circuit across
// all supported curves and backends, ensure correct serialization, and
// cross-test the constraint system solver against a big.Int test execution
// engine.
assert . ProverFailed ( & cubicCircuit , & CubicCircuit {
X : 3 , // Wrong value.
Y : 5 ,
} )
// If needed, we can directly specify the desired curves or backends.
assert . ProverSucceeded ( & cubicCircuit , & CubicCircuit {
X : 3 , // Good value.
Y : 35 ,
} , test . WithCurves ( ecc . BLS12_381 ) )
}
// TestCubicCircuit_EndToEnd shows how to generate proof for pre-defined cubic circuit,
// how to generate Go verification contract that can be compiled by NeoGo and deployed
// to the chain and how to verify proofs via verification contract invocation.
func TestCubicCircuit_EndToEnd ( t * testing . T ) {
var (
circuit CubicCircuit
assignment = CubicCircuit { X : 3 , Y : 35 }
)
// Compile our circuit into a R1CS (a constraint system).
ccs , err := frontend . Compile ( ecc . BLS12_381 . ScalarField ( ) , r1cs . NewBuilder , & circuit )
require . NoError ( t , err )
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// One time setup (groth16 zkSNARK). Built-in groth16.Setup function is used
// for the test purposes. In production environment it is recommended to use
// MPC-based solution for proving and verifying keys generation, see the
// TestCubicCircuit_EndToEnd_Prod test.
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pk , vk , err := groth16 . Setup ( ccs )
require . NoError ( t , err )
// Intermediate step: witness definition.
witness , err := frontend . NewWitness ( & assignment , ecc . BLS12_381 . ScalarField ( ) )
require . NoError ( t , err )
publicWitness , err := witness . Public ( )
require . NoError ( t , err )
// Proof creation (groth16).
proof , err := groth16 . Prove ( ccs , pk , witness )
require . NoError ( t , err )
// Ensure that gnark can successfully verify the proof (just in case).
err = groth16 . Verify ( proof , vk , publicWitness )
require . NoError ( t , err )
// Now, when we're sure that the proof is valid, we can create and deploy verification
// contract to the Neo testing chain.
args , err := zkpbinding . GetVerifyProofArgs ( proof , publicWitness )
require . NoError ( t , err )
// Create contract file.
tmpDir := t . TempDir ( )
srcPath := filepath . Join ( tmpDir , "verify.go" )
f , err := os . Create ( srcPath )
require . NoError ( t , err )
// Create contract configuration file.
cfgPath := filepath . Join ( tmpDir , "verify.yml" )
fCfg , err := os . Create ( cfgPath )
require . NoError ( t , err )
// Create contract go.mod and go.sum files.
fMod , err := os . Create ( filepath . Join ( tmpDir , "go.mod" ) )
require . NoError ( t , err )
fSum , err := os . Create ( filepath . Join ( tmpDir , "go.sum" ) )
require . NoError ( t , err )
err = zkpbinding . GenerateVerifier ( zkpbinding . Config {
VerifyingKey : vk ,
Output : f ,
CfgOutput : fCfg ,
GomodOutput : fMod ,
GosumOutput : fSum ,
} )
require . NoError ( t , err )
require . NoError ( t , f . Close ( ) )
require . NoError ( t , fCfg . Close ( ) )
require . NoError ( t , fMod . Close ( ) )
require . NoError ( t , fSum . Close ( ) )
// Create testing chain and deploy contract onto it.
bc , committee := chain . NewSingle ( t )
e := neotest . NewExecutor ( t , bc , committee , committee )
// Compile verification contract and deploy the contract onto chain.
c := neotest . CompileFile ( t , e . Validator . ScriptHash ( ) , srcPath , cfgPath )
e . DeployContract ( t , c , nil )
// Verify proof via verification contract call.
validatorInvoker := e . ValidatorInvoker ( c . Hash )
validatorInvoker . Invoke ( t , true , "verifyProof" , args . A , args . B , args . C , args . PublicWitnesses )
}
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// TestCubicCircuit_EndToEnd shows how to generate proof for pre-defined cubic circuit,
// how to generate Go verification contract that can be compiled by NeoGo and deployed
// to the chain and how to verify proofs via verification contract invocation. It
// differs from TestCubicCircuit_EndToEnd in that it uses pre-generated Powers of Tau
// result for proving/verifying keys generation and demonstrates how to contribute
// some randomness into it.
func TestCubicCircuit_EndToEnd_Prod ( t * testing . T ) {
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const (
// Response file generated locally for 2^8 powers.
pathToResponseFile = "./response8"
// The order of Powers of Tau ceremony, it depends on the response file.
orderOfResponseFile = 8
)
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var (
circuit CubicCircuit
assignment = CubicCircuit { X : 3 , Y : 35 }
)
// Compile our circuit into a R1CS (a constraint system).
ccs , err := frontend . Compile ( ecc . BLS12_381 . ScalarField ( ) , r1cs . NewBuilder , & circuit )
require . NoError ( t , err )
// Setup (groth16 zkSNARK), use MPC-based solution for proving and verifying
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// keys generation. Please, be careful while adopting this code for your circuit.
// Ensure that response file that you've provided contains enough powers computed
// so that the number of constraints in your circuit can be handled.
pk , vk := setup ( t , ccs , pathToResponseFile , orderOfResponseFile )
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// Intermediate step: witness definition.
witness , err := frontend . NewWitness ( & assignment , ecc . BLS12_381 . ScalarField ( ) )
require . NoError ( t , err )
publicWitness , err := witness . Public ( )
require . NoError ( t , err )
// Proof creation (groth16).
proof , err := groth16 . Prove ( ccs , pk , witness )
require . NoError ( t , err )
// Ensure that gnark can successfully verify the proof (just in case).
err = groth16 . Verify ( proof , vk , publicWitness )
require . NoError ( t , err )
// Now, when we're sure that the proof is valid, we can create and deploy verification
// contract to the Neo testing chain.
args , err := zkpbinding . GetVerifyProofArgs ( proof , publicWitness )
require . NoError ( t , err )
// Create contract file.
tmpDir := t . TempDir ( )
srcPath := filepath . Join ( tmpDir , "verify.go" )
f , err := os . Create ( srcPath )
require . NoError ( t , err )
// Create contract configuration file.
cfgPath := filepath . Join ( tmpDir , "verify.yml" )
fCfg , err := os . Create ( cfgPath )
require . NoError ( t , err )
// Create contract go.mod and go.sum files.
fMod , err := os . Create ( filepath . Join ( tmpDir , "go.mod" ) )
require . NoError ( t , err )
fSum , err := os . Create ( filepath . Join ( tmpDir , "go.sum" ) )
require . NoError ( t , err )
err = zkpbinding . GenerateVerifier ( zkpbinding . Config {
VerifyingKey : vk ,
Output : f ,
CfgOutput : fCfg ,
GomodOutput : fMod ,
GosumOutput : fSum ,
} )
require . NoError ( t , err )
require . NoError ( t , f . Close ( ) )
require . NoError ( t , fCfg . Close ( ) )
require . NoError ( t , fMod . Close ( ) )
require . NoError ( t , fSum . Close ( ) )
// Create testing chain and deploy contract onto it.
bc , committee := chain . NewSingle ( t )
e := neotest . NewExecutor ( t , bc , committee , committee )
// Compile verification contract and deploy the contract onto chain.
c := neotest . CompileFile ( t , e . Validator . ScriptHash ( ) , srcPath , cfgPath )
e . DeployContract ( t , c , nil )
// Verify proof via verification contract call.
validatorInvoker := e . ValidatorInvoker ( c . Hash )
validatorInvoker . Invoke ( t , true , "verifyProof" , args . A , args . B , args . C , args . PublicWitnesses )
}
// setup generates proving and verifying keys for the given compiled constrained
// system. It accepts path to the response file from Phase 1 of the Powers of Tau
// ceremony for the BLS12-381 curve and the power of the ceremony.
// See the README.md for details on the Phase 1 response file. It makes
// circuit-specific Phase 2 initialisation of the MPC ceremony and performs some
// dummy contributions for Phase 2. In production environment, participant will
// receive a []byte, deserialize it, add his contribution and send back to the
// coordinator.
func setup ( t * testing . T , ccs constraint . ConstraintSystem , phase1ResponsePath string , inPow int ) ( groth16 . ProvingKey , groth16 . VerifyingKey ) {
const (
nContributionsPhase2 = 3
blake2bHashSize = 64
)
f , err := os . Open ( phase1ResponsePath )
require . NoError ( t , err )
// Skip hash of the previous contribution, don't need it for the MPC initialisation.
_ , err = f . Seek ( blake2bHashSize , 0 )
require . NoError ( t , err )
dec := curve . NewDecoder ( f )
// Retrieve parameters.
inN := int ( math . Pow ( 2 , float64 ( inPow ) ) )
coef_g1 := make ( [ ] curve . G1Affine , 2 * inN - 1 )
coef_g2 := make ( [ ] curve . G2Affine , inN )
alpha_coef_g1 := make ( [ ] curve . G1Affine , inN )
beta_coef_g1 := make ( [ ] curve . G1Affine , inN )
// Accumulator serialization: https://github.com/filecoin-project/powersoftau/blob/ab8f85c28f04af5a99cfcc93a3b1f74c06f94105/src/accumulator.rs#L111
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errMessage := fmt . Sprintf ( "ensure your response file contains exactly 2^%d powers of tau for BLS12-381 curve" , inPow )
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for i := range coef_g1 {
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require . NoError ( t , dec . Decode ( & coef_g1 [ i ] ) , errMessage )
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}
for i := range coef_g2 {
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require . NoError ( t , dec . Decode ( & coef_g2 [ i ] ) , errMessage )
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}
for i := range alpha_coef_g1 {
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require . NoError ( t , dec . Decode ( & alpha_coef_g1 [ i ] ) , errMessage )
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}
for i := range beta_coef_g1 {
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require . NoError ( t , dec . Decode ( & beta_coef_g1 [ i ] ) , errMessage )
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}
beta_g2 := & curve . G2Affine { }
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require . NoError ( t , dec . Decode ( beta_g2 ) , errMessage )
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// Transform (take exactly those number of powers that needed for the given number of constraints).
var (
numConstraints = ccs . GetNbConstraints ( )
outPow int
)
for ; 1 << outPow < numConstraints ; outPow ++ {
}
outN := int64 ( math . Pow ( 2 , float64 ( outPow ) ) )
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if len ( coef_g1 ) < int ( 2 * outN - 1 ) {
t . Fatalf ( "number of circuit constraints is too large for the provided response file: nbConstraints is %d, required at least %d powers to be computed" , numConstraints , outN )
}
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srs1 := mpcsetup . Phase1 { }
srs1 . Parameters . G1 . Tau = coef_g1 [ : 2 * outN - 1 ] // outN + (outN-1)
srs1 . Parameters . G2 . Tau = coef_g2 [ : outN ] // outN
srs1 . Parameters . G1 . AlphaTau = alpha_coef_g1 [ : outN ] // outN
srs1 . Parameters . G1 . BetaTau = beta_coef_g1 [ : outN ] // outN
srs1 . Parameters . G2 . Beta = * beta_g2 // 1
// Prepare for phase-2
var evals mpcsetup . Phase2Evaluations
r1cs := ccs . ( * cs . R1CS )
srs2 , evals := mpcsetup . InitPhase2 ( r1cs , & srs1 )
// Make some dummy contributions for phase2. In practice, participant will
// receive a []byte, deserialize it, add his contribution and send back to
// coordinator, like it is done in https://github.com/bnb-chain/zkbnb-setup
// for BN254 elliptic curve.
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for range nContributionsPhase2 {
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srs2 . Contribute ( )
}
// Extract the proving and verifying keys
pk , vk := mpcsetup . ExtractKeys ( & srs1 , & srs2 , & evals , ccs . GetNbConstraints ( ) )
return & pk , & vk
}