// Copyright 2013-2014 Conformal Systems LLC. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package btcec_test import ( "crypto/ecdsa" "github.com/conformal/btcec" "testing" ) // BenchmarkAddJacobian benchmarks the secp256k1 curve addJacobian function with // Z values of 1 so that the associated optimizations are used. func BenchmarkAddJacobian(b *testing.B) { b.StopTimer() x1 := btcec.NewFieldVal().SetHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6") y1 := btcec.NewFieldVal().SetHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232") z1 := btcec.NewFieldVal().SetHex("1") x2 := btcec.NewFieldVal().SetHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6") y2 := btcec.NewFieldVal().SetHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232") z2 := btcec.NewFieldVal().SetHex("1") x3, y3, z3 := btcec.NewFieldVal(), btcec.NewFieldVal(), btcec.NewFieldVal() curve := btcec.S256() b.StartTimer() for i := 0; i < b.N; i++ { curve.TstAddJacobian(x1, y1, z1, x2, y2, z2, x3, y3, z3) } } // BenchmarkAddJacobianNotZOne benchmarks the secp256k1 curve addJacobian // function with Z values other than one so the optimizations associated with // Z=1 aren't used. func BenchmarkAddJacobianNotZOne(b *testing.B) { b.StopTimer() x1 := btcec.NewFieldVal().SetHex("d3e5183c393c20e4f464acf144ce9ae8266a82b67f553af33eb37e88e7fd2718") y1 := btcec.NewFieldVal().SetHex("5b8f54deb987ec491fb692d3d48f3eebb9454b034365ad480dda0cf079651190") z1 := btcec.NewFieldVal().SetHex("2") x2 := btcec.NewFieldVal().SetHex("91abba6a34b7481d922a4bd6a04899d5a686f6cf6da4e66a0cb427fb25c04bd4") y2 := btcec.NewFieldVal().SetHex("03fede65e30b4e7576a2abefc963ddbf9fdccbf791b77c29beadefe49951f7d1") z2 := btcec.NewFieldVal().SetHex("3") x3, y3, z3 := btcec.NewFieldVal(), btcec.NewFieldVal(), btcec.NewFieldVal() curve := btcec.S256() b.StartTimer() for i := 0; i < b.N; i++ { curve.TstAddJacobian(x1, y1, z1, x2, y2, z2, x3, y3, z3) } } // BechmarkScalarBaseMult benchmarks the secp256k1 curve ScalarBaseMult // function. func BechmarkScalarBaseMult(b *testing.B) { k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575") curve := btcec.S256() for i := 0; i < b.N; i++ { curve.ScalarBaseMult(k.Bytes()) } } // BenchmarkScalarMult benchmarks the secp256k1 curve ScalarMult function. func BenchmarkScalarMult(b *testing.B) { x := fromHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6") y := fromHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232") k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575") curve := btcec.S256() for i := 0; i < b.N; i++ { curve.ScalarMult(x, y, k.Bytes()) } } // BenchmarkSigVerify benchmarks how long it takes the secp256k1 curve to // verify signatures. func BenchmarkSigVerify(b *testing.B) { b.StopTimer() // Randomly generated keypair. // Private key: 9e0699c91ca1e3b7e3c9ba71eb71c89890872be97576010fe593fbf3fd57e66d pubKey := ecdsa.PublicKey{ Curve: btcec.S256(), X: fromHex("d2e670a19c6d753d1a6d8b20bd045df8a08fb162cf508956c31268c6d81ffdab"), Y: fromHex("ab65528eefbb8057aa85d597258a3fbd481a24633bc9b47a9aa045c91371de52"), } // Double sha256 of []byte{0x01, 0x02, 0x03, 0x04} msgHash := fromHex("8de472e2399610baaa7f84840547cd409434e31f5d3bd71e4d947f283874f9c0") sigR := fromHex("fef45d2892953aa5bbcdb057b5e98b208f1617a7498af7eb765574e29b5d9c2c") sigS := fromHex("d47563f52aac6b04b55de236b7c515eb9311757db01e02cff079c3ca6efb063f") if !ecdsa.Verify(&pubKey, msgHash.Bytes(), sigR, sigS) { b.Errorf("Signature failed to verify") return } b.StartTimer() for i := 0; i < b.N; i++ { ecdsa.Verify(&pubKey, msgHash.Bytes(), sigR, sigS) } }