lbcd/btcec/bench_test.go

// Copyright 2013-2016 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.

package btcec

import "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 := new(fieldVal).SetHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6")
	y1 := new(fieldVal).SetHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232")
	z1 := new(fieldVal).SetHex("1")
	x2 := new(fieldVal).SetHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6")
	y2 := new(fieldVal).SetHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232")
	z2 := new(fieldVal).SetHex("1")
	x3, y3, z3 := new(fieldVal), new(fieldVal), new(fieldVal)
	curve := S256()
	b.StartTimer()
	for i := 0; i < b.N; i++ {
		curve.addJacobian(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 := new(fieldVal).SetHex("d3e5183c393c20e4f464acf144ce9ae8266a82b67f553af33eb37e88e7fd2718")
	y1 := new(fieldVal).SetHex("5b8f54deb987ec491fb692d3d48f3eebb9454b034365ad480dda0cf079651190")
	z1 := new(fieldVal).SetHex("2")
	x2 := new(fieldVal).SetHex("91abba6a34b7481d922a4bd6a04899d5a686f6cf6da4e66a0cb427fb25c04bd4")
	y2 := new(fieldVal).SetHex("03fede65e30b4e7576a2abefc963ddbf9fdccbf791b77c29beadefe49951f7d1")
	z2 := new(fieldVal).SetHex("3")
	x3, y3, z3 := new(fieldVal), new(fieldVal), new(fieldVal)
	curve := S256()
	b.StartTimer()
	for i := 0; i < b.N; i++ {
		curve.addJacobian(x1, y1, z1, x2, y2, z2, x3, y3, z3)
	}
}

// BenchmarkScalarBaseMult benchmarks the secp256k1 curve ScalarBaseMult
// function.
func BenchmarkScalarBaseMult(b *testing.B) {
	k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575")
	curve := S256()
	for i := 0; i < b.N; i++ {
		curve.ScalarBaseMult(k.Bytes())
	}
}

// BenchmarkScalarBaseMultLarge benchmarks the secp256k1 curve ScalarBaseMult
// function with abnormally large k values.
func BenchmarkScalarBaseMultLarge(b *testing.B) {
	k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c005751111111011111110")
	curve := 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 := S256()
	for i := 0; i < b.N; i++ {
		curve.ScalarMult(x, y, k.Bytes())
	}
}

// BenchmarkNAF benchmarks the NAF function.
func BenchmarkNAF(b *testing.B) {
	k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575")
	for i := 0; i < b.N; i++ {
		NAF(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 := PublicKey{
		Curve: S256(),
		X:     fromHex("d2e670a19c6d753d1a6d8b20bd045df8a08fb162cf508956c31268c6d81ffdab"),
		Y:     fromHex("ab65528eefbb8057aa85d597258a3fbd481a24633bc9b47a9aa045c91371de52"),
	}

	// Double sha256 of []byte{0x01, 0x02, 0x03, 0x04}
	msgHash := fromHex("8de472e2399610baaa7f84840547cd409434e31f5d3bd71e4d947f283874f9c0")
	sig := Signature{
		R: fromHex("fef45d2892953aa5bbcdb057b5e98b208f1617a7498af7eb765574e29b5d9c2c"),
		S: fromHex("d47563f52aac6b04b55de236b7c515eb9311757db01e02cff079c3ca6efb063f"),
	}

	if !sig.Verify(msgHash.Bytes(), &pubKey) {
		b.Errorf("Signature failed to verify")
		return
	}
	b.StartTimer()

	for i := 0; i < b.N; i++ {
		sig.Verify(msgHash.Bytes(), &pubKey)
	}
}

// BenchmarkFieldNormalize benchmarks how long it takes the internal field
// to perform normalization (which includes modular reduction).
func BenchmarkFieldNormalize(b *testing.B) {
	// The normalize function is constant time so default value is fine.
	f := new(fieldVal)
	for i := 0; i < b.N; i++ {
		f.Normalize()
	}
}
btcec: Consolidate tests into the btcec package. Putting the test code in the same package makes it easier for forks since they don't have to change the import paths as much and it also gets rid of the need for internal_test.go to bridge. Also, remove the exception from the lint checks about returning the unexported type since it is no longer required. 2016-10-19 07:48:05 +02:00			`// Copyright 2013-2016 The btcsuite developers`
Relicense to the btcsuite developers. This commit relicenses all code in this repository to the btcsuite developers. 2015-05-01 08:28:01 +02:00			`// Use of this source code is governed by an ISC`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`// license that can be found in the LICENSE file.`

Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`package btcec`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`import "testing"`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00
Add bench for adding Jacobian points where Z!=1. 2014-02-12 20:53:17 +01:00			`// BenchmarkAddJacobian benchmarks the secp256k1 curve addJacobian function with`
			`// Z values of 1 so that the associated optimizations are used.`
Add benchmark for adding two Jacobian points. 2013-12-27 04:52:26 +01:00			`func BenchmarkAddJacobian(b *testing.B) {`
			`b.StopTimer()`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`x1 := new(fieldVal).SetHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6")`
			`y1 := new(fieldVal).SetHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232")`
			`z1 := new(fieldVal).SetHex("1")`
			`x2 := new(fieldVal).SetHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6")`
			`y2 := new(fieldVal).SetHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232")`
			`z2 := new(fieldVal).SetHex("1")`
			`x3, y3, z3 := new(fieldVal), new(fieldVal), new(fieldVal)`
			`curve := S256()`
Add benchmark for adding two Jacobian points. 2013-12-27 04:52:26 +01:00			`b.StartTimer()`
			`for i := 0; i < b.N; i++ {`
btcec: Consolidate tests into the btcec package. Putting the test code in the same package makes it easier for forks since they don't have to change the import paths as much and it also gets rid of the need for internal_test.go to bridge. Also, remove the exception from the lint checks about returning the unexported type since it is no longer required. 2016-10-19 07:48:05 +02:00			`curve.addJacobian(x1, y1, z1, x2, y2, z2, x3, y3, z3)`
Add benchmark for adding two Jacobian points. 2013-12-27 04:52:26 +01:00			`}`
			`}`

Add bench for adding Jacobian points where Z!=1. 2014-02-12 20:53:17 +01:00			`// 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()`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`x1 := new(fieldVal).SetHex("d3e5183c393c20e4f464acf144ce9ae8266a82b67f553af33eb37e88e7fd2718")`
			`y1 := new(fieldVal).SetHex("5b8f54deb987ec491fb692d3d48f3eebb9454b034365ad480dda0cf079651190")`
			`z1 := new(fieldVal).SetHex("2")`
			`x2 := new(fieldVal).SetHex("91abba6a34b7481d922a4bd6a04899d5a686f6cf6da4e66a0cb427fb25c04bd4")`
			`y2 := new(fieldVal).SetHex("03fede65e30b4e7576a2abefc963ddbf9fdccbf791b77c29beadefe49951f7d1")`
			`z2 := new(fieldVal).SetHex("3")`
			`x3, y3, z3 := new(fieldVal), new(fieldVal), new(fieldVal)`
			`curve := S256()`
Add bench for adding Jacobian points where Z!=1. 2014-02-12 20:53:17 +01:00			`b.StartTimer()`
			`for i := 0; i < b.N; i++ {`
btcec: Consolidate tests into the btcec package. Putting the test code in the same package makes it easier for forks since they don't have to change the import paths as much and it also gets rid of the need for internal_test.go to bridge. Also, remove the exception from the lint checks about returning the unexported type since it is no longer required. 2016-10-19 07:48:05 +02:00			`curve.addJacobian(x1, y1, z1, x2, y2, z2, x3, y3, z3)`
Add bench for adding Jacobian points where Z!=1. 2014-02-12 20:53:17 +01:00			`}`
			`}`

Optimize ScalarBaseMult Code uses a windowing/precomputing strategy to minimize ECC math. Every 8-bit window of the 256 bits that compose a possible scalar multiple has a complete map that's pre-computed. The precomputed data is in secp256k1.go and the generator for that file is in gensecp256k1.go Also fixed a spelling error in a benchmark test. Results so far seem to indicate the time taken is about 35% of what it was before. Closes #2 2014-09-24 19:41:07 +02:00			`// BenchmarkScalarBaseMult benchmarks the secp256k1 curve ScalarBaseMult`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`// function.`
Optimize ScalarBaseMult Code uses a windowing/precomputing strategy to minimize ECC math. Every 8-bit window of the 256 bits that compose a possible scalar multiple has a complete map that's pre-computed. The precomputed data is in secp256k1.go and the generator for that file is in gensecp256k1.go Also fixed a spelling error in a benchmark test. Results so far seem to indicate the time taken is about 35% of what it was before. Closes #2 2014-09-24 19:41:07 +02:00			`func BenchmarkScalarBaseMult(b *testing.B) {`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575")`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`curve := S256()`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`for i := 0; i < b.N; i++ {`
			`curve.ScalarBaseMult(k.Bytes())`
			`}`
			`}`

Optimize ScalarMult using endomorphism This implements a speedup to ScalarMult using the endomorphism available to secp256k1. Note the constants lambda, beta, a1, b1, a2 and b2 are from here: https://bitcointalk.org/index.php?topic=3238.0 Preliminary tests indicate a speedup of between 17%-20% (BenchScalarMult). More speedup can probably be achieved once splitK uses something more like what fieldVal uses. Unfortunately, the prime for this math is the order of G (N), not P. Note the NAF optimization was specifically not done as that's the purview of another issue. Changed both ScalarMult and ScalarBaseMult to take advantage of curve.N to reduce k. This results in a 80% speedup to large values of k for ScalarBaseMult. Note the new test BenchmarkScalarBaseMultLarge is how that speedup number can be checked. This closes #1 2015-01-22 17:06:00 +01:00			`// BenchmarkScalarBaseMultLarge benchmarks the secp256k1 curve ScalarBaseMult`
			`// function with abnormally large k values.`
			`func BenchmarkScalarBaseMultLarge(b *testing.B) {`
			`k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c005751111111011111110")`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`curve := S256()`
Optimize ScalarMult using endomorphism This implements a speedup to ScalarMult using the endomorphism available to secp256k1. Note the constants lambda, beta, a1, b1, a2 and b2 are from here: https://bitcointalk.org/index.php?topic=3238.0 Preliminary tests indicate a speedup of between 17%-20% (BenchScalarMult). More speedup can probably be achieved once splitK uses something more like what fieldVal uses. Unfortunately, the prime for this math is the order of G (N), not P. Note the NAF optimization was specifically not done as that's the purview of another issue. Changed both ScalarMult and ScalarBaseMult to take advantage of curve.N to reduce k. This results in a 80% speedup to large values of k for ScalarBaseMult. Note the new test BenchmarkScalarBaseMultLarge is how that speedup number can be checked. This closes #1 2015-01-22 17:06:00 +01:00			`for i := 0; i < b.N; i++ {`
			`curve.ScalarBaseMult(k.Bytes())`
			`}`
			`}`

Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`// BenchmarkScalarMult benchmarks the secp256k1 curve ScalarMult function.`
			`func BenchmarkScalarMult(b *testing.B) {`
			`x := fromHex("34f9460f0e4f08393d192b3c5133a6ba099aa0ad9fd54ebccfacdfa239ff49c6")`
			`y := fromHex("0b71ea9bd730fd8923f6d25a7a91e7dd7728a960686cb5a901bb419e0f2ca232")`
			`k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575")`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`curve := S256()`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`for i := 0; i < b.N; i++ {`
			`curve.ScalarMult(x, y, k.Bytes())`
Optimize ScalarMult with NAF Use Non-Adjacent Form (NAF) of large numbers to reduce ScalarMult computation times. Preliminary results indicate around a 8-9% speed improvement according to BenchmarkScalarMult. The algorithm used is 3.77 from Guide to Elliptical Curve Crytography by Hankerson, et al. This closes #3 2015-01-22 17:13:00 +01:00			`}`
			`}`

			`// BenchmarkNAF benchmarks the NAF function.`
			`func BenchmarkNAF(b *testing.B) {`
			`k := fromHex("d74bf844b0862475103d96a611cf2d898447e288d34b360bc885cb8ce7c00575")`
			`for i := 0; i < b.N; i++ {`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`NAF(k.Bytes())`
Add benchmarks for ScalarBaseMult and ScalarMult. 2013-12-23 23:56:48 +01:00			`}`
			`}`
Add benchmark for signature verifies. 2013-12-24 00:24:01 +01:00
			`// 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`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`pubKey := PublicKey{`
			`Curve: S256(),`
Add benchmark for signature verifies. 2013-12-24 00:24:01 +01:00			`X: fromHex("d2e670a19c6d753d1a6d8b20bd045df8a08fb162cf508956c31268c6d81ffdab"),`
			`Y: fromHex("ab65528eefbb8057aa85d597258a3fbd481a24633bc9b47a9aa045c91371de52"),`
			`}`

			`// Double sha256 of []byte{0x01, 0x02, 0x03, 0x04}`
			`msgHash := fromHex("8de472e2399610baaa7f84840547cd409434e31f5d3bd71e4d947f283874f9c0")`
Move the btcec benchmarks into the main package. The benchmarks are still only compiled when running 'go test' so this has no effect on regular usage. This is being done because benchmarks often need access to internal state. Normal tests are kept in a separate package since they also serve to exercise the public API, and by intentionally making it more difficult to reach into the internals, it helps ensure the public API is sanely usable. Since the benchmarks can now access the internals directly, this commit also removes the functions which exposed the internals to the test package from internal_test.go which were only used by the benchmarks. Also, it removes a duplicate benchmark. 2015-02-04 21:24:12 +01:00			`sig := Signature{`
Use btcec structs instead of ecdsa structs everywhere. This change should make it so that only btcec relies on the crypto/ecdsa package for secp256k1 math. 2014-09-29 23:32:26 +02:00			`R: fromHex("fef45d2892953aa5bbcdb057b5e98b208f1617a7498af7eb765574e29b5d9c2c"),`
			`S: fromHex("d47563f52aac6b04b55de236b7c515eb9311757db01e02cff079c3ca6efb063f"),`
			`}`
Add benchmark for signature verifies. 2013-12-24 00:24:01 +01:00
Use btcec structs instead of ecdsa structs everywhere. This change should make it so that only btcec relies on the crypto/ecdsa package for secp256k1 math. 2014-09-29 23:32:26 +02:00			`if !sig.Verify(msgHash.Bytes(), &pubKey) {`
Add benchmark for signature verifies. 2013-12-24 00:24:01 +01:00			`b.Errorf("Signature failed to verify")`
			`return`
			`}`
			`b.StartTimer()`

			`for i := 0; i < b.N; i++ {`
Use btcec structs instead of ecdsa structs everywhere. This change should make it so that only btcec relies on the crypto/ecdsa package for secp256k1 math. 2014-09-29 23:32:26 +02:00			`sig.Verify(msgHash.Bytes(), &pubKey)`
Add benchmark for signature verifies. 2013-12-24 00:24:01 +01:00			`}`
			`}`
btcec: Add benchmark for field normalization. 2017-06-07 18:12:11 +02:00
			`// BenchmarkFieldNormalize benchmarks how long it takes the internal field`
			`// to perform normalization (which includes modular reduction).`
			`func BenchmarkFieldNormalize(b *testing.B) {`
			`// The normalize function is constant time so default value is fine.`
			`f := new(fieldVal)`
			`for i := 0; i < b.N; i++ {`
			`f.Normalize()`
			`}`
			`}`