// Code generated by go generate; DO NOT EDIT. // This file was generated by robots. // +build amd64,!noasm package p751 import ( "reflect" "testing" "testing/quick" "github.com/henrydcase/nobs/dh/sidh/common" "golang.org/x/sys/cpu" ) type OptimFlag uint const ( // Indicates that optimisation which uses MUL instruction should be used kUse_MUL OptimFlag = 1 << 0 // Indicates that optimisation which uses MULX instruction should be used kUse_MULX = 1 << 1 // Indicates that optimisation which uses MULX, ADOX and ADCX instructions should be used kUse_MULXandADxX = 1 << 2 ) func resetCpuFeatures() { HasBMI2 = cpu.X86.HasBMI2 HasADXandBMI2 = cpu.X86.HasBMI2 && cpu.X86.HasADX } // Utility function used for testing Mul implementations. Tests caller provided // mulFunc against mul() func testMul(t *testing.T, f1, f2 OptimFlag) { doMulTest := func(multiplier, multiplicant common.Fp) bool { defer resetCpuFeatures() var resMulRef, resMulOptim common.FpX2 // Compute multiplier*multiplicant with first implementation HasBMI2 = (kUse_MULX & f1) == kUse_MULX HasADXandBMI2 = (kUse_MULXandADxX & f1) == kUse_MULXandADxX mulP751(&resMulOptim, &multiplier, &multiplicant) // Compute multiplier*multiplicant with second implementation HasBMI2 = (kUse_MULX & f2) == kUse_MULX HasADXandBMI2 = (kUse_MULXandADxX & f2) == kUse_MULXandADxX mulP751(&resMulRef, &multiplier, &multiplicant) // Compare results return reflect.DeepEqual(resMulRef, resMulOptim) } if err := quick.Check(doMulTest, quickCheckConfig); err != nil { t.Error(err) } } // Utility function used for testing REDC implementations. Tests caller provided // redcFunc against redc() func testRedc(t *testing.T, f1, f2 OptimFlag) { doRedcTest := func(aRR common.FpX2) bool { defer resetCpuFeatures() var resRedcF1, resRedcF2 common.Fp var aRRcpy = aRR // Compute redc with first implementation HasBMI2 = (kUse_MULX & f1) == kUse_MULX HasADXandBMI2 = (kUse_MULXandADxX & f1) == kUse_MULXandADxX rdcP751(&resRedcF1, &aRR) // Compute redc with second implementation HasBMI2 = (kUse_MULX & f2) == kUse_MULX HasADXandBMI2 = (kUse_MULXandADxX & f2) == kUse_MULXandADxX rdcP751(&resRedcF2, &aRRcpy) // Compare results return reflect.DeepEqual(resRedcF2, resRedcF1) } if err := quick.Check(doRedcTest, quickCheckConfig); err != nil { t.Error(err) } } // Ensures correctness of implementation of mul operation which uses MULX func TestMulWithMULX(t *testing.T) { defer resetCpuFeatures() if !HasBMI2 { t.Skip("MULX not supported by the platform") } testMul(t, kUse_MULX, kUse_MUL) } // Ensures correctness of implementation of mul operation which uses MULX and ADOX/ADCX func TestMulWithMULXADxX(t *testing.T) { defer resetCpuFeatures() if !HasADXandBMI2 { t.Skip("MULX, ADCX and ADOX not supported by the platform") } testMul(t, kUse_MULXandADxX, kUse_MUL) } // Ensures correctness of implementation of mul operation which uses MULX and ADOX/ADCX func TestMulWithMULXADxXAgainstMULX(t *testing.T) { defer resetCpuFeatures() if !HasADXandBMI2 { t.Skip("MULX, ADCX and ADOX not supported by the platform") } testMul(t, kUse_MULX, kUse_MULXandADxX) } // Ensures correctness of Montgomery reduction implementation which uses MULX func TestRedcWithMULX(t *testing.T) { defer resetCpuFeatures() if !HasBMI2 { t.Skip("MULX not supported by the platform") } testRedc(t, kUse_MULX, kUse_MUL) } // Ensures correctness of Montgomery reduction implementation which uses MULX // and ADCX/ADOX. func TestRedcWithMULXADxX(t *testing.T) { defer resetCpuFeatures() if !HasADXandBMI2 { t.Skip("MULX, ADCX and ADOX not supported by the platform") } testRedc(t, kUse_MULXandADxX, kUse_MUL) } // Ensures correctness of Montgomery reduction implementation which uses MULX // and ADCX/ADOX. func TestRedcWithMULXADxXAgainstMULX(t *testing.T) { defer resetCpuFeatures() if !HasADXandBMI2 { t.Skip("MULX, ADCX and ADOX not supported by the platform") } testRedc(t, kUse_MULXandADxX, kUse_MULX) }