mirror of
https://github.com/cheat/cheat.git
synced 2024-11-23 06:21:35 +01:00
80c91cbdee
Integrate `go-git` into the application, and use it to `git clone` cheatsheets when the installer runs. Previously, the installer required that `git` be installed on the system `PATH`, so this change has to big advantages: 1. It removes that system dependency on `git` 2. It paves the way for implementing the `--update` command Additionally, `cheat` now performs a `--depth=1` clone when installing cheatsheets, which should at least somewhat improve installation times (especially on slow network connections).
157 lines
4.4 KiB
ArmAsm
157 lines
4.4 KiB
ArmAsm
// +build amd64
|
|
|
|
#include "textflag.h"
|
|
|
|
// Depends on circl/math/fp25519 package
|
|
#include "../../math/fp25519/fp_amd64.h"
|
|
#include "curve_amd64.h"
|
|
|
|
// CTE_A24 is (A+2)/4 from Curve25519
|
|
#define CTE_A24 121666
|
|
|
|
#define Size 32
|
|
|
|
// multiplyA24Leg multiplies x times CTE_A24 and stores in z
|
|
// Uses: AX, DX, R8-R13, FLAGS
|
|
// Instr: x86_64, cmov
|
|
#define multiplyA24Leg(z,x) \
|
|
MOVL $CTE_A24, AX; MULQ 0+x; MOVQ AX, R8; MOVQ DX, R9; \
|
|
MOVL $CTE_A24, AX; MULQ 8+x; MOVQ AX, R12; MOVQ DX, R10; \
|
|
MOVL $CTE_A24, AX; MULQ 16+x; MOVQ AX, R13; MOVQ DX, R11; \
|
|
MOVL $CTE_A24, AX; MULQ 24+x; \
|
|
ADDQ R12, R9; \
|
|
ADCQ R13, R10; \
|
|
ADCQ AX, R11; \
|
|
ADCQ $0, DX; \
|
|
MOVL $38, AX; /* 2*C = 38 = 2^256 MOD 2^255-19*/ \
|
|
IMULQ AX, DX; \
|
|
ADDQ DX, R8; \
|
|
ADCQ $0, R9; MOVQ R9, 8+z; \
|
|
ADCQ $0, R10; MOVQ R10, 16+z; \
|
|
ADCQ $0, R11; MOVQ R11, 24+z; \
|
|
MOVQ $0, DX; \
|
|
CMOVQCS AX, DX; \
|
|
ADDQ DX, R8; MOVQ R8, 0+z;
|
|
|
|
// multiplyA24Adx multiplies x times CTE_A24 and stores in z
|
|
// Uses: AX, DX, R8-R12, FLAGS
|
|
// Instr: x86_64, cmov, bmi2
|
|
#define multiplyA24Adx(z,x) \
|
|
MOVQ $CTE_A24, DX; \
|
|
MULXQ 0+x, R8, R10; \
|
|
MULXQ 8+x, R9, R11; ADDQ R10, R9; \
|
|
MULXQ 16+x, R10, AX; ADCQ R11, R10; \
|
|
MULXQ 24+x, R11, R12; ADCQ AX, R11; \
|
|
;;;;;;;;;;;;;;;;;;;;; ADCQ $0, R12; \
|
|
MOVL $38, DX; /* 2*C = 38 = 2^256 MOD 2^255-19*/ \
|
|
IMULQ DX, R12; \
|
|
ADDQ R12, R8; \
|
|
ADCQ $0, R9; MOVQ R9, 8+z; \
|
|
ADCQ $0, R10; MOVQ R10, 16+z; \
|
|
ADCQ $0, R11; MOVQ R11, 24+z; \
|
|
MOVQ $0, R12; \
|
|
CMOVQCS DX, R12; \
|
|
ADDQ R12, R8; MOVQ R8, 0+z;
|
|
|
|
#define mulA24Legacy \
|
|
multiplyA24Leg(0(DI),0(SI))
|
|
#define mulA24Bmi2Adx \
|
|
multiplyA24Adx(0(DI),0(SI))
|
|
|
|
// func mulA24Amd64(z, x *fp255.Elt)
|
|
TEXT ·mulA24Amd64(SB),NOSPLIT,$0-16
|
|
MOVQ z+0(FP), DI
|
|
MOVQ x+8(FP), SI
|
|
CHECK_BMI2ADX(LMA24, mulA24Legacy, mulA24Bmi2Adx)
|
|
|
|
|
|
// func ladderStepAmd64(w *[5]fp255.Elt, b uint)
|
|
// ladderStepAmd64 calculates a point addition and doubling as follows:
|
|
// (x2,z2) = 2*(x2,z2) and (x3,z3) = (x2,z2)+(x3,z3) using as a difference (x1,-).
|
|
// work = (x1,x2,z2,x3,z3) are five fp255.Elt of 32 bytes.
|
|
// stack = (t0,t1) are two fp.Elt of fp.Size bytes, and
|
|
// (b0,b1) are two-double precision fp.Elt of 2*fp.Size bytes.
|
|
TEXT ·ladderStepAmd64(SB),NOSPLIT,$192-16
|
|
// Parameters
|
|
#define regWork DI
|
|
#define regMove SI
|
|
#define x1 0*Size(regWork)
|
|
#define x2 1*Size(regWork)
|
|
#define z2 2*Size(regWork)
|
|
#define x3 3*Size(regWork)
|
|
#define z3 4*Size(regWork)
|
|
// Local variables
|
|
#define t0 0*Size(SP)
|
|
#define t1 1*Size(SP)
|
|
#define b0 2*Size(SP)
|
|
#define b1 4*Size(SP)
|
|
MOVQ w+0(FP), regWork
|
|
MOVQ b+8(FP), regMove
|
|
CHECK_BMI2ADX(LLADSTEP, ladderStepLeg, ladderStepBmi2Adx)
|
|
#undef regWork
|
|
#undef regMove
|
|
#undef x1
|
|
#undef x2
|
|
#undef z2
|
|
#undef x3
|
|
#undef z3
|
|
#undef t0
|
|
#undef t1
|
|
#undef b0
|
|
#undef b1
|
|
|
|
// func diffAddAmd64(w *[5]fp255.Elt, b uint)
|
|
// diffAddAmd64 calculates a differential point addition using a precomputed point.
|
|
// (x1,z1) = (x1,z1)+(mu) using a difference point (x2,z2)
|
|
// w = (mu,x1,z1,x2,z2) are five fp.Elt, and
|
|
// stack = (b0,b1) are two-double precision fp.Elt of 2*fp.Size bytes.
|
|
TEXT ·diffAddAmd64(SB),NOSPLIT,$128-16
|
|
// Parameters
|
|
#define regWork DI
|
|
#define regSwap SI
|
|
#define ui 0*Size(regWork)
|
|
#define x1 1*Size(regWork)
|
|
#define z1 2*Size(regWork)
|
|
#define x2 3*Size(regWork)
|
|
#define z2 4*Size(regWork)
|
|
// Local variables
|
|
#define b0 0*Size(SP)
|
|
#define b1 2*Size(SP)
|
|
MOVQ w+0(FP), regWork
|
|
MOVQ b+8(FP), regSwap
|
|
cswap(x1,x2,regSwap)
|
|
cswap(z1,z2,regSwap)
|
|
CHECK_BMI2ADX(LDIFADD, difAddLeg, difAddBmi2Adx)
|
|
#undef regWork
|
|
#undef regSwap
|
|
#undef ui
|
|
#undef x1
|
|
#undef z1
|
|
#undef x2
|
|
#undef z2
|
|
#undef b0
|
|
#undef b1
|
|
|
|
// func doubleAmd64(x, z *fp255.Elt)
|
|
// doubleAmd64 calculates a point doubling (x1,z1) = 2*(x1,z1).
|
|
// stack = (t0,t1) are two fp.Elt of fp.Size bytes, and
|
|
// (b0,b1) are two-double precision fp.Elt of 2*fp.Size bytes.
|
|
TEXT ·doubleAmd64(SB),NOSPLIT,$192-16
|
|
// Parameters
|
|
#define x1 0(DI)
|
|
#define z1 0(SI)
|
|
// Local variables
|
|
#define t0 0*Size(SP)
|
|
#define t1 1*Size(SP)
|
|
#define b0 2*Size(SP)
|
|
#define b1 4*Size(SP)
|
|
MOVQ x+0(FP), DI
|
|
MOVQ z+8(FP), SI
|
|
CHECK_BMI2ADX(LDOUB,doubleLeg,doubleBmi2Adx)
|
|
#undef x1
|
|
#undef z1
|
|
#undef t0
|
|
#undef t1
|
|
#undef b0
|
|
#undef b1
|