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galois_ppc64le.go
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galois_ppc64le.go
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//go:build !noasm && !appengine && !gccgo && !nopshufb
// Copyright 2015, Klaus Post, see LICENSE for details.
// Copyright 2018, Minio, Inc.
package reedsolomon
const pshufb = true
//go:noescape
func galMulPpc(low, high, in, out []byte)
//go:noescape
func galMulPpcXor(low, high, in, out []byte)
// This is what the assembler routines do in blocks of 16 bytes:
/*
func galMulPpc(low, high, in, out []byte) {
for n, input := range in {
l := input & 0xf
h := input >> 4
out[n] = low[l] ^ high[h]
}
}
func galMulPpcXor(low, high, in, out []byte) {
for n, input := range in {
l := input & 0xf
h := input >> 4
out[n] ^= low[l] ^ high[h]
}
}
*/
func galMulSlice(c byte, in, out []byte, o *options) {
if c == 1 {
copy(out, in)
return
}
done := (len(in) >> 4) << 4
if done > 0 {
galMulPpc(mulTableLow[c][:], mulTableHigh[c][:], in[:done], out)
}
remain := len(in) - done
if remain > 0 {
mt := mulTable[c][:256]
for i := done; i < len(in); i++ {
out[i] = mt[in[i]]
}
}
}
func galMulSliceXor(c byte, in, out []byte, o *options) {
if c == 1 {
sliceXor(in, out, o)
return
}
done := (len(in) >> 4) << 4
if done > 0 {
galMulPpcXor(mulTableLow[c][:], mulTableHigh[c][:], in[:done], out)
}
remain := len(in) - done
if remain > 0 {
mt := mulTable[c][:256]
for i := done; i < len(in); i++ {
out[i] ^= mt[in[i]]
}
}
}
// 4-way butterfly
func ifftDIT4(work [][]byte, dist int, log_m01, log_m23, log_m02 ffe, o *options) {
ifftDIT4Ref(work, dist, log_m01, log_m23, log_m02, o)
}
// 4-way butterfly
func ifftDIT48(work [][]byte, dist int, log_m01, log_m23, log_m02 ffe8, o *options) {
ifftDIT4Ref8(work, dist, log_m01, log_m23, log_m02, o)
}
// 4-way butterfly
func fftDIT4(work [][]byte, dist int, log_m01, log_m23, log_m02 ffe, o *options) {
fftDIT4Ref(work, dist, log_m01, log_m23, log_m02, o)
}
// 4-way butterfly
func fftDIT48(work [][]byte, dist int, log_m01, log_m23, log_m02 ffe8, o *options) {
fftDIT4Ref8(work, dist, log_m01, log_m23, log_m02, o)
}
// 2-way butterfly forward
func fftDIT2(x, y []byte, log_m ffe, o *options) {
// Reference version:
refMulAdd(x, y, log_m)
sliceXorGo(x, y, o)
}
// 2-way butterfly forward
func fftDIT28(x, y []byte, log_m ffe8, o *options) {
// Reference version:
mulAdd8(x, y, log_m, o)
sliceXorGo(x, y, o)
}
// 2-way butterfly inverse
func ifftDIT2(x, y []byte, log_m ffe, o *options) {
// Reference version:
sliceXorGo(x, y, o)
refMulAdd(x, y, log_m)
}
// 2-way butterfly inverse
func ifftDIT28(x, y []byte, log_m ffe8, o *options) {
// Reference version:
sliceXorGo(x, y, o)
mulAdd8(x, y, log_m, o)
}
func mulgf16(x, y []byte, log_m ffe, o *options) {
refMul(x, y, log_m)
}
func mulAdd8(out, in []byte, log_m ffe8, o *options) {
t := &multiply256LUT8[log_m]
galMulPpcXor(t[:16], t[16:32], in, out)
done := (len(in) >> 4) << 4
in = in[done:]
if len(in) > 0 {
out = out[done:]
refMulAdd8(in, out, log_m)
}
}
func mulgf8(out, in []byte, log_m ffe8, o *options) {
var done int
t := &multiply256LUT8[log_m]
galMulPpc(t[:16], t[16:32], in, out)
done = (len(in) >> 4) << 4
remain := len(in) - done
if remain > 0 {
mt := mul8LUTs[log_m].Value[:]
for i := done; i < len(in); i++ {
out[i] ^= byte(mt[in[i]])
}
}
}