libgo/go/hash/crc32/gen_const_ppc64le.go - rust-lang/gcc - Git at Google

 // Copyright 2017 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // +build ignore

 // Generate the constant table associated with the poly used by the
 // vpmsumd crc32 algorithm.
 //
 // go run gen_const_ppc64le.go
 //
 // generates crc32_table_ppc64le.s

 // The following is derived from code written by Anton Blanchard
 // <anton@au.ibm.com> found at https://github.com/antonblanchard/crc32-vpmsum.
 // The original is dual licensed under GPL and Apache 2.  As the copyright holder
 // for the work, IBM has contributed this new work under the golang license.

 // This code was written in Go based on the original C implementation.

 // This is a tool needed to generate the appropriate constants needed for
 // the vpmsum algorithm.  It is included to generate new constant tables if
 // new polynomial values are included in the future.

 package main

 import (
 	"bytes"
 	"fmt"
 	"os"
 )

 var blocking = 32 * 1024

 func reflect_bits(b uint64, nr uint) uint64 {
 	var ref uint64

 	for bit := uint64(0); bit < uint64(nr); bit++ {
 		if (b & uint64(1)) == 1 {
 			ref |= (1 << (uint64(nr-1) - bit))
 		}
 		b = (b >> 1)
 	}
 	return ref
 }

 func get_remainder(poly uint64, deg uint, n uint) uint64 {

 	rem, _ := xnmodp(n, poly, deg)
 	return rem
 }

 func get_quotient(poly uint64, bits, n uint) uint64 {

 	_, div := xnmodp(n, poly, bits)
 	return div
 }

 // xnmodp returns two values, p and div:
 // p is the representation of the binary polynomial x**n mod (x ** deg + "poly")
 // That is p is the binary representation of the modulus polynomial except for its highest-order term.
 // div is the binary representation of the polynomial x**n / (x ** deg + "poly")
 func xnmodp(n uint, poly uint64, deg uint) (uint64, uint64) {

 	var mod, mask, high, div uint64

 	if n < deg {
 		div = 0
 		return poly, div
 	}
 	mask = 1<<deg - 1
 	poly &= mask
 	mod = poly
 	div = 1
 	deg--
 	n--
 	for n > deg {
 		high = (mod >> deg) & 1
 		div = (div << 1) | high
 		mod <<= 1
 		if high != 0 {
 			mod ^= poly
 		}
 		n--
 	}
 	return mod & mask, div
 }

 func main() {
 	w := new(bytes.Buffer)

 	fmt.Fprintf(w, "// autogenerated: do not edit!\n")
 	fmt.Fprintf(w, "// generated from crc32/gen_const_ppc64le.go\n")
 	fmt.Fprintln(w)
 	fmt.Fprintf(w, "#include \"textflag.h\"\n")

 	// These are the polynomials supported in vector now.
 	// If adding others, include the polynomial and a name
 	// to identify it.

 	genCrc32ConstTable(w, 0xedb88320, "IEEE")
 	genCrc32ConstTable(w, 0x82f63b78, "Cast")
 	genCrc32ConstTable(w, 0xeb31d82e, "Koop")
 	b := w.Bytes()

 	err := os.WriteFile("crc32_table_ppc64le.s", b, 0666)
 	if err != nil {
 		fmt.Printf("can't write output: %s\n", err)
 	}
 }

 func genCrc32ConstTable(w *bytes.Buffer, poly uint32, polyid string) {

 	ref_poly := reflect_bits(uint64(poly), 32)
 	fmt.Fprintf(w, "\n\t/* Reduce %d kbits to 1024 bits */\n", blocking*8)
 	j := 0
 	for i := (blocking * 8) - 1024; i > 0; i -= 1024 {
 		a := reflect_bits(get_remainder(ref_poly, 32, uint(i)), 32) << 1
 		b := reflect_bits(get_remainder(ref_poly, 32, uint(i+64)), 32) << 1

 		fmt.Fprintf(w, "\t/* x^%d mod p(x)%s, x^%d mod p(x)%s */\n", uint(i+64), "", uint(i), "")
 		fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%016x\n", polyid, j*8, b)
 		fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%016x\n", polyid, (j+1)*8, a)

 		j += 2
 		fmt.Fprintf(w, "\n")
 	}

 	for i := (1024 * 2) - 128; i >= 0; i -= 128 {
 		a := reflect_bits(get_remainder(ref_poly, 32, uint(i+32)), 32)
 		b := reflect_bits(get_remainder(ref_poly, 32, uint(i+64)), 32)
 		c := reflect_bits(get_remainder(ref_poly, 32, uint(i+96)), 32)
 		d := reflect_bits(get_remainder(ref_poly, 32, uint(i+128)), 32)

 		fmt.Fprintf(w, "\t/* x^%d mod p(x)%s, x^%d mod p(x)%s, x^%d mod p(x)%s, x^%d mod p(x)%s */\n", i+128, "", i+96, "", i+64, "", i+32, "")
 		fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%08x%08x\n", polyid, j*8, c, d)
 		fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%08x%08x\n", polyid, (j+1)*8, a, b)

 		j += 2
 		fmt.Fprintf(w, "\n")
 	}

 	fmt.Fprintf(w, "GLOBL ·%sConst(SB),RODATA,$4336\n", polyid)
 	fmt.Fprintf(w, "\n /* Barrett constant m - (4^32)/n */\n")
 	fmt.Fprintf(w, "DATA ·%sBarConst(SB)/8,$0x%016x\n", polyid, reflect_bits(get_quotient(ref_poly, 32, 64), 33))
 	fmt.Fprintf(w, "DATA ·%sBarConst+8(SB)/8,$0x0000000000000000\n", polyid)
 	fmt.Fprintf(w, "DATA ·%sBarConst+16(SB)/8,$0x%016x\n", polyid, reflect_bits((uint64(1)<<32)|ref_poly, 33)) // reflected?
 	fmt.Fprintf(w, "DATA ·%sBarConst+24(SB)/8,$0x0000000000000000\n", polyid)
 	fmt.Fprintf(w, "GLOBL ·%sBarConst(SB),RODATA,$32\n", polyid)
 }
	// Copyright 2017 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// +build ignore

	// Generate the constant table associated with the poly used by the
	// vpmsumd crc32 algorithm.
	//
	// go run gen_const_ppc64le.go
	//
	// generates crc32_table_ppc64le.s

	// The following is derived from code written by Anton Blanchard
	// <anton@au.ibm.com> found at https://github.com/antonblanchard/crc32-vpmsum.
	// The original is dual licensed under GPL and Apache 2. As the copyright holder
	// for the work, IBM has contributed this new work under the golang license.

	// This code was written in Go based on the original C implementation.

	// This is a tool needed to generate the appropriate constants needed for
	// the vpmsum algorithm. It is included to generate new constant tables if
	// new polynomial values are included in the future.

	package main

	import (
	"bytes"
	"fmt"
	"os"
	)

	var blocking = 32 * 1024

	func reflect_bits(b uint64, nr uint) uint64 {
	var ref uint64

	for bit := uint64(0); bit < uint64(nr); bit++ {
	if (b & uint64(1)) == 1 {
	ref \|= (1 << (uint64(nr-1) - bit))
	}
	b = (b >> 1)
	}
	return ref
	}

	func get_remainder(poly uint64, deg uint, n uint) uint64 {

	rem, _ := xnmodp(n, poly, deg)
	return rem
	}

	func get_quotient(poly uint64, bits, n uint) uint64 {

	_, div := xnmodp(n, poly, bits)
	return div
	}

	// xnmodp returns two values, p and div:
	// p is the representation of the binary polynomial xn mod (x deg + "poly")
	// That is p is the binary representation of the modulus polynomial except for its highest-order term.
	// div is the binary representation of the polynomial xn / (x deg + "poly")
	func xnmodp(n uint, poly uint64, deg uint) (uint64, uint64) {

	var mod, mask, high, div uint64

	if n < deg {
	div = 0
	return poly, div
	}
	mask = 1<<deg - 1
	poly &= mask
	mod = poly
	div = 1
	deg--
	n--
	for n > deg {
	high = (mod >> deg) & 1
	div = (div << 1) \| high
	mod <<= 1
	if high != 0 {
	mod ^= poly
	}
	n--
	}
	return mod & mask, div
	}

	func main() {
	w := new(bytes.Buffer)

	fmt.Fprintf(w, "// autogenerated: do not edit!\n")
	fmt.Fprintf(w, "// generated from crc32/gen_const_ppc64le.go\n")
	fmt.Fprintln(w)
	fmt.Fprintf(w, "#include \"textflag.h\"\n")

	// These are the polynomials supported in vector now.
	// If adding others, include the polynomial and a name
	// to identify it.

	genCrc32ConstTable(w, 0xedb88320, "IEEE")
	genCrc32ConstTable(w, 0x82f63b78, "Cast")
	genCrc32ConstTable(w, 0xeb31d82e, "Koop")
	b := w.Bytes()

	err := os.WriteFile("crc32_table_ppc64le.s", b, 0666)
	if err != nil {
	fmt.Printf("can't write output: %s\n", err)
	}
	}

	func genCrc32ConstTable(w *bytes.Buffer, poly uint32, polyid string) {

	ref_poly := reflect_bits(uint64(poly), 32)
	fmt.Fprintf(w, "\n\t/* Reduce %d kbits to 1024 bits /\n", blocking8)
	j := 0
	for i := (blocking * 8) - 1024; i > 0; i -= 1024 {
	a := reflect_bits(get_remainder(ref_poly, 32, uint(i)), 32) << 1
	b := reflect_bits(get_remainder(ref_poly, 32, uint(i+64)), 32) << 1

	fmt.Fprintf(w, "\t/* x^%d mod p(x)%s, x^%d mod p(x)%s */\n", uint(i+64), "", uint(i), "")
	fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%016x\n", polyid, j*8, b)
	fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%016x\n", polyid, (j+1)*8, a)

	j += 2
	fmt.Fprintf(w, "\n")
	}

	for i := (1024 * 2) - 128; i >= 0; i -= 128 {
	a := reflect_bits(get_remainder(ref_poly, 32, uint(i+32)), 32)
	b := reflect_bits(get_remainder(ref_poly, 32, uint(i+64)), 32)
	c := reflect_bits(get_remainder(ref_poly, 32, uint(i+96)), 32)
	d := reflect_bits(get_remainder(ref_poly, 32, uint(i+128)), 32)

	fmt.Fprintf(w, "\t/* x^%d mod p(x)%s, x^%d mod p(x)%s, x^%d mod p(x)%s, x^%d mod p(x)%s */\n", i+128, "", i+96, "", i+64, "", i+32, "")
	fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%08x%08x\n", polyid, j*8, c, d)
	fmt.Fprintf(w, "DATA ·%sConst+%d(SB)/8,$0x%08x%08x\n", polyid, (j+1)*8, a, b)

	j += 2
	fmt.Fprintf(w, "\n")
	}

	fmt.Fprintf(w, "GLOBL ·%sConst(SB),RODATA,$4336\n", polyid)
	fmt.Fprintf(w, "\n /* Barrett constant m - (4^32)/n */\n")
	fmt.Fprintf(w, "DATA ·%sBarConst(SB)/8,$0x%016x\n", polyid, reflect_bits(get_quotient(ref_poly, 32, 64), 33))
	fmt.Fprintf(w, "DATA ·%sBarConst+8(SB)/8,$0x0000000000000000\n", polyid)
	fmt.Fprintf(w, "DATA ·%sBarConst+16(SB)/8,$0x%016x\n", polyid, reflect_bits((uint64(1)<<32)\|ref_poly, 33)) // reflected?
	fmt.Fprintf(w, "DATA ·%sBarConst+24(SB)/8,$0x0000000000000000\n", polyid)
	fmt.Fprintf(w, "GLOBL ·%sBarConst(SB),RODATA,$32\n", polyid)
	}