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reedsolomon.go
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/**
* Reed-Solomon Coding over 8-bit values.
*
* Copyright 2015, Klaus Post
* Copyright 2015, Backblaze, Inc.
*/
// Package reedsolomon enables Erasure Coding in Go
//
// For usage and examples, see https://github.com/klauspost/reedsolomon
package reedsolomon
import (
"bytes"
"errors"
"fmt"
"io"
"runtime"
"sync"
"github.com/klauspost/cpuid/v2"
)
// Encoder is an interface to encode Reed-Salomon parity sets for your data.
type Encoder interface {
// Encode parity for a set of data shards.
// Input is 'shards' containing data shards followed by parity shards.
// The number of shards must match the number given to New().
// Each shard is a byte array, and they must all be the same size.
// The parity shards will always be overwritten and the data shards
// will remain the same, so it is safe for you to read from the
// data shards while this is running.
Encode(shards [][]byte) error
// EncodeIdx will add parity for a single data shard.
// Parity shards should start out as 0. The caller must zero them.
// Data shards must be delivered exactly once. There is no check for this.
// The parity shards will always be updated and the data shards will remain the same.
EncodeIdx(dataShard []byte, idx int, parity [][]byte) error
// Verify returns true if the parity shards contain correct data.
// The data is the same format as Encode. No data is modified, so
// you are allowed to read from data while this is running.
Verify(shards [][]byte) (bool, error)
// Reconstruct will recreate the missing shards if possible.
//
// Given a list of shards, some of which contain data, fills in the
// ones that don't have data.
//
// The length of the array must be equal to the total number of shards.
// You indicate that a shard is missing by setting it to nil or zero-length.
// If a shard is zero-length but has sufficient capacity, that memory will
// be used, otherwise a new []byte will be allocated.
//
// If there are too few shards to reconstruct the missing
// ones, ErrTooFewShards will be returned.
//
// The reconstructed shard set is complete, but integrity is not verified.
// Use the Verify function to check if data set is ok.
Reconstruct(shards [][]byte) error
// ReconstructData will recreate any missing data shards, if possible.
//
// Given a list of shards, some of which contain data, fills in the
// data shards that don't have data.
//
// The length of the array must be equal to Shards.
// You indicate that a shard is missing by setting it to nil or zero-length.
// If a shard is zero-length but has sufficient capacity, that memory will
// be used, otherwise a new []byte will be allocated.
//
// If there are too few shards to reconstruct the missing
// ones, ErrTooFewShards will be returned.
//
// As the reconstructed shard set may contain missing parity shards,
// calling the Verify function is likely to fail.
ReconstructData(shards [][]byte) error
// ReconstructSome will recreate only requested data shards, if possible.
//
// Given a list of shards, some of which contain data, fills in the
// data shards indicated by true values in the "required" parameter.
// The length of "required" array must be equal to DataShards.
//
// The length of "shards" array must be equal to Shards.
// You indicate that a shard is missing by setting it to nil or zero-length.
// If a shard is zero-length but has sufficient capacity, that memory will
// be used, otherwise a new []byte will be allocated.
//
// If there are too few shards to reconstruct the missing
// ones, ErrTooFewShards will be returned.
//
// As the reconstructed shard set may contain missing parity shards,
// calling the Verify function is likely to fail.
ReconstructSome(shards [][]byte, required []bool) error
// Update parity is use for change a few data shards and update it's parity.
// Input 'newDatashards' containing data shards changed.
// Input 'shards' containing old data shards (if data shard not changed, it can be nil) and old parity shards.
// new parity shards will in shards[DataShards:]
// Update is very useful if DataShards much larger than ParityShards and changed data shards is few. It will
// faster than Encode and not need read all data shards to encode.
Update(shards [][]byte, newDatashards [][]byte) error
// Split a data slice into the number of shards given to the encoder,
// and create empty parity shards if necessary.
//
// The data will be split into equally sized shards.
// If the data size isn't divisible by the number of shards,
// the last shard will contain extra zeros.
//
// If there is extra capacity on the provided data slice
// it will be used instead of allocating parity shards.
// It will be zeroed out.
//
// There must be at least 1 byte otherwise ErrShortData will be
// returned.
//
// The data will not be copied, except for the last shard, so you
// should not modify the data of the input slice afterwards.
Split(data []byte) ([][]byte, error)
// Join the shards and write the data segment to dst.
//
// Only the data shards are considered.
// You must supply the exact output size you want.
// If there are to few shards given, ErrTooFewShards will be returned.
// If the total data size is less than outSize, ErrShortData will be returned.
Join(dst io.Writer, shards [][]byte, outSize int) error
}
// Extensions is an optional interface.
// All returned instances will support this interface.
type Extensions interface {
// ShardSizeMultiple will return the size the shard sizes must be a multiple of.
ShardSizeMultiple() int
// DataShards will return the number of data shards.
DataShards() int
// ParityShards will return the number of parity shards.
ParityShards() int
// TotalShards will return the total number of shards.
TotalShards() int
// AllocAligned will allocate TotalShards number of slices,
// aligned to reasonable memory sizes.
// Provide the size of each shard.
AllocAligned(each int) [][]byte
}
const (
avx2CodeGenMinSize = 64
avx2CodeGenMinShards = 3
avx2CodeGenMaxGoroutines = 8
gfniCodeGenMaxGoroutines = 4
intSize = 32 << (^uint(0) >> 63) // 32 or 64
maxInt = 1<<(intSize-1) - 1
)
// reedSolomon contains a matrix for a specific
// distribution of datashards and parity shards.
// Construct if using New()
type reedSolomon struct {
dataShards int // Number of data shards, should not be modified.
parityShards int // Number of parity shards, should not be modified.
totalShards int // Total number of shards. Calculated, and should not be modified.
m matrix
tree *inversionTree
parity [][]byte
o options
mPoolSz int
mPool sync.Pool // Pool for temp matrices, etc
}
var _ = Extensions(&reedSolomon{})
func (r *reedSolomon) ShardSizeMultiple() int {
return 1
}
func (r *reedSolomon) DataShards() int {
return r.dataShards
}
func (r *reedSolomon) ParityShards() int {
return r.parityShards
}
func (r *reedSolomon) TotalShards() int {
return r.totalShards
}
func (r *reedSolomon) AllocAligned(each int) [][]byte {
return AllocAligned(r.totalShards, each)
}
// ErrInvShardNum will be returned by New, if you attempt to create
// an Encoder with less than one data shard or less than zero parity
// shards.
var ErrInvShardNum = errors.New("cannot create Encoder with less than one data shard or less than zero parity shards")
// ErrMaxShardNum will be returned by New, if you attempt to create an
// Encoder where data and parity shards are bigger than the order of
// GF(2^8).
var ErrMaxShardNum = errors.New("cannot create Encoder with more than 256 data+parity shards")
// ErrNotSupported is returned when an operation is not supported.
var ErrNotSupported = errors.New("operation not supported")
// buildMatrix creates the matrix to use for encoding, given the
// number of data shards and the number of total shards.
//
// The top square of the matrix is guaranteed to be an identity
// matrix, which means that the data shards are unchanged after
// encoding.
func buildMatrix(dataShards, totalShards int) (matrix, error) {
// Start with a Vandermonde matrix. This matrix would work,
// in theory, but doesn't have the property that the data
// shards are unchanged after encoding.
vm, err := vandermonde(totalShards, dataShards)
if err != nil {
return nil, err
}
// Multiply by the inverse of the top square of the matrix.
// This will make the top square be the identity matrix, but
// preserve the property that any square subset of rows is
// invertible.
top, err := vm.SubMatrix(0, 0, dataShards, dataShards)
if err != nil {
return nil, err
}
topInv, err := top.Invert()
if err != nil {
return nil, err
}
return vm.Multiply(topInv)
}
// buildMatrixJerasure creates the same encoding matrix as Jerasure library
//
// The top square of the matrix is guaranteed to be an identity
// matrix, which means that the data shards are unchanged after
// encoding.
func buildMatrixJerasure(dataShards, totalShards int) (matrix, error) {
// Start with a Vandermonde matrix. This matrix would work,
// in theory, but doesn't have the property that the data
// shards are unchanged after encoding.
vm, err := vandermonde(totalShards, dataShards)
if err != nil {
return nil, err
}
// Jerasure does this:
// first row is always 100..00
vm[0][0] = 1
for i := 1; i < dataShards; i++ {
vm[0][i] = 0
}
// last row is always 000..01
for i := 0; i < dataShards-1; i++ {
vm[totalShards-1][i] = 0
}
vm[totalShards-1][dataShards-1] = 1
for i := 0; i < dataShards; i++ {
// Find the row where i'th col is not 0
r := i
for ; r < totalShards && vm[r][i] == 0; r++ {
}
if r != i {
// Swap it with i'th row if not already
t := vm[r]
vm[r] = vm[i]
vm[i] = t
}
// Multiply by the inverted matrix (same as vm.Multiply(vm[0:dataShards].Invert()))
if vm[i][i] != 1 {
// Make vm[i][i] = 1 by dividing the column by vm[i][i]
tmp := galOneOver(vm[i][i])
for j := 0; j < totalShards; j++ {
vm[j][i] = galMultiply(vm[j][i], tmp)
}
}
for j := 0; j < dataShards; j++ {
// Make vm[i][j] = 0 where j != i by adding vm[i][j]*vm[.][i] to each column
tmp := vm[i][j]
if j != i && tmp != 0 {
for r := 0; r < totalShards; r++ {
vm[r][j] = galAdd(vm[r][j], galMultiply(tmp, vm[r][i]))
}
}
}
}
// Make vm[dataShards] row all ones - divide each column j by vm[dataShards][j]
for j := 0; j < dataShards; j++ {
tmp := vm[dataShards][j]
if tmp != 1 {
tmp = galOneOver(tmp)
for i := dataShards; i < totalShards; i++ {
vm[i][j] = galMultiply(vm[i][j], tmp)
}
}
}
// Make vm[dataShards...totalShards-1][0] column all ones - divide each row
for i := dataShards + 1; i < totalShards; i++ {
tmp := vm[i][0]
if tmp != 1 {
tmp = galOneOver(tmp)
for j := 0; j < dataShards; j++ {
vm[i][j] = galMultiply(vm[i][j], tmp)
}
}
}
return vm, nil
}
// buildMatrixPAR1 creates the matrix to use for encoding according to
// the PARv1 spec, given the number of data shards and the number of
// total shards. Note that the method they use is buggy, and may lead
// to cases where recovery is impossible, even if there are enough
// parity shards.
//
// The top square of the matrix is guaranteed to be an identity
// matrix, which means that the data shards are unchanged after
// encoding.
func buildMatrixPAR1(dataShards, totalShards int) (matrix, error) {
result, err := newMatrix(totalShards, dataShards)
if err != nil {
return nil, err
}
for r, row := range result {
// The top portion of the matrix is the identity
// matrix, and the bottom is a transposed Vandermonde
// matrix starting at 1 instead of 0.
if r < dataShards {
result[r][r] = 1
} else {
for c := range row {
result[r][c] = galExp(byte(c+1), r-dataShards)
}
}
}
return result, nil
}
func buildMatrixCauchy(dataShards, totalShards int) (matrix, error) {
result, err := newMatrix(totalShards, dataShards)
if err != nil {
return nil, err
}
for r, row := range result {
// The top portion of the matrix is the identity
// matrix, and the bottom is a transposed Cauchy matrix.
if r < dataShards {
result[r][r] = 1
} else {
for c := range row {
result[r][c] = invTable[(byte(r ^ c))]
}
}
}
return result, nil
}
// buildXorMatrix can be used to build a matrix with pure XOR
// operations if there is only one parity shard.
func buildXorMatrix(dataShards, totalShards int) (matrix, error) {
if dataShards+1 != totalShards {
return nil, errors.New("internal error")
}
result, err := newMatrix(totalShards, dataShards)
if err != nil {
return nil, err
}
for r, row := range result {
// The top portion of the matrix is the identity
// matrix.
if r < dataShards {
result[r][r] = 1
} else {
// Set all values to 1 (XOR)
for c := range row {
result[r][c] = 1
}
}
}
return result, nil
}
// New creates a new encoder and initializes it to
// the number of data shards and parity shards that
// you want to use. You can reuse this encoder.
// Note that the maximum number of total shards is 65536, with some
// restrictions for a total larger than 256:
//
// - Shard sizes must be multiple of 64
// - The methods Join/Split/Update/EncodeIdx are not supported
//
// If no options are supplied, default options are used.
func New(dataShards, parityShards int, opts ...Option) (Encoder, error) {
o := defaultOptions
for _, opt := range opts {
opt(&o)
}
totShards := dataShards + parityShards
switch {
case o.withLeopard == leopardGF16 && parityShards > 0 || totShards > 256:
return newFF16(dataShards, parityShards, o)
case o.withLeopard == leopardAlways && parityShards > 0:
return newFF8(dataShards, parityShards, o)
}
if totShards > 256 {
return nil, ErrMaxShardNum
}
r := reedSolomon{
dataShards: dataShards,
parityShards: parityShards,
totalShards: dataShards + parityShards,
o: o,
}
if dataShards <= 0 || parityShards < 0 {
return nil, ErrInvShardNum
}
if parityShards == 0 {
return &r, nil
}
var err error
switch {
case r.o.customMatrix != nil:
if len(r.o.customMatrix) < parityShards {
return nil, errors.New("coding matrix must contain at least parityShards rows")
}
r.m = make([][]byte, r.totalShards)
for i := 0; i < dataShards; i++ {
r.m[i] = make([]byte, dataShards)
r.m[i][i] = 1
}
for k, row := range r.o.customMatrix {
if len(row) < dataShards {
return nil, errors.New("coding matrix must contain at least dataShards columns")
}
r.m[dataShards+k] = make([]byte, dataShards)
copy(r.m[dataShards+k], row)
}
case r.o.fastOneParity && parityShards == 1:
r.m, err = buildXorMatrix(dataShards, r.totalShards)
case r.o.useCauchy:
r.m, err = buildMatrixCauchy(dataShards, r.totalShards)
case r.o.usePAR1Matrix:
r.m, err = buildMatrixPAR1(dataShards, r.totalShards)
case r.o.useJerasureMatrix:
r.m, err = buildMatrixJerasure(dataShards, r.totalShards)
default:
r.m, err = buildMatrix(dataShards, r.totalShards)
}
if err != nil {
return nil, err
}
// Calculate what we want per round
r.o.perRound = cpuid.CPU.Cache.L2
if r.o.perRound < 128<<10 {
r.o.perRound = 128 << 10
}
divide := parityShards + 1
if avx2CodeGen && r.o.useAVX2 && (dataShards > maxAvx2Inputs || parityShards > maxAvx2Outputs) {
// Base on L1 cache if we have many inputs.
r.o.perRound = cpuid.CPU.Cache.L1D
if r.o.perRound < 32<<10 {
r.o.perRound = 32 << 10
}
divide = 0
if dataShards > maxAvx2Inputs {
divide += maxAvx2Inputs
} else {
divide += dataShards
}
if parityShards > maxAvx2Inputs {
divide += maxAvx2Outputs
} else {
divide += parityShards
}
}
if cpuid.CPU.ThreadsPerCore > 1 && r.o.maxGoroutines > cpuid.CPU.PhysicalCores {
// If multiple threads per core, make sure they don't contend for cache.
r.o.perRound /= cpuid.CPU.ThreadsPerCore
}
// 1 input + parity must fit in cache, and we add one more to be safer.
r.o.perRound = r.o.perRound / divide
// Align to 64 bytes.
r.o.perRound = ((r.o.perRound + 63) / 64) * 64
// Final sanity check...
if r.o.perRound < 1<<10 {
r.o.perRound = 1 << 10
}
if r.o.minSplitSize <= 0 {
// Set minsplit as high as we can, but still have parity in L1.
cacheSize := cpuid.CPU.Cache.L1D
if cacheSize <= 0 {
cacheSize = 32 << 10
}
r.o.minSplitSize = cacheSize / (parityShards + 1)
// Min 1K
if r.o.minSplitSize < 1024 {
r.o.minSplitSize = 1024
}
}
if r.o.shardSize > 0 {
p := runtime.GOMAXPROCS(0)
if p == 1 || r.o.shardSize <= r.o.minSplitSize*2 {
// Not worth it.
r.o.maxGoroutines = 1
} else {
g := r.o.shardSize / r.o.perRound
// Overprovision by a factor of 2.
if g < p*2 && r.o.perRound > r.o.minSplitSize*2 {
g = p * 2
r.o.perRound /= 2
}
// Have g be multiple of p
g += p - 1
g -= g % p
r.o.maxGoroutines = g
}
}
// Generated AVX2 does not need data to stay in L1 cache between runs.
// We will be purely limited by RAM speed.
if r.canAVX2C(avx2CodeGenMinSize, maxAvx2Inputs, maxAvx2Outputs) && r.o.maxGoroutines > avx2CodeGenMaxGoroutines {
r.o.maxGoroutines = avx2CodeGenMaxGoroutines
}
if r.canGFNI(avx2CodeGenMinSize, maxAvx2Inputs, maxAvx2Outputs) && r.o.maxGoroutines > gfniCodeGenMaxGoroutines {
r.o.maxGoroutines = gfniCodeGenMaxGoroutines
}
// Inverted matrices are cached in a tree keyed by the indices
// of the invalid rows of the data to reconstruct.
// The inversion root node will have the identity matrix as
// its inversion matrix because it implies there are no errors
// with the original data.
if r.o.inversionCache {
r.tree = newInversionTree(dataShards, parityShards)
}
r.parity = make([][]byte, parityShards)
for i := range r.parity {
r.parity[i] = r.m[dataShards+i]
}
if avx2CodeGen && r.o.useAVX2 {
sz := r.dataShards * r.parityShards * 2 * 32
r.mPool.New = func() interface{} {
return AllocAligned(1, sz)[0]
}
r.mPoolSz = sz
}
return &r, err
}
func (r *reedSolomon) getTmpSlice() []byte {
return r.mPool.Get().([]byte)
}
func (r *reedSolomon) putTmpSlice(b []byte) {
if b != nil && cap(b) >= r.mPoolSz {
r.mPool.Put(b[:r.mPoolSz])
return
}
if false {
// Sanity check
panic(fmt.Sprintf("got short tmp returned, want %d, got %d", r.mPoolSz, cap(b)))
}
}
// ErrTooFewShards is returned if too few shards where given to
// Encode/Verify/Reconstruct/Update. It will also be returned from Reconstruct
// if there were too few shards to reconstruct the missing data.
var ErrTooFewShards = errors.New("too few shards given")
// Encode parity for a set of data shards.
// An array 'shards' containing data shards followed by parity shards.
// The number of shards must match the number given to New.
// Each shard is a byte array, and they must all be the same size.
// The parity shards will always be overwritten and the data shards
// will remain the same.
func (r *reedSolomon) Encode(shards [][]byte) error {
if len(shards) != r.totalShards {
return ErrTooFewShards
}
err := checkShards(shards, false)
if err != nil {
return err
}
// Get the slice of output buffers.
output := shards[r.dataShards:]
// Do the coding.
r.codeSomeShards(r.parity, shards[0:r.dataShards], output[:r.parityShards], len(shards[0]))
return nil
}
// EncodeIdx will add parity for a single data shard.
// Parity shards should start out zeroed. The caller must zero them before first call.
// Data shards should only be delivered once. There is no check for this.
// The parity shards will always be updated and the data shards will remain the unchanged.
func (r *reedSolomon) EncodeIdx(dataShard []byte, idx int, parity [][]byte) error {
if len(parity) != r.parityShards {
return ErrTooFewShards
}
if len(parity) == 0 {
return nil
}
if idx < 0 || idx >= r.dataShards {
return ErrInvShardNum
}
err := checkShards(parity, false)
if err != nil {
return err
}
if len(parity[0]) != len(dataShard) {
return ErrShardSize
}
if avx2CodeGen && len(dataShard) >= r.o.perRound && len(parity) >= avx2CodeGenMinShards && ((pshufb && r.o.useAVX2) || r.o.useGFNI) {
m := make([][]byte, r.parityShards)
for iRow := range m {
m[iRow] = r.parity[iRow][idx : idx+1]
}
if r.o.useGFNI {
r.codeSomeShardsGFNI(m, [][]byte{dataShard}, parity, len(dataShard), false)
} else {
r.codeSomeShardsAVXP(m, [][]byte{dataShard}, parity, len(dataShard), false)
}
return nil
}
// Process using no goroutines for now.
start, end := 0, r.o.perRound
if end > len(dataShard) {
end = len(dataShard)
}
for start < len(dataShard) {
in := dataShard[start:end]
for iRow := 0; iRow < r.parityShards; iRow++ {
galMulSliceXor(r.parity[iRow][idx], in, parity[iRow][start:end], &r.o)
}
start = end
end += r.o.perRound
if end > len(dataShard) {
end = len(dataShard)
}
}
return nil
}
// ErrInvalidInput is returned if invalid input parameter of Update.
var ErrInvalidInput = errors.New("invalid input")
func (r *reedSolomon) Update(shards [][]byte, newDatashards [][]byte) error {
if len(shards) != r.totalShards {
return ErrTooFewShards
}
if len(newDatashards) != r.dataShards {
return ErrTooFewShards
}
err := checkShards(shards, true)
if err != nil {
return err
}
err = checkShards(newDatashards, true)
if err != nil {
return err
}
for i := range newDatashards {
if newDatashards[i] != nil && shards[i] == nil {
return ErrInvalidInput
}
}
for _, p := range shards[r.dataShards:] {
if p == nil {
return ErrInvalidInput
}
}
shardSize := shardSize(shards)
// Get the slice of output buffers.
output := shards[r.dataShards:]
// Do the coding.
r.updateParityShards(r.parity, shards[0:r.dataShards], newDatashards[0:r.dataShards], output, r.parityShards, shardSize)
return nil
}
func (r *reedSolomon) updateParityShards(matrixRows, oldinputs, newinputs, outputs [][]byte, outputCount, byteCount int) {
if len(outputs) == 0 {
return
}
if r.o.maxGoroutines > 1 && byteCount > r.o.minSplitSize {
r.updateParityShardsP(matrixRows, oldinputs, newinputs, outputs, outputCount, byteCount)
return
}
for c := 0; c < r.dataShards; c++ {
in := newinputs[c]
if in == nil {
continue
}
oldin := oldinputs[c]
// oldinputs data will be changed
sliceXor(in, oldin, &r.o)
for iRow := 0; iRow < outputCount; iRow++ {
galMulSliceXor(matrixRows[iRow][c], oldin, outputs[iRow], &r.o)
}
}
}
func (r *reedSolomon) updateParityShardsP(matrixRows, oldinputs, newinputs, outputs [][]byte, outputCount, byteCount int) {
var wg sync.WaitGroup
do := byteCount / r.o.maxGoroutines
if do < r.o.minSplitSize {
do = r.o.minSplitSize
}
start := 0
for start < byteCount {
if start+do > byteCount {
do = byteCount - start
}
wg.Add(1)
go func(start, stop int) {
for c := 0; c < r.dataShards; c++ {
in := newinputs[c]
if in == nil {
continue
}
oldin := oldinputs[c]
// oldinputs data will be change
sliceXor(in[start:stop], oldin[start:stop], &r.o)
for iRow := 0; iRow < outputCount; iRow++ {
galMulSliceXor(matrixRows[iRow][c], oldin[start:stop], outputs[iRow][start:stop], &r.o)
}
}
wg.Done()
}(start, start+do)
start += do
}
wg.Wait()
}
// Verify returns true if the parity shards contain the right data.
// The data is the same format as Encode. No data is modified.
func (r *reedSolomon) Verify(shards [][]byte) (bool, error) {
if len(shards) != r.totalShards {
return false, ErrTooFewShards
}
err := checkShards(shards, false)
if err != nil {
return false, err
}
// Slice of buffers being checked.
toCheck := shards[r.dataShards:]
// Do the checking.
return r.checkSomeShards(r.parity, shards[:r.dataShards], toCheck[:r.parityShards], len(shards[0])), nil
}
func (r *reedSolomon) canAVX2C(byteCount int, inputs, outputs int) bool {
return avx2CodeGen && pshufb && r.o.useAVX2 &&
byteCount >= avx2CodeGenMinSize && inputs+outputs >= avx2CodeGenMinShards &&
inputs <= maxAvx2Inputs && outputs <= maxAvx2Outputs
}
func (r *reedSolomon) canGFNI(byteCount int, inputs, outputs int) bool {
return avx2CodeGen && r.o.useGFNI &&
byteCount >= avx2CodeGenMinSize && inputs+outputs >= avx2CodeGenMinShards &&
inputs <= maxAvx2Inputs && outputs <= maxAvx2Outputs
}
// Multiplies a subset of rows from a coding matrix by a full set of
// input totalShards to produce some output totalShards.
// 'matrixRows' is The rows from the matrix to use.
// 'inputs' An array of byte arrays, each of which is one input shard.
// The number of inputs used is determined by the length of each matrix row.
// outputs Byte arrays where the computed totalShards are stored.
// The number of outputs computed, and the
// number of matrix rows used, is determined by
// outputCount, which is the number of outputs to compute.
func (r *reedSolomon) codeSomeShards(matrixRows, inputs, outputs [][]byte, byteCount int) {
if len(outputs) == 0 {
return
}
if byteCount > r.o.minSplitSize {
r.codeSomeShardsP(matrixRows, inputs, outputs, byteCount)
return
}
// Process using no goroutines
start, end := 0, r.o.perRound
if end > len(inputs[0]) {
end = len(inputs[0])
}
if r.canGFNI(byteCount, len(inputs), len(outputs)) {
var gfni [maxAvx2Inputs * maxAvx2Outputs]uint64
m := genGFNIMatrix(matrixRows, len(inputs), 0, len(outputs), gfni[:])
start += galMulSlicesGFNI(m, inputs, outputs, 0, byteCount)
end = len(inputs[0])
} else if r.canAVX2C(byteCount, len(inputs), len(outputs)) {
m := genAvx2Matrix(matrixRows, len(inputs), 0, len(outputs), r.getTmpSlice())
start += galMulSlicesAvx2(m, inputs, outputs, 0, byteCount)
r.putTmpSlice(m)
end = len(inputs[0])
} else if len(inputs)+len(outputs) > avx2CodeGenMinShards && r.canAVX2C(byteCount, maxAvx2Inputs, maxAvx2Outputs) {
var gfni [maxAvx2Inputs * maxAvx2Outputs]uint64
end = len(inputs[0])
inIdx := 0
m := r.getTmpSlice()
defer r.putTmpSlice(m)
ins := inputs
for len(ins) > 0 {
inPer := ins
if len(inPer) > maxAvx2Inputs {
inPer = inPer[:maxAvx2Inputs]
}
outs := outputs
outIdx := 0
for len(outs) > 0 {
outPer := outs
if len(outPer) > maxAvx2Outputs {
outPer = outPer[:maxAvx2Outputs]
}
if r.o.useGFNI {
m := genGFNIMatrix(matrixRows[outIdx:], len(inPer), inIdx, len(outPer), gfni[:])
if inIdx == 0 {
galMulSlicesGFNI(m, inPer, outPer, 0, byteCount)
} else {
galMulSlicesGFNIXor(m, inPer, outPer, 0, byteCount)
}
} else {
m = genAvx2Matrix(matrixRows[outIdx:], len(inPer), inIdx, len(outPer), m)
if inIdx == 0 {
galMulSlicesAvx2(m, inPer, outPer, 0, byteCount)
} else {
galMulSlicesAvx2Xor(m, inPer, outPer, 0, byteCount)
}
}
start = byteCount & avxSizeMask
outIdx += len(outPer)
outs = outs[len(outPer):]
}
inIdx += len(inPer)
ins = ins[len(inPer):]
}
if start >= end {
return
}
}
for start < len(inputs[0]) {
for c := 0; c < len(inputs); c++ {
in := inputs[c][start:end]
for iRow := 0; iRow < len(outputs); iRow++ {
if c == 0 {
galMulSlice(matrixRows[iRow][c], in, outputs[iRow][start:end], &r.o)
} else {
galMulSliceXor(matrixRows[iRow][c], in, outputs[iRow][start:end], &r.o)
}
}
}
start = end
end += r.o.perRound
if end > len(inputs[0]) {
end = len(inputs[0])
}
}
}
// Perform the same as codeSomeShards, but split the workload into
// several goroutines.
func (r *reedSolomon) codeSomeShardsP(matrixRows, inputs, outputs [][]byte, byteCount int) {
var wg sync.WaitGroup
gor := r.o.maxGoroutines
var avx2Matrix []byte
var gfniMatrix []uint64
useAvx2 := r.canAVX2C(byteCount, len(inputs), len(outputs))
useGFNI := r.canGFNI(byteCount, len(inputs), len(outputs))
if useGFNI {
var tmp [maxAvx2Inputs * maxAvx2Outputs]uint64
gfniMatrix = genGFNIMatrix(matrixRows, len(inputs), 0, len(outputs), tmp[:])
} else if useAvx2 {
avx2Matrix = genAvx2Matrix(matrixRows, len(inputs), 0, len(outputs), r.getTmpSlice())
defer r.putTmpSlice(avx2Matrix)
} else if r.o.useGFNI && byteCount < 10<<20 && len(inputs)+len(outputs) > avx2CodeGenMinShards &&
r.canGFNI(byteCount/4, maxAvx2Inputs, maxAvx2Outputs) {
// It appears there is a switchover point at around 10MB where
// Regular processing is faster...
r.codeSomeShardsGFNI(matrixRows, inputs, outputs, byteCount, true)
return
} else if r.o.useAVX2 && byteCount < 10<<20 && len(inputs)+len(outputs) > avx2CodeGenMinShards &&
r.canAVX2C(byteCount/4, maxAvx2Inputs, maxAvx2Outputs) {
// It appears there is a switchover point at around 10MB where
// Regular processing is faster...
r.codeSomeShardsAVXP(matrixRows, inputs, outputs, byteCount, true)
return
}
do := byteCount / gor
if do < r.o.minSplitSize {
do = r.o.minSplitSize
}
exec := func(start, stop int) {
if stop-start >= 64 {
if useGFNI {
start += galMulSlicesGFNI(gfniMatrix, inputs, outputs, start, stop)
} else if useAvx2 {
start += galMulSlicesAvx2(avx2Matrix, inputs, outputs, start, stop)
}
}
lstart, lstop := start, start+r.o.perRound
if lstop > stop {
lstop = stop
}
for lstart < stop {
for c := 0; c < len(inputs); c++ {
in := inputs[c][lstart:lstop]
for iRow := 0; iRow < len(outputs); iRow++ {
if c == 0 {
galMulSlice(matrixRows[iRow][c], in, outputs[iRow][lstart:lstop], &r.o)
} else {
galMulSliceXor(matrixRows[iRow][c], in, outputs[iRow][lstart:lstop], &r.o)
}
}
}
lstart = lstop
lstop += r.o.perRound
if lstop > stop {
lstop = stop
}
}
wg.Done()
}
if gor <= 1 {
wg.Add(1)
exec(0, byteCount)
return
}
// Make sizes divisible by 64
do = (do + 63) & (^63)
start := 0
for start < byteCount {
if start+do > byteCount {
do = byteCount - start
}
wg.Add(1)
go exec(start, start+do)
start += do
}
wg.Wait()
}