minio/cmd/erasure-metadata-utils.go
Klaus Post 4972735507
Fix lint issues from v1.62.0 upgrade (#20633)
* Fix lint issues from v1.62.0 upgrade

* Fix xlMetaV2TrimData version checks.
2024-11-11 06:51:43 -08:00

383 lines
12 KiB
Go

// Copyright (c) 2015-2021 MinIO, Inc.
//
// This file is part of MinIO Object Storage stack
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Affero General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
package cmd
import (
"context"
"encoding/binary"
"errors"
"hash/crc32"
"github.com/minio/pkg/v3/sync/errgroup"
)
// counterMap type adds GetValueWithQuorum method to a map[T]int used to count occurrences of values of type T.
type counterMap[T comparable] map[T]int
// GetValueWithQuorum returns the first key which occurs >= quorum number of times.
func (c counterMap[T]) GetValueWithQuorum(quorum int) (T, bool) {
var zero T
for x, count := range c {
if count >= quorum {
return x, true
}
}
return zero, false
}
// figure out the most commonVersions across disk that satisfies
// the 'writeQuorum' this function returns "" if quorum cannot
// be achieved and disks have too many inconsistent versions.
func reduceCommonVersions(diskVersions [][]byte, writeQuorum int) (versions []byte) {
diskVersionsCount := make(map[uint64]int)
for _, versions := range diskVersions {
if len(versions) > 0 {
diskVersionsCount[binary.BigEndian.Uint64(versions)]++
}
}
var commonVersions uint64
maxCnt := 0
for versions, count := range diskVersionsCount {
if maxCnt < count {
maxCnt = count
commonVersions = versions
}
}
if maxCnt >= writeQuorum {
for _, versions := range diskVersions {
if binary.BigEndian.Uint64(versions) == commonVersions {
return versions
}
}
}
return []byte{}
}
// figure out the most commonVersions across disk that satisfies
// the 'writeQuorum' this function returns '0' if quorum cannot
// be achieved and disks have too many inconsistent versions.
func reduceCommonDataDir(dataDirs []string, writeQuorum int) (dataDir string) {
dataDirsCount := make(map[string]int)
for _, ddir := range dataDirs {
dataDirsCount[ddir]++
}
maxCnt := 0
for ddir, count := range dataDirsCount {
if maxCnt < count {
maxCnt = count
dataDir = ddir
}
}
if maxCnt >= writeQuorum {
return dataDir
}
return ""
}
// Returns number of errors that occurred the most (incl. nil) and the
// corresponding error value. NB When there is more than one error value that
// occurs maximum number of times, the error value returned depends on how
// golang's map orders keys. This doesn't affect correctness as long as quorum
// value is greater than or equal to simple majority, since none of the equally
// maximal values would occur quorum or more number of times.
func reduceErrs(errs []error, ignoredErrs []error) (maxCount int, maxErr error) {
errorCounts := make(map[error]int)
for _, err := range errs {
if IsErrIgnored(err, ignoredErrs...) {
continue
}
// Errors due to context cancellation may be wrapped - group them by context.Canceled.
if errors.Is(err, context.Canceled) {
errorCounts[context.Canceled]++
continue
}
errorCounts[err]++
}
maxCnt := 0
for err, count := range errorCounts {
switch {
case maxCnt < count:
maxCnt = count
maxErr = err
// Prefer `nil` over other error values with the same
// number of occurrences.
case maxCnt == count && err == nil:
maxErr = err
}
}
return maxCnt, maxErr
}
// reduceQuorumErrs behaves like reduceErrs by only for returning
// values of maximally occurring errors validated against a generic
// quorum number that can be read or write quorum depending on usage.
func reduceQuorumErrs(ctx context.Context, errs []error, ignoredErrs []error, quorum int, quorumErr error) error {
if contextCanceled(ctx) {
return context.Canceled
}
maxCount, maxErr := reduceErrs(errs, ignoredErrs)
if maxCount >= quorum {
return maxErr
}
return quorumErr
}
// reduceReadQuorumErrs behaves like reduceErrs but only for returning
// values of maximally occurring errors validated against readQuorum.
func reduceReadQuorumErrs(ctx context.Context, errs []error, ignoredErrs []error, readQuorum int) (maxErr error) {
return reduceQuorumErrs(ctx, errs, ignoredErrs, readQuorum, errErasureReadQuorum)
}
// reduceWriteQuorumErrs behaves like reduceErrs but only for returning
// values of maximally occurring errors validated against writeQuorum.
func reduceWriteQuorumErrs(ctx context.Context, errs []error, ignoredErrs []error, writeQuorum int) (maxErr error) {
return reduceQuorumErrs(ctx, errs, ignoredErrs, writeQuorum, errErasureWriteQuorum)
}
// Similar to 'len(slice)' but returns the actual elements count
// skipping the unallocated elements.
func diskCount(disks []StorageAPI) int {
diskCount := 0
for _, disk := range disks {
if disk == nil {
continue
}
diskCount++
}
return diskCount
}
// hashOrder - hashes input key to return consistent
// hashed integer slice. Returned integer order is salted
// with an input key. This results in consistent order.
// NOTE: collisions are fine, we are not looking for uniqueness
// in the slices returned.
func hashOrder(key string, cardinality int) []int {
if cardinality <= 0 {
// Returns an empty int slice for cardinality < 0.
return nil
}
nums := make([]int, cardinality)
keyCrc := crc32.Checksum([]byte(key), crc32.IEEETable)
start := int(keyCrc % uint32(cardinality))
for i := 1; i <= cardinality; i++ {
nums[i-1] = 1 + ((start + i) % cardinality)
}
return nums
}
// Reads all `xl.meta` metadata as a FileInfo slice.
// Returns error slice indicating the failed metadata reads.
func readAllFileInfo(ctx context.Context, disks []StorageAPI, origbucket string, bucket, object, versionID string, readData, healing bool) ([]FileInfo, []error) {
metadataArray := make([]FileInfo, len(disks))
opts := ReadOptions{
ReadData: readData,
Healing: healing,
}
g := errgroup.WithNErrs(len(disks))
// Read `xl.meta` in parallel across disks.
for index := range disks {
index := index
g.Go(func() (err error) {
if disks[index] == nil {
return errDiskNotFound
}
metadataArray[index], err = disks[index].ReadVersion(ctx, origbucket, bucket, object, versionID, opts)
return err
}, index)
}
return metadataArray, g.Wait()
}
// shuffleDisksAndPartsMetadataByIndex this function should be always used by GetObjectNInfo()
// and CompleteMultipartUpload code path, it is not meant to be used with PutObject,
// NewMultipartUpload metadata shuffling.
func shuffleDisksAndPartsMetadataByIndex(disks []StorageAPI, metaArr []FileInfo, fi FileInfo) (shuffledDisks []StorageAPI, shuffledPartsMetadata []FileInfo) {
shuffledDisks = make([]StorageAPI, len(disks))
shuffledPartsMetadata = make([]FileInfo, len(disks))
distribution := fi.Erasure.Distribution
var inconsistent int
for i, meta := range metaArr {
if disks[i] == nil {
// Assuming offline drives as inconsistent,
// to be safe and fallback to original
// distribution order.
inconsistent++
continue
}
if !meta.IsValid() {
inconsistent++
continue
}
if meta.XLV1 != fi.XLV1 {
inconsistent++
continue
}
// check if erasure distribution order matches the index
// position if this is not correct we discard the disk
// and move to collect others
if distribution[i] != meta.Erasure.Index {
inconsistent++ // keep track of inconsistent entries
continue
}
shuffledDisks[meta.Erasure.Index-1] = disks[i]
shuffledPartsMetadata[meta.Erasure.Index-1] = metaArr[i]
}
// Inconsistent meta info is with in the limit of
// expected quorum, proceed with EcIndex based
// disk order.
if inconsistent < fi.Erasure.ParityBlocks {
return shuffledDisks, shuffledPartsMetadata
}
// fall back to original distribution based order.
return shuffleDisksAndPartsMetadata(disks, metaArr, fi)
}
// Return shuffled partsMetadata depending on fi.Distribution.
// additional validation is attempted and invalid metadata is
// automatically skipped only when fi.ModTime is non-zero
// indicating that this is called during read-phase
func shuffleDisksAndPartsMetadata(disks []StorageAPI, partsMetadata []FileInfo, fi FileInfo) (shuffledDisks []StorageAPI, shuffledPartsMetadata []FileInfo) {
shuffledDisks = make([]StorageAPI, len(disks))
shuffledPartsMetadata = make([]FileInfo, len(partsMetadata))
distribution := fi.Erasure.Distribution
init := fi.ModTime.IsZero()
// Shuffle slice xl metadata for expected distribution.
for index := range partsMetadata {
if disks[index] == nil {
continue
}
if !init && !partsMetadata[index].IsValid() {
// Check for parts metadata validity for only
// fi.ModTime is not empty - ModTime is always set,
// if object was ever written previously.
continue
}
if !init && fi.XLV1 != partsMetadata[index].XLV1 {
continue
}
blockIndex := distribution[index]
shuffledPartsMetadata[blockIndex-1] = partsMetadata[index]
shuffledDisks[blockIndex-1] = disks[index]
}
return shuffledDisks, shuffledPartsMetadata
}
// Return shuffled partsMetadata depending on distribution.
func shufflePartsMetadata(partsMetadata []FileInfo, distribution []int) (shuffledPartsMetadata []FileInfo) {
if distribution == nil {
return partsMetadata
}
shuffledPartsMetadata = make([]FileInfo, len(partsMetadata))
// Shuffle slice xl metadata for expected distribution.
for index := range partsMetadata {
blockIndex := distribution[index]
shuffledPartsMetadata[blockIndex-1] = partsMetadata[index]
}
return shuffledPartsMetadata
}
// shuffleDisks - shuffle input disks slice depending on the
// erasure distribution. Return shuffled slice of disks with
// their expected distribution.
func shuffleDisks(disks []StorageAPI, distribution []int) (shuffledDisks []StorageAPI) {
if distribution == nil {
return disks
}
shuffledDisks = make([]StorageAPI, len(disks))
// Shuffle disks for expected distribution.
for index := range disks {
blockIndex := distribution[index]
shuffledDisks[blockIndex-1] = disks[index]
}
return shuffledDisks
}
// evalDisks - returns a new slice of disks where nil is set if
// the corresponding error in errs slice is not nil
func evalDisks(disks []StorageAPI, errs []error) []StorageAPI {
if len(errs) != len(disks) {
bugLogIf(GlobalContext, errors.New("unexpected drives/errors slice length"))
return nil
}
newDisks := make([]StorageAPI, len(disks))
for index := range errs {
if errs[index] == nil {
newDisks[index] = disks[index]
} else {
newDisks[index] = nil
}
}
return newDisks
}
// Errors specifically generated by calculatePartSizeFromIdx function.
var (
errPartSizeZero = errors.New("Part size cannot be zero")
errPartSizeIndex = errors.New("Part index cannot be smaller than 1")
)
// calculatePartSizeFromIdx calculates the part size according to input index.
// returns error if totalSize is -1, partSize is 0, partIndex is 0.
func calculatePartSizeFromIdx(ctx context.Context, totalSize int64, partSize int64, partIndex int) (currPartSize int64, err error) {
if totalSize < -1 {
return 0, errInvalidArgument
}
if partSize == 0 {
return 0, errPartSizeZero
}
if partIndex < 1 {
return 0, errPartSizeIndex
}
if totalSize == -1 {
return -1, nil
}
if totalSize > 0 {
// Compute the total count of parts
partsCount := totalSize/partSize + 1
// Return the part's size
switch {
case int64(partIndex) < partsCount:
currPartSize = partSize
case int64(partIndex) == partsCount:
// Size of last part
currPartSize = totalSize % partSize
default:
currPartSize = 0
}
}
return currPartSize, nil
}