minio/cmd/erasure-metadata-utils.go
Anis Eleuch 95bf4a57b6
logging: Add subsystem to log API (#19002)
Create new code paths for multiple subsystems in the code. This will
make maintaing this easier later.

Also introduce bugLogIf() for errors that should not happen in the first
place.
2024-04-04 05:04:40 -07:00

337 lines
10 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"
"errors"
"hash/crc32"
"github.com/minio/pkg/v2/sync/errgroup"
)
// 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 reduceCommonVersions(diskVersions []uint64, writeQuorum int) (commonVersions uint64) {
diskVersionsCount := make(map[uint64]int)
for _, versions := range diskVersions {
diskVersionsCount[versions]++
}
max := 0
for versions, count := range diskVersionsCount {
if max < count {
max = count
commonVersions = versions
}
}
if max >= writeQuorum {
return commonVersions
}
return 0
}
// 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]++
}
max := 0
for err, count := range errorCounts {
switch {
case max < count:
max = count
maxErr = err
// Prefer `nil` over other error values with the same
// number of occurrences.
case max == count && err == nil:
maxErr = err
}
}
return max, 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
}