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395 lines
12 KiB
Go
395 lines
12 KiB
Go
// Copyright (c) 2015-2021 MinIO, Inc.
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//
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// This file is part of MinIO Object Storage stack
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//
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Affero General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// This program is distributed in the hope that it will be useful
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Affero General Public License for more details.
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//
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// You should have received a copy of the GNU Affero General Public License
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// along with this program. If not, see <http://www.gnu.org/licenses/>.
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package cmd
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import (
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"fmt"
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"sort"
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"strconv"
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"strings"
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"github.com/minio/minio-go/v7/pkg/set"
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"github.com/minio/minio/internal/config"
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"github.com/minio/pkg/ellipses"
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"github.com/minio/pkg/env"
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)
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// This file implements and supports ellipses pattern for
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// `minio server` command line arguments.
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// Endpoint set represents parsed ellipses values, also provides
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// methods to get the sets of endpoints.
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type endpointSet struct {
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argPatterns []ellipses.ArgPattern
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endpoints []string // Endpoints saved from previous GetEndpoints().
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setIndexes [][]uint64 // All the sets.
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}
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// Supported set sizes this is used to find the optimal
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// single set size.
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var setSizes = []uint64{4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16}
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// getDivisibleSize - returns a greatest common divisor of
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// all the ellipses sizes.
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func getDivisibleSize(totalSizes []uint64) (result uint64) {
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gcd := func(x, y uint64) uint64 {
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for y != 0 {
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x, y = y, x%y
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}
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return x
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}
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result = totalSizes[0]
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for i := 1; i < len(totalSizes); i++ {
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result = gcd(result, totalSizes[i])
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}
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return result
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}
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// isValidSetSize - checks whether given count is a valid set size for erasure coding.
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var isValidSetSize = func(count uint64) bool {
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return (count >= setSizes[0] && count <= setSizes[len(setSizes)-1])
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}
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func commonSetDriveCount(divisibleSize uint64, setCounts []uint64) (setSize uint64) {
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// prefers setCounts to be sorted for optimal behavior.
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if divisibleSize < setCounts[len(setCounts)-1] {
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return divisibleSize
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}
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// Figure out largest value of total_drives_in_erasure_set which results
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// in least number of total_drives/total_drives_erasure_set ratio.
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prevD := divisibleSize / setCounts[0]
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for _, cnt := range setCounts {
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if divisibleSize%cnt == 0 {
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d := divisibleSize / cnt
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if d <= prevD {
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prevD = d
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setSize = cnt
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}
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}
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}
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return setSize
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}
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// possibleSetCountsWithSymmetry returns symmetrical setCounts based on the
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// input argument patterns, the symmetry calculation is to ensure that
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// we also use uniform number of drives common across all ellipses patterns.
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func possibleSetCountsWithSymmetry(setCounts []uint64, argPatterns []ellipses.ArgPattern) []uint64 {
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var newSetCounts = make(map[uint64]struct{})
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for _, ss := range setCounts {
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var symmetry bool
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for _, argPattern := range argPatterns {
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for _, p := range argPattern {
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if uint64(len(p.Seq)) > ss {
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symmetry = uint64(len(p.Seq))%ss == 0
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} else {
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symmetry = ss%uint64(len(p.Seq)) == 0
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}
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}
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}
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// With no arg patterns, it is expected that user knows
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// the right symmetry, so either ellipses patterns are
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// provided (recommended) or no ellipses patterns.
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if _, ok := newSetCounts[ss]; !ok && (symmetry || argPatterns == nil) {
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newSetCounts[ss] = struct{}{}
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}
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}
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setCounts = []uint64{}
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for setCount := range newSetCounts {
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setCounts = append(setCounts, setCount)
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}
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// Not necessarily needed but it ensures to the readers
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// eyes that we prefer a sorted setCount slice for the
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// subsequent function to figure out the right common
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// divisor, it avoids loops.
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sort.Slice(setCounts, func(i, j int) bool {
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return setCounts[i] < setCounts[j]
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})
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return setCounts
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}
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// getSetIndexes returns list of indexes which provides the set size
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// on each index, this function also determines the final set size
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// The final set size has the affinity towards choosing smaller
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// indexes (total sets)
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func getSetIndexes(args []string, totalSizes []uint64, customSetDriveCount uint64, argPatterns []ellipses.ArgPattern) (setIndexes [][]uint64, err error) {
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if len(totalSizes) == 0 || len(args) == 0 {
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return nil, errInvalidArgument
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}
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setIndexes = make([][]uint64, len(totalSizes))
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for _, totalSize := range totalSizes {
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// Check if totalSize has minimum range upto setSize
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if totalSize < setSizes[0] || totalSize < customSetDriveCount {
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msg := fmt.Sprintf("Incorrect number of endpoints provided %s", args)
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return nil, config.ErrInvalidNumberOfErasureEndpoints(nil).Msg(msg)
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}
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}
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commonSize := getDivisibleSize(totalSizes)
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possibleSetCounts := func(setSize uint64) (ss []uint64) {
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for _, s := range setSizes {
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if setSize%s == 0 {
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ss = append(ss, s)
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}
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}
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return ss
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}
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setCounts := possibleSetCounts(commonSize)
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if len(setCounts) == 0 {
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msg := fmt.Sprintf("Incorrect number of endpoints provided %s, number of disks %d is not divisible by any supported erasure set sizes %d", args, commonSize, setSizes)
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return nil, config.ErrInvalidNumberOfErasureEndpoints(nil).Msg(msg)
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}
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var setSize uint64
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// Custom set drive count allows to override automatic distribution.
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// only meant if you want to further optimize drive distribution.
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if customSetDriveCount > 0 {
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msg := fmt.Sprintf("Invalid set drive count. Acceptable values for %d number drives are %d", commonSize, setCounts)
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var found bool
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for _, ss := range setCounts {
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if ss == customSetDriveCount {
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found = true
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}
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}
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if !found {
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return nil, config.ErrInvalidErasureSetSize(nil).Msg(msg)
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}
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// No automatic symmetry calculation expected, user is on their own
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setSize = customSetDriveCount
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globalCustomErasureDriveCount = true
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} else {
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// Returns possible set counts with symmetry.
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setCounts = possibleSetCountsWithSymmetry(setCounts, argPatterns)
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if len(setCounts) == 0 {
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msg := fmt.Sprintf("No symmetric distribution detected with input endpoints provided %s, disks %d cannot be spread symmetrically by any supported erasure set sizes %d", args, commonSize, setSizes)
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return nil, config.ErrInvalidNumberOfErasureEndpoints(nil).Msg(msg)
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}
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// Final set size with all the symmetry accounted for.
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setSize = commonSetDriveCount(commonSize, setCounts)
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}
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// Check whether setSize is with the supported range.
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if !isValidSetSize(setSize) {
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msg := fmt.Sprintf("Incorrect number of endpoints provided %s, number of disks %d is not divisible by any supported erasure set sizes %d", args, commonSize, setSizes)
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return nil, config.ErrInvalidNumberOfErasureEndpoints(nil).Msg(msg)
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}
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for i := range totalSizes {
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for j := uint64(0); j < totalSizes[i]/setSize; j++ {
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setIndexes[i] = append(setIndexes[i], setSize)
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}
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}
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return setIndexes, nil
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}
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// Returns all the expanded endpoints, each argument is expanded separately.
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func (s endpointSet) getEndpoints() (endpoints []string) {
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if len(s.endpoints) != 0 {
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return s.endpoints
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}
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for _, argPattern := range s.argPatterns {
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for _, lbls := range argPattern.Expand() {
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endpoints = append(endpoints, strings.Join(lbls, ""))
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}
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}
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s.endpoints = endpoints
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return endpoints
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}
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// Get returns the sets representation of the endpoints
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// this function also intelligently decides on what will
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// be the right set size etc.
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func (s endpointSet) Get() (sets [][]string) {
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var k = uint64(0)
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endpoints := s.getEndpoints()
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for i := range s.setIndexes {
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for j := range s.setIndexes[i] {
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sets = append(sets, endpoints[k:s.setIndexes[i][j]+k])
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k = s.setIndexes[i][j] + k
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}
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}
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return sets
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}
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// Return the total size for each argument patterns.
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func getTotalSizes(argPatterns []ellipses.ArgPattern) []uint64 {
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var totalSizes []uint64
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for _, argPattern := range argPatterns {
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var totalSize uint64 = 1
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for _, p := range argPattern {
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totalSize = totalSize * uint64(len(p.Seq))
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}
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totalSizes = append(totalSizes, totalSize)
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}
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return totalSizes
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}
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// Parses all arguments and returns an endpointSet which is a collection
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// of endpoints following the ellipses pattern, this is what is used
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// by the object layer for initializing itself.
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func parseEndpointSet(customSetDriveCount uint64, args ...string) (ep endpointSet, err error) {
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var argPatterns = make([]ellipses.ArgPattern, len(args))
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for i, arg := range args {
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patterns, perr := ellipses.FindEllipsesPatterns(arg)
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if perr != nil {
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return endpointSet{}, config.ErrInvalidErasureEndpoints(nil).Msg(perr.Error())
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}
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argPatterns[i] = patterns
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}
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ep.setIndexes, err = getSetIndexes(args, getTotalSizes(argPatterns), customSetDriveCount, argPatterns)
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if err != nil {
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return endpointSet{}, config.ErrInvalidErasureEndpoints(nil).Msg(err.Error())
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}
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ep.argPatterns = argPatterns
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return ep, nil
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}
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// GetAllSets - parses all ellipses input arguments, expands them into
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// corresponding list of endpoints chunked evenly in accordance with a
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// specific set size.
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// For example: {1...64} is divided into 4 sets each of size 16.
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// This applies to even distributed setup syntax as well.
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func GetAllSets(args ...string) ([][]string, error) {
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var customSetDriveCount uint64
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if v := env.Get(EnvErasureSetDriveCount, ""); v != "" {
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driveCount, err := strconv.Atoi(v)
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if err != nil {
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return nil, config.ErrInvalidErasureSetSize(err)
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}
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customSetDriveCount = uint64(driveCount)
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}
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var setArgs [][]string
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if !ellipses.HasEllipses(args...) {
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var setIndexes [][]uint64
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// Check if we have more one args.
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if len(args) > 1 {
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var err error
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setIndexes, err = getSetIndexes(args, []uint64{uint64(len(args))}, customSetDriveCount, nil)
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if err != nil {
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return nil, err
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}
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} else {
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// We are in FS setup, proceed forward.
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setIndexes = [][]uint64{{uint64(len(args))}}
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}
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s := endpointSet{
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endpoints: args,
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setIndexes: setIndexes,
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}
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setArgs = s.Get()
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} else {
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s, err := parseEndpointSet(customSetDriveCount, args...)
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if err != nil {
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return nil, err
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}
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setArgs = s.Get()
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}
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uniqueArgs := set.NewStringSet()
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for _, sargs := range setArgs {
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for _, arg := range sargs {
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if uniqueArgs.Contains(arg) {
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return nil, config.ErrInvalidErasureEndpoints(nil).Msg(fmt.Sprintf("Input args (%s) has duplicate ellipses", args))
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}
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uniqueArgs.Add(arg)
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}
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}
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return setArgs, nil
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}
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// Override set drive count for manual distribution.
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const (
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EnvErasureSetDriveCount = "MINIO_ERASURE_SET_DRIVE_COUNT"
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)
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var (
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globalCustomErasureDriveCount = false
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)
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// CreateServerEndpoints - validates and creates new endpoints from input args, supports
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// both ellipses and without ellipses transparently.
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func createServerEndpoints(serverAddr string, args ...string) (
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endpointServerPools EndpointServerPools, setupType SetupType, err error) {
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if len(args) == 0 {
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return nil, -1, errInvalidArgument
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}
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if !ellipses.HasEllipses(args...) {
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setArgs, err := GetAllSets(args...)
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if err != nil {
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return nil, -1, err
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}
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endpointList, newSetupType, err := CreateEndpoints(serverAddr, false, setArgs...)
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if err != nil {
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return nil, -1, err
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}
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endpointServerPools = append(endpointServerPools, PoolEndpoints{
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SetCount: len(setArgs),
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DrivesPerSet: len(setArgs[0]),
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Endpoints: endpointList,
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})
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setupType = newSetupType
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return endpointServerPools, setupType, nil
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}
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var foundPrevLocal bool
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for _, arg := range args {
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setArgs, err := GetAllSets(arg)
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if err != nil {
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return nil, -1, err
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}
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endpointList, gotSetupType, err := CreateEndpoints(serverAddr, foundPrevLocal, setArgs...)
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if err != nil {
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return nil, -1, err
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}
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if err = endpointServerPools.Add(PoolEndpoints{
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SetCount: len(setArgs),
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DrivesPerSet: len(setArgs[0]),
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Endpoints: endpointList,
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}); err != nil {
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return nil, -1, err
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}
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foundPrevLocal = endpointList.atleastOneEndpointLocal()
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if setupType == UnknownSetupType {
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setupType = gotSetupType
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}
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if setupType == ErasureSetupType && gotSetupType == DistErasureSetupType {
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setupType = DistErasureSetupType
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}
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}
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return endpointServerPools, setupType, nil
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}
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