// Copyright 2023 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. // Package toolchain implements dynamic switching of Go toolchains. package toolchain import ( "context" "errors" "flag" "fmt" "go/build" "io/fs" "log" "os" "path/filepath" "runtime" "strconv" "strings" "cmd/go/internal/base" "cmd/go/internal/cfg" "cmd/go/internal/gover" "cmd/go/internal/modfetch" "cmd/go/internal/modload" "cmd/go/internal/run" "cmd/go/internal/work" "cmd/internal/telemetry" "golang.org/x/mod/module" ) const ( // We download golang.org/toolchain version v0.0.1-.-. // If the 0.0.1 indicates anything at all, its the version of the toolchain packaging: // if for some reason we needed to change the way toolchains are packaged into // module zip files in a future version of Go, we could switch to v0.0.2 and then // older versions expecting the old format could use v0.0.1 and newer versions // would use v0.0.2. Of course, then we'd also have to publish two of each // module zip file. It's not likely we'll ever need to change this. gotoolchainModule = "golang.org/toolchain" gotoolchainVersion = "v0.0.1" // targetEnv is a special environment variable set to the expected // toolchain version during the toolchain switch by the parent // process and cleared in the child process. When set, that indicates // to the child to confirm that it provides the expected toolchain version. targetEnv = "GOTOOLCHAIN_INTERNAL_SWITCH_VERSION" // countEnv is a special environment variable // that is incremented during each toolchain switch, to detect loops. // It is cleared before invoking programs in 'go run', 'go test', 'go generate', and 'go tool' // by invoking them in an environment filtered with FilterEnv, // so user programs should not see this in their environment. countEnv = "GOTOOLCHAIN_INTERNAL_SWITCH_COUNT" // maxSwitch is the maximum toolchain switching depth. // Most uses should never see more than three. // (Perhaps one for the initial GOTOOLCHAIN dispatch, // a second for go get doing an upgrade, and a third if // for some reason the chosen upgrade version is too small // by a little.) // When the count reaches maxSwitch - 10, we start logging // the switched versions for debugging before crashing with // a fatal error upon reaching maxSwitch. // That should be enough to see the repetition. maxSwitch = 100 ) // FilterEnv returns a copy of env with internal GOTOOLCHAIN environment // variables filtered out. func FilterEnv(env []string) []string { // Note: Don't need to filter out targetEnv because Switch does that. var out []string for _, e := range env { if strings.HasPrefix(e, countEnv+"=") { continue } out = append(out, e) } return out } var counterErrorsInvalidToolchainInFile = telemetry.NewCounter("go/errors:invalid-toolchain-in-file") // Select invokes a different Go toolchain if directed by // the GOTOOLCHAIN environment variable or the user's configuration // or go.mod file. // It must be called early in startup. // See https://go.dev/doc/toolchain#select. func Select() { log.SetPrefix("go: ") defer log.SetPrefix("") if !modload.WillBeEnabled() { return } // As a special case, let "go env GOTOOLCHAIN" and "go env -w GOTOOLCHAIN=..." // be handled by the local toolchain, since an older toolchain may not understand it. // This provides an easy way out of "go env -w GOTOOLCHAIN=go1.19" and makes // sure that "go env GOTOOLCHAIN" always prints the local go command's interpretation of it. // We look for these specific command lines in order to avoid mishandling // // GOTOOLCHAIN=go1.999 go env -newflag GOTOOLCHAIN // // where -newflag is a flag known to Go 1.999 but not known to us. if (len(os.Args) == 3 && os.Args[1] == "env" && os.Args[2] == "GOTOOLCHAIN") || (len(os.Args) == 4 && os.Args[1] == "env" && os.Args[2] == "-w" && strings.HasPrefix(os.Args[3], "GOTOOLCHAIN=")) { return } // As a special case, let "go env GOMOD" and "go env GOWORK" be handled by // the local toolchain. Users expect to be able to look up GOMOD and GOWORK // since the go.mod and go.work file need to be determined to determine // the minimum toolchain. See issue #61455. if len(os.Args) == 3 && os.Args[1] == "env" && (os.Args[2] == "GOMOD" || os.Args[2] == "GOWORK") { return } // Interpret GOTOOLCHAIN to select the Go toolchain to run. gotoolchain := cfg.Getenv("GOTOOLCHAIN") gover.Startup.GOTOOLCHAIN = gotoolchain if gotoolchain == "" { // cfg.Getenv should fall back to $GOROOT/go.env, // so this should not happen, unless a packager // has deleted the GOTOOLCHAIN line from go.env. // It can also happen if GOROOT is missing or broken, // in which case best to let the go command keep running // and diagnose the problem. return } // Note: minToolchain is what https://go.dev/doc/toolchain#select calls the default toolchain. minToolchain := gover.LocalToolchain() minVers := gover.Local() var mode string if gotoolchain == "auto" { mode = "auto" } else if gotoolchain == "path" { mode = "path" } else { min, suffix, plus := strings.Cut(gotoolchain, "+") // go1.2.3+auto if min != "local" { v := gover.FromToolchain(min) if v == "" { if plus { base.Fatalf("invalid GOTOOLCHAIN %q: invalid minimum toolchain %q", gotoolchain, min) } base.Fatalf("invalid GOTOOLCHAIN %q", gotoolchain) } minToolchain = min minVers = v } if plus && suffix != "auto" && suffix != "path" { base.Fatalf("invalid GOTOOLCHAIN %q: only version suffixes are +auto and +path", gotoolchain) } mode = suffix } gotoolchain = minToolchain if (mode == "auto" || mode == "path") && !goInstallVersion() { // Read go.mod to find new minimum and suggested toolchain. file, goVers, toolchain := modGoToolchain() gover.Startup.AutoFile = file if toolchain == "default" { // "default" means always use the default toolchain, // which is already set, so nothing to do here. // Note that if we have Go 1.21 installed originally, // GOTOOLCHAIN=go1.30.0+auto or GOTOOLCHAIN=go1.30.0, // and the go.mod says "toolchain default", we use Go 1.30, not Go 1.21. // That is, default overrides the "auto" part of the calculation // but not the minimum that the user has set. // Of course, if the go.mod also says "go 1.35", using Go 1.30 // will provoke an error about the toolchain being too old. // That's what people who use toolchain default want: // only ever use the toolchain configured by the user // (including its environment and go env -w file). gover.Startup.AutoToolchain = toolchain } else { if toolchain != "" { // Accept toolchain only if it is > our min. // (If it is equal, then min satisfies it anyway: that can matter if min // has a suffix like "go1.21.1-foo" and toolchain is "go1.21.1".) toolVers := gover.FromToolchain(toolchain) if toolVers == "" || (!strings.HasPrefix(toolchain, "go") && !strings.Contains(toolchain, "-go")) { counterErrorsInvalidToolchainInFile.Inc() base.Fatalf("invalid toolchain %q in %s", toolchain, base.ShortPath(file)) } if gover.Compare(toolVers, minVers) > 0 { gotoolchain = toolchain minVers = toolVers gover.Startup.AutoToolchain = toolchain } } if gover.Compare(goVers, minVers) > 0 { gotoolchain = "go" + goVers gover.Startup.AutoGoVersion = goVers gover.Startup.AutoToolchain = "" // in case we are overriding it for being too old } } } // If we are invoked as a target toolchain, confirm that // we provide the expected version and then run. // This check is delayed until after the handling of auto and path // so that we have initialized gover.Startup for use in error messages. if target := os.Getenv(targetEnv); target != "" && TestVersionSwitch != "loop" { if gover.LocalToolchain() != target { base.Fatalf("toolchain %v invoked to provide %v", gover.LocalToolchain(), target) } os.Unsetenv(targetEnv) // Note: It is tempting to check that if gotoolchain != "local" // then target == gotoolchain here, as a sanity check that // the child has made the same version determination as the parent. // This turns out not always to be the case. Specifically, if we are // running Go 1.21 with GOTOOLCHAIN=go1.22+auto, which invokes // Go 1.22, then 'go get go@1.23.0' or 'go get needs_go_1_23' // will invoke Go 1.23, but as the Go 1.23 child the reason for that // will not be apparent here: it will look like we should be using Go 1.22. // We rely on the targetEnv being set to know not to downgrade. // A longer term problem with the sanity check is that the exact details // may change over time: there may be other reasons that a future Go // version might invoke an older one, and the older one won't know why. // Best to just accept that we were invoked to provide a specific toolchain // (which we just checked) and leave it at that. return } if gotoolchain == "local" || gotoolchain == gover.LocalToolchain() { // Let the current binary handle the command. return } // Minimal sanity check of GOTOOLCHAIN setting before search. // We want to allow things like go1.20.3 but also gccgo-go1.20.3. // We want to disallow mistakes / bad ideas like GOTOOLCHAIN=bash, // since we will find that in the path lookup. if !strings.HasPrefix(gotoolchain, "go1") && !strings.Contains(gotoolchain, "-go1") { base.Fatalf("invalid GOTOOLCHAIN %q", gotoolchain) } counterSelectExec.Inc() Exec(gotoolchain) } var counterSelectExec = telemetry.NewCounter("go/toolchain/select-exec") // TestVersionSwitch is set in the test go binary to the value in $TESTGO_VERSION_SWITCH. // Valid settings are: // // "switch" - simulate version switches by reinvoking the test go binary with a different TESTGO_VERSION. // "mismatch" - like "switch" but forget to set TESTGO_VERSION, so it looks like we invoked a mismatched toolchain // "loop" - like "mismatch" but forget the target check, causing a toolchain switching loop var TestVersionSwitch string // Exec invokes the specified Go toolchain or else prints an error and exits the process. // If $GOTOOLCHAIN is set to path or min+path, Exec only considers the PATH // as a source of Go toolchains. Otherwise Exec tries the PATH but then downloads // a toolchain if necessary. func Exec(gotoolchain string) { log.SetPrefix("go: ") writeBits = sysWriteBits() count, _ := strconv.Atoi(os.Getenv(countEnv)) if count >= maxSwitch-10 { fmt.Fprintf(os.Stderr, "go: switching from go%v to %v [depth %d]\n", gover.Local(), gotoolchain, count) } if count >= maxSwitch { base.Fatalf("too many toolchain switches") } os.Setenv(countEnv, fmt.Sprint(count+1)) env := cfg.Getenv("GOTOOLCHAIN") pathOnly := env == "path" || strings.HasSuffix(env, "+path") // For testing, if TESTGO_VERSION is already in use // (only happens in the cmd/go test binary) // and TESTGO_VERSION_SWITCH=switch is set, // "switch" toolchains by changing TESTGO_VERSION // and reinvoking the current binary. // The special cases =loop and =mismatch skip the // setting of TESTGO_VERSION so that it looks like we // accidentally invoked the wrong toolchain, // to test detection of that failure mode. switch TestVersionSwitch { case "switch": os.Setenv("TESTGO_VERSION", gotoolchain) fallthrough case "loop", "mismatch": exe, err := os.Executable() if err != nil { base.Fatalf("%v", err) } execGoToolchain(gotoolchain, os.Getenv("GOROOT"), exe) } // Look in PATH for the toolchain before we download one. // This allows custom toolchains as well as reuse of toolchains // already installed using go install golang.org/dl/go1.2.3@latest. if exe, err := cfg.LookPath(gotoolchain); err == nil { execGoToolchain(gotoolchain, "", exe) } // GOTOOLCHAIN=auto looks in PATH and then falls back to download. // GOTOOLCHAIN=path only looks in PATH. if pathOnly { base.Fatalf("cannot find %q in PATH", gotoolchain) } // Set up modules without an explicit go.mod, to download distribution. modload.Reset() modload.ForceUseModules = true modload.RootMode = modload.NoRoot modload.Init() // Download and unpack toolchain module into module cache. // Note that multiple go commands might be doing this at the same time, // and that's OK: the module cache handles that case correctly. m := module.Version{ Path: gotoolchainModule, Version: gotoolchainVersion + "-" + gotoolchain + "." + runtime.GOOS + "-" + runtime.GOARCH, } dir, err := modfetch.Download(context.Background(), m) if err != nil { if errors.Is(err, fs.ErrNotExist) { base.Fatalf("download %s for %s/%s: toolchain not available", gotoolchain, runtime.GOOS, runtime.GOARCH) } base.Fatalf("download %s: %v", gotoolchain, err) } // On first use after download, set the execute bits on the commands // so that we can run them. Note that multiple go commands might be // doing this at the same time, but if so no harm done. if runtime.GOOS != "windows" { info, err := os.Stat(filepath.Join(dir, "bin/go")) if err != nil { base.Fatalf("download %s: %v", gotoolchain, err) } if info.Mode()&0111 == 0 { // allowExec sets the exec permission bits on all files found in dir. allowExec := func(dir string) { err := filepath.WalkDir(dir, func(path string, d fs.DirEntry, err error) error { if err != nil { return err } if !d.IsDir() { info, err := os.Stat(path) if err != nil { return err } if err := os.Chmod(path, info.Mode()&0777|0111); err != nil { return err } } return nil }) if err != nil { base.Fatalf("download %s: %v", gotoolchain, err) } } // Set the bits in pkg/tool before bin/go. // If we are racing with another go command and do bin/go first, // then the check of bin/go above might succeed, the other go command // would skip its own mode-setting, and then the go command might // try to run a tool before we get to setting the bits on pkg/tool. // Setting pkg/tool before bin/go avoids that ordering problem. // The only other tool the go command invokes is gofmt, // so we set that one explicitly before handling bin (which will include bin/go). allowExec(filepath.Join(dir, "pkg/tool")) allowExec(filepath.Join(dir, "bin/gofmt")) allowExec(filepath.Join(dir, "bin")) } } srcUGoMod := filepath.Join(dir, "src/_go.mod") srcGoMod := filepath.Join(dir, "src/go.mod") if size(srcGoMod) != size(srcUGoMod) { err := filepath.WalkDir(dir, func(path string, d fs.DirEntry, err error) error { if err != nil { return err } if path == srcUGoMod { // Leave for last, in case we are racing with another go command. return nil } if pdir, name := filepath.Split(path); name == "_go.mod" { if err := raceSafeCopy(path, pdir+"go.mod"); err != nil { return err } } return nil }) // Handle src/go.mod; this is the signal to other racing go commands // that everything is okay and they can skip this step. if err == nil { err = raceSafeCopy(srcUGoMod, srcGoMod) } if err != nil { base.Fatalf("download %s: %v", gotoolchain, err) } } // Reinvoke the go command. execGoToolchain(gotoolchain, dir, filepath.Join(dir, "bin/go")) } func size(path string) int64 { info, err := os.Stat(path) if err != nil { return -1 } return info.Size() } var writeBits fs.FileMode // raceSafeCopy copies the file old to the file new, being careful to ensure // that if multiple go commands call raceSafeCopy(old, new) at the same time, // they don't interfere with each other: both will succeed and return and // later observe the correct content in new. Like in the build cache, we arrange // this by opening new without truncation and then writing the content. // Both go commands can do this simultaneously and will write the same thing // (old never changes content). func raceSafeCopy(old, new string) error { oldInfo, err := os.Stat(old) if err != nil { return err } newInfo, err := os.Stat(new) if err == nil && newInfo.Size() == oldInfo.Size() { return nil } data, err := os.ReadFile(old) if err != nil { return err } // The module cache has unwritable directories by default. // Restore the user write bit in the directory so we can create // the new go.mod file. We clear it again at the end on a // best-effort basis (ignoring failures). dir := filepath.Dir(old) info, err := os.Stat(dir) if err != nil { return err } if err := os.Chmod(dir, info.Mode()|writeBits); err != nil { return err } defer os.Chmod(dir, info.Mode()) // Note: create the file writable, so that a racing go command // doesn't get an error before we store the actual data. f, err := os.OpenFile(new, os.O_CREATE|os.O_WRONLY, writeBits&^0o111) if err != nil { // If OpenFile failed because a racing go command completed our work // (and then OpenFile failed because the directory or file is now read-only), // count that as a success. if size(old) == size(new) { return nil } return err } defer os.Chmod(new, oldInfo.Mode()) if _, err := f.Write(data); err != nil { f.Close() return err } return f.Close() } // modGoToolchain finds the enclosing go.work or go.mod file // and returns the go version and toolchain lines from the file. // The toolchain line overrides the version line func modGoToolchain() (file, goVers, toolchain string) { wd := base.UncachedCwd() file = modload.FindGoWork(wd) // $GOWORK can be set to a file that does not yet exist, if we are running 'go work init'. // Do not try to load the file in that case if _, err := os.Stat(file); err != nil { file = "" } if file == "" { file = modload.FindGoMod(wd) } if file == "" { return "", "", "" } data, err := os.ReadFile(file) if err != nil { base.Fatalf("%v", err) } return file, gover.GoModLookup(data, "go"), gover.GoModLookup(data, "toolchain") } // goInstallVersion reports whether the command line is go install m@v or go run m@v. // If so, Select must not read the go.mod or go.work file in "auto" or "path" mode. func goInstallVersion() bool { // Note: We assume there are no flags between 'go' and 'install' or 'run'. // During testing there are some debugging flags that are accepted // in that position, but in production go binaries there are not. if len(os.Args) < 3 { return false } var cmdFlags *flag.FlagSet switch os.Args[1] { default: // Command doesn't support a pkg@version as the main module. return false case "install": cmdFlags = &work.CmdInstall.Flag case "run": cmdFlags = &run.CmdRun.Flag } // The modcachrw flag is unique, in that it affects how we fetch the // requested module to even figure out what toolchain it needs. // We need to actually set it before we check the toolchain version. // (See https://go.dev/issue/64282.) modcacherwFlag := cmdFlags.Lookup("modcacherw") if modcacherwFlag == nil { base.Fatalf("internal error: modcacherw flag not registered for command") } modcacherwVal, ok := modcacherwFlag.Value.(interface { IsBoolFlag() bool flag.Value }) if !ok || !modcacherwVal.IsBoolFlag() { base.Fatalf("internal error: modcacherw is not a boolean flag") } // Make a best effort to parse the command's args to find the pkg@version // argument and the -modcacherw flag. var ( pkgArg string modcacherwSeen bool ) for args := os.Args[2:]; len(args) > 0; { a := args[0] args = args[1:] if a == "--" { if len(args) == 0 { return false } pkgArg = args[0] break } a, ok := strings.CutPrefix(a, "-") if !ok { // Not a flag argument. Must be a package. pkgArg = a break } a = strings.TrimPrefix(a, "-") // Treat --flag as -flag. name, val, hasEq := strings.Cut(a, "=") if name == "modcacherw" { if !hasEq { val = "true" } if err := modcacherwVal.Set(val); err != nil { return false } modcacherwSeen = true continue } if hasEq { // Already has a value; don't bother parsing it. continue } f := run.CmdRun.Flag.Lookup(a) if f == nil { // We don't know whether this flag is a boolean. if os.Args[1] == "run" { // We don't know where to find the pkg@version argument. // For run, the pkg@version can be anywhere on the command line, // because it is preceded by run flags and followed by arguments to the // program being run. Since we don't know whether this flag takes // an argument, we can't reliably identify the end of the run flags. // Just give up and let the user clarify using the "=" form.. return false } // We would like to let 'go install -newflag pkg@version' work even // across a toolchain switch. To make that work, assume by default that // the pkg@version is the last argument and skip the remaining args unless // we spot a plausible "-modcacherw" flag. for len(args) > 0 { a := args[0] name, _, _ := strings.Cut(a, "=") if name == "-modcacherw" || name == "--modcacherw" { break } if len(args) == 1 && !strings.HasPrefix(a, "-") { pkgArg = a } args = args[1:] } continue } if bf, ok := f.Value.(interface{ IsBoolFlag() bool }); !ok || !bf.IsBoolFlag() { // The next arg is the value for this flag. Skip it. args = args[1:] continue } } if !strings.Contains(pkgArg, "@") || build.IsLocalImport(pkgArg) || filepath.IsAbs(pkgArg) { return false } path, version, _ := strings.Cut(pkgArg, "@") if path == "" || version == "" || gover.IsToolchain(path) { return false } if !modcacherwSeen && base.InGOFLAGS("-modcacherw") { fs := flag.NewFlagSet("goInstallVersion", flag.ExitOnError) fs.Var(modcacherwVal, "modcacherw", modcacherwFlag.Usage) base.SetFromGOFLAGS(fs) } // It would be correct to simply return true here, bypassing use // of the current go.mod or go.work, and let "go run" or "go install" // do the rest, including a toolchain switch. // Our goal instead is, since we have gone to the trouble of handling // unknown flags to some degree, to run the switch now, so that // these commands can switch to a newer toolchain directed by the // go.mod which may actually understand the flag. // This was brought up during the go.dev/issue/57001 proposal discussion // and may end up being common in self-contained "go install" or "go run" // command lines if we add new flags in the future. // Set up modules without an explicit go.mod, to download go.mod. modload.ForceUseModules = true modload.RootMode = modload.NoRoot modload.Init() defer modload.Reset() // See internal/load.PackagesAndErrorsOutsideModule ctx := context.Background() allowed := modload.CheckAllowed if modload.IsRevisionQuery(path, version) { // Don't check for retractions if a specific revision is requested. allowed = nil } noneSelected := func(path string) (version string) { return "none" } _, err := modload.QueryPackages(ctx, path, version, noneSelected, allowed) if errors.Is(err, gover.ErrTooNew) { // Run early switch, same one go install or go run would eventually do, // if it understood all the command-line flags. SwitchOrFatal(ctx, err) } return true // pkg@version found }