Go is a tool for managing Go source code.
Usage:
go <command> [arguments]
The commands are:
bug start a bug report build compile packages and dependencies clean remove object files and cached files doc show documentation for package or symbol env print Go environment information fix update packages to use new APIs fmt gofmt (reformat) package sources generate generate Go files by processing source get add dependencies to current module and install them install compile and install packages and dependencies list list packages or modules mod module maintenance work workspace maintenance run compile and run Go program telemetry manage telemetry data and settings test test packages tool run specified go tool version print Go version vet report likely mistakes in packages
Use "go help <command>" for more information about a command.
Additional help topics:
buildconstraint build constraints buildmode build modes c calling between Go and C cache build and test caching environment environment variables filetype file types go.mod the go.mod file gopath GOPATH environment variable goproxy module proxy protocol importpath import path syntax modules modules, module versions, and more module-auth module authentication using go.sum packages package lists and patterns private configuration for downloading non-public code testflag testing flags testfunc testing functions vcs controlling version control with GOVCS
Use "go help <topic>" for more information about that topic.
Usage:
go bug
Bug opens the default browser and starts a new bug report. The report includes useful system information.
Usage:
go build [-o output] [build flags] [packages]
Build compiles the packages named by the import paths, along with their dependencies, but it does not install the results.
If the arguments to build are a list of .go files from a single directory, build treats them as a list of source files specifying a single package.
When compiling packages, build ignores files that end in '_test.go'.
When compiling a single main package, build writes the resulting executable to an output file named after the last non-major-version component of the package import path. The '.exe' suffix is added when writing a Windows executable. So 'go build example/sam' writes 'sam' or 'sam.exe'. 'go build example.com/foo/v2' writes 'foo' or 'foo.exe', not 'v2.exe'.
When compiling a package from a list of .go files, the executable is named after the first source file. 'go build ed.go rx.go' writes 'ed' or 'ed.exe'.
When compiling multiple packages or a single non-main package, build compiles the packages but discards the resulting object, serving only as a check that the packages can be built.
The -o flag forces build to write the resulting executable or object to the named output file or directory, instead of the default behavior described in the last two paragraphs. If the named output is an existing directory or ends with a slash or backslash, then any resulting executables will be written to that directory.
The build flags are shared by the build, clean, get, install, list, run, and test commands:
-C dir Change to dir before running the command. Any files named on the command line are interpreted after changing directories. If used, this flag must be the first one in the command line. -a force rebuilding of packages that are already up-to-date. -n print the commands but do not run them. -p n the number of programs, such as build commands or test binaries, that can be run in parallel. The default is GOMAXPROCS, normally the number of CPUs available. -race enable data race detection. Supported only on linux/amd64, freebsd/amd64, darwin/amd64, darwin/arm64, windows/amd64, linux/ppc64le and linux/arm64 (only for 48-bit VMA). -msan enable interoperation with memory sanitizer. Supported only on linux/amd64, linux/arm64, linux/loong64, freebsd/amd64 and only with Clang/LLVM as the host C compiler. PIE build mode will be used on all platforms except linux/amd64. -asan enable interoperation with address sanitizer. Supported only on linux/arm64, linux/amd64, linux/loong64. Supported on linux/amd64 or linux/arm64 and only with GCC 7 and higher or Clang/LLVM 9 and higher. And supported on linux/loong64 only with Clang/LLVM 16 and higher. -cover enable code coverage instrumentation. -covermode set,count,atomic set the mode for coverage analysis. The default is "set" unless -race is enabled, in which case it is "atomic". The values: set: bool: does this statement run? count: int: how many times does this statement run? atomic: int: count, but correct in multithreaded tests; significantly more expensive. Sets -cover. -coverpkg pattern1,pattern2,pattern3 For a build that targets package 'main' (e.g. building a Go executable), apply coverage analysis to each package matching the patterns. The default is to apply coverage analysis to packages in the main Go module. See 'go help packages' for a description of package patterns. Sets -cover. -v print the names of packages as they are compiled. -work print the name of the temporary work directory and do not delete it when exiting. -x print the commands. -asmflags '[pattern=]arg list' arguments to pass on each go tool asm invocation. -buildmode mode build mode to use. See 'go help buildmode' for more. -buildvcs Whether to stamp binaries with version control information ("true", "false", or "auto"). By default ("auto"), version control information is stamped into a binary if the main package, the main module containing it, and the current directory are all in the same repository. Use -buildvcs=false to always omit version control information, or -buildvcs=true to error out if version control information is available but cannot be included due to a missing tool or ambiguous directory structure. -compiler name name of compiler to use, as in runtime.Compiler (gccgo or gc). -gccgoflags '[pattern=]arg list' arguments to pass on each gccgo compiler/linker invocation. -gcflags '[pattern=]arg list' arguments to pass on each go tool compile invocation. -installsuffix suffix a suffix to use in the name of the package installation directory, in order to keep output separate from default builds. If using the -race flag, the install suffix is automatically set to race or, if set explicitly, has _race appended to it. Likewise for the -msan and -asan flags. Using a -buildmode option that requires non-default compile flags has a similar effect. -ldflags '[pattern=]arg list' arguments to pass on each go tool link invocation. -linkshared build code that will be linked against shared libraries previously created with -buildmode=shared. -mod mode module download mode to use: readonly, vendor, or mod. By default, if a vendor directory is present and the go version in go.mod is 1.14 or higher, the go command acts as if -mod=vendor were set. Otherwise, the go command acts as if -mod=readonly were set. See https://golang.org/ref/mod#build-commands for details. -modcacherw leave newly-created directories in the module cache read-write instead of making them read-only. -modfile file in module aware mode, read (and possibly write) an alternate go.mod file instead of the one in the module root directory. A file named "go.mod" must still be present in order to determine the module root directory, but it is not accessed. When -modfile is specified, an alternate go.sum file is also used: its path is derived from the -modfile flag by trimming the ".mod" extension and appending ".sum". -overlay file read a JSON config file that provides an overlay for build operations. The file is a JSON struct with a single field, named 'Replace', that maps each disk file path (a string) to its backing file path, so that a build will run as if the disk file path exists with the contents given by the backing file paths, or as if the disk file path does not exist if its backing file path is empty. Support for the -overlay flag has some limitations: importantly, cgo files included from outside the include path must be in the same directory as the Go package they are included from, and overlays will not appear when binaries and tests are run through go run and go test respectively. -pgo file specify the file path of a profile for profile-guided optimization (PGO). When the special name "auto" is specified, for each main package in the build, the go command selects a file named "default.pgo" in the package's directory if that file exists, and applies it to the (transitive) dependencies of the main package (other packages are not affected). Special name "off" turns off PGO. The default is "auto". -pkgdir dir install and load all packages from dir instead of the usual locations. For example, when building with a non-standard configuration, use -pkgdir to keep generated packages in a separate location. -tags tag,list a comma-separated list of additional build tags to consider satisfied during the build. For more information about build tags, see 'go help buildconstraint'. (Earlier versions of Go used a space-separated list, and that form is deprecated but still recognized.) -trimpath remove all file system paths from the resulting executable. Instead of absolute file system paths, the recorded file names will begin either a module path@version (when using modules), or a plain import path (when using the standard library, or GOPATH). -toolexec 'cmd args' a program to use to invoke toolchain programs like vet and asm. For example, instead of running asm, the go command will run 'cmd args /path/to/asm <arguments for asm>'. The TOOLEXEC_IMPORTPATH environment variable will be set, matching 'go list -f {{.ImportPath}}' for the package being built.
The -asmflags, -gccgoflags, -gcflags, and -ldflags flags accept a space-separated list of arguments to pass to an underlying tool during the build. To embed spaces in an element in the list, surround it with either single or double quotes. The argument list may be preceded by a package pattern and an equal sign, which restricts the use of that argument list to the building of packages matching that pattern (see 'go help packages' for a description of package patterns). Without a pattern, the argument list applies only to the packages named on the command line. The flags may be repeated with different patterns in order to specify different arguments for different sets of packages. If a package matches patterns given in multiple flags, the latest match on the command line wins. For example, 'go build -gcflags=-S fmt' prints the disassembly only for package fmt, while 'go build -gcflags=all=-S fmt' prints the disassembly for fmt and all its dependencies.
For more about specifying packages, see 'go help packages'. For more about where packages and binaries are installed, run 'go help gopath'. For more about calling between Go and C/C++, run 'go help c'.
Note: Build adheres to certain conventions such as those described by 'go help gopath'. Not all projects can follow these conventions, however. Installations that have their own conventions or that use a separate software build system may choose to use lower-level invocations such as 'go tool compile' and 'go tool link' to avoid some of the overheads and design decisions of the build tool.
See also: go install, go get, go clean.
Usage:
go clean [-i] [-r] [-cache] [-testcache] [-modcache] [-fuzzcache] [build flags] [packages]
Clean removes object files from package source directories. The go command builds most objects in a temporary directory, so go clean is mainly concerned with object files left by other tools or by manual invocations of go build.
If a package argument is given or the -i or -r flag is set, clean removes the following files from each of the source directories corresponding to the import paths:
_obj/ old object directory, left from Makefiles _test/ old test directory, left from Makefiles _testmain.go old gotest file, left from Makefiles test.out old test log, left from Makefiles build.out old test log, left from Makefiles *.[568ao] object files, left from Makefiles DIR(.exe) from go build DIR.test(.exe) from go test -c MAINFILE(.exe) from go build MAINFILE.go *.so from SWIG
In the list, DIR represents the final path element of the directory, and MAINFILE is the base name of any Go source file in the directory that is not included when building the package.
The -i flag causes clean to remove the corresponding installed archive or binary (what 'go install' would create).
The -n flag causes clean to print the remove commands it would execute, but not run them.
The -r flag causes clean to be applied recursively to all the dependencies of the packages named by the import paths.
The -x flag causes clean to print remove commands as it executes them.
The -cache flag causes clean to remove the entire go build cache.
The -testcache flag causes clean to expire all test results in the go build cache.
The -modcache flag causes clean to remove the entire module download cache, including unpacked source code of versioned dependencies.
The -fuzzcache flag causes clean to remove files stored in the Go build cache for fuzz testing. The fuzzing engine caches files that expand code coverage, so removing them may make fuzzing less effective until new inputs are found that provide the same coverage. These files are distinct from those stored in testdata directory; clean does not remove those files.
For more about build flags, see 'go help build'.
For more about specifying packages, see 'go help packages'.
Usage:
go doc [doc flags] [package|[package.]symbol[.methodOrField]]
Doc prints the documentation comments associated with the item identified by its arguments (a package, const, func, type, var, method, or struct field) followed by a one-line summary of each of the first-level items "under" that item (package-level declarations for a package, methods for a type, etc.).
Doc accepts zero, one, or two arguments.
Given no arguments, that is, when run as
go doc
it prints the package documentation for the package in the current directory. If the package is a command (package main), the exported symbols of the package are elided from the presentation unless the -cmd flag is provided.
When run with one argument, the argument is treated as a Go-syntax-like representation of the item to be documented. What the argument selects depends on what is installed in GOROOT and GOPATH, as well as the form of the argument, which is schematically one of these:
go doc <pkg> go doc <sym>[.<methodOrField>] go doc [<pkg>.]<sym>[.<methodOrField>] go doc [<pkg>.][<sym>.]<methodOrField>
The first item in this list matched by the argument is the one whose documentation is printed. (See the examples below.) However, if the argument starts with a capital letter it is assumed to identify a symbol or method in the current directory.
For packages, the order of scanning is determined lexically in breadth-first order. That is, the package presented is the one that matches the search and is nearest the root and lexically first at its level of the hierarchy. The GOROOT tree is always scanned in its entirety before GOPATH.
If there is no package specified or matched, the package in the current directory is selected, so "go doc Foo" shows the documentation for symbol Foo in the current package.
The package path must be either a qualified path or a proper suffix of a path. The go tool's usual package mechanism does not apply: package path elements like . and ... are not implemented by go doc.
When run with two arguments, the first is a package path (full path or suffix), and the second is a symbol, or symbol with method or struct field:
go doc <pkg> <sym>[.<methodOrField>]
In all forms, when matching symbols, lower-case letters in the argument match either case but upper-case letters match exactly. This means that there may be multiple matches of a lower-case argument in a package if different symbols have different cases. If this occurs, documentation for all matches is printed.
Examples:
go doc Show documentation for current package. go doc Foo Show documentation for Foo in the current package. (Foo starts with a capital letter so it cannot match a package path.) go doc encoding/json Show documentation for the encoding/json package. go doc json Shorthand for encoding/json. go doc json.Number (or go doc json.number) Show documentation and method summary for json.Number. go doc json.Number.Int64 (or go doc json.number.int64) Show documentation for json.Number's Int64 method. go doc cmd/doc Show package docs for the doc command. go doc -cmd cmd/doc Show package docs and exported symbols within the doc command. go doc template.new Show documentation for html/template's New function. (html/template is lexically before text/template) go doc text/template.new # One argument Show documentation for text/template's New function. go doc text/template new # Two arguments Show documentation for text/template's New function. At least in the current tree, these invocations all print the documentation for json.Decoder's Decode method: go doc json.Decoder.Decode go doc json.decoder.decode go doc json.decode cd go/src/encoding/json; go doc decode
Flags:
-all Show all the documentation for the package. -c Respect case when matching symbols. -cmd Treat a command (package main) like a regular package. Otherwise package main's exported symbols are hidden when showing the package's top-level documentation. -short One-line representation for each symbol. -src Show the full source code for the symbol. This will display the full Go source of its declaration and definition, such as a function definition (including the body), type declaration or enclosing const block. The output may therefore include unexported details. -u Show documentation for unexported as well as exported symbols, methods, and fields.
Usage:
go env [-json] [-changed] [-u] [-w] [var ...]
Env prints Go environment information.
By default env prints information as a shell script (on Windows, a batch file). If one or more variable names is given as arguments, env prints the value of each named variable on its own line.
The -json flag prints the environment in JSON format instead of as a shell script.
The -u flag requires one or more arguments and unsets the default setting for the named environment variables, if one has been set with 'go env -w'.
The -w flag requires one or more arguments of the form NAME=VALUE and changes the default settings of the named environment variables to the given values.
The -changed flag prints only those settings whose effective value differs from the default value that would be obtained in an empty environment with no prior uses of the -w flag.
For more about environment variables, see 'go help environment'.
Usage:
go fix [-fix list] [packages]
Fix runs the Go fix command on the packages named by the import paths.
The -fix flag sets a comma-separated list of fixes to run. The default is all known fixes. (Its value is passed to 'go tool fix -r'.)
For more about fix, see 'go doc cmd/fix'. For more about specifying packages, see 'go help packages'.
To run fix with other options, run 'go tool fix'.
See also: go fmt, go vet.
Usage:
go fmt [-n] [-x] [packages]
Fmt runs the command 'gofmt -l -w' on the packages named by the import paths. It prints the names of the files that are modified.
For more about gofmt, see 'go doc cmd/gofmt'. For more about specifying packages, see 'go help packages'.
The -n flag prints commands that would be executed. The -x flag prints commands as they are executed.
The -mod flag's value sets which module download mode to use: readonly or vendor. See 'go help modules' for more.
To run gofmt with specific options, run gofmt itself.
See also: go fix, go vet.
Usage:
go generate [-run regexp] [-n] [-v] [-x] [build flags] [file.go... | packages]
Generate runs commands described by directives within existing files. Those commands can run any process but the intent is to create or update Go source files.
Go generate is never run automatically by go build, go test, and so on. It must be run explicitly.
Go generate scans the file for directives, which are lines of the form,
//go:generate command argument...
(note: no leading spaces and no space in "//go") where command is the generator to be run, corresponding to an executable file that can be run locally. It must either be in the shell path (gofmt), a fully qualified path (/usr/you/bin/mytool), or a command alias, described below.
Note that go generate does not parse the file, so lines that look like directives in comments or multiline strings will be treated as directives.
The arguments to the directive are space-separated tokens or double-quoted strings passed to the generator as individual arguments when it is run.
Quoted strings use Go syntax and are evaluated before execution; a quoted string appears as a single argument to the generator.
To convey to humans and machine tools that code is generated, generated source should have a line that matches the following regular expression (in Go syntax):
^// Code generated .* DO NOT EDIT\.$
This line must appear before the first non-comment, non-blank text in the file.
Go generate sets several variables when it runs the generator:
$GOARCH The execution architecture (arm, amd64, etc.) $GOOS The execution operating system (linux, windows, etc.) $GOFILE The base name of the file. $GOLINE The line number of the directive in the source file. $GOPACKAGE The name of the package of the file containing the directive. $GOROOT The GOROOT directory for the 'go' command that invoked the generator, containing the Go toolchain and standard library. $DOLLAR A dollar sign. $PATH The $PATH of the parent process, with $GOROOT/bin placed at the beginning. This causes generators that execute 'go' commands to use the same 'go' as the parent 'go generate' command.
Other than variable substitution and quoted-string evaluation, no special processing such as "globbing" is performed on the command line.
As a last step before running the command, any invocations of any environment variables with alphanumeric names, such as $GOFILE or $HOME, are expanded throughout the command line. The syntax for variable expansion is $NAME on all operating systems. Due to the order of evaluation, variables are expanded even inside quoted strings. If the variable NAME is not set, $NAME expands to the empty string.
A directive of the form,
//go:generate -command xxx args...
specifies, for the remainder of this source file only, that the string xxx represents the command identified by the arguments. This can be used to create aliases or to handle multiword generators. For example,
//go:generate -command foo go tool foo
specifies that the command "foo" represents the generator "go tool foo".
Generate processes packages in the order given on the command line, one at a time. If the command line lists .go files from a single directory, they are treated as a single package. Within a package, generate processes the source files in a package in file name order, one at a time. Within a source file, generate runs generators in the order they appear in the file, one at a time. The go generate tool also sets the build tag "generate" so that files may be examined by go generate but ignored during build.
For packages with invalid code, generate processes only source files with a valid package clause.
If any generator returns an error exit status, "go generate" skips all further processing for that package.
The generator is run in the package's source directory.
Go generate accepts two specific flags:
-run="" if non-empty, specifies a regular expression to select directives whose full original source text (excluding any trailing spaces and final newline) matches the expression. -skip="" if non-empty, specifies a regular expression to suppress directives whose full original source text (excluding any trailing spaces and final newline) matches the expression. If a directive matches both the -run and the -skip arguments, it is skipped.
It also accepts the standard build flags including -v, -n, and -x. The -v flag prints the names of packages and files as they are processed. The -n flag prints commands that would be executed. The -x flag prints commands as they are executed.
For more about build flags, see 'go help build'.
For more about specifying packages, see 'go help packages'.
Usage:
go get [-t] [-u] [-v] [build flags] [packages]
Get resolves its command-line arguments to packages at specific module versions, updates go.mod to require those versions, and downloads source code into the module cache.
To add a dependency for a package or upgrade it to its latest version:
go get example.com/pkg
To upgrade or downgrade a package to a specific version:
go get example.com/pkg@v1.2.3
To remove a dependency on a module and downgrade modules that require it:
go get example.com/mod@none
To upgrade the minimum required Go version to the latest released Go version:
go get go@latest
To upgrade the Go toolchain to the latest patch release of the current Go toolchain:
go get toolchain@patch
See https://golang.org/ref/mod#go-get for details.
In earlier versions of Go, 'go get' was used to build and install packages. Now, 'go get' is dedicated to adjusting dependencies in go.mod. 'go install' may be used to build and install commands instead. When a version is specified, 'go install' runs in module-aware mode and ignores the go.mod file in the current directory. For example:
go install example.com/pkg@v1.2.3 go install example.com/pkg@latest
See 'go help install' or https://golang.org/ref/mod#go-install for details.
'go get' accepts the following flags.
The -t flag instructs get to consider modules needed to build tests of packages specified on the command line.
The -u flag instructs get to update modules providing dependencies of packages named on the command line to use newer minor or patch releases when available.
The -u=patch flag (not -u patch) also instructs get to update dependencies, but changes the default to select patch releases.
When the -t and -u flags are used together, get will update test dependencies as well.
The -x flag prints commands as they are executed. This is useful for debugging version control commands when a module is downloaded directly from a repository.
For more about build flags, see 'go help build'.
For more about modules, see https://golang.org/ref/mod.
For more about using 'go get' to update the minimum Go version and suggested Go toolchain, see https://go.dev/doc/toolchain.
For more about specifying packages, see 'go help packages'.
This text describes the behavior of get using modules to manage source code and dependencies. If instead the go command is running in GOPATH mode, the details of get's flags and effects change, as does 'go help get'. See 'go help gopath-get'.
See also: go build, go install, go clean, go mod.
Usage:
go install [build flags] [packages]
Install compiles and installs the packages named by the import paths.
Executables are installed in the directory named by the GOBIN environment variable, which defaults to $GOPATH/bin or $HOME/go/bin if the GOPATH environment variable is not set. Executables in $GOROOT are installed in $GOROOT/bin or $GOTOOLDIR instead of $GOBIN.
If the arguments have version suffixes (like @latest or @v1.0.0), "go install" builds packages in module-aware mode, ignoring the go.mod file in the current directory or any parent directory, if there is one. This is useful for installing executables without affecting the dependencies of the main module. To eliminate ambiguity about which module versions are used in the build, the arguments must satisfy the following constraints:
- Arguments must be package paths or package patterns (with "..." wildcards). They must not be standard packages (like fmt), meta-patterns (std, cmd, all), or relative or absolute file paths.
- All arguments must have the same version suffix. Different queries are not allowed, even if they refer to the same version.
- All arguments must refer to packages in the same module at the same version.
- Package path arguments must refer to main packages. Pattern arguments will only match main packages.
- No module is considered the "main" module. If the module containing packages named on the command line has a go.mod file, it must not contain directives (replace and exclude) that would cause it to be interpreted differently than if it were the main module. The module must not require a higher version of itself.
- Vendor directories are not used in any module. (Vendor directories are not included in the module zip files downloaded by 'go install'.)
If the arguments don't have version suffixes, "go install" may run in module-aware mode or GOPATH mode, depending on the GO111MODULE environment variable and the presence of a go.mod file. See 'go help modules' for details. If module-aware mode is enabled, "go install" runs in the context of the main module.
When module-aware mode is disabled, non-main packages are installed in the directory $GOPATH/pkg/$GOOS_$GOARCH. When module-aware mode is enabled, non-main packages are built and cached but not installed.
Before Go 1.20, the standard library was installed to $GOROOT/pkg/$GOOS_$GOARCH. Starting in Go 1.20, the standard library is built and cached but not installed. Setting GODEBUG=installgoroot=all restores the use of $GOROOT/pkg/$GOOS_$GOARCH.
For more about build flags, see 'go help build'.
For more about specifying packages, see 'go help packages'.
See also: go build, go get, go clean.
Usage:
go list [-f format] [-json] [-m] [list flags] [build flags] [packages]
List lists the named packages, one per line. The most commonly-used flags are -f and -json, which control the form of the output printed for each package. Other list flags, documented below, control more specific details.
The default output shows the package import path:
bytes encoding/json github.com/gorilla/mux golang.org/x/net/html
The -f flag specifies an alternate format for the list, using the syntax of package template. The default output is equivalent to -f '{{.ImportPath}}'. The struct being passed to the template is:
type Package struct { Dir string // directory containing package sources ImportPath string // import path of package in dir ImportComment string // path in import comment on package statement Name string // package name Doc string // package documentation string Target string // install path Shlib string // the shared library that contains this package (only set when -linkshared) Goroot bool // is this package in the Go root? Standard bool // is this package part of the standard Go library? Stale bool // would 'go install' do anything for this package? StaleReason string // explanation for Stale==true Root string // Go root or Go path dir containing this package ConflictDir string // this directory shadows Dir in $GOPATH BinaryOnly bool // binary-only package (no longer supported) ForTest string // package is only for use in named test Export string // file containing export data (when using -export) BuildID string // build ID of the compiled package (when using -export) Module *Module // info about package's containing module, if any (can be nil) Match []string // command-line patterns matching this package DepOnly bool // package is only a dependency, not explicitly listed DefaultGODEBUG string // default GODEBUG setting, for main packages // Source files GoFiles []string // .go source files (excluding CgoFiles, TestGoFiles, XTestGoFiles) CgoFiles []string // .go source files that import "C" CompiledGoFiles []string // .go files presented to compiler (when using -compiled) IgnoredGoFiles []string // .go source files ignored due to build constraints IgnoredOtherFiles []string // non-.go source files ignored due to build constraints CFiles []string // .c source files CXXFiles []string // .cc, .cxx and .cpp source files MFiles []string // .m source files HFiles []string // .h, .hh, .hpp and .hxx source files FFiles []string // .f, .F, .for and .f90 Fortran source files SFiles []string // .s source files SwigFiles []string // .swig files SwigCXXFiles []string // .swigcxx files SysoFiles []string // .syso object files to add to archive TestGoFiles []string // _test.go files in package XTestGoFiles []string // _test.go files outside package // Embedded files EmbedPatterns []string // //go:embed patterns EmbedFiles []string // files matched by EmbedPatterns TestEmbedPatterns []string // //go:embed patterns in TestGoFiles TestEmbedFiles []string // files matched by TestEmbedPatterns XTestEmbedPatterns []string // //go:embed patterns in XTestGoFiles XTestEmbedFiles []string // files matched by XTestEmbedPatterns // Cgo directives CgoCFLAGS []string // cgo: flags for C compiler CgoCPPFLAGS []string // cgo: flags for C preprocessor CgoCXXFLAGS []string // cgo: flags for C++ compiler CgoFFLAGS []string // cgo: flags for Fortran compiler CgoLDFLAGS []string // cgo: flags for linker CgoPkgConfig []string // cgo: pkg-config names // Dependency information Imports []string // import paths used by this package ImportMap map[string]string // map from source import to ImportPath (identity entries omitted) Deps []string // all (recursively) imported dependencies TestImports []string // imports from TestGoFiles XTestImports []string // imports from XTestGoFiles // Error information Incomplete bool // this package or a dependency has an error Error *PackageError // error loading package DepsErrors []*PackageError // errors loading dependencies }
Packages stored in vendor directories report an ImportPath that includes the path to the vendor directory (for example, "d/vendor/p" instead of "p"), so that the ImportPath uniquely identifies a given copy of a package. The Imports, Deps, TestImports, and XTestImports lists also contain these expanded import paths. See golang.org/s/go15vendor for more about vendoring.
The error information, if any, is
type PackageError struct { ImportStack []string // shortest path from package named on command line to this one Pos string // position of error (if present, file:line:col) Err string // the error itself }
The module information is a Module struct, defined in the discussion of list -m below.
The template function "join" calls strings.Join.
The template function "context" returns the build context, defined as:
type Context struct { GOARCH string // target architecture GOOS string // target operating system GOROOT string // Go root GOPATH string // Go path CgoEnabled bool // whether cgo can be used UseAllFiles bool // use files regardless of //go:build lines, file names Compiler string // compiler to assume when computing target paths BuildTags []string // build constraints to match in //go:build lines ToolTags []string // toolchain-specific build constraints ReleaseTags []string // releases the current release is compatible with InstallSuffix string // suffix to use in the name of the install dir }
For more information about the meaning of these fields see the documentation for the go/build package's Context type.
The -json flag causes the package data to be printed in JSON format instead of using the template format. The JSON flag can optionally be provided with a set of comma-separated required field names to be output. If so, those required fields will always appear in JSON output, but others may be omitted to save work in computing the JSON struct.
The -compiled flag causes list to set CompiledGoFiles to the Go source files presented to the compiler. Typically this means that it repeats the files listed in GoFiles and then also adds the Go code generated by processing CgoFiles and SwigFiles. The Imports list contains the union of all imports from both GoFiles and CompiledGoFiles.
The -deps flag causes list to iterate over not just the named packages but also all their dependencies. It visits them in a depth-first post-order traversal, so that a package is listed only after all its dependencies. Packages not explicitly listed on the command line will have the DepOnly field set to true.
The -e flag changes the handling of erroneous packages, those that cannot be found or are malformed. By default, the list command prints an error to standard error for each erroneous package and omits the packages from consideration during the usual printing. With the -e flag, the list command never prints errors to standard error and instead processes the erroneous packages with the usual printing. Erroneous packages will have a non-empty ImportPath and a non-nil Error field; other information may or may not be missing (zeroed).
The -export flag causes list to set the Export field to the name of a file containing up-to-date export information for the given package, and the BuildID field to the build ID of the compiled package.
The -find flag causes list to identify the named packages but not resolve their dependencies: the Imports and Deps lists will be empty. With the -find flag, the -deps, -test and -export commands cannot be used.
The -test flag causes list to report not only the named packages but also their test binaries (for packages with tests), to convey to source code analysis tools exactly how test binaries are constructed. The reported import path for a test binary is the import path of the package followed by a ".test" suffix, as in "math/rand.test". When building a test, it is sometimes necessary to rebuild certain dependencies specially for that test (most commonly the tested package itself). The reported import path of a package recompiled for a particular test binary is followed by a space and the name of the test binary in brackets, as in "math/rand math/rand.test" or "regexp [sort.test]". The ForTest field is also set to the name of the package being tested ("math/rand" or "sort" in the previous examples).
The Dir, Target, Shlib, Root, ConflictDir, and Export file paths are all absolute paths.
By default, the lists GoFiles, CgoFiles, and so on hold names of files in Dir (that is, paths relative to Dir, not absolute paths). The generated files added when using the -compiled and -test flags are absolute paths referring to cached copies of generated Go source files. Although they are Go source files, the paths may not end in ".go".
The -m flag causes list to list modules instead of packages.
When listing modules, the -f flag still specifies a format template applied to a Go struct, but now a Module struct:
type Module struct { Path string // module path Query string // version query corresponding to this version Version string // module version Versions []string // available module versions Replace *Module // replaced by this module Time *time.Time // time version was created Update *Module // available update (with -u) Main bool // is this the main module? Indirect bool // module is only indirectly needed by main module Dir string // directory holding local copy of files, if any GoMod string // path to go.mod file describing module, if any GoVersion string // go version used in module Retracted []string // retraction information, if any (with -retracted or -u) Deprecated string // deprecation message, if any (with -u) Error *ModuleError // error loading module Sum string // checksum for path, version (as in go.sum) GoModSum string // checksum for go.mod (as in go.sum) Origin any // provenance of module Reuse bool // reuse of old module info is safe } type ModuleError struct { Err string // the error itself }
The file GoMod refers to may be outside the module directory if the module is in the module cache or if the -modfile flag is used.
The default output is to print the module path and then information about the version and replacement if any. For example, 'go list -m all' might print:
my/main/module golang.org/x/text v0.3.0 => /tmp/text rsc.io/pdf v0.1.1
The Module struct has a String method that formats this line of output, so that the default format is equivalent to -f '{{.String}}'.
Note that when a module has been replaced, its Replace field describes the replacement module, and its Dir field is set to the replacement's source code, if present. (That is, if Replace is non-nil, then Dir is set to Replace.Dir, with no access to the replaced source code.)
The -u flag adds information about available upgrades. When the latest version of a given module is newer than the current one, list -u sets the Module's Update field to information about the newer module. list -u will also set the module's Retracted field if the current version is retracted. The Module's String method indicates an available upgrade by formatting the newer version in brackets after the current version. If a version is retracted, the string "(retracted)" will follow it. For example, 'go list -m -u all' might print:
my/main/module golang.org/x/text v0.3.0 [v0.4.0] => /tmp/text rsc.io/pdf v0.1.1 (retracted) [v0.1.2]
(For tools, 'go list -m -u -json all' may be more convenient to parse.)
The -versions flag causes list to set the Module's Versions field to a list of all known versions of that module, ordered according to semantic versioning, earliest to latest. The flag also changes the default output format to display the module path followed by the space-separated version list.
The -retracted flag causes list to report information about retracted module versions. When -retracted is used with -f or -json, the Retracted field will be set to a string explaining why the version was retracted. The string is taken from comments on the retract directive in the module's go.mod file. When -retracted is used with -versions, retracted versions are listed together with unretracted versions. The -retracted flag may be used with or without -m.
The arguments to list -m are interpreted as a list of modules, not packages. The main module is the module containing the current directory. The active modules are the main module and its dependencies. With no arguments, list -m shows the main module. With arguments, list -m shows the modules specified by the arguments. Any of the active modules can be specified by its module path. The special pattern "all" specifies all the active modules, first the main module and then dependencies sorted by module path. A pattern containing "..." specifies the active modules whose module paths match the pattern. A query of the form path@version specifies the result of that query, which is not limited to active modules. See 'go help modules' for more about module queries.
The template function "module" takes a single string argument that must be a module path or query and returns the specified module as a Module struct. If an error occurs, the result will be a Module struct with a non-nil Error field.
When using -m, the -reuse=old.json flag accepts the name of file containing the JSON output of a previous 'go list -m -json' invocation with the same set of modifier flags (such as -u, -retracted, and -versions). The go command may use this file to determine that a module is unchanged since the previous invocation and avoid redownloading information about it. Modules that are not redownloaded will be marked in the new output by setting the Reuse field to true. Normally the module cache provides this kind of reuse automatically; the -reuse flag can be useful on systems that do not preserve the module cache.
For more about build flags, see 'go help build'.
For more about specifying packages, see 'go help packages'.
For more about modules, see https://golang.org/ref/mod.
Go mod provides access to operations on modules.
Note that support for modules is built into all the go commands, not just 'go mod'. For example, day-to-day adding, removing, upgrading, and downgrading of dependencies should be done using 'go get'. See 'go help modules' for an overview of module functionality.
Usage:
go mod <command> [arguments]
The commands are:
download download modules to local cache edit edit go.mod from tools or scripts graph print module requirement graph init initialize new module in current directory tidy add missing and remove unused modules vendor make vendored copy of dependencies verify verify dependencies have expected content why explain why packages or modules are needed
Use "go help mod <command>" for more information about a command.
Usage:
go mod download [-x] [-json] [-reuse=old.json] [modules]
Download downloads the named modules, which can be module patterns selecting dependencies of the main module or module queries of the form path@version.
With no arguments, download applies to the modules needed to build and test the packages in the main module: the modules explicitly required by the main module if it is at 'go 1.17' or higher, or all transitively-required modules if at 'go 1.16' or lower.
The go command will automatically download modules as needed during ordinary execution. The "go mod download" command is useful mainly for pre-filling the local cache or to compute the answers for a Go module proxy.
By default, download writes nothing to standard output. It may print progress messages and errors to standard error.
The -json flag causes download to print a sequence of JSON objects to standard output, describing each downloaded module (or failure), corresponding to this Go struct:
type Module struct { Path string // module path Query string // version query corresponding to this version Version string // module version Error string // error loading module Info string // absolute path to cached .info file GoMod string // absolute path to cached .mod file Zip string // absolute path to cached .zip file Dir string // absolute path to cached source root directory Sum string // checksum for path, version (as in go.sum) GoModSum string // checksum for go.mod (as in go.sum) Origin any // provenance of module Reuse bool // reuse of old module info is safe }
The -reuse flag accepts the name of file containing the JSON output of a previous 'go mod download -json' invocation. The go command may use this file to determine that a module is unchanged since the previous invocation and avoid redownloading it. Modules that are not redownloaded will be marked in the new output by setting the Reuse field to true. Normally the module cache provides this kind of reuse automatically; the -reuse flag can be useful on systems that do not preserve the module cache.
The -x flag causes download to print the commands download executes.
See https://golang.org/ref/mod#go-mod-download for more about 'go mod download'.
See https://golang.org/ref/mod#version-queries for more about version queries.
Usage:
go mod edit [editing flags] [-fmt|-print|-json] [go.mod]
Edit provides a command-line interface for editing go.mod, for use primarily by tools or scripts. It reads only go.mod; it does not look up information about the modules involved. By default, edit reads and writes the go.mod file of the main module, but a different target file can be specified after the editing flags.
The editing flags specify a sequence of editing operations.
The -fmt flag reformats the go.mod file without making other changes. This reformatting is also implied by any other modifications that use or rewrite the go.mod file. The only time this flag is needed is if no other flags are specified, as in 'go mod edit -fmt'.
The -module flag changes the module's path (the go.mod file's module line).
The -godebug=key=value flag adds a godebug key=value line, replacing any existing godebug lines with the given key.
The -dropgodebug=key flag drops any existing godebug lines with the given key.
The -require=path@version and -droprequire=path flags add and drop a requirement on the given module path and version. Note that -require overrides any existing requirements on path. These flags are mainly for tools that understand the module graph. Users should prefer 'go get path@version' or 'go get path@none', which make other go.mod adjustments as needed to satisfy constraints imposed by other modules.
The -go=version flag sets the expected Go language version. This flag is mainly for tools that understand Go version dependencies. Users should prefer 'go get go@version'.
The -toolchain=version flag sets the Go toolchain to use. This flag is mainly for tools that understand Go version dependencies. Users should prefer 'go get toolchain@version'.
The -exclude=path@version and -dropexclude=path@version flags add and drop an exclusion for the given module path and version. Note that -exclude=path@version is a no-op if that exclusion already exists.
The -replace=old[@v]=new[@v] flag adds a replacement of the given module path and version pair. If the @v in old@v is omitted, a replacement without a version on the left side is added, which applies to all versions of the old module path. If the @v in new@v is omitted, the new path should be a local module root directory, not a module path. Note that -replace overrides any redundant replacements for old[@v], so omitting @v will drop existing replacements for specific versions.
The -dropreplace=old[@v] flag drops a replacement of the given module path and version pair. If the @v is omitted, a replacement without a version on the left side is dropped.
The -retract=version and -dropretract=version flags add and drop a retraction on the given version. The version may be a single version like "v1.2.3" or a closed interval like "[v1.1.0,v1.1.9]". Note that -retract=version is a no-op if that retraction already exists.
The -godebug, -dropgodebug, -require, -droprequire, -exclude, -dropexclude, -replace, -dropreplace, -retract, and -dropretract editing flags may be repeated, and the changes are applied in the order given.
The -print flag prints the final go.mod in its text format instead of writing it back to go.mod.
The -json flag prints the final go.mod file in JSON format instead of writing it back to go.mod. The JSON output corresponds to these Go types:
type Module struct { Path string Version string } type GoMod struct { Module ModPath Go string Toolchain string Godebug []Godebug Require []Require Exclude []Module Replace []Replace Retract []Retract } type ModPath struct { Path string Deprecated string } type Godebug struct { Key string Value string } type Require struct { Path string Version string Indirect bool } type Replace struct { Old Module New Module } type Retract struct { Low string High string Rationale string }
Retract entries representing a single version (not an interval) will have the "Low" and "High" fields set to the same value.
Note that this only describes the go.mod file itself, not other modules referred to indirectly. For the full set of modules available to a build, use 'go list -m -json all'.
Edit also provides the -C, -n, and -x build flags.
See https://golang.org/ref/mod#go-mod-edit for more about 'go mod edit'.
Usage:
go mod graph [-go=version] [-x]
Graph prints the module requirement graph (with replacements applied) in text form. Each line in the output has two space-separated fields: a module and one of its requirements. Each module is identified as a string of the form path@version, except for the main module, which has no @version suffix.
The -go flag causes graph to report the module graph as loaded by the given Go version, instead of the version indicated by the 'go' directive in the go.mod file.
The -x flag causes graph to print the commands graph executes.
See https://golang.org/ref/mod#go-mod-graph for more about 'go mod graph'.
Usage:
go mod init [module-path]
Init initializes and writes a new go.mod file in the current directory, in effect creating a new module rooted at the current directory. The go.mod file must not already exist.
Init accepts one optional argument, the module path for the new module. If the module path argument is omitted, init will attempt to infer the module path using import comments in .go files, vendoring tool configuration files (like Gopkg.lock), and the current directory (if in GOPATH).
See https://golang.org/ref/mod#go-mod-init for more about 'go mod init'.
Usage:
go mod tidy [-e] [-v] [-x] [-diff] [-go=version] [-compat=version]
Tidy makes sure go.mod matches the source code in the module. It adds any missing modules necessary to build the current module's packages and dependencies, and it removes unused modules that don't provide any relevant packages. It also adds any missing entries to go.sum and removes any unnecessary ones.
The -v flag causes tidy to print information about removed modules to standard error.
The -e flag causes tidy to attempt to proceed despite errors encountered while loading packages.
The -diff flag causes tidy not to modify go.mod or go.sum but instead print the necessary changes as a unified diff. It exits with a non-zero code if the diff is not empty.
The -go flag causes tidy to update the 'go' directive in the go.mod file to the given version, which may change which module dependencies are retained as explicit requirements in the go.mod file. (Go versions 1.17 and higher retain more requirements in order to support lazy module loading.)
The -compat flag preserves any additional checksums needed for the 'go' command from the indicated major Go release to successfully load the module graph, and causes tidy to error out if that version of the 'go' command would load any imported package from a different module version. By default, tidy acts as if the -compat flag were set to the version prior to the one indicated by the 'go' directive in the go.mod file.
The -x flag causes tidy to print the commands download executes.
See https://golang.org/ref/mod#go-mod-tidy for more about 'go mod tidy'.
Usage:
go mod vendor [-e] [-v] [-o outdir]
Vendor resets the main module's vendor directory to include all packages needed to build and test all the main module's packages. It does not include test code for vendored packages.
The -v flag causes vendor to print the names of vendored modules and packages to standard error.
The -e flag causes vendor to attempt to proceed despite errors encountered while loading packages.
The -o flag causes vendor to create the vendor directory at the given path instead of "vendor". The go command can only use a vendor directory named "vendor" within the module root directory, so this flag is primarily useful for other tools.
See https://golang.org/ref/mod#go-mod-vendor for more about 'go mod vendor'.
Usage:
go mod verify
Verify checks that the dependencies of the current module, which are stored in a local downloaded source cache, have not been modified since being downloaded. If all the modules are unmodified, verify prints "all modules verified." Otherwise it reports which modules have been changed and causes 'go mod' to exit with a non-zero status.
See https://golang.org/ref/mod#go-mod-verify for more about 'go mod verify'.
Usage:
go mod why [-m] [-vendor] packages...
Why shows a shortest path in the import graph from the main module to each of the listed packages. If the -m flag is given, why treats the arguments as a list of modules and finds a path to any package in each of the modules.
By default, why queries the graph of packages matched by "go list all", which includes tests for reachable packages. The -vendor flag causes why to exclude tests of dependencies.
The output is a sequence of stanzas, one for each package or module name on the command line, separated by blank lines. Each stanza begins with a comment line "# package" or "# module" giving the target package or module. Subsequent lines give a path through the import graph, one package per line. If the package or module is not referenced from the main module, the stanza will display a single parenthesized note indicating that fact.
For example:
$ go mod why golang.org/x/text/language golang.org/x/text/encoding # golang.org/x/text/language rsc.io/quote rsc.io/sampler golang.org/x/text/language # golang.org/x/text/encoding (main module does not need package golang.org/x/text/encoding) $
See https://golang.org/ref/mod#go-mod-why for more about 'go mod why'.
Work provides access to operations on workspaces.
Note that support for workspaces is built into many other commands, not just 'go work'.
See 'go help modules' for information about Go's module system of which workspaces are a part.
See https://go.dev/ref/mod#workspaces for an in-depth reference on workspaces.
See https://go.dev/doc/tutorial/workspaces for an introductory tutorial on workspaces.
A workspace is specified by a go.work file that specifies a set of module directories with the "use" directive. These modules are used as root modules by the go command for builds and related operations. A workspace that does not specify modules to be used cannot be used to do builds from local modules.
go.work files are line-oriented. Each line holds a single directive, made up of a keyword followed by arguments. For example:
go 1.18 use ../foo/bar use ./baz replace example.com/foo v1.2.3 => example.com/bar v1.4.5
The leading keyword can be factored out of adjacent lines to create a block, like in Go imports.
use ( ../foo/bar ./baz )
The use directive specifies a module to be included in the workspace's set of main modules. The argument to the use directive is the directory containing the module's go.mod file.
The go directive specifies the version of Go the file was written at. It is possible there may be future changes in the semantics of workspaces that could be controlled by this version, but for now the version specified has no effect.
The replace directive has the same syntax as the replace directive in a go.mod file and takes precedence over replaces in go.mod files. It is primarily intended to override conflicting replaces in different workspace modules.
To determine whether the go command is operating in workspace mode, use the "go env GOWORK" command. This will specify the workspace file being used.
Usage:
go work <command> [arguments]
The commands are:
edit edit go.work from tools or scripts init initialize workspace file sync sync workspace build list to modules use add modules to workspace file vendor make vendored copy of dependencies
Use "go help work <command>" for more information about a command.
Usage:
go work edit [editing flags] [go.work]
Edit provides a command-line interface for editing go.work, for use primarily by tools or scripts. It only reads go.work; it does not look up information about the modules involved. If no file is specified, Edit looks for a go.work file in the current directory and its parent directories
The editing flags specify a sequence of editing operations.
The -fmt flag reformats the go.work file without making other changes. This reformatting is also implied by any other modifications that use or rewrite the go.mod file. The only time this flag is needed is if no other flags are specified, as in 'go work edit -fmt'.
The -godebug=key=value flag adds a godebug key=value line, replacing any existing godebug lines with the given key.
The -dropgodebug=key flag drops any existing godebug lines with the given key.
The -use=path and -dropuse=path flags add and drop a use directive from the go.work file's set of module directories.
The -replace=old[@v]=new[@v] flag adds a replacement of the given module path and version pair. If the @v in old@v is omitted, a replacement without a version on the left side is added, which applies to all versions of the old module path. If the @v in new@v is omitted, the new path should be a local module root directory, not a module path. Note that -replace overrides any redundant replacements for old[@v], so omitting @v will drop existing replacements for specific versions.
The -dropreplace=old[@v] flag drops a replacement of the given module path and version pair. If the @v is omitted, a replacement without a version on the left side is dropped.
The -use, -dropuse, -replace, and -dropreplace, editing flags may be repeated, and the changes are applied in the order given.
The -go=version flag sets the expected Go language version.
The -toolchain=name flag sets the Go toolchain to use.
The -print flag prints the final go.work in its text format instead of writing it back to go.mod.
The -json flag prints the final go.work file in JSON format instead of writing it back to go.mod. The JSON output corresponds to these Go types:
type GoWork struct { Go string Toolchain string Godebug []Godebug Use []Use Replace []Replace } type Godebug struct { Key string Value string } type Use struct { DiskPath string ModulePath string } type Replace struct { Old Module New Module } type Module struct { Path string Version string }
See the workspaces reference at https://go.dev/ref/mod#workspaces for more information.
Usage:
go work init [moddirs]
Init initializes and writes a new go.work file in the current directory, in effect creating a new workspace at the current directory.
go work init optionally accepts paths to the workspace modules as arguments. If the argument is omitted, an empty workspace with no modules will be created.
Each argument path is added to a use directive in the go.work file. The current go version will also be listed in the go.work file.
See the workspaces reference at https://go.dev/ref/mod#workspaces for more information.
Usage:
go work sync
Sync syncs the workspace's build list back to the workspace's modules
The workspace's build list is the set of versions of all the (transitive) dependency modules used to do builds in the workspace. go work sync generates that build list using the Minimal Version Selection algorithm, and then syncs those versions back to each of modules specified in the workspace (with use directives).
The syncing is done by sequentially upgrading each of the dependency modules specified in a workspace module to the version in the build list if the dependency module's version is not already the same as the build list's version. Note that Minimal Version Selection guarantees that the build list's version of each module is always the same or higher than that in each workspace module.
See the workspaces reference at https://go.dev/ref/mod#workspaces for more information.
Usage:
go work use [-r] [moddirs]
Use provides a command-line interface for adding directories, optionally recursively, to a go.work file.
A use directive will be added to the go.work file for each argument directory listed on the command line go.work file, if it exists, or removed from the go.work file if it does not exist. Use fails if any remaining use directives refer to modules that do not exist.
Use updates the go line in go.work to specify a version at least as new as all the go lines in the used modules, both preexisting ones and newly added ones. With no arguments, this update is the only thing that go work use does.
The -r flag searches recursively for modules in the argument directories, and the use command operates as if each of the directories were specified as arguments.
See the workspaces reference at https://go.dev/ref/mod#workspaces for more information.
Usage:
go work vendor [-e] [-v] [-o outdir]
Vendor resets the workspace's vendor directory to include all packages needed to build and test all the workspace's packages. It does not include test code for vendored packages.
The -v flag causes vendor to print the names of vendored modules and packages to standard error.
The -e flag causes vendor to attempt to proceed despite errors encountered while loading packages.
The -o flag causes vendor to create the vendor directory at the given path instead of "vendor". The go command can only use a vendor directory named "vendor" within the module root directory, so this flag is primarily useful for other tools.
Usage:
go run [build flags] [-exec xprog] package [arguments...]
Run compiles and runs the named main Go package. Typically the package is specified as a list of .go source files from a single directory, but it may also be an import path, file system path, or pattern matching a single known package, as in 'go run .' or 'go run my/cmd'.
If the package argument has a version suffix (like @latest or @v1.0.0), "go run" builds the program in module-aware mode, ignoring the go.mod file in the current directory or any parent directory, if there is one. This is useful for running programs without affecting the dependencies of the main module.
If the package argument doesn't have a version suffix, "go run" may run in module-aware mode or GOPATH mode, depending on the GO111MODULE environment variable and the presence of a go.mod file. See 'go help modules' for details. If module-aware mode is enabled, "go run" runs in the context of the main module.
By default, 'go run' runs the compiled binary directly: 'a.out arguments...'. If the -exec flag is given, 'go run' invokes the binary using xprog:
'xprog a.out arguments...'.
If the -exec flag is not given, GOOS or GOARCH is different from the system default, and a program named go_$GOOS_$GOARCH_exec can be found on the current search path, 'go run' invokes the binary using that program, for example 'go_js_wasm_exec a.out arguments...'. This allows execution of cross-compiled programs when a simulator or other execution method is available.
By default, 'go run' compiles the binary without generating the information used by debuggers, to reduce build time. To include debugger information in the binary, use 'go build'.
The exit status of Run is not the exit status of the compiled binary.
For more about build flags, see 'go help build'. For more about specifying packages, see 'go help packages'.
See also: go build.
Usage:
go telemetry [off|local|on]
Telemetry is used to manage Go telemetry data and settings.
Telemetry can be in one of three modes: off, local, or on.
When telemetry is in local mode, counter data is written to the local file system, but will not be uploaded to remote servers.
When telemetry is off, local counter data is neither collected nor uploaded.
When telemetry is on, telemetry data is written to the local file system and periodically sent to https://telemetry.go.dev/. Uploaded data is used to help improve the Go toolchain and related tools, and it will be published as part of a public dataset.
For more details, see https://telemetry.go.dev/privacy. This data is collected in accordance with the Google Privacy Policy (https://policies.google.com/privacy).
To view the current telemetry mode, run "go telemetry". To disable telemetry uploading, but keep local data collection, run "go telemetry local". To enable both collection and uploading, run “go telemetry on”. To disable both collection and uploading, run "go telemetry off".
See https://go.dev/doc/telemetry for more information on telemetry.
Usage:
go test [build/test flags] [packages] [build/test flags & test binary flags]
'Go test' automates testing the packages named by the import paths. It prints a summary of the test results in the format:
ok archive/tar 0.011s FAIL archive/zip 0.022s ok compress/gzip 0.033s ...
followed by detailed output for each failed package.
'Go test' recompiles each package along with any files with names matching the file pattern "*_test.go". These additional files can contain test functions, benchmark functions, fuzz tests and example functions. See 'go help testfunc' for more. Each listed package causes the execution of a separate test binary. Files whose names begin with "_" (including "_test.go") or "." are ignored.
Test files that declare a package with the suffix "_test" will be compiled as a separate package, and then linked and run with the main test binary.
The go tool will ignore a directory named "testdata", making it available to hold ancillary data needed by the tests.
As part of building a test binary, go test runs go vet on the package and its test source files to identify significant problems. If go vet finds any problems, go test reports those and does not run the test binary. Only a high-confidence subset of the default go vet checks are used. That subset is: atomic, bool, buildtags, directive, errorsas, ifaceassert, nilfunc, printf, and stringintconv. You can see the documentation for these and other vet tests via "go doc cmd/vet". To disable the running of go vet, use the -vet=off flag. To run all checks, use the -vet=all flag.
All test output and summary lines are printed to the go command's standard output, even if the test printed them to its own standard error. (The go command's standard error is reserved for printing errors building the tests.)
The go command places $GOROOT/bin at the beginning of $PATH in the test's environment, so that tests that execute 'go' commands use the same 'go' as the parent 'go test' command.
Go test runs in two different modes:
The first, called local directory mode, occurs when go test is invoked with no package arguments (for example, 'go test' or 'go test -v'). In this mode, go test compiles the package sources and tests found in the current directory and then runs the resulting test binary. In this mode, caching (discussed below) is disabled. After the package test finishes, go test prints a summary line showing the test status ('ok' or 'FAIL'), package name, and elapsed time.
The second, called package list mode, occurs when go test is invoked with explicit package arguments (for example 'go test math', 'go test ./...', and even 'go test .'). In this mode, go test compiles and tests each of the packages listed on the command line. If a package test passes, go test prints only the final 'ok' summary line. If a package test fails, go test prints the full test output. If invoked with the -bench or -v flag, go test prints the full output even for passing package tests, in order to display the requested benchmark results or verbose logging. After the package tests for all of the listed packages finish, and their output is printed, go test prints a final 'FAIL' status if any package test has failed.
In package list mode only, go test caches successful package test results to avoid unnecessary repeated running of tests. When the result of a test can be recovered from the cache, go test will redisplay the previous output instead of running the test binary again. When this happens, go test prints '(cached)' in place of the elapsed time in the summary line.
The rule for a match in the cache is that the run involves the same test binary and the flags on the command line come entirely from a restricted set of 'cacheable' test flags, defined as -benchtime, -cpu, -list, -parallel, -run, -short, -timeout, -failfast, -fullpath and -v. If a run of go test has any test or non-test flags outside this set, the result is not cached. To disable test caching, use any test flag or argument other than the cacheable flags. The idiomatic way to disable test caching explicitly is to use -count=1. Tests that open files within the package's source root (usually $GOPATH) or that consult environment variables only match future runs in which the files and environment variables are unchanged. A cached test result is treated as executing in no time at all, so a successful package test result will be cached and reused regardless of -timeout setting.
In addition to the build flags, the flags handled by 'go test' itself are:
-args Pass the remainder of the command line (everything after -args) to the test binary, uninterpreted and unchanged. Because this flag consumes the remainder of the command line, the package list (if present) must appear before this flag. -c Compile the test binary to pkg.test in the current directory but do not run it (where pkg is the last element of the package's import path). The file name or target directory can be changed with the -o flag. -exec xprog Run the test binary using xprog. The behavior is the same as in 'go run'. See 'go help run' for details. -json Convert test output to JSON suitable for automated processing. See 'go doc test2json' for the encoding details. -o file Compile the test binary to the named file. The test still runs (unless -c or -i is specified). If file ends in a slash or names an existing directory, the test is written to pkg.test in that directory.
The test binary also accepts flags that control execution of the test; these flags are also accessible by 'go test'. See 'go help testflag' for details.
For more about build flags, see 'go help build'. For more about specifying packages, see 'go help packages'.
See also: go build, go vet.
Usage:
go tool [-n] command [args...]
Tool runs the go tool command identified by the arguments. With no arguments it prints the list of known tools.
The -n flag causes tool to print the command that would be executed but not execute it.
For more about each tool command, see 'go doc cmd/<command>'.
Usage:
go version [-m] [-v] [file ...]
Version prints the build information for Go binary files.
Go version reports the Go version used to build each of the named files.
If no files are named on the command line, go version prints its own version information.
If a directory is named, go version walks that directory, recursively, looking for recognized Go binaries and reporting their versions. By default, go version does not report unrecognized files found during a directory scan. The -v flag causes it to report unrecognized files.
The -m flag causes go version to print each file's embedded module version information, when available. In the output, the module information consists of multiple lines following the version line, each indented by a leading tab character.
See also: go doc runtime/debug.BuildInfo.
Usage:
go vet [build flags] [-vettool prog] [vet flags] [packages]
Vet runs the Go vet command on the packages named by the import paths.
For more about vet and its flags, see 'go doc cmd/vet'. For more about specifying packages, see 'go help packages'. For a list of checkers and their flags, see 'go tool vet help'. For details of a specific checker such as 'printf', see 'go tool vet help printf'.
The -vettool=prog flag selects a different analysis tool with alternative or additional checks. For example, the 'shadow' analyzer can be built and run using these commands:
go install golang.org/x/tools/go/analysis/passes/shadow/cmd/shadow@latest go vet -vettool=$(which shadow)
The build flags supported by go vet are those that control package resolution and execution, such as -C, -n, -x, -v, -tags, and -toolexec. For more about these flags, see 'go help build'.
See also: go fmt, go fix.
A build constraint, also known as a build tag, is a condition under which a file should be included in the package. Build constraints are given by a line comment that begins
//go:build
Build constraints can also be used to downgrade the language version used to compile a file.
Constraints may appear in any kind of source file (not just Go), but they must appear near the top of the file, preceded only by blank lines and other comments. These rules mean that in Go files a build constraint must appear before the package clause.
To distinguish build constraints from package documentation, a build constraint should be followed by a blank line.
A build constraint comment is evaluated as an expression containing build tags combined by ||, &&, and ! operators and parentheses. Operators have the same meaning as in Go.
For example, the following build constraint constrains a file to build when the "linux" and "386" constraints are satisfied, or when "darwin" is satisfied and "cgo" is not:
//go:build (linux && 386) || (darwin && !cgo)
It is an error for a file to have more than one //go:build line.
During a particular build, the following build tags are satisfied:
There are no separate build tags for beta or minor releases.
If a file's name, after stripping the extension and a possible _test suffix, matches any of the following patterns:
*_GOOS *_GOARCH *_GOOS_GOARCH
(example: source_windows_amd64.go) where GOOS and GOARCH represent any known operating system and architecture values respectively, then the file is considered to have an implicit build constraint requiring those terms (in addition to any explicit constraints in the file).
Using GOOS=android matches build tags and files as for GOOS=linux in addition to android tags and files.
Using GOOS=illumos matches build tags and files as for GOOS=solaris in addition to illumos tags and files.
Using GOOS=ios matches build tags and files as for GOOS=darwin in addition to ios tags and files.
The defined architecture feature build tags are:
For GOARCH=amd64, arm, ppc64, ppc64le, and riscv64, a particular feature level sets the feature build tags for all previous levels as well. For example, GOAMD64=v2 sets the amd64.v1 and amd64.v2 feature flags. This ensures that code making use of v2 features continues to compile when, say, GOAMD64=v4 is introduced. Code handling the absence of a particular feature level should use a negation:
//go:build !amd64.v2
To keep a file from being considered for any build:
//go:build ignore
(Any other unsatisfied word will work as well, but "ignore" is conventional.)
To build a file only when using cgo, and only on Linux and OS X:
//go:build cgo && (linux || darwin)
Such a file is usually paired with another file implementing the default functionality for other systems, which in this case would carry the constraint:
//go:build !(cgo && (linux || darwin))
Naming a file dns_windows.go will cause it to be included only when building the package for Windows; similarly, math_386.s will be included only when building the package for 32-bit x86.
Go versions 1.16 and earlier used a different syntax for build constraints, with a "// +build" prefix. The gofmt command will add an equivalent //go:build constraint when encountering the older syntax.
In modules with a Go version of 1.21 or later, if a file's build constraint has a term for a Go major release, the language version used when compiling the file will be the minimum version implied by the build constraint.
The 'go build' and 'go install' commands take a -buildmode argument which indicates which kind of object file is to be built. Currently supported values are:
-buildmode=archive Build the listed non-main packages into .a files. Packages named main are ignored. -buildmode=c-archive Build the listed main package, plus all packages it imports, into a C archive file. The only callable symbols will be those functions exported using a cgo //export comment. Requires exactly one main package to be listed. -buildmode=c-shared Build the listed main package, plus all packages it imports, into a C shared library. The only callable symbols will be those functions exported using a cgo //export comment. Requires exactly one main package to be listed. -buildmode=default Listed main packages are built into executables and listed non-main packages are built into .a files (the default behavior). -buildmode=shared Combine all the listed non-main packages into a single shared library that will be used when building with the -linkshared option. Packages named main are ignored. -buildmode=exe Build the listed main packages and everything they import into executables. Packages not named main are ignored. -buildmode=pie Build the listed main packages and everything they import into position independent executables (PIE). Packages not named main are ignored. -buildmode=plugin Build the listed main packages, plus all packages that they import, into a Go plugin. Packages not named main are ignored.
On AIX, when linking a C program that uses a Go archive built with -buildmode=c-archive, you must pass -Wl,-bnoobjreorder to the C compiler.
There are two different ways to call between Go and C/C++ code.
The first is the cgo tool, which is part of the Go distribution. For information on how to use it see the cgo documentation (go doc cmd/cgo).
The second is the SWIG program, which is a general tool for interfacing between languages. For information on SWIG see http://swig.org/. When running go build, any file with a .swig extension will be passed to SWIG. Any file with a .swigcxx extension will be passed to SWIG with the -c++ option.
When either cgo or SWIG is used, go build will pass any .c, .m, .s, .S or .sx files to the C compiler, and any .cc, .cpp, .cxx files to the C++ compiler. The CC or CXX environment variables may be set to determine the C or C++ compiler, respectively, to use.
The go command caches build outputs for reuse in future builds. The default location for cache data is a subdirectory named go-build in the standard user cache directory for the current operating system. Setting the GOCACHE environment variable overrides this default, and running 'go env GOCACHE' prints the current cache directory.
The go command periodically deletes cached data that has not been used recently. Running 'go clean -cache' deletes all cached data.
The build cache correctly accounts for changes to Go source files, compilers, compiler options, and so on: cleaning the cache explicitly should not be necessary in typical use. However, the build cache does not detect changes to C libraries imported with cgo. If you have made changes to the C libraries on your system, you will need to clean the cache explicitly or else use the -a build flag (see 'go help build') to force rebuilding of packages that depend on the updated C libraries.
The go command also caches successful package test results. See 'go help test' for details. Running 'go clean -testcache' removes all cached test results (but not cached build results).
The go command also caches values used in fuzzing with 'go test -fuzz', specifically, values that expanded code coverage when passed to a fuzz function. These values are not used for regular building and testing, but they're stored in a subdirectory of the build cache. Running 'go clean -fuzzcache' removes all cached fuzzing values. This may make fuzzing less effective, temporarily.
The GODEBUG environment variable can enable printing of debugging information about the state of the cache:
GODEBUG=gocacheverify=1 causes the go command to bypass the use of any cache entries and instead rebuild everything and check that the results match existing cache entries.
GODEBUG=gocachehash=1 causes the go command to print the inputs for all of the content hashes it uses to construct cache lookup keys. The output is voluminous but can be useful for debugging the cache.
GODEBUG=gocachetest=1 causes the go command to print details of its decisions about whether to reuse a cached test result.
The go command and the tools it invokes consult environment variables for configuration. If an environment variable is unset or empty, the go command uses a sensible default setting. To see the effective setting of the variable <NAME>, run 'go env <NAME>'. To change the default setting, run 'go env -w <NAME>=<VALUE>'. Defaults changed using 'go env -w' are recorded in a Go environment configuration file stored in the per-user configuration directory, as reported by os.UserConfigDir. The location of the configuration file can be changed by setting the environment variable GOENV, and 'go env GOENV' prints the effective location, but 'go env -w' cannot change the default location. See 'go help env' for details.
General-purpose environment variables:
GO111MODULE Controls whether the go command runs in module-aware mode or GOPATH mode. May be "off", "on", or "auto". See https://golang.org/ref/mod#mod-commands. GCCGO The gccgo command to run for 'go build -compiler=gccgo'. GOARCH The architecture, or processor, for which to compile code. Examples are amd64, 386, arm, ppc64. GOBIN The directory where 'go install' will install a command. GOCACHE The directory where the go command will store cached information for reuse in future builds. GOMODCACHE The directory where the go command will store downloaded modules. GODEBUG Enable various debugging facilities. See https://go.dev/doc/godebug for details. GOENV The location of the Go environment configuration file. Cannot be set using 'go env -w'. Setting GOENV=off in the environment disables the use of the default configuration file. GOFLAGS A space-separated list of -flag=value settings to apply to go commands by default, when the given flag is known by the current command. Each entry must be a standalone flag. Because the entries are space-separated, flag values must not contain spaces. Flags listed on the command line are applied after this list and therefore override it. GOINSECURE Comma-separated list of glob patterns (in the syntax of Go's path.Match) of module path prefixes that should always be fetched in an insecure manner. Only applies to dependencies that are being fetched directly. GOINSECURE does not disable checksum database validation. GOPRIVATE or GONOSUMDB may be used to achieve that. GOOS The operating system for which to compile code. Examples are linux, darwin, windows, netbsd. GOPATH Controls where various files are stored. See: 'go help gopath'. GOPROXY URL of Go module proxy. See https://golang.org/ref/mod#environment-variables and https://golang.org/ref/mod#module-proxy for details. GOPRIVATE, GONOPROXY, GONOSUMDB Comma-separated list of glob patterns (in the syntax of Go's path.Match) of module path prefixes that should always be fetched directly or that should not be compared against the checksum database. See https://golang.org/ref/mod#private-modules. GOROOT The root of the go tree. GOSUMDB The name of checksum database to use and optionally its public key and URL. See https://golang.org/ref/mod#authenticating. GOTOOLCHAIN Controls which Go toolchain is used. See https://go.dev/doc/toolchain. GOTMPDIR The directory where the go command will write temporary source files, packages, and binaries. GOVCS Lists version control commands that may be used with matching servers. See 'go help vcs'. GOWORK In module aware mode, use the given go.work file as a workspace file. By default or when GOWORK is "auto", the go command searches for a file named go.work in the current directory and then containing directories until one is found. If a valid go.work file is found, the modules specified will collectively be used as the main modules. If GOWORK is "off", or a go.work file is not found in "auto" mode, workspace mode is disabled.
Environment variables for use with cgo:
AR The command to use to manipulate library archives when building with the gccgo compiler. The default is 'ar'. CC The command to use to compile C code. CGO_ENABLED Whether the cgo command is supported. Either 0 or 1. CGO_CFLAGS Flags that cgo will pass to the compiler when compiling C code. CGO_CFLAGS_ALLOW A regular expression specifying additional flags to allow to appear in #cgo CFLAGS source code directives. Does not apply to the CGO_CFLAGS environment variable. CGO_CFLAGS_DISALLOW A regular expression specifying flags that must be disallowed from appearing in #cgo CFLAGS source code directives. Does not apply to the CGO_CFLAGS environment variable. CGO_CPPFLAGS, CGO_CPPFLAGS_ALLOW, CGO_CPPFLAGS_DISALLOW Like CGO_CFLAGS, CGO_CFLAGS_ALLOW, and CGO_CFLAGS_DISALLOW, but for the C preprocessor. CGO_CXXFLAGS, CGO_CXXFLAGS_ALLOW, CGO_CXXFLAGS_DISALLOW Like CGO_CFLAGS, CGO_CFLAGS_ALLOW, and CGO_CFLAGS_DISALLOW, but for the C++ compiler. CGO_FFLAGS, CGO_FFLAGS_ALLOW, CGO_FFLAGS_DISALLOW Like CGO_CFLAGS, CGO_CFLAGS_ALLOW, and CGO_CFLAGS_DISALLOW, but for the Fortran compiler. CGO_LDFLAGS, CGO_LDFLAGS_ALLOW, CGO_LDFLAGS_DISALLOW Like CGO_CFLAGS, CGO_CFLAGS_ALLOW, and CGO_CFLAGS_DISALLOW, but for the linker. CXX The command to use to compile C++ code. FC The command to use to compile Fortran code. PKG_CONFIG Path to pkg-config tool.
Architecture-specific environment variables:
GOARM For GOARCH=arm, the ARM architecture for which to compile. Valid values are 5, 6, 7. The value can be followed by an option specifying how to implement floating point instructions. Valid options are ,softfloat (default for 5) and ,hardfloat (default for 6 and 7). GOARM64 For GOARCH=arm64, the ARM64 architecture for which to compile. Valid values are v8.0 (default), v8.{1-9}, v9.{0-5}. The value can be followed by an option specifying extensions implemented by target hardware. Valid options are ,lse and ,crypto. Note that some extensions are enabled by default starting from a certain GOARM64 version; for example, lse is enabled by default starting from v8.1. GO386 For GOARCH=386, how to implement floating point instructions. Valid values are sse2 (default), softfloat. GOAMD64 For GOARCH=amd64, the microarchitecture level for which to compile. Valid values are v1 (default), v2, v3, v4. See https://golang.org/wiki/MinimumRequirements#amd64 GOMIPS For GOARCH=mips{,le}, whether to use floating point instructions. Valid values are hardfloat (default), softfloat. GOMIPS64 For GOARCH=mips64{,le}, whether to use floating point instructions. Valid values are hardfloat (default), softfloat. GOPPC64 For GOARCH=ppc64{,le}, the target ISA (Instruction Set Architecture). Valid values are power8 (default), power9, power10. GORISCV64 For GOARCH=riscv64, the RISC-V user-mode application profile for which to compile. Valid values are rva20u64 (default), rva22u64. See https://github.com/riscv/riscv-profiles/blob/main/src/profiles.adoc GOWASM For GOARCH=wasm, comma-separated list of experimental WebAssembly features to use. Valid values are satconv, signext.
Environment variables for use with code coverage:
GOCOVERDIR Directory into which to write code coverage data files generated by running a "go build -cover" binary. Requires that GOEXPERIMENT=coverageredesign is enabled.
Special-purpose environment variables:
GCCGOTOOLDIR If set, where to find gccgo tools, such as cgo. The default is based on how gccgo was configured. GOEXPERIMENT Comma-separated list of toolchain experiments to enable or disable. The list of available experiments may change arbitrarily over time. See src/internal/goexperiment/flags.go for currently valid values. Warning: This variable is provided for the development and testing of the Go toolchain itself. Use beyond that purpose is unsupported. GO_EXTLINK_ENABLED Whether the linker should use external linking mode when using -linkmode=auto with code that uses cgo. Set to 0 to disable external linking mode, 1 to enable it. GIT_ALLOW_PROTOCOL Defined by Git. A colon-separated list of schemes that are allowed to be used with git fetch/clone. If set, any scheme not explicitly mentioned will be considered insecure by 'go get'. Because the variable is defined by Git, the default value cannot be set using 'go env -w'.
Additional information available from 'go env' but not read from the environment:
GOEXE The executable file name suffix (".exe" on Windows, "" on other systems). GOGCCFLAGS A space-separated list of arguments supplied to the CC command. GOHOSTARCH The architecture (GOARCH) of the Go toolchain binaries. GOHOSTOS The operating system (GOOS) of the Go toolchain binaries. GOMOD The absolute path to the go.mod of the main module. If module-aware mode is enabled, but there is no go.mod, GOMOD will be os.DevNull ("/dev/null" on Unix-like systems, "NUL" on Windows). If module-aware mode is disabled, GOMOD will be the empty string. GOTOOLDIR The directory where the go tools (compile, cover, doc, etc...) are installed. GOVERSION The version of the installed Go tree, as reported by runtime.Version.
The go command examines the contents of a restricted set of files in each directory. It identifies which files to examine based on the extension of the file name. These extensions are:
.go Go source files. .c, .h C source files. If the package uses cgo or SWIG, these will be compiled with the OS-native compiler (typically gcc); otherwise they will trigger an error. .cc, .cpp, .cxx, .hh, .hpp, .hxx C++ source files. Only useful with cgo or SWIG, and always compiled with the OS-native compiler. .m Objective-C source files. Only useful with cgo, and always compiled with the OS-native compiler. .s, .S, .sx Assembler source files. If the package uses cgo or SWIG, these will be assembled with the OS-native assembler (typically gcc (sic)); otherwise they will be assembled with the Go assembler. .swig, .swigcxx SWIG definition files. .syso System object files.
Files of each of these types except .syso may contain build constraints, but the go command stops scanning for build constraints at the first item in the file that is not a blank line or //-style line comment. See the go/build package documentation for more details.
A module version is defined by a tree of source files, with a go.mod file in its root. When the go command is run, it looks in the current directory and then successive parent directories to find the go.mod marking the root of the main (current) module.
The go.mod file format is described in detail at https://golang.org/ref/mod#go-mod-file.
To create a new go.mod file, use 'go mod init'. For details see 'go help mod init' or https://golang.org/ref/mod#go-mod-init.
To add missing module requirements or remove unneeded requirements, use 'go mod tidy'. For details, see 'go help mod tidy' or https://golang.org/ref/mod#go-mod-tidy.
To add, upgrade, downgrade, or remove a specific module requirement, use 'go get'. For details, see 'go help module-get' or https://golang.org/ref/mod#go-get.
To make other changes or to parse go.mod as JSON for use by other tools, use 'go mod edit'. See 'go help mod edit' or https://golang.org/ref/mod#go-mod-edit.
The Go path is used to resolve import statements. It is implemented by and documented in the go/build package.
The GOPATH environment variable lists places to look for Go code. On Unix, the value is a colon-separated string. On Windows, the value is a semicolon-separated string. On Plan 9, the value is a list.
If the environment variable is unset, GOPATH defaults to a subdirectory named "go" in the user's home directory ($HOME/go on Unix, %USERPROFILE%\go on Windows), unless that directory holds a Go distribution. Run "go env GOPATH" to see the current GOPATH.
See https://golang.org/wiki/SettingGOPATH to set a custom GOPATH.
Each directory listed in GOPATH must have a prescribed structure:
The src directory holds source code. The path below src determines the import path or executable name.
The pkg directory holds installed package objects. As in the Go tree, each target operating system and architecture pair has its own subdirectory of pkg (pkg/GOOS_GOARCH).
If DIR is a directory listed in the GOPATH, a package with source in DIR/src/foo/bar can be imported as "foo/bar" and has its compiled form installed to "DIR/pkg/GOOS_GOARCH/foo/bar.a".
The bin directory holds compiled commands. Each command is named for its source directory, but only the final element, not the entire path. That is, the command with source in DIR/src/foo/quux is installed into DIR/bin/quux, not DIR/bin/foo/quux. The "foo/" prefix is stripped so that you can add DIR/bin to your PATH to get at the installed commands. If the GOBIN environment variable is set, commands are installed to the directory it names instead of DIR/bin. GOBIN must be an absolute path.
Here's an example directory layout:
GOPATH=/home/user/go /home/user/go/ src/ foo/ bar/ (go code in package bar) x.go quux/ (go code in package main) y.go bin/ quux (installed command) pkg/ linux_amd64/ foo/ bar.a (installed package object)
Go searches each directory listed in GOPATH to find source code, but new packages are always downloaded into the first directory in the list.
See https://golang.org/doc/code.html for an example.
When using modules, GOPATH is no longer used for resolving imports. However, it is still used to store downloaded source code (in GOPATH/pkg/mod) and compiled commands (in GOPATH/bin).
Code in or below a directory named "internal" is importable only by code in the directory tree rooted at the parent of "internal". Here's an extended version of the directory layout above:
/home/user/go/ src/ crash/ bang/ (go code in package bang) b.go foo/ (go code in package foo) f.go bar/ (go code in package bar) x.go internal/ baz/ (go code in package baz) z.go quux/ (go code in package main) y.go
The code in z.go is imported as "foo/internal/baz", but that import statement can only appear in source files in the subtree rooted at foo. The source files foo/f.go, foo/bar/x.go, and foo/quux/y.go can all import "foo/internal/baz", but the source file crash/bang/b.go cannot.
See https://golang.org/s/go14internal for details.
Go 1.6 includes support for using local copies of external dependencies to satisfy imports of those dependencies, often referred to as vendoring.
Code below a directory named "vendor" is importable only by code in the directory tree rooted at the parent of "vendor", and only using an import path that omits the prefix up to and including the vendor element.
Here's the example from the previous section, but with the "internal" directory renamed to "vendor" and a new foo/vendor/crash/bang directory added:
/home/user/go/ src/ crash/ bang/ (go code in package bang) b.go foo/ (go code in package foo) f.go bar/ (go code in package bar) x.go vendor/ crash/ bang/ (go code in package bang) b.go baz/ (go code in package baz) z.go quux/ (go code in package main) y.go
The same visibility rules apply as for internal, but the code in z.go is imported as "baz", not as "foo/vendor/baz".
Code in vendor directories deeper in the source tree shadows code in higher directories. Within the subtree rooted at foo, an import of "crash/bang" resolves to "foo/vendor/crash/bang", not the top-level "crash/bang".
Code in vendor directories is not subject to import path checking (see 'go help importpath').
When 'go get' checks out or updates a git repository, it now also updates submodules.
Vendor directories do not affect the placement of new repositories being checked out for the first time by 'go get': those are always placed in the main GOPATH, never in a vendor subtree.
See https://golang.org/s/go15vendor for details.
A Go module proxy is any web server that can respond to GET requests for URLs of a specified form. The requests have no query parameters, so even a site serving from a fixed file system (including a file:/// URL) can be a module proxy.
For details on the GOPROXY protocol, see https://golang.org/ref/mod#goproxy-protocol.
An import path (see 'go help packages') denotes a package stored in the local file system. In general, an import path denotes either a standard package (such as "unicode/utf8") or a package found in one of the work spaces (For more details see: 'go help gopath').
An import path beginning with ./ or ../ is called a relative path. The toolchain supports relative import paths as a shortcut in two ways.
First, a relative path can be used as a shorthand on the command line. If you are working in the directory containing the code imported as "unicode" and want to run the tests for "unicode/utf8", you can type "go test ./utf8" instead of needing to specify the full path. Similarly, in the reverse situation, "go test .." will test "unicode" from the "unicode/utf8" directory. Relative patterns are also allowed, like "go test ./..." to test all subdirectories. See 'go help packages' for details on the pattern syntax.
Second, if you are compiling a Go program not in a work space, you can use a relative path in an import statement in that program to refer to nearby code also not in a work space. This makes it easy to experiment with small multipackage programs outside of the usual work spaces, but such programs cannot be installed with "go install" (there is no work space in which to install them), so they are rebuilt from scratch each time they are built. To avoid ambiguity, Go programs cannot use relative import paths within a work space.
Certain import paths also describe how to obtain the source code for the package using a revision control system.
A few common code hosting sites have special syntax:
Bitbucket (Git, Mercurial) import "bitbucket.org/user/project" import "bitbucket.org/user/project/sub/directory" GitHub (Git) import "github.com/user/project" import "github.com/user/project/sub/directory" Launchpad (Bazaar) import "launchpad.net/project" import "launchpad.net/project/series" import "launchpad.net/project/series/sub/directory" import "launchpad.net/~user/project/branch" import "launchpad.net/~user/project/branch/sub/directory" IBM DevOps Services (Git) import "hub.jazz.net/git/user/project" import "hub.jazz.net/git/user/project/sub/directory"
For code hosted on other servers, import paths may either be qualified with the version control type, or the go tool can dynamically fetch the import path over https/http and discover where the code resides from a <meta> tag in the HTML.
To declare the code location, an import path of the form
repository.vcs/path
specifies the given repository, with or without the .vcs suffix, using the named version control system, and then the path inside that repository. The supported version control systems are:
Bazaar .bzr Fossil .fossil Git .git Mercurial .hg Subversion .svn
For example,
import "example.org/user/foo.hg"
denotes the root directory of the Mercurial repository at example.org/user/foo or foo.hg, and
import "example.org/repo.git/foo/bar"
denotes the foo/bar directory of the Git repository at example.org/repo or repo.git.
When a version control system supports multiple protocols, each is tried in turn when downloading. For example, a Git download tries https://, then git+ssh://.
By default, downloads are restricted to known secure protocols (e.g. https, ssh). To override this setting for Git downloads, the GIT_ALLOW_PROTOCOL environment variable can be set (For more details see: 'go help environment').
If the import path is not a known code hosting site and also lacks a version control qualifier, the go tool attempts to fetch the import over https/http and looks for a <meta> tag in the document's HTML <head>.
The meta tag has the form:
<meta name="go-import" content="import-prefix vcs repo-root">
The import-prefix is the import path corresponding to the repository root. It must be a prefix or an exact match of the package being fetched with "go get". If it's not an exact match, another http request is made at the prefix to verify the <meta> tags match.
The meta tag should appear as early in the file as possible. In particular, it should appear before any raw JavaScript or CSS, to avoid confusing the go command's restricted parser.
The vcs is one of "bzr", "fossil", "git", "hg", "svn".
The repo-root is the root of the version control system containing a scheme and not containing a .vcs qualifier.
For example,
import "example.org/pkg/foo"
will result in the following requests:
https://example.org/pkg/foo?go-get=1 (preferred) http://example.org/pkg/foo?go-get=1 (fallback, only with use of correctly set GOINSECURE)
If that page contains the meta tag
<meta name="go-import" content="example.org git https://code.org/r/p/exproj">
the go tool will verify that https://example.org/?go-get=1 contains the same meta tag and then git clone https://code.org/r/p/exproj into GOPATH/src/example.org.
When using GOPATH, downloaded packages are written to the first directory listed in the GOPATH environment variable. (See 'go help gopath-get' and 'go help gopath'.)
When using modules, downloaded packages are stored in the module cache. See https://golang.org/ref/mod#module-cache.
When using modules, an additional variant of the go-import meta tag is recognized and is preferred over those listing version control systems. That variant uses "mod" as the vcs in the content value, as in:
<meta name="go-import" content="example.org mod https://code.org/moduleproxy">
This tag means to fetch modules with paths beginning with example.org from the module proxy available at the URL https://code.org/moduleproxy. See https://golang.org/ref/mod#goproxy-protocol for details about the proxy protocol.
When the custom import path feature described above redirects to a known code hosting site, each of the resulting packages has two possible import paths, using the custom domain or the known hosting site.
A package statement is said to have an "import comment" if it is immediately followed (before the next newline) by a comment of one of these two forms:
package math // import "path" package math /* import "path" */
The go command will refuse to install a package with an import comment unless it is being referred to by that import path. In this way, import comments let package authors make sure the custom import path is used and not a direct path to the underlying code hosting site.
Import path checking is disabled for code found within vendor trees. This makes it possible to copy code into alternate locations in vendor trees without needing to update import comments.
Import path checking is also disabled when using modules. Import path comments are obsoleted by the go.mod file's module statement.
See https://golang.org/s/go14customimport for details.
Modules are how Go manages dependencies.
A module is a collection of packages that are released, versioned, and distributed together. Modules may be downloaded directly from version control repositories or from module proxy servers.
For a series of tutorials on modules, see https://golang.org/doc/tutorial/create-module.
For a detailed reference on modules, see https://golang.org/ref/mod.
By default, the go command may download modules from https://proxy.golang.org. It may authenticate modules using the checksum database at https://sum.golang.org. Both services are operated by the Go team at Google. The privacy policies for these services are available at https://proxy.golang.org/privacy and https://sum.golang.org/privacy, respectively.
The go command's download behavior may be configured using GOPROXY, GOSUMDB, GOPRIVATE, and other environment variables. See 'go help environment' and https://golang.org/ref/mod#private-module-privacy for more information.
When the go command downloads a module zip file or go.mod file into the module cache, it computes a cryptographic hash and compares it with a known value to verify the file hasn't changed since it was first downloaded. Known hashes are stored in a file in the module root directory named go.sum. Hashes may also be downloaded from the checksum database depending on the values of GOSUMDB, GOPRIVATE, and GONOSUMDB.
For details, see https://golang.org/ref/mod#authenticating.
Many commands apply to a set of packages:
go <action> [packages]
Usually, [packages] is a list of import paths.
An import path that is a rooted path or that begins with a . or .. element is interpreted as a file system path and denotes the package in that directory.
Otherwise, the import path P denotes the package found in the directory DIR/src/P for some DIR listed in the GOPATH environment variable (For more details see: 'go help gopath').
If no import paths are given, the action applies to the package in the current directory.
There are four reserved names for paths that should not be used for packages to be built with the go tool:
- "main" denotes the top-level package in a stand-alone executable.
- "all" expands to all packages found in all the GOPATH trees. For example, 'go list all' lists all the packages on the local system. When using modules, "all" expands to all packages in the main module and their dependencies, including dependencies needed by tests of any of those.
- "std" is like all but expands to just the packages in the standard Go library.
- "cmd" expands to the Go repository's commands and their internal libraries.
Import paths beginning with "cmd/" only match source code in the Go repository.
An import path is a pattern if it includes one or more "..." wildcards, each of which can match any string, including the empty string and strings containing slashes. Such a pattern expands to all package directories found in the GOPATH trees with names matching the patterns.
To make common patterns more convenient, there are two special cases. First, /... at the end of the pattern can match an empty string, so that net/... matches both net and packages in its subdirectories, like net/http. Second, any slash-separated pattern element containing a wildcard never participates in a match of the "vendor" element in the path of a vendored package, so that ./... does not match packages in subdirectories of ./vendor or ./mycode/vendor, but ./vendor/... and ./mycode/vendor/... do. Note, however, that a directory named vendor that itself contains code is not a vendored package: cmd/vendor would be a command named vendor, and the pattern cmd/... matches it. See golang.org/s/go15vendor for more about vendoring.
An import path can also name a package to be downloaded from a remote repository. Run 'go help importpath' for details.
Every package in a program must have a unique import path. By convention, this is arranged by starting each path with a unique prefix that belongs to you. For example, paths used internally at Google all begin with 'google', and paths denoting remote repositories begin with the path to the code, such as 'github.com/user/repo'.
Packages in a program need not have unique package names, but there are two reserved package names with special meaning. The name main indicates a command, not a library. Commands are built into binaries and cannot be imported. The name documentation indicates documentation for a non-Go program in the directory. Files in package documentation are ignored by the go command.
As a special case, if the package list is a list of .go files from a single directory, the command is applied to a single synthesized package made up of exactly those files, ignoring any build constraints in those files and ignoring any other files in the directory.
Directory and file names that begin with "." or "_" are ignored by the go tool, as are directories named "testdata".
The go command defaults to downloading modules from the public Go module mirror at proxy.golang.org. It also defaults to validating downloaded modules, regardless of source, against the public Go checksum database at sum.golang.org. These defaults work well for publicly available source code.
The GOPRIVATE environment variable controls which modules the go command considers to be private (not available publicly) and should therefore not use the proxy or checksum database. The variable is a comma-separated list of glob patterns (in the syntax of Go's path.Match) of module path prefixes. For example,
GOPRIVATE=*.corp.example.com,rsc.io/private
causes the go command to treat as private any module with a path prefix matching either pattern, including git.corp.example.com/xyzzy, rsc.io/private, and rsc.io/private/quux.
For fine-grained control over module download and validation, the GONOPROXY and GONOSUMDB environment variables accept the same kind of glob list and override GOPRIVATE for the specific decision of whether to use the proxy and checksum database, respectively.
For example, if a company ran a module proxy serving private modules, users would configure go using:
GOPRIVATE=*.corp.example.com GOPROXY=proxy.example.com GONOPROXY=none
The GOPRIVATE variable is also used to define the "public" and "private" patterns for the GOVCS variable; see 'go help vcs'. For that usage, GOPRIVATE applies even in GOPATH mode. In that case, it matches import paths instead of module paths.
The 'go env -w' command (see 'go help env') can be used to set these variables for future go command invocations.
For more details, see https://golang.org/ref/mod#private-modules.
The 'go test' command takes both flags that apply to 'go test' itself and flags that apply to the resulting test binary.
Several of the flags control profiling and write an execution profile suitable for "go tool pprof"; run "go tool pprof -h" for more information. The --alloc_space, --alloc_objects, and --show_bytes options of pprof control how the information is presented.
The following flags are recognized by the 'go test' command and control the execution of any test:
-bench regexp Run only those benchmarks matching a regular expression. By default, no benchmarks are run. To run all benchmarks, use '-bench .' or '-bench=.'. The regular expression is split by unbracketed slash (/) characters into a sequence of regular expressions, and each part of a benchmark's identifier must match the corresponding element in the sequence, if any. Possible parents of matches are run with b.N=1 to identify sub-benchmarks. For example, given -bench=X/Y, top-level benchmarks matching X are run with b.N=1 to find any sub-benchmarks matching Y, which are then run in full. -benchtime t Run enough iterations of each benchmark to take t, specified as a time.Duration (for example, -benchtime 1h30s). The default is 1 second (1s). The special syntax Nx means to run the benchmark N times (for example, -benchtime 100x). -count n Run each test, benchmark, and fuzz seed n times (default 1). If -cpu is set, run n times for each GOMAXPROCS value. Examples are always run once. -count does not apply to fuzz tests matched by -fuzz. -cover Enable coverage analysis. Note that because coverage works by annotating the source code before compilation, compilation and test failures with coverage enabled may report line numbers that don't correspond to the original sources. -covermode set,count,atomic Set the mode for coverage analysis for the package[s] being tested. The default is "set" unless -race is enabled, in which case it is "atomic". The values: set: bool: does this statement run? count: int: how many times does this statement run? atomic: int: count, but correct in multithreaded tests; significantly more expensive. Sets -cover. -coverpkg pattern1,pattern2,pattern3 Apply coverage analysis in each test to packages matching the patterns. The default is for each test to analyze only the package being tested. See 'go help packages' for a description of package patterns. Sets -cover. -cpu 1,2,4 Specify a list of GOMAXPROCS values for which the tests, benchmarks or fuzz tests should be executed. The default is the current value of GOMAXPROCS. -cpu does not apply to fuzz tests matched by -fuzz. -failfast Do not start new tests after the first test failure. -fullpath Show full file names in the error messages. -fuzz regexp Run the fuzz test matching the regular expression. When specified, the command line argument must match exactly one package within the main module, and regexp must match exactly one fuzz test within that package. Fuzzing will occur after tests, benchmarks, seed corpora of other fuzz tests, and examples have completed. See the Fuzzing section of the testing package documentation for details. -fuzztime t Run enough iterations of the fuzz target during fuzzing to take t, specified as a time.Duration (for example, -fuzztime 1h30s). The default is to run forever. The special syntax Nx means to run the fuzz target N times (for example, -fuzztime 1000x). -fuzzminimizetime t Run enough iterations of the fuzz target during each minimization attempt to take t, as specified as a time.Duration (for example, -fuzzminimizetime 30s). The default is 60s. The special syntax Nx means to run the fuzz target N times (for example, -fuzzminimizetime 100x). -json Log verbose output and test results in JSON. This presents the same information as the -v flag in a machine-readable format. -list regexp List tests, benchmarks, fuzz tests, or examples matching the regular expression. No tests, benchmarks, fuzz tests, or examples will be run. This will only list top-level tests. No subtest or subbenchmarks will be shown. -parallel n Allow parallel execution of test functions that call t.Parallel, and fuzz targets that call t.Parallel when running the seed corpus. The value of this flag is the maximum number of tests to run simultaneously. While fuzzing, the value of this flag is the maximum number of subprocesses that may call the fuzz function simultaneously, regardless of whether T.Parallel is called. By default, -parallel is set to the value of GOMAXPROCS. Setting -parallel to values higher than GOMAXPROCS may cause degraded performance due to CPU contention, especially when fuzzing. Note that -parallel only applies within a single test binary. The 'go test' command may run tests for different packages in parallel as well, according to the setting of the -p flag (see 'go help build'). -run regexp Run only those tests, examples, and fuzz tests matching the regular expression. For tests, the regular expression is split by unbracketed slash (/) characters into a sequence of regular expressions, and each part of a test's identifier must match the corresponding element in the sequence, if any. Note that possible parents of matches are run too, so that -run=X/Y matches and runs and reports the result of all tests matching X, even those without sub-tests matching Y, because it must run them to look for those sub-tests. See also -skip. -short Tell long-running tests to shorten their run time. It is off by default but set during all.bash so that installing the Go tree can run a sanity check but not spend time running exhaustive tests. -shuffle off,on,N Randomize the execution order of tests and benchmarks. It is off by default. If -shuffle is set to on, then it will seed the randomizer using the system clock. If -shuffle is set to an integer N, then N will be used as the seed value. In both cases, the seed will be reported for reproducibility. -skip regexp Run only those tests, examples, fuzz tests, and benchmarks that do not match the regular expression. Like for -run and -bench, for tests and benchmarks, the regular expression is split by unbracketed slash (/) characters into a sequence of regular expressions, and each part of a test's identifier must match the corresponding element in the sequence, if any. -timeout d If a test binary runs longer than duration d, panic. If d is 0, the timeout is disabled. The default is 10 minutes (10m). -v Verbose output: log all tests as they are run. Also print all text from Log and Logf calls even if the test succeeds. -vet list Configure the invocation of "go vet" during "go test" to use the comma-separated list of vet checks. If list is empty, "go test" runs "go vet" with a curated list of checks believed to be always worth addressing. If list is "off", "go test" does not run "go vet" at all.
The following flags are also recognized by 'go test' and can be used to profile the tests during execution:
-benchmem Print memory allocation statistics for benchmarks. Allocations made in C or using C.malloc are not counted. -blockprofile block.out Write a goroutine blocking profile to the specified file when all tests are complete. Writes test binary as -c would. -blockprofilerate n Control the detail provided in goroutine blocking profiles by calling runtime.SetBlockProfileRate with n. See 'go doc runtime.SetBlockProfileRate'. The profiler aims to sample, on average, one blocking event every n nanoseconds the program spends blocked. By default, if -test.blockprofile is set without this flag, all blocking events are recorded, equivalent to -test.blockprofilerate=1. -coverprofile cover.out Write a coverage profile to the file after all tests have passed. Sets -cover. -cpuprofile cpu.out Write a CPU profile to the specified file before exiting. Writes test binary as -c would. -memprofile mem.out Write an allocation profile to the file after all tests have passed. Writes test binary as -c would. -memprofilerate n Enable more precise (and expensive) memory allocation profiles by setting runtime.MemProfileRate. See 'go doc runtime.MemProfileRate'. To profile all memory allocations, use -test.memprofilerate=1. -mutexprofile mutex.out Write a mutex contention profile to the specified file when all tests are complete. Writes test binary as -c would. -mutexprofilefraction n Sample 1 in n stack traces of goroutines holding a contended mutex. -outputdir directory Place output files from profiling in the specified directory, by default the directory in which "go test" is running. -trace trace.out Write an execution trace to the specified file before exiting.
Each of these flags is also recognized with an optional 'test.' prefix, as in -test.v. When invoking the generated test binary (the result of 'go test -c') directly, however, the prefix is mandatory.
The 'go test' command rewrites or removes recognized flags, as appropriate, both before and after the optional package list, before invoking the test binary.
For instance, the command
go test -v -myflag testdata -cpuprofile=prof.out -x
will compile the test binary and then run it as
pkg.test -test.v -myflag testdata -test.cpuprofile=prof.out
(The -x flag is removed because it applies only to the go command's execution, not to the test itself.)
The test flags that generate profiles (other than for coverage) also leave the test binary in pkg.test for use when analyzing the profiles.
When 'go test' runs a test binary, it does so from within the corresponding package's source code directory. Depending on the test, it may be necessary to do the same when invoking a generated test binary directly. Because that directory may be located within the module cache, which may be read-only and is verified by checksums, the test must not write to it or any other directory within the module unless explicitly requested by the user (such as with the -fuzz flag, which writes failures to testdata/fuzz).
The command-line package list, if present, must appear before any flag not known to the go test command. Continuing the example above, the package list would have to appear before -myflag, but could appear on either side of -v.
When 'go test' runs in package list mode, 'go test' caches successful package test results to avoid unnecessary repeated running of tests. To disable test caching, use any test flag or argument other than the cacheable flags. The idiomatic way to disable test caching explicitly is to use -count=1.
To keep an argument for a test binary from being interpreted as a known flag or a package name, use -args (see 'go help test') which passes the remainder of the command line through to the test binary uninterpreted and unaltered.
For instance, the command
go test -v -args -x -v
will compile the test binary and then run it as
pkg.test -test.v -x -v
Similarly,
go test -args math
will compile the test binary and then run it as
pkg.test math
In the first example, the -x and the second -v are passed through to the test binary unchanged and with no effect on the go command itself. In the second example, the argument math is passed through to the test binary, instead of being interpreted as the package list.
The 'go test' command expects to find test, benchmark, and example functions in the "*_test.go" files corresponding to the package under test.
A test function is one named TestXxx (where Xxx does not start with a lower case letter) and should have the signature,
func TestXxx(t *testing.T) { ... }
A benchmark function is one named BenchmarkXxx and should have the signature,
func BenchmarkXxx(b *testing.B) { ... }
A fuzz test is one named FuzzXxx and should have the signature,
func FuzzXxx(f *testing.F) { ... }
An example function is similar to a test function but, instead of using *testing.T to report success or failure, prints output to os.Stdout. If the last comment in the function starts with "Output:" then the output is compared exactly against the comment (see examples below). If the last comment begins with "Unordered output:" then the output is compared to the comment, however the order of the lines is ignored. An example with no such comment is compiled but not executed. An example with no text after "Output:" is compiled, executed, and expected to produce no output.
Godoc displays the body of ExampleXxx to demonstrate the use of the function, constant, or variable Xxx. An example of a method M with receiver type T or *T is named ExampleT_M. There may be multiple examples for a given function, constant, or variable, distinguished by a trailing _xxx, where xxx is a suffix not beginning with an upper case letter.
Here is an example of an example:
func ExamplePrintln() { Println("The output of\nthis example.") // Output: The output of // this example. }
Here is another example where the ordering of the output is ignored:
func ExamplePerm() { for _, value := range Perm(4) { fmt.Println(value) } // Unordered output: 4 // 2 // 1 // 3 // 0 }
The entire test file is presented as the example when it contains a single example function, at least one other function, type, variable, or constant declaration, and no tests, benchmarks, or fuzz tests.
See the documentation of the testing package for more information.
The 'go get' command can run version control commands like git to download imported code. This functionality is critical to the decentralized Go package ecosystem, in which code can be imported from any server, but it is also a potential security problem, if a malicious server finds a way to cause the invoked version control command to run unintended code.
To balance the functionality and security concerns, the 'go get' command by default will only use git and hg to download code from public servers. But it will use any known version control system (bzr, fossil, git, hg, svn) to download code from private servers, defined as those hosting packages matching the GOPRIVATE variable (see 'go help private'). The rationale behind allowing only Git and Mercurial is that these two systems have had the most attention to issues of being run as clients of untrusted servers. In contrast, Bazaar, Fossil, and Subversion have primarily been used in trusted, authenticated environments and are not as well scrutinized as attack surfaces.
The version control command restrictions only apply when using direct version control access to download code. When downloading modules from a proxy, 'go get' uses the proxy protocol instead, which is always permitted. By default, the 'go get' command uses the Go module mirror (proxy.golang.org) for public packages and only falls back to version control for private packages or when the mirror refuses to serve a public package (typically for legal reasons). Therefore, clients can still access public code served from Bazaar, Fossil, or Subversion repositories by default, because those downloads use the Go module mirror, which takes on the security risk of running the version control commands using a custom sandbox.
The GOVCS variable can be used to change the allowed version control systems for specific packages (identified by a module or import path). The GOVCS variable applies when building package in both module-aware mode and GOPATH mode. When using modules, the patterns match against the module path. When using GOPATH, the patterns match against the import path corresponding to the root of the version control repository.
The general form of the GOVCS setting is a comma-separated list of pattern:vcslist rules. The pattern is a glob pattern that must match one or more leading elements of the module or import path. The vcslist is a pipe-separated list of allowed version control commands, or "all" to allow use of any known command, or "off" to disallow all commands. Note that if a module matches a pattern with vcslist "off", it may still be downloaded if the origin server uses the "mod" scheme, which instructs the go command to download the module using the GOPROXY protocol. The earliest matching pattern in the list applies, even if later patterns might also match.
For example, consider:
GOVCS=github.com:git,evil.com:off,*:git|hg
With this setting, code with a module or import path beginning with github.com/ can only use git; paths on evil.com cannot use any version control command, and all other paths (* matches everything) can use only git or hg.
The special patterns "public" and "private" match public and private module or import paths. A path is private if it matches the GOPRIVATE variable; otherwise it is public.
If no rules in the GOVCS variable match a particular module or import path, the 'go get' command applies its default rule, which can now be summarized in GOVCS notation as 'public:git|hg,private:all'.
To allow unfettered use of any version control system for any package, use:
GOVCS=*:all
To disable all use of version control, use:
GOVCS=*:off
The 'go env -w' command (see 'go help env') can be used to set the GOVCS variable for future go command invocations.
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