go/packages/doc.go - tools - Git at Google

 // Copyright 2018 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 /*
 Package packages loads Go packages for inspection and analysis.

 The Load function takes as input a list of patterns and return a list of Package
 structs describing individual packages matched by those patterns.
 The LoadMode controls the amount of detail in the loaded packages.

 Load passes most patterns directly to the underlying build tool,
 but all patterns with the prefix "query=", where query is a
 non-empty string of letters from [a-z], are reserved and may be
 interpreted as query operators.

 Two query operators are currently supported: "file" and "pattern".

 The query "file=path/to/file.go" matches the package or packages enclosing
 the Go source file path/to/file.go.  For example "file=~/go/src/fmt/print.go"
 might return the packages "fmt" and "fmt [fmt.test]".

 The query "pattern=string" causes "string" to be passed directly to
 the underlying build tool. In most cases this is unnecessary,
 but an application can use Load("pattern=" + x) as an escaping mechanism
 to ensure that x is not interpreted as a query operator if it contains '='.

 All other query operators are reserved for future use and currently
 cause Load to report an error.

 The Package struct provides basic information about the package, including

   - ID, a unique identifier for the package in the returned set;
   - GoFiles, the names of the package's Go source files;
   - Imports, a map from source import strings to the Packages they name;
   - Types, the type information for the package's exported symbols;
   - Syntax, the parsed syntax trees for the package's source code; and
   - TypeInfo, the result of a complete type-check of the package syntax trees.

 (See the documentation for type Package for the complete list of fields
 and more detailed descriptions.)

 For example,

 	Load(nil, "bytes", "unicode...")

 returns four Package structs describing the standard library packages
 bytes, unicode, unicode/utf16, and unicode/utf8. Note that one pattern
 can match multiple packages and that a package might be matched by
 multiple patterns: in general it is not possible to determine which
 packages correspond to which patterns.

 Note that the list returned by Load contains only the packages matched
 by the patterns. Their dependencies can be found by walking the import
 graph using the Imports fields.

 The Load function can be configured by passing a pointer to a Config as
 the first argument. A nil Config is equivalent to the zero Config, which
 causes Load to run in LoadFiles mode, collecting minimal information.
 See the documentation for type Config for details.

 As noted earlier, the Config.Mode controls the amount of detail
 reported about the loaded packages. See the documentation for type LoadMode
 for details.

 Most tools should pass their command-line arguments (after any flags)
 uninterpreted to the loader, so that the loader can interpret them
 according to the conventions of the underlying build system.
 See the Example function for typical usage.

 */
 package packages // import "golang.org/x/tools/go/packages"

 /*

 Motivation and design considerations

 The new package's design solves problems addressed by two existing
 packages: go/build, which locates and describes packages, and
 golang.org/x/tools/go/loader, which loads, parses and type-checks them.
 The go/build.Package structure encodes too much of the 'go build' way
 of organizing projects, leaving us in need of a data type that describes a
 package of Go source code independent of the underlying build system.
 We wanted something that works equally well with go build and vgo, and
 also other build systems such as Bazel and Blaze, making it possible to
 construct analysis tools that work in all these environments.
 Tools such as errcheck and staticcheck were essentially unavailable to
 the Go community at Google, and some of Google's internal tools for Go
 are unavailable externally.
 This new package provides a uniform way to obtain package metadata by
 querying each of these build systems, optionally supporting their
 preferred command-line notations for packages, so that tools integrate
 neatly with users' build environments. The Metadata query function
 executes an external query tool appropriate to the current workspace.

 Loading packages always returns the complete import graph "all the way down",
 even if all you want is information about a single package, because the query
 mechanisms of all the build systems we currently support ({go,vgo} list, and
 blaze/bazel aspect-based query) cannot provide detailed information
 about one package without visiting all its dependencies too, so there is
 no additional asymptotic cost to providing transitive information.
 (This property might not be true of a hypothetical 5th build system.)

 In calls to TypeCheck, all initial packages, and any package that
 transitively depends on one of them, must be loaded from source.
 Consider A->B->C->D->E: if A,C are initial, A,B,C must be loaded from
 source; D may be loaded from export data, and E may not be loaded at all
 (though it's possible that D's export data mentions it, so a
 types.Package may be created for it and exposed.)

 The old loader had a feature to suppress type-checking of function
 bodies on a per-package basis, primarily intended to reduce the work of
 obtaining type information for imported packages. Now that imports are
 satisfied by export data, the optimization no longer seems necessary.

 Despite some early attempts, the old loader did not exploit export data,
 instead always using the equivalent of WholeProgram mode. This was due
 to the complexity of mixing source and export data packages (now
 resolved by the upward traversal mentioned above), and because export data
 files were nearly always missing or stale. Now that 'go build' supports
 caching, all the underlying build systems can guarantee to produce
 export data in a reasonable (amortized) time.

 Test "main" packages synthesized by the build system are now reported as
 first-class packages, avoiding the need for clients (such as go/ssa) to
 reinvent this generation logic.

 One way in which go/packages is simpler than the old loader is in its
 treatment of in-package tests. In-package tests are packages that
 consist of all the files of the library under test, plus the test files.
 The old loader constructed in-package tests by a two-phase process of
 mutation called "augmentation": first it would construct and type check
 all the ordinary library packages and type-check the packages that
 depend on them; then it would add more (test) files to the package and
 type-check again. This two-phase approach had four major problems:
 1) in processing the tests, the loader modified the library package,
    leaving no way for a client application to see both the test
    package and the library package; one would mutate into the other.
 2) because test files can declare additional methods on types defined in
    the library portion of the package, the dispatch of method calls in
    the library portion was affected by the presence of the test files.
    This should have been a clue that the packages were logically
    different.
 3) this model of "augmentation" assumed at most one in-package test
    per library package, which is true of projects using 'go build',
    but not other build systems.
 4) because of the two-phase nature of test processing, all packages that
    import the library package had to be processed before augmentation,
    forcing a "one-shot" API and preventing the client from calling Load
    in several times in sequence as is now possible in WholeProgram mode.
    (TypeCheck mode has a similar one-shot restriction for a different reason.)

 Early drafts of this package supported "multi-shot" operation.
 Although it allowed clients to make a sequence of calls (or concurrent
 calls) to Load, building up the graph of Packages incrementally,
 it was of marginal value: it complicated the API
 (since it allowed some options to vary across calls but not others),
 it complicated the implementation,
 it cannot be made to work in Types mode, as explained above,
 and it was less efficient than making one combined call (when this is possible).
 Among the clients we have inspected, none made multiple calls to load
 but could not be easily and satisfactorily modified to make only a single call.
 However, applications changes may be required.
 For example, the ssadump command loads the user-specified packages
 and in addition the runtime package.  It is tempting to simply append
 "runtime" to the user-provided list, but that does not work if the user
 specified an ad-hoc package such as [a.go b.go].
 Instead, ssadump no longer requests the runtime package,
 but seeks it among the dependencies of the user-specified packages,
 and emits an error if it is not found.

 Overlays: The Overlay field in the Config allows providing alternate contents
 for Go source files, by providing a mapping from file path to contents.
 go/packages will pull in new imports added in overlay files when go/packages
 is run in LoadImports mode or greater.
 Overlay support for the go list driver isn't complete yet: if the file doesn't
 exist on disk, it will only be recognized in an overlay if it is a non-test file
 and the package would be reported even without the overlay.

 Questions & Tasks

 - Add GOARCH/GOOS?
   They are not portable concepts, but could be made portable.
   Our goal has been to allow users to express themselves using the conventions
   of the underlying build system: if the build system honors GOARCH
   during a build and during a metadata query, then so should
   applications built atop that query mechanism.
   Conversely, if the target architecture of the build is determined by
   command-line flags, the application can pass the relevant
   flags through to the build system using a command such as:
     myapp -query_flag="--cpu=amd64" -query_flag="--os=darwin"
   However, this approach is low-level, unwieldy, and non-portable.
   GOOS and GOARCH seem important enough to warrant a dedicated option.

 - How should we handle partial failures such as a mixture of good and
   malformed patterns, existing and non-existent packages, successful and
   failed builds, import failures, import cycles, and so on, in a call to
   Load?

 - Support bazel, blaze, and go1.10 list, not just go1.11 list.

 - Handle (and test) various partial success cases, e.g.
   a mixture of good packages and:
   invalid patterns
   nonexistent packages
   empty packages
   packages with malformed package or import declarations
   unreadable files
   import cycles
   other parse errors
   type errors
   Make sure we record errors at the correct place in the graph.

 - Missing packages among initial arguments are not reported.
   Return bogus packages for them, like golist does.

 - "undeclared name" errors (for example) are reported out of source file
   order. I suspect this is due to the breadth-first resolution now used
   by go/types. Is that a bug? Discuss with gri.

 */
	// Copyright 2018 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	/*
	Package packages loads Go packages for inspection and analysis.

	The Load function takes as input a list of patterns and return a list of Package
	structs describing individual packages matched by those patterns.
	The LoadMode controls the amount of detail in the loaded packages.

	Load passes most patterns directly to the underlying build tool,
	but all patterns with the prefix "query=", where query is a
	non-empty string of letters from [a-z], are reserved and may be
	interpreted as query operators.

	Two query operators are currently supported: "file" and "pattern".

	The query "file=path/to/file.go" matches the package or packages enclosing
	the Go source file path/to/file.go. For example "file=~/go/src/fmt/print.go"
	might return the packages "fmt" and "fmt [fmt.test]".

	The query "pattern=string" causes "string" to be passed directly to
	the underlying build tool. In most cases this is unnecessary,
	but an application can use Load("pattern=" + x) as an escaping mechanism
	to ensure that x is not interpreted as a query operator if it contains '='.

	All other query operators are reserved for future use and currently
	cause Load to report an error.

	The Package struct provides basic information about the package, including

	- ID, a unique identifier for the package in the returned set;
	- GoFiles, the names of the package's Go source files;
	- Imports, a map from source import strings to the Packages they name;
	- Types, the type information for the package's exported symbols;
	- Syntax, the parsed syntax trees for the package's source code; and
	- TypeInfo, the result of a complete type-check of the package syntax trees.

	(See the documentation for type Package for the complete list of fields
	and more detailed descriptions.)

	For example,

	Load(nil, "bytes", "unicode...")

	returns four Package structs describing the standard library packages
	bytes, unicode, unicode/utf16, and unicode/utf8. Note that one pattern
	can match multiple packages and that a package might be matched by
	multiple patterns: in general it is not possible to determine which
	packages correspond to which patterns.

	Note that the list returned by Load contains only the packages matched
	by the patterns. Their dependencies can be found by walking the import
	graph using the Imports fields.

	The Load function can be configured by passing a pointer to a Config as
	the first argument. A nil Config is equivalent to the zero Config, which
	causes Load to run in LoadFiles mode, collecting minimal information.
	See the documentation for type Config for details.

	As noted earlier, the Config.Mode controls the amount of detail
	reported about the loaded packages. See the documentation for type LoadMode
	for details.

	Most tools should pass their command-line arguments (after any flags)
	uninterpreted to the loader, so that the loader can interpret them
	according to the conventions of the underlying build system.
	See the Example function for typical usage.

	*/
	package packages // import "golang.org/x/tools/go/packages"

	/*

	Motivation and design considerations

	The new package's design solves problems addressed by two existing
	packages: go/build, which locates and describes packages, and
	golang.org/x/tools/go/loader, which loads, parses and type-checks them.
	The go/build.Package structure encodes too much of the 'go build' way
	of organizing projects, leaving us in need of a data type that describes a
	package of Go source code independent of the underlying build system.
	We wanted something that works equally well with go build and vgo, and
	also other build systems such as Bazel and Blaze, making it possible to
	construct analysis tools that work in all these environments.
	Tools such as errcheck and staticcheck were essentially unavailable to
	the Go community at Google, and some of Google's internal tools for Go
	are unavailable externally.
	This new package provides a uniform way to obtain package metadata by
	querying each of these build systems, optionally supporting their
	preferred command-line notations for packages, so that tools integrate
	neatly with users' build environments. The Metadata query function
	executes an external query tool appropriate to the current workspace.

	Loading packages always returns the complete import graph "all the way down",
	even if all you want is information about a single package, because the query
	mechanisms of all the build systems we currently support ({go,vgo} list, and
	blaze/bazel aspect-based query) cannot provide detailed information
	about one package without visiting all its dependencies too, so there is
	no additional asymptotic cost to providing transitive information.
	(This property might not be true of a hypothetical 5th build system.)

	In calls to TypeCheck, all initial packages, and any package that
	transitively depends on one of them, must be loaded from source.
	Consider A->B->C->D->E: if A,C are initial, A,B,C must be loaded from
	source; D may be loaded from export data, and E may not be loaded at all
	(though it's possible that D's export data mentions it, so a
	types.Package may be created for it and exposed.)

	The old loader had a feature to suppress type-checking of function
	bodies on a per-package basis, primarily intended to reduce the work of
	obtaining type information for imported packages. Now that imports are
	satisfied by export data, the optimization no longer seems necessary.

	Despite some early attempts, the old loader did not exploit export data,
	instead always using the equivalent of WholeProgram mode. This was due
	to the complexity of mixing source and export data packages (now
	resolved by the upward traversal mentioned above), and because export data
	files were nearly always missing or stale. Now that 'go build' supports
	caching, all the underlying build systems can guarantee to produce
	export data in a reasonable (amortized) time.

	Test "main" packages synthesized by the build system are now reported as
	first-class packages, avoiding the need for clients (such as go/ssa) to
	reinvent this generation logic.

	One way in which go/packages is simpler than the old loader is in its
	treatment of in-package tests. In-package tests are packages that
	consist of all the files of the library under test, plus the test files.
	The old loader constructed in-package tests by a two-phase process of
	mutation called "augmentation": first it would construct and type check
	all the ordinary library packages and type-check the packages that
	depend on them; then it would add more (test) files to the package and
	type-check again. This two-phase approach had four major problems:
	1) in processing the tests, the loader modified the library package,
	leaving no way for a client application to see both the test
	package and the library package; one would mutate into the other.
	2) because test files can declare additional methods on types defined in
	the library portion of the package, the dispatch of method calls in
	the library portion was affected by the presence of the test files.
	This should have been a clue that the packages were logically
	different.
	3) this model of "augmentation" assumed at most one in-package test
	per library package, which is true of projects using 'go build',
	but not other build systems.
	4) because of the two-phase nature of test processing, all packages that
	import the library package had to be processed before augmentation,
	forcing a "one-shot" API and preventing the client from calling Load
	in several times in sequence as is now possible in WholeProgram mode.
	(TypeCheck mode has a similar one-shot restriction for a different reason.)

	Early drafts of this package supported "multi-shot" operation.
	Although it allowed clients to make a sequence of calls (or concurrent
	calls) to Load, building up the graph of Packages incrementally,
	it was of marginal value: it complicated the API
	(since it allowed some options to vary across calls but not others),
	it complicated the implementation,
	it cannot be made to work in Types mode, as explained above,
	and it was less efficient than making one combined call (when this is possible).
	Among the clients we have inspected, none made multiple calls to load
	but could not be easily and satisfactorily modified to make only a single call.
	However, applications changes may be required.
	For example, the ssadump command loads the user-specified packages
	and in addition the runtime package. It is tempting to simply append
	"runtime" to the user-provided list, but that does not work if the user
	specified an ad-hoc package such as [a.go b.go].
	Instead, ssadump no longer requests the runtime package,
	but seeks it among the dependencies of the user-specified packages,
	and emits an error if it is not found.

	Overlays: The Overlay field in the Config allows providing alternate contents
	for Go source files, by providing a mapping from file path to contents.
	go/packages will pull in new imports added in overlay files when go/packages
	is run in LoadImports mode or greater.
	Overlay support for the go list driver isn't complete yet: if the file doesn't
	exist on disk, it will only be recognized in an overlay if it is a non-test file
	and the package would be reported even without the overlay.

	Questions & Tasks

	- Add GOARCH/GOOS?
	They are not portable concepts, but could be made portable.
	Our goal has been to allow users to express themselves using the conventions
	of the underlying build system: if the build system honors GOARCH
	during a build and during a metadata query, then so should
	applications built atop that query mechanism.
	Conversely, if the target architecture of the build is determined by
	command-line flags, the application can pass the relevant
	flags through to the build system using a command such as:
	myapp -query_flag="--cpu=amd64" -query_flag="--os=darwin"
	However, this approach is low-level, unwieldy, and non-portable.
	GOOS and GOARCH seem important enough to warrant a dedicated option.

	- How should we handle partial failures such as a mixture of good and
	malformed patterns, existing and non-existent packages, successful and
	failed builds, import failures, import cycles, and so on, in a call to
	Load?

	- Support bazel, blaze, and go1.10 list, not just go1.11 list.

	- Handle (and test) various partial success cases, e.g.
	a mixture of good packages and:
	invalid patterns
	nonexistent packages
	empty packages
	packages with malformed package or import declarations
	unreadable files
	import cycles
	other parse errors
	type errors
	Make sure we record errors at the correct place in the graph.

	- Missing packages among initial arguments are not reported.
	Return bogus packages for them, like golist does.

	- "undeclared name" errors (for example) are reported out of source file
	order. I suspect this is due to the breadth-first resolution now used
	by go/types. Is that a bug? Discuss with gri.

	*/