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

 /*

 The analysis package defines the interface between a modular static
 analysis and an analysis driver program.

 Background

 A static analysis is a function that inspects a package of Go code and
 reports a set of diagnostics (typically mistakes in the code), and
 perhaps produces other results as well, such as suggested refactorings
 or other facts. An analysis that reports mistakes is informally called a
 "checker". For example, the printf checker reports mistakes in
 fmt.Printf format strings.

 A "modular" analysis is one that inspects one package at a time but can
 save information from a lower-level package and use it when inspecting a
 higher-level package, analogous to separate compilation in a toolchain.
 The printf checker is modular: when it discovers that a function such as
 log.Fatalf delegates to fmt.Printf, it records this fact, and checks
 calls to that function too, including calls made from another package.

 By implementing a common interface, checkers from a variety of sources
 can be easily selected, incorporated, and reused in a wide range of
 driver programs including command-line tools (such as vet), text editors and
 IDEs, build and test systems (such as go build, Bazel, or Buck), test
 frameworks, code review tools, code-base indexers (such as SourceGraph),
 documentation viewers (such as godoc), batch pipelines for large code
 bases, and so on.


 Analyzer

 The primary type in the API is Analyzer. An Analyzer statically
 describes an analysis function: its name, documentation, flags,
 relationship to other analyzers, and of course, its logic.

 To define an analysis, a user declares a (logically constant) variable
 of type Analyzer. Here is a typical example from one of the analyzers in
 the go/analysis/passes/ subdirectory:

 	package unusedresult

 	var Analyzer = &analysis.Analyzer{
 		Name:	"unusedresult",
 		Doc:	"check for unused results of calls to some functions",
 		Run:    run,
 		...
 	}

 	func run(pass *analysis.Pass) (interface{}, error) {
 		...
 	}


 An analysis driver is a program such as vet that runs a set of
 analyses and prints the diagnostics that they report.
 The driver program must import the list of Analyzers it needs.
 Typically each Analyzer resides in a separate package.
 To add a new Analyzer to an existing driver, add another item to the list:

 	import ( "unusedresult"; "nilness"; "printf" )

 	var analyses = []*analysis.Analyzer{
 		unusedresult.Analyzer,
 		nilness.Analyzer,
 		printf.Analyzer,
 	}

 A driver may use the name, flags, and documentation to provide on-line
 help that describes the analyses its performs.
 The doc comment contains a brief one-line summary,
 optionally followed by paragraphs of explanation.
 The vet command, shown below, is an example of a driver that runs
 multiple analyzers. It is based on the multichecker package
 (see the "Standalone commands" section for details).

 	$ go build golang.org/x/tools/go/analysis/cmd/vet
 	$ ./vet help
 	vet is a tool for static analysis of Go programs.

 	Usage: vet [-flag] [package]

 	Registered analyzers:

 	    asmdecl      report mismatches between assembly files and Go declarations
 	    assign       check for useless assignments
 	    atomic       check for common mistakes using the sync/atomic package
 	    ...
 	    unusedresult check for unused results of calls to some functions

 	$ ./vet help unusedresult
 	unusedresult: check for unused results of calls to some functions

 	Analyzer flags:

 	  -unusedresult.funcs value
 	        comma-separated list of functions whose results must be used (default Error,String)
 	  -unusedresult.stringmethods value
 	        comma-separated list of names of methods of type func() string whose results must be used

 	Some functions like fmt.Errorf return a result and have no side effects,
 	so it is always a mistake to discard the result. This analyzer reports
 	calls to certain functions in which the result of the call is ignored.

 	The set of functions may be controlled using flags.

 The Analyzer type has more fields besides those shown above:

 	type Analyzer struct {
 		Name			string
 		Doc			string
 		Flags			flag.FlagSet
 		Run			func(*Pass) (interface{}, error)
 		RunDespiteErrors	bool
 		ResultType		reflect.Type
 		Requires		[]*Analyzer
 		FactTypes		[]Fact
 	}

 The Flags field declares a set of named (global) flag variables that
 control analysis behavior. Unlike vet, analysis flags are not declared
 directly in the command line FlagSet; it is up to the driver to set the
 flag variables. A driver for a single analysis, a, might expose its flag
 f directly on the command line as -f, whereas a driver for multiple
 analyses might prefix the flag name by the analysis name (-a.f) to avoid
 ambiguity. An IDE might expose the flags through a graphical interface,
 and a batch pipeline might configure them from a config file.
 See the "findcall" analyzer for an example of flags in action.

 The RunDespiteErrors flag indicates whether the analysis is equipped to
 handle ill-typed code. If not, the driver will skip the analysis if
 there were parse or type errors.
 The optional ResultType field specifies the type of the result value
 computed by this analysis and made available to other analyses.
 The Requires field specifies a list of analyses upon which
 this one depends and whose results it may access, and it constrains the
 order in which a driver may run analyses.
 The FactTypes field is discussed in the section on Modularity.
 The analysis package provides a Validate function to perform basic
 sanity checks on an Analyzer, such as that its Requires graph is
 acyclic, its fact and result types are unique, and so on.

 Finally, the Run field contains a function to be called by the driver to
 execute the analysis on a single package. The driver passes it an
 instance of the Pass type.


 Pass

 A Pass describes a single unit of work: the application of a particular
 Analyzer to a particular package of Go code.
 The Pass provides information to the Analyzer's Run function about the
 package being analyzed, and provides operations to the Run function for
 reporting diagnostics and other information back to the driver.

 	type Pass struct {
 		Fset   		*token.FileSet
 		Files		[]*ast.File
 		OtherFiles	[]string
 		Pkg		*types.Package
 		TypesInfo	*types.Info
 		ResultOf	map[*Analyzer]interface{}
 		Report		func(Diagnostic)
 		...
 	}

 The Fset, Files, Pkg, and TypesInfo fields provide the syntax trees,
 type information, and source positions for a single package of Go code.

 The OtherFiles field provides the names, but not the contents, of non-Go
 files such as assembly that are part of this package. See the "asmdecl"
 or "buildtags" analyzers for examples of loading non-Go files and report
 diagnostics against them.

 The ResultOf field provides the results computed by the analyzers
 required by this one, as expressed in its Analyzer.Requires field. The
 driver runs the required analyzers first and makes their results
 available in this map. Each Analyzer must return a value of the type
 described in its Analyzer.ResultType field.
 For example, the "ctrlflow" analyzer returns a *ctrlflow.CFGs, which
 provides a control-flow graph for each function in the package (see
 golang.org/x/tools/go/cfg); the "inspect" analyzer returns a value that
 enables other Analyzers to traverse the syntax trees of the package more
 efficiently; and the "buildssa" analyzer constructs an SSA-form
 intermediate representation.
 Each of these Analyzers extends the capabilities of later Analyzers
 without adding a dependency to the core API, so an analysis tool pays
 only for the extensions it needs.

 The Report function emits a diagnostic, a message associated with a
 source position. For most analyses, diagnostics are their primary
 result.
 For convenience, Pass provides a helper method, Reportf, to report a new
 diagnostic by formatting a string.
 Diagnostic is defined as:

 	type Diagnostic struct {
 		Pos      token.Pos
 		Category string // optional
 		Message  string
 	}

 The optional Category field is a short identifier that classifies the
 kind of message when an analysis produces several kinds of diagnostic.

 Most Analyzers inspect typed Go syntax trees, but a few, such as asmdecl
 and buildtag, inspect the raw text of Go source files or even non-Go
 files such as assembly. To report a diagnostic against a line of a
 raw text file, use the following sequence:

 	content, err := ioutil.ReadFile(filename)
 	if err != nil { ... }
 	tf := fset.AddFile(filename, -1, len(content))
 	tf.SetLinesForContent(content)
 	...
 	pass.Reportf(tf.LineStart(line), "oops")


 Modular analysis with Facts

 To improve efficiency and scalability, large programs are routinely
 built using separate compilation: units of the program are compiled
 separately, and recompiled only when one of their dependencies changes;
 independent modules may be compiled in parallel. The same technique may
 be applied to static analyses, for the same benefits. Such analyses are
 described as "modular".

 A compiler’s type checker is an example of a modular static analysis.
 Many other checkers we would like to apply to Go programs can be
 understood as alternative or non-standard type systems. For example,
 vet's printf checker infers whether a function has the "printf wrapper"
 type, and it applies stricter checks to calls of such functions. In
 addition, it records which functions are printf wrappers for use by
 later analysis units to identify other printf wrappers by induction.
 A result such as “f is a printf wrapper” that is not interesting by
 itself but serves as a stepping stone to an interesting result (such as
 a diagnostic) is called a "fact".

 The analysis API allows an analysis to define new types of facts, to
 associate facts of these types with objects (named entities) declared
 within the current package, or with the package as a whole, and to query
 for an existing fact of a given type associated with an object or
 package.

 An Analyzer that uses facts must declare their types:

 	var Analyzer = &analysis.Analyzer{
 		Name:       "printf",
 		FactTypes: []analysis.Fact{new(isWrapper)},
 		...
 	}

 	type isWrapper struct{} // => *types.Func f “is a printf wrapper”

 A driver program ensures that facts for a pass’s dependencies are
 generated before analyzing the pass and are responsible for propagating
 facts between from one pass to another, possibly across address spaces.
 Consequently, Facts must be serializable. The API requires that drivers
 use the gob encoding, an efficient, robust, self-describing binary
 protocol. A fact type may implement the GobEncoder/GobDecoder interfaces
 if the default encoding is unsuitable. Facts should be stateless.

 The Pass type has functions to import and export facts,
 associated either with an object or with a package:

 	type Pass struct {
 		...
 		ExportObjectFact func(types.Object, Fact)
 		ImportObjectFact func(types.Object, Fact) bool

 		ExportPackageFact func(fact Fact)
 		ImportPackageFact func(*types.Package, Fact) bool
 	}

 An Analyzer may only export facts associated with the current package or
 its objects, though it may import facts from any package or object that
 is an import dependency of the current package.

 Conceptually, ExportObjectFact(obj, fact) inserts fact into a hidden map keyed by
 the pair (obj, TypeOf(fact)), and the ImportObjectFact function
 retrieves the entry from this map and copies its value into the variable
 pointed to by fact. This scheme assumes that the concrete type of fact
 is a pointer; this assumption is checked by the Validate function.
 See the "printf" analyzer for an example of object facts in action.

 Some driver implementations (such as those based on Bazel and Blaze) do
 not currently apply analyzers to packages of the standard library.
 Therefore, for best results, analyzer authors should not rely on
 analysis facts being available for standard packages.
 For example, although the printf checker is capable of deducing during
 analysis of the log package that log.Printf is a printf-wrapper,
 this fact is built in to the analyzer so that it correctly checks
 calls to log.Printf even when run in a driver that does not apply
 it to standard packages. We plan to remove this limitation in future.


 Testing an Analyzer

 The analysistest subpackage provides utilities for testing an Analyzer.
 In a few lines of code, it is possible to run an analyzer on a package
 of testdata files and check that it reported all the expected
 diagnostics and facts (and no more). Expectations are expressed using
 "// want ..." comments in the input code.


 Standalone commands

 Analyzers are provided in the form of packages that a driver program is
 expected to import. The vet command imports a set of several analyzers,
 but users may wish to define their own analysis commands that perform
 additional checks. To simplify the task of creating an analysis command,
 either for a single analyzer or for a whole suite, we provide the
 singlechecker and multichecker subpackages.

 The singlechecker package provides the main function for a command that
 runs one analyzer. By convention, each analyzer such as
 go/passes/findcall should be accompanied by a singlechecker-based
 command such as go/analysis/passes/findcall/cmd/findcall, defined in its
 entirety as:

 	package main

 	import (
 		"golang.org/x/tools/go/analysis/passes/findcall"
 		"golang.org/x/tools/go/analysis/singlechecker"
 	)

 	func main() { singlechecker.Main(findcall.Analyzer) }

 A tool that provides multiple analyzers can use multichecker in a
 similar way, giving it the list of Analyzers.


 */
 package analysis
	/*

	The analysis package defines the interface between a modular static
	analysis and an analysis driver program.

	Background

	A static analysis is a function that inspects a package of Go code and
	reports a set of diagnostics (typically mistakes in the code), and
	perhaps produces other results as well, such as suggested refactorings
	or other facts. An analysis that reports mistakes is informally called a
	"checker". For example, the printf checker reports mistakes in
	fmt.Printf format strings.

	A "modular" analysis is one that inspects one package at a time but can
	save information from a lower-level package and use it when inspecting a
	higher-level package, analogous to separate compilation in a toolchain.
	The printf checker is modular: when it discovers that a function such as
	log.Fatalf delegates to fmt.Printf, it records this fact, and checks
	calls to that function too, including calls made from another package.

	By implementing a common interface, checkers from a variety of sources
	can be easily selected, incorporated, and reused in a wide range of
	driver programs including command-line tools (such as vet), text editors and
	IDEs, build and test systems (such as go build, Bazel, or Buck), test
	frameworks, code review tools, code-base indexers (such as SourceGraph),
	documentation viewers (such as godoc), batch pipelines for large code
	bases, and so on.


	Analyzer

	The primary type in the API is Analyzer. An Analyzer statically
	describes an analysis function: its name, documentation, flags,
	relationship to other analyzers, and of course, its logic.

	To define an analysis, a user declares a (logically constant) variable
	of type Analyzer. Here is a typical example from one of the analyzers in
	the go/analysis/passes/ subdirectory:

	package unusedresult

	var Analyzer = &analysis.Analyzer{
	Name: "unusedresult",
	Doc: "check for unused results of calls to some functions",
	Run: run,
	...
	}

	func run(pass *analysis.Pass) (interface{}, error) {
	...
	}


	An analysis driver is a program such as vet that runs a set of
	analyses and prints the diagnostics that they report.
	The driver program must import the list of Analyzers it needs.
	Typically each Analyzer resides in a separate package.
	To add a new Analyzer to an existing driver, add another item to the list:

	import ( "unusedresult"; "nilness"; "printf" )

	var analyses = []*analysis.Analyzer{
	unusedresult.Analyzer,
	nilness.Analyzer,
	printf.Analyzer,
	}

	A driver may use the name, flags, and documentation to provide on-line
	help that describes the analyses its performs.
	The doc comment contains a brief one-line summary,
	optionally followed by paragraphs of explanation.
	The vet command, shown below, is an example of a driver that runs
	multiple analyzers. It is based on the multichecker package
	(see the "Standalone commands" section for details).

	$ go build golang.org/x/tools/go/analysis/cmd/vet
	$ ./vet help
	vet is a tool for static analysis of Go programs.

	Usage: vet [-flag] [package]

	Registered analyzers:

	asmdecl report mismatches between assembly files and Go declarations
	assign check for useless assignments
	atomic check for common mistakes using the sync/atomic package
	...
	unusedresult check for unused results of calls to some functions

	$ ./vet help unusedresult
	unusedresult: check for unused results of calls to some functions

	Analyzer flags:

	-unusedresult.funcs value
	comma-separated list of functions whose results must be used (default Error,String)
	-unusedresult.stringmethods value
	comma-separated list of names of methods of type func() string whose results must be used

	Some functions like fmt.Errorf return a result and have no side effects,
	so it is always a mistake to discard the result. This analyzer reports
	calls to certain functions in which the result of the call is ignored.

	The set of functions may be controlled using flags.

	The Analyzer type has more fields besides those shown above:

	type Analyzer struct {
	Name string
	Doc string
	Flags flag.FlagSet
	Run func(*Pass) (interface{}, error)
	RunDespiteErrors bool
	ResultType reflect.Type
	Requires []*Analyzer
	FactTypes []Fact
	}

	The Flags field declares a set of named (global) flag variables that
	control analysis behavior. Unlike vet, analysis flags are not declared
	directly in the command line FlagSet; it is up to the driver to set the
	flag variables. A driver for a single analysis, a, might expose its flag
	f directly on the command line as -f, whereas a driver for multiple
	analyses might prefix the flag name by the analysis name (-a.f) to avoid
	ambiguity. An IDE might expose the flags through a graphical interface,
	and a batch pipeline might configure them from a config file.
	See the "findcall" analyzer for an example of flags in action.

	The RunDespiteErrors flag indicates whether the analysis is equipped to
	handle ill-typed code. If not, the driver will skip the analysis if
	there were parse or type errors.
	The optional ResultType field specifies the type of the result value
	computed by this analysis and made available to other analyses.
	The Requires field specifies a list of analyses upon which
	this one depends and whose results it may access, and it constrains the
	order in which a driver may run analyses.
	The FactTypes field is discussed in the section on Modularity.
	The analysis package provides a Validate function to perform basic
	sanity checks on an Analyzer, such as that its Requires graph is
	acyclic, its fact and result types are unique, and so on.

	Finally, the Run field contains a function to be called by the driver to
	execute the analysis on a single package. The driver passes it an
	instance of the Pass type.


	Pass

	A Pass describes a single unit of work: the application of a particular
	Analyzer to a particular package of Go code.
	The Pass provides information to the Analyzer's Run function about the
	package being analyzed, and provides operations to the Run function for
	reporting diagnostics and other information back to the driver.

	type Pass struct {
	Fset *token.FileSet
	Files []*ast.File
	OtherFiles []string
	Pkg *types.Package
	TypesInfo *types.Info
	ResultOf map[*Analyzer]interface{}
	Report func(Diagnostic)
	...
	}

	The Fset, Files, Pkg, and TypesInfo fields provide the syntax trees,
	type information, and source positions for a single package of Go code.

	The OtherFiles field provides the names, but not the contents, of non-Go
	files such as assembly that are part of this package. See the "asmdecl"
	or "buildtags" analyzers for examples of loading non-Go files and report
	diagnostics against them.

	The ResultOf field provides the results computed by the analyzers
	required by this one, as expressed in its Analyzer.Requires field. The
	driver runs the required analyzers first and makes their results
	available in this map. Each Analyzer must return a value of the type
	described in its Analyzer.ResultType field.
	For example, the "ctrlflow" analyzer returns a *ctrlflow.CFGs, which
	provides a control-flow graph for each function in the package (see
	golang.org/x/tools/go/cfg); the "inspect" analyzer returns a value that
	enables other Analyzers to traverse the syntax trees of the package more
	efficiently; and the "buildssa" analyzer constructs an SSA-form
	intermediate representation.
	Each of these Analyzers extends the capabilities of later Analyzers
	without adding a dependency to the core API, so an analysis tool pays
	only for the extensions it needs.

	The Report function emits a diagnostic, a message associated with a
	source position. For most analyses, diagnostics are their primary
	result.
	For convenience, Pass provides a helper method, Reportf, to report a new
	diagnostic by formatting a string.
	Diagnostic is defined as:

	type Diagnostic struct {
	Pos token.Pos
	Category string // optional
	Message string
	}

	The optional Category field is a short identifier that classifies the
	kind of message when an analysis produces several kinds of diagnostic.

	Most Analyzers inspect typed Go syntax trees, but a few, such as asmdecl
	and buildtag, inspect the raw text of Go source files or even non-Go
	files such as assembly. To report a diagnostic against a line of a
	raw text file, use the following sequence:

	content, err := ioutil.ReadFile(filename)
	if err != nil { ... }
	tf := fset.AddFile(filename, -1, len(content))
	tf.SetLinesForContent(content)
	...
	pass.Reportf(tf.LineStart(line), "oops")


	Modular analysis with Facts

	To improve efficiency and scalability, large programs are routinely
	built using separate compilation: units of the program are compiled
	separately, and recompiled only when one of their dependencies changes;
	independent modules may be compiled in parallel. The same technique may
	be applied to static analyses, for the same benefits. Such analyses are
	described as "modular".

	A compiler’s type checker is an example of a modular static analysis.
	Many other checkers we would like to apply to Go programs can be
	understood as alternative or non-standard type systems. For example,
	vet's printf checker infers whether a function has the "printf wrapper"
	type, and it applies stricter checks to calls of such functions. In
	addition, it records which functions are printf wrappers for use by
	later analysis units to identify other printf wrappers by induction.
	A result such as “f is a printf wrapper” that is not interesting by
	itself but serves as a stepping stone to an interesting result (such as
	a diagnostic) is called a "fact".

	The analysis API allows an analysis to define new types of facts, to
	associate facts of these types with objects (named entities) declared
	within the current package, or with the package as a whole, and to query
	for an existing fact of a given type associated with an object or
	package.

	An Analyzer that uses facts must declare their types:

	var Analyzer = &analysis.Analyzer{
	Name: "printf",
	FactTypes: []analysis.Fact{new(isWrapper)},
	...
	}

	type isWrapper struct{} // => *types.Func f “is a printf wrapper”

	A driver program ensures that facts for a pass’s dependencies are
	generated before analyzing the pass and are responsible for propagating
	facts between from one pass to another, possibly across address spaces.
	Consequently, Facts must be serializable. The API requires that drivers
	use the gob encoding, an efficient, robust, self-describing binary
	protocol. A fact type may implement the GobEncoder/GobDecoder interfaces
	if the default encoding is unsuitable. Facts should be stateless.

	The Pass type has functions to import and export facts,
	associated either with an object or with a package:

	type Pass struct {
	...
	ExportObjectFact func(types.Object, Fact)
	ImportObjectFact func(types.Object, Fact) bool

	ExportPackageFact func(fact Fact)
	ImportPackageFact func(*types.Package, Fact) bool
	}

	An Analyzer may only export facts associated with the current package or
	its objects, though it may import facts from any package or object that
	is an import dependency of the current package.

	Conceptually, ExportObjectFact(obj, fact) inserts fact into a hidden map keyed by
	the pair (obj, TypeOf(fact)), and the ImportObjectFact function
	retrieves the entry from this map and copies its value into the variable
	pointed to by fact. This scheme assumes that the concrete type of fact
	is a pointer; this assumption is checked by the Validate function.
	See the "printf" analyzer for an example of object facts in action.

	Some driver implementations (such as those based on Bazel and Blaze) do
	not currently apply analyzers to packages of the standard library.
	Therefore, for best results, analyzer authors should not rely on
	analysis facts being available for standard packages.
	For example, although the printf checker is capable of deducing during
	analysis of the log package that log.Printf is a printf-wrapper,
	this fact is built in to the analyzer so that it correctly checks
	calls to log.Printf even when run in a driver that does not apply
	it to standard packages. We plan to remove this limitation in future.


	Testing an Analyzer

	The analysistest subpackage provides utilities for testing an Analyzer.
	In a few lines of code, it is possible to run an analyzer on a package
	of testdata files and check that it reported all the expected
	diagnostics and facts (and no more). Expectations are expressed using
	"// want ..." comments in the input code.


	Standalone commands

	Analyzers are provided in the form of packages that a driver program is
	expected to import. The vet command imports a set of several analyzers,
	but users may wish to define their own analysis commands that perform
	additional checks. To simplify the task of creating an analysis command,
	either for a single analyzer or for a whole suite, we provide the
	singlechecker and multichecker subpackages.

	The singlechecker package provides the main function for a command that
	runs one analyzer. By convention, each analyzer such as
	go/passes/findcall should be accompanied by a singlechecker-based
	command such as go/analysis/passes/findcall/cmd/findcall, defined in its
	entirety as:

	package main

	import (
	"golang.org/x/tools/go/analysis/passes/findcall"
	"golang.org/x/tools/go/analysis/singlechecker"
	)

	func main() { singlechecker.Main(findcall.Analyzer) }

	A tool that provides multiple analyzers can use multichecker in a
	similar way, giving it the list of Analyzers.



	*/
	package analysis