2019-11-25 20:16:00 +00:00
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/*
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2020-02-10 16:52:43 +00:00
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Package analysis defines the interface between a modular static
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analysis and an analysis driver program.
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2019-11-27 12:22:23 +00:00
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2019-11-25 20:16:00 +00:00
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Background
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A static analysis is a function that inspects a package of Go code and
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reports a set of diagnostics (typically mistakes in the code), and
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perhaps produces other results as well, such as suggested refactorings
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or other facts. An analysis that reports mistakes is informally called a
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"checker". For example, the printf checker reports mistakes in
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fmt.Printf format strings.
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A "modular" analysis is one that inspects one package at a time but can
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save information from a lower-level package and use it when inspecting a
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higher-level package, analogous to separate compilation in a toolchain.
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The printf checker is modular: when it discovers that a function such as
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log.Fatalf delegates to fmt.Printf, it records this fact, and checks
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calls to that function too, including calls made from another package.
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By implementing a common interface, checkers from a variety of sources
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can be easily selected, incorporated, and reused in a wide range of
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driver programs including command-line tools (such as vet), text editors and
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IDEs, build and test systems (such as go build, Bazel, or Buck), test
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frameworks, code review tools, code-base indexers (such as SourceGraph),
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documentation viewers (such as godoc), batch pipelines for large code
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bases, and so on.
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Analyzer
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The primary type in the API is Analyzer. An Analyzer statically
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describes an analysis function: its name, documentation, flags,
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relationship to other analyzers, and of course, its logic.
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To define an analysis, a user declares a (logically constant) variable
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of type Analyzer. Here is a typical example from one of the analyzers in
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the go/analysis/passes/ subdirectory:
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package unusedresult
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var Analyzer = &analysis.Analyzer{
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Name: "unusedresult",
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Doc: "check for unused results of calls to some functions",
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Run: run,
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...
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}
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func run(pass *analysis.Pass) (interface{}, error) {
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...
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}
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An analysis driver is a program such as vet that runs a set of
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analyses and prints the diagnostics that they report.
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The driver program must import the list of Analyzers it needs.
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Typically each Analyzer resides in a separate package.
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To add a new Analyzer to an existing driver, add another item to the list:
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import ( "unusedresult"; "nilness"; "printf" )
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var analyses = []*analysis.Analyzer{
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unusedresult.Analyzer,
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nilness.Analyzer,
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printf.Analyzer,
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}
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A driver may use the name, flags, and documentation to provide on-line
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help that describes the analyses it performs.
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The doc comment contains a brief one-line summary,
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optionally followed by paragraphs of explanation.
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The Analyzer type has more fields besides those shown above:
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type Analyzer struct {
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Name string
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Doc string
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Flags flag.FlagSet
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Run func(*Pass) (interface{}, error)
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RunDespiteErrors bool
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ResultType reflect.Type
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Requires []*Analyzer
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FactTypes []Fact
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}
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The Flags field declares a set of named (global) flag variables that
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control analysis behavior. Unlike vet, analysis flags are not declared
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directly in the command line FlagSet; it is up to the driver to set the
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flag variables. A driver for a single analysis, a, might expose its flag
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f directly on the command line as -f, whereas a driver for multiple
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analyses might prefix the flag name by the analysis name (-a.f) to avoid
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ambiguity. An IDE might expose the flags through a graphical interface,
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and a batch pipeline might configure them from a config file.
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See the "findcall" analyzer for an example of flags in action.
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The RunDespiteErrors flag indicates whether the analysis is equipped to
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handle ill-typed code. If not, the driver will skip the analysis if
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there were parse or type errors.
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The optional ResultType field specifies the type of the result value
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computed by this analysis and made available to other analyses.
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The Requires field specifies a list of analyses upon which
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this one depends and whose results it may access, and it constrains the
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order in which a driver may run analyses.
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The FactTypes field is discussed in the section on Modularity.
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The analysis package provides a Validate function to perform basic
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sanity checks on an Analyzer, such as that its Requires graph is
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acyclic, its fact and result types are unique, and so on.
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Finally, the Run field contains a function to be called by the driver to
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execute the analysis on a single package. The driver passes it an
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instance of the Pass type.
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Pass
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A Pass describes a single unit of work: the application of a particular
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Analyzer to a particular package of Go code.
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The Pass provides information to the Analyzer's Run function about the
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package being analyzed, and provides operations to the Run function for
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reporting diagnostics and other information back to the driver.
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type Pass struct {
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Fset *token.FileSet
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Files []*ast.File
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OtherFiles []string
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Pkg *types.Package
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TypesInfo *types.Info
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ResultOf map[*Analyzer]interface{}
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Report func(Diagnostic)
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...
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}
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The Fset, Files, Pkg, and TypesInfo fields provide the syntax trees,
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type information, and source positions for a single package of Go code.
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The OtherFiles field provides the names, but not the contents, of non-Go
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files such as assembly that are part of this package. See the "asmdecl"
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or "buildtags" analyzers for examples of loading non-Go files and reporting
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diagnostics against them.
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The ResultOf field provides the results computed by the analyzers
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required by this one, as expressed in its Analyzer.Requires field. The
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driver runs the required analyzers first and makes their results
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available in this map. Each Analyzer must return a value of the type
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described in its Analyzer.ResultType field.
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For example, the "ctrlflow" analyzer returns a *ctrlflow.CFGs, which
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provides a control-flow graph for each function in the package (see
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golang.org/x/tools/go/cfg); the "inspect" analyzer returns a value that
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enables other Analyzers to traverse the syntax trees of the package more
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efficiently; and the "buildssa" analyzer constructs an SSA-form
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intermediate representation.
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Each of these Analyzers extends the capabilities of later Analyzers
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without adding a dependency to the core API, so an analysis tool pays
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only for the extensions it needs.
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The Report function emits a diagnostic, a message associated with a
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source position. For most analyses, diagnostics are their primary
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result.
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For convenience, Pass provides a helper method, Reportf, to report a new
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diagnostic by formatting a string.
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Diagnostic is defined as:
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type Diagnostic struct {
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Pos token.Pos
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Category string // optional
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Message string
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}
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The optional Category field is a short identifier that classifies the
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kind of message when an analysis produces several kinds of diagnostic.
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Most Analyzers inspect typed Go syntax trees, but a few, such as asmdecl
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and buildtag, inspect the raw text of Go source files or even non-Go
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files such as assembly. To report a diagnostic against a line of a
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raw text file, use the following sequence:
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content, err := ioutil.ReadFile(filename)
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if err != nil { ... }
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tf := fset.AddFile(filename, -1, len(content))
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tf.SetLinesForContent(content)
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...
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pass.Reportf(tf.LineStart(line), "oops")
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Modular analysis with Facts
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To improve efficiency and scalability, large programs are routinely
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built using separate compilation: units of the program are compiled
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separately, and recompiled only when one of their dependencies changes;
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independent modules may be compiled in parallel. The same technique may
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be applied to static analyses, for the same benefits. Such analyses are
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described as "modular".
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A compiler’s type checker is an example of a modular static analysis.
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Many other checkers we would like to apply to Go programs can be
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understood as alternative or non-standard type systems. For example,
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vet's printf checker infers whether a function has the "printf wrapper"
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type, and it applies stricter checks to calls of such functions. In
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addition, it records which functions are printf wrappers for use by
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later analysis passes to identify other printf wrappers by induction.
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A result such as “f is a printf wrapper” that is not interesting by
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itself but serves as a stepping stone to an interesting result (such as
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a diagnostic) is called a "fact".
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The analysis API allows an analysis to define new types of facts, to
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associate facts of these types with objects (named entities) declared
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within the current package, or with the package as a whole, and to query
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for an existing fact of a given type associated with an object or
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package.
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An Analyzer that uses facts must declare their types:
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var Analyzer = &analysis.Analyzer{
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Name: "printf",
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FactTypes: []analysis.Fact{new(isWrapper)},
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...
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}
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type isWrapper struct{} // => *types.Func f “is a printf wrapper”
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The driver program ensures that facts for a pass’s dependencies are
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generated before analyzing the package and is responsible for propagating
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facts from one package to another, possibly across address spaces.
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Consequently, Facts must be serializable. The API requires that drivers
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use the gob encoding, an efficient, robust, self-describing binary
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protocol. A fact type may implement the GobEncoder/GobDecoder interfaces
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if the default encoding is unsuitable. Facts should be stateless.
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The Pass type has functions to import and export facts,
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associated either with an object or with a package:
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type Pass struct {
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...
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ExportObjectFact func(types.Object, Fact)
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ImportObjectFact func(types.Object, Fact) bool
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ExportPackageFact func(fact Fact)
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ImportPackageFact func(*types.Package, Fact) bool
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}
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An Analyzer may only export facts associated with the current package or
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its objects, though it may import facts from any package or object that
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is an import dependency of the current package.
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Conceptually, ExportObjectFact(obj, fact) inserts fact into a hidden map keyed by
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the pair (obj, TypeOf(fact)), and the ImportObjectFact function
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retrieves the entry from this map and copies its value into the variable
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pointed to by fact. This scheme assumes that the concrete type of fact
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is a pointer; this assumption is checked by the Validate function.
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See the "printf" analyzer for an example of object facts in action.
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Some driver implementations (such as those based on Bazel and Blaze) do
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not currently apply analyzers to packages of the standard library.
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Therefore, for best results, analyzer authors should not rely on
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analysis facts being available for standard packages.
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For example, although the printf checker is capable of deducing during
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analysis of the log package that log.Printf is a printf wrapper,
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this fact is built in to the analyzer so that it correctly checks
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calls to log.Printf even when run in a driver that does not apply
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it to standard packages. We would like to remove this limitation in future.
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Testing an Analyzer
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The analysistest subpackage provides utilities for testing an Analyzer.
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In a few lines of code, it is possible to run an analyzer on a package
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of testdata files and check that it reported all the expected
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diagnostics and facts (and no more). Expectations are expressed using
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"// want ..." comments in the input code.
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Standalone commands
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Analyzers are provided in the form of packages that a driver program is
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expected to import. The vet command imports a set of several analyzers,
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but users may wish to define their own analysis commands that perform
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additional checks. To simplify the task of creating an analysis command,
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either for a single analyzer or for a whole suite, we provide the
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singlechecker and multichecker subpackages.
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The singlechecker package provides the main function for a command that
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runs one analyzer. By convention, each analyzer such as
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go/passes/findcall should be accompanied by a singlechecker-based
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command such as go/analysis/passes/findcall/cmd/findcall, defined in its
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entirety as:
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package main
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import (
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"golang.org/x/tools/go/analysis/passes/findcall"
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"golang.org/x/tools/go/analysis/singlechecker"
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)
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func main() { singlechecker.Main(findcall.Analyzer) }
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A tool that provides multiple analyzers can use multichecker in a
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similar way, giving it the list of Analyzers.
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*/
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package analysis
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