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update dependencies (#6267)

Browse Source 
Signed-off-by: hongming <coder.scala@gmail.com>
This commit is contained in:
hongming
2024-11-06 10:27:06 +08:00
committed by GitHub
parent faf255a084
commit cfebd96a1f
4263 changed files with 341374 additions and 132036 deletions
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32
vendor/golang.org/x/tools/go/ast/astutil/enclosing.go generated vendored
View File

@@ -11,8 +11,6 @@ import (
"go/ast"
"go/token"
"sort"
"golang.org/x/tools/internal/typeparams"
)
// PathEnclosingInterval returns the node that encloses the source
@@ -108,8 +106,21 @@ func PathEnclosingInterval(root *ast.File, start, end token.Pos) (path []ast.Nod
// Does augmented child strictly contain [start, end)?
if augPos <= start && end <= augEnd {
_, isToken := child.(tokenNode)
return isToken || visit(child)
if is[tokenNode](child) {
return true
}
// childrenOf elides the FuncType node beneath FuncDecl.
// Add it back here for TypeParams, Params, Results,
// all FieldLists). But we don't add it back for the "func" token
// even though it is is the tree at FuncDecl.Type.Func.
if decl, ok := node.(*ast.FuncDecl); ok {
if fields, ok := child.(*ast.FieldList); ok && fields != decl.Recv {
path = append(path, decl.Type)
}
}
return visit(child)
}
// Does [start, end) overlap multiple children?
@@ -315,6 +326,8 @@ func childrenOf(n ast.Node) []ast.Node {
//
// As a workaround, we inline the case for FuncType
// here and order things correctly.
// We also need to insert the elided FuncType just
// before the 'visit' recursion.
//
children = nil // discard ast.Walk(FuncDecl) info subtrees
children = append(children, tok(n.Type.Func, len("func")))
@@ -322,7 +335,7 @@ func childrenOf(n ast.Node) []ast.Node {
children = append(children, n.Recv)
}
children = append(children, n.Name)
if tparams := typeparams.ForFuncType(n.Type); tparams != nil {
if tparams := n.Type.TypeParams; tparams != nil {
children = append(children, tparams)
}
if n.Type.Params != nil {
@@ -377,7 +390,7 @@ func childrenOf(n ast.Node) []ast.Node {
tok(n.Lbrack, len("[")),
tok(n.Rbrack, len("]")))
case *typeparams.IndexListExpr:
case *ast.IndexListExpr:
children = append(children,
tok(n.Lbrack, len("[")),
tok(n.Rbrack, len("]")))
@@ -588,7 +601,7 @@ func NodeDescription(n ast.Node) string {
return "decrement statement"
case *ast.IndexExpr:
return "index expression"
case *typeparams.IndexListExpr:
case *ast.IndexListExpr:
return "index list expression"
case *ast.InterfaceType:
return "interface type"
@@ -634,3 +647,8 @@ func NodeDescription(n ast.Node) string {
}
panic(fmt.Sprintf("unexpected node type: %T", n))
}
func is[T any](x any) bool {
_, ok := x.(T)
return ok
}

8
vendor/golang.org/x/tools/go/ast/astutil/rewrite.go generated vendored
View File

@@ -9,8 +9,6 @@ import (
"go/ast"
"reflect"
"sort"
"golang.org/x/tools/internal/typeparams"
)
// An ApplyFunc is invoked by Apply for each node n, even if n is nil,
@@ -252,7 +250,7 @@ func (a *application) apply(parent ast.Node, name string, iter *iterator, n ast.
a.apply(n, "X", nil, n.X)
a.apply(n, "Index", nil, n.Index)
case *typeparams.IndexListExpr:
case *ast.IndexListExpr:
a.apply(n, "X", nil, n.X)
a.applyList(n, "Indices")
@@ -293,7 +291,7 @@ func (a *application) apply(parent ast.Node, name string, iter *iterator, n ast.
a.apply(n, "Fields", nil, n.Fields)
case *ast.FuncType:
if tparams := typeparams.ForFuncType(n); tparams != nil {
if tparams := n.TypeParams; tparams != nil {
a.apply(n, "TypeParams", nil, tparams)
}
a.apply(n, "Params", nil, n.Params)
@@ -408,7 +406,7 @@ func (a *application) apply(parent ast.Node, name string, iter *iterator, n ast.
case *ast.TypeSpec:
a.apply(n, "Doc", nil, n.Doc)
a.apply(n, "Name", nil, n.Name)
if tparams := typeparams.ForTypeSpec(n); tparams != nil {
if tparams := n.TypeParams; tparams != nil {
a.apply(n, "TypeParams", nil, tparams)
}
a.apply(n, "Type", nil, n.Type)

11
vendor/golang.org/x/tools/go/ast/astutil/util.go generated vendored
View File

@@ -7,12 +7,5 @@ package astutil
import "go/ast"
// Unparen returns e with any enclosing parentheses stripped.
func Unparen(e ast.Expr) ast.Expr {
for {
p, ok := e.(*ast.ParenExpr)
if !ok {
return e
}
e = p.X
}
}
// Deprecated: use [ast.Unparen].
func Unparen(e ast.Expr) ast.Expr { return ast.Unparen(e) }

13
vendor/golang.org/x/tools/go/ast/inspector/inspector.go generated vendored
View File

@@ -64,14 +64,24 @@ type event struct {
// depth-first order. It calls f(n) for each node n before it visits
// n's children.
//
// The complete traversal sequence is determined by ast.Inspect.
// The types argument, if non-empty, enables type-based filtering of
// events. The function f if is called only for nodes whose type
// events. The function f is called only for nodes whose type
// matches an element of the types slice.
func (in *Inspector) Preorder(types []ast.Node, f func(ast.Node)) {
// Because it avoids postorder calls to f, and the pruning
// check, Preorder is almost twice as fast as Nodes. The two
// features seem to contribute similar slowdowns (~1.4x each).
// This function is equivalent to the PreorderSeq call below,
// but to avoid the additional dynamic call (which adds 13-35%
// to the benchmarks), we expand it out.
//
// in.PreorderSeq(types...)(func(n ast.Node) bool {
// f(n)
// return true
// })
mask := maskOf(types)
for i := 0; i < len(in.events); {
ev := in.events[i]
@@ -97,6 +107,7 @@ func (in *Inspector) Preorder(types []ast.Node, f func(ast.Node)) {
// of the non-nil children of the node, followed by a call of
// f(n, false).
//
// The complete traversal sequence is determined by ast.Inspect.
// The types argument, if non-empty, enables type-based filtering of
// events. The function f if is called only for nodes whose type
// matches an element of the types slice.

85
vendor/golang.org/x/tools/go/ast/inspector/iter.go generated vendored Normal file
View File

@@ -0,0 +1,85 @@
// Copyright 2024 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.
//go:build go1.23
package inspector
import (
"go/ast"
"iter"
)
// PreorderSeq returns an iterator that visits all the
// nodes of the files supplied to New in depth-first order.
// It visits each node n before n's children.
// The complete traversal sequence is determined by ast.Inspect.
//
// The types argument, if non-empty, enables type-based
// filtering of events: only nodes whose type matches an
// element of the types slice are included in the sequence.
func (in *Inspector) PreorderSeq(types ...ast.Node) iter.Seq[ast.Node] {
// This implementation is identical to Preorder,
// except that it supports breaking out of the loop.
return func(yield func(ast.Node) bool) {
mask := maskOf(types)
for i := 0; i < len(in.events); {
ev := in.events[i]
if ev.index > i {
// push
if ev.typ&mask != 0 {
if !yield(ev.node) {
break
}
}
pop := ev.index
if in.events[pop].typ&mask == 0 {
// Subtrees do not contain types: skip them and pop.
i = pop + 1
continue
}
}
i++
}
}
}
// All[N] returns an iterator over all the nodes of type N.
// N must be a pointer-to-struct type that implements ast.Node.
//
// Example:
//
// for call := range All[*ast.CallExpr](in) { ... }
func All[N interface {
*S
ast.Node
}, S any](in *Inspector) iter.Seq[N] {
// To avoid additional dynamic call overheads,
// we duplicate rather than call the logic of PreorderSeq.
mask := typeOf((N)(nil))
return func(yield func(N) bool) {
for i := 0; i < len(in.events); {
ev := in.events[i]
if ev.index > i {
// push
if ev.typ&mask != 0 {
if !yield(ev.node.(N)) {
break
}
}
pop := ev.index
if in.events[pop].typ&mask == 0 {
// Subtrees do not contain types: skip them and pop.
i = pop + 1
continue
}
}
i++
}
}
}

4
vendor/golang.org/x/tools/go/ast/inspector/typeof.go generated vendored
View File

@@ -12,8 +12,6 @@ package inspector
import (
"go/ast"
"math"
"golang.org/x/tools/internal/typeparams"
)
const (
@@ -171,7 +169,7 @@ func typeOf(n ast.Node) uint64 {
return 1 << nIncDecStmt
case *ast.IndexExpr:
return 1 << nIndexExpr
case *typeparams.IndexListExpr:
case *ast.IndexListExpr:
return 1 << nIndexListExpr
case *ast.InterfaceType:
return 1 << nInterfaceType

13
vendor/golang.org/x/tools/go/gcexportdata/gcexportdata.go generated vendored
View File

@@ -47,7 +47,7 @@ import (
func Find(importPath, srcDir string) (filename, path string) {
cmd := exec.Command("go", "list", "-json", "-export", "--", importPath)
cmd.Dir = srcDir
out, err := cmd.CombinedOutput()
out, err := cmd.Output()
if err != nil {
return "", ""
}
@@ -128,15 +128,14 @@ func Read(in io.Reader, fset *token.FileSet, imports map[string]*types.Package,
// (from "version"). Select appropriate importer.
if len(data) > 0 {
switch data[0] {
case 'i':
case 'v', 'c', 'd': // binary, till go1.10
return nil, fmt.Errorf("binary (%c) import format is no longer supported", data[0])
case 'i': // indexed, till go1.19
_, pkg, err := gcimporter.IImportData(fset, imports, data[1:], path)
return pkg, err
case 'v', 'c', 'd':
_, pkg, err := gcimporter.BImportData(fset, imports, data, path)
return pkg, err
case 'u':
case 'u': // unified, from go1.20
_, pkg, err := gcimporter.UImportData(fset, imports, data[1:], path)
return pkg, err

49
vendor/golang.org/x/tools/go/internal/packagesdriver/sizes.go generated vendored
View File

@@ -1,49 +0,0 @@
// 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 packagesdriver fetches type sizes for go/packages and go/analysis.
package packagesdriver
import (
"context"
"fmt"
"go/types"
"strings"
"golang.org/x/tools/internal/gocommand"
)
var debug = false
func GetSizesGolist(ctx context.Context, inv gocommand.Invocation, gocmdRunner *gocommand.Runner) (types.Sizes, error) {
inv.Verb = "list"
inv.Args = []string{"-f", "{{context.GOARCH}} {{context.Compiler}}", "--", "unsafe"}
stdout, stderr, friendlyErr, rawErr := gocmdRunner.RunRaw(ctx, inv)
var goarch, compiler string
if rawErr != nil {
if rawErrMsg := rawErr.Error(); strings.Contains(rawErrMsg, "cannot find main module") || strings.Contains(rawErrMsg, "go.mod file not found") {
// User's running outside of a module. All bets are off. Get GOARCH and guess compiler is gc.
// TODO(matloob): Is this a problem in practice?
inv.Verb = "env"
inv.Args = []string{"GOARCH"}
envout, enverr := gocmdRunner.Run(ctx, inv)
if enverr != nil {
return nil, enverr
}
goarch = strings.TrimSpace(envout.String())
compiler = "gc"
} else {
return nil, friendlyErr
}
} else {
fields := strings.Fields(stdout.String())
if len(fields) < 2 {
return nil, fmt.Errorf("could not parse GOARCH and Go compiler in format \"<GOARCH> <compiler>\":\nstdout: <<%s>>\nstderr: <<%s>>",
stdout.String(), stderr.String())
}
goarch = fields[0]
compiler = fields[1]
}
return types.SizesFor(compiler, goarch), nil
}

63
vendor/golang.org/x/tools/go/packages/doc.go generated vendored
View File

@@ -5,12 +5,20 @@
/*
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.
The [Load] function takes as input a list of patterns and returns a
list of [Package] values describing individual packages matched by those
patterns.
A [Config] specifies configuration options, the most important of which is
the [LoadMode], which 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
Load passes most patterns directly to the underlying build tool.
The default build tool is the go command.
Its supported patterns are described at
https://pkg.go.dev/cmd/go#hdr-Package_lists_and_patterns.
Other build systems may be supported by providing a "driver";
see [The driver protocol].
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.
@@ -35,7 +43,7 @@ The Package struct provides basic information about the package, including
- 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.
- TypesInfo, 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.)
@@ -56,7 +64,7 @@ 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.
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
@@ -64,9 +72,40 @@ 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
uninterpreted to Load, so that it can interpret them
according to the conventions of the underlying build system.
See the Example function for typical usage.
# The driver protocol
Load may be used to load Go packages even in Go projects that use
alternative build systems, by installing an appropriate "driver"
program for the build system and specifying its location in the
GOPACKAGESDRIVER environment variable.
For example,
https://github.com/bazelbuild/rules_go/wiki/Editor-and-tool-integration
explains how to use the driver for Bazel.
The driver program is responsible for interpreting patterns in its
preferred notation and reporting information about the packages that
those patterns identify. Drivers must also support the special "file="
and "pattern=" patterns described above.
The patterns are provided as positional command-line arguments. A
JSON-encoded [DriverRequest] message providing additional information
is written to the driver's standard input. The driver must write a
JSON-encoded [DriverResponse] message to its standard output. (This
message differs from the JSON schema produced by 'go list'.)
The value of the PWD environment variable seen by the driver process
is the preferred name of its working directory. (The working directory
may have other aliases due to symbolic links; see the comment on the
Dir field of [exec.Cmd] for related information.)
When the driver process emits in its response the name of a file
that is a descendant of this directory, it must use an absolute path
that has the value of PWD as a prefix, to ensure that the returned
filenames satisfy the original query.
*/
package packages // import "golang.org/x/tools/go/packages"
@@ -168,14 +207,6 @@ 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?

103
vendor/golang.org/x/tools/go/packages/external.go generated vendored
View File

@@ -2,48 +2,87 @@
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// This file enables an external tool to intercept package requests.
// If the tool is present then its results are used in preference to
// the go list command.
package packages
// This file defines the protocol that enables an external "driver"
// tool to supply package metadata in place of 'go list'.
import (
"bytes"
"encoding/json"
"fmt"
exec "golang.org/x/sys/execabs"
"os"
"os/exec"
"strings"
)
// The Driver Protocol
// DriverRequest defines the schema of a request for package metadata
// from an external driver program. The JSON-encoded DriverRequest
// message is provided to the driver program's standard input. The
// query patterns are provided as command-line arguments.
//
// The driver, given the inputs to a call to Load, returns metadata about the packages specified.
// This allows for different build systems to support go/packages by telling go/packages how the
// packages' source is organized.
// The driver is a binary, either specified by the GOPACKAGESDRIVER environment variable or in
// the path as gopackagesdriver. It's given the inputs to load in its argv. See the package
// documentation in doc.go for the full description of the patterns that need to be supported.
// A driver receives as a JSON-serialized driverRequest struct in standard input and will
// produce a JSON-serialized driverResponse (see definition in packages.go) in its standard output.
// driverRequest is used to provide the portion of Load's Config that is needed by a driver.
type driverRequest struct {
// See the package documentation for an overview.
type DriverRequest struct {
Mode LoadMode `json:"mode"`
// Env specifies the environment the underlying build system should be run in.
Env []string `json:"env"`
// BuildFlags are flags that should be passed to the underlying build system.
BuildFlags []string `json:"build_flags"`
// Tests specifies whether the patterns should also return test packages.
Tests bool `json:"tests"`
// Overlay maps file paths (relative to the driver's working directory) to the byte contents
// of overlay files.
// Overlay maps file paths (relative to the driver's working directory)
// to the contents of overlay files (see Config.Overlay).
Overlay map[string][]byte `json:"overlay"`
}
// DriverResponse defines the schema of a response from an external
// driver program, providing the results of a query for package
// metadata. The driver program must write a JSON-encoded
// DriverResponse message to its standard output.
//
// See the package documentation for an overview.
type DriverResponse struct {
// NotHandled is returned if the request can't be handled by the current
// driver. If an external driver returns a response with NotHandled, the
// rest of the DriverResponse is ignored, and go/packages will fallback
// to the next driver. If go/packages is extended in the future to support
// lists of multiple drivers, go/packages will fall back to the next driver.
NotHandled bool
// Compiler and Arch are the arguments pass of types.SizesFor
// to get a types.Sizes to use when type checking.
Compiler string
Arch string
// Roots is the set of package IDs that make up the root packages.
// We have to encode this separately because when we encode a single package
// we cannot know if it is one of the roots as that requires knowledge of the
// graph it is part of.
Roots []string `json:",omitempty"`
// Packages is the full set of packages in the graph.
// The packages are not connected into a graph.
// The Imports if populated will be stubs that only have their ID set.
// Imports will be connected and then type and syntax information added in a
// later pass (see refine).
Packages []*Package
// GoVersion is the minor version number used by the driver
// (e.g. the go command on the PATH) when selecting .go files.
// Zero means unknown.
GoVersion int
}
// driver is the type for functions that query the build system for the
// packages named by the patterns.
type driver func(cfg *Config, patterns ...string) (*DriverResponse, error)
// findExternalDriver returns the file path of a tool that supplies
// the build system package structure, or "" if not found."
// the build system package structure, or "" if not found.
// If GOPACKAGESDRIVER is set in the environment findExternalTool returns its
// value, otherwise it searches for a binary named gopackagesdriver on the PATH.
func findExternalDriver(cfg *Config) driver {
@@ -64,8 +103,8 @@ func findExternalDriver(cfg *Config) driver {
return nil
}
}
return func(cfg *Config, words ...string) (*driverResponse, error) {
req, err := json.Marshal(driverRequest{
return func(cfg *Config, words ...string) (*DriverResponse, error) {
req, err := json.Marshal(DriverRequest{
Mode: cfg.Mode,
Env: cfg.Env,
BuildFlags: cfg.BuildFlags,
@@ -80,7 +119,19 @@ func findExternalDriver(cfg *Config) driver {
stderr := new(bytes.Buffer)
cmd := exec.CommandContext(cfg.Context, tool, words...)
cmd.Dir = cfg.Dir
cmd.Env = cfg.Env
// The cwd gets resolved to the real path. On Darwin, where
// /tmp is a symlink, this breaks anything that expects the
// working directory to keep the original path, including the
// go command when dealing with modules.
//
// os.Getwd stdlib has a special feature where if the
// cwd and the PWD are the same node then it trusts
// the PWD, so by setting it in the env for the child
// process we fix up all the paths returned by the go
// command.
//
// (See similar trick in Invocation.run in ../../internal/gocommand/invoke.go)
cmd.Env = append(slicesClip(cfg.Env), "PWD="+cfg.Dir)
cmd.Stdin = bytes.NewReader(req)
cmd.Stdout = buf
cmd.Stderr = stderr
@@ -92,10 +143,14 @@ func findExternalDriver(cfg *Config) driver {
fmt.Fprintf(os.Stderr, "%s stderr: <<%s>>\n", cmdDebugStr(cmd), stderr)
}
var response driverResponse
var response DriverResponse
if err := json.Unmarshal(buf.Bytes(), &response); err != nil {
return nil, err
}
return &response, nil
}
}
// slicesClip removes unused capacity from the slice, returning s[:len(s):len(s)].
// TODO(adonovan): use go1.21 slices.Clip.
func slicesClip[S ~[]E, E any](s S) S { return s[:len(s):len(s)] }

269
vendor/golang.org/x/tools/go/packages/golist.go generated vendored
View File

@@ -9,10 +9,9 @@ import (
"context"
"encoding/json"
"fmt"
"go/types"
"io/ioutil"
"log"
"os"
"os/exec"
"path"
"path/filepath"
"reflect"
@@ -22,8 +21,6 @@ import (
"sync"
"unicode"
exec "golang.org/x/sys/execabs"
"golang.org/x/tools/go/internal/packagesdriver"
"golang.org/x/tools/internal/gocommand"
"golang.org/x/tools/internal/packagesinternal"
)
@@ -37,23 +34,23 @@ type goTooOldError struct {
error
}
// responseDeduper wraps a driverResponse, deduplicating its contents.
// responseDeduper wraps a DriverResponse, deduplicating its contents.
type responseDeduper struct {
seenRoots map[string]bool
seenPackages map[string]*Package
dr *driverResponse
dr *DriverResponse
}
func newDeduper() *responseDeduper {
return &responseDeduper{
dr: &driverResponse{},
dr: &DriverResponse{},
seenRoots: map[string]bool{},
seenPackages: map[string]*Package{},
}
}
// addAll fills in r with a driverResponse.
func (r *responseDeduper) addAll(dr *driverResponse) {
// addAll fills in r with a DriverResponse.
func (r *responseDeduper) addAll(dr *DriverResponse) {
for _, pkg := range dr.Packages {
r.addPackage(pkg)
}
@@ -130,7 +127,7 @@ func (state *golistState) mustGetEnv() map[string]string {
// goListDriver uses the go list command to interpret the patterns and produce
// the build system package structure.
// See driver for more details.
func goListDriver(cfg *Config, patterns ...string) (*driverResponse, error) {
func goListDriver(cfg *Config, patterns ...string) (_ *DriverResponse, err error) {
// Make sure that any asynchronous go commands are killed when we return.
parentCtx := cfg.Context
if parentCtx == nil {
@@ -148,16 +145,18 @@ func goListDriver(cfg *Config, patterns ...string) (*driverResponse, error) {
}
// Fill in response.Sizes asynchronously if necessary.
var sizeserr error
var sizeswg sync.WaitGroup
if cfg.Mode&NeedTypesSizes != 0 || cfg.Mode&NeedTypes != 0 {
sizeswg.Add(1)
errCh := make(chan error)
go func() {
var sizes types.Sizes
sizes, sizeserr = packagesdriver.GetSizesGolist(ctx, state.cfgInvocation(), cfg.gocmdRunner)
// types.SizesFor always returns nil or a *types.StdSizes.
response.dr.Sizes, _ = sizes.(*types.StdSizes)
sizeswg.Done()
compiler, arch, err := getSizesForArgs(ctx, state.cfgInvocation(), cfg.gocmdRunner)
response.dr.Compiler = compiler
response.dr.Arch = arch
errCh <- err
}()
defer func() {
if sizesErr := <-errCh; sizesErr != nil {
err = sizesErr
}
}()
}
@@ -210,87 +209,10 @@ extractQueries:
}
}
// Only use go/packages' overlay processing if we're using a Go version
// below 1.16. Otherwise, go list handles it.
if goVersion, err := state.getGoVersion(); err == nil && goVersion < 16 {
modifiedPkgs, needPkgs, err := state.processGolistOverlay(response)
if err != nil {
return nil, err
}
var containsCandidates []string
if len(containFiles) > 0 {
containsCandidates = append(containsCandidates, modifiedPkgs...)
containsCandidates = append(containsCandidates, needPkgs...)
}
if err := state.addNeededOverlayPackages(response, needPkgs); err != nil {
return nil, err
}
// Check candidate packages for containFiles.
if len(containFiles) > 0 {
for _, id := range containsCandidates {
pkg, ok := response.seenPackages[id]
if !ok {
response.addPackage(&Package{
ID: id,
Errors: []Error{{
Kind: ListError,
Msg: fmt.Sprintf("package %s expected but not seen", id),
}},
})
continue
}
for _, f := range containFiles {
for _, g := range pkg.GoFiles {
if sameFile(f, g) {
response.addRoot(id)
}
}
}
}
}
// Add root for any package that matches a pattern. This applies only to
// packages that are modified by overlays, since they are not added as
// roots automatically.
for _, pattern := range restPatterns {
match := matchPattern(pattern)
for _, pkgID := range modifiedPkgs {
pkg, ok := response.seenPackages[pkgID]
if !ok {
continue
}
if match(pkg.PkgPath) {
response.addRoot(pkg.ID)
}
}
}
}
sizeswg.Wait()
if sizeserr != nil {
return nil, sizeserr
}
// (We may yet return an error due to defer.)
return response.dr, nil
}
func (state *golistState) addNeededOverlayPackages(response *responseDeduper, pkgs []string) error {
if len(pkgs) == 0 {
return nil
}
dr, err := state.createDriverResponse(pkgs...)
if err != nil {
return err
}
for _, pkg := range dr.Packages {
response.addPackage(pkg)
}
_, needPkgs, err := state.processGolistOverlay(response)
if err != nil {
return err
}
return state.addNeededOverlayPackages(response, needPkgs)
}
func (state *golistState) runContainsQueries(response *responseDeduper, queries []string) error {
for _, query := range queries {
// TODO(matloob): Do only one query per directory.
@@ -342,7 +264,7 @@ func (state *golistState) runContainsQueries(response *responseDeduper, queries
// adhocPackage attempts to load or construct an ad-hoc package for a given
// query, if the original call to the driver produced inadequate results.
func (state *golistState) adhocPackage(pattern, query string) (*driverResponse, error) {
func (state *golistState) adhocPackage(pattern, query string) (*DriverResponse, error) {
response, err := state.createDriverResponse(query)
if err != nil {
return nil, err
@@ -433,7 +355,7 @@ func otherFiles(p *jsonPackage) [][]string {
// createDriverResponse uses the "go list" command to expand the pattern
// words and return a response for the specified packages.
func (state *golistState) createDriverResponse(words ...string) (*driverResponse, error) {
func (state *golistState) createDriverResponse(words ...string) (*DriverResponse, error) {
// go list uses the following identifiers in ImportPath and Imports:
//
// "p" -- importable package or main (command)
@@ -460,7 +382,7 @@ func (state *golistState) createDriverResponse(words ...string) (*driverResponse
pkgs := make(map[string]*Package)
additionalErrors := make(map[string][]Error)
// Decode the JSON and convert it to Package form.
response := &driverResponse{
response := &DriverResponse{
GoVersion: goVersion,
}
for dec := json.NewDecoder(buf); dec.More(); {
@@ -625,7 +547,12 @@ func (state *golistState) createDriverResponse(words ...string) (*driverResponse
}
if pkg.PkgPath == "unsafe" {
pkg.GoFiles = nil // ignore fake unsafe.go file
pkg.CompiledGoFiles = nil // ignore fake unsafe.go file (#59929)
} else if len(pkg.CompiledGoFiles) == 0 {
// Work around for pre-go.1.11 versions of go list.
// TODO(matloob): they should be handled by the fallback.
// Can we delete this?
pkg.CompiledGoFiles = pkg.GoFiles
}
// Assume go list emits only absolute paths for Dir.
@@ -663,16 +590,12 @@ func (state *golistState) createDriverResponse(words ...string) (*driverResponse
response.Roots = append(response.Roots, pkg.ID)
}
// Work around for pre-go.1.11 versions of go list.
// TODO(matloob): they should be handled by the fallback.
// Can we delete this?
if len(pkg.CompiledGoFiles) == 0 {
pkg.CompiledGoFiles = pkg.GoFiles
}
// Temporary work-around for golang/go#39986. Parse filenames out of
// error messages. This happens if there are unrecoverable syntax
// errors in the source, so we can't match on a specific error message.
//
// TODO(rfindley): remove this heuristic, in favor of considering
// InvalidGoFiles from the list driver.
if err := p.Error; err != nil && state.shouldAddFilenameFromError(p) {
addFilenameFromPos := func(pos string) bool {
split := strings.Split(pos, ":")
@@ -891,6 +814,15 @@ func golistargs(cfg *Config, words []string, goVersion int) []string {
// probably because you'd just get the TestMain.
fmt.Sprintf("-find=%t", !cfg.Tests && cfg.Mode&findFlags == 0 && !usesExportData(cfg)),
}
// golang/go#60456: with go1.21 and later, go list serves pgo variants, which
// can be costly to compute and may result in redundant processing for the
// caller. Disable these variants. If someone wants to add e.g. a NeedPGO
// mode flag, that should be a separate proposal.
if goVersion >= 21 {
fullargs = append(fullargs, "-pgo=off")
}
fullargs = append(fullargs, cfg.BuildFlags...)
fullargs = append(fullargs, "--")
fullargs = append(fullargs, words...)
@@ -908,6 +840,7 @@ func (state *golistState) cfgInvocation() gocommand.Invocation {
Env: cfg.Env,
Logf: cfg.Logf,
WorkingDir: cfg.Dir,
Overlay: cfg.goListOverlayFile,
}
}
@@ -916,26 +849,6 @@ func (state *golistState) invokeGo(verb string, args ...string) (*bytes.Buffer,
cfg := state.cfg
inv := state.cfgInvocation()
// For Go versions 1.16 and above, `go list` accepts overlays directly via
// the -overlay flag. Set it, if it's available.
//
// The check for "list" is not necessarily required, but we should avoid
// getting the go version if possible.
if verb == "list" {
goVersion, err := state.getGoVersion()
if err != nil {
return nil, err
}
if goVersion >= 16 {
filename, cleanup, err := state.writeOverlays()
if err != nil {
return nil, err
}
defer cleanup()
inv.Overlay = filename
}
}
inv.Verb = verb
inv.Args = args
gocmdRunner := cfg.gocmdRunner
@@ -1082,67 +995,6 @@ func (state *golistState) invokeGo(verb string, args ...string) (*bytes.Buffer,
return stdout, nil
}
// OverlayJSON is the format overlay files are expected to be in.
// The Replace map maps from overlaid paths to replacement paths:
// the Go command will forward all reads trying to open
// each overlaid path to its replacement path, or consider the overlaid
// path not to exist if the replacement path is empty.
//
// From golang/go#39958.
type OverlayJSON struct {
Replace map[string]string `json:"replace,omitempty"`
}
// writeOverlays writes out files for go list's -overlay flag, as described
// above.
func (state *golistState) writeOverlays() (filename string, cleanup func(), err error) {
// Do nothing if there are no overlays in the config.
if len(state.cfg.Overlay) == 0 {
return "", func() {}, nil
}
dir, err := ioutil.TempDir("", "gopackages-*")
if err != nil {
return "", nil, err
}
// The caller must clean up this directory, unless this function returns an
// error.
cleanup = func() {
os.RemoveAll(dir)
}
defer func() {
if err != nil {
cleanup()
}
}()
overlays := map[string]string{}
for k, v := range state.cfg.Overlay {
// Create a unique filename for the overlaid files, to avoid
// creating nested directories.
noSeparator := strings.Join(strings.Split(filepath.ToSlash(k), "/"), "")
f, err := ioutil.TempFile(dir, fmt.Sprintf("*-%s", noSeparator))
if err != nil {
return "", func() {}, err
}
if _, err := f.Write(v); err != nil {
return "", func() {}, err
}
if err := f.Close(); err != nil {
return "", func() {}, err
}
overlays[k] = f.Name()
}
b, err := json.Marshal(OverlayJSON{Replace: overlays})
if err != nil {
return "", func() {}, err
}
// Write out the overlay file that contains the filepath mappings.
filename = filepath.Join(dir, "overlay.json")
if err := ioutil.WriteFile(filename, b, 0665); err != nil {
return "", func() {}, err
}
return filename, cleanup, nil
}
func containsGoFile(s []string) bool {
for _, f := range s {
if strings.HasSuffix(f, ".go") {
@@ -1171,3 +1023,44 @@ func cmdDebugStr(cmd *exec.Cmd) string {
}
return fmt.Sprintf("GOROOT=%v GOPATH=%v GO111MODULE=%v GOPROXY=%v PWD=%v %v", env["GOROOT"], env["GOPATH"], env["GO111MODULE"], env["GOPROXY"], env["PWD"], strings.Join(args, " "))
}
// getSizesForArgs queries 'go list' for the appropriate
// Compiler and GOARCH arguments to pass to [types.SizesFor].
func getSizesForArgs(ctx context.Context, inv gocommand.Invocation, gocmdRunner *gocommand.Runner) (string, string, error) {
inv.Verb = "list"
inv.Args = []string{"-f", "{{context.GOARCH}} {{context.Compiler}}", "--", "unsafe"}
stdout, stderr, friendlyErr, rawErr := gocmdRunner.RunRaw(ctx, inv)
var goarch, compiler string
if rawErr != nil {
rawErrMsg := rawErr.Error()
if strings.Contains(rawErrMsg, "cannot find main module") ||
strings.Contains(rawErrMsg, "go.mod file not found") {
// User's running outside of a module.
// All bets are off. Get GOARCH and guess compiler is gc.
// TODO(matloob): Is this a problem in practice?
inv.Verb = "env"
inv.Args = []string{"GOARCH"}
envout, enverr := gocmdRunner.Run(ctx, inv)
if enverr != nil {
return "", "", enverr
}
goarch = strings.TrimSpace(envout.String())
compiler = "gc"
} else if friendlyErr != nil {
return "", "", friendlyErr
} else {
// This should be unreachable, but be defensive
// in case RunRaw's error results are inconsistent.
return "", "", rawErr
}
} else {
fields := strings.Fields(stdout.String())
if len(fields) < 2 {
return "", "", fmt.Errorf("could not parse GOARCH and Go compiler in format \"<GOARCH> <compiler>\":\nstdout: <<%s>>\nstderr: <<%s>>",
stdout.String(), stderr.String())
}
goarch = fields[0]
compiler = fields[1]
}
return compiler, goarch, nil
}

492
vendor/golang.org/x/tools/go/packages/golist_overlay.go generated vendored
View File

@@ -6,314 +6,11 @@ package packages
import (
"encoding/json"
"fmt"
"go/parser"
"go/token"
"os"
"path/filepath"
"regexp"
"sort"
"strconv"
"strings"
"golang.org/x/tools/internal/gocommand"
)
// processGolistOverlay provides rudimentary support for adding
// files that don't exist on disk to an overlay. The results can be
// sometimes incorrect.
// TODO(matloob): Handle unsupported cases, including the following:
// - determining the correct package to add given a new import path
func (state *golistState) processGolistOverlay(response *responseDeduper) (modifiedPkgs, needPkgs []string, err error) {
havePkgs := make(map[string]string) // importPath -> non-test package ID
needPkgsSet := make(map[string]bool)
modifiedPkgsSet := make(map[string]bool)
pkgOfDir := make(map[string][]*Package)
for _, pkg := range response.dr.Packages {
// This is an approximation of import path to id. This can be
// wrong for tests, vendored packages, and a number of other cases.
havePkgs[pkg.PkgPath] = pkg.ID
dir, err := commonDir(pkg.GoFiles)
if err != nil {
return nil, nil, err
}
if dir != "" {
pkgOfDir[dir] = append(pkgOfDir[dir], pkg)
}
}
// If no new imports are added, it is safe to avoid loading any needPkgs.
// Otherwise, it's hard to tell which package is actually being loaded
// (due to vendoring) and whether any modified package will show up
// in the transitive set of dependencies (because new imports are added,
// potentially modifying the transitive set of dependencies).
var overlayAddsImports bool
// If both a package and its test package are created by the overlay, we
// need the real package first. Process all non-test files before test
// files, and make the whole process deterministic while we're at it.
var overlayFiles []string
for opath := range state.cfg.Overlay {
overlayFiles = append(overlayFiles, opath)
}
sort.Slice(overlayFiles, func(i, j int) bool {
iTest := strings.HasSuffix(overlayFiles[i], "_test.go")
jTest := strings.HasSuffix(overlayFiles[j], "_test.go")
if iTest != jTest {
return !iTest // non-tests are before tests.
}
return overlayFiles[i] < overlayFiles[j]
})
for _, opath := range overlayFiles {
contents := state.cfg.Overlay[opath]
base := filepath.Base(opath)
dir := filepath.Dir(opath)
var pkg *Package // if opath belongs to both a package and its test variant, this will be the test variant
var testVariantOf *Package // if opath is a test file, this is the package it is testing
var fileExists bool
isTestFile := strings.HasSuffix(opath, "_test.go")
pkgName, ok := extractPackageName(opath, contents)
if !ok {
// Don't bother adding a file that doesn't even have a parsable package statement
// to the overlay.
continue
}
// If all the overlay files belong to a different package, change the
// package name to that package.
maybeFixPackageName(pkgName, isTestFile, pkgOfDir[dir])
nextPackage:
for _, p := range response.dr.Packages {
if pkgName != p.Name && p.ID != "command-line-arguments" {
continue
}
for _, f := range p.GoFiles {
if !sameFile(filepath.Dir(f), dir) {
continue
}
// Make sure to capture information on the package's test variant, if needed.
if isTestFile && !hasTestFiles(p) {
// TODO(matloob): Are there packages other than the 'production' variant
// of a package that this can match? This shouldn't match the test main package
// because the file is generated in another directory.
testVariantOf = p
continue nextPackage
} else if !isTestFile && hasTestFiles(p) {
// We're examining a test variant, but the overlaid file is
// a non-test file. Because the overlay implementation
// (currently) only adds a file to one package, skip this
// package, so that we can add the file to the production
// variant of the package. (https://golang.org/issue/36857
// tracks handling overlays on both the production and test
// variant of a package).
continue nextPackage
}
if pkg != nil && p != pkg && pkg.PkgPath == p.PkgPath {
// We have already seen the production version of the
// for which p is a test variant.
if hasTestFiles(p) {
testVariantOf = pkg
}
}
pkg = p
if filepath.Base(f) == base {
fileExists = true
}
}
}
// The overlay could have included an entirely new package or an
// ad-hoc package. An ad-hoc package is one that we have manually
// constructed from inadequate `go list` results for a file= query.
// It will have the ID command-line-arguments.
if pkg == nil || pkg.ID == "command-line-arguments" {
// Try to find the module or gopath dir the file is contained in.
// Then for modules, add the module opath to the beginning.
pkgPath, ok, err := state.getPkgPath(dir)
if err != nil {
return nil, nil, err
}
if !ok {
break
}
var forTest string // only set for x tests
isXTest := strings.HasSuffix(pkgName, "_test")
if isXTest {
forTest = pkgPath
pkgPath += "_test"
}
id := pkgPath
if isTestFile {
if isXTest {
id = fmt.Sprintf("%s [%s.test]", pkgPath, forTest)
} else {
id = fmt.Sprintf("%s [%s.test]", pkgPath, pkgPath)
}
}
if pkg != nil {
// TODO(rstambler): We should change the package's path and ID
// here. The only issue is that this messes with the roots.
} else {
// Try to reclaim a package with the same ID, if it exists in the response.
for _, p := range response.dr.Packages {
if reclaimPackage(p, id, opath, contents) {
pkg = p
break
}
}
// Otherwise, create a new package.
if pkg == nil {
pkg = &Package{
PkgPath: pkgPath,
ID: id,
Name: pkgName,
Imports: make(map[string]*Package),
}
response.addPackage(pkg)
havePkgs[pkg.PkgPath] = id
// Add the production package's sources for a test variant.
if isTestFile && !isXTest && testVariantOf != nil {
pkg.GoFiles = append(pkg.GoFiles, testVariantOf.GoFiles...)
pkg.CompiledGoFiles = append(pkg.CompiledGoFiles, testVariantOf.CompiledGoFiles...)
// Add the package under test and its imports to the test variant.
pkg.forTest = testVariantOf.PkgPath
for k, v := range testVariantOf.Imports {
pkg.Imports[k] = &Package{ID: v.ID}
}
}
if isXTest {
pkg.forTest = forTest
}
}
}
}
if !fileExists {
pkg.GoFiles = append(pkg.GoFiles, opath)
// TODO(matloob): Adding the file to CompiledGoFiles can exhibit the wrong behavior
// if the file will be ignored due to its build tags.
pkg.CompiledGoFiles = append(pkg.CompiledGoFiles, opath)
modifiedPkgsSet[pkg.ID] = true
}
imports, err := extractImports(opath, contents)
if err != nil {
// Let the parser or type checker report errors later.
continue
}
for _, imp := range imports {
// TODO(rstambler): If the package is an x test and the import has
// a test variant, make sure to replace it.
if _, found := pkg.Imports[imp]; found {
continue
}
overlayAddsImports = true
id, ok := havePkgs[imp]
if !ok {
var err error
id, err = state.resolveImport(dir, imp)
if err != nil {
return nil, nil, err
}
}
pkg.Imports[imp] = &Package{ID: id}
// Add dependencies to the non-test variant version of this package as well.
if testVariantOf != nil {
testVariantOf.Imports[imp] = &Package{ID: id}
}
}
}
// toPkgPath guesses the package path given the id.
toPkgPath := func(sourceDir, id string) (string, error) {
if i := strings.IndexByte(id, ' '); i >= 0 {
return state.resolveImport(sourceDir, id[:i])
}
return state.resolveImport(sourceDir, id)
}
// Now that new packages have been created, do another pass to determine
// the new set of missing packages.
for _, pkg := range response.dr.Packages {
for _, imp := range pkg.Imports {
if len(pkg.GoFiles) == 0 {
return nil, nil, fmt.Errorf("cannot resolve imports for package %q with no Go files", pkg.PkgPath)
}
pkgPath, err := toPkgPath(filepath.Dir(pkg.GoFiles[0]), imp.ID)
if err != nil {
return nil, nil, err
}
if _, ok := havePkgs[pkgPath]; !ok {
needPkgsSet[pkgPath] = true
}
}
}
if overlayAddsImports {
needPkgs = make([]string, 0, len(needPkgsSet))
for pkg := range needPkgsSet {
needPkgs = append(needPkgs, pkg)
}
}
modifiedPkgs = make([]string, 0, len(modifiedPkgsSet))
for pkg := range modifiedPkgsSet {
modifiedPkgs = append(modifiedPkgs, pkg)
}
return modifiedPkgs, needPkgs, err
}
// resolveImport finds the ID of a package given its import path.
// In particular, it will find the right vendored copy when in GOPATH mode.
func (state *golistState) resolveImport(sourceDir, importPath string) (string, error) {
env, err := state.getEnv()
if err != nil {
return "", err
}
if env["GOMOD"] != "" {
return importPath, nil
}
searchDir := sourceDir
for {
vendorDir := filepath.Join(searchDir, "vendor")
exists, ok := state.vendorDirs[vendorDir]
if !ok {
info, err := os.Stat(vendorDir)
exists = err == nil && info.IsDir()
state.vendorDirs[vendorDir] = exists
}
if exists {
vendoredPath := filepath.Join(vendorDir, importPath)
if info, err := os.Stat(vendoredPath); err == nil && info.IsDir() {
// We should probably check for .go files here, but shame on anyone who fools us.
path, ok, err := state.getPkgPath(vendoredPath)
if err != nil {
return "", err
}
if ok {
return path, nil
}
}
}
// We know we've hit the top of the filesystem when we Dir / and get /,
// or C:\ and get C:\, etc.
next := filepath.Dir(searchDir)
if next == searchDir {
break
}
searchDir = next
}
return importPath, nil
}
func hasTestFiles(p *Package) bool {
for _, f := range p.GoFiles {
if strings.HasSuffix(f, "_test.go") {
return true
}
}
return false
}
// determineRootDirs returns a mapping from absolute directories that could
// contain code to their corresponding import path prefixes.
func (state *golistState) determineRootDirs() (map[string]string, error) {
@@ -384,192 +81,3 @@ func (state *golistState) determineRootDirsGOPATH() (map[string]string, error) {
}
return m, nil
}
func extractImports(filename string, contents []byte) ([]string, error) {
f, err := parser.ParseFile(token.NewFileSet(), filename, contents, parser.ImportsOnly) // TODO(matloob): reuse fileset?
if err != nil {
return nil, err
}
var res []string
for _, imp := range f.Imports {
quotedPath := imp.Path.Value
path, err := strconv.Unquote(quotedPath)
if err != nil {
return nil, err
}
res = append(res, path)
}
return res, nil
}
// reclaimPackage attempts to reuse a package that failed to load in an overlay.
//
// If the package has errors and has no Name, GoFiles, or Imports,
// then it's possible that it doesn't yet exist on disk.
func reclaimPackage(pkg *Package, id string, filename string, contents []byte) bool {
// TODO(rstambler): Check the message of the actual error?
// It differs between $GOPATH and module mode.
if pkg.ID != id {
return false
}
if len(pkg.Errors) != 1 {
return false
}
if pkg.Name != "" || pkg.ExportFile != "" {
return false
}
if len(pkg.GoFiles) > 0 || len(pkg.CompiledGoFiles) > 0 || len(pkg.OtherFiles) > 0 {
return false
}
if len(pkg.Imports) > 0 {
return false
}
pkgName, ok := extractPackageName(filename, contents)
if !ok {
return false
}
pkg.Name = pkgName
pkg.Errors = nil
return true
}
func extractPackageName(filename string, contents []byte) (string, bool) {
// TODO(rstambler): Check the message of the actual error?
// It differs between $GOPATH and module mode.
f, err := parser.ParseFile(token.NewFileSet(), filename, contents, parser.PackageClauseOnly) // TODO(matloob): reuse fileset?
if err != nil {
return "", false
}
return f.Name.Name, true
}
// commonDir returns the directory that all files are in, "" if files is empty,
// or an error if they aren't in the same directory.
func commonDir(files []string) (string, error) {
seen := make(map[string]bool)
for _, f := range files {
seen[filepath.Dir(f)] = true
}
if len(seen) > 1 {
return "", fmt.Errorf("files (%v) are in more than one directory: %v", files, seen)
}
for k := range seen {
// seen has only one element; return it.
return k, nil
}
return "", nil // no files
}
// It is possible that the files in the disk directory dir have a different package
// name from newName, which is deduced from the overlays. If they all have a different
// package name, and they all have the same package name, then that name becomes
// the package name.
// It returns true if it changes the package name, false otherwise.
func maybeFixPackageName(newName string, isTestFile bool, pkgsOfDir []*Package) {
names := make(map[string]int)
for _, p := range pkgsOfDir {
names[p.Name]++
}
if len(names) != 1 {
// some files are in different packages
return
}
var oldName string
for k := range names {
oldName = k
}
if newName == oldName {
return
}
// We might have a case where all of the package names in the directory are
// the same, but the overlay file is for an x test, which belongs to its
// own package. If the x test does not yet exist on disk, we may not yet
// have its package name on disk, but we should not rename the packages.
//
// We use a heuristic to determine if this file belongs to an x test:
// The test file should have a package name whose package name has a _test
// suffix or looks like "newName_test".
maybeXTest := strings.HasPrefix(oldName+"_test", newName) || strings.HasSuffix(newName, "_test")
if isTestFile && maybeXTest {
return
}
for _, p := range pkgsOfDir {
p.Name = newName
}
}
// This function is copy-pasted from
// https://github.com/golang/go/blob/9706f510a5e2754595d716bd64be8375997311fb/src/cmd/go/internal/search/search.go#L360.
// It should be deleted when we remove support for overlays from go/packages.
//
// NOTE: This does not handle any ./... or ./ style queries, as this function
// doesn't know the working directory.
//
// matchPattern(pattern)(name) reports whether
// name matches pattern. Pattern is a limited glob
// pattern in which '...' means 'any string' and there
// is no other special syntax.
// Unfortunately, there are two special cases. Quoting "go help packages":
//
// 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.
func matchPattern(pattern string) func(name string) bool {
// Convert pattern to regular expression.
// The strategy for the trailing /... is to nest it in an explicit ? expression.
// The strategy for the vendor exclusion is to change the unmatchable
// vendor strings to a disallowed code point (vendorChar) and to use
// "(anything but that codepoint)*" as the implementation of the ... wildcard.
// This is a bit complicated but the obvious alternative,
// namely a hand-written search like in most shell glob matchers,
// is too easy to make accidentally exponential.
// Using package regexp guarantees linear-time matching.
const vendorChar = "\x00"
if strings.Contains(pattern, vendorChar) {
return func(name string) bool { return false }
}
re := regexp.QuoteMeta(pattern)
re = replaceVendor(re, vendorChar)
switch {
case strings.HasSuffix(re, `/`+vendorChar+`/\.\.\.`):
re = strings.TrimSuffix(re, `/`+vendorChar+`/\.\.\.`) + `(/vendor|/` + vendorChar + `/\.\.\.)`
case re == vendorChar+`/\.\.\.`:
re = `(/vendor|/` + vendorChar + `/\.\.\.)`
case strings.HasSuffix(re, `/\.\.\.`):
re = strings.TrimSuffix(re, `/\.\.\.`) + `(/\.\.\.)?`
}
re = strings.ReplaceAll(re, `\.\.\.`, `[^`+vendorChar+`]*`)
reg := regexp.MustCompile(`^` + re + `$`)
return func(name string) bool {
if strings.Contains(name, vendorChar) {
return false
}
return reg.MatchString(replaceVendor(name, vendorChar))
}
}
// replaceVendor returns the result of replacing
// non-trailing vendor path elements in x with repl.
func replaceVendor(x, repl string) string {
if !strings.Contains(x, "vendor") {
return x
}
elem := strings.Split(x, "/")
for i := 0; i < len(elem)-1; i++ {
if elem[i] == "vendor" {
elem[i] = repl
}
}
return strings.Join(elem, "/")
}

71
vendor/golang.org/x/tools/go/packages/loadmode_string.go generated vendored
View File

@@ -9,49 +9,46 @@ import (
"strings"
)
var allModes = []LoadMode{
NeedName,
NeedFiles,
NeedCompiledGoFiles,
NeedImports,
NeedDeps,
NeedExportFile,
NeedTypes,
NeedSyntax,
NeedTypesInfo,
NeedTypesSizes,
var modes = [...]struct {
mode LoadMode
name string
}{
{NeedName, "NeedName"},
{NeedFiles, "NeedFiles"},
{NeedCompiledGoFiles, "NeedCompiledGoFiles"},
{NeedImports, "NeedImports"},
{NeedDeps, "NeedDeps"},
{NeedExportFile, "NeedExportFile"},
{NeedTypes, "NeedTypes"},
{NeedSyntax, "NeedSyntax"},
{NeedTypesInfo, "NeedTypesInfo"},
{NeedTypesSizes, "NeedTypesSizes"},
{NeedModule, "NeedModule"},
{NeedEmbedFiles, "NeedEmbedFiles"},
{NeedEmbedPatterns, "NeedEmbedPatterns"},
}
var modeStrings = []string{
"NeedName",
"NeedFiles",
"NeedCompiledGoFiles",
"NeedImports",
"NeedDeps",
"NeedExportFile",
"NeedTypes",
"NeedSyntax",
"NeedTypesInfo",
"NeedTypesSizes",
}
func (mod LoadMode) String() string {
m := mod
if m == 0 {
func (mode LoadMode) String() string {
if mode == 0 {
return "LoadMode(0)"
}
var out []string
for i, x := range allModes {
if x > m {
break
}
if (m & x) != 0 {
out = append(out, modeStrings[i])
m = m ^ x
// named bits
for _, item := range modes {
if (mode & item.mode) != 0 {
mode ^= item.mode
out = append(out, item.name)
}
}
if m != 0 {
out = append(out, "Unknown")
// unnamed residue
if mode != 0 {
if out == nil {
return fmt.Sprintf("LoadMode(%#x)", int(mode))
}
out = append(out, fmt.Sprintf("%#x", int(mode)))
}
return fmt.Sprintf("LoadMode(%s)", strings.Join(out, "|"))
if len(out) == 1 {
return out[0]
}
return "(" + strings.Join(out, "|") + ")"
}

499
vendor/golang.org/x/tools/go/packages/packages.go generated vendored
View File

@@ -9,6 +9,7 @@ package packages
import (
"context"
"encoding/json"
"errors"
"fmt"
"go/ast"
"go/parser"
@@ -16,7 +17,6 @@ import (
"go/token"
"go/types"
"io"
"io/ioutil"
"log"
"os"
"path/filepath"
@@ -25,20 +25,31 @@ import (
"sync"
"time"
"golang.org/x/sync/errgroup"
"golang.org/x/tools/go/gcexportdata"
"golang.org/x/tools/internal/gocommand"
"golang.org/x/tools/internal/packagesinternal"
"golang.org/x/tools/internal/typeparams"
"golang.org/x/tools/internal/typesinternal"
"golang.org/x/tools/internal/versions"
)
// A LoadMode controls the amount of detail to return when loading.
// The bits below can be combined to specify which fields should be
// filled in the result packages.
//
// The zero value is a special case, equivalent to combining
// the NeedName, NeedFiles, and NeedCompiledGoFiles bits.
//
// ID and Errors (if present) will always be filled.
// Load may return more information than requested.
// [Load] may return more information than requested.
//
// Unfortunately there are a number of open bugs related to
// interactions among the LoadMode bits:
// - https://github.com/golang/go/issues/56633
// - https://github.com/golang/go/issues/56677
// - https://github.com/golang/go/issues/58726
// - https://github.com/golang/go/issues/63517
type LoadMode int
const (
@@ -64,7 +75,7 @@ const (
// NeedTypes adds Types, Fset, and IllTyped.
NeedTypes
// NeedSyntax adds Syntax.
// NeedSyntax adds Syntax and Fset.
NeedSyntax
// NeedTypesInfo adds TypesInfo.
@@ -92,25 +103,37 @@ const (
// NeedEmbedPatterns adds EmbedPatterns.
NeedEmbedPatterns
// Be sure to update loadmode_string.go when adding new items!
)
const (
// LoadFiles loads the name and file names for the initial packages.
//
// Deprecated: LoadFiles exists for historical compatibility
// and should not be used. Please directly specify the needed fields using the Need values.
LoadFiles = NeedName | NeedFiles | NeedCompiledGoFiles
// LoadImports loads the name, file names, and import mapping for the initial packages.
//
// Deprecated: LoadImports exists for historical compatibility
// and should not be used. Please directly specify the needed fields using the Need values.
LoadImports = LoadFiles | NeedImports
// LoadTypes loads exported type information for the initial packages.
//
// Deprecated: LoadTypes exists for historical compatibility
// and should not be used. Please directly specify the needed fields using the Need values.
LoadTypes = LoadImports | NeedTypes | NeedTypesSizes
// LoadSyntax loads typed syntax for the initial packages.
//
// Deprecated: LoadSyntax exists for historical compatibility
// and should not be used. Please directly specify the needed fields using the Need values.
LoadSyntax = LoadTypes | NeedSyntax | NeedTypesInfo
// LoadAllSyntax loads typed syntax for the initial packages and all dependencies.
//
// Deprecated: LoadAllSyntax exists for historical compatibility
// and should not be used. Please directly specify the needed fields using the Need values.
LoadAllSyntax = LoadSyntax | NeedDeps
@@ -121,15 +144,21 @@ const (
// A Config specifies details about how packages should be loaded.
// The zero value is a valid configuration.
//
// Calls to Load do not modify this struct.
//
// TODO(adonovan): #67702: this is currently false: in fact,
// calls to [Load] do not modify the public fields of this struct, but
// may modify hidden fields, so concurrent calls to [Load] must not
// use the same Config. But perhaps we should reestablish the
// documented invariant.
type Config struct {
// Mode controls the level of information returned for each package.
Mode LoadMode
// Context specifies the context for the load operation.
// If the context is cancelled, the loader may stop early
// and return an ErrCancelled error.
// If Context is nil, the load cannot be cancelled.
// Cancelling the context may cause [Load] to abort and
// return an error.
Context context.Context
// Logf is the logger for the config.
@@ -198,93 +227,209 @@ type Config struct {
// setting Tests may have no effect.
Tests bool
// Overlay provides a mapping of absolute file paths to file contents.
// If the file with the given path already exists, the parser will use the
// alternative file contents provided by the map.
// Overlay is a mapping from absolute file paths to file contents.
//
// Overlays provide incomplete support for when a given file doesn't
// already exist on disk. See the package doc above for more details.
// For each map entry, [Load] uses the alternative file
// contents provided by the overlay mapping instead of reading
// from the file system. This mechanism can be used to enable
// editor-integrated tools to correctly analyze the contents
// of modified but unsaved buffers, for example.
//
// The overlay mapping is passed to the build system's driver
// (see "The driver protocol") so that it too can report
// consistent package metadata about unsaved files. However,
// drivers may vary in their level of support for overlays.
Overlay map[string][]byte
}
// driver is the type for functions that query the build system for the
// packages named by the patterns.
type driver func(cfg *Config, patterns ...string) (*driverResponse, error)
// driverResponse contains the results for a driver query.
type driverResponse struct {
// NotHandled is returned if the request can't be handled by the current
// driver. If an external driver returns a response with NotHandled, the
// rest of the driverResponse is ignored, and go/packages will fallback
// to the next driver. If go/packages is extended in the future to support
// lists of multiple drivers, go/packages will fall back to the next driver.
NotHandled bool
// Sizes, if not nil, is the types.Sizes to use when type checking.
Sizes *types.StdSizes
// Roots is the set of package IDs that make up the root packages.
// We have to encode this separately because when we encode a single package
// we cannot know if it is one of the roots as that requires knowledge of the
// graph it is part of.
Roots []string `json:",omitempty"`
// Packages is the full set of packages in the graph.
// The packages are not connected into a graph.
// The Imports if populated will be stubs that only have their ID set.
// Imports will be connected and then type and syntax information added in a
// later pass (see refine).
Packages []*Package
// GoVersion is the minor version number used by the driver
// (e.g. the go command on the PATH) when selecting .go files.
// Zero means unknown.
GoVersion int
// goListOverlayFile is the JSON file that encodes the Overlay
// mapping, used by 'go list -overlay=...'
goListOverlayFile string
}
// Load loads and returns the Go packages named by the given patterns.
//
// Config specifies loading options;
// nil behaves the same as an empty Config.
// The cfg parameter specifies loading options; nil behaves the same as an empty [Config].
//
// Load returns an error if any of the patterns was invalid
// as defined by the underlying build system.
// The [Config.Mode] field is a set of bits that determine what kinds
// of information should be computed and returned. Modes that require
// more information tend to be slower. See [LoadMode] for details
// and important caveats. Its zero value is equivalent to
// [NeedName] | [NeedFiles] | [NeedCompiledGoFiles].
//
// Each call to Load returns a new set of [Package] instances.
// The Packages and their Imports form a directed acyclic graph.
//
// If the [NeedTypes] mode flag was set, each call to Load uses a new
// [types.Importer], so [types.Object] and [types.Type] values from
// different calls to Load must not be mixed as they will have
// inconsistent notions of type identity.
//
// If any of the patterns was invalid as defined by the
// underlying build system, Load returns an error.
// It may return an empty list of packages without an error,
// for instance for an empty expansion of a valid wildcard.
// Errors associated with a particular package are recorded in the
// corresponding Package's Errors list, and do not cause Load to
// return an error. Clients may need to handle such errors before
// proceeding with further analysis. The PrintErrors function is
// proceeding with further analysis. The [PrintErrors] function is
// provided for convenient display of all errors.
func Load(cfg *Config, patterns ...string) ([]*Package, error) {
l := newLoader(cfg)
response, err := defaultDriver(&l.Config, patterns...)
ld := newLoader(cfg)
response, external, err := defaultDriver(&ld.Config, patterns...)
if err != nil {
return nil, err
}
l.sizes = response.Sizes
return l.refine(response)
ld.sizes = types.SizesFor(response.Compiler, response.Arch)
if ld.sizes == nil && ld.Config.Mode&(NeedTypes|NeedTypesSizes|NeedTypesInfo) != 0 {
// Type size information is needed but unavailable.
if external {
// An external driver may fail to populate the Compiler/GOARCH fields,
// especially since they are relatively new (see #63700).
// Provide a sensible fallback in this case.
ld.sizes = types.SizesFor("gc", runtime.GOARCH)
if ld.sizes == nil { // gccgo-only arch
ld.sizes = types.SizesFor("gc", "amd64")
}
} else {
// Go list should never fail to deliver accurate size information.
// Reject the whole Load since the error is the same for every package.
return nil, fmt.Errorf("can't determine type sizes for compiler %q on GOARCH %q",
response.Compiler, response.Arch)
}
}
return ld.refine(response)
}
// defaultDriver is a driver that implements go/packages' fallback behavior.
// It will try to request to an external driver, if one exists. If there's
// no external driver, or the driver returns a response with NotHandled set,
// defaultDriver will fall back to the go list driver.
func defaultDriver(cfg *Config, patterns ...string) (*driverResponse, error) {
driver := findExternalDriver(cfg)
if driver == nil {
driver = goListDriver
}
response, err := driver(cfg, patterns...)
// The boolean result indicates that an external driver handled the request.
func defaultDriver(cfg *Config, patterns ...string) (*DriverResponse, bool, error) {
const (
// windowsArgMax specifies the maximum command line length for
// the Windows' CreateProcess function.
windowsArgMax = 32767
// maxEnvSize is a very rough estimation of the maximum environment
// size of a user.
maxEnvSize = 16384
// safeArgMax specifies the maximum safe command line length to use
// by the underlying driver excl. the environment. We choose the Windows'
// ARG_MAX as the starting point because it's one of the lowest ARG_MAX
// constants out of the different supported platforms,
// e.g., https://www.in-ulm.de/~mascheck/various/argmax/#results.
safeArgMax = windowsArgMax - maxEnvSize
)
chunks, err := splitIntoChunks(patterns, safeArgMax)
if err != nil {
return response, err
} else if response.NotHandled {
return goListDriver(cfg, patterns...)
return nil, false, err
}
return response, nil
if driver := findExternalDriver(cfg); driver != nil {
response, err := callDriverOnChunks(driver, cfg, chunks)
if err != nil {
return nil, false, err
} else if !response.NotHandled {
return response, true, nil
}
// (fall through)
}
// go list fallback
//
// Write overlays once, as there are many calls
// to 'go list' (one per chunk plus others too).
overlay, cleanupOverlay, err := gocommand.WriteOverlays(cfg.Overlay)
if err != nil {
return nil, false, err
}
defer cleanupOverlay()
cfg.goListOverlayFile = overlay
response, err := callDriverOnChunks(goListDriver, cfg, chunks)
if err != nil {
return nil, false, err
}
return response, false, err
}
// splitIntoChunks chunks the slice so that the total number of characters
// in a chunk is no longer than argMax.
func splitIntoChunks(patterns []string, argMax int) ([][]string, error) {
if argMax <= 0 {
return nil, errors.New("failed to split patterns into chunks, negative safe argMax value")
}
var chunks [][]string
charsInChunk := 0
nextChunkStart := 0
for i, v := range patterns {
vChars := len(v)
if vChars > argMax {
// a single pattern is longer than the maximum safe ARG_MAX, hardly should happen
return nil, errors.New("failed to split patterns into chunks, a pattern is too long")
}
charsInChunk += vChars + 1 // +1 is for a whitespace between patterns that has to be counted too
if charsInChunk > argMax {
chunks = append(chunks, patterns[nextChunkStart:i])
nextChunkStart = i
charsInChunk = vChars
}
}
// add the last chunk
if nextChunkStart < len(patterns) {
chunks = append(chunks, patterns[nextChunkStart:])
}
return chunks, nil
}
func callDriverOnChunks(driver driver, cfg *Config, chunks [][]string) (*DriverResponse, error) {
if len(chunks) == 0 {
return driver(cfg)
}
responses := make([]*DriverResponse, len(chunks))
errNotHandled := errors.New("driver returned NotHandled")
var g errgroup.Group
for i, chunk := range chunks {
i := i
chunk := chunk
g.Go(func() (err error) {
responses[i], err = driver(cfg, chunk...)
if responses[i] != nil && responses[i].NotHandled {
err = errNotHandled
}
return err
})
}
if err := g.Wait(); err != nil {
if errors.Is(err, errNotHandled) {
return &DriverResponse{NotHandled: true}, nil
}
return nil, err
}
return mergeResponses(responses...), nil
}
func mergeResponses(responses ...*DriverResponse) *DriverResponse {
if len(responses) == 0 {
return nil
}
response := newDeduper()
response.dr.NotHandled = false
response.dr.Compiler = responses[0].Compiler
response.dr.Arch = responses[0].Arch
response.dr.GoVersion = responses[0].GoVersion
for _, v := range responses {
response.addAll(v)
}
return response.dr
}
// A Package describes a loaded Go package.
//
// It also defines part of the JSON schema of [DriverResponse].
// See the package documentation for an overview.
type Package struct {
// ID is a unique identifier for a package,
// in a syntax provided by the underlying build system.
@@ -308,6 +453,9 @@ type Package struct {
TypeErrors []types.Error
// GoFiles lists the absolute file paths of the package's Go source files.
// It may include files that should not be compiled, for example because
// they contain non-matching build tags, are documentary pseudo-files such as
// unsafe/unsafe.go or builtin/builtin.go, or are subject to cgo preprocessing.
GoFiles []string
// CompiledGoFiles lists the absolute file paths of the package's source
@@ -340,19 +488,30 @@ type Package struct {
// to corresponding loaded Packages.
Imports map[string]*Package
// Module is the module information for the package if it exists.
//
// Note: it may be missing for std and cmd; see Go issue #65816.
Module *Module
// -- The following fields are not part of the driver JSON schema. --
// Types provides type information for the package.
// The NeedTypes LoadMode bit sets this field for packages matching the
// patterns; type information for dependencies may be missing or incomplete,
// unless NeedDeps and NeedImports are also set.
Types *types.Package
//
// Each call to [Load] returns a consistent set of type
// symbols, as defined by the comment at [types.Identical].
// Avoid mixing type information from two or more calls to [Load].
Types *types.Package `json:"-"`
// Fset provides position information for Types, TypesInfo, and Syntax.
// It is set only when Types is set.
Fset *token.FileSet
Fset *token.FileSet `json:"-"`
// IllTyped indicates whether the package or any dependency contains errors.
// It is set only when Types is set.
IllTyped bool
IllTyped bool `json:"-"`
// Syntax is the package's syntax trees, for the files listed in CompiledGoFiles.
//
@@ -362,26 +521,28 @@ type Package struct {
//
// Syntax is kept in the same order as CompiledGoFiles, with the caveat that nils are
// removed. If parsing returned nil, Syntax may be shorter than CompiledGoFiles.
Syntax []*ast.File
Syntax []*ast.File `json:"-"`
// TypesInfo provides type information about the package's syntax trees.
// It is set only when Syntax is set.
TypesInfo *types.Info
TypesInfo *types.Info `json:"-"`
// TypesSizes provides the effective size function for types in TypesInfo.
TypesSizes types.Sizes
TypesSizes types.Sizes `json:"-"`
// -- internal --
// forTest is the package under test, if any.
forTest string
// depsErrors is the DepsErrors field from the go list response, if any.
depsErrors []*packagesinternal.PackageError
// module is the module information for the package if it exists.
Module *Module
}
// Module provides module information for a package.
//
// It also defines part of the JSON schema of [DriverResponse].
// See the package documentation for an overview.
type Module struct {
Path string // module path
Version string // module version
@@ -407,12 +568,6 @@ func init() {
packagesinternal.GetDepsErrors = func(p interface{}) []*packagesinternal.PackageError {
return p.(*Package).depsErrors
}
packagesinternal.GetGoCmdRunner = func(config interface{}) *gocommand.Runner {
return config.(*Config).gocmdRunner
}
packagesinternal.SetGoCmdRunner = func(config interface{}, runner *gocommand.Runner) {
config.(*Config).gocmdRunner = runner
}
packagesinternal.SetModFile = func(config interface{}, value string) {
config.(*Config).modFile = value
}
@@ -520,6 +675,7 @@ func (p *Package) UnmarshalJSON(b []byte) error {
OtherFiles: flat.OtherFiles,
EmbedFiles: flat.EmbedFiles,
EmbedPatterns: flat.EmbedPatterns,
IgnoredFiles: flat.IgnoredFiles,
ExportFile: flat.ExportFile,
}
if len(flat.Imports) > 0 {
@@ -549,7 +705,7 @@ type loaderPackage struct {
type loader struct {
pkgs map[string]*loaderPackage
Config
sizes types.Sizes
sizes types.Sizes // non-nil if needed by mode
parseCache map[string]*parseValue
parseCacheMu sync.Mutex
exportMu sync.Mutex // enforces mutual exclusion of exportdata operations
@@ -618,6 +774,7 @@ func newLoader(cfg *Config) *loader {
// because we load source if export data is missing.
if ld.ParseFile == nil {
ld.ParseFile = func(fset *token.FileSet, filename string, src []byte) (*ast.File, error) {
// We implicitly promise to keep doing ast.Object resolution. :(
const mode = parser.AllErrors | parser.ParseComments
return parser.ParseFile(fset, filename, src, mode)
}
@@ -627,9 +784,9 @@ func newLoader(cfg *Config) *loader {
return ld
}
// refine connects the supplied packages into a graph and then adds type and
// refine connects the supplied packages into a graph and then adds type
// and syntax information as requested by the LoadMode.
func (ld *loader) refine(response *driverResponse) ([]*Package, error) {
func (ld *loader) refine(response *DriverResponse) ([]*Package, error) {
roots := response.Roots
rootMap := make(map[string]int, len(roots))
for i, root := range roots {
@@ -674,39 +831,38 @@ func (ld *loader) refine(response *driverResponse) ([]*Package, error) {
}
}
// Materialize the import graph.
if ld.Mode&NeedImports != 0 {
// Materialize the import graph.
const (
white = 0 // new
grey = 1 // in progress
black = 2 // complete
)
const (
white = 0 // new
grey = 1 // in progress
black = 2 // complete
)
// visit traverses the import graph, depth-first,
// and materializes the graph as Packages.Imports.
//
// Valid imports are saved in the Packages.Import map.
// Invalid imports (cycles and missing nodes) are saved in the importErrors map.
// Thus, even in the presence of both kinds of errors, the Import graph remains a DAG.
//
// visit returns whether the package needs src or has a transitive
// dependency on a package that does. These are the only packages
// for which we load source code.
var stack []*loaderPackage
var visit func(lpkg *loaderPackage) bool
var srcPkgs []*loaderPackage
visit = func(lpkg *loaderPackage) bool {
switch lpkg.color {
case black:
return lpkg.needsrc
case grey:
panic("internal error: grey node")
}
lpkg.color = grey
stack = append(stack, lpkg) // push
stubs := lpkg.Imports // the structure form has only stubs with the ID in the Imports
// If NeedImports isn't set, the imports fields will all be zeroed out.
if ld.Mode&NeedImports != 0 {
// visit traverses the import graph, depth-first,
// and materializes the graph as Packages.Imports.
//
// Valid imports are saved in the Packages.Import map.
// Invalid imports (cycles and missing nodes) are saved in the importErrors map.
// Thus, even in the presence of both kinds of errors,
// the Import graph remains a DAG.
//
// visit returns whether the package needs src or has a transitive
// dependency on a package that does. These are the only packages
// for which we load source code.
var stack []*loaderPackage
var visit func(lpkg *loaderPackage) bool
visit = func(lpkg *loaderPackage) bool {
switch lpkg.color {
case black:
return lpkg.needsrc
case grey:
panic("internal error: grey node")
}
lpkg.color = grey
stack = append(stack, lpkg) // push
stubs := lpkg.Imports // the structure form has only stubs with the ID in the Imports
lpkg.Imports = make(map[string]*Package, len(stubs))
for importPath, ipkg := range stubs {
var importErr error
@@ -730,40 +886,39 @@ func (ld *loader) refine(response *driverResponse) ([]*Package, error) {
}
lpkg.Imports[importPath] = imp.Package
}
}
if lpkg.needsrc {
srcPkgs = append(srcPkgs, lpkg)
}
if ld.Mode&NeedTypesSizes != 0 {
lpkg.TypesSizes = ld.sizes
}
stack = stack[:len(stack)-1] // pop
lpkg.color = black
return lpkg.needsrc
}
// Complete type information is required for the
// immediate dependencies of each source package.
if lpkg.needsrc && ld.Mode&NeedTypes != 0 {
for _, ipkg := range lpkg.Imports {
ld.pkgs[ipkg.ID].needtypes = true
}
}
if ld.Mode&NeedImports == 0 {
// We do this to drop the stub import packages that we are not even going to try to resolve.
for _, lpkg := range initial {
lpkg.Imports = nil
// NeedTypeSizes causes TypeSizes to be set even
// on packages for which types aren't needed.
if ld.Mode&NeedTypesSizes != 0 {
lpkg.TypesSizes = ld.sizes
}
stack = stack[:len(stack)-1] // pop
lpkg.color = black
return lpkg.needsrc
}
} else {
// For each initial package, create its import DAG.
for _, lpkg := range initial {
visit(lpkg)
}
}
if ld.Mode&NeedImports != 0 && ld.Mode&NeedTypes != 0 {
for _, lpkg := range srcPkgs {
// Complete type information is required for the
// immediate dependencies of each source package.
for _, ipkg := range lpkg.Imports {
imp := ld.pkgs[ipkg.ID]
imp.needtypes = true
}
} else {
// !NeedImports: drop the stub (ID-only) import packages
// that we are not even going to try to resolve.
for _, lpkg := range initial {
lpkg.Imports = nil
}
}
// Load type data and syntax if needed, starting at
// the initial packages (roots of the import DAG).
if ld.Mode&NeedTypes != 0 || ld.Mode&NeedSyntax != 0 {
@@ -778,6 +933,12 @@ func (ld *loader) refine(response *driverResponse) ([]*Package, error) {
wg.Wait()
}
// If the context is done, return its error and
// throw out [likely] incomplete packages.
if err := ld.Context.Err(); err != nil {
return nil, err
}
result := make([]*Package, len(initial))
for i, lpkg := range initial {
result[i] = lpkg.Package
@@ -811,12 +972,14 @@ func (ld *loader) refine(response *driverResponse) ([]*Package, error) {
}
if ld.requestedMode&NeedTypes == 0 {
ld.pkgs[i].Types = nil
ld.pkgs[i].Fset = nil
ld.pkgs[i].IllTyped = false
}
if ld.requestedMode&NeedSyntax == 0 {
ld.pkgs[i].Syntax = nil
}
if ld.requestedMode&NeedTypes == 0 && ld.requestedMode&NeedSyntax == 0 {
ld.pkgs[i].Fset = nil
}
if ld.requestedMode&NeedTypesInfo == 0 {
ld.pkgs[i].TypesInfo = nil
}
@@ -873,6 +1036,14 @@ func (ld *loader) loadPackage(lpkg *loaderPackage) {
lpkg.Types = types.NewPackage(lpkg.PkgPath, lpkg.Name)
lpkg.Fset = ld.Fset
// Start shutting down if the context is done and do not load
// source or export data files.
// Packages that import this one will have ld.Context.Err() != nil.
// ld.Context.Err() will be returned later by refine.
if ld.Context.Err() != nil {
return
}
// Subtle: we populate all Types fields with an empty Package
// before loading export data so that export data processing
// never has to create a types.Package for an indirect dependency,
@@ -992,15 +1163,23 @@ func (ld *loader) loadPackage(lpkg *loaderPackage) {
return
}
// Start shutting down if the context is done and do not type check.
// Packages that import this one will have ld.Context.Err() != nil.
// ld.Context.Err() will be returned later by refine.
if ld.Context.Err() != nil {
return
}
lpkg.TypesInfo = &types.Info{
Types: make(map[ast.Expr]types.TypeAndValue),
Defs: make(map[*ast.Ident]types.Object),
Uses: make(map[*ast.Ident]types.Object),
Implicits: make(map[ast.Node]types.Object),
Instances: make(map[*ast.Ident]types.Instance),
Scopes: make(map[ast.Node]*types.Scope),
Selections: make(map[*ast.SelectorExpr]*types.Selection),
}
typeparams.InitInstanceInfo(lpkg.TypesInfo)
versions.InitFileVersions(lpkg.TypesInfo)
lpkg.TypesSizes = ld.sizes
importer := importerFunc(func(path string) (*types.Package, error) {
@@ -1038,7 +1217,10 @@ func (ld *loader) loadPackage(lpkg *loaderPackage) {
IgnoreFuncBodies: ld.Mode&NeedDeps == 0 && !lpkg.initial,
Error: appendError,
Sizes: ld.sizes,
Sizes: ld.sizes, // may be nil
}
if lpkg.Module != nil && lpkg.Module.GoVersion != "" {
tc.GoVersion = "go" + lpkg.Module.GoVersion
}
if (ld.Mode & typecheckCgo) != 0 {
if !typesinternal.SetUsesCgo(tc) {
@@ -1049,10 +1231,24 @@ func (ld *loader) loadPackage(lpkg *loaderPackage) {
return
}
}
types.NewChecker(tc, ld.Fset, lpkg.Types, lpkg.TypesInfo).Files(lpkg.Syntax)
typErr := types.NewChecker(tc, ld.Fset, lpkg.Types, lpkg.TypesInfo).Files(lpkg.Syntax)
lpkg.importErrors = nil // no longer needed
// In go/types go1.21 and go1.22, Checker.Files failed fast with a
// a "too new" error, without calling tc.Error and without
// proceeding to type-check the package (#66525).
// We rely on the runtimeVersion error to give the suggested remedy.
if typErr != nil && len(lpkg.Errors) == 0 && len(lpkg.Syntax) > 0 {
if msg := typErr.Error(); strings.HasPrefix(msg, "package requires newer Go version") {
appendError(types.Error{
Fset: ld.Fset,
Pos: lpkg.Syntax[0].Package,
Msg: msg,
})
}
}
// If !Cgo, the type-checker uses FakeImportC mode, so
// it doesn't invoke the importer for import "C",
// nor report an error for the import,
@@ -1074,6 +1270,12 @@ func (ld *loader) loadPackage(lpkg *loaderPackage) {
}
}
// If types.Checker.Files had an error that was unreported,
// make sure to report the unknown error so the package is illTyped.
if typErr != nil && len(lpkg.Errors) == 0 {
appendError(typErr)
}
// Record accumulated errors.
illTyped := len(lpkg.Errors) > 0
if !illTyped {
@@ -1119,7 +1321,7 @@ func (ld *loader) parseFile(filename string) (*ast.File, error) {
var err error
if src == nil {
ioLimit <- true // wait
src, err = ioutil.ReadFile(filename)
src, err = os.ReadFile(filename)
<-ioLimit // signal
}
if err != nil {
@@ -1145,11 +1347,6 @@ func (ld *loader) parseFiles(filenames []string) ([]*ast.File, []error) {
parsed := make([]*ast.File, n)
errors := make([]error, n)
for i, file := range filenames {
if ld.Config.Context.Err() != nil {
parsed[i] = nil
errors[i] = ld.Config.Context.Err()
continue
}
wg.Add(1)
go func(i int, filename string) {
parsed[i], errors[i] = ld.parseFile(filename)
@@ -1315,6 +1512,10 @@ func impliedLoadMode(loadMode LoadMode) LoadMode {
// All these things require knowing the import graph.
loadMode |= NeedImports
}
if loadMode&NeedTypes != 0 {
// Types require the GoVersion from Module.
loadMode |= NeedModule
}
return loadMode
}

9
vendor/golang.org/x/tools/go/packages/visit.go generated vendored
View File

@@ -49,11 +49,20 @@ func Visit(pkgs []*Package, pre func(*Package) bool, post func(*Package)) {
// PrintErrors returns the number of errors printed.
func PrintErrors(pkgs []*Package) int {
var n int
errModules := make(map[*Module]bool)
Visit(pkgs, nil, func(pkg *Package) {
for _, err := range pkg.Errors {
fmt.Fprintln(os.Stderr, err)
n++
}
// Print pkg.Module.Error once if present.
mod := pkg.Module
if mod != nil && mod.Error != nil && !errModules[mod] {
errModules[mod] = true
fmt.Fprintln(os.Stderr, mod.Error.Err)
n++
}
})
return n
}

788
vendor/golang.org/x/tools/go/types/objectpath/objectpath.go generated vendored Normal file
View File

@@ -0,0 +1,788 @@
// 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 objectpath defines a naming scheme for types.Objects
// (that is, named entities in Go programs) relative to their enclosing
// package.
//
// Type-checker objects are canonical, so they are usually identified by
// their address in memory (a pointer), but a pointer has meaning only
// within one address space. By contrast, objectpath names allow the
// identity of an object to be sent from one program to another,
// establishing a correspondence between types.Object variables that are
// distinct but logically equivalent.
//
// A single object may have multiple paths. In this example,
//
// type A struct{ X int }
// type B A
//
// the field X has two paths due to its membership of both A and B.
// The For(obj) function always returns one of these paths, arbitrarily
// but consistently.
package objectpath
import (
"fmt"
"go/types"
"strconv"
"strings"
"golang.org/x/tools/internal/aliases"
"golang.org/x/tools/internal/typesinternal"
)
// TODO(adonovan): think about generic aliases.
// A Path is an opaque name that identifies a types.Object
// relative to its package. Conceptually, the name consists of a
// sequence of destructuring operations applied to the package scope
// to obtain the original object.
// The name does not include the package itself.
type Path string
// Encoding
//
// An object path is a textual and (with training) human-readable encoding
// of a sequence of destructuring operators, starting from a types.Package.
// The sequences represent a path through the package/object/type graph.
// We classify these operators by their type:
//
// PO package->object Package.Scope.Lookup
// OT object->type Object.Type
// TT type->type Type.{Elem,Key,{,{,Recv}Type}Params,Results,Underlying,Rhs} [EKPRUTrCa]
// TO type->object Type.{At,Field,Method,Obj} [AFMO]
//
// All valid paths start with a package and end at an object
// and thus may be defined by the regular language:
//
// objectpath = PO (OT TT* TO)*
//
// The concrete encoding follows directly:
// - The only PO operator is Package.Scope.Lookup, which requires an identifier.
// - The only OT operator is Object.Type,
// which we encode as '.' because dot cannot appear in an identifier.
// - The TT operators are encoded as [EKPRUTrCa];
// two of these ({,Recv}TypeParams) require an integer operand,
// which is encoded as a string of decimal digits.
// - The TO operators are encoded as [AFMO];
// three of these (At,Field,Method) require an integer operand,
// which is encoded as a string of decimal digits.
// These indices are stable across different representations
// of the same package, even source and export data.
// The indices used are implementation specific and may not correspond to
// the argument to the go/types function.
//
// In the example below,
//
// package p
//
// type T interface {
// f() (a string, b struct{ X int })
// }
//
// field X has the path "T.UM0.RA1.F0",
// representing the following sequence of operations:
//
// p.Lookup("T") T
// .Type().Underlying().Method(0). f
// .Type().Results().At(1) b
// .Type().Field(0) X
//
// The encoding is not maximally compact---every R or P is
// followed by an A, for example---but this simplifies the
// encoder and decoder.
const (
// object->type operators
opType = '.' // .Type() (Object)
// type->type operators
opElem = 'E' // .Elem() (Pointer, Slice, Array, Chan, Map)
opKey = 'K' // .Key() (Map)
opParams = 'P' // .Params() (Signature)
opResults = 'R' // .Results() (Signature)
opUnderlying = 'U' // .Underlying() (Named)
opTypeParam = 'T' // .TypeParams.At(i) (Named, Signature)
opRecvTypeParam = 'r' // .RecvTypeParams.At(i) (Signature)
opConstraint = 'C' // .Constraint() (TypeParam)
opRhs = 'a' // .Rhs() (Alias)
// type->object operators
opAt = 'A' // .At(i) (Tuple)
opField = 'F' // .Field(i) (Struct)
opMethod = 'M' // .Method(i) (Named or Interface; not Struct: "promoted" names are ignored)
opObj = 'O' // .Obj() (Named, TypeParam)
)
// For is equivalent to new(Encoder).For(obj).
//
// It may be more efficient to reuse a single Encoder across several calls.
func For(obj types.Object) (Path, error) {
return new(Encoder).For(obj)
}
// An Encoder amortizes the cost of encoding the paths of multiple objects.
// The zero value of an Encoder is ready to use.
type Encoder struct {
scopeMemo map[*types.Scope][]types.Object // memoization of scopeObjects
}
// For returns the path to an object relative to its package,
// or an error if the object is not accessible from the package's Scope.
//
// The For function guarantees to return a path only for the following objects:
// - package-level types
// - exported package-level non-types
// - methods
// - parameter and result variables
// - struct fields
// These objects are sufficient to define the API of their package.
// The objects described by a package's export data are drawn from this set.
//
// The set of objects accessible from a package's Scope depends on
// whether the package was produced by type-checking syntax, or
// reading export data; the latter may have a smaller Scope since
// export data trims objects that are not reachable from an exported
// declaration. For example, the For function will return a path for
// an exported method of an unexported type that is not reachable
// from any public declaration; this path will cause the Object
// function to fail if called on a package loaded from export data.
// TODO(adonovan): is this a bug or feature? Should this package
// compute accessibility in the same way?
//
// For does not return a path for predeclared names, imported package
// names, local names, and unexported package-level names (except
// types).
//
// Example: given this definition,
//
// package p
//
// type T interface {
// f() (a string, b struct{ X int })
// }
//
// For(X) would return a path that denotes the following sequence of operations:
//
// p.Scope().Lookup("T") (TypeName T)
// .Type().Underlying().Method(0). (method Func f)
// .Type().Results().At(1) (field Var b)
// .Type().Field(0) (field Var X)
//
// where p is the package (*types.Package) to which X belongs.
func (enc *Encoder) For(obj types.Object) (Path, error) {
pkg := obj.Pkg()
// This table lists the cases of interest.
//
// Object Action
// ------ ------
// nil reject
// builtin reject
// pkgname reject
// label reject
// var
// package-level accept
// func param/result accept
// local reject
// struct field accept
// const
// package-level accept
// local reject
// func
// package-level accept
// init functions reject
// concrete method accept
// interface method accept
// type
// package-level accept
// local reject
//
// The only accessible package-level objects are members of pkg itself.
//
// The cases are handled in four steps:
//
// 1. reject nil and builtin
// 2. accept package-level objects
// 3. reject obviously invalid objects
// 4. search the API for the path to the param/result/field/method.
// 1. reference to nil or builtin?
if pkg == nil {
return "", fmt.Errorf("predeclared %s has no path", obj)
}
scope := pkg.Scope()
// 2. package-level object?
if scope.Lookup(obj.Name()) == obj {
// Only exported objects (and non-exported types) have a path.
// Non-exported types may be referenced by other objects.
if _, ok := obj.(*types.TypeName); !ok && !obj.Exported() {
return "", fmt.Errorf("no path for non-exported %v", obj)
}
return Path(obj.Name()), nil
}
// 3. Not a package-level object.
// Reject obviously non-viable cases.
switch obj := obj.(type) {
case *types.TypeName:
if _, ok := types.Unalias(obj.Type()).(*types.TypeParam); !ok {
// With the exception of type parameters, only package-level type names
// have a path.
return "", fmt.Errorf("no path for %v", obj)
}
case *types.Const, // Only package-level constants have a path.
*types.Label, // Labels are function-local.
*types.PkgName: // PkgNames are file-local.
return "", fmt.Errorf("no path for %v", obj)
case *types.Var:
// Could be:
// - a field (obj.IsField())
// - a func parameter or result
// - a local var.
// Sadly there is no way to distinguish
// a param/result from a local
// so we must proceed to the find.
case *types.Func:
// A func, if not package-level, must be a method.
if recv := obj.Type().(*types.Signature).Recv(); recv == nil {
return "", fmt.Errorf("func is not a method: %v", obj)
}
if path, ok := enc.concreteMethod(obj); ok {
// Fast path for concrete methods that avoids looping over scope.
return path, nil
}
default:
panic(obj)
}
// 4. Search the API for the path to the var (field/param/result) or method.
// First inspect package-level named types.
// In the presence of path aliases, these give
// the best paths because non-types may
// refer to types, but not the reverse.
empty := make([]byte, 0, 48) // initial space
objs := enc.scopeObjects(scope)
for _, o := range objs {
tname, ok := o.(*types.TypeName)
if !ok {
continue // handle non-types in second pass
}
path := append(empty, o.Name()...)
path = append(path, opType)
T := o.Type()
if alias, ok := T.(*types.Alias); ok {
if r := findTypeParam(obj, aliases.TypeParams(alias), path, opTypeParam, nil); r != nil {
return Path(r), nil
}
if r := find(obj, aliases.Rhs(alias), append(path, opRhs), nil); r != nil {
return Path(r), nil
}
} else if tname.IsAlias() {
// legacy alias
if r := find(obj, T, path, nil); r != nil {
return Path(r), nil
}
} else if named, ok := T.(*types.Named); ok {
// defined (named) type
if r := findTypeParam(obj, named.TypeParams(), path, opTypeParam, nil); r != nil {
return Path(r), nil
}
if r := find(obj, named.Underlying(), append(path, opUnderlying), nil); r != nil {
return Path(r), nil
}
}
}
// Then inspect everything else:
// non-types, and declared methods of defined types.
for _, o := range objs {
path := append(empty, o.Name()...)
if _, ok := o.(*types.TypeName); !ok {
if o.Exported() {
// exported non-type (const, var, func)
if r := find(obj, o.Type(), append(path, opType), nil); r != nil {
return Path(r), nil
}
}
continue
}
// Inspect declared methods of defined types.
if T, ok := types.Unalias(o.Type()).(*types.Named); ok {
path = append(path, opType)
// The method index here is always with respect
// to the underlying go/types data structures,
// which ultimately derives from source order
// and must be preserved by export data.
for i := 0; i < T.NumMethods(); i++ {
m := T.Method(i)
path2 := appendOpArg(path, opMethod, i)
if m == obj {
return Path(path2), nil // found declared method
}
if r := find(obj, m.Type(), append(path2, opType), nil); r != nil {
return Path(r), nil
}
}
}
}
return "", fmt.Errorf("can't find path for %v in %s", obj, pkg.Path())
}
func appendOpArg(path []byte, op byte, arg int) []byte {
path = append(path, op)
path = strconv.AppendInt(path, int64(arg), 10)
return path
}
// concreteMethod returns the path for meth, which must have a non-nil receiver.
// The second return value indicates success and may be false if the method is
// an interface method or if it is an instantiated method.
//
// This function is just an optimization that avoids the general scope walking
// approach. You are expected to fall back to the general approach if this
// function fails.
func (enc *Encoder) concreteMethod(meth *types.Func) (Path, bool) {
// Concrete methods can only be declared on package-scoped named types. For
// that reason we can skip the expensive walk over the package scope: the
// path will always be package -> named type -> method. We can trivially get
// the type name from the receiver, and only have to look over the type's
// methods to find the method index.
//
// Methods on generic types require special consideration, however. Consider
// the following package:
//
// L1: type S[T any] struct{}
// L2: func (recv S[A]) Foo() { recv.Bar() }
// L3: func (recv S[B]) Bar() { }
// L4: type Alias = S[int]
// L5: func _[T any]() { var s S[int]; s.Foo() }
//
// The receivers of methods on generic types are instantiations. L2 and L3
// instantiate S with the type-parameters A and B, which are scoped to the
// respective methods. L4 and L5 each instantiate S with int. Each of these
// instantiations has its own method set, full of methods (and thus objects)
// with receivers whose types are the respective instantiations. In other
// words, we have
//
// S[A].Foo, S[A].Bar
// S[B].Foo, S[B].Bar
// S[int].Foo, S[int].Bar
//
// We may thus be trying to produce object paths for any of these objects.
//
// S[A].Foo and S[B].Bar are the origin methods, and their paths are S.Foo
// and S.Bar, which are the paths that this function naturally produces.
//
// S[A].Bar, S[B].Foo, and both methods on S[int] are instantiations that
// don't correspond to the origin methods. For S[int], this is significant.
// The most precise object path for S[int].Foo, for example, is Alias.Foo,
// not S.Foo. Our function, however, would produce S.Foo, which would
// resolve to a different object.
//
// For S[A].Bar and S[B].Foo it could be argued that S.Bar and S.Foo are
// still the correct paths, since only the origin methods have meaningful
// paths. But this is likely only true for trivial cases and has edge cases.
// Since this function is only an optimization, we err on the side of giving
// up, deferring to the slower but definitely correct algorithm. Most users
// of objectpath will only be giving us origin methods, anyway, as referring
// to instantiated methods is usually not useful.
if meth.Origin() != meth {
return "", false
}
_, named := typesinternal.ReceiverNamed(meth.Type().(*types.Signature).Recv())
if named == nil {
return "", false
}
if types.IsInterface(named) {
// Named interfaces don't have to be package-scoped
//
// TODO(dominikh): opt: if scope.Lookup(name) == named, then we can apply this optimization to interface
// methods, too, I think.
return "", false
}
// Preallocate space for the name, opType, opMethod, and some digits.
name := named.Obj().Name()
path := make([]byte, 0, len(name)+8)
path = append(path, name...)
path = append(path, opType)
// Method indices are w.r.t. the go/types data structures,
// ultimately deriving from source order,
// which is preserved by export data.
for i := 0; i < named.NumMethods(); i++ {
if named.Method(i) == meth {
path = appendOpArg(path, opMethod, i)
return Path(path), true
}
}
// Due to golang/go#59944, go/types fails to associate the receiver with
// certain methods on cgo types.
//
// TODO(rfindley): replace this panic once golang/go#59944 is fixed in all Go
// versions gopls supports.
return "", false
// panic(fmt.Sprintf("couldn't find method %s on type %s; methods: %#v", meth, named, enc.namedMethods(named)))
}
// find finds obj within type T, returning the path to it, or nil if not found.
//
// The seen map is used to short circuit cycles through type parameters. If
// nil, it will be allocated as necessary.
func find(obj types.Object, T types.Type, path []byte, seen map[*types.TypeName]bool) []byte {
switch T := T.(type) {
case *types.Alias:
return find(obj, types.Unalias(T), path, seen)
case *types.Basic, *types.Named:
// Named types belonging to pkg were handled already,
// so T must belong to another package. No path.
return nil
case *types.Pointer:
return find(obj, T.Elem(), append(path, opElem), seen)
case *types.Slice:
return find(obj, T.Elem(), append(path, opElem), seen)
case *types.Array:
return find(obj, T.Elem(), append(path, opElem), seen)
case *types.Chan:
return find(obj, T.Elem(), append(path, opElem), seen)
case *types.Map:
if r := find(obj, T.Key(), append(path, opKey), seen); r != nil {
return r
}
return find(obj, T.Elem(), append(path, opElem), seen)
case *types.Signature:
if r := findTypeParam(obj, T.RecvTypeParams(), path, opRecvTypeParam, nil); r != nil {
return r
}
if r := findTypeParam(obj, T.TypeParams(), path, opTypeParam, seen); r != nil {
return r
}
if r := find(obj, T.Params(), append(path, opParams), seen); r != nil {
return r
}
return find(obj, T.Results(), append(path, opResults), seen)
case *types.Struct:
for i := 0; i < T.NumFields(); i++ {
fld := T.Field(i)
path2 := appendOpArg(path, opField, i)
if fld == obj {
return path2 // found field var
}
if r := find(obj, fld.Type(), append(path2, opType), seen); r != nil {
return r
}
}
return nil
case *types.Tuple:
for i := 0; i < T.Len(); i++ {
v := T.At(i)
path2 := appendOpArg(path, opAt, i)
if v == obj {
return path2 // found param/result var
}
if r := find(obj, v.Type(), append(path2, opType), seen); r != nil {
return r
}
}
return nil
case *types.Interface:
for i := 0; i < T.NumMethods(); i++ {
m := T.Method(i)
path2 := appendOpArg(path, opMethod, i)
if m == obj {
return path2 // found interface method
}
if r := find(obj, m.Type(), append(path2, opType), seen); r != nil {
return r
}
}
return nil
case *types.TypeParam:
name := T.Obj()
if name == obj {
return append(path, opObj)
}
if seen[name] {
return nil
}
if seen == nil {
seen = make(map[*types.TypeName]bool)
}
seen[name] = true
if r := find(obj, T.Constraint(), append(path, opConstraint), seen); r != nil {
return r
}
return nil
}
panic(T)
}
func findTypeParam(obj types.Object, list *types.TypeParamList, path []byte, op byte, seen map[*types.TypeName]bool) []byte {
for i := 0; i < list.Len(); i++ {
tparam := list.At(i)
path2 := appendOpArg(path, op, i)
if r := find(obj, tparam, path2, seen); r != nil {
return r
}
}
return nil
}
// Object returns the object denoted by path p within the package pkg.
func Object(pkg *types.Package, p Path) (types.Object, error) {
pathstr := string(p)
if pathstr == "" {
return nil, fmt.Errorf("empty path")
}
var pkgobj, suffix string
if dot := strings.IndexByte(pathstr, opType); dot < 0 {
pkgobj = pathstr
} else {
pkgobj = pathstr[:dot]
suffix = pathstr[dot:] // suffix starts with "."
}
obj := pkg.Scope().Lookup(pkgobj)
if obj == nil {
return nil, fmt.Errorf("package %s does not contain %q", pkg.Path(), pkgobj)
}
// abstraction of *types.{Pointer,Slice,Array,Chan,Map}
type hasElem interface {
Elem() types.Type
}
// abstraction of *types.{Named,Signature}
type hasTypeParams interface {
TypeParams() *types.TypeParamList
}
// abstraction of *types.{Named,TypeParam}
type hasObj interface {
Obj() *types.TypeName
}
// The loop state is the pair (t, obj),
// exactly one of which is non-nil, initially obj.
// All suffixes start with '.' (the only object->type operation),
// followed by optional type->type operations,
// then a type->object operation.
// The cycle then repeats.
var t types.Type
for suffix != "" {
code := suffix[0]
suffix = suffix[1:]
// Codes [AFMTr] have an integer operand.
var index int
switch code {
case opAt, opField, opMethod, opTypeParam, opRecvTypeParam:
rest := strings.TrimLeft(suffix, "0123456789")
numerals := suffix[:len(suffix)-len(rest)]
suffix = rest
i, err := strconv.Atoi(numerals)
if err != nil {
return nil, fmt.Errorf("invalid path: bad numeric operand %q for code %q", numerals, code)
}
index = int(i)
case opObj:
// no operand
default:
// The suffix must end with a type->object operation.
if suffix == "" {
return nil, fmt.Errorf("invalid path: ends with %q, want [AFMO]", code)
}
}
if code == opType {
if t != nil {
return nil, fmt.Errorf("invalid path: unexpected %q in type context", opType)
}
t = obj.Type()
obj = nil
continue
}
if t == nil {
return nil, fmt.Errorf("invalid path: code %q in object context", code)
}
// Inv: t != nil, obj == nil
t = types.Unalias(t)
switch code {
case opElem:
hasElem, ok := t.(hasElem) // Pointer, Slice, Array, Chan, Map
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want pointer, slice, array, chan or map)", code, t, t)
}
t = hasElem.Elem()
case opKey:
mapType, ok := t.(*types.Map)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want map)", code, t, t)
}
t = mapType.Key()
case opParams:
sig, ok := t.(*types.Signature)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want signature)", code, t, t)
}
t = sig.Params()
case opResults:
sig, ok := t.(*types.Signature)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want signature)", code, t, t)
}
t = sig.Results()
case opUnderlying:
named, ok := t.(*types.Named)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want named)", code, t, t)
}
t = named.Underlying()
case opRhs:
if alias, ok := t.(*types.Alias); ok {
t = aliases.Rhs(alias)
} else if false && aliases.Enabled() {
// The Enabled check is too expensive, so for now we
// simply assume that aliases are not enabled.
// TODO(adonovan): replace with "if true {" when go1.24 is assured.
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want alias)", code, t, t)
}
case opTypeParam:
hasTypeParams, ok := t.(hasTypeParams) // Named, Signature
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want named or signature)", code, t, t)
}
tparams := hasTypeParams.TypeParams()
if n := tparams.Len(); index >= n {
return nil, fmt.Errorf("tuple index %d out of range [0-%d)", index, n)
}
t = tparams.At(index)
case opRecvTypeParam:
sig, ok := t.(*types.Signature) // Signature
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want signature)", code, t, t)
}
rtparams := sig.RecvTypeParams()
if n := rtparams.Len(); index >= n {
return nil, fmt.Errorf("tuple index %d out of range [0-%d)", index, n)
}
t = rtparams.At(index)
case opConstraint:
tparam, ok := t.(*types.TypeParam)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want type parameter)", code, t, t)
}
t = tparam.Constraint()
case opAt:
tuple, ok := t.(*types.Tuple)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want tuple)", code, t, t)
}
if n := tuple.Len(); index >= n {
return nil, fmt.Errorf("tuple index %d out of range [0-%d)", index, n)
}
obj = tuple.At(index)
t = nil
case opField:
structType, ok := t.(*types.Struct)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want struct)", code, t, t)
}
if n := structType.NumFields(); index >= n {
return nil, fmt.Errorf("field index %d out of range [0-%d)", index, n)
}
obj = structType.Field(index)
t = nil
case opMethod:
switch t := t.(type) {
case *types.Interface:
if index >= t.NumMethods() {
return nil, fmt.Errorf("method index %d out of range [0-%d)", index, t.NumMethods())
}
obj = t.Method(index) // Id-ordered
case *types.Named:
if index >= t.NumMethods() {
return nil, fmt.Errorf("method index %d out of range [0-%d)", index, t.NumMethods())
}
obj = t.Method(index)
default:
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want interface or named)", code, t, t)
}
t = nil
case opObj:
hasObj, ok := t.(hasObj)
if !ok {
return nil, fmt.Errorf("cannot apply %q to %s (got %T, want named or type param)", code, t, t)
}
obj = hasObj.Obj()
t = nil
default:
return nil, fmt.Errorf("invalid path: unknown code %q", code)
}
}
if obj == nil {
panic(p) // path does not end in an object-valued operator
}
if obj.Pkg() != pkg {
return nil, fmt.Errorf("path denotes %s, which belongs to a different package", obj)
}
return obj, nil // success
}
// scopeObjects is a memoization of scope objects.
// Callers must not modify the result.
func (enc *Encoder) scopeObjects(scope *types.Scope) []types.Object {
m := enc.scopeMemo
if m == nil {
m = make(map[*types.Scope][]types.Object)
enc.scopeMemo = m
}
objs, ok := m[scope]
if !ok {
names := scope.Names() // allocates and sorts
objs = make([]types.Object, len(names))
for i, name := range names {
objs[i] = scope.Lookup(name)
}
m[scope] = objs
}
return objs
}

68
vendor/golang.org/x/tools/go/types/typeutil/callee.go generated vendored Normal file
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// 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 typeutil
import (
"go/ast"
"go/types"
"golang.org/x/tools/internal/typeparams"
)
// Callee returns the named target of a function call, if any:
// a function, method, builtin, or variable.
//
// Functions and methods may potentially have type parameters.
func Callee(info *types.Info, call *ast.CallExpr) types.Object {
fun := ast.Unparen(call.Fun)
// Look through type instantiation if necessary.
isInstance := false
switch fun.(type) {
case *ast.IndexExpr, *ast.IndexListExpr:
// When extracting the callee from an *IndexExpr, we need to check that
// it is a *types.Func and not a *types.Var.
// Example: Don't match a slice m within the expression `m[0]()`.
isInstance = true
fun, _, _, _ = typeparams.UnpackIndexExpr(fun)
}
var obj types.Object
switch fun := fun.(type) {
case *ast.Ident:
obj = info.Uses[fun] // type, var, builtin, or declared func
case *ast.SelectorExpr:
if sel, ok := info.Selections[fun]; ok {
obj = sel.Obj() // method or field
} else {
obj = info.Uses[fun.Sel] // qualified identifier?
}
}
if _, ok := obj.(*types.TypeName); ok {
return nil // T(x) is a conversion, not a call
}
// A Func is required to match instantiations.
if _, ok := obj.(*types.Func); isInstance && !ok {
return nil // Was not a Func.
}
return obj
}
// StaticCallee returns the target (function or method) of a static function
// call, if any. It returns nil for calls to builtins.
//
// Note: for calls of instantiated functions and methods, StaticCallee returns
// the corresponding generic function or method on the generic type.
func StaticCallee(info *types.Info, call *ast.CallExpr) *types.Func {
if f, ok := Callee(info, call).(*types.Func); ok && !interfaceMethod(f) {
return f
}
return nil
}
func interfaceMethod(f *types.Func) bool {
recv := f.Type().(*types.Signature).Recv()
return recv != nil && types.IsInterface(recv.Type())
}

30
vendor/golang.org/x/tools/go/types/typeutil/imports.go generated vendored Normal file
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// Copyright 2014 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 typeutil
import "go/types"
// Dependencies returns all dependencies of the specified packages.
//
// Dependent packages appear in topological order: if package P imports
// package Q, Q appears earlier than P in the result.
// The algorithm follows import statements in the order they
// appear in the source code, so the result is a total order.
func Dependencies(pkgs ...*types.Package) []*types.Package {
var result []*types.Package
seen := make(map[*types.Package]bool)
var visit func(pkgs []*types.Package)
visit = func(pkgs []*types.Package) {
for _, p := range pkgs {
if !seen[p] {
seen[p] = true
visit(p.Imports())
result = append(result, p)
}
}
}
visit(pkgs)
return result
}

517
vendor/golang.org/x/tools/go/types/typeutil/map.go generated vendored Normal file
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// Copyright 2014 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 typeutil defines various utilities for types, such as Map,
// a mapping from types.Type to any values.
package typeutil // import "golang.org/x/tools/go/types/typeutil"
import (
"bytes"
"fmt"
"go/types"
"reflect"
"golang.org/x/tools/internal/typeparams"
)
// Map is a hash-table-based mapping from types (types.Type) to
// arbitrary any values. The concrete types that implement
// the Type interface are pointers. Since they are not canonicalized,
// == cannot be used to check for equivalence, and thus we cannot
// simply use a Go map.
//
// Just as with map[K]V, a nil *Map is a valid empty map.
//
// Not thread-safe.
type Map struct {
hasher Hasher // shared by many Maps
table map[uint32][]entry // maps hash to bucket; entry.key==nil means unused
length int // number of map entries
}
// entry is an entry (key/value association) in a hash bucket.
type entry struct {
key types.Type
value any
}
// SetHasher sets the hasher used by Map.
//
// All Hashers are functionally equivalent but contain internal state
// used to cache the results of hashing previously seen types.
//
// A single Hasher created by MakeHasher() may be shared among many
// Maps. This is recommended if the instances have many keys in
// common, as it will amortize the cost of hash computation.
//
// A Hasher may grow without bound as new types are seen. Even when a
// type is deleted from the map, the Hasher never shrinks, since other
// types in the map may reference the deleted type indirectly.
//
// Hashers are not thread-safe, and read-only operations such as
// Map.Lookup require updates to the hasher, so a full Mutex lock (not a
// read-lock) is require around all Map operations if a shared
// hasher is accessed from multiple threads.
//
// If SetHasher is not called, the Map will create a private hasher at
// the first call to Insert.
func (m *Map) SetHasher(hasher Hasher) {
m.hasher = hasher
}
// Delete removes the entry with the given key, if any.
// It returns true if the entry was found.
func (m *Map) Delete(key types.Type) bool {
if m != nil && m.table != nil {
hash := m.hasher.Hash(key)
bucket := m.table[hash]
for i, e := range bucket {
if e.key != nil && types.Identical(key, e.key) {
// We can't compact the bucket as it
// would disturb iterators.
bucket[i] = entry{}
m.length--
return true
}
}
}
return false
}
// At returns the map entry for the given key.
// The result is nil if the entry is not present.
func (m *Map) At(key types.Type) any {
if m != nil && m.table != nil {
for _, e := range m.table[m.hasher.Hash(key)] {
if e.key != nil && types.Identical(key, e.key) {
return e.value
}
}
}
return nil
}
// Set sets the map entry for key to val,
// and returns the previous entry, if any.
func (m *Map) Set(key types.Type, value any) (prev any) {
if m.table != nil {
hash := m.hasher.Hash(key)
bucket := m.table[hash]
var hole *entry
for i, e := range bucket {
if e.key == nil {
hole = &bucket[i]
} else if types.Identical(key, e.key) {
prev = e.value
bucket[i].value = value
return
}
}
if hole != nil {
*hole = entry{key, value} // overwrite deleted entry
} else {
m.table[hash] = append(bucket, entry{key, value})
}
} else {
if m.hasher.memo == nil {
m.hasher = MakeHasher()
}
hash := m.hasher.Hash(key)
m.table = map[uint32][]entry{hash: {entry{key, value}}}
}
m.length++
return
}
// Len returns the number of map entries.
func (m *Map) Len() int {
if m != nil {
return m.length
}
return 0
}
// Iterate calls function f on each entry in the map in unspecified order.
//
// If f should mutate the map, Iterate provides the same guarantees as
// Go maps: if f deletes a map entry that Iterate has not yet reached,
// f will not be invoked for it, but if f inserts a map entry that
// Iterate has not yet reached, whether or not f will be invoked for
// it is unspecified.
func (m *Map) Iterate(f func(key types.Type, value any)) {
if m != nil {
for _, bucket := range m.table {
for _, e := range bucket {
if e.key != nil {
f(e.key, e.value)
}
}
}
}
}
// Keys returns a new slice containing the set of map keys.
// The order is unspecified.
func (m *Map) Keys() []types.Type {
keys := make([]types.Type, 0, m.Len())
m.Iterate(func(key types.Type, _ any) {
keys = append(keys, key)
})
return keys
}
func (m *Map) toString(values bool) string {
if m == nil {
return "{}"
}
var buf bytes.Buffer
fmt.Fprint(&buf, "{")
sep := ""
m.Iterate(func(key types.Type, value any) {
fmt.Fprint(&buf, sep)
sep = ", "
fmt.Fprint(&buf, key)
if values {
fmt.Fprintf(&buf, ": %q", value)
}
})
fmt.Fprint(&buf, "}")
return buf.String()
}
// String returns a string representation of the map's entries.
// Values are printed using fmt.Sprintf("%v", v).
// Order is unspecified.
func (m *Map) String() string {
return m.toString(true)
}
// KeysString returns a string representation of the map's key set.
// Order is unspecified.
func (m *Map) KeysString() string {
return m.toString(false)
}
////////////////////////////////////////////////////////////////////////
// Hasher
// A Hasher maps each type to its hash value.
// For efficiency, a hasher uses memoization; thus its memory
// footprint grows monotonically over time.
// Hashers are not thread-safe.
// Hashers have reference semantics.
// Call MakeHasher to create a Hasher.
type Hasher struct {
memo map[types.Type]uint32
// ptrMap records pointer identity.
ptrMap map[any]uint32
// sigTParams holds type parameters from the signature being hashed.
// Signatures are considered identical modulo renaming of type parameters, so
// within the scope of a signature type the identity of the signature's type
// parameters is just their index.
//
// Since the language does not currently support referring to uninstantiated
// generic types or functions, and instantiated signatures do not have type
// parameter lists, we should never encounter a second non-empty type
// parameter list when hashing a generic signature.
sigTParams *types.TypeParamList
}
// MakeHasher returns a new Hasher instance.
func MakeHasher() Hasher {
return Hasher{
memo: make(map[types.Type]uint32),
ptrMap: make(map[any]uint32),
sigTParams: nil,
}
}
// Hash computes a hash value for the given type t such that
// Identical(t, t') => Hash(t) == Hash(t').
func (h Hasher) Hash(t types.Type) uint32 {
hash, ok := h.memo[t]
if !ok {
hash = h.hashFor(t)
h.memo[t] = hash
}
return hash
}
// hashString computes the FowlerNollVo hash of s.
func hashString(s string) uint32 {
var h uint32
for i := 0; i < len(s); i++ {
h ^= uint32(s[i])
h *= 16777619
}
return h
}
// hashFor computes the hash of t.
func (h Hasher) hashFor(t types.Type) uint32 {
// See Identical for rationale.
switch t := t.(type) {
case *types.Basic:
return uint32(t.Kind())
case *types.Alias:
return h.Hash(types.Unalias(t))
case *types.Array:
return 9043 + 2*uint32(t.Len()) + 3*h.Hash(t.Elem())
case *types.Slice:
return 9049 + 2*h.Hash(t.Elem())
case *types.Struct:
var hash uint32 = 9059
for i, n := 0, t.NumFields(); i < n; i++ {
f := t.Field(i)
if f.Anonymous() {
hash += 8861
}
hash += hashString(t.Tag(i))
hash += hashString(f.Name()) // (ignore f.Pkg)
hash += h.Hash(f.Type())
}
return hash
case *types.Pointer:
return 9067 + 2*h.Hash(t.Elem())
case *types.Signature:
var hash uint32 = 9091
if t.Variadic() {
hash *= 8863
}
// Use a separate hasher for types inside of the signature, where type
// parameter identity is modified to be (index, constraint). We must use a
// new memo for this hasher as type identity may be affected by this
// masking. For example, in func[T any](*T), the identity of *T depends on
// whether we are mapping the argument in isolation, or recursively as part
// of hashing the signature.
//
// We should never encounter a generic signature while hashing another
// generic signature, but defensively set sigTParams only if h.mask is
// unset.
tparams := t.TypeParams()
if h.sigTParams == nil && tparams.Len() != 0 {
h = Hasher{
// There may be something more efficient than discarding the existing
// memo, but it would require detecting whether types are 'tainted' by
// references to type parameters.
memo: make(map[types.Type]uint32),
// Re-using ptrMap ensures that pointer identity is preserved in this
// hasher.
ptrMap: h.ptrMap,
sigTParams: tparams,
}
}
for i := 0; i < tparams.Len(); i++ {
tparam := tparams.At(i)
hash += 7 * h.Hash(tparam.Constraint())
}
return hash + 3*h.hashTuple(t.Params()) + 5*h.hashTuple(t.Results())
case *types.Union:
return h.hashUnion(t)
case *types.Interface:
// Interfaces are identical if they have the same set of methods, with
// identical names and types, and they have the same set of type
// restrictions. See go/types.identical for more details.
var hash uint32 = 9103
// Hash methods.
for i, n := 0, t.NumMethods(); i < n; i++ {
// Method order is not significant.
// Ignore m.Pkg().
m := t.Method(i)
// Use shallow hash on method signature to
// avoid anonymous interface cycles.
hash += 3*hashString(m.Name()) + 5*h.shallowHash(m.Type())
}
// Hash type restrictions.
terms, err := typeparams.InterfaceTermSet(t)
// if err != nil t has invalid type restrictions.
if err == nil {
hash += h.hashTermSet(terms)
}
return hash
case *types.Map:
return 9109 + 2*h.Hash(t.Key()) + 3*h.Hash(t.Elem())
case *types.Chan:
return 9127 + 2*uint32(t.Dir()) + 3*h.Hash(t.Elem())
case *types.Named:
hash := h.hashPtr(t.Obj())
targs := t.TypeArgs()
for i := 0; i < targs.Len(); i++ {
targ := targs.At(i)
hash += 2 * h.Hash(targ)
}
return hash
case *types.TypeParam:
return h.hashTypeParam(t)
case *types.Tuple:
return h.hashTuple(t)
}
panic(fmt.Sprintf("%T: %v", t, t))
}
func (h Hasher) hashTuple(tuple *types.Tuple) uint32 {
// See go/types.identicalTypes for rationale.
n := tuple.Len()
hash := 9137 + 2*uint32(n)
for i := 0; i < n; i++ {
hash += 3 * h.Hash(tuple.At(i).Type())
}
return hash
}
func (h Hasher) hashUnion(t *types.Union) uint32 {
// Hash type restrictions.
terms, err := typeparams.UnionTermSet(t)
// if err != nil t has invalid type restrictions. Fall back on a non-zero
// hash.
if err != nil {
return 9151
}
return h.hashTermSet(terms)
}
func (h Hasher) hashTermSet(terms []*types.Term) uint32 {
hash := 9157 + 2*uint32(len(terms))
for _, term := range terms {
// term order is not significant.
termHash := h.Hash(term.Type())
if term.Tilde() {
termHash *= 9161
}
hash += 3 * termHash
}
return hash
}
// hashTypeParam returns a hash of the type parameter t, with a hash value
// depending on whether t is contained in h.sigTParams.
//
// If h.sigTParams is set and contains t, then we are in the process of hashing
// a signature, and the hash value of t must depend only on t's index and
// constraint: signatures are considered identical modulo type parameter
// renaming. To avoid infinite recursion, we only hash the type parameter
// index, and rely on types.Identical to handle signatures where constraints
// are not identical.
//
// Otherwise the hash of t depends only on t's pointer identity.
func (h Hasher) hashTypeParam(t *types.TypeParam) uint32 {
if h.sigTParams != nil {
i := t.Index()
if i >= 0 && i < h.sigTParams.Len() && t == h.sigTParams.At(i) {
return 9173 + 3*uint32(i)
}
}
return h.hashPtr(t.Obj())
}
// hashPtr hashes the pointer identity of ptr. It uses h.ptrMap to ensure that
// pointers values are not dependent on the GC.
func (h Hasher) hashPtr(ptr any) uint32 {
if hash, ok := h.ptrMap[ptr]; ok {
return hash
}
hash := uint32(reflect.ValueOf(ptr).Pointer())
h.ptrMap[ptr] = hash
return hash
}
// shallowHash computes a hash of t without looking at any of its
// element Types, to avoid potential anonymous cycles in the types of
// interface methods.
//
// When an unnamed non-empty interface type appears anywhere among the
// arguments or results of an interface method, there is a potential
// for endless recursion. Consider:
//
// type X interface { m() []*interface { X } }
//
// The problem is that the Methods of the interface in m's result type
// include m itself; there is no mention of the named type X that
// might help us break the cycle.
// (See comment in go/types.identical, case *Interface, for more.)
func (h Hasher) shallowHash(t types.Type) uint32 {
// t is the type of an interface method (Signature),
// its params or results (Tuples), or their immediate
// elements (mostly Slice, Pointer, Basic, Named),
// so there's no need to optimize anything else.
switch t := t.(type) {
case *types.Alias:
return h.shallowHash(types.Unalias(t))
case *types.Signature:
var hash uint32 = 604171
if t.Variadic() {
hash *= 971767
}
// The Signature/Tuple recursion is always finite
// and invariably shallow.
return hash + 1062599*h.shallowHash(t.Params()) + 1282529*h.shallowHash(t.Results())
case *types.Tuple:
n := t.Len()
hash := 9137 + 2*uint32(n)
for i := 0; i < n; i++ {
hash += 53471161 * h.shallowHash(t.At(i).Type())
}
return hash
case *types.Basic:
return 45212177 * uint32(t.Kind())
case *types.Array:
return 1524181 + 2*uint32(t.Len())
case *types.Slice:
return 2690201
case *types.Struct:
return 3326489
case *types.Pointer:
return 4393139
case *types.Union:
return 562448657
case *types.Interface:
return 2124679 // no recursion here
case *types.Map:
return 9109
case *types.Chan:
return 9127
case *types.Named:
return h.hashPtr(t.Obj())
case *types.TypeParam:
return h.hashPtr(t.Obj())
}
panic(fmt.Sprintf("shallowHash: %T: %v", t, t))
}

71
vendor/golang.org/x/tools/go/types/typeutil/methodsetcache.go generated vendored Normal file
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// Copyright 2014 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.
// This file implements a cache of method sets.
package typeutil
import (
"go/types"
"sync"
)
// A MethodSetCache records the method set of each type T for which
// MethodSet(T) is called so that repeat queries are fast.
// The zero value is a ready-to-use cache instance.
type MethodSetCache struct {
mu sync.Mutex
named map[*types.Named]struct{ value, pointer *types.MethodSet } // method sets for named N and *N
others map[types.Type]*types.MethodSet // all other types
}
// MethodSet returns the method set of type T. It is thread-safe.
//
// If cache is nil, this function is equivalent to types.NewMethodSet(T).
// Utility functions can thus expose an optional *MethodSetCache
// parameter to clients that care about performance.
func (cache *MethodSetCache) MethodSet(T types.Type) *types.MethodSet {
if cache == nil {
return types.NewMethodSet(T)
}
cache.mu.Lock()
defer cache.mu.Unlock()
switch T := types.Unalias(T).(type) {
case *types.Named:
return cache.lookupNamed(T).value
case *types.Pointer:
if N, ok := types.Unalias(T.Elem()).(*types.Named); ok {
return cache.lookupNamed(N).pointer
}
}
// all other types
// (The map uses pointer equivalence, not type identity.)
mset := cache.others[T]
if mset == nil {
mset = types.NewMethodSet(T)
if cache.others == nil {
cache.others = make(map[types.Type]*types.MethodSet)
}
cache.others[T] = mset
}
return mset
}
func (cache *MethodSetCache) lookupNamed(named *types.Named) struct{ value, pointer *types.MethodSet } {
if cache.named == nil {
cache.named = make(map[*types.Named]struct{ value, pointer *types.MethodSet })
}
// Avoid recomputing mset(*T) for each distinct Pointer
// instance whose underlying type is a named type.
msets, ok := cache.named[named]
if !ok {
msets.value = types.NewMethodSet(named)
msets.pointer = types.NewMethodSet(types.NewPointer(named))
cache.named[named] = msets
}
return msets
}

53
vendor/golang.org/x/tools/go/types/typeutil/ui.go generated vendored Normal file
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@@ -0,0 +1,53 @@
// Copyright 2014 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 typeutil
// This file defines utilities for user interfaces that display types.
import (
"go/types"
)
// IntuitiveMethodSet returns the intuitive method set of a type T,
// which is the set of methods you can call on an addressable value of
// that type.
//
// The result always contains MethodSet(T), and is exactly MethodSet(T)
// for interface types and for pointer-to-concrete types.
// For all other concrete types T, the result additionally
// contains each method belonging to *T if there is no identically
// named method on T itself.
//
// This corresponds to user intuition about method sets;
// this function is intended only for user interfaces.
//
// The order of the result is as for types.MethodSet(T).
func IntuitiveMethodSet(T types.Type, msets *MethodSetCache) []*types.Selection {
isPointerToConcrete := func(T types.Type) bool {
ptr, ok := types.Unalias(T).(*types.Pointer)
return ok && !types.IsInterface(ptr.Elem())
}
var result []*types.Selection
mset := msets.MethodSet(T)
if types.IsInterface(T) || isPointerToConcrete(T) {
for i, n := 0, mset.Len(); i < n; i++ {
result = append(result, mset.At(i))
}
} else {
// T is some other concrete type.
// Report methods of T and *T, preferring those of T.
pmset := msets.MethodSet(types.NewPointer(T))
for i, n := 0, pmset.Len(); i < n; i++ {
meth := pmset.At(i)
if m := mset.Lookup(meth.Obj().Pkg(), meth.Obj().Name()); m != nil {
meth = m
}
result = append(result, meth)
}
}
return result
}