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#136: Start working on database persistence

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This commit is contained in:
TwinProduction
2021-07-12 00:56:30 -04:00
committed by Chris
parent e6335da94f
commit bd1eb7c61b
657 changed files with 2190821 additions and 82 deletions
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3
vendor/golang.org/x/tools/AUTHORS generated vendored Normal file
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# This source code refers to The Go Authors for copyright purposes.
# The master list of authors is in the main Go distribution,
# visible at http://tip.golang.org/AUTHORS.

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vendor/golang.org/x/tools/CONTRIBUTORS generated vendored Normal file
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# This source code was written by the Go contributors.
# The master list of contributors is in the main Go distribution,
# visible at http://tip.golang.org/CONTRIBUTORS.

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vendor/golang.org/x/tools/LICENSE generated vendored Normal file
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Copyright (c) 2009 The Go Authors. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above
copyright notice, this list of conditions and the following disclaimer
in the documentation and/or other materials provided with the
distribution.
* Neither the name of Google Inc. nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

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vendor/golang.org/x/tools/PATENTS generated vendored Normal file
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Additional IP Rights Grant (Patents)
"This implementation" means the copyrightable works distributed by
Google as part of the Go project.
Google hereby grants to You a perpetual, worldwide, non-exclusive,
no-charge, royalty-free, irrevocable (except as stated in this section)
patent license to make, have made, use, offer to sell, sell, import,
transfer and otherwise run, modify and propagate the contents of this
implementation of Go, where such license applies only to those patent
claims, both currently owned or controlled by Google and acquired in
the future, licensable by Google that are necessarily infringed by this
implementation of Go. This grant does not include claims that would be
infringed only as a consequence of further modification of this
implementation. If you or your agent or exclusive licensee institute or
order or agree to the institution of patent litigation against any
entity (including a cross-claim or counterclaim in a lawsuit) alleging
that this implementation of Go or any code incorporated within this
implementation of Go constitutes direct or contributory patent
infringement, or inducement of patent infringement, then any patent
rights granted to you under this License for this implementation of Go
shall terminate as of the date such litigation is filed.

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vendor/golang.org/x/tools/go/gcexportdata/gcexportdata.go generated vendored Normal file
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// Copyright 2016 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 gcexportdata provides functions for locating, reading, and
// writing export data files containing type information produced by the
// gc compiler. This package supports go1.7 export data format and all
// later versions.
//
// Although it might seem convenient for this package to live alongside
// go/types in the standard library, this would cause version skew
// problems for developer tools that use it, since they must be able to
// consume the outputs of the gc compiler both before and after a Go
// update such as from Go 1.7 to Go 1.8. Because this package lives in
// golang.org/x/tools, sites can update their version of this repo some
// time before the Go 1.8 release and rebuild and redeploy their
// developer tools, which will then be able to consume both Go 1.7 and
// Go 1.8 export data files, so they will work before and after the
// Go update. (See discussion at https://golang.org/issue/15651.)
//
package gcexportdata // import "golang.org/x/tools/go/gcexportdata"
import (
"bufio"
"bytes"
"fmt"
"go/token"
"go/types"
"io"
"io/ioutil"
"golang.org/x/tools/go/internal/gcimporter"
)
// Find returns the name of an object (.o) or archive (.a) file
// containing type information for the specified import path,
// using the workspace layout conventions of go/build.
// If no file was found, an empty filename is returned.
//
// A relative srcDir is interpreted relative to the current working directory.
//
// Find also returns the package's resolved (canonical) import path,
// reflecting the effects of srcDir and vendoring on importPath.
func Find(importPath, srcDir string) (filename, path string) {
return gcimporter.FindPkg(importPath, srcDir)
}
// NewReader returns a reader for the export data section of an object
// (.o) or archive (.a) file read from r. The new reader may provide
// additional trailing data beyond the end of the export data.
func NewReader(r io.Reader) (io.Reader, error) {
buf := bufio.NewReader(r)
_, err := gcimporter.FindExportData(buf)
// If we ever switch to a zip-like archive format with the ToC
// at the end, we can return the correct portion of export data,
// but for now we must return the entire rest of the file.
return buf, err
}
// Read reads export data from in, decodes it, and returns type
// information for the package.
// The package name is specified by path.
// File position information is added to fset.
//
// Read may inspect and add to the imports map to ensure that references
// within the export data to other packages are consistent. The caller
// must ensure that imports[path] does not exist, or exists but is
// incomplete (see types.Package.Complete), and Read inserts the
// resulting package into this map entry.
//
// On return, the state of the reader is undefined.
func Read(in io.Reader, fset *token.FileSet, imports map[string]*types.Package, path string) (*types.Package, error) {
data, err := ioutil.ReadAll(in)
if err != nil {
return nil, fmt.Errorf("reading export data for %q: %v", path, err)
}
if bytes.HasPrefix(data, []byte("!<arch>")) {
return nil, fmt.Errorf("can't read export data for %q directly from an archive file (call gcexportdata.NewReader first to extract export data)", path)
}
// The App Engine Go runtime v1.6 uses the old export data format.
// TODO(adonovan): delete once v1.7 has been around for a while.
if bytes.HasPrefix(data, []byte("package ")) {
return gcimporter.ImportData(imports, path, path, bytes.NewReader(data))
}
// The indexed export format starts with an 'i'; the older
// binary export format starts with a 'c', 'd', or 'v'
// (from "version"). Select appropriate importer.
if len(data) > 0 && data[0] == 'i' {
_, pkg, err := gcimporter.IImportData(fset, imports, data[1:], path)
return pkg, err
}
_, pkg, err := gcimporter.BImportData(fset, imports, data, path)
return pkg, err
}
// Write writes encoded type information for the specified package to out.
// The FileSet provides file position information for named objects.
func Write(out io.Writer, fset *token.FileSet, pkg *types.Package) error {
b, err := gcimporter.IExportData(fset, pkg)
if err != nil {
return err
}
_, err = out.Write(b)
return err
}

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vendor/golang.org/x/tools/go/gcexportdata/importer.go generated vendored Normal file
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// Copyright 2016 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 gcexportdata
import (
"fmt"
"go/token"
"go/types"
"os"
)
// NewImporter returns a new instance of the types.Importer interface
// that reads type information from export data files written by gc.
// The Importer also satisfies types.ImporterFrom.
//
// Export data files are located using "go build" workspace conventions
// and the build.Default context.
//
// Use this importer instead of go/importer.For("gc", ...) to avoid the
// version-skew problems described in the documentation of this package,
// or to control the FileSet or access the imports map populated during
// package loading.
//
func NewImporter(fset *token.FileSet, imports map[string]*types.Package) types.ImporterFrom {
return importer{fset, imports}
}
type importer struct {
fset *token.FileSet
imports map[string]*types.Package
}
func (imp importer) Import(importPath string) (*types.Package, error) {
return imp.ImportFrom(importPath, "", 0)
}
func (imp importer) ImportFrom(importPath, srcDir string, mode types.ImportMode) (_ *types.Package, err error) {
filename, path := Find(importPath, srcDir)
if filename == "" {
if importPath == "unsafe" {
// Even for unsafe, call Find first in case
// the package was vendored.
return types.Unsafe, nil
}
return nil, fmt.Errorf("can't find import: %s", importPath)
}
if pkg, ok := imp.imports[path]; ok && pkg.Complete() {
return pkg, nil // cache hit
}
// open file
f, err := os.Open(filename)
if err != nil {
return nil, err
}
defer func() {
f.Close()
if err != nil {
// add file name to error
err = fmt.Errorf("reading export data: %s: %v", filename, err)
}
}()
r, err := NewReader(f)
if err != nil {
return nil, err
}
return Read(r, imp.fset, imp.imports, path)
}

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vendor/golang.org/x/tools/go/internal/gcimporter/bexport.go generated vendored Normal file
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// Copyright 2016 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.
// Binary package export.
// This file was derived from $GOROOT/src/cmd/compile/internal/gc/bexport.go;
// see that file for specification of the format.
package gcimporter
import (
"bytes"
"encoding/binary"
"fmt"
"go/ast"
"go/constant"
"go/token"
"go/types"
"math"
"math/big"
"sort"
"strings"
)
// If debugFormat is set, each integer and string value is preceded by a marker
// and position information in the encoding. This mechanism permits an importer
// to recognize immediately when it is out of sync. The importer recognizes this
// mode automatically (i.e., it can import export data produced with debugging
// support even if debugFormat is not set at the time of import). This mode will
// lead to massively larger export data (by a factor of 2 to 3) and should only
// be enabled during development and debugging.
//
// NOTE: This flag is the first flag to enable if importing dies because of
// (suspected) format errors, and whenever a change is made to the format.
const debugFormat = false // default: false
// If trace is set, debugging output is printed to std out.
const trace = false // default: false
// Current export format version. Increase with each format change.
// Note: The latest binary (non-indexed) export format is at version 6.
// This exporter is still at level 4, but it doesn't matter since
// the binary importer can handle older versions just fine.
// 6: package height (CL 105038) -- NOT IMPLEMENTED HERE
// 5: improved position encoding efficiency (issue 20080, CL 41619) -- NOT IMPLEMEMTED HERE
// 4: type name objects support type aliases, uses aliasTag
// 3: Go1.8 encoding (same as version 2, aliasTag defined but never used)
// 2: removed unused bool in ODCL export (compiler only)
// 1: header format change (more regular), export package for _ struct fields
// 0: Go1.7 encoding
const exportVersion = 4
// trackAllTypes enables cycle tracking for all types, not just named
// types. The existing compiler invariants assume that unnamed types
// that are not completely set up are not used, or else there are spurious
// errors.
// If disabled, only named types are tracked, possibly leading to slightly
// less efficient encoding in rare cases. It also prevents the export of
// some corner-case type declarations (but those are not handled correctly
// with with the textual export format either).
// TODO(gri) enable and remove once issues caused by it are fixed
const trackAllTypes = false
type exporter struct {
fset *token.FileSet
out bytes.Buffer
// object -> index maps, indexed in order of serialization
strIndex map[string]int
pkgIndex map[*types.Package]int
typIndex map[types.Type]int
// position encoding
posInfoFormat bool
prevFile string
prevLine int
// debugging support
written int // bytes written
indent int // for trace
}
// internalError represents an error generated inside this package.
type internalError string
func (e internalError) Error() string { return "gcimporter: " + string(e) }
func internalErrorf(format string, args ...interface{}) error {
return internalError(fmt.Sprintf(format, args...))
}
// BExportData returns binary export data for pkg.
// If no file set is provided, position info will be missing.
func BExportData(fset *token.FileSet, pkg *types.Package) (b []byte, err error) {
defer func() {
if e := recover(); e != nil {
if ierr, ok := e.(internalError); ok {
err = ierr
return
}
// Not an internal error; panic again.
panic(e)
}
}()
p := exporter{
fset: fset,
strIndex: map[string]int{"": 0}, // empty string is mapped to 0
pkgIndex: make(map[*types.Package]int),
typIndex: make(map[types.Type]int),
posInfoFormat: true, // TODO(gri) might become a flag, eventually
}
// write version info
// The version string must start with "version %d" where %d is the version
// number. Additional debugging information may follow after a blank; that
// text is ignored by the importer.
p.rawStringln(fmt.Sprintf("version %d", exportVersion))
var debug string
if debugFormat {
debug = "debug"
}
p.rawStringln(debug) // cannot use p.bool since it's affected by debugFormat; also want to see this clearly
p.bool(trackAllTypes)
p.bool(p.posInfoFormat)
// --- generic export data ---
// populate type map with predeclared "known" types
for index, typ := range predeclared() {
p.typIndex[typ] = index
}
if len(p.typIndex) != len(predeclared()) {
return nil, internalError("duplicate entries in type map?")
}
// write package data
p.pkg(pkg, true)
if trace {
p.tracef("\n")
}
// write objects
objcount := 0
scope := pkg.Scope()
for _, name := range scope.Names() {
if !ast.IsExported(name) {
continue
}
if trace {
p.tracef("\n")
}
p.obj(scope.Lookup(name))
objcount++
}
// indicate end of list
if trace {
p.tracef("\n")
}
p.tag(endTag)
// for self-verification only (redundant)
p.int(objcount)
if trace {
p.tracef("\n")
}
// --- end of export data ---
return p.out.Bytes(), nil
}
func (p *exporter) pkg(pkg *types.Package, emptypath bool) {
if pkg == nil {
panic(internalError("unexpected nil pkg"))
}
// if we saw the package before, write its index (>= 0)
if i, ok := p.pkgIndex[pkg]; ok {
p.index('P', i)
return
}
// otherwise, remember the package, write the package tag (< 0) and package data
if trace {
p.tracef("P%d = { ", len(p.pkgIndex))
defer p.tracef("} ")
}
p.pkgIndex[pkg] = len(p.pkgIndex)
p.tag(packageTag)
p.string(pkg.Name())
if emptypath {
p.string("")
} else {
p.string(pkg.Path())
}
}
func (p *exporter) obj(obj types.Object) {
switch obj := obj.(type) {
case *types.Const:
p.tag(constTag)
p.pos(obj)
p.qualifiedName(obj)
p.typ(obj.Type())
p.value(obj.Val())
case *types.TypeName:
if obj.IsAlias() {
p.tag(aliasTag)
p.pos(obj)
p.qualifiedName(obj)
} else {
p.tag(typeTag)
}
p.typ(obj.Type())
case *types.Var:
p.tag(varTag)
p.pos(obj)
p.qualifiedName(obj)
p.typ(obj.Type())
case *types.Func:
p.tag(funcTag)
p.pos(obj)
p.qualifiedName(obj)
sig := obj.Type().(*types.Signature)
p.paramList(sig.Params(), sig.Variadic())
p.paramList(sig.Results(), false)
default:
panic(internalErrorf("unexpected object %v (%T)", obj, obj))
}
}
func (p *exporter) pos(obj types.Object) {
if !p.posInfoFormat {
return
}
file, line := p.fileLine(obj)
if file == p.prevFile {
// common case: write line delta
// delta == 0 means different file or no line change
delta := line - p.prevLine
p.int(delta)
if delta == 0 {
p.int(-1) // -1 means no file change
}
} else {
// different file
p.int(0)
// Encode filename as length of common prefix with previous
// filename, followed by (possibly empty) suffix. Filenames
// frequently share path prefixes, so this can save a lot
// of space and make export data size less dependent on file
// path length. The suffix is unlikely to be empty because
// file names tend to end in ".go".
n := commonPrefixLen(p.prevFile, file)
p.int(n) // n >= 0
p.string(file[n:]) // write suffix only
p.prevFile = file
p.int(line)
}
p.prevLine = line
}
func (p *exporter) fileLine(obj types.Object) (file string, line int) {
if p.fset != nil {
pos := p.fset.Position(obj.Pos())
file = pos.Filename
line = pos.Line
}
return
}
func commonPrefixLen(a, b string) int {
if len(a) > len(b) {
a, b = b, a
}
// len(a) <= len(b)
i := 0
for i < len(a) && a[i] == b[i] {
i++
}
return i
}
func (p *exporter) qualifiedName(obj types.Object) {
p.string(obj.Name())
p.pkg(obj.Pkg(), false)
}
func (p *exporter) typ(t types.Type) {
if t == nil {
panic(internalError("nil type"))
}
// Possible optimization: Anonymous pointer types *T where
// T is a named type are common. We could canonicalize all
// such types *T to a single type PT = *T. This would lead
// to at most one *T entry in typIndex, and all future *T's
// would be encoded as the respective index directly. Would
// save 1 byte (pointerTag) per *T and reduce the typIndex
// size (at the cost of a canonicalization map). We can do
// this later, without encoding format change.
// if we saw the type before, write its index (>= 0)
if i, ok := p.typIndex[t]; ok {
p.index('T', i)
return
}
// otherwise, remember the type, write the type tag (< 0) and type data
if trackAllTypes {
if trace {
p.tracef("T%d = {>\n", len(p.typIndex))
defer p.tracef("<\n} ")
}
p.typIndex[t] = len(p.typIndex)
}
switch t := t.(type) {
case *types.Named:
if !trackAllTypes {
// if we don't track all types, track named types now
p.typIndex[t] = len(p.typIndex)
}
p.tag(namedTag)
p.pos(t.Obj())
p.qualifiedName(t.Obj())
p.typ(t.Underlying())
if !types.IsInterface(t) {
p.assocMethods(t)
}
case *types.Array:
p.tag(arrayTag)
p.int64(t.Len())
p.typ(t.Elem())
case *types.Slice:
p.tag(sliceTag)
p.typ(t.Elem())
case *dddSlice:
p.tag(dddTag)
p.typ(t.elem)
case *types.Struct:
p.tag(structTag)
p.fieldList(t)
case *types.Pointer:
p.tag(pointerTag)
p.typ(t.Elem())
case *types.Signature:
p.tag(signatureTag)
p.paramList(t.Params(), t.Variadic())
p.paramList(t.Results(), false)
case *types.Interface:
p.tag(interfaceTag)
p.iface(t)
case *types.Map:
p.tag(mapTag)
p.typ(t.Key())
p.typ(t.Elem())
case *types.Chan:
p.tag(chanTag)
p.int(int(3 - t.Dir())) // hack
p.typ(t.Elem())
default:
panic(internalErrorf("unexpected type %T: %s", t, t))
}
}
func (p *exporter) assocMethods(named *types.Named) {
// Sort methods (for determinism).
var methods []*types.Func
for i := 0; i < named.NumMethods(); i++ {
methods = append(methods, named.Method(i))
}
sort.Sort(methodsByName(methods))
p.int(len(methods))
if trace && methods != nil {
p.tracef("associated methods {>\n")
}
for i, m := range methods {
if trace && i > 0 {
p.tracef("\n")
}
p.pos(m)
name := m.Name()
p.string(name)
if !exported(name) {
p.pkg(m.Pkg(), false)
}
sig := m.Type().(*types.Signature)
p.paramList(types.NewTuple(sig.Recv()), false)
p.paramList(sig.Params(), sig.Variadic())
p.paramList(sig.Results(), false)
p.int(0) // dummy value for go:nointerface pragma - ignored by importer
}
if trace && methods != nil {
p.tracef("<\n} ")
}
}
type methodsByName []*types.Func
func (x methodsByName) Len() int { return len(x) }
func (x methodsByName) Swap(i, j int) { x[i], x[j] = x[j], x[i] }
func (x methodsByName) Less(i, j int) bool { return x[i].Name() < x[j].Name() }
func (p *exporter) fieldList(t *types.Struct) {
if trace && t.NumFields() > 0 {
p.tracef("fields {>\n")
defer p.tracef("<\n} ")
}
p.int(t.NumFields())
for i := 0; i < t.NumFields(); i++ {
if trace && i > 0 {
p.tracef("\n")
}
p.field(t.Field(i))
p.string(t.Tag(i))
}
}
func (p *exporter) field(f *types.Var) {
if !f.IsField() {
panic(internalError("field expected"))
}
p.pos(f)
p.fieldName(f)
p.typ(f.Type())
}
func (p *exporter) iface(t *types.Interface) {
// TODO(gri): enable importer to load embedded interfaces,
// then emit Embeddeds and ExplicitMethods separately here.
p.int(0)
n := t.NumMethods()
if trace && n > 0 {
p.tracef("methods {>\n")
defer p.tracef("<\n} ")
}
p.int(n)
for i := 0; i < n; i++ {
if trace && i > 0 {
p.tracef("\n")
}
p.method(t.Method(i))
}
}
func (p *exporter) method(m *types.Func) {
sig := m.Type().(*types.Signature)
if sig.Recv() == nil {
panic(internalError("method expected"))
}
p.pos(m)
p.string(m.Name())
if m.Name() != "_" && !ast.IsExported(m.Name()) {
p.pkg(m.Pkg(), false)
}
// interface method; no need to encode receiver.
p.paramList(sig.Params(), sig.Variadic())
p.paramList(sig.Results(), false)
}
func (p *exporter) fieldName(f *types.Var) {
name := f.Name()
if f.Anonymous() {
// anonymous field - we distinguish between 3 cases:
// 1) field name matches base type name and is exported
// 2) field name matches base type name and is not exported
// 3) field name doesn't match base type name (alias name)
bname := basetypeName(f.Type())
if name == bname {
if ast.IsExported(name) {
name = "" // 1) we don't need to know the field name or package
} else {
name = "?" // 2) use unexported name "?" to force package export
}
} else {
// 3) indicate alias and export name as is
// (this requires an extra "@" but this is a rare case)
p.string("@")
}
}
p.string(name)
if name != "" && !ast.IsExported(name) {
p.pkg(f.Pkg(), false)
}
}
func basetypeName(typ types.Type) string {
switch typ := deref(typ).(type) {
case *types.Basic:
return typ.Name()
case *types.Named:
return typ.Obj().Name()
default:
return "" // unnamed type
}
}
func (p *exporter) paramList(params *types.Tuple, variadic bool) {
// use negative length to indicate unnamed parameters
// (look at the first parameter only since either all
// names are present or all are absent)
n := params.Len()
if n > 0 && params.At(0).Name() == "" {
n = -n
}
p.int(n)
for i := 0; i < params.Len(); i++ {
q := params.At(i)
t := q.Type()
if variadic && i == params.Len()-1 {
t = &dddSlice{t.(*types.Slice).Elem()}
}
p.typ(t)
if n > 0 {
name := q.Name()
p.string(name)
if name != "_" {
p.pkg(q.Pkg(), false)
}
}
p.string("") // no compiler-specific info
}
}
func (p *exporter) value(x constant.Value) {
if trace {
p.tracef("= ")
}
switch x.Kind() {
case constant.Bool:
tag := falseTag
if constant.BoolVal(x) {
tag = trueTag
}
p.tag(tag)
case constant.Int:
if v, exact := constant.Int64Val(x); exact {
// common case: x fits into an int64 - use compact encoding
p.tag(int64Tag)
p.int64(v)
return
}
// uncommon case: large x - use float encoding
// (powers of 2 will be encoded efficiently with exponent)
p.tag(floatTag)
p.float(constant.ToFloat(x))
case constant.Float:
p.tag(floatTag)
p.float(x)
case constant.Complex:
p.tag(complexTag)
p.float(constant.Real(x))
p.float(constant.Imag(x))
case constant.String:
p.tag(stringTag)
p.string(constant.StringVal(x))
case constant.Unknown:
// package contains type errors
p.tag(unknownTag)
default:
panic(internalErrorf("unexpected value %v (%T)", x, x))
}
}
func (p *exporter) float(x constant.Value) {
if x.Kind() != constant.Float {
panic(internalErrorf("unexpected constant %v, want float", x))
}
// extract sign (there is no -0)
sign := constant.Sign(x)
if sign == 0 {
// x == 0
p.int(0)
return
}
// x != 0
var f big.Float
if v, exact := constant.Float64Val(x); exact {
// float64
f.SetFloat64(v)
} else if num, denom := constant.Num(x), constant.Denom(x); num.Kind() == constant.Int {
// TODO(gri): add big.Rat accessor to constant.Value.
r := valueToRat(num)
f.SetRat(r.Quo(r, valueToRat(denom)))
} else {
// Value too large to represent as a fraction => inaccessible.
// TODO(gri): add big.Float accessor to constant.Value.
f.SetFloat64(math.MaxFloat64) // FIXME
}
// extract exponent such that 0.5 <= m < 1.0
var m big.Float
exp := f.MantExp(&m)
// extract mantissa as *big.Int
// - set exponent large enough so mant satisfies mant.IsInt()
// - get *big.Int from mant
m.SetMantExp(&m, int(m.MinPrec()))
mant, acc := m.Int(nil)
if acc != big.Exact {
panic(internalError("internal error"))
}
p.int(sign)
p.int(exp)
p.string(string(mant.Bytes()))
}
func valueToRat(x constant.Value) *big.Rat {
// Convert little-endian to big-endian.
// I can't believe this is necessary.
bytes := constant.Bytes(x)
for i := 0; i < len(bytes)/2; i++ {
bytes[i], bytes[len(bytes)-1-i] = bytes[len(bytes)-1-i], bytes[i]
}
return new(big.Rat).SetInt(new(big.Int).SetBytes(bytes))
}
func (p *exporter) bool(b bool) bool {
if trace {
p.tracef("[")
defer p.tracef("= %v] ", b)
}
x := 0
if b {
x = 1
}
p.int(x)
return b
}
// ----------------------------------------------------------------------------
// Low-level encoders
func (p *exporter) index(marker byte, index int) {
if index < 0 {
panic(internalError("invalid index < 0"))
}
if debugFormat {
p.marker('t')
}
if trace {
p.tracef("%c%d ", marker, index)
}
p.rawInt64(int64(index))
}
func (p *exporter) tag(tag int) {
if tag >= 0 {
panic(internalError("invalid tag >= 0"))
}
if debugFormat {
p.marker('t')
}
if trace {
p.tracef("%s ", tagString[-tag])
}
p.rawInt64(int64(tag))
}
func (p *exporter) int(x int) {
p.int64(int64(x))
}
func (p *exporter) int64(x int64) {
if debugFormat {
p.marker('i')
}
if trace {
p.tracef("%d ", x)
}
p.rawInt64(x)
}
func (p *exporter) string(s string) {
if debugFormat {
p.marker('s')
}
if trace {
p.tracef("%q ", s)
}
// if we saw the string before, write its index (>= 0)
// (the empty string is mapped to 0)
if i, ok := p.strIndex[s]; ok {
p.rawInt64(int64(i))
return
}
// otherwise, remember string and write its negative length and bytes
p.strIndex[s] = len(p.strIndex)
p.rawInt64(-int64(len(s)))
for i := 0; i < len(s); i++ {
p.rawByte(s[i])
}
}
// marker emits a marker byte and position information which makes
// it easy for a reader to detect if it is "out of sync". Used for
// debugFormat format only.
func (p *exporter) marker(m byte) {
p.rawByte(m)
// Enable this for help tracking down the location
// of an incorrect marker when running in debugFormat.
if false && trace {
p.tracef("#%d ", p.written)
}
p.rawInt64(int64(p.written))
}
// rawInt64 should only be used by low-level encoders.
func (p *exporter) rawInt64(x int64) {
var tmp [binary.MaxVarintLen64]byte
n := binary.PutVarint(tmp[:], x)
for i := 0; i < n; i++ {
p.rawByte(tmp[i])
}
}
// rawStringln should only be used to emit the initial version string.
func (p *exporter) rawStringln(s string) {
for i := 0; i < len(s); i++ {
p.rawByte(s[i])
}
p.rawByte('\n')
}
// rawByte is the bottleneck interface to write to p.out.
// rawByte escapes b as follows (any encoding does that
// hides '$'):
//
// '$' => '|' 'S'
// '|' => '|' '|'
//
// Necessary so other tools can find the end of the
// export data by searching for "$$".
// rawByte should only be used by low-level encoders.
func (p *exporter) rawByte(b byte) {
switch b {
case '$':
// write '$' as '|' 'S'
b = 'S'
fallthrough
case '|':
// write '|' as '|' '|'
p.out.WriteByte('|')
p.written++
}
p.out.WriteByte(b)
p.written++
}
// tracef is like fmt.Printf but it rewrites the format string
// to take care of indentation.
func (p *exporter) tracef(format string, args ...interface{}) {
if strings.ContainsAny(format, "<>\n") {
var buf bytes.Buffer
for i := 0; i < len(format); i++ {
// no need to deal with runes
ch := format[i]
switch ch {
case '>':
p.indent++
continue
case '<':
p.indent--
continue
}
buf.WriteByte(ch)
if ch == '\n' {
for j := p.indent; j > 0; j-- {
buf.WriteString(". ")
}
}
}
format = buf.String()
}
fmt.Printf(format, args...)
}
// Debugging support.
// (tagString is only used when tracing is enabled)
var tagString = [...]string{
// Packages
-packageTag: "package",
// Types
-namedTag: "named type",
-arrayTag: "array",
-sliceTag: "slice",
-dddTag: "ddd",
-structTag: "struct",
-pointerTag: "pointer",
-signatureTag: "signature",
-interfaceTag: "interface",
-mapTag: "map",
-chanTag: "chan",
// Values
-falseTag: "false",
-trueTag: "true",
-int64Tag: "int64",
-floatTag: "float",
-fractionTag: "fraction",
-complexTag: "complex",
-stringTag: "string",
-unknownTag: "unknown",
// Type aliases
-aliasTag: "alias",
}

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// Copyright 2011 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 is a copy of $GOROOT/src/go/internal/gcimporter/exportdata.go.
// This file implements FindExportData.
package gcimporter
import (
"bufio"
"fmt"
"io"
"strconv"
"strings"
)
func readGopackHeader(r *bufio.Reader) (name string, size int, err error) {
// See $GOROOT/include/ar.h.
hdr := make([]byte, 16+12+6+6+8+10+2)
_, err = io.ReadFull(r, hdr)
if err != nil {
return
}
// leave for debugging
if false {
fmt.Printf("header: %s", hdr)
}
s := strings.TrimSpace(string(hdr[16+12+6+6+8:][:10]))
size, err = strconv.Atoi(s)
if err != nil || hdr[len(hdr)-2] != '`' || hdr[len(hdr)-1] != '\n' {
err = fmt.Errorf("invalid archive header")
return
}
name = strings.TrimSpace(string(hdr[:16]))
return
}
// FindExportData positions the reader r at the beginning of the
// export data section of an underlying GC-created object/archive
// file by reading from it. The reader must be positioned at the
// start of the file before calling this function. The hdr result
// is the string before the export data, either "$$" or "$$B".
//
func FindExportData(r *bufio.Reader) (hdr string, err error) {
// Read first line to make sure this is an object file.
line, err := r.ReadSlice('\n')
if err != nil {
err = fmt.Errorf("can't find export data (%v)", err)
return
}
if string(line) == "!<arch>\n" {
// Archive file. Scan to __.PKGDEF.
var name string
if name, _, err = readGopackHeader(r); err != nil {
return
}
// First entry should be __.PKGDEF.
if name != "__.PKGDEF" {
err = fmt.Errorf("go archive is missing __.PKGDEF")
return
}
// Read first line of __.PKGDEF data, so that line
// is once again the first line of the input.
if line, err = r.ReadSlice('\n'); err != nil {
err = fmt.Errorf("can't find export data (%v)", err)
return
}
}
// Now at __.PKGDEF in archive or still at beginning of file.
// Either way, line should begin with "go object ".
if !strings.HasPrefix(string(line), "go object ") {
err = fmt.Errorf("not a Go object file")
return
}
// Skip over object header to export data.
// Begins after first line starting with $$.
for line[0] != '$' {
if line, err = r.ReadSlice('\n'); err != nil {
err = fmt.Errorf("can't find export data (%v)", err)
return
}
}
hdr = string(line)
return
}

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// Copyright 2019 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.
// Indexed binary package export.
// This file was derived from $GOROOT/src/cmd/compile/internal/gc/iexport.go;
// see that file for specification of the format.
package gcimporter
import (
"bytes"
"encoding/binary"
"go/ast"
"go/constant"
"go/token"
"go/types"
"io"
"math/big"
"reflect"
"sort"
)
// Current indexed export format version. Increase with each format change.
// 0: Go1.11 encoding
const iexportVersion = 0
// IExportData returns the binary export data for pkg.
//
// If no file set is provided, position info will be missing.
// The package path of the top-level package will not be recorded,
// so that calls to IImportData can override with a provided package path.
func IExportData(fset *token.FileSet, pkg *types.Package) (b []byte, err error) {
defer func() {
if e := recover(); e != nil {
if ierr, ok := e.(internalError); ok {
err = ierr
return
}
// Not an internal error; panic again.
panic(e)
}
}()
p := iexporter{
out: bytes.NewBuffer(nil),
fset: fset,
allPkgs: map[*types.Package]bool{},
stringIndex: map[string]uint64{},
declIndex: map[types.Object]uint64{},
typIndex: map[types.Type]uint64{},
localpkg: pkg,
}
for i, pt := range predeclared() {
p.typIndex[pt] = uint64(i)
}
if len(p.typIndex) > predeclReserved {
panic(internalErrorf("too many predeclared types: %d > %d", len(p.typIndex), predeclReserved))
}
// Initialize work queue with exported declarations.
scope := pkg.Scope()
for _, name := range scope.Names() {
if ast.IsExported(name) {
p.pushDecl(scope.Lookup(name))
}
}
// Loop until no more work.
for !p.declTodo.empty() {
p.doDecl(p.declTodo.popHead())
}
// Append indices to data0 section.
dataLen := uint64(p.data0.Len())
w := p.newWriter()
w.writeIndex(p.declIndex)
w.flush()
// Assemble header.
var hdr intWriter
hdr.WriteByte('i')
hdr.uint64(iexportVersion)
hdr.uint64(uint64(p.strings.Len()))
hdr.uint64(dataLen)
// Flush output.
io.Copy(p.out, &hdr)
io.Copy(p.out, &p.strings)
io.Copy(p.out, &p.data0)
return p.out.Bytes(), nil
}
// writeIndex writes out an object index. mainIndex indicates whether
// we're writing out the main index, which is also read by
// non-compiler tools and includes a complete package description
// (i.e., name and height).
func (w *exportWriter) writeIndex(index map[types.Object]uint64) {
// Build a map from packages to objects from that package.
pkgObjs := map[*types.Package][]types.Object{}
// For the main index, make sure to include every package that
// we reference, even if we're not exporting (or reexporting)
// any symbols from it.
pkgObjs[w.p.localpkg] = nil
for pkg := range w.p.allPkgs {
pkgObjs[pkg] = nil
}
for obj := range index {
pkgObjs[obj.Pkg()] = append(pkgObjs[obj.Pkg()], obj)
}
var pkgs []*types.Package
for pkg, objs := range pkgObjs {
pkgs = append(pkgs, pkg)
sort.Slice(objs, func(i, j int) bool {
return objs[i].Name() < objs[j].Name()
})
}
sort.Slice(pkgs, func(i, j int) bool {
return w.exportPath(pkgs[i]) < w.exportPath(pkgs[j])
})
w.uint64(uint64(len(pkgs)))
for _, pkg := range pkgs {
w.string(w.exportPath(pkg))
w.string(pkg.Name())
w.uint64(uint64(0)) // package height is not needed for go/types
objs := pkgObjs[pkg]
w.uint64(uint64(len(objs)))
for _, obj := range objs {
w.string(obj.Name())
w.uint64(index[obj])
}
}
}
type iexporter struct {
fset *token.FileSet
out *bytes.Buffer
localpkg *types.Package
// allPkgs tracks all packages that have been referenced by
// the export data, so we can ensure to include them in the
// main index.
allPkgs map[*types.Package]bool
declTodo objQueue
strings intWriter
stringIndex map[string]uint64
data0 intWriter
declIndex map[types.Object]uint64
typIndex map[types.Type]uint64
}
// stringOff returns the offset of s within the string section.
// If not already present, it's added to the end.
func (p *iexporter) stringOff(s string) uint64 {
off, ok := p.stringIndex[s]
if !ok {
off = uint64(p.strings.Len())
p.stringIndex[s] = off
p.strings.uint64(uint64(len(s)))
p.strings.WriteString(s)
}
return off
}
// pushDecl adds n to the declaration work queue, if not already present.
func (p *iexporter) pushDecl(obj types.Object) {
// Package unsafe is known to the compiler and predeclared.
assert(obj.Pkg() != types.Unsafe)
if _, ok := p.declIndex[obj]; ok {
return
}
p.declIndex[obj] = ^uint64(0) // mark n present in work queue
p.declTodo.pushTail(obj)
}
// exportWriter handles writing out individual data section chunks.
type exportWriter struct {
p *iexporter
data intWriter
currPkg *types.Package
prevFile string
prevLine int64
}
func (w *exportWriter) exportPath(pkg *types.Package) string {
if pkg == w.p.localpkg {
return ""
}
return pkg.Path()
}
func (p *iexporter) doDecl(obj types.Object) {
w := p.newWriter()
w.setPkg(obj.Pkg(), false)
switch obj := obj.(type) {
case *types.Var:
w.tag('V')
w.pos(obj.Pos())
w.typ(obj.Type(), obj.Pkg())
case *types.Func:
sig, _ := obj.Type().(*types.Signature)
if sig.Recv() != nil {
panic(internalErrorf("unexpected method: %v", sig))
}
w.tag('F')
w.pos(obj.Pos())
w.signature(sig)
case *types.Const:
w.tag('C')
w.pos(obj.Pos())
w.value(obj.Type(), obj.Val())
case *types.TypeName:
if obj.IsAlias() {
w.tag('A')
w.pos(obj.Pos())
w.typ(obj.Type(), obj.Pkg())
break
}
// Defined type.
w.tag('T')
w.pos(obj.Pos())
underlying := obj.Type().Underlying()
w.typ(underlying, obj.Pkg())
t := obj.Type()
if types.IsInterface(t) {
break
}
named, ok := t.(*types.Named)
if !ok {
panic(internalErrorf("%s is not a defined type", t))
}
n := named.NumMethods()
w.uint64(uint64(n))
for i := 0; i < n; i++ {
m := named.Method(i)
w.pos(m.Pos())
w.string(m.Name())
sig, _ := m.Type().(*types.Signature)
w.param(sig.Recv())
w.signature(sig)
}
default:
panic(internalErrorf("unexpected object: %v", obj))
}
p.declIndex[obj] = w.flush()
}
func (w *exportWriter) tag(tag byte) {
w.data.WriteByte(tag)
}
func (w *exportWriter) pos(pos token.Pos) {
if w.p.fset == nil {
w.int64(0)
return
}
p := w.p.fset.Position(pos)
file := p.Filename
line := int64(p.Line)
// When file is the same as the last position (common case),
// we can save a few bytes by delta encoding just the line
// number.
//
// Note: Because data objects may be read out of order (or not
// at all), we can only apply delta encoding within a single
// object. This is handled implicitly by tracking prevFile and
// prevLine as fields of exportWriter.
if file == w.prevFile {
delta := line - w.prevLine
w.int64(delta)
if delta == deltaNewFile {
w.int64(-1)
}
} else {
w.int64(deltaNewFile)
w.int64(line) // line >= 0
w.string(file)
w.prevFile = file
}
w.prevLine = line
}
func (w *exportWriter) pkg(pkg *types.Package) {
// Ensure any referenced packages are declared in the main index.
w.p.allPkgs[pkg] = true
w.string(w.exportPath(pkg))
}
func (w *exportWriter) qualifiedIdent(obj types.Object) {
// Ensure any referenced declarations are written out too.
w.p.pushDecl(obj)
w.string(obj.Name())
w.pkg(obj.Pkg())
}
func (w *exportWriter) typ(t types.Type, pkg *types.Package) {
w.data.uint64(w.p.typOff(t, pkg))
}
func (p *iexporter) newWriter() *exportWriter {
return &exportWriter{p: p}
}
func (w *exportWriter) flush() uint64 {
off := uint64(w.p.data0.Len())
io.Copy(&w.p.data0, &w.data)
return off
}
func (p *iexporter) typOff(t types.Type, pkg *types.Package) uint64 {
off, ok := p.typIndex[t]
if !ok {
w := p.newWriter()
w.doTyp(t, pkg)
off = predeclReserved + w.flush()
p.typIndex[t] = off
}
return off
}
func (w *exportWriter) startType(k itag) {
w.data.uint64(uint64(k))
}
func (w *exportWriter) doTyp(t types.Type, pkg *types.Package) {
switch t := t.(type) {
case *types.Named:
w.startType(definedType)
w.qualifiedIdent(t.Obj())
case *types.Pointer:
w.startType(pointerType)
w.typ(t.Elem(), pkg)
case *types.Slice:
w.startType(sliceType)
w.typ(t.Elem(), pkg)
case *types.Array:
w.startType(arrayType)
w.uint64(uint64(t.Len()))
w.typ(t.Elem(), pkg)
case *types.Chan:
w.startType(chanType)
// 1 RecvOnly; 2 SendOnly; 3 SendRecv
var dir uint64
switch t.Dir() {
case types.RecvOnly:
dir = 1
case types.SendOnly:
dir = 2
case types.SendRecv:
dir = 3
}
w.uint64(dir)
w.typ(t.Elem(), pkg)
case *types.Map:
w.startType(mapType)
w.typ(t.Key(), pkg)
w.typ(t.Elem(), pkg)
case *types.Signature:
w.startType(signatureType)
w.setPkg(pkg, true)
w.signature(t)
case *types.Struct:
w.startType(structType)
w.setPkg(pkg, true)
n := t.NumFields()
w.uint64(uint64(n))
for i := 0; i < n; i++ {
f := t.Field(i)
w.pos(f.Pos())
w.string(f.Name())
w.typ(f.Type(), pkg)
w.bool(f.Anonymous())
w.string(t.Tag(i)) // note (or tag)
}
case *types.Interface:
w.startType(interfaceType)
w.setPkg(pkg, true)
n := t.NumEmbeddeds()
w.uint64(uint64(n))
for i := 0; i < n; i++ {
f := t.Embedded(i)
w.pos(f.Obj().Pos())
w.typ(f.Obj().Type(), f.Obj().Pkg())
}
n = t.NumExplicitMethods()
w.uint64(uint64(n))
for i := 0; i < n; i++ {
m := t.ExplicitMethod(i)
w.pos(m.Pos())
w.string(m.Name())
sig, _ := m.Type().(*types.Signature)
w.signature(sig)
}
default:
panic(internalErrorf("unexpected type: %v, %v", t, reflect.TypeOf(t)))
}
}
func (w *exportWriter) setPkg(pkg *types.Package, write bool) {
if write {
w.pkg(pkg)
}
w.currPkg = pkg
}
func (w *exportWriter) signature(sig *types.Signature) {
w.paramList(sig.Params())
w.paramList(sig.Results())
if sig.Params().Len() > 0 {
w.bool(sig.Variadic())
}
}
func (w *exportWriter) paramList(tup *types.Tuple) {
n := tup.Len()
w.uint64(uint64(n))
for i := 0; i < n; i++ {
w.param(tup.At(i))
}
}
func (w *exportWriter) param(obj types.Object) {
w.pos(obj.Pos())
w.localIdent(obj)
w.typ(obj.Type(), obj.Pkg())
}
func (w *exportWriter) value(typ types.Type, v constant.Value) {
w.typ(typ, nil)
switch v.Kind() {
case constant.Bool:
w.bool(constant.BoolVal(v))
case constant.Int:
var i big.Int
if i64, exact := constant.Int64Val(v); exact {
i.SetInt64(i64)
} else if ui64, exact := constant.Uint64Val(v); exact {
i.SetUint64(ui64)
} else {
i.SetString(v.ExactString(), 10)
}
w.mpint(&i, typ)
case constant.Float:
f := constantToFloat(v)
w.mpfloat(f, typ)
case constant.Complex:
w.mpfloat(constantToFloat(constant.Real(v)), typ)
w.mpfloat(constantToFloat(constant.Imag(v)), typ)
case constant.String:
w.string(constant.StringVal(v))
case constant.Unknown:
// package contains type errors
default:
panic(internalErrorf("unexpected value %v (%T)", v, v))
}
}
// constantToFloat converts a constant.Value with kind constant.Float to a
// big.Float.
func constantToFloat(x constant.Value) *big.Float {
assert(x.Kind() == constant.Float)
// Use the same floating-point precision (512) as cmd/compile
// (see Mpprec in cmd/compile/internal/gc/mpfloat.go).
const mpprec = 512
var f big.Float
f.SetPrec(mpprec)
if v, exact := constant.Float64Val(x); exact {
// float64
f.SetFloat64(v)
} else if num, denom := constant.Num(x), constant.Denom(x); num.Kind() == constant.Int {
// TODO(gri): add big.Rat accessor to constant.Value.
n := valueToRat(num)
d := valueToRat(denom)
f.SetRat(n.Quo(n, d))
} else {
// Value too large to represent as a fraction => inaccessible.
// TODO(gri): add big.Float accessor to constant.Value.
_, ok := f.SetString(x.ExactString())
assert(ok)
}
return &f
}
// mpint exports a multi-precision integer.
//
// For unsigned types, small values are written out as a single
// byte. Larger values are written out as a length-prefixed big-endian
// byte string, where the length prefix is encoded as its complement.
// For example, bytes 0, 1, and 2 directly represent the integer
// values 0, 1, and 2; while bytes 255, 254, and 253 indicate a 1-,
// 2-, and 3-byte big-endian string follow.
//
// Encoding for signed types use the same general approach as for
// unsigned types, except small values use zig-zag encoding and the
// bottom bit of length prefix byte for large values is reserved as a
// sign bit.
//
// The exact boundary between small and large encodings varies
// according to the maximum number of bytes needed to encode a value
// of type typ. As a special case, 8-bit types are always encoded as a
// single byte.
//
// TODO(mdempsky): Is this level of complexity really worthwhile?
func (w *exportWriter) mpint(x *big.Int, typ types.Type) {
basic, ok := typ.Underlying().(*types.Basic)
if !ok {
panic(internalErrorf("unexpected type %v (%T)", typ.Underlying(), typ.Underlying()))
}
signed, maxBytes := intSize(basic)
negative := x.Sign() < 0
if !signed && negative {
panic(internalErrorf("negative unsigned integer; type %v, value %v", typ, x))
}
b := x.Bytes()
if len(b) > 0 && b[0] == 0 {
panic(internalErrorf("leading zeros"))
}
if uint(len(b)) > maxBytes {
panic(internalErrorf("bad mpint length: %d > %d (type %v, value %v)", len(b), maxBytes, typ, x))
}
maxSmall := 256 - maxBytes
if signed {
maxSmall = 256 - 2*maxBytes
}
if maxBytes == 1 {
maxSmall = 256
}
// Check if x can use small value encoding.
if len(b) <= 1 {
var ux uint
if len(b) == 1 {
ux = uint(b[0])
}
if signed {
ux <<= 1
if negative {
ux--
}
}
if ux < maxSmall {
w.data.WriteByte(byte(ux))
return
}
}
n := 256 - uint(len(b))
if signed {
n = 256 - 2*uint(len(b))
if negative {
n |= 1
}
}
if n < maxSmall || n >= 256 {
panic(internalErrorf("encoding mistake: %d, %v, %v => %d", len(b), signed, negative, n))
}
w.data.WriteByte(byte(n))
w.data.Write(b)
}
// mpfloat exports a multi-precision floating point number.
//
// The number's value is decomposed into mantissa × 2**exponent, where
// mantissa is an integer. The value is written out as mantissa (as a
// multi-precision integer) and then the exponent, except exponent is
// omitted if mantissa is zero.
func (w *exportWriter) mpfloat(f *big.Float, typ types.Type) {
if f.IsInf() {
panic("infinite constant")
}
// Break into f = mant × 2**exp, with 0.5 <= mant < 1.
var mant big.Float
exp := int64(f.MantExp(&mant))
// Scale so that mant is an integer.
prec := mant.MinPrec()
mant.SetMantExp(&mant, int(prec))
exp -= int64(prec)
manti, acc := mant.Int(nil)
if acc != big.Exact {
panic(internalErrorf("mantissa scaling failed for %f (%s)", f, acc))
}
w.mpint(manti, typ)
if manti.Sign() != 0 {
w.int64(exp)
}
}
func (w *exportWriter) bool(b bool) bool {
var x uint64
if b {
x = 1
}
w.uint64(x)
return b
}
func (w *exportWriter) int64(x int64) { w.data.int64(x) }
func (w *exportWriter) uint64(x uint64) { w.data.uint64(x) }
func (w *exportWriter) string(s string) { w.uint64(w.p.stringOff(s)) }
func (w *exportWriter) localIdent(obj types.Object) {
// Anonymous parameters.
if obj == nil {
w.string("")
return
}
name := obj.Name()
if name == "_" {
w.string("_")
return
}
w.string(name)
}
type intWriter struct {
bytes.Buffer
}
func (w *intWriter) int64(x int64) {
var buf [binary.MaxVarintLen64]byte
n := binary.PutVarint(buf[:], x)
w.Write(buf[:n])
}
func (w *intWriter) uint64(x uint64) {
var buf [binary.MaxVarintLen64]byte
n := binary.PutUvarint(buf[:], x)
w.Write(buf[:n])
}
func assert(cond bool) {
if !cond {
panic("internal error: assertion failed")
}
}
// The below is copied from go/src/cmd/compile/internal/gc/syntax.go.
// objQueue is a FIFO queue of types.Object. The zero value of objQueue is
// a ready-to-use empty queue.
type objQueue struct {
ring []types.Object
head, tail int
}
// empty returns true if q contains no Nodes.
func (q *objQueue) empty() bool {
return q.head == q.tail
}
// pushTail appends n to the tail of the queue.
func (q *objQueue) pushTail(obj types.Object) {
if len(q.ring) == 0 {
q.ring = make([]types.Object, 16)
} else if q.head+len(q.ring) == q.tail {
// Grow the ring.
nring := make([]types.Object, len(q.ring)*2)
// Copy the old elements.
part := q.ring[q.head%len(q.ring):]
if q.tail-q.head <= len(part) {
part = part[:q.tail-q.head]
copy(nring, part)
} else {
pos := copy(nring, part)
copy(nring[pos:], q.ring[:q.tail%len(q.ring)])
}
q.ring, q.head, q.tail = nring, 0, q.tail-q.head
}
q.ring[q.tail%len(q.ring)] = obj
q.tail++
}
// popHead pops a node from the head of the queue. It panics if q is empty.
func (q *objQueue) popHead() types.Object {
if q.empty() {
panic("dequeue empty")
}
obj := q.ring[q.head%len(q.ring)]
q.head++
return obj
}

630
vendor/golang.org/x/tools/go/internal/gcimporter/iimport.go generated vendored Normal file
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@ -0,0 +1,630 @@
// 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.
// Indexed package import.
// See cmd/compile/internal/gc/iexport.go for the export data format.
// This file is a copy of $GOROOT/src/go/internal/gcimporter/iimport.go.
package gcimporter
import (
"bytes"
"encoding/binary"
"fmt"
"go/constant"
"go/token"
"go/types"
"io"
"sort"
)
type intReader struct {
*bytes.Reader
path string
}
func (r *intReader) int64() int64 {
i, err := binary.ReadVarint(r.Reader)
if err != nil {
errorf("import %q: read varint error: %v", r.path, err)
}
return i
}
func (r *intReader) uint64() uint64 {
i, err := binary.ReadUvarint(r.Reader)
if err != nil {
errorf("import %q: read varint error: %v", r.path, err)
}
return i
}
const predeclReserved = 32
type itag uint64
const (
// Types
definedType itag = iota
pointerType
sliceType
arrayType
chanType
mapType
signatureType
structType
interfaceType
)
// IImportData imports a package from the serialized package data
// and returns the number of bytes consumed and a reference to the package.
// If the export data version is not recognized or the format is otherwise
// compromised, an error is returned.
func IImportData(fset *token.FileSet, imports map[string]*types.Package, data []byte, path string) (_ int, pkg *types.Package, err error) {
const currentVersion = 1
version := int64(-1)
defer func() {
if e := recover(); e != nil {
if version > currentVersion {
err = fmt.Errorf("cannot import %q (%v), export data is newer version - update tool", path, e)
} else {
err = fmt.Errorf("cannot import %q (%v), possibly version skew - reinstall package", path, e)
}
}
}()
r := &intReader{bytes.NewReader(data), path}
version = int64(r.uint64())
switch version {
case currentVersion, 0:
default:
errorf("unknown iexport format version %d", version)
}
sLen := int64(r.uint64())
dLen := int64(r.uint64())
whence, _ := r.Seek(0, io.SeekCurrent)
stringData := data[whence : whence+sLen]
declData := data[whence+sLen : whence+sLen+dLen]
r.Seek(sLen+dLen, io.SeekCurrent)
p := iimporter{
ipath: path,
version: int(version),
stringData: stringData,
stringCache: make(map[uint64]string),
pkgCache: make(map[uint64]*types.Package),
declData: declData,
pkgIndex: make(map[*types.Package]map[string]uint64),
typCache: make(map[uint64]types.Type),
fake: fakeFileSet{
fset: fset,
files: make(map[string]*token.File),
},
}
for i, pt := range predeclared() {
p.typCache[uint64(i)] = pt
}
pkgList := make([]*types.Package, r.uint64())
for i := range pkgList {
pkgPathOff := r.uint64()
pkgPath := p.stringAt(pkgPathOff)
pkgName := p.stringAt(r.uint64())
_ = r.uint64() // package height; unused by go/types
if pkgPath == "" {
pkgPath = path
}
pkg := imports[pkgPath]
if pkg == nil {
pkg = types.NewPackage(pkgPath, pkgName)
imports[pkgPath] = pkg
} else if pkg.Name() != pkgName {
errorf("conflicting names %s and %s for package %q", pkg.Name(), pkgName, path)
}
p.pkgCache[pkgPathOff] = pkg
nameIndex := make(map[string]uint64)
for nSyms := r.uint64(); nSyms > 0; nSyms-- {
name := p.stringAt(r.uint64())
nameIndex[name] = r.uint64()
}
p.pkgIndex[pkg] = nameIndex
pkgList[i] = pkg
}
if len(pkgList) == 0 {
errorf("no packages found for %s", path)
panic("unreachable")
}
p.ipkg = pkgList[0]
names := make([]string, 0, len(p.pkgIndex[p.ipkg]))
for name := range p.pkgIndex[p.ipkg] {
names = append(names, name)
}
sort.Strings(names)
for _, name := range names {
p.doDecl(p.ipkg, name)
}
for _, typ := range p.interfaceList {
typ.Complete()
}
// record all referenced packages as imports
list := append(([]*types.Package)(nil), pkgList[1:]...)
sort.Sort(byPath(list))
p.ipkg.SetImports(list)
// package was imported completely and without errors
p.ipkg.MarkComplete()
consumed, _ := r.Seek(0, io.SeekCurrent)
return int(consumed), p.ipkg, nil
}
type iimporter struct {
ipath string
ipkg *types.Package
version int
stringData []byte
stringCache map[uint64]string
pkgCache map[uint64]*types.Package
declData []byte
pkgIndex map[*types.Package]map[string]uint64
typCache map[uint64]types.Type
fake fakeFileSet
interfaceList []*types.Interface
}
func (p *iimporter) doDecl(pkg *types.Package, name string) {
// See if we've already imported this declaration.
if obj := pkg.Scope().Lookup(name); obj != nil {
return
}
off, ok := p.pkgIndex[pkg][name]
if !ok {
errorf("%v.%v not in index", pkg, name)
}
r := &importReader{p: p, currPkg: pkg}
r.declReader.Reset(p.declData[off:])
r.obj(name)
}
func (p *iimporter) stringAt(off uint64) string {
if s, ok := p.stringCache[off]; ok {
return s
}
slen, n := binary.Uvarint(p.stringData[off:])
if n <= 0 {
errorf("varint failed")
}
spos := off + uint64(n)
s := string(p.stringData[spos : spos+slen])
p.stringCache[off] = s
return s
}
func (p *iimporter) pkgAt(off uint64) *types.Package {
if pkg, ok := p.pkgCache[off]; ok {
return pkg
}
path := p.stringAt(off)
if path == p.ipath {
return p.ipkg
}
errorf("missing package %q in %q", path, p.ipath)
return nil
}
func (p *iimporter) typAt(off uint64, base *types.Named) types.Type {
if t, ok := p.typCache[off]; ok && (base == nil || !isInterface(t)) {
return t
}
if off < predeclReserved {
errorf("predeclared type missing from cache: %v", off)
}
r := &importReader{p: p}
r.declReader.Reset(p.declData[off-predeclReserved:])
t := r.doType(base)
if base == nil || !isInterface(t) {
p.typCache[off] = t
}
return t
}
type importReader struct {
p *iimporter
declReader bytes.Reader
currPkg *types.Package
prevFile string
prevLine int64
prevColumn int64
}
func (r *importReader) obj(name string) {
tag := r.byte()
pos := r.pos()
switch tag {
case 'A':
typ := r.typ()
r.declare(types.NewTypeName(pos, r.currPkg, name, typ))
case 'C':
typ, val := r.value()
r.declare(types.NewConst(pos, r.currPkg, name, typ, val))
case 'F':
sig := r.signature(nil)
r.declare(types.NewFunc(pos, r.currPkg, name, sig))
case 'T':
// Types can be recursive. We need to setup a stub
// declaration before recursing.
obj := types.NewTypeName(pos, r.currPkg, name, nil)
named := types.NewNamed(obj, nil, nil)
r.declare(obj)
underlying := r.p.typAt(r.uint64(), named).Underlying()
named.SetUnderlying(underlying)
if !isInterface(underlying) {
for n := r.uint64(); n > 0; n-- {
mpos := r.pos()
mname := r.ident()
recv := r.param()
msig := r.signature(recv)
named.AddMethod(types.NewFunc(mpos, r.currPkg, mname, msig))
}
}
case 'V':
typ := r.typ()
r.declare(types.NewVar(pos, r.currPkg, name, typ))
default:
errorf("unexpected tag: %v", tag)
}
}
func (r *importReader) declare(obj types.Object) {
obj.Pkg().Scope().Insert(obj)
}
func (r *importReader) value() (typ types.Type, val constant.Value) {
typ = r.typ()
switch b := typ.Underlying().(*types.Basic); b.Info() & types.IsConstType {
case types.IsBoolean:
val = constant.MakeBool(r.bool())
case types.IsString:
val = constant.MakeString(r.string())
case types.IsInteger:
val = r.mpint(b)
case types.IsFloat:
val = r.mpfloat(b)
case types.IsComplex:
re := r.mpfloat(b)
im := r.mpfloat(b)
val = constant.BinaryOp(re, token.ADD, constant.MakeImag(im))
default:
if b.Kind() == types.Invalid {
val = constant.MakeUnknown()
return
}
errorf("unexpected type %v", typ) // panics
panic("unreachable")
}
return
}
func intSize(b *types.Basic) (signed bool, maxBytes uint) {
if (b.Info() & types.IsUntyped) != 0 {
return true, 64
}
switch b.Kind() {
case types.Float32, types.Complex64:
return true, 3
case types.Float64, types.Complex128:
return true, 7
}
signed = (b.Info() & types.IsUnsigned) == 0
switch b.Kind() {
case types.Int8, types.Uint8:
maxBytes = 1
case types.Int16, types.Uint16:
maxBytes = 2
case types.Int32, types.Uint32:
maxBytes = 4
default:
maxBytes = 8
}
return
}
func (r *importReader) mpint(b *types.Basic) constant.Value {
signed, maxBytes := intSize(b)
maxSmall := 256 - maxBytes
if signed {
maxSmall = 256 - 2*maxBytes
}
if maxBytes == 1 {
maxSmall = 256
}
n, _ := r.declReader.ReadByte()
if uint(n) < maxSmall {
v := int64(n)
if signed {
v >>= 1
if n&1 != 0 {
v = ^v
}
}
return constant.MakeInt64(v)
}
v := -n
if signed {
v = -(n &^ 1) >> 1
}
if v < 1 || uint(v) > maxBytes {
errorf("weird decoding: %v, %v => %v", n, signed, v)
}
buf := make([]byte, v)
io.ReadFull(&r.declReader, buf)
// convert to little endian
// TODO(gri) go/constant should have a more direct conversion function
// (e.g., once it supports a big.Float based implementation)
for i, j := 0, len(buf)-1; i < j; i, j = i+1, j-1 {
buf[i], buf[j] = buf[j], buf[i]
}
x := constant.MakeFromBytes(buf)
if signed && n&1 != 0 {
x = constant.UnaryOp(token.SUB, x, 0)
}
return x
}
func (r *importReader) mpfloat(b *types.Basic) constant.Value {
x := r.mpint(b)
if constant.Sign(x) == 0 {
return x
}
exp := r.int64()
switch {
case exp > 0:
x = constant.Shift(x, token.SHL, uint(exp))
case exp < 0:
d := constant.Shift(constant.MakeInt64(1), token.SHL, uint(-exp))
x = constant.BinaryOp(x, token.QUO, d)
}
return x
}
func (r *importReader) ident() string {
return r.string()
}
func (r *importReader) qualifiedIdent() (*types.Package, string) {
name := r.string()
pkg := r.pkg()
return pkg, name
}
func (r *importReader) pos() token.Pos {
if r.p.version >= 1 {
r.posv1()
} else {
r.posv0()
}
if r.prevFile == "" && r.prevLine == 0 && r.prevColumn == 0 {
return token.NoPos
}
return r.p.fake.pos(r.prevFile, int(r.prevLine), int(r.prevColumn))
}
func (r *importReader) posv0() {
delta := r.int64()
if delta != deltaNewFile {
r.prevLine += delta
} else if l := r.int64(); l == -1 {
r.prevLine += deltaNewFile
} else {
r.prevFile = r.string()
r.prevLine = l
}
}
func (r *importReader) posv1() {
delta := r.int64()
r.prevColumn += delta >> 1
if delta&1 != 0 {
delta = r.int64()
r.prevLine += delta >> 1
if delta&1 != 0 {
r.prevFile = r.string()
}
}
}
func (r *importReader) typ() types.Type {
return r.p.typAt(r.uint64(), nil)
}
func isInterface(t types.Type) bool {
_, ok := t.(*types.Interface)
return ok
}
func (r *importReader) pkg() *types.Package { return r.p.pkgAt(r.uint64()) }
func (r *importReader) string() string { return r.p.stringAt(r.uint64()) }
func (r *importReader) doType(base *types.Named) types.Type {
switch k := r.kind(); k {
default:
errorf("unexpected kind tag in %q: %v", r.p.ipath, k)
return nil
case definedType:
pkg, name := r.qualifiedIdent()
r.p.doDecl(pkg, name)
return pkg.Scope().Lookup(name).(*types.TypeName).Type()
case pointerType:
return types.NewPointer(r.typ())
case sliceType:
return types.NewSlice(r.typ())
case arrayType:
n := r.uint64()
return types.NewArray(r.typ(), int64(n))
case chanType:
dir := chanDir(int(r.uint64()))
return types.NewChan(dir, r.typ())
case mapType:
return types.NewMap(r.typ(), r.typ())
case signatureType:
r.currPkg = r.pkg()
return r.signature(nil)
case structType:
r.currPkg = r.pkg()
fields := make([]*types.Var, r.uint64())
tags := make([]string, len(fields))
for i := range fields {
fpos := r.pos()
fname := r.ident()
ftyp := r.typ()
emb := r.bool()
tag := r.string()
fields[i] = types.NewField(fpos, r.currPkg, fname, ftyp, emb)
tags[i] = tag
}
return types.NewStruct(fields, tags)
case interfaceType:
r.currPkg = r.pkg()
embeddeds := make([]types.Type, r.uint64())
for i := range embeddeds {
_ = r.pos()
embeddeds[i] = r.typ()
}
methods := make([]*types.Func, r.uint64())
for i := range methods {
mpos := r.pos()
mname := r.ident()
// TODO(mdempsky): Matches bimport.go, but I
// don't agree with this.
var recv *types.Var
if base != nil {
recv = types.NewVar(token.NoPos, r.currPkg, "", base)
}
msig := r.signature(recv)
methods[i] = types.NewFunc(mpos, r.currPkg, mname, msig)
}
typ := newInterface(methods, embeddeds)
r.p.interfaceList = append(r.p.interfaceList, typ)
return typ
}
}
func (r *importReader) kind() itag {
return itag(r.uint64())
}
func (r *importReader) signature(recv *types.Var) *types.Signature {
params := r.paramList()
results := r.paramList()
variadic := params.Len() > 0 && r.bool()
return types.NewSignature(recv, params, results, variadic)
}
func (r *importReader) paramList() *types.Tuple {
xs := make([]*types.Var, r.uint64())
for i := range xs {
xs[i] = r.param()
}
return types.NewTuple(xs...)
}
func (r *importReader) param() *types.Var {
pos := r.pos()
name := r.ident()
typ := r.typ()
return types.NewParam(pos, r.currPkg, name, typ)
}
func (r *importReader) bool() bool {
return r.uint64() != 0
}
func (r *importReader) int64() int64 {
n, err := binary.ReadVarint(&r.declReader)
if err != nil {
errorf("readVarint: %v", err)
}
return n
}
func (r *importReader) uint64() uint64 {
n, err := binary.ReadUvarint(&r.declReader)
if err != nil {
errorf("readUvarint: %v", err)
}
return n
}
func (r *importReader) byte() byte {
x, err := r.declReader.ReadByte()
if err != nil {
errorf("declReader.ReadByte: %v", err)
}
return x
}

21
vendor/golang.org/x/tools/go/internal/gcimporter/newInterface10.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.
// +build !go1.11
package gcimporter
import "go/types"
func newInterface(methods []*types.Func, embeddeds []types.Type) *types.Interface {
named := make([]*types.Named, len(embeddeds))
for i, e := range embeddeds {
var ok bool
named[i], ok = e.(*types.Named)
if !ok {
panic("embedding of non-defined interfaces in interfaces is not supported before Go 1.11")
}
}
return types.NewInterface(methods, named)
}

13
vendor/golang.org/x/tools/go/internal/gcimporter/newInterface11.go generated vendored Normal file
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@ -0,0 +1,13 @@
// 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.
// +build go1.11
package gcimporter
import "go/types"
func newInterface(methods []*types.Func, embeddeds []types.Type) *types.Interface {
return types.NewInterfaceType(methods, embeddeds)
}

49
vendor/golang.org/x/tools/go/internal/packagesdriver/sizes.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 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 strings.Contains(rawErr.Error(), "cannot find main module") {
// 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
}

221
vendor/golang.org/x/tools/go/packages/doc.go generated vendored Normal file
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@ -0,0 +1,221 @@
// Copyright 2018 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
/*
Package packages loads Go packages for inspection and analysis.
The Load function takes as input a list of patterns and return a list of Package
structs describing individual packages matched by those patterns.
The LoadMode controls the amount of detail in the loaded packages.
Load passes most patterns directly to the underlying build tool,
but all patterns with the prefix "query=", where query is a
non-empty string of letters from [a-z], are reserved and may be
interpreted as query operators.
Two query operators are currently supported: "file" and "pattern".
The query "file=path/to/file.go" matches the package or packages enclosing
the Go source file path/to/file.go. For example "file=~/go/src/fmt/print.go"
might return the packages "fmt" and "fmt [fmt.test]".
The query "pattern=string" causes "string" to be passed directly to
the underlying build tool. In most cases this is unnecessary,
but an application can use Load("pattern=" + x) as an escaping mechanism
to ensure that x is not interpreted as a query operator if it contains '='.
All other query operators are reserved for future use and currently
cause Load to report an error.
The Package struct provides basic information about the package, including
- ID, a unique identifier for the package in the returned set;
- GoFiles, the names of the package's Go source files;
- Imports, a map from source import strings to the Packages they name;
- Types, the type information for the package's exported symbols;
- Syntax, the parsed syntax trees for the package's source code; and
- TypeInfo, the result of a complete type-check of the package syntax trees.
(See the documentation for type Package for the complete list of fields
and more detailed descriptions.)
For example,
Load(nil, "bytes", "unicode...")
returns four Package structs describing the standard library packages
bytes, unicode, unicode/utf16, and unicode/utf8. Note that one pattern
can match multiple packages and that a package might be matched by
multiple patterns: in general it is not possible to determine which
packages correspond to which patterns.
Note that the list returned by Load contains only the packages matched
by the patterns. Their dependencies can be found by walking the import
graph using the Imports fields.
The Load function can be configured by passing a pointer to a Config as
the first argument. A nil Config is equivalent to the zero Config, which
causes Load to run in LoadFiles mode, collecting minimal information.
See the documentation for type Config for details.
As noted earlier, the Config.Mode controls the amount of detail
reported about the loaded packages. See the documentation for type LoadMode
for details.
Most tools should pass their command-line arguments (after any flags)
uninterpreted to the loader, so that the loader can interpret them
according to the conventions of the underlying build system.
See the Example function for typical usage.
*/
package packages // import "golang.org/x/tools/go/packages"
/*
Motivation and design considerations
The new package's design solves problems addressed by two existing
packages: go/build, which locates and describes packages, and
golang.org/x/tools/go/loader, which loads, parses and type-checks them.
The go/build.Package structure encodes too much of the 'go build' way
of organizing projects, leaving us in need of a data type that describes a
package of Go source code independent of the underlying build system.
We wanted something that works equally well with go build and vgo, and
also other build systems such as Bazel and Blaze, making it possible to
construct analysis tools that work in all these environments.
Tools such as errcheck and staticcheck were essentially unavailable to
the Go community at Google, and some of Google's internal tools for Go
are unavailable externally.
This new package provides a uniform way to obtain package metadata by
querying each of these build systems, optionally supporting their
preferred command-line notations for packages, so that tools integrate
neatly with users' build environments. The Metadata query function
executes an external query tool appropriate to the current workspace.
Loading packages always returns the complete import graph "all the way down",
even if all you want is information about a single package, because the query
mechanisms of all the build systems we currently support ({go,vgo} list, and
blaze/bazel aspect-based query) cannot provide detailed information
about one package without visiting all its dependencies too, so there is
no additional asymptotic cost to providing transitive information.
(This property might not be true of a hypothetical 5th build system.)
In calls to TypeCheck, all initial packages, and any package that
transitively depends on one of them, must be loaded from source.
Consider A->B->C->D->E: if A,C are initial, A,B,C must be loaded from
source; D may be loaded from export data, and E may not be loaded at all
(though it's possible that D's export data mentions it, so a
types.Package may be created for it and exposed.)
The old loader had a feature to suppress type-checking of function
bodies on a per-package basis, primarily intended to reduce the work of
obtaining type information for imported packages. Now that imports are
satisfied by export data, the optimization no longer seems necessary.
Despite some early attempts, the old loader did not exploit export data,
instead always using the equivalent of WholeProgram mode. This was due
to the complexity of mixing source and export data packages (now
resolved by the upward traversal mentioned above), and because export data
files were nearly always missing or stale. Now that 'go build' supports
caching, all the underlying build systems can guarantee to produce
export data in a reasonable (amortized) time.
Test "main" packages synthesized by the build system are now reported as
first-class packages, avoiding the need for clients (such as go/ssa) to
reinvent this generation logic.
One way in which go/packages is simpler than the old loader is in its
treatment of in-package tests. In-package tests are packages that
consist of all the files of the library under test, plus the test files.
The old loader constructed in-package tests by a two-phase process of
mutation called "augmentation": first it would construct and type check
all the ordinary library packages and type-check the packages that
depend on them; then it would add more (test) files to the package and
type-check again. This two-phase approach had four major problems:
1) in processing the tests, the loader modified the library package,
leaving no way for a client application to see both the test
package and the library package; one would mutate into the other.
2) because test files can declare additional methods on types defined in
the library portion of the package, the dispatch of method calls in
the library portion was affected by the presence of the test files.
This should have been a clue that the packages were logically
different.
3) this model of "augmentation" assumed at most one in-package test
per library package, which is true of projects using 'go build',
but not other build systems.
4) because of the two-phase nature of test processing, all packages that
import the library package had to be processed before augmentation,
forcing a "one-shot" API and preventing the client from calling Load
in several times in sequence as is now possible in WholeProgram mode.
(TypeCheck mode has a similar one-shot restriction for a different reason.)
Early drafts of this package supported "multi-shot" operation.
Although it allowed clients to make a sequence of calls (or concurrent
calls) to Load, building up the graph of Packages incrementally,
it was of marginal value: it complicated the API
(since it allowed some options to vary across calls but not others),
it complicated the implementation,
it cannot be made to work in Types mode, as explained above,
and it was less efficient than making one combined call (when this is possible).
Among the clients we have inspected, none made multiple calls to load
but could not be easily and satisfactorily modified to make only a single call.
However, applications changes may be required.
For example, the ssadump command loads the user-specified packages
and in addition the runtime package. It is tempting to simply append
"runtime" to the user-provided list, but that does not work if the user
specified an ad-hoc package such as [a.go b.go].
Instead, ssadump no longer requests the runtime package,
but seeks it among the dependencies of the user-specified packages,
and emits an error if it is not found.
Overlays: The Overlay field in the Config allows providing alternate contents
for Go source files, by providing a mapping from file path to contents.
go/packages will pull in new imports added in overlay files when go/packages
is run in LoadImports mode or greater.
Overlay support for the go list driver isn't complete yet: if the file doesn't
exist on disk, it will only be recognized in an overlay if it is a non-test file
and the package would be reported even without the overlay.
Questions & Tasks
- Add GOARCH/GOOS?
They are not portable concepts, but could be made portable.
Our goal has been to allow users to express themselves using the conventions
of the underlying build system: if the build system honors GOARCH
during a build and during a metadata query, then so should
applications built atop that query mechanism.
Conversely, if the target architecture of the build is determined by
command-line flags, the application can pass the relevant
flags through to the build system using a command such as:
myapp -query_flag="--cpu=amd64" -query_flag="--os=darwin"
However, this approach is low-level, unwieldy, and non-portable.
GOOS and GOARCH seem important enough to warrant a dedicated option.
- How should we handle partial failures such as a mixture of good and
malformed patterns, existing and non-existent packages, successful and
failed builds, import failures, import cycles, and so on, in a call to
Load?
- Support bazel, blaze, and go1.10 list, not just go1.11 list.
- Handle (and test) various partial success cases, e.g.
a mixture of good packages and:
invalid patterns
nonexistent packages
empty packages
packages with malformed package or import declarations
unreadable files
import cycles
other parse errors
type errors
Make sure we record errors at the correct place in the graph.
- Missing packages among initial arguments are not reported.
Return bogus packages for them, like golist does.
- "undeclared name" errors (for example) are reported out of source file
order. I suspect this is due to the breadth-first resolution now used
by go/types. Is that a bug? Discuss with gri.
*/

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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.
// 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
import (
"bytes"
"encoding/json"
"fmt"
"os"
"os/exec"
"strings"
)
// The Driver Protocol
//
// 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 {
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 map[string][]byte `json:"overlay"`
}
// findExternalDriver returns the file path of a tool that supplies
// 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 {
const toolPrefix = "GOPACKAGESDRIVER="
tool := ""
for _, env := range cfg.Env {
if val := strings.TrimPrefix(env, toolPrefix); val != env {
tool = val
}
}
if tool != "" && tool == "off" {
return nil
}
if tool == "" {
var err error
tool, err = exec.LookPath("gopackagesdriver")
if err != nil {
return nil
}
}
return func(cfg *Config, words ...string) (*driverResponse, error) {
req, err := json.Marshal(driverRequest{
Mode: cfg.Mode,
Env: cfg.Env,
BuildFlags: cfg.BuildFlags,
Tests: cfg.Tests,
Overlay: cfg.Overlay,
})
if err != nil {
return nil, fmt.Errorf("failed to encode message to driver tool: %v", err)
}
buf := new(bytes.Buffer)
stderr := new(bytes.Buffer)
cmd := exec.CommandContext(cfg.Context, tool, words...)
cmd.Dir = cfg.Dir
cmd.Env = cfg.Env
cmd.Stdin = bytes.NewReader(req)
cmd.Stdout = buf
cmd.Stderr = stderr
if err := cmd.Run(); err != nil {
return nil, fmt.Errorf("%v: %v: %s", tool, err, cmd.Stderr)
}
if len(stderr.Bytes()) != 0 && os.Getenv("GOPACKAGESPRINTDRIVERERRORS") != "" {
fmt.Fprintf(os.Stderr, "%s stderr: <<%s>>\n", cmdDebugStr(cmd), stderr)
}
var response driverResponse
if err := json.Unmarshal(buf.Bytes(), &response); err != nil {
return nil, err
}
return &response, nil
}
}

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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 packages
import (
"encoding/json"
"fmt"
"go/parser"
"go/token"
"log"
"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
x := commonDir(pkg.GoFiles)
if x != "" {
pkgOfDir[x] = append(pkgOfDir[x], 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) {
env, err := state.getEnv()
if err != nil {
return nil, err
}
if env["GOMOD"] != "" {
state.rootsOnce.Do(func() {
state.rootDirs, state.rootDirsError = state.determineRootDirsModules()
})
} else {
state.rootsOnce.Do(func() {
state.rootDirs, state.rootDirsError = state.determineRootDirsGOPATH()
})
}
return state.rootDirs, state.rootDirsError
}
func (state *golistState) determineRootDirsModules() (map[string]string, error) {
// List all of the modules--the first will be the directory for the main
// module. Any replaced modules will also need to be treated as roots.
// Editing files in the module cache isn't a great idea, so we don't
// plan to ever support that.
out, err := state.invokeGo("list", "-m", "-json", "all")
if err != nil {
// 'go list all' will fail if we're outside of a module and
// GO111MODULE=on. Try falling back without 'all'.
var innerErr error
out, innerErr = state.invokeGo("list", "-m", "-json")
if innerErr != nil {
return nil, err
}
}
roots := map[string]string{}
modules := map[string]string{}
var i int
for dec := json.NewDecoder(out); dec.More(); {
mod := new(gocommand.ModuleJSON)
if err := dec.Decode(mod); err != nil {
return nil, err
}
if mod.Dir != "" && mod.Path != "" {
// This is a valid module; add it to the map.
absDir, err := filepath.Abs(mod.Dir)
if err != nil {
return nil, err
}
modules[absDir] = mod.Path
// The first result is the main module.
if i == 0 || mod.Replace != nil && mod.Replace.Path != "" {
roots[absDir] = mod.Path
}
}
i++
}
return roots, nil
}
func (state *golistState) determineRootDirsGOPATH() (map[string]string, error) {
m := map[string]string{}
for _, dir := range filepath.SplitList(state.mustGetEnv()["GOPATH"]) {
absDir, err := filepath.Abs(dir)
if err != nil {
return nil, err
}
m[filepath.Join(absDir, "src")] = ""
}
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
}
func commonDir(a []string) string {
seen := make(map[string]bool)
x := append([]string{}, a...)
for _, f := range x {
seen[filepath.Dir(f)] = true
}
if len(seen) > 1 {
log.Fatalf("commonDir saw %v for %v", seen, x)
}
for k := range seen {
// len(seen) == 1
return k
}
return "" // 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, "/")
}

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vendor/golang.org/x/tools/go/packages/loadmode_string.go generated vendored Normal file
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// Copyright 2019 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package packages
import (
"fmt"
"strings"
)
var allModes = []LoadMode{
NeedName,
NeedFiles,
NeedCompiledGoFiles,
NeedImports,
NeedDeps,
NeedExportsFile,
NeedTypes,
NeedSyntax,
NeedTypesInfo,
NeedTypesSizes,
}
var modeStrings = []string{
"NeedName",
"NeedFiles",
"NeedCompiledGoFiles",
"NeedImports",
"NeedDeps",
"NeedExportsFile",
"NeedTypes",
"NeedSyntax",
"NeedTypesInfo",
"NeedTypesSizes",
}
func (mod LoadMode) String() string {
m := mod
if m == 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
}
}
if m != 0 {
out = append(out, "Unknown")
}
return fmt.Sprintf("LoadMode(%s)", strings.Join(out, "|"))
}

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vendor/golang.org/x/tools/go/packages/packages.go generated vendored Normal file
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55
vendor/golang.org/x/tools/go/packages/visit.go generated vendored Normal file
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package packages
import (
"fmt"
"os"
"sort"
)
// Visit visits all the packages in the import graph whose roots are
// pkgs, calling the optional pre function the first time each package
// is encountered (preorder), and the optional post function after a
// package's dependencies have been visited (postorder).
// The boolean result of pre(pkg) determines whether
// the imports of package pkg are visited.
func Visit(pkgs []*Package, pre func(*Package) bool, post func(*Package)) {
seen := make(map[*Package]bool)
var visit func(*Package)
visit = func(pkg *Package) {
if !seen[pkg] {
seen[pkg] = true
if pre == nil || pre(pkg) {
paths := make([]string, 0, len(pkg.Imports))
for path := range pkg.Imports {
paths = append(paths, path)
}
sort.Strings(paths) // Imports is a map, this makes visit stable
for _, path := range paths {
visit(pkg.Imports[path])
}
}
if post != nil {
post(pkg)
}
}
}
for _, pkg := range pkgs {
visit(pkg)
}
}
// PrintErrors prints to os.Stderr the accumulated errors of all
// packages in the import graph rooted at pkgs, dependencies first.
// PrintErrors returns the number of errors printed.
func PrintErrors(pkgs []*Package) int {
var n int
Visit(pkgs, nil, func(pkg *Package) {
for _, err := range pkg.Errors {
fmt.Fprintln(os.Stderr, err)
n++
}
})
return n
}

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// Copyright 2019 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 core provides support for event based telemetry.
package core
import (
"fmt"
"time"
"golang.org/x/tools/internal/event/label"
)
// Event holds the information about an event of note that occurred.
type Event struct {
at time.Time
// As events are often on the stack, storing the first few labels directly
// in the event can avoid an allocation at all for the very common cases of
// simple events.
// The length needs to be large enough to cope with the majority of events
// but no so large as to cause undue stack pressure.
// A log message with two values will use 3 labels (one for each value and
// one for the message itself).
static [3]label.Label // inline storage for the first few labels
dynamic []label.Label // dynamically sized storage for remaining labels
}
// eventLabelMap implements label.Map for a the labels of an Event.
type eventLabelMap struct {
event Event
}
func (ev Event) At() time.Time { return ev.at }
func (ev Event) Format(f fmt.State, r rune) {
if !ev.at.IsZero() {
fmt.Fprint(f, ev.at.Format("2006/01/02 15:04:05 "))
}
for index := 0; ev.Valid(index); index++ {
if l := ev.Label(index); l.Valid() {
fmt.Fprintf(f, "\n\t%v", l)
}
}
}
func (ev Event) Valid(index int) bool {
return index >= 0 && index < len(ev.static)+len(ev.dynamic)
}
func (ev Event) Label(index int) label.Label {
if index < len(ev.static) {
return ev.static[index]
}
return ev.dynamic[index-len(ev.static)]
}
func (ev Event) Find(key label.Key) label.Label {
for _, l := range ev.static {
if l.Key() == key {
return l
}
}
for _, l := range ev.dynamic {
if l.Key() == key {
return l
}
}
return label.Label{}
}
func MakeEvent(static [3]label.Label, labels []label.Label) Event {
return Event{
static: static,
dynamic: labels,
}
}
// CloneEvent event returns a copy of the event with the time adjusted to at.
func CloneEvent(ev Event, at time.Time) Event {
ev.at = at
return ev
}

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// Copyright 2019 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 core
import (
"context"
"sync/atomic"
"time"
"unsafe"
"golang.org/x/tools/internal/event/label"
)
// Exporter is a function that handles events.
// It may return a modified context and event.
type Exporter func(context.Context, Event, label.Map) context.Context
var (
exporter unsafe.Pointer
)
// SetExporter sets the global exporter function that handles all events.
// The exporter is called synchronously from the event call site, so it should
// return quickly so as not to hold up user code.
func SetExporter(e Exporter) {
p := unsafe.Pointer(&e)
if e == nil {
// &e is always valid, and so p is always valid, but for the early abort
// of ProcessEvent to be efficient it needs to make the nil check on the
// pointer without having to dereference it, so we make the nil function
// also a nil pointer
p = nil
}
atomic.StorePointer(&exporter, p)
}
// deliver is called to deliver an event to the supplied exporter.
// it will fill in the time.
func deliver(ctx context.Context, exporter Exporter, ev Event) context.Context {
// add the current time to the event
ev.at = time.Now()
// hand the event off to the current exporter
return exporter(ctx, ev, ev)
}
// Export is called to deliver an event to the global exporter if set.
func Export(ctx context.Context, ev Event) context.Context {
// get the global exporter and abort early if there is not one
exporterPtr := (*Exporter)(atomic.LoadPointer(&exporter))
if exporterPtr == nil {
return ctx
}
return deliver(ctx, *exporterPtr, ev)
}
// ExportPair is called to deliver a start event to the supplied exporter.
// It also returns a function that will deliver the end event to the same
// exporter.
// It will fill in the time.
func ExportPair(ctx context.Context, begin, end Event) (context.Context, func()) {
// get the global exporter and abort early if there is not one
exporterPtr := (*Exporter)(atomic.LoadPointer(&exporter))
if exporterPtr == nil {
return ctx, func() {}
}
ctx = deliver(ctx, *exporterPtr, begin)
return ctx, func() { deliver(ctx, *exporterPtr, end) }
}

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vendor/golang.org/x/tools/internal/event/core/fast.go generated vendored Normal file
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// Copyright 2019 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 core
import (
"context"
"golang.org/x/tools/internal/event/keys"
"golang.org/x/tools/internal/event/label"
)
// Log1 takes a message and one label delivers a log event to the exporter.
// It is a customized version of Print that is faster and does no allocation.
func Log1(ctx context.Context, message string, t1 label.Label) {
Export(ctx, MakeEvent([3]label.Label{
keys.Msg.Of(message),
t1,
}, nil))
}
// Log2 takes a message and two labels and delivers a log event to the exporter.
// It is a customized version of Print that is faster and does no allocation.
func Log2(ctx context.Context, message string, t1 label.Label, t2 label.Label) {
Export(ctx, MakeEvent([3]label.Label{
keys.Msg.Of(message),
t1,
t2,
}, nil))
}
// Metric1 sends a label event to the exporter with the supplied labels.
func Metric1(ctx context.Context, t1 label.Label) context.Context {
return Export(ctx, MakeEvent([3]label.Label{
keys.Metric.New(),
t1,
}, nil))
}
// Metric2 sends a label event to the exporter with the supplied labels.
func Metric2(ctx context.Context, t1, t2 label.Label) context.Context {
return Export(ctx, MakeEvent([3]label.Label{
keys.Metric.New(),
t1,
t2,
}, nil))
}
// Start1 sends a span start event with the supplied label list to the exporter.
// It also returns a function that will end the span, which should normally be
// deferred.
func Start1(ctx context.Context, name string, t1 label.Label) (context.Context, func()) {
return ExportPair(ctx,
MakeEvent([3]label.Label{
keys.Start.Of(name),
t1,
}, nil),
MakeEvent([3]label.Label{
keys.End.New(),
}, nil))
}
// Start2 sends a span start event with the supplied label list to the exporter.
// It also returns a function that will end the span, which should normally be
// deferred.
func Start2(ctx context.Context, name string, t1, t2 label.Label) (context.Context, func()) {
return ExportPair(ctx,
MakeEvent([3]label.Label{
keys.Start.Of(name),
t1,
t2,
}, nil),
MakeEvent([3]label.Label{
keys.End.New(),
}, nil))
}

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vendor/golang.org/x/tools/internal/event/doc.go generated vendored Normal file
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// Copyright 2019 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 event provides a set of packages that cover the main
// concepts of telemetry in an implementation agnostic way.
package event

127
vendor/golang.org/x/tools/internal/event/event.go generated vendored Normal file
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// Copyright 2019 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 event
import (
"context"
"golang.org/x/tools/internal/event/core"
"golang.org/x/tools/internal/event/keys"
"golang.org/x/tools/internal/event/label"
)
// Exporter is a function that handles events.
// It may return a modified context and event.
type Exporter func(context.Context, core.Event, label.Map) context.Context
// SetExporter sets the global exporter function that handles all events.
// The exporter is called synchronously from the event call site, so it should
// return quickly so as not to hold up user code.
func SetExporter(e Exporter) {
core.SetExporter(core.Exporter(e))
}
// Log takes a message and a label list and combines them into a single event
// before delivering them to the exporter.
func Log(ctx context.Context, message string, labels ...label.Label) {
core.Export(ctx, core.MakeEvent([3]label.Label{
keys.Msg.Of(message),
}, labels))
}
// IsLog returns true if the event was built by the Log function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsLog(ev core.Event) bool {
return ev.Label(0).Key() == keys.Msg
}
// Error takes a message and a label list and combines them into a single event
// before delivering them to the exporter. It captures the error in the
// delivered event.
func Error(ctx context.Context, message string, err error, labels ...label.Label) {
core.Export(ctx, core.MakeEvent([3]label.Label{
keys.Msg.Of(message),
keys.Err.Of(err),
}, labels))
}
// IsError returns true if the event was built by the Error function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsError(ev core.Event) bool {
return ev.Label(0).Key() == keys.Msg &&
ev.Label(1).Key() == keys.Err
}
// Metric sends a label event to the exporter with the supplied labels.
func Metric(ctx context.Context, labels ...label.Label) {
core.Export(ctx, core.MakeEvent([3]label.Label{
keys.Metric.New(),
}, labels))
}
// IsMetric returns true if the event was built by the Metric function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsMetric(ev core.Event) bool {
return ev.Label(0).Key() == keys.Metric
}
// Label sends a label event to the exporter with the supplied labels.
func Label(ctx context.Context, labels ...label.Label) context.Context {
return core.Export(ctx, core.MakeEvent([3]label.Label{
keys.Label.New(),
}, labels))
}
// IsLabel returns true if the event was built by the Label function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsLabel(ev core.Event) bool {
return ev.Label(0).Key() == keys.Label
}
// Start sends a span start event with the supplied label list to the exporter.
// It also returns a function that will end the span, which should normally be
// deferred.
func Start(ctx context.Context, name string, labels ...label.Label) (context.Context, func()) {
return core.ExportPair(ctx,
core.MakeEvent([3]label.Label{
keys.Start.Of(name),
}, labels),
core.MakeEvent([3]label.Label{
keys.End.New(),
}, nil))
}
// IsStart returns true if the event was built by the Start function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsStart(ev core.Event) bool {
return ev.Label(0).Key() == keys.Start
}
// IsEnd returns true if the event was built by the End function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsEnd(ev core.Event) bool {
return ev.Label(0).Key() == keys.End
}
// Detach returns a context without an associated span.
// This allows the creation of spans that are not children of the current span.
func Detach(ctx context.Context) context.Context {
return core.Export(ctx, core.MakeEvent([3]label.Label{
keys.Detach.New(),
}, nil))
}
// IsDetach returns true if the event was built by the Detach function.
// It is intended to be used in exporters to identify the semantics of the
// event when deciding what to do with it.
func IsDetach(ev core.Event) bool {
return ev.Label(0).Key() == keys.Detach
}

564
vendor/golang.org/x/tools/internal/event/keys/keys.go generated vendored Normal file
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// Copyright 2019 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 keys
import (
"fmt"
"io"
"math"
"strconv"
"golang.org/x/tools/internal/event/label"
)
// Value represents a key for untyped values.
type Value struct {
name string
description string
}
// New creates a new Key for untyped values.
func New(name, description string) *Value {
return &Value{name: name, description: description}
}
func (k *Value) Name() string { return k.name }
func (k *Value) Description() string { return k.description }
func (k *Value) Format(w io.Writer, buf []byte, l label.Label) {
fmt.Fprint(w, k.From(l))
}
// Get can be used to get a label for the key from a label.Map.
func (k *Value) Get(lm label.Map) interface{} {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return nil
}
// From can be used to get a value from a Label.
func (k *Value) From(t label.Label) interface{} { return t.UnpackValue() }
// Of creates a new Label with this key and the supplied value.
func (k *Value) Of(value interface{}) label.Label { return label.OfValue(k, value) }
// Tag represents a key for tagging labels that have no value.
// These are used when the existence of the label is the entire information it
// carries, such as marking events to be of a specific kind, or from a specific
// package.
type Tag struct {
name string
description string
}
// NewTag creates a new Key for tagging labels.
func NewTag(name, description string) *Tag {
return &Tag{name: name, description: description}
}
func (k *Tag) Name() string { return k.name }
func (k *Tag) Description() string { return k.description }
func (k *Tag) Format(w io.Writer, buf []byte, l label.Label) {}
// New creates a new Label with this key.
func (k *Tag) New() label.Label { return label.OfValue(k, nil) }
// Int represents a key
type Int struct {
name string
description string
}
// NewInt creates a new Key for int values.
func NewInt(name, description string) *Int {
return &Int{name: name, description: description}
}
func (k *Int) Name() string { return k.name }
func (k *Int) Description() string { return k.description }
func (k *Int) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendInt(buf, int64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *Int) Of(v int) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *Int) Get(lm label.Map) int {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Int) From(t label.Label) int { return int(t.Unpack64()) }
// Int8 represents a key
type Int8 struct {
name string
description string
}
// NewInt8 creates a new Key for int8 values.
func NewInt8(name, description string) *Int8 {
return &Int8{name: name, description: description}
}
func (k *Int8) Name() string { return k.name }
func (k *Int8) Description() string { return k.description }
func (k *Int8) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendInt(buf, int64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *Int8) Of(v int8) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *Int8) Get(lm label.Map) int8 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Int8) From(t label.Label) int8 { return int8(t.Unpack64()) }
// Int16 represents a key
type Int16 struct {
name string
description string
}
// NewInt16 creates a new Key for int16 values.
func NewInt16(name, description string) *Int16 {
return &Int16{name: name, description: description}
}
func (k *Int16) Name() string { return k.name }
func (k *Int16) Description() string { return k.description }
func (k *Int16) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendInt(buf, int64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *Int16) Of(v int16) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *Int16) Get(lm label.Map) int16 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Int16) From(t label.Label) int16 { return int16(t.Unpack64()) }
// Int32 represents a key
type Int32 struct {
name string
description string
}
// NewInt32 creates a new Key for int32 values.
func NewInt32(name, description string) *Int32 {
return &Int32{name: name, description: description}
}
func (k *Int32) Name() string { return k.name }
func (k *Int32) Description() string { return k.description }
func (k *Int32) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendInt(buf, int64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *Int32) Of(v int32) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *Int32) Get(lm label.Map) int32 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Int32) From(t label.Label) int32 { return int32(t.Unpack64()) }
// Int64 represents a key
type Int64 struct {
name string
description string
}
// NewInt64 creates a new Key for int64 values.
func NewInt64(name, description string) *Int64 {
return &Int64{name: name, description: description}
}
func (k *Int64) Name() string { return k.name }
func (k *Int64) Description() string { return k.description }
func (k *Int64) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendInt(buf, k.From(l), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *Int64) Of(v int64) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *Int64) Get(lm label.Map) int64 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Int64) From(t label.Label) int64 { return int64(t.Unpack64()) }
// UInt represents a key
type UInt struct {
name string
description string
}
// NewUInt creates a new Key for uint values.
func NewUInt(name, description string) *UInt {
return &UInt{name: name, description: description}
}
func (k *UInt) Name() string { return k.name }
func (k *UInt) Description() string { return k.description }
func (k *UInt) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendUint(buf, uint64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *UInt) Of(v uint) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *UInt) Get(lm label.Map) uint {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *UInt) From(t label.Label) uint { return uint(t.Unpack64()) }
// UInt8 represents a key
type UInt8 struct {
name string
description string
}
// NewUInt8 creates a new Key for uint8 values.
func NewUInt8(name, description string) *UInt8 {
return &UInt8{name: name, description: description}
}
func (k *UInt8) Name() string { return k.name }
func (k *UInt8) Description() string { return k.description }
func (k *UInt8) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendUint(buf, uint64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *UInt8) Of(v uint8) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *UInt8) Get(lm label.Map) uint8 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *UInt8) From(t label.Label) uint8 { return uint8(t.Unpack64()) }
// UInt16 represents a key
type UInt16 struct {
name string
description string
}
// NewUInt16 creates a new Key for uint16 values.
func NewUInt16(name, description string) *UInt16 {
return &UInt16{name: name, description: description}
}
func (k *UInt16) Name() string { return k.name }
func (k *UInt16) Description() string { return k.description }
func (k *UInt16) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendUint(buf, uint64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *UInt16) Of(v uint16) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *UInt16) Get(lm label.Map) uint16 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *UInt16) From(t label.Label) uint16 { return uint16(t.Unpack64()) }
// UInt32 represents a key
type UInt32 struct {
name string
description string
}
// NewUInt32 creates a new Key for uint32 values.
func NewUInt32(name, description string) *UInt32 {
return &UInt32{name: name, description: description}
}
func (k *UInt32) Name() string { return k.name }
func (k *UInt32) Description() string { return k.description }
func (k *UInt32) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendUint(buf, uint64(k.From(l)), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *UInt32) Of(v uint32) label.Label { return label.Of64(k, uint64(v)) }
// Get can be used to get a label for the key from a label.Map.
func (k *UInt32) Get(lm label.Map) uint32 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *UInt32) From(t label.Label) uint32 { return uint32(t.Unpack64()) }
// UInt64 represents a key
type UInt64 struct {
name string
description string
}
// NewUInt64 creates a new Key for uint64 values.
func NewUInt64(name, description string) *UInt64 {
return &UInt64{name: name, description: description}
}
func (k *UInt64) Name() string { return k.name }
func (k *UInt64) Description() string { return k.description }
func (k *UInt64) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendUint(buf, k.From(l), 10))
}
// Of creates a new Label with this key and the supplied value.
func (k *UInt64) Of(v uint64) label.Label { return label.Of64(k, v) }
// Get can be used to get a label for the key from a label.Map.
func (k *UInt64) Get(lm label.Map) uint64 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *UInt64) From(t label.Label) uint64 { return t.Unpack64() }
// Float32 represents a key
type Float32 struct {
name string
description string
}
// NewFloat32 creates a new Key for float32 values.
func NewFloat32(name, description string) *Float32 {
return &Float32{name: name, description: description}
}
func (k *Float32) Name() string { return k.name }
func (k *Float32) Description() string { return k.description }
func (k *Float32) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendFloat(buf, float64(k.From(l)), 'E', -1, 32))
}
// Of creates a new Label with this key and the supplied value.
func (k *Float32) Of(v float32) label.Label {
return label.Of64(k, uint64(math.Float32bits(v)))
}
// Get can be used to get a label for the key from a label.Map.
func (k *Float32) Get(lm label.Map) float32 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Float32) From(t label.Label) float32 {
return math.Float32frombits(uint32(t.Unpack64()))
}
// Float64 represents a key
type Float64 struct {
name string
description string
}
// NewFloat64 creates a new Key for int64 values.
func NewFloat64(name, description string) *Float64 {
return &Float64{name: name, description: description}
}
func (k *Float64) Name() string { return k.name }
func (k *Float64) Description() string { return k.description }
func (k *Float64) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendFloat(buf, k.From(l), 'E', -1, 64))
}
// Of creates a new Label with this key and the supplied value.
func (k *Float64) Of(v float64) label.Label {
return label.Of64(k, math.Float64bits(v))
}
// Get can be used to get a label for the key from a label.Map.
func (k *Float64) Get(lm label.Map) float64 {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return 0
}
// From can be used to get a value from a Label.
func (k *Float64) From(t label.Label) float64 {
return math.Float64frombits(t.Unpack64())
}
// String represents a key
type String struct {
name string
description string
}
// NewString creates a new Key for int64 values.
func NewString(name, description string) *String {
return &String{name: name, description: description}
}
func (k *String) Name() string { return k.name }
func (k *String) Description() string { return k.description }
func (k *String) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendQuote(buf, k.From(l)))
}
// Of creates a new Label with this key and the supplied value.
func (k *String) Of(v string) label.Label { return label.OfString(k, v) }
// Get can be used to get a label for the key from a label.Map.
func (k *String) Get(lm label.Map) string {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return ""
}
// From can be used to get a value from a Label.
func (k *String) From(t label.Label) string { return t.UnpackString() }
// Boolean represents a key
type Boolean struct {
name string
description string
}
// NewBoolean creates a new Key for bool values.
func NewBoolean(name, description string) *Boolean {
return &Boolean{name: name, description: description}
}
func (k *Boolean) Name() string { return k.name }
func (k *Boolean) Description() string { return k.description }
func (k *Boolean) Format(w io.Writer, buf []byte, l label.Label) {
w.Write(strconv.AppendBool(buf, k.From(l)))
}
// Of creates a new Label with this key and the supplied value.
func (k *Boolean) Of(v bool) label.Label {
if v {
return label.Of64(k, 1)
}
return label.Of64(k, 0)
}
// Get can be used to get a label for the key from a label.Map.
func (k *Boolean) Get(lm label.Map) bool {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return false
}
// From can be used to get a value from a Label.
func (k *Boolean) From(t label.Label) bool { return t.Unpack64() > 0 }
// Error represents a key
type Error struct {
name string
description string
}
// NewError creates a new Key for int64 values.
func NewError(name, description string) *Error {
return &Error{name: name, description: description}
}
func (k *Error) Name() string { return k.name }
func (k *Error) Description() string { return k.description }
func (k *Error) Format(w io.Writer, buf []byte, l label.Label) {
io.WriteString(w, k.From(l).Error())
}
// Of creates a new Label with this key and the supplied value.
func (k *Error) Of(v error) label.Label { return label.OfValue(k, v) }
// Get can be used to get a label for the key from a label.Map.
func (k *Error) Get(lm label.Map) error {
if t := lm.Find(k); t.Valid() {
return k.From(t)
}
return nil
}
// From can be used to get a value from a Label.
func (k *Error) From(t label.Label) error {
err, _ := t.UnpackValue().(error)
return err
}

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vendor/golang.org/x/tools/internal/event/keys/standard.go generated vendored Normal file
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// Copyright 2020 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 keys
var (
// Msg is a key used to add message strings to label lists.
Msg = NewString("message", "a readable message")
// Label is a key used to indicate an event adds labels to the context.
Label = NewTag("label", "a label context marker")
// Start is used for things like traces that have a name.
Start = NewString("start", "span start")
// Metric is a key used to indicate an event records metrics.
End = NewTag("end", "a span end marker")
// Metric is a key used to indicate an event records metrics.
Detach = NewTag("detach", "a span detach marker")
// Err is a key used to add error values to label lists.
Err = NewError("error", "an error that occurred")
// Metric is a key used to indicate an event records metrics.
Metric = NewTag("metric", "a metric event marker")
)

213
vendor/golang.org/x/tools/internal/event/label/label.go generated vendored Normal file
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// Copyright 2019 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 label
import (
"fmt"
"io"
"reflect"
"unsafe"
)
// Key is used as the identity of a Label.
// Keys are intended to be compared by pointer only, the name should be unique
// for communicating with external systems, but it is not required or enforced.
type Key interface {
// Name returns the key name.
Name() string
// Description returns a string that can be used to describe the value.
Description() string
// Format is used in formatting to append the value of the label to the
// supplied buffer.
// The formatter may use the supplied buf as a scratch area to avoid
// allocations.
Format(w io.Writer, buf []byte, l Label)
}
// Label holds a key and value pair.
// It is normally used when passing around lists of labels.
type Label struct {
key Key
packed uint64
untyped interface{}
}
// Map is the interface to a collection of Labels indexed by key.
type Map interface {
// Find returns the label that matches the supplied key.
Find(key Key) Label
}
// List is the interface to something that provides an iterable
// list of labels.
// Iteration should start from 0 and continue until Valid returns false.
type List interface {
// Valid returns true if the index is within range for the list.
// It does not imply the label at that index will itself be valid.
Valid(index int) bool
// Label returns the label at the given index.
Label(index int) Label
}
// list implements LabelList for a list of Labels.
type list struct {
labels []Label
}
// filter wraps a LabelList filtering out specific labels.
type filter struct {
keys []Key
underlying List
}
// listMap implements LabelMap for a simple list of labels.
type listMap struct {
labels []Label
}
// mapChain implements LabelMap for a list of underlying LabelMap.
type mapChain struct {
maps []Map
}
// OfValue creates a new label from the key and value.
// This method is for implementing new key types, label creation should
// normally be done with the Of method of the key.
func OfValue(k Key, value interface{}) Label { return Label{key: k, untyped: value} }
// UnpackValue assumes the label was built using LabelOfValue and returns the value
// that was passed to that constructor.
// This method is for implementing new key types, for type safety normal
// access should be done with the From method of the key.
func (t Label) UnpackValue() interface{} { return t.untyped }
// Of64 creates a new label from a key and a uint64. This is often
// used for non uint64 values that can be packed into a uint64.
// This method is for implementing new key types, label creation should
// normally be done with the Of method of the key.
func Of64(k Key, v uint64) Label { return Label{key: k, packed: v} }
// Unpack64 assumes the label was built using LabelOf64 and returns the value that
// was passed to that constructor.
// This method is for implementing new key types, for type safety normal
// access should be done with the From method of the key.
func (t Label) Unpack64() uint64 { return t.packed }
// OfString creates a new label from a key and a string.
// This method is for implementing new key types, label creation should
// normally be done with the Of method of the key.
func OfString(k Key, v string) Label {
hdr := (*reflect.StringHeader)(unsafe.Pointer(&v))
return Label{
key: k,
packed: uint64(hdr.Len),
untyped: unsafe.Pointer(hdr.Data),
}
}
// UnpackString assumes the label was built using LabelOfString and returns the
// value that was passed to that constructor.
// This method is for implementing new key types, for type safety normal
// access should be done with the From method of the key.
func (t Label) UnpackString() string {
var v string
hdr := (*reflect.StringHeader)(unsafe.Pointer(&v))
hdr.Data = uintptr(t.untyped.(unsafe.Pointer))
hdr.Len = int(t.packed)
return *(*string)(unsafe.Pointer(hdr))
}
// Valid returns true if the Label is a valid one (it has a key).
func (t Label) Valid() bool { return t.key != nil }
// Key returns the key of this Label.
func (t Label) Key() Key { return t.key }
// Format is used for debug printing of labels.
func (t Label) Format(f fmt.State, r rune) {
if !t.Valid() {
io.WriteString(f, `nil`)
return
}
io.WriteString(f, t.Key().Name())
io.WriteString(f, "=")
var buf [128]byte
t.Key().Format(f, buf[:0], t)
}
func (l *list) Valid(index int) bool {
return index >= 0 && index < len(l.labels)
}
func (l *list) Label(index int) Label {
return l.labels[index]
}
func (f *filter) Valid(index int) bool {
return f.underlying.Valid(index)
}
func (f *filter) Label(index int) Label {
l := f.underlying.Label(index)
for _, f := range f.keys {
if l.Key() == f {
return Label{}
}
}
return l
}
func (lm listMap) Find(key Key) Label {
for _, l := range lm.labels {
if l.Key() == key {
return l
}
}
return Label{}
}
func (c mapChain) Find(key Key) Label {
for _, src := range c.maps {
l := src.Find(key)
if l.Valid() {
return l
}
}
return Label{}
}
var emptyList = &list{}
func NewList(labels ...Label) List {
if len(labels) == 0 {
return emptyList
}
return &list{labels: labels}
}
func Filter(l List, keys ...Key) List {
if len(keys) == 0 {
return l
}
return &filter{keys: keys, underlying: l}
}
func NewMap(labels ...Label) Map {
return listMap{labels: labels}
}
func MergeMaps(srcs ...Map) Map {
var nonNil []Map
for _, src := range srcs {
if src != nil {
nonNil = append(nonNil, src)
}
}
if len(nonNil) == 1 {
return nonNil[0]
}
return mapChain{maps: nonNil}
}

273
vendor/golang.org/x/tools/internal/gocommand/invoke.go generated vendored Normal file
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// Copyright 2020 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 gocommand is a helper for calling the go command.
package gocommand
import (
"bytes"
"context"
"fmt"
"io"
"os"
"os/exec"
"regexp"
"strconv"
"strings"
"sync"
"time"
"golang.org/x/tools/internal/event"
)
// An Runner will run go command invocations and serialize
// them if it sees a concurrency error.
type Runner struct {
// once guards the runner initialization.
once sync.Once
// inFlight tracks available workers.
inFlight chan struct{}
// serialized guards the ability to run a go command serially,
// to avoid deadlocks when claiming workers.
serialized chan struct{}
}
const maxInFlight = 10
func (runner *Runner) initialize() {
runner.once.Do(func() {
runner.inFlight = make(chan struct{}, maxInFlight)
runner.serialized = make(chan struct{}, 1)
})
}
// 1.13: go: updates to go.mod needed, but contents have changed
// 1.14: go: updating go.mod: existing contents have changed since last read
var modConcurrencyError = regexp.MustCompile(`go:.*go.mod.*contents have changed`)
// Run is a convenience wrapper around RunRaw.
// It returns only stdout and a "friendly" error.
func (runner *Runner) Run(ctx context.Context, inv Invocation) (*bytes.Buffer, error) {
stdout, _, friendly, _ := runner.RunRaw(ctx, inv)
return stdout, friendly
}
// RunPiped runs the invocation serially, always waiting for any concurrent
// invocations to complete first.
func (runner *Runner) RunPiped(ctx context.Context, inv Invocation, stdout, stderr io.Writer) error {
_, err := runner.runPiped(ctx, inv, stdout, stderr)
return err
}
// RunRaw runs the invocation, serializing requests only if they fight over
// go.mod changes.
func (runner *Runner) RunRaw(ctx context.Context, inv Invocation) (*bytes.Buffer, *bytes.Buffer, error, error) {
// Make sure the runner is always initialized.
runner.initialize()
// First, try to run the go command concurrently.
stdout, stderr, friendlyErr, err := runner.runConcurrent(ctx, inv)
// If we encounter a load concurrency error, we need to retry serially.
if friendlyErr == nil || !modConcurrencyError.MatchString(friendlyErr.Error()) {
return stdout, stderr, friendlyErr, err
}
event.Error(ctx, "Load concurrency error, will retry serially", err)
// Run serially by calling runPiped.
stdout.Reset()
stderr.Reset()
friendlyErr, err = runner.runPiped(ctx, inv, stdout, stderr)
return stdout, stderr, friendlyErr, err
}
func (runner *Runner) runConcurrent(ctx context.Context, inv Invocation) (*bytes.Buffer, *bytes.Buffer, error, error) {
// Wait for 1 worker to become available.
select {
case <-ctx.Done():
return nil, nil, nil, ctx.Err()
case runner.inFlight <- struct{}{}:
defer func() { <-runner.inFlight }()
}
stdout, stderr := &bytes.Buffer{}, &bytes.Buffer{}
friendlyErr, err := inv.runWithFriendlyError(ctx, stdout, stderr)
return stdout, stderr, friendlyErr, err
}
func (runner *Runner) runPiped(ctx context.Context, inv Invocation, stdout, stderr io.Writer) (error, error) {
// Make sure the runner is always initialized.
runner.initialize()
// Acquire the serialization lock. This avoids deadlocks between two
// runPiped commands.
select {
case <-ctx.Done():
return nil, ctx.Err()
case runner.serialized <- struct{}{}:
defer func() { <-runner.serialized }()
}
// Wait for all in-progress go commands to return before proceeding,
// to avoid load concurrency errors.
for i := 0; i < maxInFlight; i++ {
select {
case <-ctx.Done():
return nil, ctx.Err()
case runner.inFlight <- struct{}{}:
// Make sure we always "return" any workers we took.
defer func() { <-runner.inFlight }()
}
}
return inv.runWithFriendlyError(ctx, stdout, stderr)
}
// An Invocation represents a call to the go command.
type Invocation struct {
Verb string
Args []string
BuildFlags []string
ModFlag string
ModFile string
Overlay string
// If CleanEnv is set, the invocation will run only with the environment
// in Env, not starting with os.Environ.
CleanEnv bool
Env []string
WorkingDir string
Logf func(format string, args ...interface{})
}
func (i *Invocation) runWithFriendlyError(ctx context.Context, stdout, stderr io.Writer) (friendlyError error, rawError error) {
rawError = i.run(ctx, stdout, stderr)
if rawError != nil {
friendlyError = rawError
// Check for 'go' executable not being found.
if ee, ok := rawError.(*exec.Error); ok && ee.Err == exec.ErrNotFound {
friendlyError = fmt.Errorf("go command required, not found: %v", ee)
}
if ctx.Err() != nil {
friendlyError = ctx.Err()
}
friendlyError = fmt.Errorf("err: %v: stderr: %s", friendlyError, stderr)
}
return
}
func (i *Invocation) run(ctx context.Context, stdout, stderr io.Writer) error {
log := i.Logf
if log == nil {
log = func(string, ...interface{}) {}
}
goArgs := []string{i.Verb}
appendModFile := func() {
if i.ModFile != "" {
goArgs = append(goArgs, "-modfile="+i.ModFile)
}
}
appendModFlag := func() {
if i.ModFlag != "" {
goArgs = append(goArgs, "-mod="+i.ModFlag)
}
}
appendOverlayFlag := func() {
if i.Overlay != "" {
goArgs = append(goArgs, "-overlay="+i.Overlay)
}
}
switch i.Verb {
case "env", "version":
goArgs = append(goArgs, i.Args...)
case "mod":
// mod needs the sub-verb before flags.
goArgs = append(goArgs, i.Args[0])
appendModFile()
goArgs = append(goArgs, i.Args[1:]...)
case "get":
goArgs = append(goArgs, i.BuildFlags...)
appendModFile()
goArgs = append(goArgs, i.Args...)
default: // notably list and build.
goArgs = append(goArgs, i.BuildFlags...)
appendModFile()
appendModFlag()
appendOverlayFlag()
goArgs = append(goArgs, i.Args...)
}
cmd := exec.Command("go", goArgs...)
cmd.Stdout = stdout
cmd.Stderr = stderr
// On darwin the cwd gets resolved to the real path, which breaks anything that
// expects the working directory to keep the original path, including the
// go command when dealing with modules.
// The Go 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.
if !i.CleanEnv {
cmd.Env = os.Environ()
}
cmd.Env = append(cmd.Env, i.Env...)
if i.WorkingDir != "" {
cmd.Env = append(cmd.Env, "PWD="+i.WorkingDir)
cmd.Dir = i.WorkingDir
}
defer func(start time.Time) { log("%s for %v", time.Since(start), cmdDebugStr(cmd)) }(time.Now())
return runCmdContext(ctx, cmd)
}
// runCmdContext is like exec.CommandContext except it sends os.Interrupt
// before os.Kill.
func runCmdContext(ctx context.Context, cmd *exec.Cmd) error {
if err := cmd.Start(); err != nil {
return err
}
resChan := make(chan error, 1)
go func() {
resChan <- cmd.Wait()
}()
select {
case err := <-resChan:
return err
case <-ctx.Done():
}
// Cancelled. Interrupt and see if it ends voluntarily.
cmd.Process.Signal(os.Interrupt)
select {
case err := <-resChan:
return err
case <-time.After(time.Second):
}
// Didn't shut down in response to interrupt. Kill it hard.
cmd.Process.Kill()
return <-resChan
}
func cmdDebugStr(cmd *exec.Cmd) string {
env := make(map[string]string)
for _, kv := range cmd.Env {
split := strings.SplitN(kv, "=", 2)
k, v := split[0], split[1]
env[k] = v
}
var args []string
for _, arg := range cmd.Args {
quoted := strconv.Quote(arg)
if quoted[1:len(quoted)-1] != arg || strings.Contains(arg, " ") {
args = append(args, quoted)
} else {
args = append(args, arg)
}
}
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, " "))
}

102
vendor/golang.org/x/tools/internal/gocommand/vendor.go generated vendored Normal file
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// Copyright 2020 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 gocommand
import (
"bytes"
"context"
"fmt"
"os"
"path/filepath"
"regexp"
"strings"
"golang.org/x/mod/semver"
)
// ModuleJSON holds information about a module.
type ModuleJSON struct {
Path string // module path
Replace *ModuleJSON // replaced by this module
Main bool // is this the main module?
Indirect bool // is this module only an indirect dependency of main module?
Dir string // directory holding files for this module, if any
GoMod string // path to go.mod file for this module, if any
GoVersion string // go version used in module
}
var modFlagRegexp = regexp.MustCompile(`-mod[ =](\w+)`)
// VendorEnabled reports whether vendoring is enabled. It takes a *Runner to execute Go commands
// with the supplied context.Context and Invocation. The Invocation can contain pre-defined fields,
// of which only Verb and Args are modified to run the appropriate Go command.
// Inspired by setDefaultBuildMod in modload/init.go
func VendorEnabled(ctx context.Context, inv Invocation, r *Runner) (*ModuleJSON, bool, error) {
mainMod, go114, err := getMainModuleAnd114(ctx, inv, r)
if err != nil {
return nil, false, err
}
// We check the GOFLAGS to see if there is anything overridden or not.
inv.Verb = "env"
inv.Args = []string{"GOFLAGS"}
stdout, err := r.Run(ctx, inv)
if err != nil {
return nil, false, err
}
goflags := string(bytes.TrimSpace(stdout.Bytes()))
matches := modFlagRegexp.FindStringSubmatch(goflags)
var modFlag string
if len(matches) != 0 {
modFlag = matches[1]
}
if modFlag != "" {
// Don't override an explicit '-mod=' argument.
return mainMod, modFlag == "vendor", nil
}
if mainMod == nil || !go114 {
return mainMod, false, nil
}
// Check 1.14's automatic vendor mode.
if fi, err := os.Stat(filepath.Join(mainMod.Dir, "vendor")); err == nil && fi.IsDir() {
if mainMod.GoVersion != "" && semver.Compare("v"+mainMod.GoVersion, "v1.14") >= 0 {
// The Go version is at least 1.14, and a vendor directory exists.
// Set -mod=vendor by default.
return mainMod, true, nil
}
}
return mainMod, false, nil
}
// getMainModuleAnd114 gets the main module's information and whether the
// go command in use is 1.14+. This is the information needed to figure out
// if vendoring should be enabled.
func getMainModuleAnd114(ctx context.Context, inv Invocation, r *Runner) (*ModuleJSON, bool, error) {
const format = `{{.Path}}
{{.Dir}}
{{.GoMod}}
{{.GoVersion}}
{{range context.ReleaseTags}}{{if eq . "go1.14"}}{{.}}{{end}}{{end}}
`
inv.Verb = "list"
inv.Args = []string{"-m", "-f", format}
stdout, err := r.Run(ctx, inv)
if err != nil {
return nil, false, err
}
lines := strings.Split(stdout.String(), "\n")
if len(lines) < 5 {
return nil, false, fmt.Errorf("unexpected stdout: %q", stdout.String())
}
mod := &ModuleJSON{
Path: lines[0],
Dir: lines[1],
GoMod: lines[2],
GoVersion: lines[3],
Main: true,
}
return mod, lines[4] == "go1.14", nil
}

40
vendor/golang.org/x/tools/internal/gocommand/version.go generated vendored Normal file
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// Copyright 2020 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 gocommand
import (
"context"
"fmt"
"strings"
)
// GoVersion checks the go version by running "go list" with modules off.
// It returns the X in Go 1.X.
func GoVersion(ctx context.Context, inv Invocation, r *Runner) (int, error) {
inv.Verb = "list"
inv.Args = []string{"-e", "-f", `{{context.ReleaseTags}}`}
inv.Env = append(append([]string{}, inv.Env...), "GO111MODULE=off")
// Unset any unneeded flags.
inv.ModFile = ""
inv.ModFlag = ""
stdoutBytes, err := r.Run(ctx, inv)
if err != nil {
return 0, err
}
stdout := stdoutBytes.String()
if len(stdout) < 3 {
return 0, fmt.Errorf("bad ReleaseTags output: %q", stdout)
}
// Split up "[go1.1 go1.15]"
tags := strings.Fields(stdout[1 : len(stdout)-2])
for i := len(tags) - 1; i >= 0; i-- {
var version int
if _, err := fmt.Sscanf(tags[i], "go1.%d", &version); err != nil {
continue
}
return version, nil
}
return 0, fmt.Errorf("no parseable ReleaseTags in %v", tags)
}

17
vendor/golang.org/x/tools/internal/packagesinternal/packages.go generated vendored Normal file
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// Package packagesinternal exposes internal-only fields from go/packages.
package packagesinternal
import (
"golang.org/x/tools/internal/gocommand"
)
var GetForTest = func(p interface{}) string { return "" }
var GetGoCmdRunner = func(config interface{}) *gocommand.Runner { return nil }
var SetGoCmdRunner = func(config interface{}, runner *gocommand.Runner) {}
var TypecheckCgo int
var SetModFlag = func(config interface{}, value string) {}
var SetModFile = func(config interface{}, value string) {}

1358
vendor/golang.org/x/tools/internal/typesinternal/errorcode.go generated vendored Normal file
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152
vendor/golang.org/x/tools/internal/typesinternal/errorcode_string.go generated vendored Normal file
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// Code generated by "stringer -type=ErrorCode"; DO NOT EDIT.
package typesinternal
import "strconv"
func _() {
// An "invalid array index" compiler error signifies that the constant values have changed.
// Re-run the stringer command to generate them again.
var x [1]struct{}
_ = x[Test-1]
_ = x[BlankPkgName-2]
_ = x[MismatchedPkgName-3]
_ = x[InvalidPkgUse-4]
_ = x[BadImportPath-5]
_ = x[BrokenImport-6]
_ = x[ImportCRenamed-7]
_ = x[UnusedImport-8]
_ = x[InvalidInitCycle-9]
_ = x[DuplicateDecl-10]
_ = x[InvalidDeclCycle-11]
_ = x[InvalidTypeCycle-12]
_ = x[InvalidConstInit-13]
_ = x[InvalidConstVal-14]
_ = x[InvalidConstType-15]
_ = x[UntypedNil-16]
_ = x[WrongAssignCount-17]
_ = x[UnassignableOperand-18]
_ = x[NoNewVar-19]
_ = x[MultiValAssignOp-20]
_ = x[InvalidIfaceAssign-21]
_ = x[InvalidChanAssign-22]
_ = x[IncompatibleAssign-23]
_ = x[UnaddressableFieldAssign-24]
_ = x[NotAType-25]
_ = x[InvalidArrayLen-26]
_ = x[BlankIfaceMethod-27]
_ = x[IncomparableMapKey-28]
_ = x[InvalidIfaceEmbed-29]
_ = x[InvalidPtrEmbed-30]
_ = x[BadRecv-31]
_ = x[InvalidRecv-32]
_ = x[DuplicateFieldAndMethod-33]
_ = x[DuplicateMethod-34]
_ = x[InvalidBlank-35]
_ = x[InvalidIota-36]
_ = x[MissingInitBody-37]
_ = x[InvalidInitSig-38]
_ = x[InvalidInitDecl-39]
_ = x[InvalidMainDecl-40]
_ = x[TooManyValues-41]
_ = x[NotAnExpr-42]
_ = x[TruncatedFloat-43]
_ = x[NumericOverflow-44]
_ = x[UndefinedOp-45]
_ = x[MismatchedTypes-46]
_ = x[DivByZero-47]
_ = x[NonNumericIncDec-48]
_ = x[UnaddressableOperand-49]
_ = x[InvalidIndirection-50]
_ = x[NonIndexableOperand-51]
_ = x[InvalidIndex-52]
_ = x[SwappedSliceIndices-53]
_ = x[NonSliceableOperand-54]
_ = x[InvalidSliceExpr-55]
_ = x[InvalidShiftCount-56]
_ = x[InvalidShiftOperand-57]
_ = x[InvalidReceive-58]
_ = x[InvalidSend-59]
_ = x[DuplicateLitKey-60]
_ = x[MissingLitKey-61]
_ = x[InvalidLitIndex-62]
_ = x[OversizeArrayLit-63]
_ = x[MixedStructLit-64]
_ = x[InvalidStructLit-65]
_ = x[MissingLitField-66]
_ = x[DuplicateLitField-67]
_ = x[UnexportedLitField-68]
_ = x[InvalidLitField-69]
_ = x[UntypedLit-70]
_ = x[InvalidLit-71]
_ = x[AmbiguousSelector-72]
_ = x[UndeclaredImportedName-73]
_ = x[UnexportedName-74]
_ = x[UndeclaredName-75]
_ = x[MissingFieldOrMethod-76]
_ = x[BadDotDotDotSyntax-77]
_ = x[NonVariadicDotDotDot-78]
_ = x[MisplacedDotDotDot-79]
_ = x[InvalidDotDotDotOperand-80]
_ = x[InvalidDotDotDot-81]
_ = x[UncalledBuiltin-82]
_ = x[InvalidAppend-83]
_ = x[InvalidCap-84]
_ = x[InvalidClose-85]
_ = x[InvalidCopy-86]
_ = x[InvalidComplex-87]
_ = x[InvalidDelete-88]
_ = x[InvalidImag-89]
_ = x[InvalidLen-90]
_ = x[SwappedMakeArgs-91]
_ = x[InvalidMake-92]
_ = x[InvalidReal-93]
_ = x[InvalidAssert-94]
_ = x[ImpossibleAssert-95]
_ = x[InvalidConversion-96]
_ = x[InvalidUntypedConversion-97]
_ = x[BadOffsetofSyntax-98]
_ = x[InvalidOffsetof-99]
_ = x[UnusedExpr-100]
_ = x[UnusedVar-101]
_ = x[MissingReturn-102]
_ = x[WrongResultCount-103]
_ = x[OutOfScopeResult-104]
_ = x[InvalidCond-105]
_ = x[InvalidPostDecl-106]
_ = x[InvalidChanRange-107]
_ = x[InvalidIterVar-108]
_ = x[InvalidRangeExpr-109]
_ = x[MisplacedBreak-110]
_ = x[MisplacedContinue-111]
_ = x[MisplacedFallthrough-112]
_ = x[DuplicateCase-113]
_ = x[DuplicateDefault-114]
_ = x[BadTypeKeyword-115]
_ = x[InvalidTypeSwitch-116]
_ = x[InvalidSelectCase-117]
_ = x[UndeclaredLabel-118]
_ = x[DuplicateLabel-119]
_ = x[MisplacedLabel-120]
_ = x[UnusedLabel-121]
_ = x[JumpOverDecl-122]
_ = x[JumpIntoBlock-123]
_ = x[InvalidMethodExpr-124]
_ = x[WrongArgCount-125]
_ = x[InvalidCall-126]
_ = x[UnusedResults-127]
_ = x[InvalidDefer-128]
_ = x[InvalidGo-129]
}
const _ErrorCode_name = "TestBlankPkgNameMismatchedPkgNameInvalidPkgUseBadImportPathBrokenImportImportCRenamedUnusedImportInvalidInitCycleDuplicateDeclInvalidDeclCycleInvalidTypeCycleInvalidConstInitInvalidConstValInvalidConstTypeUntypedNilWrongAssignCountUnassignableOperandNoNewVarMultiValAssignOpInvalidIfaceAssignInvalidChanAssignIncompatibleAssignUnaddressableFieldAssignNotATypeInvalidArrayLenBlankIfaceMethodIncomparableMapKeyInvalidIfaceEmbedInvalidPtrEmbedBadRecvInvalidRecvDuplicateFieldAndMethodDuplicateMethodInvalidBlankInvalidIotaMissingInitBodyInvalidInitSigInvalidInitDeclInvalidMainDeclTooManyValuesNotAnExprTruncatedFloatNumericOverflowUndefinedOpMismatchedTypesDivByZeroNonNumericIncDecUnaddressableOperandInvalidIndirectionNonIndexableOperandInvalidIndexSwappedSliceIndicesNonSliceableOperandInvalidSliceExprInvalidShiftCountInvalidShiftOperandInvalidReceiveInvalidSendDuplicateLitKeyMissingLitKeyInvalidLitIndexOversizeArrayLitMixedStructLitInvalidStructLitMissingLitFieldDuplicateLitFieldUnexportedLitFieldInvalidLitFieldUntypedLitInvalidLitAmbiguousSelectorUndeclaredImportedNameUnexportedNameUndeclaredNameMissingFieldOrMethodBadDotDotDotSyntaxNonVariadicDotDotDotMisplacedDotDotDotInvalidDotDotDotOperandInvalidDotDotDotUncalledBuiltinInvalidAppendInvalidCapInvalidCloseInvalidCopyInvalidComplexInvalidDeleteInvalidImagInvalidLenSwappedMakeArgsInvalidMakeInvalidRealInvalidAssertImpossibleAssertInvalidConversionInvalidUntypedConversionBadOffsetofSyntaxInvalidOffsetofUnusedExprUnusedVarMissingReturnWrongResultCountOutOfScopeResultInvalidCondInvalidPostDeclInvalidChanRangeInvalidIterVarInvalidRangeExprMisplacedBreakMisplacedContinueMisplacedFallthroughDuplicateCaseDuplicateDefaultBadTypeKeywordInvalidTypeSwitchInvalidSelectCaseUndeclaredLabelDuplicateLabelMisplacedLabelUnusedLabelJumpOverDeclJumpIntoBlockInvalidMethodExprWrongArgCountInvalidCallUnusedResultsInvalidDeferInvalidGo"
var _ErrorCode_index = [...]uint16{0, 4, 16, 33, 46, 59, 71, 85, 97, 113, 126, 142, 158, 174, 189, 205, 215, 231, 250, 258, 274, 292, 309, 327, 351, 359, 374, 390, 408, 425, 440, 447, 458, 481, 496, 508, 519, 534, 548, 563, 578, 591, 600, 614, 629, 640, 655, 664, 680, 700, 718, 737, 749, 768, 787, 803, 820, 839, 853, 864, 879, 892, 907, 923, 937, 953, 968, 985, 1003, 1018, 1028, 1038, 1055, 1077, 1091, 1105, 1125, 1143, 1163, 1181, 1204, 1220, 1235, 1248, 1258, 1270, 1281, 1295, 1308, 1319, 1329, 1344, 1355, 1366, 1379, 1395, 1412, 1436, 1453, 1468, 1478, 1487, 1500, 1516, 1532, 1543, 1558, 1574, 1588, 1604, 1618, 1635, 1655, 1668, 1684, 1698, 1715, 1732, 1747, 1761, 1775, 1786, 1798, 1811, 1828, 1841, 1852, 1865, 1877, 1886}
func (i ErrorCode) String() string {
i -= 1
if i < 0 || i >= ErrorCode(len(_ErrorCode_index)-1) {
return "ErrorCode(" + strconv.FormatInt(int64(i+1), 10) + ")"
}
return _ErrorCode_name[_ErrorCode_index[i]:_ErrorCode_index[i+1]]
}

45
vendor/golang.org/x/tools/internal/typesinternal/types.go generated vendored Normal file
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// Copyright 2020 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 typesinternal provides access to internal go/types APIs that are not
// yet exported.
package typesinternal
import (
"go/token"
"go/types"
"reflect"
"unsafe"
)
func SetUsesCgo(conf *types.Config) bool {
v := reflect.ValueOf(conf).Elem()
f := v.FieldByName("go115UsesCgo")
if !f.IsValid() {
f = v.FieldByName("UsesCgo")
if !f.IsValid() {
return false
}
}
addr := unsafe.Pointer(f.UnsafeAddr())
*(*bool)(addr) = true
return true
}
func ReadGo116ErrorData(terr types.Error) (ErrorCode, token.Pos, token.Pos, bool) {
var data [3]int
// By coincidence all of these fields are ints, which simplifies things.
v := reflect.ValueOf(terr)
for i, name := range []string{"go116code", "go116start", "go116end"} {
f := v.FieldByName(name)
if !f.IsValid() {
return 0, 0, 0, false
}
data[i] = int(f.Int())
}
return ErrorCode(data[0]), token.Pos(data[1]), token.Pos(data[2]), true
}