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go.mod: bump client-go and api machinerie

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I had to run `make generate`.
Some API functions got additional parameters `Options` and `Context`.
I used empty options and `context.TODO()` for now.

Signed-off-by: leonnicolas <leonloechner@gmx.de>
This commit is contained in:
leonnicolas
2021-05-15 12:08:31 +02:00
parent f2c37b9de6
commit a3bf13711c
2386 changed files with 419055 additions and 183398 deletions
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85
vendor/golang.org/x/tools/internal/event/core/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 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
}

70
vendor/golang.org/x/tools/internal/event/core/export.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"
"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) }
}

77
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))
}

7
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
}

22
vendor/golang.org/x/tools/internal/event/keys/standard.go generated vendored Normal file
View File

@@ -0,0 +1,22 @@
// 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
View File

@@ -0,0 +1,213 @@
// 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}
}

10
vendor/golang.org/x/tools/internal/fastwalk/fastwalk.go generated vendored
View File

@@ -14,14 +14,14 @@ import (
"sync"
)
// TraverseLink is used as a return value from WalkFuncs to indicate that the
// ErrTraverseLink is used as a return value from WalkFuncs to indicate that the
// symlink named in the call may be traversed.
var TraverseLink = errors.New("fastwalk: traverse symlink, assuming target is a directory")
var ErrTraverseLink = errors.New("fastwalk: traverse symlink, assuming target is a directory")
// SkipFiles is a used as a return value from WalkFuncs to indicate that the
// ErrSkipFiles is a used as a return value from WalkFuncs to indicate that the
// callback should not be called for any other files in the current directory.
// Child directories will still be traversed.
var SkipFiles = errors.New("fastwalk: skip remaining files in directory")
var ErrSkipFiles = errors.New("fastwalk: skip remaining files in directory")
// Walk is a faster implementation of filepath.Walk.
//
@@ -167,7 +167,7 @@ func (w *walker) onDirEnt(dirName, baseName string, typ os.FileMode) error {
err := w.fn(joined, typ)
if typ == os.ModeSymlink {
if err == TraverseLink {
if err == ErrTraverseLink {
// Set callbackDone so we don't call it twice for both the
// symlink-as-symlink and the symlink-as-directory later:
w.enqueue(walkItem{dir: joined, callbackDone: true})

2
vendor/golang.org/x/tools/internal/fastwalk/fastwalk_portable.go generated vendored
View File

@@ -26,7 +26,7 @@ func readDir(dirName string, fn func(dirName, entName string, typ os.FileMode) e
continue
}
if err := fn(dirName, fi.Name(), fi.Mode()&os.ModeType); err != nil {
if err == SkipFiles {
if err == ErrSkipFiles {
skipFiles = true
continue
}

7
vendor/golang.org/x/tools/internal/fastwalk/fastwalk_unix.go generated vendored
View File

@@ -66,7 +66,7 @@ func readDir(dirName string, fn func(dirName, entName string, typ os.FileMode) e
continue
}
if err := fn(dirName, name, typ); err != nil {
if err == SkipFiles {
if err == ErrSkipFiles {
skipFiles = true
continue
}
@@ -76,8 +76,9 @@ func readDir(dirName string, fn func(dirName, entName string, typ os.FileMode) e
}
func parseDirEnt(buf []byte) (consumed int, name string, typ os.FileMode) {
// golang.org/issue/15653
dirent := (*syscall.Dirent)(unsafe.Pointer(&buf[0]))
// golang.org/issue/37269
dirent := &syscall.Dirent{}
copy((*[unsafe.Sizeof(syscall.Dirent{})]byte)(unsafe.Pointer(dirent))[:], buf)
if v := unsafe.Offsetof(dirent.Reclen) + unsafe.Sizeof(dirent.Reclen); uintptr(len(buf)) < v {
panic(fmt.Sprintf("buf size of %d smaller than dirent header size %d", len(buf), v))
}

273
vendor/golang.org/x/tools/internal/gocommand/invoke.go generated vendored Normal file
View File

@@ -0,0 +1,273 @@
// 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"
exec "golang.org/x/sys/execabs"
"io"
"os"
"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
View File

@@ -0,0 +1,102 @@
// 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
}

51
vendor/golang.org/x/tools/internal/gocommand/version.go generated vendored Normal file
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@@ -0,0 +1,51 @@
// 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, and remove them from BuildFlags, if they're
// present.
inv.ModFile = ""
inv.ModFlag = ""
var buildFlags []string
for _, flag := range inv.BuildFlags {
// Flags can be prefixed by one or two dashes.
f := strings.TrimPrefix(strings.TrimPrefix(flag, "-"), "-")
if strings.HasPrefix(f, "mod=") || strings.HasPrefix(f, "modfile=") {
continue
}
buildFlags = append(buildFlags, flag)
}
inv.BuildFlags = buildFlags
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)
}

90
vendor/golang.org/x/tools/internal/gopathwalk/walk.go generated vendored
View File

@@ -10,20 +10,22 @@ import (
"bufio"
"bytes"
"fmt"
"go/build"
"io/ioutil"
"log"
"os"
"path/filepath"
"strings"
"time"
"golang.org/x/tools/internal/fastwalk"
)
// Options controls the behavior of a Walk call.
type Options struct {
Debug bool // Enable debug logging
ModulesEnabled bool // Search module caches. Also disables legacy goimports ignore rules.
// If Logf is non-nil, debug logging is enabled through this function.
Logf func(format string, args ...interface{})
// Search module caches. Also disables legacy goimports ignore rules.
ModulesEnabled bool
}
// RootType indicates the type of a Root.
@@ -44,39 +46,44 @@ type Root struct {
Type RootType
}
// SrcDirsRoots returns the roots from build.Default.SrcDirs(). Not modules-compatible.
func SrcDirsRoots(ctx *build.Context) []Root {
var roots []Root
roots = append(roots, Root{filepath.Join(ctx.GOROOT, "src"), RootGOROOT})
for _, p := range filepath.SplitList(ctx.GOPATH) {
roots = append(roots, Root{filepath.Join(p, "src"), RootGOPATH})
}
return roots
}
// Walk walks Go source directories ($GOROOT, $GOPATH, etc) to find packages.
// For each package found, add will be called (concurrently) with the absolute
// paths of the containing source directory and the package directory.
// add will be called concurrently.
func Walk(roots []Root, add func(root Root, dir string), opts Options) {
WalkSkip(roots, add, func(Root, string) bool { return false }, opts)
}
// WalkSkip walks Go source directories ($GOROOT, $GOPATH, etc) to find packages.
// For each package found, add will be called (concurrently) with the absolute
// paths of the containing source directory and the package directory.
// For each directory that will be scanned, skip will be called (concurrently)
// with the absolute paths of the containing source directory and the directory.
// If skip returns false on a directory it will be processed.
// add will be called concurrently.
// skip will be called concurrently.
func WalkSkip(roots []Root, add func(root Root, dir string), skip func(root Root, dir string) bool, opts Options) {
for _, root := range roots {
walkDir(root, add, opts)
walkDir(root, add, skip, opts)
}
}
func walkDir(root Root, add func(Root, string), opts Options) {
// walkDir creates a walker and starts fastwalk with this walker.
func walkDir(root Root, add func(Root, string), skip func(root Root, dir string) bool, opts Options) {
if _, err := os.Stat(root.Path); os.IsNotExist(err) {
if opts.Debug {
log.Printf("skipping nonexistant directory: %v", root.Path)
if opts.Logf != nil {
opts.Logf("skipping nonexistent directory: %v", root.Path)
}
return
}
if opts.Debug {
log.Printf("scanning %s", root.Path)
start := time.Now()
if opts.Logf != nil {
opts.Logf("gopathwalk: scanning %s", root.Path)
}
w := &walker{
root: root,
add: add,
skip: skip,
opts: opts,
}
w.init()
@@ -84,21 +91,22 @@ func walkDir(root Root, add func(Root, string), opts Options) {
log.Printf("gopathwalk: scanning directory %v: %v", root.Path, err)
}
if opts.Debug {
log.Printf("scanned %s", root.Path)
if opts.Logf != nil {
opts.Logf("gopathwalk: scanned %s in %v", root.Path, time.Since(start))
}
}
// walker is the callback for fastwalk.Walk.
type walker struct {
root Root // The source directory to scan.
add func(Root, string) // The callback that will be invoked for every possible Go package dir.
opts Options // Options passed to Walk by the user.
root Root // The source directory to scan.
add func(Root, string) // The callback that will be invoked for every possible Go package dir.
skip func(Root, string) bool // The callback that will be invoked for every dir. dir is skipped if it returns true.
opts Options // Options passed to Walk by the user.
ignoredDirs []os.FileInfo // The ignored directories, loaded from .goimportsignore files.
}
// init initializes the walker based on its Options.
// init initializes the walker based on its Options
func (w *walker) init() {
var ignoredPaths []string
if w.root.Type == RootModuleCache {
@@ -113,11 +121,11 @@ func (w *walker) init() {
full := filepath.Join(w.root.Path, p)
if fi, err := os.Stat(full); err == nil {
w.ignoredDirs = append(w.ignoredDirs, fi)
if w.opts.Debug {
log.Printf("Directory added to ignore list: %s", full)
if w.opts.Logf != nil {
w.opts.Logf("Directory added to ignore list: %s", full)
}
} else if w.opts.Debug {
log.Printf("Error statting ignored directory: %v", err)
} else if w.opts.Logf != nil {
w.opts.Logf("Error statting ignored directory: %v", err)
}
}
}
@@ -128,11 +136,11 @@ func (w *walker) init() {
func (w *walker) getIgnoredDirs(path string) []string {
file := filepath.Join(path, ".goimportsignore")
slurp, err := ioutil.ReadFile(file)
if w.opts.Debug {
if w.opts.Logf != nil {
if err != nil {
log.Print(err)
w.opts.Logf("%v", err)
} else {
log.Printf("Read %s", file)
w.opts.Logf("Read %s", file)
}
}
if err != nil {
@@ -151,29 +159,35 @@ func (w *walker) getIgnoredDirs(path string) []string {
return ignoredDirs
}
func (w *walker) shouldSkipDir(fi os.FileInfo) bool {
// shouldSkipDir reports whether the file should be skipped or not.
func (w *walker) shouldSkipDir(fi os.FileInfo, dir string) bool {
for _, ignoredDir := range w.ignoredDirs {
if os.SameFile(fi, ignoredDir) {
return true
}
}
if w.skip != nil {
// Check with the user specified callback.
return w.skip(w.root, dir)
}
return false
}
// walk walks through the given path.
func (w *walker) walk(path string, typ os.FileMode) error {
dir := filepath.Dir(path)
if typ.IsRegular() {
if dir == w.root.Path && (w.root.Type == RootGOROOT || w.root.Type == RootGOPATH) {
// Doesn't make sense to have regular files
// directly in your $GOPATH/src or $GOROOT/src.
return fastwalk.SkipFiles
return fastwalk.ErrSkipFiles
}
if !strings.HasSuffix(path, ".go") {
return nil
}
w.add(w.root, dir)
return fastwalk.SkipFiles
return fastwalk.ErrSkipFiles
}
if typ == os.ModeDir {
base := filepath.Base(path)
@@ -184,7 +198,7 @@ func (w *walker) walk(path string, typ os.FileMode) error {
return filepath.SkipDir
}
fi, err := os.Lstat(path)
if err == nil && w.shouldSkipDir(fi) {
if err == nil && w.shouldSkipDir(fi, path) {
return filepath.SkipDir
}
return nil
@@ -201,7 +215,7 @@ func (w *walker) walk(path string, typ os.FileMode) error {
return nil
}
if w.shouldTraverse(dir, fi) {
return fastwalk.TraverseLink
return fastwalk.ErrTraverseLink
}
}
return nil
@@ -224,7 +238,7 @@ func (w *walker) shouldTraverse(dir string, fi os.FileInfo) bool {
if !ts.IsDir() {
return false
}
if w.shouldSkipDir(ts) {
if w.shouldSkipDir(ts, dir) {
return false
}
// Check for symlink loops by statting each directory component

1730
vendor/golang.org/x/tools/internal/imports/fix.go generated vendored Normal file
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346
vendor/golang.org/x/tools/internal/imports/imports.go generated vendored Normal file
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@@ -0,0 +1,346 @@
// Copyright 2013 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
//go:generate go run mkstdlib.go
// Package imports implements a Go pretty-printer (like package "go/format")
// that also adds or removes import statements as necessary.
package imports
import (
"bufio"
"bytes"
"fmt"
"go/ast"
"go/format"
"go/parser"
"go/printer"
"go/token"
"io"
"regexp"
"strconv"
"strings"
"golang.org/x/tools/go/ast/astutil"
)
// Options is golang.org/x/tools/imports.Options with extra internal-only options.
type Options struct {
Env *ProcessEnv // The environment to use. Note: this contains the cached module and filesystem state.
// LocalPrefix is a comma-separated string of import path prefixes, which, if
// set, instructs Process to sort the import paths with the given prefixes
// into another group after 3rd-party packages.
LocalPrefix string
Fragment bool // Accept fragment of a source file (no package statement)
AllErrors bool // Report all errors (not just the first 10 on different lines)
Comments bool // Print comments (true if nil *Options provided)
TabIndent bool // Use tabs for indent (true if nil *Options provided)
TabWidth int // Tab width (8 if nil *Options provided)
FormatOnly bool // Disable the insertion and deletion of imports
}
// Process implements golang.org/x/tools/imports.Process with explicit context in opt.Env.
func Process(filename string, src []byte, opt *Options) (formatted []byte, err error) {
fileSet := token.NewFileSet()
file, adjust, err := parse(fileSet, filename, src, opt)
if err != nil {
return nil, err
}
if !opt.FormatOnly {
if err := fixImports(fileSet, file, filename, opt.Env); err != nil {
return nil, err
}
}
return formatFile(fileSet, file, src, adjust, opt)
}
// FixImports returns a list of fixes to the imports that, when applied,
// will leave the imports in the same state as Process. src and opt must
// be specified.
//
// Note that filename's directory influences which imports can be chosen,
// so it is important that filename be accurate.
func FixImports(filename string, src []byte, opt *Options) (fixes []*ImportFix, err error) {
fileSet := token.NewFileSet()
file, _, err := parse(fileSet, filename, src, opt)
if err != nil {
return nil, err
}
return getFixes(fileSet, file, filename, opt.Env)
}
// ApplyFixes applies all of the fixes to the file and formats it. extraMode
// is added in when parsing the file. src and opts must be specified, but no
// env is needed.
func ApplyFixes(fixes []*ImportFix, filename string, src []byte, opt *Options, extraMode parser.Mode) (formatted []byte, err error) {
// Don't use parse() -- we don't care about fragments or statement lists
// here, and we need to work with unparseable files.
fileSet := token.NewFileSet()
parserMode := parser.Mode(0)
if opt.Comments {
parserMode |= parser.ParseComments
}
if opt.AllErrors {
parserMode |= parser.AllErrors
}
parserMode |= extraMode
file, err := parser.ParseFile(fileSet, filename, src, parserMode)
if file == nil {
return nil, err
}
// Apply the fixes to the file.
apply(fileSet, file, fixes)
return formatFile(fileSet, file, src, nil, opt)
}
func formatFile(fileSet *token.FileSet, file *ast.File, src []byte, adjust func(orig []byte, src []byte) []byte, opt *Options) ([]byte, error) {
mergeImports(fileSet, file)
sortImports(opt.LocalPrefix, fileSet, file)
imps := astutil.Imports(fileSet, file)
var spacesBefore []string // import paths we need spaces before
for _, impSection := range imps {
// Within each block of contiguous imports, see if any
// import lines are in different group numbers. If so,
// we'll need to put a space between them so it's
// compatible with gofmt.
lastGroup := -1
for _, importSpec := range impSection {
importPath, _ := strconv.Unquote(importSpec.Path.Value)
groupNum := importGroup(opt.LocalPrefix, importPath)
if groupNum != lastGroup && lastGroup != -1 {
spacesBefore = append(spacesBefore, importPath)
}
lastGroup = groupNum
}
}
printerMode := printer.UseSpaces
if opt.TabIndent {
printerMode |= printer.TabIndent
}
printConfig := &printer.Config{Mode: printerMode, Tabwidth: opt.TabWidth}
var buf bytes.Buffer
err := printConfig.Fprint(&buf, fileSet, file)
if err != nil {
return nil, err
}
out := buf.Bytes()
if adjust != nil {
out = adjust(src, out)
}
if len(spacesBefore) > 0 {
out, err = addImportSpaces(bytes.NewReader(out), spacesBefore)
if err != nil {
return nil, err
}
}
out, err = format.Source(out)
if err != nil {
return nil, err
}
return out, nil
}
// parse parses src, which was read from filename,
// as a Go source file or statement list.
func parse(fset *token.FileSet, filename string, src []byte, opt *Options) (*ast.File, func(orig, src []byte) []byte, error) {
parserMode := parser.Mode(0)
if opt.Comments {
parserMode |= parser.ParseComments
}
if opt.AllErrors {
parserMode |= parser.AllErrors
}
// Try as whole source file.
file, err := parser.ParseFile(fset, filename, src, parserMode)
if err == nil {
return file, nil, nil
}
// If the error is that the source file didn't begin with a
// package line and we accept fragmented input, fall through to
// try as a source fragment. Stop and return on any other error.
if !opt.Fragment || !strings.Contains(err.Error(), "expected 'package'") {
return nil, nil, err
}
// If this is a declaration list, make it a source file
// by inserting a package clause.
// Insert using a ;, not a newline, so that parse errors are on
// the correct line.
const prefix = "package main;"
psrc := append([]byte(prefix), src...)
file, err = parser.ParseFile(fset, filename, psrc, parserMode)
if err == nil {
// Gofmt will turn the ; into a \n.
// Do that ourselves now and update the file contents,
// so that positions and line numbers are correct going forward.
psrc[len(prefix)-1] = '\n'
fset.File(file.Package).SetLinesForContent(psrc)
// If a main function exists, we will assume this is a main
// package and leave the file.
if containsMainFunc(file) {
return file, nil, nil
}
adjust := func(orig, src []byte) []byte {
// Remove the package clause.
src = src[len(prefix):]
return matchSpace(orig, src)
}
return file, adjust, nil
}
// If the error is that the source file didn't begin with a
// declaration, fall through to try as a statement list.
// Stop and return on any other error.
if !strings.Contains(err.Error(), "expected declaration") {
return nil, nil, err
}
// If this is a statement list, make it a source file
// by inserting a package clause and turning the list
// into a function body. This handles expressions too.
// Insert using a ;, not a newline, so that the line numbers
// in fsrc match the ones in src.
fsrc := append(append([]byte("package p; func _() {"), src...), '}')
file, err = parser.ParseFile(fset, filename, fsrc, parserMode)
if err == nil {
adjust := func(orig, src []byte) []byte {
// Remove the wrapping.
// Gofmt has turned the ; into a \n\n.
src = src[len("package p\n\nfunc _() {"):]
src = src[:len(src)-len("}\n")]
// Gofmt has also indented the function body one level.
// Remove that indent.
src = bytes.Replace(src, []byte("\n\t"), []byte("\n"), -1)
return matchSpace(orig, src)
}
return file, adjust, nil
}
// Failed, and out of options.
return nil, nil, err
}
// containsMainFunc checks if a file contains a function declaration with the
// function signature 'func main()'
func containsMainFunc(file *ast.File) bool {
for _, decl := range file.Decls {
if f, ok := decl.(*ast.FuncDecl); ok {
if f.Name.Name != "main" {
continue
}
if len(f.Type.Params.List) != 0 {
continue
}
if f.Type.Results != nil && len(f.Type.Results.List) != 0 {
continue
}
return true
}
}
return false
}
func cutSpace(b []byte) (before, middle, after []byte) {
i := 0
for i < len(b) && (b[i] == ' ' || b[i] == '\t' || b[i] == '\n') {
i++
}
j := len(b)
for j > 0 && (b[j-1] == ' ' || b[j-1] == '\t' || b[j-1] == '\n') {
j--
}
if i <= j {
return b[:i], b[i:j], b[j:]
}
return nil, nil, b[j:]
}
// matchSpace reformats src to use the same space context as orig.
// 1) If orig begins with blank lines, matchSpace inserts them at the beginning of src.
// 2) matchSpace copies the indentation of the first non-blank line in orig
// to every non-blank line in src.
// 3) matchSpace copies the trailing space from orig and uses it in place
// of src's trailing space.
func matchSpace(orig []byte, src []byte) []byte {
before, _, after := cutSpace(orig)
i := bytes.LastIndex(before, []byte{'\n'})
before, indent := before[:i+1], before[i+1:]
_, src, _ = cutSpace(src)
var b bytes.Buffer
b.Write(before)
for len(src) > 0 {
line := src
if i := bytes.IndexByte(line, '\n'); i >= 0 {
line, src = line[:i+1], line[i+1:]
} else {
src = nil
}
if len(line) > 0 && line[0] != '\n' { // not blank
b.Write(indent)
}
b.Write(line)
}
b.Write(after)
return b.Bytes()
}
var impLine = regexp.MustCompile(`^\s+(?:[\w\.]+\s+)?"(.+)"`)
func addImportSpaces(r io.Reader, breaks []string) ([]byte, error) {
var out bytes.Buffer
in := bufio.NewReader(r)
inImports := false
done := false
for {
s, err := in.ReadString('\n')
if err == io.EOF {
break
} else if err != nil {
return nil, err
}
if !inImports && !done && strings.HasPrefix(s, "import") {
inImports = true
}
if inImports && (strings.HasPrefix(s, "var") ||
strings.HasPrefix(s, "func") ||
strings.HasPrefix(s, "const") ||
strings.HasPrefix(s, "type")) {
done = true
inImports = false
}
if inImports && len(breaks) > 0 {
if m := impLine.FindStringSubmatch(s); m != nil {
if m[1] == breaks[0] {
out.WriteByte('\n')
breaks = breaks[1:]
}
}
}
fmt.Fprint(&out, s)
}
return out.Bytes(), nil
}

693
vendor/golang.org/x/tools/internal/imports/mod.go generated vendored Normal file
View File

@@ -0,0 +1,693 @@
// 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 imports
import (
"bytes"
"context"
"encoding/json"
"fmt"
"io/ioutil"
"os"
"path"
"path/filepath"
"regexp"
"sort"
"strconv"
"strings"
"golang.org/x/mod/module"
"golang.org/x/tools/internal/gocommand"
"golang.org/x/tools/internal/gopathwalk"
)
// ModuleResolver implements resolver for modules using the go command as little
// as feasible.
type ModuleResolver struct {
env *ProcessEnv
moduleCacheDir string
dummyVendorMod *gocommand.ModuleJSON // If vendoring is enabled, the pseudo-module that represents the /vendor directory.
roots []gopathwalk.Root
scanSema chan struct{} // scanSema prevents concurrent scans and guards scannedRoots.
scannedRoots map[gopathwalk.Root]bool
initialized bool
main *gocommand.ModuleJSON
modsByModPath []*gocommand.ModuleJSON // All modules, ordered by # of path components in module Path...
modsByDir []*gocommand.ModuleJSON // ...or Dir.
// moduleCacheCache stores information about the module cache.
moduleCacheCache *dirInfoCache
otherCache *dirInfoCache
}
func newModuleResolver(e *ProcessEnv) *ModuleResolver {
r := &ModuleResolver{
env: e,
scanSema: make(chan struct{}, 1),
}
r.scanSema <- struct{}{}
return r
}
func (r *ModuleResolver) init() error {
if r.initialized {
return nil
}
goenv, err := r.env.goEnv()
if err != nil {
return err
}
inv := gocommand.Invocation{
BuildFlags: r.env.BuildFlags,
ModFlag: r.env.ModFlag,
ModFile: r.env.ModFile,
Env: r.env.env(),
Logf: r.env.Logf,
WorkingDir: r.env.WorkingDir,
}
mainMod, vendorEnabled, err := gocommand.VendorEnabled(context.TODO(), inv, r.env.GocmdRunner)
if err != nil {
return err
}
if mainMod != nil && vendorEnabled {
// Vendor mode is on, so all the non-Main modules are irrelevant,
// and we need to search /vendor for everything.
r.main = mainMod
r.dummyVendorMod = &gocommand.ModuleJSON{
Path: "",
Dir: filepath.Join(mainMod.Dir, "vendor"),
}
r.modsByModPath = []*gocommand.ModuleJSON{mainMod, r.dummyVendorMod}
r.modsByDir = []*gocommand.ModuleJSON{mainMod, r.dummyVendorMod}
} else {
// Vendor mode is off, so run go list -m ... to find everything.
err := r.initAllMods()
// We expect an error when running outside of a module with
// GO111MODULE=on. Other errors are fatal.
if err != nil && !strings.Contains(err.Error(), "working directory is not part of a module") {
return err
}
}
if gmc := r.env.Env["GOMODCACHE"]; gmc != "" {
r.moduleCacheDir = gmc
} else {
gopaths := filepath.SplitList(goenv["GOPATH"])
if len(gopaths) == 0 {
return fmt.Errorf("empty GOPATH")
}
r.moduleCacheDir = filepath.Join(gopaths[0], "/pkg/mod")
}
sort.Slice(r.modsByModPath, func(i, j int) bool {
count := func(x int) int {
return strings.Count(r.modsByModPath[x].Path, "/")
}
return count(j) < count(i) // descending order
})
sort.Slice(r.modsByDir, func(i, j int) bool {
count := func(x int) int {
return strings.Count(r.modsByDir[x].Dir, "/")
}
return count(j) < count(i) // descending order
})
r.roots = []gopathwalk.Root{
{filepath.Join(goenv["GOROOT"], "/src"), gopathwalk.RootGOROOT},
}
if r.main != nil {
r.roots = append(r.roots, gopathwalk.Root{r.main.Dir, gopathwalk.RootCurrentModule})
}
if vendorEnabled {
r.roots = append(r.roots, gopathwalk.Root{r.dummyVendorMod.Dir, gopathwalk.RootOther})
} else {
addDep := func(mod *gocommand.ModuleJSON) {
if mod.Replace == nil {
// This is redundant with the cache, but we'll skip it cheaply enough.
r.roots = append(r.roots, gopathwalk.Root{mod.Dir, gopathwalk.RootModuleCache})
} else {
r.roots = append(r.roots, gopathwalk.Root{mod.Dir, gopathwalk.RootOther})
}
}
// Walk dependent modules before scanning the full mod cache, direct deps first.
for _, mod := range r.modsByModPath {
if !mod.Indirect && !mod.Main {
addDep(mod)
}
}
for _, mod := range r.modsByModPath {
if mod.Indirect && !mod.Main {
addDep(mod)
}
}
r.roots = append(r.roots, gopathwalk.Root{r.moduleCacheDir, gopathwalk.RootModuleCache})
}
r.scannedRoots = map[gopathwalk.Root]bool{}
if r.moduleCacheCache == nil {
r.moduleCacheCache = &dirInfoCache{
dirs: map[string]*directoryPackageInfo{},
listeners: map[*int]cacheListener{},
}
}
if r.otherCache == nil {
r.otherCache = &dirInfoCache{
dirs: map[string]*directoryPackageInfo{},
listeners: map[*int]cacheListener{},
}
}
r.initialized = true
return nil
}
func (r *ModuleResolver) initAllMods() error {
stdout, err := r.env.invokeGo(context.TODO(), "list", "-m", "-e", "-json", "...")
if err != nil {
return err
}
for dec := json.NewDecoder(stdout); dec.More(); {
mod := &gocommand.ModuleJSON{}
if err := dec.Decode(mod); err != nil {
return err
}
if mod.Dir == "" {
if r.env.Logf != nil {
r.env.Logf("module %v has not been downloaded and will be ignored", mod.Path)
}
// Can't do anything with a module that's not downloaded.
continue
}
// golang/go#36193: the go command doesn't always clean paths.
mod.Dir = filepath.Clean(mod.Dir)
r.modsByModPath = append(r.modsByModPath, mod)
r.modsByDir = append(r.modsByDir, mod)
if mod.Main {
r.main = mod
}
}
return nil
}
func (r *ModuleResolver) ClearForNewScan() {
<-r.scanSema
r.scannedRoots = map[gopathwalk.Root]bool{}
r.otherCache = &dirInfoCache{
dirs: map[string]*directoryPackageInfo{},
listeners: map[*int]cacheListener{},
}
r.scanSema <- struct{}{}
}
func (r *ModuleResolver) ClearForNewMod() {
<-r.scanSema
*r = ModuleResolver{
env: r.env,
moduleCacheCache: r.moduleCacheCache,
otherCache: r.otherCache,
scanSema: r.scanSema,
}
r.init()
r.scanSema <- struct{}{}
}
// findPackage returns the module and directory that contains the package at
// the given import path, or returns nil, "" if no module is in scope.
func (r *ModuleResolver) findPackage(importPath string) (*gocommand.ModuleJSON, string) {
// This can't find packages in the stdlib, but that's harmless for all
// the existing code paths.
for _, m := range r.modsByModPath {
if !strings.HasPrefix(importPath, m.Path) {
continue
}
pathInModule := importPath[len(m.Path):]
pkgDir := filepath.Join(m.Dir, pathInModule)
if r.dirIsNestedModule(pkgDir, m) {
continue
}
if info, ok := r.cacheLoad(pkgDir); ok {
if loaded, err := info.reachedStatus(nameLoaded); loaded {
if err != nil {
continue // No package in this dir.
}
return m, pkgDir
}
if scanned, err := info.reachedStatus(directoryScanned); scanned && err != nil {
continue // Dir is unreadable, etc.
}
// This is slightly wrong: a directory doesn't have to have an
// importable package to count as a package for package-to-module
// resolution. package main or _test files should count but
// don't.
// TODO(heschi): fix this.
if _, err := r.cachePackageName(info); err == nil {
return m, pkgDir
}
}
// Not cached. Read the filesystem.
pkgFiles, err := ioutil.ReadDir(pkgDir)
if err != nil {
continue
}
// A module only contains a package if it has buildable go
// files in that directory. If not, it could be provided by an
// outer module. See #29736.
for _, fi := range pkgFiles {
if ok, _ := r.env.matchFile(pkgDir, fi.Name()); ok {
return m, pkgDir
}
}
}
return nil, ""
}
func (r *ModuleResolver) cacheLoad(dir string) (directoryPackageInfo, bool) {
if info, ok := r.moduleCacheCache.Load(dir); ok {
return info, ok
}
return r.otherCache.Load(dir)
}
func (r *ModuleResolver) cacheStore(info directoryPackageInfo) {
if info.rootType == gopathwalk.RootModuleCache {
r.moduleCacheCache.Store(info.dir, info)
} else {
r.otherCache.Store(info.dir, info)
}
}
func (r *ModuleResolver) cacheKeys() []string {
return append(r.moduleCacheCache.Keys(), r.otherCache.Keys()...)
}
// cachePackageName caches the package name for a dir already in the cache.
func (r *ModuleResolver) cachePackageName(info directoryPackageInfo) (string, error) {
if info.rootType == gopathwalk.RootModuleCache {
return r.moduleCacheCache.CachePackageName(info)
}
return r.otherCache.CachePackageName(info)
}
func (r *ModuleResolver) cacheExports(ctx context.Context, env *ProcessEnv, info directoryPackageInfo) (string, []string, error) {
if info.rootType == gopathwalk.RootModuleCache {
return r.moduleCacheCache.CacheExports(ctx, env, info)
}
return r.otherCache.CacheExports(ctx, env, info)
}
// findModuleByDir returns the module that contains dir, or nil if no such
// module is in scope.
func (r *ModuleResolver) findModuleByDir(dir string) *gocommand.ModuleJSON {
// This is quite tricky and may not be correct. dir could be:
// - a package in the main module.
// - a replace target underneath the main module's directory.
// - a nested module in the above.
// - a replace target somewhere totally random.
// - a nested module in the above.
// - in the mod cache.
// - in /vendor/ in -mod=vendor mode.
// - nested module? Dunno.
// Rumor has it that replace targets cannot contain other replace targets.
for _, m := range r.modsByDir {
if !strings.HasPrefix(dir, m.Dir) {
continue
}
if r.dirIsNestedModule(dir, m) {
continue
}
return m
}
return nil
}
// dirIsNestedModule reports if dir is contained in a nested module underneath
// mod, not actually in mod.
func (r *ModuleResolver) dirIsNestedModule(dir string, mod *gocommand.ModuleJSON) bool {
if !strings.HasPrefix(dir, mod.Dir) {
return false
}
if r.dirInModuleCache(dir) {
// Nested modules in the module cache are pruned,
// so it cannot be a nested module.
return false
}
if mod != nil && mod == r.dummyVendorMod {
// The /vendor pseudomodule is flattened and doesn't actually count.
return false
}
modDir, _ := r.modInfo(dir)
if modDir == "" {
return false
}
return modDir != mod.Dir
}
func (r *ModuleResolver) modInfo(dir string) (modDir string, modName string) {
readModName := func(modFile string) string {
modBytes, err := ioutil.ReadFile(modFile)
if err != nil {
return ""
}
return modulePath(modBytes)
}
if r.dirInModuleCache(dir) {
if matches := modCacheRegexp.FindStringSubmatch(dir); len(matches) == 3 {
index := strings.Index(dir, matches[1]+"@"+matches[2])
modDir := filepath.Join(dir[:index], matches[1]+"@"+matches[2])
return modDir, readModName(filepath.Join(modDir, "go.mod"))
}
}
for {
if info, ok := r.cacheLoad(dir); ok {
return info.moduleDir, info.moduleName
}
f := filepath.Join(dir, "go.mod")
info, err := os.Stat(f)
if err == nil && !info.IsDir() {
return dir, readModName(f)
}
d := filepath.Dir(dir)
if len(d) >= len(dir) {
return "", "" // reached top of file system, no go.mod
}
dir = d
}
}
func (r *ModuleResolver) dirInModuleCache(dir string) bool {
if r.moduleCacheDir == "" {
return false
}
return strings.HasPrefix(dir, r.moduleCacheDir)
}
func (r *ModuleResolver) loadPackageNames(importPaths []string, srcDir string) (map[string]string, error) {
if err := r.init(); err != nil {
return nil, err
}
names := map[string]string{}
for _, path := range importPaths {
_, packageDir := r.findPackage(path)
if packageDir == "" {
continue
}
name, err := packageDirToName(packageDir)
if err != nil {
continue
}
names[path] = name
}
return names, nil
}
func (r *ModuleResolver) scan(ctx context.Context, callback *scanCallback) error {
if err := r.init(); err != nil {
return err
}
processDir := func(info directoryPackageInfo) {
// Skip this directory if we were not able to get the package information successfully.
if scanned, err := info.reachedStatus(directoryScanned); !scanned || err != nil {
return
}
pkg, err := r.canonicalize(info)
if err != nil {
return
}
if !callback.dirFound(pkg) {
return
}
pkg.packageName, err = r.cachePackageName(info)
if err != nil {
return
}
if !callback.packageNameLoaded(pkg) {
return
}
_, exports, err := r.loadExports(ctx, pkg, false)
if err != nil {
return
}
callback.exportsLoaded(pkg, exports)
}
// Start processing everything in the cache, and listen for the new stuff
// we discover in the walk below.
stop1 := r.moduleCacheCache.ScanAndListen(ctx, processDir)
defer stop1()
stop2 := r.otherCache.ScanAndListen(ctx, processDir)
defer stop2()
// We assume cached directories are fully cached, including all their
// children, and have not changed. We can skip them.
skip := func(root gopathwalk.Root, dir string) bool {
info, ok := r.cacheLoad(dir)
if !ok {
return false
}
// This directory can be skipped as long as we have already scanned it.
// Packages with errors will continue to have errors, so there is no need
// to rescan them.
packageScanned, _ := info.reachedStatus(directoryScanned)
return packageScanned
}
// Add anything new to the cache, and process it if we're still listening.
add := func(root gopathwalk.Root, dir string) {
r.cacheStore(r.scanDirForPackage(root, dir))
}
// r.roots and the callback are not necessarily safe to use in the
// goroutine below. Process them eagerly.
roots := filterRoots(r.roots, callback.rootFound)
// We can't cancel walks, because we need them to finish to have a usable
// cache. Instead, run them in a separate goroutine and detach.
scanDone := make(chan struct{})
go func() {
select {
case <-ctx.Done():
return
case <-r.scanSema:
}
defer func() { r.scanSema <- struct{}{} }()
// We have the lock on r.scannedRoots, and no other scans can run.
for _, root := range roots {
if ctx.Err() != nil {
return
}
if r.scannedRoots[root] {
continue
}
gopathwalk.WalkSkip([]gopathwalk.Root{root}, add, skip, gopathwalk.Options{Logf: r.env.Logf, ModulesEnabled: true})
r.scannedRoots[root] = true
}
close(scanDone)
}()
select {
case <-ctx.Done():
case <-scanDone:
}
return nil
}
func (r *ModuleResolver) scoreImportPath(ctx context.Context, path string) float64 {
if _, ok := stdlib[path]; ok {
return MaxRelevance
}
mod, _ := r.findPackage(path)
return modRelevance(mod)
}
func modRelevance(mod *gocommand.ModuleJSON) float64 {
var relevance float64
switch {
case mod == nil: // out of scope
return MaxRelevance - 4
case mod.Indirect:
relevance = MaxRelevance - 3
case !mod.Main:
relevance = MaxRelevance - 2
default:
relevance = MaxRelevance - 1 // main module ties with stdlib
}
_, versionString, ok := module.SplitPathVersion(mod.Path)
if ok {
index := strings.Index(versionString, "v")
if index == -1 {
return relevance
}
if versionNumber, err := strconv.ParseFloat(versionString[index+1:], 64); err == nil {
relevance += versionNumber / 1000
}
}
return relevance
}
// canonicalize gets the result of canonicalizing the packages using the results
// of initializing the resolver from 'go list -m'.
func (r *ModuleResolver) canonicalize(info directoryPackageInfo) (*pkg, error) {
// Packages in GOROOT are already canonical, regardless of the std/cmd modules.
if info.rootType == gopathwalk.RootGOROOT {
return &pkg{
importPathShort: info.nonCanonicalImportPath,
dir: info.dir,
packageName: path.Base(info.nonCanonicalImportPath),
relevance: MaxRelevance,
}, nil
}
importPath := info.nonCanonicalImportPath
mod := r.findModuleByDir(info.dir)
// Check if the directory is underneath a module that's in scope.
if mod != nil {
// It is. If dir is the target of a replace directive,
// our guessed import path is wrong. Use the real one.
if mod.Dir == info.dir {
importPath = mod.Path
} else {
dirInMod := info.dir[len(mod.Dir)+len("/"):]
importPath = path.Join(mod.Path, filepath.ToSlash(dirInMod))
}
} else if !strings.HasPrefix(importPath, info.moduleName) {
// The module's name doesn't match the package's import path. It
// probably needs a replace directive we don't have.
return nil, fmt.Errorf("package in %q is not valid without a replace statement", info.dir)
}
res := &pkg{
importPathShort: importPath,
dir: info.dir,
relevance: modRelevance(mod),
}
// We may have discovered a package that has a different version
// in scope already. Canonicalize to that one if possible.
if _, canonicalDir := r.findPackage(importPath); canonicalDir != "" {
res.dir = canonicalDir
}
return res, nil
}
func (r *ModuleResolver) loadExports(ctx context.Context, pkg *pkg, includeTest bool) (string, []string, error) {
if err := r.init(); err != nil {
return "", nil, err
}
if info, ok := r.cacheLoad(pkg.dir); ok && !includeTest {
return r.cacheExports(ctx, r.env, info)
}
return loadExportsFromFiles(ctx, r.env, pkg.dir, includeTest)
}
func (r *ModuleResolver) scanDirForPackage(root gopathwalk.Root, dir string) directoryPackageInfo {
subdir := ""
if dir != root.Path {
subdir = dir[len(root.Path)+len("/"):]
}
importPath := filepath.ToSlash(subdir)
if strings.HasPrefix(importPath, "vendor/") {
// Only enter vendor directories if they're explicitly requested as a root.
return directoryPackageInfo{
status: directoryScanned,
err: fmt.Errorf("unwanted vendor directory"),
}
}
switch root.Type {
case gopathwalk.RootCurrentModule:
importPath = path.Join(r.main.Path, filepath.ToSlash(subdir))
case gopathwalk.RootModuleCache:
matches := modCacheRegexp.FindStringSubmatch(subdir)
if len(matches) == 0 {
return directoryPackageInfo{
status: directoryScanned,
err: fmt.Errorf("invalid module cache path: %v", subdir),
}
}
modPath, err := module.UnescapePath(filepath.ToSlash(matches[1]))
if err != nil {
if r.env.Logf != nil {
r.env.Logf("decoding module cache path %q: %v", subdir, err)
}
return directoryPackageInfo{
status: directoryScanned,
err: fmt.Errorf("decoding module cache path %q: %v", subdir, err),
}
}
importPath = path.Join(modPath, filepath.ToSlash(matches[3]))
}
modDir, modName := r.modInfo(dir)
result := directoryPackageInfo{
status: directoryScanned,
dir: dir,
rootType: root.Type,
nonCanonicalImportPath: importPath,
moduleDir: modDir,
moduleName: modName,
}
if root.Type == gopathwalk.RootGOROOT {
// stdlib packages are always in scope, despite the confusing go.mod
return result
}
return result
}
// modCacheRegexp splits a path in a module cache into module, module version, and package.
var modCacheRegexp = regexp.MustCompile(`(.*)@([^/\\]*)(.*)`)
var (
slashSlash = []byte("//")
moduleStr = []byte("module")
)
// modulePath returns the module path from the gomod file text.
// If it cannot find a module path, it returns an empty string.
// It is tolerant of unrelated problems in the go.mod file.
//
// Copied from cmd/go/internal/modfile.
func modulePath(mod []byte) string {
for len(mod) > 0 {
line := mod
mod = nil
if i := bytes.IndexByte(line, '\n'); i >= 0 {
line, mod = line[:i], line[i+1:]
}
if i := bytes.Index(line, slashSlash); i >= 0 {
line = line[:i]
}
line = bytes.TrimSpace(line)
if !bytes.HasPrefix(line, moduleStr) {
continue
}
line = line[len(moduleStr):]
n := len(line)
line = bytes.TrimSpace(line)
if len(line) == n || len(line) == 0 {
continue
}
if line[0] == '"' || line[0] == '`' {
p, err := strconv.Unquote(string(line))
if err != nil {
return "" // malformed quoted string or multiline module path
}
return p
}
return string(line)
}
return "" // missing module path
}

236
vendor/golang.org/x/tools/internal/imports/mod_cache.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 imports
import (
"context"
"fmt"
"sync"
"golang.org/x/tools/internal/gopathwalk"
)
// To find packages to import, the resolver needs to know about all of the
// the packages that could be imported. This includes packages that are
// already in modules that are in (1) the current module, (2) replace targets,
// and (3) packages in the module cache. Packages in (1) and (2) may change over
// time, as the client may edit the current module and locally replaced modules.
// The module cache (which includes all of the packages in (3)) can only
// ever be added to.
//
// The resolver can thus save state about packages in the module cache
// and guarantee that this will not change over time. To obtain information
// about new modules added to the module cache, the module cache should be
// rescanned.
//
// It is OK to serve information about modules that have been deleted,
// as they do still exist.
// TODO(suzmue): can we share information with the caller about
// what module needs to be downloaded to import this package?
type directoryPackageStatus int
const (
_ directoryPackageStatus = iota
directoryScanned
nameLoaded
exportsLoaded
)
type directoryPackageInfo struct {
// status indicates the extent to which this struct has been filled in.
status directoryPackageStatus
// err is non-nil when there was an error trying to reach status.
err error
// Set when status >= directoryScanned.
// dir is the absolute directory of this package.
dir string
rootType gopathwalk.RootType
// nonCanonicalImportPath is the package's expected import path. It may
// not actually be importable at that path.
nonCanonicalImportPath string
// Module-related information.
moduleDir string // The directory that is the module root of this dir.
moduleName string // The module name that contains this dir.
// Set when status >= nameLoaded.
packageName string // the package name, as declared in the source.
// Set when status >= exportsLoaded.
exports []string
}
// reachedStatus returns true when info has a status at least target and any error associated with
// an attempt to reach target.
func (info *directoryPackageInfo) reachedStatus(target directoryPackageStatus) (bool, error) {
if info.err == nil {
return info.status >= target, nil
}
if info.status == target {
return true, info.err
}
return true, nil
}
// dirInfoCache is a concurrency safe map for storing information about
// directories that may contain packages.
//
// The information in this cache is built incrementally. Entries are initialized in scan.
// No new keys should be added in any other functions, as all directories containing
// packages are identified in scan.
//
// Other functions, including loadExports and findPackage, may update entries in this cache
// as they discover new things about the directory.
//
// The information in the cache is not expected to change for the cache's
// lifetime, so there is no protection against competing writes. Users should
// take care not to hold the cache across changes to the underlying files.
//
// TODO(suzmue): consider other concurrency strategies and data structures (RWLocks, sync.Map, etc)
type dirInfoCache struct {
mu sync.Mutex
// dirs stores information about packages in directories, keyed by absolute path.
dirs map[string]*directoryPackageInfo
listeners map[*int]cacheListener
}
type cacheListener func(directoryPackageInfo)
// ScanAndListen calls listener on all the items in the cache, and on anything
// newly added. The returned stop function waits for all in-flight callbacks to
// finish and blocks new ones.
func (d *dirInfoCache) ScanAndListen(ctx context.Context, listener cacheListener) func() {
ctx, cancel := context.WithCancel(ctx)
// Flushing out all the callbacks is tricky without knowing how many there
// are going to be. Setting an arbitrary limit makes it much easier.
const maxInFlight = 10
sema := make(chan struct{}, maxInFlight)
for i := 0; i < maxInFlight; i++ {
sema <- struct{}{}
}
cookie := new(int) // A unique ID we can use for the listener.
// We can't hold mu while calling the listener.
d.mu.Lock()
var keys []string
for key := range d.dirs {
keys = append(keys, key)
}
d.listeners[cookie] = func(info directoryPackageInfo) {
select {
case <-ctx.Done():
return
case <-sema:
}
listener(info)
sema <- struct{}{}
}
d.mu.Unlock()
stop := func() {
cancel()
d.mu.Lock()
delete(d.listeners, cookie)
d.mu.Unlock()
for i := 0; i < maxInFlight; i++ {
<-sema
}
}
// Process the pre-existing keys.
for _, k := range keys {
select {
case <-ctx.Done():
return stop
default:
}
if v, ok := d.Load(k); ok {
listener(v)
}
}
return stop
}
// Store stores the package info for dir.
func (d *dirInfoCache) Store(dir string, info directoryPackageInfo) {
d.mu.Lock()
_, old := d.dirs[dir]
d.dirs[dir] = &info
var listeners []cacheListener
for _, l := range d.listeners {
listeners = append(listeners, l)
}
d.mu.Unlock()
if !old {
for _, l := range listeners {
l(info)
}
}
}
// Load returns a copy of the directoryPackageInfo for absolute directory dir.
func (d *dirInfoCache) Load(dir string) (directoryPackageInfo, bool) {
d.mu.Lock()
defer d.mu.Unlock()
info, ok := d.dirs[dir]
if !ok {
return directoryPackageInfo{}, false
}
return *info, true
}
// Keys returns the keys currently present in d.
func (d *dirInfoCache) Keys() (keys []string) {
d.mu.Lock()
defer d.mu.Unlock()
for key := range d.dirs {
keys = append(keys, key)
}
return keys
}
func (d *dirInfoCache) CachePackageName(info directoryPackageInfo) (string, error) {
if loaded, err := info.reachedStatus(nameLoaded); loaded {
return info.packageName, err
}
if scanned, err := info.reachedStatus(directoryScanned); !scanned || err != nil {
return "", fmt.Errorf("cannot read package name, scan error: %v", err)
}
info.packageName, info.err = packageDirToName(info.dir)
info.status = nameLoaded
d.Store(info.dir, info)
return info.packageName, info.err
}
func (d *dirInfoCache) CacheExports(ctx context.Context, env *ProcessEnv, info directoryPackageInfo) (string, []string, error) {
if reached, _ := info.reachedStatus(exportsLoaded); reached {
return info.packageName, info.exports, info.err
}
if reached, err := info.reachedStatus(nameLoaded); reached && err != nil {
return "", nil, err
}
info.packageName, info.exports, info.err = loadExportsFromFiles(ctx, env, info.dir, false)
if info.err == context.Canceled || info.err == context.DeadlineExceeded {
return info.packageName, info.exports, info.err
}
// The cache structure wants things to proceed linearly. We can skip a
// step here, but only if we succeed.
if info.status == nameLoaded || info.err == nil {
info.status = exportsLoaded
} else {
info.status = nameLoaded
}
d.Store(info.dir, info)
return info.packageName, info.exports, info.err
}

280
vendor/golang.org/x/tools/internal/imports/sortimports.go generated vendored Normal file
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// Copyright 2013 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.
// Hacked up copy of go/ast/import.go
package imports
import (
"go/ast"
"go/token"
"sort"
"strconv"
)
// sortImports sorts runs of consecutive import lines in import blocks in f.
// It also removes duplicate imports when it is possible to do so without data loss.
func sortImports(localPrefix string, fset *token.FileSet, f *ast.File) {
for i, d := range f.Decls {
d, ok := d.(*ast.GenDecl)
if !ok || d.Tok != token.IMPORT {
// Not an import declaration, so we're done.
// Imports are always first.
break
}
if len(d.Specs) == 0 {
// Empty import block, remove it.
f.Decls = append(f.Decls[:i], f.Decls[i+1:]...)
}
if !d.Lparen.IsValid() {
// Not a block: sorted by default.
continue
}
// Identify and sort runs of specs on successive lines.
i := 0
specs := d.Specs[:0]
for j, s := range d.Specs {
if j > i && fset.Position(s.Pos()).Line > 1+fset.Position(d.Specs[j-1].End()).Line {
// j begins a new run. End this one.
specs = append(specs, sortSpecs(localPrefix, fset, f, d.Specs[i:j])...)
i = j
}
}
specs = append(specs, sortSpecs(localPrefix, fset, f, d.Specs[i:])...)
d.Specs = specs
// Deduping can leave a blank line before the rparen; clean that up.
if len(d.Specs) > 0 {
lastSpec := d.Specs[len(d.Specs)-1]
lastLine := fset.Position(lastSpec.Pos()).Line
if rParenLine := fset.Position(d.Rparen).Line; rParenLine > lastLine+1 {
fset.File(d.Rparen).MergeLine(rParenLine - 1)
}
}
}
}
// mergeImports merges all the import declarations into the first one.
// Taken from golang.org/x/tools/ast/astutil.
func mergeImports(fset *token.FileSet, f *ast.File) {
if len(f.Decls) <= 1 {
return
}
// Merge all the import declarations into the first one.
var first *ast.GenDecl
for i := 0; i < len(f.Decls); i++ {
decl := f.Decls[i]
gen, ok := decl.(*ast.GenDecl)
if !ok || gen.Tok != token.IMPORT || declImports(gen, "C") {
continue
}
if first == nil {
first = gen
continue // Don't touch the first one.
}
// We now know there is more than one package in this import
// declaration. Ensure that it ends up parenthesized.
first.Lparen = first.Pos()
// Move the imports of the other import declaration to the first one.
for _, spec := range gen.Specs {
spec.(*ast.ImportSpec).Path.ValuePos = first.Pos()
first.Specs = append(first.Specs, spec)
}
f.Decls = append(f.Decls[:i], f.Decls[i+1:]...)
i--
}
}
// declImports reports whether gen contains an import of path.
// Taken from golang.org/x/tools/ast/astutil.
func declImports(gen *ast.GenDecl, path string) bool {
if gen.Tok != token.IMPORT {
return false
}
for _, spec := range gen.Specs {
impspec := spec.(*ast.ImportSpec)
if importPath(impspec) == path {
return true
}
}
return false
}
func importPath(s ast.Spec) string {
t, err := strconv.Unquote(s.(*ast.ImportSpec).Path.Value)
if err == nil {
return t
}
return ""
}
func importName(s ast.Spec) string {
n := s.(*ast.ImportSpec).Name
if n == nil {
return ""
}
return n.Name
}
func importComment(s ast.Spec) string {
c := s.(*ast.ImportSpec).Comment
if c == nil {
return ""
}
return c.Text()
}
// collapse indicates whether prev may be removed, leaving only next.
func collapse(prev, next ast.Spec) bool {
if importPath(next) != importPath(prev) || importName(next) != importName(prev) {
return false
}
return prev.(*ast.ImportSpec).Comment == nil
}
type posSpan struct {
Start token.Pos
End token.Pos
}
func sortSpecs(localPrefix string, fset *token.FileSet, f *ast.File, specs []ast.Spec) []ast.Spec {
// Can't short-circuit here even if specs are already sorted,
// since they might yet need deduplication.
// A lone import, however, may be safely ignored.
if len(specs) <= 1 {
return specs
}
// Record positions for specs.
pos := make([]posSpan, len(specs))
for i, s := range specs {
pos[i] = posSpan{s.Pos(), s.End()}
}
// Identify comments in this range.
// Any comment from pos[0].Start to the final line counts.
lastLine := fset.Position(pos[len(pos)-1].End).Line
cstart := len(f.Comments)
cend := len(f.Comments)
for i, g := range f.Comments {
if g.Pos() < pos[0].Start {
continue
}
if i < cstart {
cstart = i
}
if fset.Position(g.End()).Line > lastLine {
cend = i
break
}
}
comments := f.Comments[cstart:cend]
// Assign each comment to the import spec preceding it.
importComment := map[*ast.ImportSpec][]*ast.CommentGroup{}
specIndex := 0
for _, g := range comments {
for specIndex+1 < len(specs) && pos[specIndex+1].Start <= g.Pos() {
specIndex++
}
s := specs[specIndex].(*ast.ImportSpec)
importComment[s] = append(importComment[s], g)
}
// Sort the import specs by import path.
// Remove duplicates, when possible without data loss.
// Reassign the import paths to have the same position sequence.
// Reassign each comment to abut the end of its spec.
// Sort the comments by new position.
sort.Sort(byImportSpec{localPrefix, specs})
// Dedup. Thanks to our sorting, we can just consider
// adjacent pairs of imports.
deduped := specs[:0]
for i, s := range specs {
if i == len(specs)-1 || !collapse(s, specs[i+1]) {
deduped = append(deduped, s)
} else {
p := s.Pos()
fset.File(p).MergeLine(fset.Position(p).Line)
}
}
specs = deduped
// Fix up comment positions
for i, s := range specs {
s := s.(*ast.ImportSpec)
if s.Name != nil {
s.Name.NamePos = pos[i].Start
}
s.Path.ValuePos = pos[i].Start
s.EndPos = pos[i].End
nextSpecPos := pos[i].End
for _, g := range importComment[s] {
for _, c := range g.List {
c.Slash = pos[i].End
nextSpecPos = c.End()
}
}
if i < len(specs)-1 {
pos[i+1].Start = nextSpecPos
pos[i+1].End = nextSpecPos
}
}
sort.Sort(byCommentPos(comments))
// Fixup comments can insert blank lines, because import specs are on different lines.
// We remove those blank lines here by merging import spec to the first import spec line.
firstSpecLine := fset.Position(specs[0].Pos()).Line
for _, s := range specs[1:] {
p := s.Pos()
line := fset.File(p).Line(p)
for previousLine := line - 1; previousLine >= firstSpecLine; {
fset.File(p).MergeLine(previousLine)
previousLine--
}
}
return specs
}
type byImportSpec struct {
localPrefix string
specs []ast.Spec // slice of *ast.ImportSpec
}
func (x byImportSpec) Len() int { return len(x.specs) }
func (x byImportSpec) Swap(i, j int) { x.specs[i], x.specs[j] = x.specs[j], x.specs[i] }
func (x byImportSpec) Less(i, j int) bool {
ipath := importPath(x.specs[i])
jpath := importPath(x.specs[j])
igroup := importGroup(x.localPrefix, ipath)
jgroup := importGroup(x.localPrefix, jpath)
if igroup != jgroup {
return igroup < jgroup
}
if ipath != jpath {
return ipath < jpath
}
iname := importName(x.specs[i])
jname := importName(x.specs[j])
if iname != jname {
return iname < jname
}
return importComment(x.specs[i]) < importComment(x.specs[j])
}
type byCommentPos []*ast.CommentGroup
func (x byCommentPos) Len() int { return len(x) }
func (x byCommentPos) Swap(i, j int) { x[i], x[j] = x[j], x[i] }
func (x byCommentPos) Less(i, j int) bool { return x[i].Pos() < x[j].Pos() }

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vendor/golang.org/x/tools/internal/imports/zstdlib.go generated vendored Normal file
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vendor/golang.org/x/tools/internal/module/module.go generated vendored
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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 module defines the module.Version type
// along with support code.
package module
// IMPORTANT NOTE
//
// This file essentially defines the set of valid import paths for the go command.
// There are many subtle considerations, including Unicode ambiguity,
// security, network, and file system representations.
//
// This file also defines the set of valid module path and version combinations,
// another topic with many subtle considerations.
//
// Changes to the semantics in this file require approval from rsc.
import (
"fmt"
"sort"
"strings"
"unicode"
"unicode/utf8"
"golang.org/x/tools/internal/semver"
)
// A Version is defined by a module path and version pair.
type Version struct {
Path string
// Version is usually a semantic version in canonical form.
// There are two exceptions to this general rule.
// First, the top-level target of a build has no specific version
// and uses Version = "".
// Second, during MVS calculations the version "none" is used
// to represent the decision to take no version of a given module.
Version string `json:",omitempty"`
}
// Check checks that a given module path, version pair is valid.
// In addition to the path being a valid module path
// and the version being a valid semantic version,
// the two must correspond.
// For example, the path "yaml/v2" only corresponds to
// semantic versions beginning with "v2.".
func Check(path, version string) error {
if err := CheckPath(path); err != nil {
return err
}
if !semver.IsValid(version) {
return fmt.Errorf("malformed semantic version %v", version)
}
_, pathMajor, _ := SplitPathVersion(path)
if !MatchPathMajor(version, pathMajor) {
if pathMajor == "" {
pathMajor = "v0 or v1"
}
if pathMajor[0] == '.' { // .v1
pathMajor = pathMajor[1:]
}
return fmt.Errorf("mismatched module path %v and version %v (want %v)", path, version, pathMajor)
}
return nil
}
// firstPathOK reports whether r can appear in the first element of a module path.
// The first element of the path must be an LDH domain name, at least for now.
// To avoid case ambiguity, the domain name must be entirely lower case.
func firstPathOK(r rune) bool {
return r == '-' || r == '.' ||
'0' <= r && r <= '9' ||
'a' <= r && r <= 'z'
}
// pathOK reports whether r can appear in an import path element.
// Paths can be ASCII letters, ASCII digits, and limited ASCII punctuation: + - . _ and ~.
// This matches what "go get" has historically recognized in import paths.
// TODO(rsc): We would like to allow Unicode letters, but that requires additional
// care in the safe encoding (see note below).
func pathOK(r rune) bool {
if r < utf8.RuneSelf {
return r == '+' || r == '-' || r == '.' || r == '_' || r == '~' ||
'0' <= r && r <= '9' ||
'A' <= r && r <= 'Z' ||
'a' <= r && r <= 'z'
}
return false
}
// fileNameOK reports whether r can appear in a file name.
// For now we allow all Unicode letters but otherwise limit to pathOK plus a few more punctuation characters.
// If we expand the set of allowed characters here, we have to
// work harder at detecting potential case-folding and normalization collisions.
// See note about "safe encoding" below.
func fileNameOK(r rune) bool {
if r < utf8.RuneSelf {
// Entire set of ASCII punctuation, from which we remove characters:
// ! " # $ % & ' ( ) * + , - . / : ; < = > ? @ [ \ ] ^ _ ` { | } ~
// We disallow some shell special characters: " ' * < > ? ` |
// (Note that some of those are disallowed by the Windows file system as well.)
// We also disallow path separators / : and \ (fileNameOK is only called on path element characters).
// We allow spaces (U+0020) in file names.
const allowed = "!#$%&()+,-.=@[]^_{}~ "
if '0' <= r && r <= '9' || 'A' <= r && r <= 'Z' || 'a' <= r && r <= 'z' {
return true
}
for i := 0; i < len(allowed); i++ {
if rune(allowed[i]) == r {
return true
}
}
return false
}
// It may be OK to add more ASCII punctuation here, but only carefully.
// For example Windows disallows < > \, and macOS disallows :, so we must not allow those.
return unicode.IsLetter(r)
}
// CheckPath checks that a module path is valid.
func CheckPath(path string) error {
if err := checkPath(path, false); err != nil {
return fmt.Errorf("malformed module path %q: %v", path, err)
}
i := strings.Index(path, "/")
if i < 0 {
i = len(path)
}
if i == 0 {
return fmt.Errorf("malformed module path %q: leading slash", path)
}
if !strings.Contains(path[:i], ".") {
return fmt.Errorf("malformed module path %q: missing dot in first path element", path)
}
if path[0] == '-' {
return fmt.Errorf("malformed module path %q: leading dash in first path element", path)
}
for _, r := range path[:i] {
if !firstPathOK(r) {
return fmt.Errorf("malformed module path %q: invalid char %q in first path element", path, r)
}
}
if _, _, ok := SplitPathVersion(path); !ok {
return fmt.Errorf("malformed module path %q: invalid version", path)
}
return nil
}
// CheckImportPath checks that an import path is valid.
func CheckImportPath(path string) error {
if err := checkPath(path, false); err != nil {
return fmt.Errorf("malformed import path %q: %v", path, err)
}
return nil
}
// checkPath checks that a general path is valid.
// It returns an error describing why but not mentioning path.
// Because these checks apply to both module paths and import paths,
// the caller is expected to add the "malformed ___ path %q: " prefix.
// fileName indicates whether the final element of the path is a file name
// (as opposed to a directory name).
func checkPath(path string, fileName bool) error {
if !utf8.ValidString(path) {
return fmt.Errorf("invalid UTF-8")
}
if path == "" {
return fmt.Errorf("empty string")
}
if strings.Contains(path, "..") {
return fmt.Errorf("double dot")
}
if strings.Contains(path, "//") {
return fmt.Errorf("double slash")
}
if path[len(path)-1] == '/' {
return fmt.Errorf("trailing slash")
}
elemStart := 0
for i, r := range path {
if r == '/' {
if err := checkElem(path[elemStart:i], fileName); err != nil {
return err
}
elemStart = i + 1
}
}
if err := checkElem(path[elemStart:], fileName); err != nil {
return err
}
return nil
}
// checkElem checks whether an individual path element is valid.
// fileName indicates whether the element is a file name (not a directory name).
func checkElem(elem string, fileName bool) error {
if elem == "" {
return fmt.Errorf("empty path element")
}
if strings.Count(elem, ".") == len(elem) {
return fmt.Errorf("invalid path element %q", elem)
}
if elem[0] == '.' && !fileName {
return fmt.Errorf("leading dot in path element")
}
if elem[len(elem)-1] == '.' {
return fmt.Errorf("trailing dot in path element")
}
charOK := pathOK
if fileName {
charOK = fileNameOK
}
for _, r := range elem {
if !charOK(r) {
return fmt.Errorf("invalid char %q", r)
}
}
// Windows disallows a bunch of path elements, sadly.
// See https://docs.microsoft.com/en-us/windows/desktop/fileio/naming-a-file
short := elem
if i := strings.Index(short, "."); i >= 0 {
short = short[:i]
}
for _, bad := range badWindowsNames {
if strings.EqualFold(bad, short) {
return fmt.Errorf("disallowed path element %q", elem)
}
}
return nil
}
// CheckFilePath checks whether a slash-separated file path is valid.
func CheckFilePath(path string) error {
if err := checkPath(path, true); err != nil {
return fmt.Errorf("malformed file path %q: %v", path, err)
}
return nil
}
// badWindowsNames are the reserved file path elements on Windows.
// See https://docs.microsoft.com/en-us/windows/desktop/fileio/naming-a-file
var badWindowsNames = []string{
"CON",
"PRN",
"AUX",
"NUL",
"COM1",
"COM2",
"COM3",
"COM4",
"COM5",
"COM6",
"COM7",
"COM8",
"COM9",
"LPT1",
"LPT2",
"LPT3",
"LPT4",
"LPT5",
"LPT6",
"LPT7",
"LPT8",
"LPT9",
}
// SplitPathVersion returns prefix and major version such that prefix+pathMajor == path
// and version is either empty or "/vN" for N >= 2.
// As a special case, gopkg.in paths are recognized directly;
// they require ".vN" instead of "/vN", and for all N, not just N >= 2.
func SplitPathVersion(path string) (prefix, pathMajor string, ok bool) {
if strings.HasPrefix(path, "gopkg.in/") {
return splitGopkgIn(path)
}
i := len(path)
dot := false
for i > 0 && ('0' <= path[i-1] && path[i-1] <= '9' || path[i-1] == '.') {
if path[i-1] == '.' {
dot = true
}
i--
}
if i <= 1 || i == len(path) || path[i-1] != 'v' || path[i-2] != '/' {
return path, "", true
}
prefix, pathMajor = path[:i-2], path[i-2:]
if dot || len(pathMajor) <= 2 || pathMajor[2] == '0' || pathMajor == "/v1" {
return path, "", false
}
return prefix, pathMajor, true
}
// splitGopkgIn is like SplitPathVersion but only for gopkg.in paths.
func splitGopkgIn(path string) (prefix, pathMajor string, ok bool) {
if !strings.HasPrefix(path, "gopkg.in/") {
return path, "", false
}
i := len(path)
if strings.HasSuffix(path, "-unstable") {
i -= len("-unstable")
}
for i > 0 && ('0' <= path[i-1] && path[i-1] <= '9') {
i--
}
if i <= 1 || path[i-1] != 'v' || path[i-2] != '.' {
// All gopkg.in paths must end in vN for some N.
return path, "", false
}
prefix, pathMajor = path[:i-2], path[i-2:]
if len(pathMajor) <= 2 || pathMajor[2] == '0' && pathMajor != ".v0" {
return path, "", false
}
return prefix, pathMajor, true
}
// MatchPathMajor reports whether the semantic version v
// matches the path major version pathMajor.
func MatchPathMajor(v, pathMajor string) bool {
if strings.HasPrefix(pathMajor, ".v") && strings.HasSuffix(pathMajor, "-unstable") {
pathMajor = strings.TrimSuffix(pathMajor, "-unstable")
}
if strings.HasPrefix(v, "v0.0.0-") && pathMajor == ".v1" {
// Allow old bug in pseudo-versions that generated v0.0.0- pseudoversion for gopkg .v1.
// For example, gopkg.in/yaml.v2@v2.2.1's go.mod requires gopkg.in/check.v1 v0.0.0-20161208181325-20d25e280405.
return true
}
m := semver.Major(v)
if pathMajor == "" {
return m == "v0" || m == "v1" || semver.Build(v) == "+incompatible"
}
return (pathMajor[0] == '/' || pathMajor[0] == '.') && m == pathMajor[1:]
}
// CanonicalVersion returns the canonical form of the version string v.
// It is the same as semver.Canonical(v) except that it preserves the special build suffix "+incompatible".
func CanonicalVersion(v string) string {
cv := semver.Canonical(v)
if semver.Build(v) == "+incompatible" {
cv += "+incompatible"
}
return cv
}
// Sort sorts the list by Path, breaking ties by comparing Versions.
func Sort(list []Version) {
sort.Slice(list, func(i, j int) bool {
mi := list[i]
mj := list[j]
if mi.Path != mj.Path {
return mi.Path < mj.Path
}
// To help go.sum formatting, allow version/file.
// Compare semver prefix by semver rules,
// file by string order.
vi := mi.Version
vj := mj.Version
var fi, fj string
if k := strings.Index(vi, "/"); k >= 0 {
vi, fi = vi[:k], vi[k:]
}
if k := strings.Index(vj, "/"); k >= 0 {
vj, fj = vj[:k], vj[k:]
}
if vi != vj {
return semver.Compare(vi, vj) < 0
}
return fi < fj
})
}
// Safe encodings
//
// Module paths appear as substrings of file system paths
// (in the download cache) and of web server URLs in the proxy protocol.
// In general we cannot rely on file systems to be case-sensitive,
// nor can we rely on web servers, since they read from file systems.
// That is, we cannot rely on the file system to keep rsc.io/QUOTE
// and rsc.io/quote separate. Windows and macOS don't.
// Instead, we must never require two different casings of a file path.
// Because we want the download cache to match the proxy protocol,
// and because we want the proxy protocol to be possible to serve
// from a tree of static files (which might be stored on a case-insensitive
// file system), the proxy protocol must never require two different casings
// of a URL path either.
//
// One possibility would be to make the safe encoding be the lowercase
// hexadecimal encoding of the actual path bytes. This would avoid ever
// needing different casings of a file path, but it would be fairly illegible
// to most programmers when those paths appeared in the file system
// (including in file paths in compiler errors and stack traces)
// in web server logs, and so on. Instead, we want a safe encoding that
// leaves most paths unaltered.
//
// The safe encoding is this:
// replace every uppercase letter with an exclamation mark
// followed by the letter's lowercase equivalent.
//
// For example,
// github.com/Azure/azure-sdk-for-go -> github.com/!azure/azure-sdk-for-go.
// github.com/GoogleCloudPlatform/cloudsql-proxy -> github.com/!google!cloud!platform/cloudsql-proxy
// github.com/Sirupsen/logrus -> github.com/!sirupsen/logrus.
//
// Import paths that avoid upper-case letters are left unchanged.
// Note that because import paths are ASCII-only and avoid various
// problematic punctuation (like : < and >), the safe encoding is also ASCII-only
// and avoids the same problematic punctuation.
//
// Import paths have never allowed exclamation marks, so there is no
// need to define how to encode a literal !.
//
// Although paths are disallowed from using Unicode (see pathOK above),
// the eventual plan is to allow Unicode letters as well, to assume that
// file systems and URLs are Unicode-safe (storing UTF-8), and apply
// the !-for-uppercase convention. Note however that not all runes that
// are different but case-fold equivalent are an upper/lower pair.
// For example, U+004B ('K'), U+006B ('k'), and U+212A ('' for Kelvin)
// are considered to case-fold to each other. When we do add Unicode
// letters, we must not assume that upper/lower are the only case-equivalent pairs.
// Perhaps the Kelvin symbol would be disallowed entirely, for example.
// Or perhaps it would encode as "!!k", or perhaps as "(212A)".
//
// Also, it would be nice to allow Unicode marks as well as letters,
// but marks include combining marks, and then we must deal not
// only with case folding but also normalization: both U+00E9 ('é')
// and U+0065 U+0301 ('e' followed by combining acute accent)
// look the same on the page and are treated by some file systems
// as the same path. If we do allow Unicode marks in paths, there
// must be some kind of normalization to allow only one canonical
// encoding of any character used in an import path.
// EncodePath returns the safe encoding of the given module path.
// It fails if the module path is invalid.
func EncodePath(path string) (encoding string, err error) {
if err := CheckPath(path); err != nil {
return "", err
}
return encodeString(path)
}
// EncodeVersion returns the safe encoding of the given module version.
// Versions are allowed to be in non-semver form but must be valid file names
// and not contain exclamation marks.
func EncodeVersion(v string) (encoding string, err error) {
if err := checkElem(v, true); err != nil || strings.Contains(v, "!") {
return "", fmt.Errorf("disallowed version string %q", v)
}
return encodeString(v)
}
func encodeString(s string) (encoding string, err error) {
haveUpper := false
for _, r := range s {
if r == '!' || r >= utf8.RuneSelf {
// This should be disallowed by CheckPath, but diagnose anyway.
// The correctness of the encoding loop below depends on it.
return "", fmt.Errorf("internal error: inconsistency in EncodePath")
}
if 'A' <= r && r <= 'Z' {
haveUpper = true
}
}
if !haveUpper {
return s, nil
}
var buf []byte
for _, r := range s {
if 'A' <= r && r <= 'Z' {
buf = append(buf, '!', byte(r+'a'-'A'))
} else {
buf = append(buf, byte(r))
}
}
return string(buf), nil
}
// DecodePath returns the module path of the given safe encoding.
// It fails if the encoding is invalid or encodes an invalid path.
func DecodePath(encoding string) (path string, err error) {
path, ok := decodeString(encoding)
if !ok {
return "", fmt.Errorf("invalid module path encoding %q", encoding)
}
if err := CheckPath(path); err != nil {
return "", fmt.Errorf("invalid module path encoding %q: %v", encoding, err)
}
return path, nil
}
// DecodeVersion returns the version string for the given safe encoding.
// It fails if the encoding is invalid or encodes an invalid version.
// Versions are allowed to be in non-semver form but must be valid file names
// and not contain exclamation marks.
func DecodeVersion(encoding string) (v string, err error) {
v, ok := decodeString(encoding)
if !ok {
return "", fmt.Errorf("invalid version encoding %q", encoding)
}
if err := checkElem(v, true); err != nil {
return "", fmt.Errorf("disallowed version string %q", v)
}
return v, nil
}
func decodeString(encoding string) (string, bool) {
var buf []byte
bang := false
for _, r := range encoding {
if r >= utf8.RuneSelf {
return "", false
}
if bang {
bang = false
if r < 'a' || 'z' < r {
return "", false
}
buf = append(buf, byte(r+'A'-'a'))
continue
}
if r == '!' {
bang = true
continue
}
if 'A' <= r && r <= 'Z' {
return "", false
}
buf = append(buf, byte(r))
}
if bang {
return "", false
}
return string(buf), true
}

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vendor/golang.org/x/tools/internal/semver/semver.go generated vendored
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@@ -1,388 +0,0 @@
// Copyright 2018 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Package semver implements comparison of semantic version strings.
// In this package, semantic version strings must begin with a leading "v",
// as in "v1.0.0".
//
// The general form of a semantic version string accepted by this package is
//
// vMAJOR[.MINOR[.PATCH[-PRERELEASE][+BUILD]]]
//
// where square brackets indicate optional parts of the syntax;
// MAJOR, MINOR, and PATCH are decimal integers without extra leading zeros;
// PRERELEASE and BUILD are each a series of non-empty dot-separated identifiers
// using only alphanumeric characters and hyphens; and
// all-numeric PRERELEASE identifiers must not have leading zeros.
//
// This package follows Semantic Versioning 2.0.0 (see semver.org)
// with two exceptions. First, it requires the "v" prefix. Second, it recognizes
// vMAJOR and vMAJOR.MINOR (with no prerelease or build suffixes)
// as shorthands for vMAJOR.0.0 and vMAJOR.MINOR.0.
package semver
// parsed returns the parsed form of a semantic version string.
type parsed struct {
major string
minor string
patch string
short string
prerelease string
build string
err string
}
// IsValid reports whether v is a valid semantic version string.
func IsValid(v string) bool {
_, ok := parse(v)
return ok
}
// Canonical returns the canonical formatting of the semantic version v.
// It fills in any missing .MINOR or .PATCH and discards build metadata.
// Two semantic versions compare equal only if their canonical formattings
// are identical strings.
// The canonical invalid semantic version is the empty string.
func Canonical(v string) string {
p, ok := parse(v)
if !ok {
return ""
}
if p.build != "" {
return v[:len(v)-len(p.build)]
}
if p.short != "" {
return v + p.short
}
return v
}
// Major returns the major version prefix of the semantic version v.
// For example, Major("v2.1.0") == "v2".
// If v is an invalid semantic version string, Major returns the empty string.
func Major(v string) string {
pv, ok := parse(v)
if !ok {
return ""
}
return v[:1+len(pv.major)]
}
// MajorMinor returns the major.minor version prefix of the semantic version v.
// For example, MajorMinor("v2.1.0") == "v2.1".
// If v is an invalid semantic version string, MajorMinor returns the empty string.
func MajorMinor(v string) string {
pv, ok := parse(v)
if !ok {
return ""
}
i := 1 + len(pv.major)
if j := i + 1 + len(pv.minor); j <= len(v) && v[i] == '.' && v[i+1:j] == pv.minor {
return v[:j]
}
return v[:i] + "." + pv.minor
}
// Prerelease returns the prerelease suffix of the semantic version v.
// For example, Prerelease("v2.1.0-pre+meta") == "-pre".
// If v is an invalid semantic version string, Prerelease returns the empty string.
func Prerelease(v string) string {
pv, ok := parse(v)
if !ok {
return ""
}
return pv.prerelease
}
// Build returns the build suffix of the semantic version v.
// For example, Build("v2.1.0+meta") == "+meta".
// If v is an invalid semantic version string, Build returns the empty string.
func Build(v string) string {
pv, ok := parse(v)
if !ok {
return ""
}
return pv.build
}
// Compare returns an integer comparing two versions according to
// according to semantic version precedence.
// The result will be 0 if v == w, -1 if v < w, or +1 if v > w.
//
// An invalid semantic version string is considered less than a valid one.
// All invalid semantic version strings compare equal to each other.
func Compare(v, w string) int {
pv, ok1 := parse(v)
pw, ok2 := parse(w)
if !ok1 && !ok2 {
return 0
}
if !ok1 {
return -1
}
if !ok2 {
return +1
}
if c := compareInt(pv.major, pw.major); c != 0 {
return c
}
if c := compareInt(pv.minor, pw.minor); c != 0 {
return c
}
if c := compareInt(pv.patch, pw.patch); c != 0 {
return c
}
return comparePrerelease(pv.prerelease, pw.prerelease)
}
// Max canonicalizes its arguments and then returns the version string
// that compares greater.
func Max(v, w string) string {
v = Canonical(v)
w = Canonical(w)
if Compare(v, w) > 0 {
return v
}
return w
}
func parse(v string) (p parsed, ok bool) {
if v == "" || v[0] != 'v' {
p.err = "missing v prefix"
return
}
p.major, v, ok = parseInt(v[1:])
if !ok {
p.err = "bad major version"
return
}
if v == "" {
p.minor = "0"
p.patch = "0"
p.short = ".0.0"
return
}
if v[0] != '.' {
p.err = "bad minor prefix"
ok = false
return
}
p.minor, v, ok = parseInt(v[1:])
if !ok {
p.err = "bad minor version"
return
}
if v == "" {
p.patch = "0"
p.short = ".0"
return
}
if v[0] != '.' {
p.err = "bad patch prefix"
ok = false
return
}
p.patch, v, ok = parseInt(v[1:])
if !ok {
p.err = "bad patch version"
return
}
if len(v) > 0 && v[0] == '-' {
p.prerelease, v, ok = parsePrerelease(v)
if !ok {
p.err = "bad prerelease"
return
}
}
if len(v) > 0 && v[0] == '+' {
p.build, v, ok = parseBuild(v)
if !ok {
p.err = "bad build"
return
}
}
if v != "" {
p.err = "junk on end"
ok = false
return
}
ok = true
return
}
func parseInt(v string) (t, rest string, ok bool) {
if v == "" {
return
}
if v[0] < '0' || '9' < v[0] {
return
}
i := 1
for i < len(v) && '0' <= v[i] && v[i] <= '9' {
i++
}
if v[0] == '0' && i != 1 {
return
}
return v[:i], v[i:], true
}
func parsePrerelease(v string) (t, rest string, ok bool) {
// "A pre-release version MAY be denoted by appending a hyphen and
// a series of dot separated identifiers immediately following the patch version.
// Identifiers MUST comprise only ASCII alphanumerics and hyphen [0-9A-Za-z-].
// Identifiers MUST NOT be empty. Numeric identifiers MUST NOT include leading zeroes."
if v == "" || v[0] != '-' {
return
}
i := 1
start := 1
for i < len(v) && v[i] != '+' {
if !isIdentChar(v[i]) && v[i] != '.' {
return
}
if v[i] == '.' {
if start == i || isBadNum(v[start:i]) {
return
}
start = i + 1
}
i++
}
if start == i || isBadNum(v[start:i]) {
return
}
return v[:i], v[i:], true
}
func parseBuild(v string) (t, rest string, ok bool) {
if v == "" || v[0] != '+' {
return
}
i := 1
start := 1
for i < len(v) {
if !isIdentChar(v[i]) {
return
}
if v[i] == '.' {
if start == i {
return
}
start = i + 1
}
i++
}
if start == i {
return
}
return v[:i], v[i:], true
}
func isIdentChar(c byte) bool {
return 'A' <= c && c <= 'Z' || 'a' <= c && c <= 'z' || '0' <= c && c <= '9' || c == '-'
}
func isBadNum(v string) bool {
i := 0
for i < len(v) && '0' <= v[i] && v[i] <= '9' {
i++
}
return i == len(v) && i > 1 && v[0] == '0'
}
func isNum(v string) bool {
i := 0
for i < len(v) && '0' <= v[i] && v[i] <= '9' {
i++
}
return i == len(v)
}
func compareInt(x, y string) int {
if x == y {
return 0
}
if len(x) < len(y) {
return -1
}
if len(x) > len(y) {
return +1
}
if x < y {
return -1
} else {
return +1
}
}
func comparePrerelease(x, y string) int {
// "When major, minor, and patch are equal, a pre-release version has
// lower precedence than a normal version.
// Example: 1.0.0-alpha < 1.0.0.
// Precedence for two pre-release versions with the same major, minor,
// and patch version MUST be determined by comparing each dot separated
// identifier from left to right until a difference is found as follows:
// identifiers consisting of only digits are compared numerically and
// identifiers with letters or hyphens are compared lexically in ASCII
// sort order. Numeric identifiers always have lower precedence than
// non-numeric identifiers. A larger set of pre-release fields has a
// higher precedence than a smaller set, if all of the preceding
// identifiers are equal.
// Example: 1.0.0-alpha < 1.0.0-alpha.1 < 1.0.0-alpha.beta <
// 1.0.0-beta < 1.0.0-beta.2 < 1.0.0-beta.11 < 1.0.0-rc.1 < 1.0.0."
if x == y {
return 0
}
if x == "" {
return +1
}
if y == "" {
return -1
}
for x != "" && y != "" {
x = x[1:] // skip - or .
y = y[1:] // skip - or .
var dx, dy string
dx, x = nextIdent(x)
dy, y = nextIdent(y)
if dx != dy {
ix := isNum(dx)
iy := isNum(dy)
if ix != iy {
if ix {
return -1
} else {
return +1
}
}
if ix {
if len(dx) < len(dy) {
return -1
}
if len(dx) > len(dy) {
return +1
}
}
if dx < dy {
return -1
} else {
return +1
}
}
}
if x == "" {
return -1
} else {
return +1
}
}
func nextIdent(x string) (dx, rest string) {
i := 0
for i < len(x) && x[i] != '.' {
i++
}
return x[:i], x[i:]
}