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mirror of https://github.com/go-gitea/gitea synced 2024-11-14 14:14:25 +00:00
gitea/vendor/github.com/go-stack/stack/stack.go
Antoine GIRARD 9fe4437bda Use vendored go-swagger (#8087)
* Use vendored go-swagger

* vendor go-swagger

* revert un wanteed change

* remove un-needed GO111MODULE

* Update Makefile

Co-Authored-By: techknowlogick <matti@mdranta.net>
2019-09-04 22:53:54 +03:00

401 lines
12 KiB
Go
Vendored

// +build go1.7
// Package stack implements utilities to capture, manipulate, and format call
// stacks. It provides a simpler API than package runtime.
//
// The implementation takes care of the minutia and special cases of
// interpreting the program counter (pc) values returned by runtime.Callers.
//
// Package stack's types implement fmt.Formatter, which provides a simple and
// flexible way to declaratively configure formatting when used with logging
// or error tracking packages.
package stack
import (
"bytes"
"errors"
"fmt"
"io"
"runtime"
"strconv"
"strings"
)
// Call records a single function invocation from a goroutine stack.
type Call struct {
frame runtime.Frame
}
// Caller returns a Call from the stack of the current goroutine. The argument
// skip is the number of stack frames to ascend, with 0 identifying the
// calling function.
func Caller(skip int) Call {
// As of Go 1.9 we need room for up to three PC entries.
//
// 0. An entry for the stack frame prior to the target to check for
// special handling needed if that prior entry is runtime.sigpanic.
// 1. A possible second entry to hold metadata about skipped inlined
// functions. If inline functions were not skipped the target frame
// PC will be here.
// 2. A third entry for the target frame PC when the second entry
// is used for skipped inline functions.
var pcs [3]uintptr
n := runtime.Callers(skip+1, pcs[:])
frames := runtime.CallersFrames(pcs[:n])
frame, _ := frames.Next()
frame, _ = frames.Next()
return Call{
frame: frame,
}
}
// String implements fmt.Stinger. It is equivalent to fmt.Sprintf("%v", c).
func (c Call) String() string {
return fmt.Sprint(c)
}
// MarshalText implements encoding.TextMarshaler. It formats the Call the same
// as fmt.Sprintf("%v", c).
func (c Call) MarshalText() ([]byte, error) {
if c.frame == (runtime.Frame{}) {
return nil, ErrNoFunc
}
buf := bytes.Buffer{}
fmt.Fprint(&buf, c)
return buf.Bytes(), nil
}
// ErrNoFunc means that the Call has a nil *runtime.Func. The most likely
// cause is a Call with the zero value.
var ErrNoFunc = errors.New("no call stack information")
// Format implements fmt.Formatter with support for the following verbs.
//
// %s source file
// %d line number
// %n function name
// %k last segment of the package path
// %v equivalent to %s:%d
//
// It accepts the '+' and '#' flags for most of the verbs as follows.
//
// %+s path of source file relative to the compile time GOPATH,
// or the module path joined to the path of source file relative
// to module root
// %#s full path of source file
// %+n import path qualified function name
// %+k full package path
// %+v equivalent to %+s:%d
// %#v equivalent to %#s:%d
func (c Call) Format(s fmt.State, verb rune) {
if c.frame == (runtime.Frame{}) {
fmt.Fprintf(s, "%%!%c(NOFUNC)", verb)
return
}
switch verb {
case 's', 'v':
file := c.frame.File
switch {
case s.Flag('#'):
// done
case s.Flag('+'):
file = pkgFilePath(&c.frame)
default:
const sep = "/"
if i := strings.LastIndex(file, sep); i != -1 {
file = file[i+len(sep):]
}
}
io.WriteString(s, file)
if verb == 'v' {
buf := [7]byte{':'}
s.Write(strconv.AppendInt(buf[:1], int64(c.frame.Line), 10))
}
case 'd':
buf := [6]byte{}
s.Write(strconv.AppendInt(buf[:0], int64(c.frame.Line), 10))
case 'k':
name := c.frame.Function
const pathSep = "/"
start, end := 0, len(name)
if i := strings.LastIndex(name, pathSep); i != -1 {
start = i + len(pathSep)
}
const pkgSep = "."
if i := strings.Index(name[start:], pkgSep); i != -1 {
end = start + i
}
if s.Flag('+') {
start = 0
}
io.WriteString(s, name[start:end])
case 'n':
name := c.frame.Function
if !s.Flag('+') {
const pathSep = "/"
if i := strings.LastIndex(name, pathSep); i != -1 {
name = name[i+len(pathSep):]
}
const pkgSep = "."
if i := strings.Index(name, pkgSep); i != -1 {
name = name[i+len(pkgSep):]
}
}
io.WriteString(s, name)
}
}
// Frame returns the call frame infomation for the Call.
func (c Call) Frame() runtime.Frame {
return c.frame
}
// PC returns the program counter for this call frame; multiple frames may
// have the same PC value.
//
// Deprecated: Use Call.Frame instead.
func (c Call) PC() uintptr {
return c.frame.PC
}
// CallStack records a sequence of function invocations from a goroutine
// stack.
type CallStack []Call
// String implements fmt.Stinger. It is equivalent to fmt.Sprintf("%v", cs).
func (cs CallStack) String() string {
return fmt.Sprint(cs)
}
var (
openBracketBytes = []byte("[")
closeBracketBytes = []byte("]")
spaceBytes = []byte(" ")
)
// MarshalText implements encoding.TextMarshaler. It formats the CallStack the
// same as fmt.Sprintf("%v", cs).
func (cs CallStack) MarshalText() ([]byte, error) {
buf := bytes.Buffer{}
buf.Write(openBracketBytes)
for i, pc := range cs {
if i > 0 {
buf.Write(spaceBytes)
}
fmt.Fprint(&buf, pc)
}
buf.Write(closeBracketBytes)
return buf.Bytes(), nil
}
// Format implements fmt.Formatter by printing the CallStack as square brackets
// ([, ]) surrounding a space separated list of Calls each formatted with the
// supplied verb and options.
func (cs CallStack) Format(s fmt.State, verb rune) {
s.Write(openBracketBytes)
for i, pc := range cs {
if i > 0 {
s.Write(spaceBytes)
}
pc.Format(s, verb)
}
s.Write(closeBracketBytes)
}
// Trace returns a CallStack for the current goroutine with element 0
// identifying the calling function.
func Trace() CallStack {
var pcs [512]uintptr
n := runtime.Callers(1, pcs[:])
frames := runtime.CallersFrames(pcs[:n])
cs := make(CallStack, 0, n)
// Skip extra frame retrieved just to make sure the runtime.sigpanic
// special case is handled.
frame, more := frames.Next()
for more {
frame, more = frames.Next()
cs = append(cs, Call{frame: frame})
}
return cs
}
// TrimBelow returns a slice of the CallStack with all entries below c
// removed.
func (cs CallStack) TrimBelow(c Call) CallStack {
for len(cs) > 0 && cs[0] != c {
cs = cs[1:]
}
return cs
}
// TrimAbove returns a slice of the CallStack with all entries above c
// removed.
func (cs CallStack) TrimAbove(c Call) CallStack {
for len(cs) > 0 && cs[len(cs)-1] != c {
cs = cs[:len(cs)-1]
}
return cs
}
// pkgIndex returns the index that results in file[index:] being the path of
// file relative to the compile time GOPATH, and file[:index] being the
// $GOPATH/src/ portion of file. funcName must be the name of a function in
// file as returned by runtime.Func.Name.
func pkgIndex(file, funcName string) int {
// As of Go 1.6.2 there is no direct way to know the compile time GOPATH
// at runtime, but we can infer the number of path segments in the GOPATH.
// We note that runtime.Func.Name() returns the function name qualified by
// the import path, which does not include the GOPATH. Thus we can trim
// segments from the beginning of the file path until the number of path
// separators remaining is one more than the number of path separators in
// the function name. For example, given:
//
// GOPATH /home/user
// file /home/user/src/pkg/sub/file.go
// fn.Name() pkg/sub.Type.Method
//
// We want to produce:
//
// file[:idx] == /home/user/src/
// file[idx:] == pkg/sub/file.go
//
// From this we can easily see that fn.Name() has one less path separator
// than our desired result for file[idx:]. We count separators from the
// end of the file path until it finds two more than in the function name
// and then move one character forward to preserve the initial path
// segment without a leading separator.
const sep = "/"
i := len(file)
for n := strings.Count(funcName, sep) + 2; n > 0; n-- {
i = strings.LastIndex(file[:i], sep)
if i == -1 {
i = -len(sep)
break
}
}
// get back to 0 or trim the leading separator
return i + len(sep)
}
// pkgFilePath returns the frame's filepath relative to the compile-time GOPATH,
// or its module path joined to its path relative to the module root.
//
// As of Go 1.11 there is no direct way to know the compile time GOPATH or
// module paths at runtime, but we can piece together the desired information
// from available information. We note that runtime.Frame.Function contains the
// function name qualified by the package path, which includes the module path
// but not the GOPATH. We can extract the package path from that and append the
// last segments of the file path to arrive at the desired package qualified
// file path. For example, given:
//
// GOPATH /home/user
// import path pkg/sub
// frame.File /home/user/src/pkg/sub/file.go
// frame.Function pkg/sub.Type.Method
// Desired return pkg/sub/file.go
//
// It appears that we simply need to trim ".Type.Method" from frame.Function and
// append "/" + path.Base(file).
//
// But there are other wrinkles. Although it is idiomatic to do so, the internal
// name of a package is not required to match the last segment of its import
// path. In addition, the introduction of modules in Go 1.11 allows working
// without a GOPATH. So we also must make these work right:
//
// GOPATH /home/user
// import path pkg/go-sub
// package name sub
// frame.File /home/user/src/pkg/go-sub/file.go
// frame.Function pkg/sub.Type.Method
// Desired return pkg/go-sub/file.go
//
// Module path pkg/v2
// import path pkg/v2/go-sub
// package name sub
// frame.File /home/user/cloned-pkg/go-sub/file.go
// frame.Function pkg/v2/sub.Type.Method
// Desired return pkg/v2/go-sub/file.go
//
// We can handle all of these situations by using the package path extracted
// from frame.Function up to, but not including, the last segment as the prefix
// and the last two segments of frame.File as the suffix of the returned path.
// This preserves the existing behavior when working in a GOPATH without modules
// and a semantically equivalent behavior when used in module aware project.
func pkgFilePath(frame *runtime.Frame) string {
pre := pkgPrefix(frame.Function)
post := pathSuffix(frame.File)
if pre == "" {
return post
}
return pre + "/" + post
}
// pkgPrefix returns the import path of the function's package with the final
// segment removed.
func pkgPrefix(funcName string) string {
const pathSep = "/"
end := strings.LastIndex(funcName, pathSep)
if end == -1 {
return ""
}
return funcName[:end]
}
// pathSuffix returns the last two segments of path.
func pathSuffix(path string) string {
const pathSep = "/"
lastSep := strings.LastIndex(path, pathSep)
if lastSep == -1 {
return path
}
return path[strings.LastIndex(path[:lastSep], pathSep)+1:]
}
var runtimePath string
func init() {
var pcs [3]uintptr
runtime.Callers(0, pcs[:])
frames := runtime.CallersFrames(pcs[:])
frame, _ := frames.Next()
file := frame.File
idx := pkgIndex(frame.File, frame.Function)
runtimePath = file[:idx]
if runtime.GOOS == "windows" {
runtimePath = strings.ToLower(runtimePath)
}
}
func inGoroot(c Call) bool {
file := c.frame.File
if len(file) == 0 || file[0] == '?' {
return true
}
if runtime.GOOS == "windows" {
file = strings.ToLower(file)
}
return strings.HasPrefix(file, runtimePath) || strings.HasSuffix(file, "/_testmain.go")
}
// TrimRuntime returns a slice of the CallStack with the topmost entries from
// the go runtime removed. It considers any calls originating from unknown
// files, files under GOROOT, or _testmain.go as part of the runtime.
func (cs CallStack) TrimRuntime() CallStack {
for len(cs) > 0 && inGoroot(cs[len(cs)-1]) {
cs = cs[:len(cs)-1]
}
return cs
}