mirror of
https://codeberg.org/forgejo/forgejo.git
synced 2024-12-29 11:20:42 +00:00
509 lines
13 KiB
Go
509 lines
13 KiB
Go
/*
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* Copyright (c) 2013 Dave Collins <dave@davec.name>
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*
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* Permission to use, copy, modify, and distribute this software for any
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* purpose with or without fee is hereby granted, provided that the above
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* copyright notice and this permission notice appear in all copies.
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*
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* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
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* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
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* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
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* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
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* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
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* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
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* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
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*/
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package spew
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import (
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"bytes"
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"encoding/hex"
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"fmt"
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"io"
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"os"
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"reflect"
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"regexp"
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"strconv"
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"strings"
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)
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var (
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// uint8Type is a reflect.Type representing a uint8. It is used to
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// convert cgo types to uint8 slices for hexdumping.
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uint8Type = reflect.TypeOf(uint8(0))
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// cCharRE is a regular expression that matches a cgo char.
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// It is used to detect character arrays to hexdump them.
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cCharRE = regexp.MustCompile("^.*\\._Ctype_char$")
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// cUnsignedCharRE is a regular expression that matches a cgo unsigned
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// char. It is used to detect unsigned character arrays to hexdump
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// them.
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cUnsignedCharRE = regexp.MustCompile("^.*\\._Ctype_unsignedchar$")
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// cUint8tCharRE is a regular expression that matches a cgo uint8_t.
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// It is used to detect uint8_t arrays to hexdump them.
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cUint8tCharRE = regexp.MustCompile("^.*\\._Ctype_uint8_t$")
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)
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// dumpState contains information about the state of a dump operation.
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type dumpState struct {
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w io.Writer
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depth int
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pointers map[uintptr]int
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ignoreNextType bool
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ignoreNextIndent bool
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cs *ConfigState
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}
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// indent performs indentation according to the depth level and cs.Indent
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// option.
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func (d *dumpState) indent() {
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if d.ignoreNextIndent {
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d.ignoreNextIndent = false
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return
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}
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d.w.Write(bytes.Repeat([]byte(d.cs.Indent), d.depth))
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}
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// unpackValue returns values inside of non-nil interfaces when possible.
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// This is useful for data types like structs, arrays, slices, and maps which
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// can contain varying types packed inside an interface.
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func (d *dumpState) unpackValue(v reflect.Value) reflect.Value {
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if v.Kind() == reflect.Interface && !v.IsNil() {
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v = v.Elem()
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}
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return v
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}
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// dumpPtr handles formatting of pointers by indirecting them as necessary.
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func (d *dumpState) dumpPtr(v reflect.Value) {
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// Remove pointers at or below the current depth from map used to detect
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// circular refs.
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for k, depth := range d.pointers {
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if depth >= d.depth {
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delete(d.pointers, k)
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}
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}
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// Keep list of all dereferenced pointers to show later.
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pointerChain := make([]uintptr, 0)
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// Figure out how many levels of indirection there are by dereferencing
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// pointers and unpacking interfaces down the chain while detecting circular
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// references.
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nilFound := false
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cycleFound := false
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indirects := 0
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ve := v
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for ve.Kind() == reflect.Ptr {
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if ve.IsNil() {
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nilFound = true
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break
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}
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indirects++
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addr := ve.Pointer()
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pointerChain = append(pointerChain, addr)
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if pd, ok := d.pointers[addr]; ok && pd < d.depth {
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cycleFound = true
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indirects--
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break
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}
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d.pointers[addr] = d.depth
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ve = ve.Elem()
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if ve.Kind() == reflect.Interface {
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if ve.IsNil() {
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nilFound = true
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break
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}
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ve = ve.Elem()
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}
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}
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// Display type information.
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d.w.Write(openParenBytes)
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d.w.Write(bytes.Repeat(asteriskBytes, indirects))
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d.w.Write([]byte(ve.Type().String()))
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d.w.Write(closeParenBytes)
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// Display pointer information.
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if len(pointerChain) > 0 {
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d.w.Write(openParenBytes)
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for i, addr := range pointerChain {
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if i > 0 {
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d.w.Write(pointerChainBytes)
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}
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printHexPtr(d.w, addr)
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}
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d.w.Write(closeParenBytes)
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}
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// Display dereferenced value.
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d.w.Write(openParenBytes)
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switch {
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case nilFound == true:
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d.w.Write(nilAngleBytes)
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case cycleFound == true:
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d.w.Write(circularBytes)
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default:
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d.ignoreNextType = true
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d.dump(ve)
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}
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d.w.Write(closeParenBytes)
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}
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// dumpSlice handles formatting of arrays and slices. Byte (uint8 under
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// reflection) arrays and slices are dumped in hexdump -C fashion.
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func (d *dumpState) dumpSlice(v reflect.Value) {
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// Determine whether this type should be hex dumped or not. Also,
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// for types which should be hexdumped, try to use the underlying data
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// first, then fall back to trying to convert them to a uint8 slice.
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var buf []uint8
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doConvert := false
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doHexDump := false
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numEntries := v.Len()
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if numEntries > 0 {
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vt := v.Index(0).Type()
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vts := vt.String()
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switch {
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// C types that need to be converted.
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case cCharRE.MatchString(vts):
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fallthrough
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case cUnsignedCharRE.MatchString(vts):
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fallthrough
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case cUint8tCharRE.MatchString(vts):
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doConvert = true
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// Try to use existing uint8 slices and fall back to converting
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// and copying if that fails.
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case vt.Kind() == reflect.Uint8:
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// We need an addressable interface to convert the type
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// to a byte slice. However, the reflect package won't
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// give us an interface on certain things like
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// unexported struct fields in order to enforce
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// visibility rules. We use unsafe, when available, to
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// bypass these restrictions since this package does not
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// mutate the values.
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vs := v
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if !vs.CanInterface() || !vs.CanAddr() {
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vs = unsafeReflectValue(vs)
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}
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if !UnsafeDisabled {
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vs = vs.Slice(0, numEntries)
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// Use the existing uint8 slice if it can be
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// type asserted.
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iface := vs.Interface()
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if slice, ok := iface.([]uint8); ok {
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buf = slice
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doHexDump = true
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break
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}
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}
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// The underlying data needs to be converted if it can't
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// be type asserted to a uint8 slice.
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doConvert = true
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}
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// Copy and convert the underlying type if needed.
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if doConvert && vt.ConvertibleTo(uint8Type) {
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// Convert and copy each element into a uint8 byte
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// slice.
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buf = make([]uint8, numEntries)
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for i := 0; i < numEntries; i++ {
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vv := v.Index(i)
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buf[i] = uint8(vv.Convert(uint8Type).Uint())
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}
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doHexDump = true
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}
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}
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// Hexdump the entire slice as needed.
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if doHexDump {
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indent := strings.Repeat(d.cs.Indent, d.depth)
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str := indent + hex.Dump(buf)
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str = strings.Replace(str, "\n", "\n"+indent, -1)
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str = strings.TrimRight(str, d.cs.Indent)
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d.w.Write([]byte(str))
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return
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}
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// Recursively call dump for each item.
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for i := 0; i < numEntries; i++ {
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d.dump(d.unpackValue(v.Index(i)))
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if i < (numEntries - 1) {
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d.w.Write(commaNewlineBytes)
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} else {
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d.w.Write(newlineBytes)
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}
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}
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}
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// dump is the main workhorse for dumping a value. It uses the passed reflect
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// value to figure out what kind of object we are dealing with and formats it
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// appropriately. It is a recursive function, however circular data structures
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// are detected and handled properly.
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func (d *dumpState) dump(v reflect.Value) {
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// Handle invalid reflect values immediately.
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kind := v.Kind()
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if kind == reflect.Invalid {
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d.w.Write(invalidAngleBytes)
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return
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}
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// Handle pointers specially.
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if kind == reflect.Ptr {
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d.indent()
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d.dumpPtr(v)
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return
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}
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// Print type information unless already handled elsewhere.
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if !d.ignoreNextType {
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d.indent()
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d.w.Write(openParenBytes)
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d.w.Write([]byte(v.Type().String()))
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d.w.Write(closeParenBytes)
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d.w.Write(spaceBytes)
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}
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d.ignoreNextType = false
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// Display length and capacity if the built-in len and cap functions
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// work with the value's kind and the len/cap itself is non-zero.
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valueLen, valueCap := 0, 0
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switch v.Kind() {
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case reflect.Array, reflect.Slice, reflect.Chan:
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valueLen, valueCap = v.Len(), v.Cap()
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case reflect.Map, reflect.String:
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valueLen = v.Len()
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}
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if valueLen != 0 || valueCap != 0 {
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d.w.Write(openParenBytes)
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if valueLen != 0 {
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d.w.Write(lenEqualsBytes)
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printInt(d.w, int64(valueLen), 10)
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}
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if valueCap != 0 {
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if valueLen != 0 {
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d.w.Write(spaceBytes)
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}
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d.w.Write(capEqualsBytes)
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printInt(d.w, int64(valueCap), 10)
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}
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d.w.Write(closeParenBytes)
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d.w.Write(spaceBytes)
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}
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// Call Stringer/error interfaces if they exist and the handle methods flag
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// is enabled
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if !d.cs.DisableMethods {
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if (kind != reflect.Invalid) && (kind != reflect.Interface) {
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if handled := handleMethods(d.cs, d.w, v); handled {
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return
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}
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}
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}
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switch kind {
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case reflect.Invalid:
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// Do nothing. We should never get here since invalid has already
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// been handled above.
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case reflect.Bool:
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printBool(d.w, v.Bool())
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case reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64, reflect.Int:
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printInt(d.w, v.Int(), 10)
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case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uint:
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printUint(d.w, v.Uint(), 10)
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case reflect.Float32:
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printFloat(d.w, v.Float(), 32)
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case reflect.Float64:
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printFloat(d.w, v.Float(), 64)
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case reflect.Complex64:
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printComplex(d.w, v.Complex(), 32)
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case reflect.Complex128:
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printComplex(d.w, v.Complex(), 64)
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case reflect.Slice:
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if v.IsNil() {
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d.w.Write(nilAngleBytes)
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break
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}
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fallthrough
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case reflect.Array:
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d.w.Write(openBraceNewlineBytes)
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d.depth++
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if (d.cs.MaxDepth != 0) && (d.depth > d.cs.MaxDepth) {
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d.indent()
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d.w.Write(maxNewlineBytes)
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} else {
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d.dumpSlice(v)
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}
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d.depth--
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d.indent()
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d.w.Write(closeBraceBytes)
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case reflect.String:
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d.w.Write([]byte(strconv.Quote(v.String())))
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case reflect.Interface:
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// The only time we should get here is for nil interfaces due to
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// unpackValue calls.
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if v.IsNil() {
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d.w.Write(nilAngleBytes)
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}
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case reflect.Ptr:
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// Do nothing. We should never get here since pointers have already
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// been handled above.
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case reflect.Map:
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// nil maps should be indicated as different than empty maps
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if v.IsNil() {
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d.w.Write(nilAngleBytes)
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break
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}
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d.w.Write(openBraceNewlineBytes)
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d.depth++
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if (d.cs.MaxDepth != 0) && (d.depth > d.cs.MaxDepth) {
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d.indent()
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d.w.Write(maxNewlineBytes)
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} else {
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numEntries := v.Len()
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keys := v.MapKeys()
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if d.cs.SortKeys {
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sortValues(keys, d.cs)
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}
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for i, key := range keys {
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d.dump(d.unpackValue(key))
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d.w.Write(colonSpaceBytes)
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d.ignoreNextIndent = true
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d.dump(d.unpackValue(v.MapIndex(key)))
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if i < (numEntries - 1) {
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d.w.Write(commaNewlineBytes)
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} else {
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d.w.Write(newlineBytes)
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}
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}
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}
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d.depth--
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d.indent()
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d.w.Write(closeBraceBytes)
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case reflect.Struct:
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d.w.Write(openBraceNewlineBytes)
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d.depth++
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if (d.cs.MaxDepth != 0) && (d.depth > d.cs.MaxDepth) {
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d.indent()
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d.w.Write(maxNewlineBytes)
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} else {
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vt := v.Type()
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numFields := v.NumField()
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for i := 0; i < numFields; i++ {
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d.indent()
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vtf := vt.Field(i)
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d.w.Write([]byte(vtf.Name))
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d.w.Write(colonSpaceBytes)
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d.ignoreNextIndent = true
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d.dump(d.unpackValue(v.Field(i)))
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if i < (numFields - 1) {
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d.w.Write(commaNewlineBytes)
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} else {
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d.w.Write(newlineBytes)
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}
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}
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}
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d.depth--
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d.indent()
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d.w.Write(closeBraceBytes)
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case reflect.Uintptr:
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printHexPtr(d.w, uintptr(v.Uint()))
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case reflect.UnsafePointer, reflect.Chan, reflect.Func:
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printHexPtr(d.w, v.Pointer())
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// There were not any other types at the time this code was written, but
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// fall back to letting the default fmt package handle it in case any new
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// types are added.
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default:
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if v.CanInterface() {
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fmt.Fprintf(d.w, "%v", v.Interface())
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} else {
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fmt.Fprintf(d.w, "%v", v.String())
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}
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}
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}
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// fdump is a helper function to consolidate the logic from the various public
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// methods which take varying writers and config states.
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func fdump(cs *ConfigState, w io.Writer, a ...interface{}) {
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for _, arg := range a {
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if arg == nil {
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w.Write(interfaceBytes)
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w.Write(spaceBytes)
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w.Write(nilAngleBytes)
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w.Write(newlineBytes)
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continue
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}
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d := dumpState{w: w, cs: cs}
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d.pointers = make(map[uintptr]int)
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d.dump(reflect.ValueOf(arg))
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d.w.Write(newlineBytes)
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}
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}
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// Fdump formats and displays the passed arguments to io.Writer w. It formats
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// exactly the same as Dump.
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func Fdump(w io.Writer, a ...interface{}) {
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fdump(&Config, w, a...)
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}
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// Sdump returns a string with the passed arguments formatted exactly the same
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// as Dump.
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func Sdump(a ...interface{}) string {
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var buf bytes.Buffer
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fdump(&Config, &buf, a...)
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return buf.String()
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}
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/*
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Dump displays the passed parameters to standard out with newlines, customizable
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indentation, and additional debug information such as complete types and all
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pointer addresses used to indirect to the final value. It provides the
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following features over the built-in printing facilities provided by the fmt
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package:
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* Pointers are dereferenced and followed
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* Circular data structures are detected and handled properly
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* Custom Stringer/error interfaces are optionally invoked, including
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on unexported types
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* Custom types which only implement the Stringer/error interfaces via
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a pointer receiver are optionally invoked when passing non-pointer
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variables
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* Byte arrays and slices are dumped like the hexdump -C command which
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includes offsets, byte values in hex, and ASCII output
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The configuration options are controlled by an exported package global,
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spew.Config. See ConfigState for options documentation.
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See Fdump if you would prefer dumping to an arbitrary io.Writer or Sdump to
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get the formatted result as a string.
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*/
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func Dump(a ...interface{}) {
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fdump(&Config, os.Stdout, a...)
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}
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