peridot/vendor/github.com/bluekeyes/go-gitdiff/gitdiff/apply.go

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Go
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2022-07-07 20:11:50 +00:00
package gitdiff
import (
"errors"
"fmt"
"io"
"sort"
)
// Conflict indicates an apply failed due to a conflict between the patch and
// the source content.
//
// Users can test if an error was caused by a conflict by using errors.Is with
// an empty Conflict:
//
// if errors.Is(err, &Conflict{}) {
// // handle conflict
// }
//
type Conflict struct {
msg string
}
func (c *Conflict) Error() string {
return "conflict: " + c.msg
}
// Is implements error matching for Conflict. Passing an empty instance of
// Conflict always returns true.
func (c *Conflict) Is(other error) bool {
if other, ok := other.(*Conflict); ok {
return other.msg == "" || other.msg == c.msg
}
return false
}
// ApplyError wraps an error that occurs during patch application with
// additional location information, if it is available.
type ApplyError struct {
// Line is the one-indexed line number in the source data
Line int64
// Fragment is the one-indexed fragment number in the file
Fragment int
// FragmentLine is the one-indexed line number in the fragment
FragmentLine int
err error
}
// Unwrap returns the wrapped error.
func (e *ApplyError) Unwrap() error {
return e.err
}
func (e *ApplyError) Error() string {
return fmt.Sprintf("%v", e.err)
}
type lineNum int
type fragNum int
type fragLineNum int
// applyError creates a new *ApplyError wrapping err or augments the information
// in err with args if it is already an *ApplyError. Returns nil if err is nil.
func applyError(err error, args ...interface{}) error {
if err == nil {
return nil
}
e, ok := err.(*ApplyError)
if !ok {
if err == io.EOF {
err = io.ErrUnexpectedEOF
}
e = &ApplyError{err: err}
}
for _, arg := range args {
switch v := arg.(type) {
case lineNum:
e.Line = int64(v) + 1
case fragNum:
e.Fragment = int(v) + 1
case fragLineNum:
e.FragmentLine = int(v) + 1
}
}
return e
}
var (
errApplyInProgress = errors.New("gitdiff: incompatible apply in progress")
)
const (
applyInitial = iota
applyText
applyBinary
applyFile
)
// Apply is a convenience function that creates an Applier for src with default
// settings and applies the changes in f, writing the result to dst.
func Apply(dst io.Writer, src io.ReaderAt, f *File) error {
return NewApplier(src).ApplyFile(dst, f)
}
// Applier applies changes described in fragments to source data. If changes
// are described in multiple fragments, those fragments must be applied in
// order, usually by calling ApplyFile.
//
// By default, Applier operates in "strict" mode, where fragment content and
// positions must exactly match those of the source.
//
// If an error occurs while applying, methods on Applier return instances of
// *ApplyError that annotate the wrapped error with additional information
// when available. If the error is because of a conflict between a fragment and
// the source, the wrapped error will be a *Conflict.
//
// While an Applier can apply both text and binary fragments, only one fragment
// type can be used without resetting the Applier. The first fragment applied
// sets the type for the Applier. Mixing fragment types or mixing
// fragment-level and file-level applies results in an error.
type Applier struct {
src io.ReaderAt
lineSrc LineReaderAt
nextLine int64
applyType int
}
// NewApplier creates an Applier that reads data from src. If src is a
// LineReaderAt, it is used directly to apply text fragments.
func NewApplier(src io.ReaderAt) *Applier {
a := new(Applier)
a.Reset(src)
return a
}
// Reset resets the input and internal state of the Applier. If src is nil, the
// existing source is reused.
func (a *Applier) Reset(src io.ReaderAt) {
if src != nil {
a.src = src
if lineSrc, ok := src.(LineReaderAt); ok {
a.lineSrc = lineSrc
} else {
a.lineSrc = &lineReaderAt{r: src}
}
}
a.nextLine = 0
a.applyType = applyInitial
}
// ApplyFile applies the changes in all of the fragments of f and writes the
// result to dst.
func (a *Applier) ApplyFile(dst io.Writer, f *File) error {
if a.applyType != applyInitial {
return applyError(errApplyInProgress)
}
defer func() { a.applyType = applyFile }()
if f.IsBinary && len(f.TextFragments) > 0 {
return applyError(errors.New("binary file contains text fragments"))
}
if !f.IsBinary && f.BinaryFragment != nil {
return applyError(errors.New("text file contains binary fragment"))
}
switch {
case f.BinaryFragment != nil:
return a.ApplyBinaryFragment(dst, f.BinaryFragment)
case len(f.TextFragments) > 0:
frags := make([]*TextFragment, len(f.TextFragments))
copy(frags, f.TextFragments)
sort.Slice(frags, func(i, j int) bool {
return frags[i].OldPosition < frags[j].OldPosition
})
// TODO(bkeyes): consider merging overlapping fragments
// right now, the application fails if fragments overlap, but it should be
// possible to precompute the result of applying them in order
for i, frag := range frags {
if err := a.ApplyTextFragment(dst, frag); err != nil {
return applyError(err, fragNum(i))
}
}
}
return applyError(a.Flush(dst))
}
// ApplyTextFragment applies the changes in the fragment f and writes unwritten
// data before the start of the fragment and the result to dst. If multiple
// text fragments apply to the same source, ApplyTextFragment must be called in
// order of increasing start position. As a result, each fragment can be
// applied at most once before a call to Reset.
func (a *Applier) ApplyTextFragment(dst io.Writer, f *TextFragment) error {
if a.applyType != applyInitial && a.applyType != applyText {
return applyError(errApplyInProgress)
}
defer func() { a.applyType = applyText }()
// application code assumes fragment fields are consistent
if err := f.Validate(); err != nil {
return applyError(err)
}
// lines are 0-indexed, positions are 1-indexed (but new files have position = 0)
fragStart := f.OldPosition - 1
if fragStart < 0 {
fragStart = 0
}
fragEnd := fragStart + f.OldLines
start := a.nextLine
if fragStart < start {
return applyError(&Conflict{"fragment overlaps with an applied fragment"})
}
if f.OldPosition == 0 {
ok, err := isLen(a.src, 0)
if err != nil {
return applyError(err)
}
if !ok {
return applyError(&Conflict{"cannot create new file from non-empty src"})
}
}
preimage := make([][]byte, fragEnd-start)
n, err := a.lineSrc.ReadLinesAt(preimage, start)
switch {
case err == nil:
case err == io.EOF && n == len(preimage): // last line of frag has no newline character
default:
return applyError(err, lineNum(start+int64(n)))
}
// copy leading data before the fragment starts
for i, line := range preimage[:fragStart-start] {
if _, err := dst.Write(line); err != nil {
a.nextLine = start + int64(i)
return applyError(err, lineNum(a.nextLine))
}
}
preimage = preimage[fragStart-start:]
// apply the changes in the fragment
used := int64(0)
for i, line := range f.Lines {
if err := applyTextLine(dst, line, preimage, used); err != nil {
a.nextLine = fragStart + used
return applyError(err, lineNum(a.nextLine), fragLineNum(i))
}
if line.Old() {
used++
}
}
a.nextLine = fragStart + used
// new position of +0,0 mean a full delete, so check for leftovers
if f.NewPosition == 0 && f.NewLines == 0 {
var b [1][]byte
n, err := a.lineSrc.ReadLinesAt(b[:], a.nextLine)
if err != nil && err != io.EOF {
return applyError(err, lineNum(a.nextLine))
}
if n > 0 {
return applyError(&Conflict{"src still has content after full delete"}, lineNum(a.nextLine))
}
}
return nil
}
func applyTextLine(dst io.Writer, line Line, preimage [][]byte, i int64) (err error) {
if line.Old() && string(preimage[i]) != line.Line {
return &Conflict{"fragment line does not match src line"}
}
if line.New() {
_, err = io.WriteString(dst, line.Line)
}
return err
}
// Flush writes any data following the last applied fragment to dst.
func (a *Applier) Flush(dst io.Writer) (err error) {
switch a.applyType {
case applyInitial:
_, err = copyFrom(dst, a.src, 0)
case applyText:
_, err = copyLinesFrom(dst, a.lineSrc, a.nextLine)
case applyBinary:
// nothing to flush, binary apply "consumes" full source
}
return err
}
// ApplyBinaryFragment applies the changes in the fragment f and writes the
// result to dst. At most one binary fragment can be applied before a call to
// Reset.
func (a *Applier) ApplyBinaryFragment(dst io.Writer, f *BinaryFragment) error {
if a.applyType != applyInitial {
return applyError(errApplyInProgress)
}
defer func() { a.applyType = applyBinary }()
if f == nil {
return applyError(errors.New("nil fragment"))
}
switch f.Method {
case BinaryPatchLiteral:
if _, err := dst.Write(f.Data); err != nil {
return applyError(err)
}
case BinaryPatchDelta:
if err := applyBinaryDeltaFragment(dst, a.src, f.Data); err != nil {
return applyError(err)
}
default:
return applyError(fmt.Errorf("unsupported binary patch method: %v", f.Method))
}
return nil
}
func applyBinaryDeltaFragment(dst io.Writer, src io.ReaderAt, frag []byte) error {
srcSize, delta := readBinaryDeltaSize(frag)
if err := checkBinarySrcSize(src, srcSize); err != nil {
return err
}
dstSize, delta := readBinaryDeltaSize(delta)
for len(delta) > 0 {
op := delta[0]
if op == 0 {
return errors.New("invalid delta opcode 0")
}
var n int64
var err error
switch op & 0x80 {
case 0x80:
n, delta, err = applyBinaryDeltaCopy(dst, op, delta[1:], src)
case 0x00:
n, delta, err = applyBinaryDeltaAdd(dst, op, delta[1:])
}
if err != nil {
return err
}
dstSize -= n
}
if dstSize != 0 {
return errors.New("corrupt binary delta: insufficient or extra data")
}
return nil
}
// readBinaryDeltaSize reads a variable length size from a delta-encoded binary
// fragment, returing the size and the unused data. Data is encoded as:
//
// [[1xxxxxxx]...] [0xxxxxxx]
//
// in little-endian order, with 7 bits of the value per byte.
func readBinaryDeltaSize(d []byte) (size int64, rest []byte) {
shift := uint(0)
for i, b := range d {
size |= int64(b&0x7F) << shift
shift += 7
if b <= 0x7F {
return size, d[i+1:]
}
}
return size, nil
}
// applyBinaryDeltaAdd applies an add opcode in a delta-encoded binary
// fragment, returning the amount of data written and the usused part of the
// fragment. An add operation takes the form:
//
// [0xxxxxx][[data1]...]
//
// where the lower seven bits of the opcode is the number of data bytes
// following the opcode. See also pack-format.txt in the Git source.
func applyBinaryDeltaAdd(w io.Writer, op byte, delta []byte) (n int64, rest []byte, err error) {
size := int(op)
if len(delta) < size {
return 0, delta, errors.New("corrupt binary delta: incomplete add")
}
_, err = w.Write(delta[:size])
return int64(size), delta[size:], err
}
// applyBinaryDeltaCopy applies a copy opcode in a delta-encoded binary
// fragment, returing the amount of data written and the unused part of the
// fragment. A copy operation takes the form:
//
// [1xxxxxxx][offset1][offset2][offset3][offset4][size1][size2][size3]
//
// where the lower seven bits of the opcode determine which non-zero offset and
// size bytes are present in little-endian order: if bit 0 is set, offset1 is
// present, etc. If no offset or size bytes are present, offset is 0 and size
// is 0x10000. See also pack-format.txt in the Git source.
func applyBinaryDeltaCopy(w io.Writer, op byte, delta []byte, src io.ReaderAt) (n int64, rest []byte, err error) {
const defaultSize = 0x10000
unpack := func(start, bits uint) (v int64) {
for i := uint(0); i < bits; i++ {
mask := byte(1 << (i + start))
if op&mask > 0 {
if len(delta) == 0 {
err = errors.New("corrupt binary delta: incomplete copy")
return
}
v |= int64(delta[0]) << (8 * i)
delta = delta[1:]
}
}
return
}
offset := unpack(0, 4)
size := unpack(4, 3)
if err != nil {
return 0, delta, err
}
if size == 0 {
size = defaultSize
}
// TODO(bkeyes): consider pooling these buffers
b := make([]byte, size)
if _, err := src.ReadAt(b, offset); err != nil {
return 0, delta, err
}
_, err = w.Write(b)
return size, delta, err
}
func checkBinarySrcSize(r io.ReaderAt, size int64) error {
ok, err := isLen(r, size)
if err != nil {
return err
}
if !ok {
return &Conflict{"fragment src size does not match actual src size"}
}
return nil
}