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gcc/libgo/go/fmt/scan.go
Ian Lance Taylor f8d9fa9e80 libgo, compiler: Upgrade libgo to Go 1.4, except for runtime. 
This upgrades all of libgo other than the runtime package to
the Go 1.4 release.  In Go 1.4 much of the runtime was
rewritten into Go.  Merging that code will take more time and
will not change the API, so I'm putting it off for now.

There are a few runtime changes anyhow, to accomodate other
packages that rely on minor modifications to the runtime
support.

The compiler changes slightly to add a one-bit flag to each
type descriptor kind that is stored directly in an interface,
which for gccgo is currently only pointer types.  Another
one-bit flag (gcprog) is reserved because it is used by the gc
compiler, but gccgo does not currently use it.

There is another error check in the compiler since I ran
across it during testing.

gotools/:
	* Makefile.am (go_cmd_go_files): Sort entries.  Add generate.go.
	* Makefile.in: Rebuild.

From-SVN: r219627
2015-01-15 00:27:56 +00:00

1170 lines
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// Copyright 2010 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 fmt
import (
"errors"
"io"
"math"
"os"
"reflect"
"strconv"
"sync"
"unicode/utf8"
)
// runeUnreader is the interface to something that can unread runes.
// If the object provided to Scan does not satisfy this interface,
// a local buffer will be used to back up the input, but its contents
// will be lost when Scan returns.
type runeUnreader interface {
UnreadRune() error
}
// ScanState represents the scanner state passed to custom scanners.
// Scanners may do rune-at-a-time scanning or ask the ScanState
// to discover the next space-delimited token.
type ScanState interface {
// ReadRune reads the next rune (Unicode code point) from the input.
// If invoked during Scanln, Fscanln, or Sscanln, ReadRune() will
// return EOF after returning the first '\n' or when reading beyond
// the specified width.
ReadRune() (r rune, size int, err error)
// UnreadRune causes the next call to ReadRune to return the same rune.
UnreadRune() error
// SkipSpace skips space in the input. Newlines are treated as space
// unless the scan operation is Scanln, Fscanln or Sscanln, in which case
// a newline is treated as EOF.
SkipSpace()
// Token skips space in the input if skipSpace is true, then returns the
// run of Unicode code points c satisfying f(c). If f is nil,
// !unicode.IsSpace(c) is used; that is, the token will hold non-space
// characters. Newlines are treated as space unless the scan operation
// is Scanln, Fscanln or Sscanln, in which case a newline is treated as
// EOF. The returned slice points to shared data that may be overwritten
// by the next call to Token, a call to a Scan function using the ScanState
// as input, or when the calling Scan method returns.
Token(skipSpace bool, f func(rune) bool) (token []byte, err error)
// Width returns the value of the width option and whether it has been set.
// The unit is Unicode code points.
Width() (wid int, ok bool)
// Because ReadRune is implemented by the interface, Read should never be
// called by the scanning routines and a valid implementation of
// ScanState may choose always to return an error from Read.
Read(buf []byte) (n int, err error)
}
// Scanner is implemented by any value that has a Scan method, which scans
// the input for the representation of a value and stores the result in the
// receiver, which must be a pointer to be useful. The Scan method is called
// for any argument to Scan, Scanf, or Scanln that implements it.
type Scanner interface {
Scan(state ScanState, verb rune) error
}
// Scan scans text read from standard input, storing successive
// space-separated values into successive arguments. Newlines count
// as space. It returns the number of items successfully scanned.
// If that is less than the number of arguments, err will report why.
func Scan(a ...interface{}) (n int, err error) {
return Fscan(os.Stdin, a...)
}
// Scanln is similar to Scan, but stops scanning at a newline and
// after the final item there must be a newline or EOF.
func Scanln(a ...interface{}) (n int, err error) {
return Fscanln(os.Stdin, a...)
}
// Scanf scans text read from standard input, storing successive
// space-separated values into successive arguments as determined by
// the format. It returns the number of items successfully scanned.
func Scanf(format string, a ...interface{}) (n int, err error) {
return Fscanf(os.Stdin, format, a...)
}
type stringReader string
func (r *stringReader) Read(b []byte) (n int, err error) {
n = copy(b, *r)
*r = (*r)[n:]
if n == 0 {
err = io.EOF
}
return
}
// Sscan scans the argument string, storing successive space-separated
// values into successive arguments. Newlines count as space. It
// returns the number of items successfully scanned. If that is less
// than the number of arguments, err will report why.
func Sscan(str string, a ...interface{}) (n int, err error) {
return Fscan((*stringReader)(&str), a...)
}
// Sscanln is similar to Sscan, but stops scanning at a newline and
// after the final item there must be a newline or EOF.
func Sscanln(str string, a ...interface{}) (n int, err error) {
return Fscanln((*stringReader)(&str), a...)
}
// Sscanf scans the argument string, storing successive space-separated
// values into successive arguments as determined by the format. It
// returns the number of items successfully parsed.
func Sscanf(str string, format string, a ...interface{}) (n int, err error) {
return Fscanf((*stringReader)(&str), format, a...)
}
// Fscan scans text read from r, storing successive space-separated
// values into successive arguments. Newlines count as space. It
// returns the number of items successfully scanned. If that is less
// than the number of arguments, err will report why.
func Fscan(r io.Reader, a ...interface{}) (n int, err error) {
s, old := newScanState(r, true, false)
n, err = s.doScan(a)
s.free(old)
return
}
// Fscanln is similar to Fscan, but stops scanning at a newline and
// after the final item there must be a newline or EOF.
func Fscanln(r io.Reader, a ...interface{}) (n int, err error) {
s, old := newScanState(r, false, true)
n, err = s.doScan(a)
s.free(old)
return
}
// Fscanf scans text read from r, storing successive space-separated
// values into successive arguments as determined by the format. It
// returns the number of items successfully parsed.
func Fscanf(r io.Reader, format string, a ...interface{}) (n int, err error) {
s, old := newScanState(r, false, false)
n, err = s.doScanf(format, a)
s.free(old)
return
}
// scanError represents an error generated by the scanning software.
// It's used as a unique signature to identify such errors when recovering.
type scanError struct {
err error
}
const eof = -1
// ss is the internal implementation of ScanState.
type ss struct {
rr io.RuneReader // where to read input
buf buffer // token accumulator
peekRune rune // one-rune lookahead
prevRune rune // last rune returned by ReadRune
count int // runes consumed so far.
atEOF bool // already read EOF
ssave
}
// ssave holds the parts of ss that need to be
// saved and restored on recursive scans.
type ssave struct {
validSave bool // is or was a part of an actual ss.
nlIsEnd bool // whether newline terminates scan
nlIsSpace bool // whether newline counts as white space
argLimit int // max value of ss.count for this arg; argLimit <= limit
limit int // max value of ss.count.
maxWid int // width of this arg.
}
// The Read method is only in ScanState so that ScanState
// satisfies io.Reader. It will never be called when used as
// intended, so there is no need to make it actually work.
func (s *ss) Read(buf []byte) (n int, err error) {
return 0, errors.New("ScanState's Read should not be called. Use ReadRune")
}
func (s *ss) ReadRune() (r rune, size int, err error) {
if s.peekRune >= 0 {
s.count++
r = s.peekRune
size = utf8.RuneLen(r)
s.prevRune = r
s.peekRune = -1
return
}
if s.atEOF || s.nlIsEnd && s.prevRune == '\n' || s.count >= s.argLimit {
err = io.EOF
return
}
r, size, err = s.rr.ReadRune()
if err == nil {
s.count++
s.prevRune = r
} else if err == io.EOF {
s.atEOF = true
}
return
}
func (s *ss) Width() (wid int, ok bool) {
if s.maxWid == hugeWid {
return 0, false
}
return s.maxWid, true
}
// The public method returns an error; this private one panics.
// If getRune reaches EOF, the return value is EOF (-1).
func (s *ss) getRune() (r rune) {
r, _, err := s.ReadRune()
if err != nil {
if err == io.EOF {
return eof
}
s.error(err)
}
return
}
// mustReadRune turns io.EOF into a panic(io.ErrUnexpectedEOF).
// It is called in cases such as string scanning where an EOF is a
// syntax error.
func (s *ss) mustReadRune() (r rune) {
r = s.getRune()
if r == eof {
s.error(io.ErrUnexpectedEOF)
}
return
}
func (s *ss) UnreadRune() error {
if u, ok := s.rr.(runeUnreader); ok {
u.UnreadRune()
} else {
s.peekRune = s.prevRune
}
s.prevRune = -1
s.count--
return nil
}
func (s *ss) error(err error) {
panic(scanError{err})
}
func (s *ss) errorString(err string) {
panic(scanError{errors.New(err)})
}
func (s *ss) Token(skipSpace bool, f func(rune) bool) (tok []byte, err error) {
defer func() {
if e := recover(); e != nil {
if se, ok := e.(scanError); ok {
err = se.err
} else {
panic(e)
}
}
}()
if f == nil {
f = notSpace
}
s.buf = s.buf[:0]
tok = s.token(skipSpace, f)
return
}
// space is a copy of the unicode.White_Space ranges,
// to avoid depending on package unicode.
var space = [][2]uint16{
{0x0009, 0x000d},
{0x0020, 0x0020},
{0x0085, 0x0085},
{0x00a0, 0x00a0},
{0x1680, 0x1680},
{0x2000, 0x200a},
{0x2028, 0x2029},
{0x202f, 0x202f},
{0x205f, 0x205f},
{0x3000, 0x3000},
}
func isSpace(r rune) bool {
if r >= 1<<16 {
return false
}
rx := uint16(r)
for _, rng := range space {
if rx < rng[0] {
return false
}
if rx <= rng[1] {
return true
}
}
return false
}
// notSpace is the default scanning function used in Token.
func notSpace(r rune) bool {
return !isSpace(r)
}
// SkipSpace provides Scan methods the ability to skip space and newline
// characters in keeping with the current scanning mode set by format strings
// and Scan/Scanln.
func (s *ss) SkipSpace() {
s.skipSpace(false)
}
// readRune is a structure to enable reading UTF-8 encoded code points
// from an io.Reader. It is used if the Reader given to the scanner does
// not already implement io.RuneReader.
type readRune struct {
reader io.Reader
buf [utf8.UTFMax]byte // used only inside ReadRune
pending int // number of bytes in pendBuf; only >0 for bad UTF-8
pendBuf [utf8.UTFMax]byte // bytes left over
}
// readByte returns the next byte from the input, which may be
// left over from a previous read if the UTF-8 was ill-formed.
func (r *readRune) readByte() (b byte, err error) {
if r.pending > 0 {
b = r.pendBuf[0]
copy(r.pendBuf[0:], r.pendBuf[1:])
r.pending--
return
}
n, err := io.ReadFull(r.reader, r.pendBuf[0:1])
if n != 1 {
return 0, err
}
return r.pendBuf[0], err
}
// unread saves the bytes for the next read.
func (r *readRune) unread(buf []byte) {
copy(r.pendBuf[r.pending:], buf)
r.pending += len(buf)
}
// ReadRune returns the next UTF-8 encoded code point from the
// io.Reader inside r.
func (r *readRune) ReadRune() (rr rune, size int, err error) {
r.buf[0], err = r.readByte()
if err != nil {
return 0, 0, err
}
if r.buf[0] < utf8.RuneSelf { // fast check for common ASCII case
rr = rune(r.buf[0])
size = 1 // Known to be 1.
return
}
var n int
for n = 1; !utf8.FullRune(r.buf[0:n]); n++ {
r.buf[n], err = r.readByte()
if err != nil {
if err == io.EOF {
err = nil
break
}
return
}
}
rr, size = utf8.DecodeRune(r.buf[0:n])
if size < n { // an error
r.unread(r.buf[size:n])
}
return
}
var ssFree = sync.Pool{
New: func() interface{} { return new(ss) },
}
// newScanState allocates a new ss struct or grab a cached one.
func newScanState(r io.Reader, nlIsSpace, nlIsEnd bool) (s *ss, old ssave) {
// If the reader is a *ss, then we've got a recursive
// call to Scan, so re-use the scan state.
s, ok := r.(*ss)
if ok {
old = s.ssave
s.limit = s.argLimit
s.nlIsEnd = nlIsEnd || s.nlIsEnd
s.nlIsSpace = nlIsSpace
return
}
s = ssFree.Get().(*ss)
if rr, ok := r.(io.RuneReader); ok {
s.rr = rr
} else {
s.rr = &readRune{reader: r}
}
s.nlIsSpace = nlIsSpace
s.nlIsEnd = nlIsEnd
s.prevRune = -1
s.peekRune = -1
s.atEOF = false
s.limit = hugeWid
s.argLimit = hugeWid
s.maxWid = hugeWid
s.validSave = true
s.count = 0
return
}
// free saves used ss structs in ssFree; avoid an allocation per invocation.
func (s *ss) free(old ssave) {
// If it was used recursively, just restore the old state.
if old.validSave {
s.ssave = old
return
}
// Don't hold on to ss structs with large buffers.
if cap(s.buf) > 1024 {
return
}
s.buf = s.buf[:0]
s.rr = nil
ssFree.Put(s)
}
// skipSpace skips spaces and maybe newlines.
func (s *ss) skipSpace(stopAtNewline bool) {
for {
r := s.getRune()
if r == eof {
return
}
if r == '\r' && s.peek("\n") {
continue
}
if r == '\n' {
if stopAtNewline {
break
}
if s.nlIsSpace {
continue
}
s.errorString("unexpected newline")
return
}
if !isSpace(r) {
s.UnreadRune()
break
}
}
}
// token returns the next space-delimited string from the input. It
// skips white space. For Scanln, it stops at newlines. For Scan,
// newlines are treated as spaces.
func (s *ss) token(skipSpace bool, f func(rune) bool) []byte {
if skipSpace {
s.skipSpace(false)
}
// read until white space or newline
for {
r := s.getRune()
if r == eof {
break
}
if !f(r) {
s.UnreadRune()
break
}
s.buf.WriteRune(r)
}
return s.buf
}
var complexError = errors.New("syntax error scanning complex number")
var boolError = errors.New("syntax error scanning boolean")
func indexRune(s string, r rune) int {
for i, c := range s {
if c == r {
return i
}
}
return -1
}
// consume reads the next rune in the input and reports whether it is in the ok string.
// If accept is true, it puts the character into the input token.
func (s *ss) consume(ok string, accept bool) bool {
r := s.getRune()
if r == eof {
return false
}
if indexRune(ok, r) >= 0 {
if accept {
s.buf.WriteRune(r)
}
return true
}
if r != eof && accept {
s.UnreadRune()
}
return false
}
// peek reports whether the next character is in the ok string, without consuming it.
func (s *ss) peek(ok string) bool {
r := s.getRune()
if r != eof {
s.UnreadRune()
}
return indexRune(ok, r) >= 0
}
func (s *ss) notEOF() {
// Guarantee there is data to be read.
if r := s.getRune(); r == eof {
panic(io.EOF)
}
s.UnreadRune()
}
// accept checks the next rune in the input. If it's a byte (sic) in the string, it puts it in the
// buffer and returns true. Otherwise it return false.
func (s *ss) accept(ok string) bool {
return s.consume(ok, true)
}
// okVerb verifies that the verb is present in the list, setting s.err appropriately if not.
func (s *ss) okVerb(verb rune, okVerbs, typ string) bool {
for _, v := range okVerbs {
if v == verb {
return true
}
}
s.errorString("bad verb %" + string(verb) + " for " + typ)
return false
}
// scanBool returns the value of the boolean represented by the next token.
func (s *ss) scanBool(verb rune) bool {
s.skipSpace(false)
s.notEOF()
if !s.okVerb(verb, "tv", "boolean") {
return false
}
// Syntax-checking a boolean is annoying. We're not fastidious about case.
switch s.getRune() {
case '0':
return false
case '1':
return true
case 't', 'T':
if s.accept("rR") && (!s.accept("uU") || !s.accept("eE")) {
s.error(boolError)
}
return true
case 'f', 'F':
if s.accept("aA") && (!s.accept("lL") || !s.accept("sS") || !s.accept("eE")) {
s.error(boolError)
}
return false
}
return false
}
// Numerical elements
const (
binaryDigits = "01"
octalDigits = "01234567"
decimalDigits = "0123456789"
hexadecimalDigits = "0123456789aAbBcCdDeEfF"
sign = "+-"
period = "."
exponent = "eEp"
)
// getBase returns the numeric base represented by the verb and its digit string.
func (s *ss) getBase(verb rune) (base int, digits string) {
s.okVerb(verb, "bdoUxXv", "integer") // sets s.err
base = 10
digits = decimalDigits
switch verb {
case 'b':
base = 2
digits = binaryDigits
case 'o':
base = 8
digits = octalDigits
case 'x', 'X', 'U':
base = 16
digits = hexadecimalDigits
}
return
}
// scanNumber returns the numerical string with specified digits starting here.
func (s *ss) scanNumber(digits string, haveDigits bool) string {
if !haveDigits {
s.notEOF()
if !s.accept(digits) {
s.errorString("expected integer")
}
}
for s.accept(digits) {
}
return string(s.buf)
}
// scanRune returns the next rune value in the input.
func (s *ss) scanRune(bitSize int) int64 {
s.notEOF()
r := int64(s.getRune())
n := uint(bitSize)
x := (r << (64 - n)) >> (64 - n)
if x != r {
s.errorString("overflow on character value " + string(r))
}
return r
}
// scanBasePrefix reports whether the integer begins with a 0 or 0x,
// and returns the base, digit string, and whether a zero was found.
// It is called only if the verb is %v.
func (s *ss) scanBasePrefix() (base int, digits string, found bool) {
if !s.peek("0") {
return 10, decimalDigits, false
}
s.accept("0")
found = true // We've put a digit into the token buffer.
// Special cases for '0' && '0x'
base, digits = 8, octalDigits
if s.peek("xX") {
s.consume("xX", false)
base, digits = 16, hexadecimalDigits
}
return
}
// scanInt returns the value of the integer represented by the next
// token, checking for overflow. Any error is stored in s.err.
func (s *ss) scanInt(verb rune, bitSize int) int64 {
if verb == 'c' {
return s.scanRune(bitSize)
}
s.skipSpace(false)
s.notEOF()
base, digits := s.getBase(verb)
haveDigits := false
if verb == 'U' {
if !s.consume("U", false) || !s.consume("+", false) {
s.errorString("bad unicode format ")
}
} else {
s.accept(sign) // If there's a sign, it will be left in the token buffer.
if verb == 'v' {
base, digits, haveDigits = s.scanBasePrefix()
}
}
tok := s.scanNumber(digits, haveDigits)
i, err := strconv.ParseInt(tok, base, 64)
if err != nil {
s.error(err)
}
n := uint(bitSize)
x := (i << (64 - n)) >> (64 - n)
if x != i {
s.errorString("integer overflow on token " + tok)
}
return i
}
// scanUint returns the value of the unsigned integer represented
// by the next token, checking for overflow. Any error is stored in s.err.
func (s *ss) scanUint(verb rune, bitSize int) uint64 {
if verb == 'c' {
return uint64(s.scanRune(bitSize))
}
s.skipSpace(false)
s.notEOF()
base, digits := s.getBase(verb)
haveDigits := false
if verb == 'U' {
if !s.consume("U", false) || !s.consume("+", false) {
s.errorString("bad unicode format ")
}
} else if verb == 'v' {
base, digits, haveDigits = s.scanBasePrefix()
}
tok := s.scanNumber(digits, haveDigits)
i, err := strconv.ParseUint(tok, base, 64)
if err != nil {
s.error(err)
}
n := uint(bitSize)
x := (i << (64 - n)) >> (64 - n)
if x != i {
s.errorString("unsigned integer overflow on token " + tok)
}
return i
}
// floatToken returns the floating-point number starting here, no longer than swid
// if the width is specified. It's not rigorous about syntax because it doesn't check that
// we have at least some digits, but Atof will do that.
func (s *ss) floatToken() string {
s.buf = s.buf[:0]
// NaN?
if s.accept("nN") && s.accept("aA") && s.accept("nN") {
return string(s.buf)
}
// leading sign?
s.accept(sign)
// Inf?
if s.accept("iI") && s.accept("nN") && s.accept("fF") {
return string(s.buf)
}
// digits?
for s.accept(decimalDigits) {
}
// decimal point?
if s.accept(period) {
// fraction?
for s.accept(decimalDigits) {
}
}
// exponent?
if s.accept(exponent) {
// leading sign?
s.accept(sign)
// digits?
for s.accept(decimalDigits) {
}
}
return string(s.buf)
}
// complexTokens returns the real and imaginary parts of the complex number starting here.
// The number might be parenthesized and has the format (N+Ni) where N is a floating-point
// number and there are no spaces within.
func (s *ss) complexTokens() (real, imag string) {
// TODO: accept N and Ni independently?
parens := s.accept("(")
real = s.floatToken()
s.buf = s.buf[:0]
// Must now have a sign.
if !s.accept("+-") {
s.error(complexError)
}
// Sign is now in buffer
imagSign := string(s.buf)
imag = s.floatToken()
if !s.accept("i") {
s.error(complexError)
}
if parens && !s.accept(")") {
s.error(complexError)
}
return real, imagSign + imag
}
// convertFloat converts the string to a float64value.
func (s *ss) convertFloat(str string, n int) float64 {
if p := indexRune(str, 'p'); p >= 0 {
// Atof doesn't handle power-of-2 exponents,
// but they're easy to evaluate.
f, err := strconv.ParseFloat(str[:p], n)
if err != nil {
// Put full string into error.
if e, ok := err.(*strconv.NumError); ok {
e.Num = str
}
s.error(err)
}
m, err := strconv.Atoi(str[p+1:])
if err != nil {
// Put full string into error.
if e, ok := err.(*strconv.NumError); ok {
e.Num = str
}
s.error(err)
}
return math.Ldexp(f, m)
}
f, err := strconv.ParseFloat(str, n)
if err != nil {
s.error(err)
}
return f
}
// convertComplex converts the next token to a complex128 value.
// The atof argument is a type-specific reader for the underlying type.
// If we're reading complex64, atof will parse float32s and convert them
// to float64's to avoid reproducing this code for each complex type.
func (s *ss) scanComplex(verb rune, n int) complex128 {
if !s.okVerb(verb, floatVerbs, "complex") {
return 0
}
s.skipSpace(false)
s.notEOF()
sreal, simag := s.complexTokens()
real := s.convertFloat(sreal, n/2)
imag := s.convertFloat(simag, n/2)
return complex(real, imag)
}
// convertString returns the string represented by the next input characters.
// The format of the input is determined by the verb.
func (s *ss) convertString(verb rune) (str string) {
if !s.okVerb(verb, "svqx", "string") {
return ""
}
s.skipSpace(false)
s.notEOF()
switch verb {
case 'q':
str = s.quotedString()
case 'x':
str = s.hexString()
default:
str = string(s.token(true, notSpace)) // %s and %v just return the next word
}
return
}
// quotedString returns the double- or back-quoted string represented by the next input characters.
func (s *ss) quotedString() string {
s.notEOF()
quote := s.getRune()
switch quote {
case '`':
// Back-quoted: Anything goes until EOF or back quote.
for {
r := s.mustReadRune()
if r == quote {
break
}
s.buf.WriteRune(r)
}
return string(s.buf)
case '"':
// Double-quoted: Include the quotes and let strconv.Unquote do the backslash escapes.
s.buf.WriteRune(quote)
for {
r := s.mustReadRune()
s.buf.WriteRune(r)
if r == '\\' {
// In a legal backslash escape, no matter how long, only the character
// immediately after the escape can itself be a backslash or quote.
// Thus we only need to protect the first character after the backslash.
s.buf.WriteRune(s.mustReadRune())
} else if r == '"' {
break
}
}
result, err := strconv.Unquote(string(s.buf))
if err != nil {
s.error(err)
}
return result
default:
s.errorString("expected quoted string")
}
return ""
}
// hexDigit returns the value of the hexadecimal digit
func (s *ss) hexDigit(d rune) int {
digit := int(d)
switch digit {
case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9':
return digit - '0'
case 'a', 'b', 'c', 'd', 'e', 'f':
return 10 + digit - 'a'
case 'A', 'B', 'C', 'D', 'E', 'F':
return 10 + digit - 'A'
}
s.errorString("illegal hex digit")
return 0
}
// hexByte returns the next hex-encoded (two-character) byte from the input.
// There must be either two hexadecimal digits or a space character in the input.
func (s *ss) hexByte() (b byte, ok bool) {
rune1 := s.getRune()
if rune1 == eof {
return
}
if isSpace(rune1) {
s.UnreadRune()
return
}
rune2 := s.mustReadRune()
return byte(s.hexDigit(rune1)<<4 | s.hexDigit(rune2)), true
}
// hexString returns the space-delimited hexpair-encoded string.
func (s *ss) hexString() string {
s.notEOF()
for {
b, ok := s.hexByte()
if !ok {
break
}
s.buf.WriteByte(b)
}
if len(s.buf) == 0 {
s.errorString("no hex data for %x string")
return ""
}
return string(s.buf)
}
const floatVerbs = "beEfFgGv"
const hugeWid = 1 << 30
// scanOne scans a single value, deriving the scanner from the type of the argument.
func (s *ss) scanOne(verb rune, arg interface{}) {
s.buf = s.buf[:0]
var err error
// If the parameter has its own Scan method, use that.
if v, ok := arg.(Scanner); ok {
err = v.Scan(s, verb)
if err != nil {
if err == io.EOF {
err = io.ErrUnexpectedEOF
}
s.error(err)
}
return
}
switch v := arg.(type) {
case *bool:
*v = s.scanBool(verb)
case *complex64:
*v = complex64(s.scanComplex(verb, 64))
case *complex128:
*v = s.scanComplex(verb, 128)
case *int:
*v = int(s.scanInt(verb, intBits))
case *int8:
*v = int8(s.scanInt(verb, 8))
case *int16:
*v = int16(s.scanInt(verb, 16))
case *int32:
*v = int32(s.scanInt(verb, 32))
case *int64:
*v = s.scanInt(verb, 64)
case *uint:
*v = uint(s.scanUint(verb, intBits))
case *uint8:
*v = uint8(s.scanUint(verb, 8))
case *uint16:
*v = uint16(s.scanUint(verb, 16))
case *uint32:
*v = uint32(s.scanUint(verb, 32))
case *uint64:
*v = s.scanUint(verb, 64)
case *uintptr:
*v = uintptr(s.scanUint(verb, uintptrBits))
// Floats are tricky because you want to scan in the precision of the result, not
// scan in high precision and convert, in order to preserve the correct error condition.
case *float32:
if s.okVerb(verb, floatVerbs, "float32") {
s.skipSpace(false)
s.notEOF()
*v = float32(s.convertFloat(s.floatToken(), 32))
}
case *float64:
if s.okVerb(verb, floatVerbs, "float64") {
s.skipSpace(false)
s.notEOF()
*v = s.convertFloat(s.floatToken(), 64)
}
case *string:
*v = s.convertString(verb)
case *[]byte:
// We scan to string and convert so we get a copy of the data.
// If we scanned to bytes, the slice would point at the buffer.
*v = []byte(s.convertString(verb))
default:
val := reflect.ValueOf(v)
ptr := val
if ptr.Kind() != reflect.Ptr {
s.errorString("type not a pointer: " + val.Type().String())
return
}
switch v := ptr.Elem(); v.Kind() {
case reflect.Bool:
v.SetBool(s.scanBool(verb))
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
v.SetInt(s.scanInt(verb, v.Type().Bits()))
case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uintptr:
v.SetUint(s.scanUint(verb, v.Type().Bits()))
case reflect.String:
v.SetString(s.convertString(verb))
case reflect.Slice:
// For now, can only handle (renamed) []byte.
typ := v.Type()
if typ.Elem().Kind() != reflect.Uint8 {
s.errorString("can't scan type: " + val.Type().String())
}
str := s.convertString(verb)
v.Set(reflect.MakeSlice(typ, len(str), len(str)))
for i := 0; i < len(str); i++ {
v.Index(i).SetUint(uint64(str[i]))
}
case reflect.Float32, reflect.Float64:
s.skipSpace(false)
s.notEOF()
v.SetFloat(s.convertFloat(s.floatToken(), v.Type().Bits()))
case reflect.Complex64, reflect.Complex128:
v.SetComplex(s.scanComplex(verb, v.Type().Bits()))
default:
s.errorString("can't scan type: " + val.Type().String())
}
}
}
// errorHandler turns local panics into error returns.
func errorHandler(errp *error) {
if e := recover(); e != nil {
if se, ok := e.(scanError); ok { // catch local error
*errp = se.err
} else if eof, ok := e.(error); ok && eof == io.EOF { // out of input
*errp = eof
} else {
panic(e)
}
}
}
// doScan does the real work for scanning without a format string.
func (s *ss) doScan(a []interface{}) (numProcessed int, err error) {
defer errorHandler(&err)
for _, arg := range a {
s.scanOne('v', arg)
numProcessed++
}
// Check for newline if required.
if !s.nlIsSpace {
for {
r := s.getRune()
if r == '\n' || r == eof {
break
}
if !isSpace(r) {
s.errorString("expected newline")
break
}
}
}
return
}
// advance determines whether the next characters in the input match
// those of the format. It returns the number of bytes (sic) consumed
// in the format. Newlines included, all runs of space characters in
// either input or format behave as a single space. This routine also
// handles the %% case. If the return value is zero, either format
// starts with a % (with no following %) or the input is empty.
// If it is negative, the input did not match the string.
func (s *ss) advance(format string) (i int) {
for i < len(format) {
fmtc, w := utf8.DecodeRuneInString(format[i:])
if fmtc == '%' {
// %% acts like a real percent
nextc, _ := utf8.DecodeRuneInString(format[i+w:]) // will not match % if string is empty
if nextc != '%' {
return
}
i += w // skip the first %
}
sawSpace := false
for isSpace(fmtc) && i < len(format) {
sawSpace = true
i += w
fmtc, w = utf8.DecodeRuneInString(format[i:])
}
if sawSpace {
// There was space in the format, so there should be space (EOF)
// in the input.
inputc := s.getRune()
if inputc == eof || inputc == '\n' {
// If we've reached a newline, stop now; don't read ahead.
return
}
if !isSpace(inputc) {
// Space in format but not in input: error
s.errorString("expected space in input to match format")
}
s.skipSpace(true)
continue
}
inputc := s.mustReadRune()
if fmtc != inputc {
s.UnreadRune()
return -1
}
i += w
}
return
}
// doScanf does the real work when scanning with a format string.
// At the moment, it handles only pointers to basic types.
func (s *ss) doScanf(format string, a []interface{}) (numProcessed int, err error) {
defer errorHandler(&err)
end := len(format) - 1
// We process one item per non-trivial format
for i := 0; i <= end; {
w := s.advance(format[i:])
if w > 0 {
i += w
continue
}
// Either we failed to advance, we have a percent character, or we ran out of input.
if format[i] != '%' {
// Can't advance format. Why not?
if w < 0 {
s.errorString("input does not match format")
}
// Otherwise at EOF; "too many operands" error handled below
break
}
i++ // % is one byte
// do we have 20 (width)?
var widPresent bool
s.maxWid, widPresent, i = parsenum(format, i, end)
if !widPresent {
s.maxWid = hugeWid
}
s.argLimit = s.limit
if f := s.count + s.maxWid; f < s.argLimit {
s.argLimit = f
}
c, w := utf8.DecodeRuneInString(format[i:])
i += w
if numProcessed >= len(a) { // out of operands
s.errorString("too few operands for format %" + format[i-w:])
break
}
arg := a[numProcessed]
s.scanOne(c, arg)
numProcessed++
s.argLimit = s.limit
}
if numProcessed < len(a) {
s.errorString("too many operands")
}
return
}
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