Commit ed1a5e5d authored by Robert Griesemer's avatar Robert Griesemer

cmd/compile: cleanup number lexing

Change-Id: Ib0dd458d4ab1c58a2baf36491e288ac32e2ff99e
Reviewed-on: https://go-review.googlesource.com/19962Reviewed-by: default avatarMatthew Dempsky <mdempsky@google.com>
Run-TryBot: Matthew Dempsky <mdempsky@google.com>
TryBot-Result: Gobot Gobot <gobot@golang.org>
parent 36f25a7e
......@@ -1355,170 +1355,143 @@ var keywords = map[string]int32{
}
func (l *lexer) number(c rune) {
// TODO(gri) this can be done nicely with fewer or even without labels
var str string
cp := &lexbuf
cp.Reset()
// parse mantissa before decimal point or exponent
isInt := false
malformedOctal := false
if c != '.' {
if c != '0' {
// decimal or float
for isDigit(c) {
cp.WriteByte(byte(c))
c = l.getr()
}
if c == '.' {
goto casedot
}
if c == 'e' || c == 'E' || c == 'p' || c == 'P' {
goto caseep
}
if c == 'i' {
goto casei
} else {
// c == 0
cp.WriteByte('0')
c = l.getr()
if c == 'x' || c == 'X' {
isInt = true // must be int
cp.WriteByte(byte(c))
c = l.getr()
for isDigit(c) || 'a' <= c && c <= 'f' || 'A' <= c && c <= 'F' {
cp.WriteByte(byte(c))
c = l.getr()
}
if lexbuf.Len() == 2 {
Yyerror("malformed hex constant")
}
} else {
// decimal 0, octal, or float
for isDigit(c) {
if c > '7' {
malformedOctal = true
}
cp.WriteByte(byte(c))
c = l.getr()
}
}
goto ncu
}
}
// c == 0
cp.WriteByte('0')
c = l.getr()
if c == 'x' || c == 'X' {
// unless we have a hex number, parse fractional part or exponent, if any
if !isInt {
isInt = true // assume int unless proven otherwise
// fraction
if c == '.' {
isInt = false
cp.WriteByte('.')
c = l.getr()
for isDigit(c) {
cp.WriteByte(byte(c))
c = l.getr()
}
// Falling through to exponent parsing here permits invalid
// floating-point numbers with fractional mantissa and base-2
// (p or P) exponent. We don't care because base-2 exponents
// can only show up in machine-generated textual export data
// which will use correct formatting.
}
// exponent
// base-2 exponent (p or P) is only allowed in export data (see #9036)
// TODO(gri) Once we switch to binary import data, importpkg will
// always be nil in this function. Simplify the code accordingly.
if c == 'e' || c == 'E' || importpkg != nil && (c == 'p' || c == 'P') {
isInt = false
cp.WriteByte(byte(c))
c = l.getr()
for isDigit(c) || 'a' <= c && c <= 'f' || 'A' <= c && c <= 'F' {
if c == '+' || c == '-' {
cp.WriteByte(byte(c))
c = l.getr()
}
if lexbuf.Len() == 2 {
Yyerror("malformed hex constant")
if !isDigit(c) {
Yyerror("malformed floating point constant exponent")
}
if c == 'p' {
goto caseep
for isDigit(c) {
cp.WriteByte(byte(c))
c = l.getr()
}
goto ncu
}
if c == 'p' { // 0p begins floating point zero
goto caseep
}
// imaginary constant
if c == 'i' {
str = lexbuf.String()
x := new(Mpcplx)
Mpmovecflt(&x.Real, 0.0)
mpatoflt(&x.Imag, str)
if x.Imag.Val.IsInf() {
Yyerror("overflow in imaginary constant")
Mpmovecflt(&x.Imag, 0.0)
}
l.val.U = x
has8or9 := false
for isDigit(c) {
if c > '7' {
has8or9 = true
if Debug['x'] != 0 {
fmt.Printf("lex: imaginary literal\n")
}
cp.WriteByte(byte(c))
c = l.getr()
}
if c == '.' {
goto casedot
}
if c == 'e' || c == 'E' {
goto caseep
goto done
}
if c == 'i' {
goto casei
}
if has8or9 {
Yyerror("malformed octal constant")
}
goto ncu
}
casedot:
// fraction
// c == '.'
cp.WriteByte('.')
c = l.getr()
for isDigit(c) {
cp.WriteByte(byte(c))
c = l.getr()
}
if c == 'i' {
goto casei
}
if c != 'e' && c != 'E' {
goto caseout
}
// base-2-exponents (p or P) don't appear in numbers
// with fractions - ok to not test for 'p' or 'P'
// above
caseep:
// exponent
if importpkg == nil && (c == 'p' || c == 'P') {
// <mantissa>p<base-2-exponent> is allowed in .a/.o imports,
// but not in .go sources. See #9036.
Yyerror("malformed floating point constant")
}
cp.WriteByte(byte(c))
c = l.getr()
if c == '+' || c == '-' {
cp.WriteByte(byte(c))
c = l.getr()
}
if !isDigit(c) {
Yyerror("malformed floating point constant exponent")
}
for isDigit(c) {
cp.WriteByte(byte(c))
c = l.getr()
}
if c != 'i' {
goto caseout
}
casei:
// imaginary constant
cp = nil
str = lexbuf.String()
l.val.U = new(Mpcplx)
Mpmovecflt(&l.val.U.(*Mpcplx).Real, 0.0)
mpatoflt(&l.val.U.(*Mpcplx).Imag, str)
if l.val.U.(*Mpcplx).Imag.Val.IsInf() {
Yyerror("overflow in imaginary constant")
Mpmovecflt(&l.val.U.(*Mpcplx).Imag, 0.0)
}
if Debug['x'] != 0 {
fmt.Printf("lex: imaginary literal\n")
}
goto done
caseout:
cp = nil
l.ungetr(c)
str = lexbuf.String()
l.val.U = newMpflt()
mpatoflt(l.val.U.(*Mpflt), str)
if l.val.U.(*Mpflt).Val.IsInf() {
Yyerror("overflow in float constant")
Mpmovecflt(l.val.U.(*Mpflt), 0.0)
}
if isInt {
if malformedOctal {
Yyerror("malformed octal constant")
}
if Debug['x'] != 0 {
fmt.Printf("lex: floating literal\n")
}
goto done
str = lexbuf.String()
x := new(Mpint)
mpatofix(x, str)
if x.Ovf {
Yyerror("overflow in constant")
Mpmovecfix(x, 0)
}
l.val.U = x
ncu:
cp = nil
l.ungetr(c)
if Debug['x'] != 0 {
fmt.Printf("lex: integer literal\n")
}
str = lexbuf.String()
l.val.U = new(Mpint)
mpatofix(l.val.U.(*Mpint), str)
if l.val.U.(*Mpint).Ovf {
Yyerror("overflow in constant")
Mpmovecfix(l.val.U.(*Mpint), 0)
}
} else { // float
if Debug['x'] != 0 {
fmt.Printf("lex: integer literal\n")
str = lexbuf.String()
x := newMpflt()
mpatoflt(x, str)
if x.Val.IsInf() {
Yyerror("overflow in float constant")
Mpmovecflt(x, 0.0)
}
l.val.U = x
if Debug['x'] != 0 {
fmt.Printf("lex: floating literal\n")
}
}
done:
......
......@@ -4,7 +4,7 @@
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Expects to see error messages on "p" exponents.
// Expects to see error messages on 'p' exponents.
package main
......@@ -14,11 +14,19 @@ const (
x1 = 1.1 // float
x2 = 1e10 // float
x3 = 0x1e10 // integer (e is a hex digit)
x4 = 0x1p10 // ERROR "malformed floating point constant"
x5 = 1p10 // ERROR "malformed floating point constant"
x6 = 0p0 // ERROR "malformed floating point constant"
)
// 'p' exponents are invalid - the 'p' is not considered
// part of a floating-point number, but introduces a new
// (unexpected) name.
//
// Error recovery is not ideal and we use a new declaration
// each time for the parser to recover.
const x4 = 0x1p10 // ERROR "unexpected p10"
const x5 = 1p10 // ERROR "unexpected p10"
const x6 = 0p0 // ERROR "unexpected p0"
func main() {
fmt.Printf("%g %T\n", x1, x1)
fmt.Printf("%g %T\n", x2, x2)
......
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