freebsd-skq/usr.bin/make/cond.c
harti ec3ee28e7c Under certain conditions the condition parser would go one past end of
the string. Until now this caused no harm, because the buffer code used
to tack two NULs onto buffers. With the new, soon to come, parsing code
this isn't the case anymore in all cases, so fix this.
2005-05-25 16:06:14 +00:00

1222 lines
26 KiB
C

/*-
* Copyright (c) 1988, 1989, 1990, 1993
* The Regents of the University of California. All rights reserved.
* Copyright (c) 1988, 1989 by Adam de Boor
* Copyright (c) 1989 by Berkeley Softworks
* All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Adam de Boor.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @(#)cond.c 8.2 (Berkeley) 1/2/94
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* Functions to handle conditionals in a makefile.
*
* Interface:
* Cond_Eval Evaluate the conditional in the passed line.
*/
#include <ctype.h>
#include <string.h>
#include <stdlib.h>
#include "buf.h"
#include "cond.h"
#include "dir.h"
#include "globals.h"
#include "GNode.h"
#include "make.h"
#include "parse.h"
#include "str.h"
#include "targ.h"
#include "util.h"
#include "var.h"
/*
* The parsing of conditional expressions is based on this grammar:
* E -> F || E
* E -> F
* F -> T && F
* F -> T
* T -> defined(variable)
* T -> make(target)
* T -> exists(file)
* T -> empty(varspec)
* T -> target(name)
* T -> symbol
* T -> $(varspec) op value
* T -> $(varspec) == "string"
* T -> $(varspec) != "string"
* T -> ( E )
* T -> ! T
* op -> == | != | > | < | >= | <=
*
* 'symbol' is some other symbol to which the default function (condDefProc)
* is applied.
*
* Tokens are scanned from the 'condExpr' string. The scanner (CondToken)
* will return And for '&' and '&&', Or for '|' and '||', Not for '!',
* LParen for '(', RParen for ')' and will evaluate the other terminal
* symbols, using either the default function or the function given in the
* terminal, and return the result as either True or False.
*
* All Non-Terminal functions (CondE, CondF and CondT) return Err on error.
*/
typedef enum {
And,
Or,
Not,
True,
False,
LParen,
RParen,
EndOfFile,
None,
Err
} Token;
typedef Boolean CondProc(int, char *);
/*-
* Structures to handle elegantly the different forms of #if's. The
* last two fields are stored in condInvert and condDefProc, respectively.
*/
static void CondPushBack(Token);
static int CondGetArg(char **, char **, const char *, Boolean);
static CondProc CondDoDefined;
static CondProc CondDoMake;
static CondProc CondDoExists;
static CondProc CondDoTarget;
static char *CondCvtArg(char *, double *);
static Token CondToken(Boolean);
static Token CondT(Boolean);
static Token CondF(Boolean);
static Token CondE(Boolean);
static const struct If {
Boolean doNot; /* TRUE if default function should be negated */
CondProc *defProc; /* Default function to apply */
Boolean isElse; /* actually el<XXX> */
} ifs[] = {
[COND_IF] = { FALSE, CondDoDefined, FALSE },
[COND_IFDEF] = { FALSE, CondDoDefined, FALSE },
[COND_IFNDEF] = { TRUE, CondDoDefined, FALSE },
[COND_IFMAKE] = { FALSE, CondDoMake, FALSE },
[COND_IFNMAKE] = { TRUE, CondDoMake, FALSE },
[COND_ELIF] = { FALSE, CondDoDefined, TRUE },
[COND_ELIFDEF] = { FALSE, CondDoDefined, TRUE },
[COND_ELIFNDEF] = { TRUE, CondDoDefined, TRUE },
[COND_ELIFMAKE] = { FALSE, CondDoMake, TRUE },
[COND_ELIFNMAKE] = { TRUE, CondDoMake, TRUE },
};
static Boolean condInvert; /* Invert the default function */
static CondProc *condDefProc; /* default function to apply */
static char *condExpr; /* The expression to parse */
static Token condPushBack = None; /* Single push-back token in parsing */
#define MAXIF 30 /* greatest depth of #if'ing */
static Boolean condStack[MAXIF]; /* Stack of conditionals's values */
static int condLineno[MAXIF]; /* Line numbers of the opening .if */
static int condTop = MAXIF; /* Top-most conditional */
static int skipIfLevel = 0; /* Depth of skipped conditionals */
static int skipIfLineno[MAXIF]; /* Line numbers of skipped .ifs */
Boolean skipLine = FALSE; /* Whether the parse module is skipping
* lines */
/**
* CondPushBack
* Push back the most recent token read. We only need one level of
* this, so the thing is just stored in 'condPushback'.
*
* Side Effects:
* condPushback is overwritten.
*/
static void
CondPushBack(Token t)
{
condPushBack = t;
}
/**
* CondGetArg
* Find the argument of a built-in function. parens is set to TRUE
* if the arguments are bounded by parens.
*
* Results:
* The length of the argument and the address of the argument.
*
* Side Effects:
* The pointer is set to point to the closing parenthesis of the
* function call.
*/
static int
CondGetArg(char **linePtr, char **argPtr, const char *func, Boolean parens)
{
char *cp;
size_t argLen;
Buffer *buf;
cp = *linePtr;
if (parens) {
while (*cp != '(' && *cp != '\0') {
cp++;
}
if (*cp == '(') {
cp++;
}
}
if (*cp == '\0') {
/*
* No arguments whatsoever. Because 'make' and 'defined'
* aren't really "reserved words", we don't print a message.
* I think this is better than hitting the user with a warning
* message every time s/he uses the word 'make' or 'defined'
* at the beginning of a symbol...
*/
*argPtr = cp;
return (0);
}
while (*cp == ' ' || *cp == '\t') {
cp++;
}
/*
* Create a buffer for the argument and start it out at 16 characters
* long. Why 16? Why not?
*/
buf = Buf_Init(16);
while ((strchr(" \t)&|", *cp) == NULL) && (*cp != '\0')) {
if (*cp == '$') {
/*
* Parse the variable spec and install it as part of
* the argument if it's valid. We tell Var_Parse to
* complain on an undefined variable, so we don't do
* it too. Nor do we return an error, though perhaps
* we should...
*/
char *cp2;
size_t len = 0;
Boolean doFree;
cp2 = Var_Parse(cp, VAR_CMD, TRUE, &len, &doFree);
Buf_Append(buf, cp2);
if (doFree) {
free(cp2);
}
cp += len;
} else {
Buf_AddByte(buf, (Byte)*cp);
cp++;
}
}
Buf_AddByte(buf, (Byte)'\0');
*argPtr = (char *)Buf_GetAll(buf, &argLen);
Buf_Destroy(buf, FALSE);
while (*cp == ' ' || *cp == '\t') {
cp++;
}
if (parens && *cp != ')') {
Parse_Error(PARSE_WARNING,
"Missing closing parenthesis for %s()", func);
return (0);
} else if (parens) {
/*
* Advance pointer past close parenthesis.
*/
cp++;
}
*linePtr = cp;
return (argLen);
}
/**
* CondDoDefined
* Handle the 'defined' function for conditionals.
*
* Results:
* TRUE if the given variable is defined.
*/
static Boolean
CondDoDefined(int argLen, char *arg)
{
char savec = arg[argLen];
Boolean result;
arg[argLen] = '\0';
if (Var_Value(arg, VAR_CMD) != NULL) {
result = TRUE;
} else {
result = FALSE;
}
arg[argLen] = savec;
return (result);
}
/**
* CondDoMake
* Handle the 'make' function for conditionals.
*
* Results:
* TRUE if the given target is being made.
*/
static Boolean
CondDoMake(int argLen, char *arg)
{
char savec = arg[argLen];
Boolean result;
const LstNode *ln;
arg[argLen] = '\0';
result = FALSE;
LST_FOREACH(ln, &create) {
if (Str_Match(Lst_Datum(ln), arg)) {
result = TRUE;
break;
}
}
arg[argLen] = savec;
return (result);
}
/**
* CondDoExists
* See if the given file exists.
*
* Results:
* TRUE if the file exists and FALSE if it does not.
*/
static Boolean
CondDoExists(int argLen, char *arg)
{
char savec = arg[argLen];
Boolean result;
char *path;
arg[argLen] = '\0';
path = Path_FindFile(arg, &dirSearchPath);
if (path != NULL) {
result = TRUE;
free(path);
} else {
result = FALSE;
}
arg[argLen] = savec;
return (result);
}
/**
* CondDoTarget
* See if the given node exists and is an actual target.
*
* Results:
* TRUE if the node exists as a target and FALSE if it does not.
*/
static Boolean
CondDoTarget(int argLen, char *arg)
{
char savec = arg[argLen];
Boolean result;
GNode *gn;
arg[argLen] = '\0';
gn = Targ_FindNode(arg, TARG_NOCREATE);
if ((gn != NULL) && !OP_NOP(gn->type)) {
result = TRUE;
} else {
result = FALSE;
}
arg[argLen] = savec;
return (result);
}
/**
* CondCvtArg
* Convert the given number into a double. If the number begins
* with 0x, it is interpreted as a hexadecimal integer
* and converted to a double from there. All other strings just have
* strtod called on them.
*
* Results:
* Sets 'value' to double value of string.
* Returns address of the first character after the last valid
* character of the converted number.
*
* Side Effects:
* Can change 'value' even if string is not a valid number.
*/
static char *
CondCvtArg(char *str, double *value)
{
if ((*str == '0') && (str[1] == 'x')) {
long i;
for (str += 2, i = 0; ; str++) {
int x;
if (isdigit((unsigned char)*str))
x = *str - '0';
else if (isxdigit((unsigned char)*str))
x = 10 + *str -
isupper((unsigned char)*str) ? 'A' : 'a';
else {
*value = (double)i;
return (str);
}
i = (i << 4) + x;
}
} else {
char *eptr;
*value = strtod(str, &eptr);
return (eptr);
}
}
/**
* CondToken
* Return the next token from the input.
*
* Results:
* A Token for the next lexical token in the stream.
*
* Side Effects:
* condPushback will be set back to None if it is used.
*/
static Token
CondToken(Boolean doEval)
{
Token t;
if (condPushBack != None) {
t = condPushBack;
condPushBack = None;
return (t);
}
while (*condExpr == ' ' || *condExpr == '\t') {
condExpr++;
}
switch (*condExpr) {
case '(':
t = LParen;
condExpr++;
break;
case ')':
t = RParen;
condExpr++;
break;
case '|':
if (condExpr[1] == '|') {
condExpr++;
}
condExpr++;
t = Or;
break;
case '&':
if (condExpr[1] == '&') {
condExpr++;
}
condExpr++;
t = And;
break;
case '!':
t = Not;
condExpr++;
break;
case '\n':
case '\0':
t = EndOfFile;
break;
case '$': {
char *lhs;
const char *op;
char *rhs;
char zero[] = "0";
size_t varSpecLen = 0;
Boolean doFree;
/*
* Parse the variable spec and skip over it, saving its
* value in lhs.
*/
t = Err;
lhs = Var_Parse(condExpr, VAR_CMD, doEval,
&varSpecLen, &doFree);
if (lhs == var_Error) {
/*
* Even if !doEval, we still report syntax
* errors, which is what getting var_Error
* back with !doEval means.
*/
return (Err);
}
condExpr += varSpecLen;
if (!isspace((unsigned char)*condExpr) &&
strchr("!=><", *condExpr) == NULL) {
Buffer *buf;
buf = Buf_Init(0);
Buf_Append(buf, lhs);
if (doFree)
free(lhs);
for (;*condExpr &&
!isspace((unsigned char)*condExpr);
condExpr++)
Buf_AddByte(buf, (Byte)*condExpr);
Buf_AddByte(buf, (Byte)'\0');
lhs = (char *)Buf_GetAll(buf, &varSpecLen);
Buf_Destroy(buf, FALSE);
doFree = TRUE;
}
/*
* Skip whitespace to get to the operator
*/
while (isspace((unsigned char)*condExpr))
condExpr++;
/*
* Make sure the operator is a valid one. If it isn't a
* known relational operator, pretend we got a
* != 0 comparison.
*/
op = condExpr;
switch (*condExpr) {
case '!':
case '=':
case '<':
case '>':
if (condExpr[1] == '=') {
condExpr += 2;
} else {
condExpr += 1;
}
while (isspace((unsigned char)*condExpr)) {
condExpr++;
}
if (*condExpr == '\0') {
Parse_Error(PARSE_WARNING,
"Missing right-hand-side of operator");
goto error;
}
rhs = condExpr;
break;
default:
op = "!=";
rhs = zero;
break;
}
if (*rhs == '"') {
/*
* Doing a string comparison. Only allow == and
* != for * operators.
*/
char *string;
char *cp, *cp2;
int qt;
Buffer *buf;
do_string_compare:
if (((*op != '!') && (*op != '=')) ||
(op[1] != '=')) {
Parse_Error(PARSE_WARNING,
"String comparison operator should "
"be either == or !=");
goto error;
}
buf = Buf_Init(0);
qt = *rhs == '"' ? 1 : 0;
for (cp = &rhs[qt];
((qt && (*cp != '"')) ||
(!qt && strchr(" \t)", *cp) == NULL)) &&
(*cp != '\0'); cp++) {
if ((*cp == '\\') && (cp[1] != '\0')) {
/*
* Backslash escapes things --
* skip over next character, * if it exists.
*/
cp++;
Buf_AddByte(buf, (Byte)*cp);
} else if (*cp == '$') {
size_t len = 0;
Boolean freeIt;
cp2 = Var_Parse(cp, VAR_CMD,
doEval, &len, &freeIt);
if (cp2 != var_Error) {
Buf_Append(buf, cp2);
if (freeIt) {
free(cp2);
}
cp += len - 1;
} else {
Buf_AddByte(buf,
(Byte)*cp);
}
} else {
Buf_AddByte(buf, (Byte)*cp);
}
}
string = Buf_Peel(buf);
DEBUGF(COND, ("lhs = \"%s\", rhs = \"%s\", "
"op = %.2s\n", lhs, string, op));
/*
* Null-terminate rhs and perform the
* comparison. t is set to the result.
*/
if (*op == '=') {
t = strcmp(lhs, string) ? False : True;
} else {
t = strcmp(lhs, string) ? True : False;
}
free(string);
if (rhs == condExpr) {
if (*cp == '\0' || (!qt && *cp == ')'))
condExpr = cp;
else
condExpr = cp + 1;
}
} else {
/*
* rhs is either a float or an integer.
* Convert both the lhs and the rhs to a
* double and compare the two.
*/
double left, right;
char *string;
if (*CondCvtArg(lhs, &left) != '\0')
goto do_string_compare;
if (*rhs == '$') {
size_t len = 0;
Boolean freeIt;
string = Var_Parse(rhs, VAR_CMD, doEval,
&len, &freeIt);
if (string == var_Error) {
right = 0.0;
} else {
if (*CondCvtArg(string,
&right) != '\0') {
if (freeIt)
free(string);
goto do_string_compare;
}
if (freeIt)
free(string);
if (rhs == condExpr)
condExpr += len;
}
} else {
char *c = CondCvtArg(rhs, &right);
if (c == rhs)
goto do_string_compare;
if (rhs == condExpr) {
/*
* Skip over the right-hand side
*/
condExpr = c;
}
}
DEBUGF(COND, ("left = %f, right = %f, "
"op = %.2s\n", left, right, op));
switch (op[0]) {
case '!':
if (op[1] != '=') {
Parse_Error(PARSE_WARNING,
"Unknown operator");
goto error;
}
t = (left != right ? True : False);
break;
case '=':
if (op[1] != '=') {
Parse_Error(PARSE_WARNING,
"Unknown operator");
goto error;
}
t = (left == right ? True : False);
break;
case '<':
if (op[1] == '=') {
t = (left <= right?True:False);
} else {
t = (left < right?True:False);
}
break;
case '>':
if (op[1] == '=') {
t = (left >= right?True:False);
} else {
t = (left > right?True:False);
}
break;
default:
break;
}
}
error:
if (doFree)
free(lhs);
break;
}
default: {
CondProc *evalProc;
Boolean invert = FALSE;
char *arg;
int arglen;
if (strncmp(condExpr, "defined", 7) == 0) {
/*
* Use CondDoDefined to evaluate the argument
* and CondGetArg to extract the argument from
* the 'function call'.
*/
evalProc = CondDoDefined;
condExpr += 7;
arglen = CondGetArg(&condExpr, &arg,
"defined", TRUE);
if (arglen == 0) {
condExpr -= 7;
goto use_default;
}
} else if (strncmp(condExpr, "make", 4) == 0) {
/*
* Use CondDoMake to evaluate the argument and
* CondGetArg to extract the argument from the
* 'function call'.
*/
evalProc = CondDoMake;
condExpr += 4;
arglen = CondGetArg(&condExpr, &arg,
"make", TRUE);
if (arglen == 0) {
condExpr -= 4;
goto use_default;
}
} else if (strncmp(condExpr, "exists", 6) == 0) {
/*
* Use CondDoExists to evaluate the argument and
* CondGetArg to extract the argument from the
* 'function call'.
*/
evalProc = CondDoExists;
condExpr += 6;
arglen = CondGetArg(&condExpr, &arg,
"exists", TRUE);
if (arglen == 0) {
condExpr -= 6;
goto use_default;
}
} else if (strncmp(condExpr, "empty", 5) == 0) {
/*
* Use Var_Parse to parse the spec in parens and
* return True if the resulting string is empty.
*/
size_t length;
Boolean doFree;
char *val;
condExpr += 5;
for (arglen = 0;
condExpr[arglen] != '(' &&
condExpr[arglen] != '\0'; arglen += 1)
continue;
if (condExpr[arglen] != '\0') {
length = 0;
val = Var_Parse(&condExpr[arglen - 1],
VAR_CMD, FALSE, &length, &doFree);
if (val == var_Error) {
t = Err;
} else {
/*
* A variable is empty when it
* just contains spaces...
* 4/15/92, christos
*/
char *p;
for (p = val;
*p &&
isspace((unsigned char)*p);
p++)
continue;
t = (*p == '\0') ? True : False;
}
if (doFree) {
free(val);
}
/*
* Advance condExpr to beyond the
* closing ). Note that we subtract
* one from arglen + length b/c length
* is calculated from
* condExpr[arglen - 1].
*/
condExpr += arglen + length - 1;
} else {
condExpr -= 5;
goto use_default;
}
break;
} else if (strncmp(condExpr, "target", 6) == 0) {
/*
* Use CondDoTarget to evaluate the argument and
* CondGetArg to extract the argument from the
* 'function call'.
*/
evalProc = CondDoTarget;
condExpr += 6;
arglen = CondGetArg(&condExpr, &arg,
"target", TRUE);
if (arglen == 0) {
condExpr -= 6;
goto use_default;
}
} else {
/*
* The symbol is itself the argument to the
* default function. We advance condExpr to
* the end of the symbol by hand (the next
* whitespace, closing paren or binary operator)
* and set to invert the evaluation
* function if condInvert is TRUE.
*/
use_default:
invert = condInvert;
evalProc = condDefProc;
arglen = CondGetArg(&condExpr, &arg, "", FALSE);
}
/*
* Evaluate the argument using the set function. If
* invert is TRUE, we invert the sense of the function.
*/
t = (!doEval || (* evalProc) (arglen, arg) ?
(invert ? False : True) :
(invert ? True : False));
free(arg);
break;
}
}
return (t);
}
/**
* CondT
* Parse a single term in the expression. This consists of a terminal
* symbol or Not and a terminal symbol (not including the binary
* operators):
* T -> defined(variable) | make(target) | exists(file) | symbol
* T -> ! T | ( E )
*
* Results:
* True, False or Err.
*
* Side Effects:
* Tokens are consumed.
*/
static Token
CondT(Boolean doEval)
{
Token t;
t = CondToken(doEval);
if (t == EndOfFile) {
/*
* If we reached the end of the expression, the expression
* is malformed...
*/
t = Err;
} else if (t == LParen) {
/*
* T -> ( E )
*/
t = CondE(doEval);
if (t != Err) {
if (CondToken(doEval) != RParen) {
t = Err;
}
}
} else if (t == Not) {
t = CondT(doEval);
if (t == True) {
t = False;
} else if (t == False) {
t = True;
}
}
return (t);
}
/**
* CondF --
* Parse a conjunctive factor (nice name, wot?)
* F -> T && F | T
*
* Results:
* True, False or Err
*
* Side Effects:
* Tokens are consumed.
*/
static Token
CondF(Boolean doEval)
{
Token l, o;
l = CondT(doEval);
if (l != Err) {
o = CondToken(doEval);
if (o == And) {
/*
* F -> T && F
*
* If T is False, the whole thing will be False, but
* we have to parse the r.h.s. anyway (to throw it
* away). If T is True, the result is the r.h.s.,
* be it an Err or no.
*/
if (l == True) {
l = CondF(doEval);
} else {
CondF(FALSE);
}
} else {
/*
* F -> T
*/
CondPushBack(o);
}
}
return (l);
}
/**
* CondE --
* Main expression production.
* E -> F || E | F
*
* Results:
* True, False or Err.
*
* Side Effects:
* Tokens are, of course, consumed.
*/
static Token
CondE(Boolean doEval)
{
Token l, o;
l = CondF(doEval);
if (l != Err) {
o = CondToken(doEval);
if (o == Or) {
/*
* E -> F || E
*
* A similar thing occurs for ||, except that here we
* make sure the l.h.s. is False before we bother to
* evaluate the r.h.s. Once again, if l is False, the
* result is the r.h.s. and once again if l is True,
* we parse the r.h.s. to throw it away.
*/
if (l == False) {
l = CondE(doEval);
} else {
CondE(FALSE);
}
} else {
/*
* E -> F
*/
CondPushBack(o);
}
}
return (l);
}
/**
* Cond_If
* Handle .if<X> and .elif<X> directives.
* This function is called even when we're skipping.
*/
void
Cond_If(char *line, int code, int lineno)
{
const struct If *ifp;
Boolean value;
ifp = &ifs[code];
if (ifp->isElse) {
if (condTop == MAXIF) {
Parse_Error(PARSE_FATAL, "if-less elif");
return;
}
if (skipIfLevel != 0) {
/*
* If skipping this conditional, just ignore
* the whole thing. If we don't, the user
* might be employing a variable that's
* undefined, for which there's an enclosing
* ifdef that we're skipping...
*/
skipIfLineno[skipIfLevel - 1] = lineno;
return;
}
} else if (skipLine) {
/*
* Don't even try to evaluate a conditional that's
* not an else if we're skipping things...
*/
skipIfLineno[skipIfLevel] = lineno;
skipIfLevel += 1;
return;
}
/*
* Initialize file-global variables for parsing
*/
condDefProc = ifp->defProc;
condInvert = ifp->doNot;
while (*line == ' ' || *line == '\t') {
line++;
}
condExpr = line;
condPushBack = None;
switch (CondE(TRUE)) {
case True:
if (CondToken(TRUE) != EndOfFile)
goto err;
value = TRUE;
break;
case False:
if (CondToken(TRUE) != EndOfFile)
goto err;
value = FALSE;
break;
case Err:
err: Parse_Error(PARSE_FATAL, "Malformed conditional (%s)", line);
return;
default:
abort();
}
if (!ifp->isElse) {
/* push this value */
condTop -= 1;
} else if (skipIfLevel != 0 || condStack[condTop]) {
/*
* If this is an else-type conditional, it should only take
* effect if its corresponding if was evaluated and FALSE.
* If its if was TRUE or skipped, we return COND_SKIP (and
* start skipping in case we weren't already), leaving the
* stack unmolested so later elif's don't screw up...
*/
skipLine = TRUE;
return;
}
if (condTop < 0) {
/*
* This is the one case where we can definitely proclaim a fatal
* error. If we don't, we're hosed.
*/
Parse_Error(PARSE_FATAL, "Too many nested if's. %d max.",MAXIF);
return;
}
/* push */
condStack[condTop] = value;
condLineno[condTop] = lineno;
skipLine = !value;
}
/**
* Cond_Else
* Handle .else statement.
*/
void
Cond_Else(char *line __unused, int code __unused, int lineno __unused)
{
while (isspace((u_char)*line))
line++;
if (*line != '\0' && (warn_flags & WARN_DIRSYNTAX)) {
Parse_Error(PARSE_WARNING, "junk after .else ignored '%s'",
line);
}
if (condTop == MAXIF) {
Parse_Error(PARSE_FATAL, "if-less else");
return;
}
if (skipIfLevel != 0)
return;
if (skipIfLevel != 0 || condStack[condTop]) {
/*
* An else should only take effect if its corresponding if was
* evaluated and FALSE.
* If its if was TRUE or skipped, we return COND_SKIP (and
* start skipping in case we weren't already), leaving the
* stack unmolested so later elif's don't screw up...
* XXX How does this work with two .else's?
*/
skipLine = TRUE;
return;
}
/* inverse value */
condStack[condTop] = !condStack[condTop];
skipLine = !condStack[condTop];
}
/**
* Cond_Endif
* Handle .endif statement.
*/
void
Cond_Endif(char *line __unused, int code __unused, int lineno __unused)
{
while (isspace((u_char)*line))
line++;
if (*line != '\0' && (warn_flags & WARN_DIRSYNTAX)) {
Parse_Error(PARSE_WARNING, "junk after .endif ignored '%s'",
line);
}
/*
* End of a conditional section. If skipIfLevel is non-zero,
* that conditional was skipped, so lines following it should
* also be skipped. Hence, we return COND_SKIP. Otherwise,
* the conditional was read so succeeding lines should be
* parsed (think about it...) so we return COND_PARSE, unless
* this endif isn't paired with a decent if.
*/
if (skipIfLevel != 0) {
skipIfLevel -= 1;
return;
}
if (condTop == MAXIF) {
Parse_Error(PARSE_FATAL, "if-less endif");
return;
}
/* pop */
skipLine = FALSE;
condTop += 1;
}
/**
* Cond_End
* Make sure everything's clean at the end of a makefile.
*
* Side Effects:
* Parse_Error will be called if open conditionals are around.
*/
void
Cond_End(void)
{
int level;
if (condTop != MAXIF) {
Parse_Error(PARSE_FATAL, "%d open conditional%s:",
MAXIF - condTop + skipIfLevel,
MAXIF - condTop + skipIfLevel== 1 ? "" : "s");
for (level = skipIfLevel; level > 0; level--)
Parse_Error(PARSE_FATAL, "\t%*sat line %d (skipped)",
MAXIF - condTop + level + 1, "",
skipIfLineno[level - 1]);
for (level = condTop; level < MAXIF; level++)
Parse_Error(PARSE_FATAL, "\t%*sat line %d "
"(evaluated to %s)", MAXIF - level + skipIfLevel,
"", condLineno[level],
condStack[level] ? "true" : "false");
}
condTop = MAXIF;
}