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chromium / external / dynamorio / f750c8d76d865ffbf0493e931ecb31bf6fff74f6 / . / core / io.c
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/* **********************************************************
* Copyright (c) 2011-2014 Google, Inc. All rights reserved.
* Copyright (c) 2002-2010 VMware, Inc. All rights reserved.
* **********************************************************/
/*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* * Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* * 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.
*
* * Neither the name of VMware, Inc. 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 COPYRIGHT HOLDERS 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 VMWARE, INC. 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.
*/
/* Copyright (c) 2003-2007 Determina Corp. */
/* Copyright (c) 2002-2003 Massachusetts Institute of Technology */
/*
* io.c - routines for i/o to avoid library dependencies
*/
/* FIXME: failure modes should be more graceful than failing asserts in most places */
#include "globals.h"
#include <string.h>
#include <stdarg.h> /* for varargs */
#ifdef UNIX
# ifdef MACOS
/* request extern functions to avoid conflicts with our own tolower() */
# define _EXTERNALIZE_CTYPE_INLINES_TOP_
# define _EXTERNALIZE_CTYPE_INLINES_
# endif
# include <wchar.h>
#endif
#ifdef NOT_DYNAMORIO_CORE_PROPER
/* drpreinject doesn't link utils.c. We fail gracefully without the assertion,
* so just define it away.
*/
# undef CLIENT_ASSERT
# define CLIENT_ASSERT(cond, msg)
# undef ASSERT
# define ASSERT(x)
#endif /* NOT_DYNAMORIO_CORE_PROPER */
#define VA_ARG_CHAR2INT
#define BUF_SIZE 64
#ifdef UNIX
const static double pos_inf = 1.0/0.0;
const static double neg_inf = -1.0/0.0;
#else
/* Windows says "error C2099: initializer is not a constant", or
* "error C2124: divide or mod by zero", for the above.
*/
# pragma warning(disable : 4723) /* warning C4723: potential divide by 0 */
const static double zerof = 0.0;
# define pos_inf (1.0/zerof)
# define neg_inf (-1.0/zerof)
#endif
/* assumes that d > 0 */
long /* exported to utils.c */
double2int_trunc(double d)
{
long i = (long)d;
double id = (double)i;
/* when building with /QIfist casting rounds instead of truncating (i#763) */
if (id > d)
return i-1;
else
return i;
}
/* assumes that d > 0 */
static long
double2int(double d)
{
long i = (long)d;
double id = (double)i;
/* when building with /QIfist casting rounds instead of truncating (i#763) */
if (id < d && d - id >= 0.5)
return i+1;
else if (id > d && id - d >= 0.5)
return i-1;
else
return i;
}
#ifdef WINDOWS
/*****************************************************************************
* UTF-8 <-> UTF-16
*
* Windows-only b/c it assumes wide chars are 2 bytes (primarily just when
* examining input values).
*/
/* Returns the number of elements written if all of the characters of src,
* or if max_chars from src, were successfully encoded into dst.
* Passing max_chars==0 means no limit.
* If there is room, appends a null terminator (which is not included in the
* return value). (This is to match our snprintf semantics.)
* Returns -1 on an error, such as src not being valid UTF-8, or on encountering
* a character that cannot be encoded with UTF-16.
* In *written, returns the number of unicode characters written to dst including
* the terminating null.
* Will not write a partial multi-byte character.
* Does not use a byte-order mark.
*
* XXX: instead of bailing and returning -1, should we use a particular encoding
* for each invalid sequence? MultiByteToWideChar uses U+FFFD.
*/
static ssize_t
utf8_to_utf16(wchar_t *dst, size_t dst_sz/*elements*/, const char *src,
size_t max_chars, size_t *written/*unicode chars*/)
{
/* Be sure to use unsigned for proper comparisons below */
const unsigned char *s = (const unsigned char *) src;
wchar_t *d = dst;
size_t chars = 0;
while (dst_sz > 0 && *s != '\0' && (max_chars == 0 || chars < max_chars)) {
if (*s <= 0x7f) {
/* through U+007F: 7 bits: bottom 7 of 1st byte */
*d = (wchar_t) *s;
chars++;
} else if (*s >> 5 == 0x6) {
/* through U+07FF: 11 bits: bottom 5 of 1st and bottom 6 of 2nd */
wchar_t first = (((wchar_t)*s) & 0x1f) << 6;
s++;
if (*s >> 6 != 0x2)
return -1; /* malformed UTF-8 */
*d = first | (*s & 0x3f);
chars++;
} else if (*s >> 4 == 0xe) {
/* through U+FFFF: 16 bits: bottom 4 of 1st, bottom 6 of 2nd + 3rd */
wchar_t first = (((wchar_t)*s) & 0xf) << 12;
s++;
if (*s >> 6 != 0x2)
return -1; /* malformed UTF-8 */
first |= ((((wchar_t)*s) & 0x3f) << 6);
s++;
if (*s >> 6 != 0x2)
return -1; /* malformed UTF-8 */
*d = first | (*s & 0x3f);
chars++;
} else if (*s >> 3 == 0x1e) {
/* through U+1FFFFF: 21 bits: bottom 3 of 1st, bottom 6 of 2nd-4th */
uint cp = (((wchar_t)*s) & 0x7) << 18;
s++;
if (*s >> 6 != 0x2)
return -1; /* malformed UTF-8 */
cp |= ((((wchar_t)*s) & 0x3f) << 12);
s++;
if (*s >> 6 != 0x2)
return -1; /* malformed UTF-8 */
cp |= ((((wchar_t)*s) & 0x3f) << 6);
s++;
if (*s >> 6 != 0x2)
return -1; /* malformed UTF-8 */
cp |= (((wchar_t)*s) & 0x3f);
/* check limit */
if (cp > 0x10ffff)
return -1; /* not encodable with UTF-16 */
/* encode using surrogate pairs */
if ((size_t)(d + 1 - dst) >= dst_sz) /* no partial chars */
break;
*d = (wchar_t) (((cp - 0x10000) >> 10) + 0xd800);
d++;
*d = (wchar_t) (((cp - 0x10000) & 0x3ff) + 0xdc00);
chars++;
} else if (*s >> 2 == 0x3e) {
/* through U+3FFFFFF: 26 bits: bottom 2 of 1st, bottom 6 of 2nd-5th */
return -1; /* not encodable with UTF-16 */
} else if (*s >> 1 == 0x7e) {
/* through U+7FFFFFFF: 31 bits: bottom 1 of 1st, bottom 6 of 2nd-6th */
return -1; /* not encodable with UTF-16 */
}
d++;
if ((size_t)(d - dst) >= dst_sz)
break;
s++;
}
if ((size_t)(d - dst) < dst_sz)
*d = L'\0';
if (written != NULL)
*written = chars;
return d - dst;
}
/* Returns the number of elements written if all of the characters of src,
* or if max_chars from src, were successfully encoded into dst.
* Passing max_chars==0 means no limit.
* If there is room, appends a null terminator (which is not included in the
* return value). (This is to match our snprintf semantics.)
* Returns -1 on an error, such as src not being valid UTF-16.
* In *written, returns the number of unicode characters written to dst including
* the terminating null.
* Will not write a partial multi-byte character.
* Does not handle a byte-order mark.
* If dst==NULL, returns the number of elements required to encode max_chars
* (or all if max_chars==0) from src.
*/
static ssize_t
utf16_to_utf8(char *dst, size_t dst_sz/*elements*/, const wchar_t *src,
size_t max_chars, size_t *written/*unicode chars*/)
{
const wchar_t *s = src;
char *d = dst;
ssize_t bytes = 0;
size_t chars = 0;
while ((dst == NULL || dst_sz > 0) && *s != L'\0' &&
(max_chars == 0 || chars < max_chars)) {
if (*s <= 0x7f) {
if (dst != NULL)
*d = (char) *s;
else
bytes++;
chars++;
} else if (*s <= 0x7ff) {
/* 2-byte encoding: 0b110xxxxx 0b10xxxxxx */
if (dst != NULL) {
if ((size_t)(d + 1 - dst) >= dst_sz) /* no partial chars */
break;
*d = (char) (0xc0 | (*s >> 6));
d++;
*d = (char) (0x80 | (*s & 0x3f));
} else
bytes += 2;
chars++;
} else if (*s >= 0xd800 && *s <= 0xdfff) {
/* surrogate pairs */
uint cp = (*s - 0xd800) << 10;
s++;
if (dst != NULL) {
if (*s == L'\0' || *s < 0xdc00 || *s > 0xdfff)
return -1; /* malformed UTF-16 */
cp |= (*s - 0xdc00);
cp += 0x10000;
/* 4-byte encoding: 0b1110xxxx 0b10xxxxxx 0b10xxxxxx 0b10xxxxxx */
if ((size_t)(d + 3 - dst) >= dst_sz) /* no partial chars */
break;
*d = (char) (0xf0 | (cp >> 18));
d++;
*d = (char) (0x80 | ((cp >> 12) & 0x3f));
d++;
*d = (char) (0x80 | ((cp >> 6) & 0x3f));
d++;
*d = (char) (0x80 | (cp & 0x3f));
} else
bytes += 4;
chars++;
} else {
/* 3-byte encoding: 0b1110xxxx 0b10xxxxxx 0b10xxxxxx */
if (dst != NULL) {
if ((size_t)(d + 2 - dst) >= dst_sz) /* no partial chars */
break;
*d = (char) (0xe0 | (*s >> 12));
d++;
*d = (char) (0x80 | ((*s >> 6) & 0x3f));
d++;
*d = (char) (0x80 | (*s & 0x3f));
} else
bytes += 3;
chars++;
}
if (dst != NULL) {
d++;
if ((size_t)(d - dst) >= dst_sz)
break;
}
s++;
}
if (dst != NULL) {
if ((size_t)(d - dst) < dst_sz)
*d = L'\0';
}
if (written != NULL)
*written = chars;
if (dst != NULL)
return d - dst;
else
return bytes;
}
ssize_t
utf16_to_utf8_size(const wchar_t *src, size_t max_chars, size_t *written/*unicode chars*/)
{
return utf16_to_utf8(NULL, 0, src, max_chars, NULL);
}
#endif
/*****************************************************************************
* snprintf
*/
/* we generate from a template to get wide and narrow versions */
#undef IOX_WIDE_CHAR
#include "iox.h"
#define IOX_WIDE_CHAR
#include "iox.h"
/*****************************************************************************
* Stand alone sscanf implementation.
*/
typedef enum _specifier_t {
SPEC_INT,
SPEC_CHAR,
SPEC_STRING
} specifer_t;
typedef enum _int_sz_t {
SZ_SHORT,
SZ_INT,
SZ_LONG,
SZ_LONGLONG,
#if defined(X64) && defined(WINDOWS)
SZ_PTR = SZ_LONGLONG
#else
SZ_PTR = SZ_LONG
#endif
} int_sz_t;
/* The isspace() from ctype.h is actually a macro that calls __ctype_b_loc(),
* which tries to look something up in the library TLS. This doesn't work
* without the private loader, so we roll our own isspace().
*/
static bool inline
our_isspace(int c)
{
return (c == ' ' || c == '\f' || c == '\n' || c == '\r' || c == '\t' ||
c == '\v');
}
const char *
parse_int(const char *sp, uint64 *res_out, uint base, uint width, bool is_signed)
{
bool negative = false;
uint64 res = 0;
uint i; /* Use an index rather than pointer to compare with width. */
/* Check for invalid base. */
if (base > 36 || base == 1) {
*res_out = (uint64) -1LL;
return NULL;
}
/* Check for negative sign if signed. */
if (is_signed) {
if (*sp == '-') {
negative = true;
sp++;
}
}
/* Ignore leading +. */
if (!negative && *sp == '+')
sp++;
/* 0x prefix for hex is optional. */
if ((base == 0 || base == 16) && sp[0] == '0' && sp[1] == 'x') {
sp += 2;
if (base == 0)
base = 16;
}
/* Leading '0' with 0 base means octal. */
if (base == 0 && *sp == '0') {
base = 8;
sp++;
}
/* If we didn't find leading '0' or "0x", base is 10. */
if (base == 0)
base = 10;
/* XXX: For efficiency we could do a couple things:
* - Specialize the loop on base
* - Use a lookup table
*/
for (i = 0; width == 0 || i < width; i++) {
uint d = sp[i];
if (d >= '0' && d <= '9') {
d -= '0';
} else if (d >= 'a' && d <= 'z') {
d = d - 'a' + 10;
} else if (d >= 'A' && d <= 'Z') {
d = d - 'A' + 10;
} else {
break; /* Non-digit character. Could be \0. */
}
/* Stop the parse here if this digit was not valid for the current base,
* (e.g. 9 for octal of g for hex).
*/
if (d >= base)
break;
/* FIXME: Check for overflow. */
/* XXX: int64 multiply is inefficient on 32-bit. */
res = res * base + d;
}
/* No digits found, return failure. */
if (i == 0)
return NULL;
if (negative)
res = -(int64)res;
*res_out = res;
return sp + i;
}
/* Stand alone implementation of sscanf. We used to call libc's vsscanf while
* trying to isolate errno (i#238), but these days sscanf calls malloc (i#762).
* Therefore, we roll our own.
*/
int
our_vsscanf(const char *str, const char *fmt, va_list ap)
{
int num_parsed = 0;
const char *fp = fmt;
const char *sp = str;
int c;
while (*fp != '\0' && *sp != '\0') {
specifer_t spec = SPEC_INT;
int_sz_t int_size = SZ_INT;
uint base = 10;
bool is_signed = false;
bool is_ignored = false;
uint width = 0;
/* Handle literal characters and spaces up front. */
c = *fp++;
if (our_isspace(c)) {
/* Space means consume any number of spaces. */
while (our_isspace(*sp)) {
sp++;
}
continue;
} else if (c != '%') {
/* Literal, so check mismatch. */
if (c != *sp)
return num_parsed;
sp++;
continue;
}
/* Parse the format specifier. */
ASSERT(c == '%');
while (true) {
c = *fp++;
switch (c) {
/* Modifiers, should all continue the loop. */
case 'l':
if (int_size == SZ_INT) {
int_size = SZ_LONG;
} else if (int_size == SZ_LONG) {
int_size = SZ_LONGLONG;
} else {
CLIENT_ASSERT(int_size != SZ_SHORT,
"dr_sscanf: can't use %hl modifier");
CLIENT_ASSERT(int_size != SZ_LONGLONG,
"dr_sscanf: too many longs (%lll)");
return num_parsed; /* error */
}
break;
case 'h':
CLIENT_ASSERT(int_size == SZ_INT,
"dr_sscanf: can't use %lh modifier");
int_size = SZ_SHORT;
continue;
case '*':
is_ignored = true;
continue;
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
/* We honor the specified width for strings to prevent buffer
* overruns, but we don't honor it for integers. Honoring the
* width for integers would require our own integer parser.
*/
width = width * 10 + c - '0';
continue;
case 'I':
/* We support I32 and I64 from Windows sscanf because DR exports
* macros that use them.
*/
if (strncmp("32", fp, 2) == 0) {
int_size = SZ_INT;
} else if (strncmp("64", fp, 2) == 0) {
int_size = SZ_LONGLONG;
} else {
CLIENT_ASSERT(false,
"dr_sscanf: unsupported I<width> modifier");
return num_parsed;
}
break;
/* XXX: Modifiers we could add support for:
* - j, z, t: C99 modifiers for intmax_t, size_t, and ptrdiff_t.
* - [] scan sets: These are complicated and better to avoid.
* - .*: For dynamically sized strings. Not part of C scanf.
* - n$: Store the result into the nth pointer arg after fmt.
*/
/* Specifiers, should all break the loop. */
case 'u':
spec = SPEC_INT;
is_signed = false;
goto spec_done;
case 'd':
spec = SPEC_INT;
is_signed = true;
goto spec_done;
case 'x':
spec = SPEC_INT;
is_signed = false;
base = 16;
goto spec_done;
case 'p':
int_size = SZ_PTR;
spec = SPEC_INT;
is_signed = false;
base = 16;
goto spec_done;
case 'c':
spec = SPEC_CHAR;
goto spec_done;
case 's':
spec = SPEC_STRING;
goto spec_done;
/* XXX: Specifiers we could add support for:
* - o: octal integer
* - g, e, f: floating point
* - n: characters consumed so far
*/
default:
CLIENT_ASSERT(false, "dr_sscanf: unknown specifier");
return num_parsed; /* error */
}
}
spec_done:
/* Parse the string. */
switch (spec) {
case SPEC_CHAR:
/* XXX: We don't support width with %c. */
if (!is_ignored) {
*va_arg(ap, char*) = *sp;
}
sp++;
break;
case SPEC_STRING:
if (is_ignored) {
while (*sp != '\0' && !our_isspace(*sp)) {
sp++;
}
} else {
char *str_out = va_arg(ap, char*);
if (width > 0) {
uint i = 0;
while (i < width && *sp != '\0' && !our_isspace(*sp)) {
*str_out++ = *sp++;
i++;
}
/* Spec says only null terminate if we hit width. */
if (i < width)
*str_out = '\0';
} else {
while (*sp != '\0' && !our_isspace(*sp)) {
*str_out++ = *sp++;
}
*str_out = '\0';
}
}
break;
case SPEC_INT: {
uint64 res;
/* C sscanf skips leading whitespace before parsing integers. */
while (*sp != '\0' && our_isspace(*sp))
sp++;
sp = parse_int(sp, &res, base, width, is_signed);
if (sp == NULL)
return num_parsed;
if (!is_ignored) {
if (int_size == SZ_SHORT)
*va_arg(ap, short *) = (short)res;
else if (int_size == SZ_INT)
*va_arg(ap, int *) = (int)res;
else if (int_size == SZ_LONG)
*va_arg(ap, long *) = (long)res;
else if (int_size == SZ_LONGLONG)
*va_arg(ap, long long *) = (long long)res;
else {
ASSERT_NOT_REACHED();
return num_parsed;
}
}
break;
}
default:
/* Format parsing code above should return an error earlier. */
ASSERT_NOT_REACHED();
return num_parsed;
}
if (!is_ignored)
num_parsed++;
}
return num_parsed;
}
int
our_sscanf(const char *str, const char *fmt, ...)
{
/* No need to save errno, we don't call libc anymore. */
int res;
va_list ap;
va_start(ap, fmt);
res = our_vsscanf(str, fmt, ap);
va_end(ap);
return res;
}
#ifdef STANDALONE_UNIT_TEST
/*****************************************************************************
* sscanf() tests
*/
/* Copied from core/unix/os.c and modified so that they work when run
* cross-arch. We need %ll to parse 64-bit ints on 32-bit and drop the %l to
* parse 32-bit ints on x64.
*/
# define MAPS_LINE_FORMAT4 "%08x-%08x %s %08x %*s %llu %4096s"
# define MAPS_LINE_FORMAT8 "%016llx-%016llx %s %016llx %*s %llu %4096s"
static void
test_sscanf_maps_x86(void)
{
char line_copy[1024];
uint start, end;
uint offset;
uint64 inode;
char perm[16];
char comment[4096];
int len;
const char *maps_line =
"f75c3000-f75c4000 rw-p 00155000 fc:00 1840387"
" /lib32/libc-2.11.1.so";
strcpy(line_copy, maps_line);
len = our_sscanf(line_copy, MAPS_LINE_FORMAT4,
&start, &end, perm, &offset, &inode, comment);
EXPECT(len, 6);
/* Do int64 comparisons directly. EXPECT casts to ptr_uint_t. */
EXPECT(start, 0xf75c3000UL);
EXPECT(end, 0xf75c4000UL);
EXPECT(offset, 0x00155000UL);
EXPECT((inode == 1840387ULL), 1);
EXPECT(strcmp(perm, "rw-p"), 0);
EXPECT(strcmp(comment, "/lib32/libc-2.11.1.so"), 0);
/* sscanf should not modify it's input. */
EXPECT(strcmp(line_copy, maps_line), 0);
}
static void
test_sscanf_maps_x64(void)
{
char line_copy[1024];
uint64 start, end;
uint64 offset;
uint64 inode;
char perm[16];
char comment[4096];
int len;
const char *maps_line =
"7f94a6757000-7f94a6758000 rw-p 0017d000 fc:00 "
"1839331 /lib/libc-2.11.1.so";
strcpy(line_copy, maps_line);
len = our_sscanf(line_copy, MAPS_LINE_FORMAT8,
&start, &end, perm, &offset, &inode, comment);
EXPECT(len, 6);
/* Do int64 comparisons directly. EXPECT casts to ptr_uint_t. */
EXPECT((start == 0x7f94a6757000ULL), 1);
EXPECT((end == 0x7f94a6758000ULL), 1);
EXPECT((offset == 0x00017d000ULL), 1);
EXPECT((inode == 1839331ULL), 1);
EXPECT(strcmp(perm, "rw-p"), 0);
EXPECT(strcmp(comment, "/lib/libc-2.11.1.so"), 0);
/* sscanf should not modify it's input. */
EXPECT(strcmp(line_copy, maps_line), 0);
}
static void
test_sscanf_all_specs(void)
{
int res;
char ch;
char str[16];
int signed_int;
int signed_int_2;
uint unsigned_int;
uint hex_num;
unsigned long long ull_num;
/* ULLONG_MAX is a corner case. */
res = our_sscanf("c str -123 +456 0x789 0xffffffffffffffff",
"%c %s %d %u %x %llx", &ch, str, &signed_int,
&unsigned_int, &hex_num, &ull_num);
EXPECT(res, 6);
EXPECT(ch, 'c');
EXPECT(strcmp(str, "str"), 0);
EXPECT(signed_int, -123);
EXPECT(unsigned_int, 456);
EXPECT(hex_num, 0x789);
EXPECT((ull_num == ULLONG_MAX), true);
/* A variety of ways to say negative one. */
res = our_sscanf("-1-1", "%d%d", &signed_int, &signed_int_2);
EXPECT(res, 2);
EXPECT(signed_int, -1);
EXPECT(signed_int_2, -1);
/* Test ignores. */
res = our_sscanf("c str -123 +456 0x789 0xffffffffffffffff 1",
"%*c %*s %*d %*u %*x %*llx %d", &signed_int);
EXPECT(res, 1);
EXPECT(signed_int, 1);
/* Test width specifications on strings. */
memset(str, '*', sizeof(str)); /* Fill string with garbage. */
res = our_sscanf("abcdefghijklmnopqrstuvwxyz",
"%13s", str);
EXPECT(res, 1);
/* our_sscanf should read 13 chars without null termination. */
EXPECT(memcmp(str, "abcdefghijklm", 13), 0);
EXPECT(str[13], '*'); /* Asterisk should still be there. */
/* Test width specifications for integers. */
res = our_sscanf("123456 0x9abc", "%03d%03d %03xc",
&signed_int, &signed_int_2, &unsigned_int);
EXPECT(res, 3);
EXPECT(signed_int, 123);
EXPECT(signed_int_2, 456);
EXPECT(unsigned_int, 0x9ab);
/* Test skipping leading whitespace for integer conversions. */
res = our_sscanf(" \t123456\t\n 0x9abc", "%d%x",
&signed_int, &unsigned_int);
EXPECT(res, 2);
EXPECT(signed_int, 123456);
EXPECT(unsigned_int, 0x9abc);
/* Test Windows-style integer width specifiers using decimal ULLONG_MAX. */
res = our_sscanf("1234 18446744073709551615", "%I32d %I64d",
&signed_int, &ull_num);
EXPECT(res, 2);
EXPECT(signed_int, 1234);
EXPECT((ull_num == ULLONG_MAX), true);
/* FIXME: When parse_int has range checking, we should add tests for parsing
* integers that overflow their requested integer sizes.
*/
}
/*****************************************************************************
* memcpy() and memset() tests
*/
# ifdef UNIX
# include <errno.h>
# include <dlfcn.h> /* for dlsym for libc routines */
/* From dlfcn.h, but we'd have to define _GNU_SOURCE 1 before globals.h. */
# define RTLD_NEXT ((void *) -1l)
typedef void (*memcpy_t)(void *dst, const void *src, size_t n);
static void
test_memcpy_offset_size(size_t src_offset, size_t dst_offset, size_t size)
{
/* These can be aligned to whatever, we'll try a few different offsets. */
byte src[1024];
byte dst[1024];
int i;
for (i = 0; i < sizeof(src); i++) {
src[i] = 0xcc;
dst[i] = 0;
}
EXPECT(src_offset + size <= sizeof(src), 1);
EXPECT(dst_offset + size <= sizeof(dst), 1);
memcpy(dst + dst_offset, src + src_offset, size);
EXPECT(memcmp(dst + dst_offset, src + src_offset, size), 0);
/* Check the bytes just out of bounds, which should still be zero. */
if (dst_offset > 0)
EXPECT(dst[dst_offset-1], 0);
if (dst_offset+size < sizeof(dst))
EXPECT(dst[dst_offset+size], 0);
}
static void
test_our_memcpy(void)
{
int i, j;
void *ret;
/* Basic, copy the whole buffer. */
test_memcpy_offset_size(0, 0, 1024);
/* Test misalignment less than copy size. */
test_memcpy_offset_size(1, 1, 2);
test_memcpy_offset_size(2, 2, 2);
test_memcpy_offset_size(1, 1, 3);
test_memcpy_offset_size(2, 2, 3);
/* Test a variety of offsets. */
for (i = 0; i < 16; i++) {
for (j = 0; j < 16; j++) {
test_memcpy_offset_size(i, j, 512);
}
}
/* Check that memcpy returns dst. */
ret = memcpy(&i, &j, sizeof(i));
EXPECT(ret == &i, 1);
}
static void
test_memset_offset_size(int val, int start_offs, int end_offs)
{
byte buf[512];
int i;
int end = sizeof(buf) - start_offs - end_offs;
/* Zero without memset. */
for (i = 0; i < sizeof(buf); i++)
buf[i] = 0;
memset(buf + start_offs, val, end);
EXPECT(is_region_memset_to_char(buf + start_offs, end, val), 1);
if (start_offs > 0)
EXPECT(buf[start_offs-1], 0);
if (end_offs > 0)
EXPECT(buf[sizeof(buf)-end_offs], 0);
}
static void
test_our_memset(void)
{
int val;
int i, j;
void *ret;
/* Test a variety of values. */
for (val = 0; val < 0xff; val++) {
for (i = 0; i < 16; i++) {
for (j = 0; j < 16; j++) {
test_memset_offset_size(val, i, j);
}
}
}
/* Check that memset returns dst. */
ret = memset(&i, -1, sizeof(i));
EXPECT(ret == &i, 1);
}
static void
our_memcpy_vs_libc(void)
{
/* Compare our memcpy with libc memcpy.
* XXX: Should compare on more sizes, especially small ones.
*/
size_t alloc_size = 20 * 1024;
int loop_count = 100 * 1000;
void *src = global_heap_alloc(alloc_size HEAPACCT(ACCT_OTHER));
void *dst = global_heap_alloc(alloc_size HEAPACCT(ACCT_OTHER));
int i;
memcpy_t glibc_memcpy = (memcpy_t) dlsym(RTLD_NEXT, "memcpy");
uint64 our_memcpy_start, our_memcpy_end, our_memcpy_time;
uint64 libc_memcpy_start, libc_memcpy_end, libc_memcpy_time;
memset(src, -1, alloc_size);
memset(dst, 0, alloc_size);
our_memcpy_start = query_time_millis();
for (i = 0; i < loop_count; i++) {
memcpy(src, dst, alloc_size);
}
our_memcpy_end = query_time_millis();
libc_memcpy_start = query_time_millis();
for (i = 0; i < loop_count; i++) {
glibc_memcpy(src, dst, alloc_size);
}
libc_memcpy_end = query_time_millis();
global_heap_free(src, alloc_size HEAPACCT(ACCT_OTHER));
global_heap_free(dst, alloc_size HEAPACCT(ACCT_OTHER));
our_memcpy_time = our_memcpy_end - our_memcpy_start;
libc_memcpy_time = libc_memcpy_end - libc_memcpy_start;
print_file(STDERR, "our_memcpy_time: "UINT64_FORMAT_STRING"\n",
our_memcpy_time);
print_file(STDERR, "libc_memcpy_time: "UINT64_FORMAT_STRING"\n",
libc_memcpy_time);
/* We could assert that we're not too much slower, but that's a recipe for
* flaky failures when the suite is run on shared VMs or in parallel.
*/
}
# endif /* UNIX */
static void
test_integer(void)
{
char buf[512];
ssize_t res;
/* test integer codes */
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%lld", 0x12345678abcdef01LL);
EXPECT(res == (ssize_t) strlen("1311768467750121217"), true);
EXPECT(strcmp(buf, "1311768467750121217"), 0);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%lld", 0x82345678abcdef01LL);
EXPECT(res == (ssize_t) strlen("-9064525073711501567"), true);
EXPECT(strcmp(buf, "-9064525073711501567"), 0);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%llu", 0x82345678abcdef01LL);
EXPECT(res == (ssize_t) strlen("9382218999998050049"), true);
EXPECT(strcmp(buf, "9382218999998050049"), 0);
/* XXX: add more tests */
}
void
unit_test_io(void)
{
char buf[512];
wchar_t wbuf[512];
ssize_t res;
/* test wide char conversion */
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%S", L"wide string");
EXPECT(res == (ssize_t) strlen("wide string"), true);
EXPECT(strcmp(buf, "wide string"), 0);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%ls", L"wide string");
EXPECT(res == (ssize_t) strlen("wide string"), true);
EXPECT(strcmp(buf, "wide string"), 0);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%.3S", L"wide string");
EXPECT(res == (ssize_t) strlen("wid"), true);
EXPECT(strcmp(buf, "wid"), 0);
res = our_snprintf(buf, 4, "%S", L"wide string");
EXPECT(res == -1, true);
EXPECT(buf[4], ' '); /* ' ' from prior calls: no NULL written since hit max */
buf[4] = '\0';
EXPECT(strcmp(buf, "wide"), 0);
/* test float */
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%3.1f", 42.9f);
EXPECT(res == (ssize_t) strlen("42.9"), true);
EXPECT(strcmp(buf, "42.9"), 0);
/* XXX: add more */
/* test all-wide */
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%d%s%3.1f",
-42, L"wide string", 42.9f);
EXPECT(res == (ssize_t) wcslen(L"-42wide string42.9"), true);
EXPECT(wcscmp(wbuf, L"-42wide string42.9"), 0);
/* test all-wide conversion */
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%S", "narrow string");
EXPECT(res == (ssize_t) wcslen(L"narrow string"), true);
EXPECT(wcscmp(wbuf, L"narrow string"), 0);
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%hs", "narrow string");
EXPECT(res == (ssize_t) wcslen(L"narrow string"), true);
EXPECT(wcscmp(wbuf, L"narrow string"), 0);
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%.3S", "narrow string");
EXPECT(res == (ssize_t) wcslen(L"nar"), true);
EXPECT(wcscmp(wbuf, L"nar"), 0);
res = our_snprintf_wide(wbuf, 6, L"%S", "narrow string");
EXPECT(res == -1, true);
EXPECT(wbuf[6], L' '); /* ' ' from prior calls: no NULL written since hit max */
wbuf[6] = L'\0';
EXPECT(wcscmp(wbuf, L"narrow"), 0);
#ifdef WINDOWS
/* test UTF-16 to UTF-8 */
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%S",
L"\x0391\x03A9\x20Ac"); /* alpha, omega, euro sign */
EXPECT(res == 7, true); /* 2x 2-char + 1 3-char encodings */
EXPECT((byte)buf[0] == 0xce && (byte)buf[1] == 0x91, true); /* UTF-8 U-0391 */
EXPECT((byte)buf[2] == 0xce && (byte)buf[3] == 0xa9, true); /* UTF-8 U-03A9 */
EXPECT((byte)buf[4] == 0xe2 && (byte)buf[5] == 0x82 && (byte)buf[6] == 0xac,
true); /* UTF-8 U-20Ac */
EXPECT((byte)buf[7] == '\0', true);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%S",
L"\xd800"); /* no low surrogate */
EXPECT(res == -1, true);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%S",
L"\xd800\xdc00"); /* surrogate pair */
EXPECT(res == 4, true); /* 4-char encoding */
EXPECT((byte)buf[0] == 0xf0 && (byte)buf[1] == 0x90 &&
(byte)buf[2] == 0x80 && (byte)buf[3] == 0x80, true); /* UTF-8 U-10000 */
EXPECT((byte)buf[4] == '\0', true);
res = our_snprintf(buf, BUFFER_SIZE_ELEMENTS(buf), "%.6S",
L"\x0391\x03A9\x20Ac"); /* alpha, omega, euro sign */
EXPECT(res == 4, true); /* 2x 2-char + aborted the 3-char encoding */
EXPECT((byte)buf[0] == 0xce && (byte)buf[1] == 0x91, true); /* UTF-8 U-0391 */
EXPECT((byte)buf[2] == 0xce && (byte)buf[3] == 0xa9, true); /* UTF-8 U-03A9 */
EXPECT((byte)buf[4] == '\0', true);
/* test UTF-8 to UTF-16 */
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%S",
"\xce\x91\xce\xa9\xe2\x82\xac"); /* alpha, omega, euro sign */
EXPECT(res == 3, true);
EXPECT(wbuf[0] == 0x0391 && wbuf[1] == 0x03a9 && wbuf[2] == 0x20ac, true);
EXPECT(wbuf[3] == L'\0', true);
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%S",
"\xff\x91\xce\xa9\xe2\x82");
EXPECT(res == -1, true); /* not encodable in UTF-16 */
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%S",
"\xf0\x90\x80\x80"); /* U-1000 */
EXPECT(res == 2, true);
EXPECT(wbuf[0] == 0xd800 && wbuf[1] == 0xdc00 && wbuf[2] == L'\0', true);
res = our_snprintf_wide(wbuf, BUFFER_SIZE_ELEMENTS(wbuf), L"%.2S",
"\xce\x91\xce\xa9\xe2\x82\xac"); /* alpha, omega, euro sign */
EXPECT(res == 2, true);
EXPECT(wbuf[0] == 0x0391 && wbuf[1] == 0x03a9 && wbuf[2] == L'\0', true);
#endif
test_integer();
/* sscanf tests */
test_sscanf_maps_x86();
test_sscanf_maps_x64();
test_sscanf_all_specs();
#ifdef UNIX
/* memcpy tests */
test_our_memcpy();
our_memcpy_vs_libc();
/* memset tests */
test_our_memset();
#endif /* UNIX */
/* XXX: add more tests */
print_file(STDERR, "io all done\n");
}
#endif /* STANDALONE_UNIT_TEST */