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Atmosphere/exosphere/src/my_libc.c

1141 lines
26 KiB
C

/* Note: copied from newlib */
#ifdef __cplusplus
extern "C" {
#endif
#include <string.h>
#include <stddef.h>
#include <limits.h>
/*
* Copyright (C) 2004 CodeSourcery, LLC
*
* Permission to use, copy, modify, and distribute this file
* for any purpose is hereby granted without fee, provided that
* the above copyright notice and this notice appears in all
* copies.
*
* This file is distributed WITHOUT ANY WARRANTY; without even the implied
* warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
*/
/* Handle ELF .{pre_init,init,fini}_array sections. */
#include <sys/types.h>
#ifndef HAVE_INITFINI_ARRAY
#define HAVE_INITFINI_ARRAY
#endif
#undef HAVE_INIT_FINI
#ifdef HAVE_INITFINI_ARRAY
/* These magic symbols are provided by the linker. */
extern void (*__preinit_array_start []) (void) __attribute__((weak));
extern void (*__preinit_array_end []) (void) __attribute__((weak));
extern void (*__init_array_start []) (void) __attribute__((weak));
extern void (*__init_array_end []) (void) __attribute__((weak));
#ifdef HAVE_INIT_FINI
extern void _init (void);
#endif
/* Iterate over all the init routines. */
void
__libc_init_array (void)
{
size_t count;
size_t i;
count = __preinit_array_end - __preinit_array_start;
for (i = 0; i < count; i++)
__preinit_array_start[i] ();
#ifdef HAVE_INIT_FINI
_init ();
#endif
count = __init_array_end - __init_array_start;
for (i = 0; i < count; i++)
__init_array_start[i] ();
}
#endif
#ifdef HAVE_INITFINI_ARRAY
extern void (*__fini_array_start []) (void) __attribute__((weak));
extern void (*__fini_array_end []) (void) __attribute__((weak));
#ifdef HAVE_INIT_FINI
extern void _fini (void);
#endif
/* Run all the cleanup routines. */
void
__libc_fini_array (void)
{
size_t count;
size_t i;
count = __fini_array_end - __fini_array_start;
for (i = count; i > 0; i--)
__fini_array_start[i-1] ();
#ifdef HAVE_INIT_FINI
_fini ();
#endif
}
#endif
/*
FUNCTION
<<memmove>>---move possibly overlapping memory
INDEX
memmove
SYNOPSIS
#include <string.h>
void *memmove(void *<[dst]>, const void *<[src]>, size_t <[length]>);
DESCRIPTION
This function moves <[length]> characters from the block of
memory starting at <<*<[src]>>> to the memory starting at
<<*<[dst]>>>. <<memmove>> reproduces the characters correctly
at <<*<[dst]>>> even if the two areas overlap.
RETURNS
The function returns <[dst]> as passed.
PORTABILITY
<<memmove>> is ANSI C.
<<memmove>> requires no supporting OS subroutines.
QUICKREF
memmove ansi pure
*/
/* Nonzero if either X or Y is not aligned on a "long" boundary. */
#define UNALIGNED(X, Y) \
(((long)X & (sizeof (long) - 1)) | ((long)Y & (sizeof (long) - 1)))
/* How many bytes are copied each iteration of the 4X unrolled loop. */
#define BIGBLOCKSIZE (sizeof (long) << 2)
/* How many bytes are copied each iteration of the word copy loop. */
#define LITTLEBLOCKSIZE (sizeof (long))
/* Threshhold for punting to the byte copier. */
#undef TOO_SMALL
#define TOO_SMALL(LEN) ((LEN) < BIGBLOCKSIZE)
/*SUPPRESS 20*/
void *
//__inhibit_loop_to_libcall
memmove (void *dst_void,
const void *src_void,
size_t length)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
char *dst = dst_void;
const char *src = src_void;
if (src < dst && dst < src + length)
{
/* Have to copy backwards */
src += length;
dst += length;
while (length--)
{
*--dst = *--src;
}
}
else
{
while (length--)
{
*dst++ = *src++;
}
}
return dst_void;
#else
char *dst = dst_void;
const char *src = src_void;
long *aligned_dst;
const long *aligned_src;
if (src < dst && dst < src + length)
{
/* Destructive overlap...have to copy backwards */
src += length;
dst += length;
while (length--)
{
*--dst = *--src;
}
}
else
{
/* Use optimizing algorithm for a non-destructive copy to closely
match memcpy. If the size is small or either SRC or DST is unaligned,
then punt into the byte copy loop. This should be rare. */
if (!TOO_SMALL(length) && !UNALIGNED (src, dst))
{
aligned_dst = (long*)dst;
aligned_src = (long*)src;
/* Copy 4X long words at a time if possible. */
while (length >= BIGBLOCKSIZE)
{
*aligned_dst++ = *aligned_src++;
*aligned_dst++ = *aligned_src++;
*aligned_dst++ = *aligned_src++;
*aligned_dst++ = *aligned_src++;
length -= BIGBLOCKSIZE;
}
/* Copy one long word at a time if possible. */
while (length >= LITTLEBLOCKSIZE)
{
*aligned_dst++ = *aligned_src++;
length -= LITTLEBLOCKSIZE;
}
/* Pick up any residual with a byte copier. */
dst = (char*)aligned_dst;
src = (char*)aligned_src;
}
while (length--)
{
*dst++ = *src++;
}
}
return dst_void;
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<memcpy>>---copy memory regions
SYNOPSIS
#include <string.h>
void* memcpy(void *restrict <[out]>, const void *restrict <[in]>,
size_t <[n]>);
DESCRIPTION
This function copies <[n]> bytes from the memory region
pointed to by <[in]> to the memory region pointed to by
<[out]>.
If the regions overlap, the behavior is undefined.
RETURNS
<<memcpy>> returns a pointer to the first byte of the <[out]>
region.
PORTABILITY
<<memcpy>> is ANSI C.
<<memcpy>> requires no supporting OS subroutines.
QUICKREF
memcpy ansi pure
*/
void *
memcpy (void * dst0,
const void * __restrict src0,
size_t len0)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
char *dst = (char *) dst0;
char *src = (char *) src0;
void *save = dst0;
while (len0--)
{
*dst++ = *src++;
}
return save;
#else
char *dst = dst0;
const char *src = src0;
long *aligned_dst;
const long *aligned_src;
/* If the size is small, or either SRC or DST is unaligned,
then punt into the byte copy loop. This should be rare. */
if (!TOO_SMALL(len0) && !UNALIGNED (src, dst))
{
aligned_dst = (long*)dst;
aligned_src = (long*)src;
/* Copy 4X long words at a time if possible. */
while (len0 >= BIGBLOCKSIZE)
{
*aligned_dst++ = *aligned_src++;
*aligned_dst++ = *aligned_src++;
*aligned_dst++ = *aligned_src++;
*aligned_dst++ = *aligned_src++;
len0 -= BIGBLOCKSIZE;
}
/* Copy one long word at a time if possible. */
while (len0 >= LITTLEBLOCKSIZE)
{
*aligned_dst++ = *aligned_src++;
len0 -= LITTLEBLOCKSIZE;
}
/* Pick up any residual with a byte copier. */
dst = (char*)aligned_dst;
src = (char*)aligned_src;
}
while (len0--)
*dst++ = *src++;
return dst0;
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<memset>>---set an area of memory
INDEX
memset
SYNOPSIS
#include <string.h>
void *memset(void *<[dst]>, int <[c]>, size_t <[length]>);
DESCRIPTION
This function converts the argument <[c]> into an unsigned
char and fills the first <[length]> characters of the array
pointed to by <[dst]> to the value.
RETURNS
<<memset>> returns the value of <[dst]>.
PORTABILITY
<<memset>> is ANSI C.
<<memset>> requires no supporting OS subroutines.
QUICKREF
memset ansi pure
*/
#include <string.h>
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
#define LBLOCKSIZE (sizeof(long))
#define UNALIGNED(X) ((long)X & (LBLOCKSIZE - 1))
#define TOO_SMALL(LEN) ((LEN) < LBLOCKSIZE)
void *
memset (void *m,
int c,
size_t n)
{
char *s = (char *) m;
#if !defined(PREFER_SIZE_OVER_SPEED) && !defined(__OPTIMIZE_SIZE__)
unsigned int i;
unsigned long buffer;
unsigned long *aligned_addr;
unsigned int d = c & 0xff; /* To avoid sign extension, copy C to an
unsigned variable. */
while (UNALIGNED (s))
{
if (n--)
*s++ = (char) c;
else
return m;
}
if (!TOO_SMALL (n))
{
/* If we get this far, we know that n is large and s is word-aligned. */
aligned_addr = (unsigned long *) s;
/* Store D into each char sized location in BUFFER so that
we can set large blocks quickly. */
buffer = (d << 8) | d;
buffer |= (buffer << 16);
for (i = 32; i < LBLOCKSIZE * 8; i <<= 1)
buffer = (buffer << i) | buffer;
/* Unroll the loop. */
while (n >= LBLOCKSIZE*4)
{
*aligned_addr++ = buffer;
*aligned_addr++ = buffer;
*aligned_addr++ = buffer;
*aligned_addr++ = buffer;
n -= 4*LBLOCKSIZE;
}
while (n >= LBLOCKSIZE)
{
*aligned_addr++ = buffer;
n -= LBLOCKSIZE;
}
/* Pick up the remainder with a bytewise loop. */
s = (char*)aligned_addr;
}
#endif /* not PREFER_SIZE_OVER_SPEED */
while (n--)
*s++ = (char) c;
return m;
}
/*
FUNCTION
<<memchr>>---find character in memory
INDEX
memchr
SYNOPSIS
#include <string.h>
void *memchr(const void *<[src]>, int <[c]>, size_t <[length]>);
DESCRIPTION
This function searches memory starting at <<*<[src]>>> for the
character <[c]>. The search only ends with the first
occurrence of <[c]>, or after <[length]> characters; in
particular, <<NUL>> does not terminate the search.
RETURNS
If the character <[c]> is found within <[length]> characters
of <<*<[src]>>>, a pointer to the character is returned. If
<[c]> is not found, then <<NULL>> is returned.
PORTABILITY
<<memchr>> is ANSI C.
<<memchr>> requires no supporting OS subroutines.
QUICKREF
memchr ansi pure
*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
/* Nonzero if either X or Y is not aligned on a "long" boundary. */
#define UNALIGNED(X) ((long)X & (sizeof (long) - 1))
/* How many bytes are loaded each iteration of the word copy loop. */
#define LBLOCKSIZE (sizeof (long))
/* Threshhold for punting to the bytewise iterator. */
#define TOO_SMALL(LEN) ((LEN) < LBLOCKSIZE)
#if LONG_MAX == 2147483647L
#define DETECTNULL(X) (((X) - 0x01010101) & ~(X) & 0x80808080)
#else
#if LONG_MAX == 9223372036854775807L
/* Nonzero if X (a long int) contains a NULL byte. */
#define DETECTNULL(X) (((X) - 0x0101010101010101) & ~(X) & 0x8080808080808080)
#else
#error long int is not a 32bit or 64bit type.
#endif
#endif
#ifndef DETECTNULL
#error long int is not a 32bit or 64bit byte
#endif
/* DETECTCHAR returns nonzero if (long)X contains the byte used
to fill (long)MASK. */
#define DETECTCHAR(X,MASK) (DETECTNULL(X ^ MASK))
void *
memchr (const void *src_void,
int c,
size_t length)
{
const unsigned char *src = (const unsigned char *) src_void;
unsigned char d = c;
#if !defined(PREFER_SIZE_OVER_SPEED) && !defined(__OPTIMIZE_SIZE__)
unsigned long *asrc;
unsigned long mask;
unsigned int i;
while (UNALIGNED (src))
{
if (!length--)
return NULL;
if (*src == d)
return (void *) src;
src++;
}
if (!TOO_SMALL (length))
{
/* If we get this far, we know that length is large and src is
word-aligned. */
/* The fast code reads the source one word at a time and only
performs the bytewise search on word-sized segments if they
contain the search character, which is detected by XORing
the word-sized segment with a word-sized block of the search
character and then detecting for the presence of NUL in the
result. */
asrc = (unsigned long *) src;
mask = d << 8 | d;
mask = mask << 16 | mask;
for (i = 32; i < LBLOCKSIZE * 8; i <<= 1)
mask = (mask << i) | mask;
while (length >= LBLOCKSIZE)
{
if (DETECTCHAR (*asrc, mask))
break;
length -= LBLOCKSIZE;
asrc++;
}
/* If there are fewer than LBLOCKSIZE characters left,
then we resort to the bytewise loop. */
src = (unsigned char *) asrc;
}
#endif /* not PREFER_SIZE_OVER_SPEED */
while (length--)
{
if (*src == d)
return (void *) src;
src++;
}
return NULL;
}
/*
FUNCTION
<<memcmp>>---compare two memory areas
INDEX
memcmp
SYNOPSIS
#include <string.h>
int memcmp(const void *<[s1]>, const void *<[s2]>, size_t <[n]>);
DESCRIPTION
This function compares not more than <[n]> characters of the
object pointed to by <[s1]> with the object pointed to by <[s2]>.
RETURNS
The function returns an integer greater than, equal to or
less than zero according to whether the object pointed to by
<[s1]> is greater than, equal to or less than the object
pointed to by <[s2]>.
PORTABILITY
<<memcmp>> is ANSI C.
<<memcmp>> requires no supporting OS subroutines.
QUICKREF
memcmp ansi pure
*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
/* Nonzero if either X or Y is not aligned on a "long" boundary. */
#define UNALIGNED(X, Y) \
(((long)X & (sizeof (long) - 1)) | ((long)Y & (sizeof (long) - 1)))
/* How many bytes are copied each iteration of the word copy loop. */
#define LBLOCKSIZE (sizeof (long))
/* Threshhold for punting to the byte copier. */
#define TOO_SMALL(LEN) ((LEN) < LBLOCKSIZE)
int
memcmp (const void *m1,
const void *m2,
size_t n)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
unsigned char *s1 = (unsigned char *) m1;
unsigned char *s2 = (unsigned char *) m2;
while (n--)
{
if (*s1 != *s2)
{
return *s1 - *s2;
}
s1++;
s2++;
}
return 0;
#else
unsigned char *s1 = (unsigned char *) m1;
unsigned char *s2 = (unsigned char *) m2;
unsigned long *a1;
unsigned long *a2;
/* If the size is too small, or either pointer is unaligned,
then we punt to the byte compare loop. Hopefully this will
not turn up in inner loops. */
if (!TOO_SMALL(n) && !UNALIGNED(s1,s2))
{
/* Otherwise, load and compare the blocks of memory one
word at a time. */
a1 = (unsigned long*) s1;
a2 = (unsigned long*) s2;
while (n >= LBLOCKSIZE)
{
if (*a1 != *a2)
break;
a1++;
a2++;
n -= LBLOCKSIZE;
}
/* check m mod LBLOCKSIZE remaining characters */
s1 = (unsigned char*)a1;
s2 = (unsigned char*)a2;
}
while (n--)
{
if (*s1 != *s2)
return *s1 - *s2;
s1++;
s2++;
}
return 0;
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<strchr>>---search for character in string
INDEX
strchr
SYNOPSIS
#include <string.h>
char * strchr(const char *<[string]>, int <[c]>);
DESCRIPTION
This function finds the first occurence of <[c]> (converted to
a char) in the string pointed to by <[string]> (including the
terminating null character).
RETURNS
Returns a pointer to the located character, or a null pointer
if <[c]> does not occur in <[string]>.
PORTABILITY
<<strchr>> is ANSI C.
<<strchr>> requires no supporting OS subroutines.
QUICKREF
strchr ansi pure
*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
/* Nonzero if X is not aligned on a "long" boundary. */
#define UNALIGNED(X) ((long)X & (sizeof (long) - 1))
/* How many bytes are loaded each iteration of the word copy loop. */
#define LBLOCKSIZE (sizeof (long))
char *
strchr (const char *s1,
int i)
{
const unsigned char *s = (const unsigned char *)s1;
unsigned char c = i;
#if !defined(PREFER_SIZE_OVER_SPEED) && !defined(__OPTIMIZE_SIZE__)
unsigned long mask,j;
unsigned long *aligned_addr;
/* Special case for finding 0. */
if (!c)
{
while (UNALIGNED (s))
{
if (!*s)
return (char *) s;
s++;
}
/* Operate a word at a time. */
aligned_addr = (unsigned long *) s;
while (!DETECTNULL (*aligned_addr))
aligned_addr++;
/* Found the end of string. */
s = (const unsigned char *) aligned_addr;
while (*s)
s++;
return (char *) s;
}
/* All other bytes. Align the pointer, then search a long at a time. */
while (UNALIGNED (s))
{
if (!*s)
return NULL;
if (*s == c)
return (char *) s;
s++;
}
mask = c;
for (j = 8; j < LBLOCKSIZE * 8; j <<= 1)
mask = (mask << j) | mask;
aligned_addr = (unsigned long *) s;
while (!DETECTNULL (*aligned_addr) && !DETECTCHAR (*aligned_addr, mask))
aligned_addr++;
/* The block of bytes currently pointed to by aligned_addr
contains either a null or the target char, or both. We
catch it using the bytewise search. */
s = (unsigned char *) aligned_addr;
#endif /* not PREFER_SIZE_OVER_SPEED */
while (*s && *s != c)
s++;
if (*s == c)
return (char *)s;
return NULL;
}
/*
FUNCTION
<<strcmp>>---character string compare
INDEX
strcmp
SYNOPSIS
#include <string.h>
int strcmp(const char *<[a]>, const char *<[b]>);
DESCRIPTION
<<strcmp>> compares the string at <[a]> to
the string at <[b]>.
RETURNS
If <<*<[a]>>> sorts lexicographically after <<*<[b]>>>,
<<strcmp>> returns a number greater than zero. If the two
strings match, <<strcmp>> returns zero. If <<*<[a]>>>
sorts lexicographically before <<*<[b]>>>, <<strcmp>> returns a
number less than zero.
PORTABILITY
<<strcmp>> is ANSI C.
<<strcmp>> requires no supporting OS subroutines.
QUICKREF
strcmp ansi pure
*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
/* Nonzero if either X or Y is not aligned on a "long" boundary. */
#define UNALIGNED(X, Y) \
(((long)X & (sizeof (long) - 1)) | ((long)Y & (sizeof (long) - 1)))
int
strcmp (const char *s1,
const char *s2)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
while (*s1 != '\0' && *s1 == *s2)
{
s1++;
s2++;
}
return (*(unsigned char *) s1) - (*(unsigned char *) s2);
#else
unsigned long *a1;
unsigned long *a2;
/* If s1 or s2 are unaligned, then compare bytes. */
if (!UNALIGNED (s1, s2))
{
/* If s1 and s2 are word-aligned, compare them a word at a time. */
a1 = (unsigned long*)s1;
a2 = (unsigned long*)s2;
while (*a1 == *a2)
{
/* To get here, *a1 == *a2, thus if we find a null in *a1,
then the strings must be equal, so return zero. */
if (DETECTNULL (*a1))
return 0;
a1++;
a2++;
}
/* A difference was detected in last few bytes of s1, so search bytewise */
s1 = (char*)a1;
s2 = (char*)a2;
}
while (*s1 != '\0' && *s1 == *s2)
{
s1++;
s2++;
}
return (*(unsigned char *) s1) - (*(unsigned char *) s2);
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<strcpy>>---copy string
INDEX
strcpy
SYNOPSIS
#include <string.h>
char *strcpy(char *<[dst]>, const char *<[src]>);
DESCRIPTION
<<strcpy>> copies the string pointed to by <[src]>
(including the terminating null character) to the array
pointed to by <[dst]>.
RETURNS
This function returns the initial value of <[dst]>.
PORTABILITY
<<strcpy>> is ANSI C.
<<strcpy>> requires no supporting OS subroutines.
QUICKREF
strcpy ansi pure
*/
/*SUPPRESS 560*/
/*SUPPRESS 530*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
/* Nonzero if either X or Y is not aligned on a "long" boundary. */
#define UNALIGNED(X, Y) \
(((long)X & (sizeof (long) - 1)) | ((long)Y & (sizeof (long) - 1)))
char*
strcpy (char *dst0,
const char *src0)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
char *s = dst0;
while (*dst0++ = *src0++)
;
return s;
#else
char *dst = dst0;
const char *src = src0;
long *aligned_dst;
const long *aligned_src;
/* If SRC or DEST is unaligned, then copy bytes. */
if (!UNALIGNED (src, dst))
{
aligned_dst = (long*)dst;
aligned_src = (long*)src;
/* SRC and DEST are both "long int" aligned, try to do "long int"
sized copies. */
while (!DETECTNULL(*aligned_src))
{
*aligned_dst++ = *aligned_src++;
}
dst = (char*)aligned_dst;
src = (char*)aligned_src;
}
while ((*dst++ = *src++))
;
return dst0;
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<strlen>>---character string length
INDEX
strlen
SYNOPSIS
#include <string.h>
size_t strlen(const char *<[str]>);
DESCRIPTION
The <<strlen>> function works out the length of the string
starting at <<*<[str]>>> by counting chararacters until it
reaches a <<NULL>> character.
RETURNS
<<strlen>> returns the character count.
PORTABILITY
<<strlen>> is ANSI C.
<<strlen>> requires no supporting OS subroutines.
QUICKREF
strlen ansi pure
*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
#define LBLOCKSIZE (sizeof (long))
#define UNALIGNED(X) ((long)X & (LBLOCKSIZE - 1))
size_t
strlen (const char *str)
{
const char *start = str;
#if !defined(PREFER_SIZE_OVER_SPEED) && !defined(__OPTIMIZE_SIZE__)
unsigned long *aligned_addr;
/* Align the pointer, so we can search a word at a time. */
while (UNALIGNED (str))
{
if (!*str)
return str - start;
str++;
}
/* If the string is word-aligned, we can check for the presence of
a null in each word-sized block. */
aligned_addr = (unsigned long *)str;
while (!DETECTNULL (*aligned_addr))
aligned_addr++;
/* Once a null is detected, we check each byte in that block for a
precise position of the null. */
str = (char *) aligned_addr;
#endif /* not PREFER_SIZE_OVER_SPEED */
while (*str)
str++;
return str - start;
}
/*
FUNCTION
<<strncmp>>---character string compare
INDEX
strncmp
SYNOPSIS
#include <string.h>
int strncmp(const char *<[a]>, const char * <[b]>, size_t <[length]>);
DESCRIPTION
<<strncmp>> compares up to <[length]> characters
from the string at <[a]> to the string at <[b]>.
RETURNS
If <<*<[a]>>> sorts lexicographically after <<*<[b]>>>,
<<strncmp>> returns a number greater than zero. If the two
strings are equivalent, <<strncmp>> returns zero. If <<*<[a]>>>
sorts lexicographically before <<*<[b]>>>, <<strncmp>> returns a
number less than zero.
PORTABILITY
<<strncmp>> is ANSI C.
<<strncmp>> requires no supporting OS subroutines.
QUICKREF
strncmp ansi pure
*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
#define UNALIGNED(X, Y) \
(((long)X & (sizeof (long) - 1)) | ((long)Y & (sizeof (long) - 1)))
int
strncmp (const char *s1,
const char *s2,
size_t n)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
if (n == 0)
return 0;
while (n-- != 0 && *s1 == *s2)
{
if (n == 0 || *s1 == '\0')
break;
s1++;
s2++;
}
return (*(unsigned char *) s1) - (*(unsigned char *) s2);
#else
unsigned long *a1;
unsigned long *a2;
if (n == 0)
return 0;
/* If s1 or s2 are unaligned, then compare bytes. */
if (!UNALIGNED (s1, s2))
{
/* If s1 and s2 are word-aligned, compare them a word at a time. */
a1 = (unsigned long*)s1;
a2 = (unsigned long*)s2;
while (n >= sizeof (long) && *a1 == *a2)
{
n -= sizeof (long);
/* If we've run out of bytes or hit a null, return zero
since we already know *a1 == *a2. */
if (n == 0 || DETECTNULL (*a1))
return 0;
a1++;
a2++;
}
/* A difference was detected in last few bytes of s1, so search bytewise */
s1 = (char*)a1;
s2 = (char*)a2;
}
while (n-- > 0 && *s1 == *s2)
{
/* If we've run out of bytes or hit a null, return zero
since we already know *s1 == *s2. */
if (n == 0 || *s1 == '\0')
return 0;
s1++;
s2++;
}
return (*(unsigned char *) s1) - (*(unsigned char *) s2);
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<strncpy>>---counted copy string
INDEX
strncpy
SYNOPSIS
#include <string.h>
char *strncpy(char *restrict <[dst]>, const char *restrict <[src]>,
size_t <[length]>);
DESCRIPTION
<<strncpy>> copies not more than <[length]> characters from the
the string pointed to by <[src]> (including the terminating
null character) to the array pointed to by <[dst]>. If the
string pointed to by <[src]> is shorter than <[length]>
characters, null characters are appended to the destination
array until a total of <[length]> characters have been
written.
RETURNS
This function returns the initial value of <[dst]>.
PORTABILITY
<<strncpy>> is ANSI C.
<<strncpy>> requires no supporting OS subroutines.
QUICKREF
strncpy ansi pure
*/
/*SUPPRESS 560*/
/*SUPPRESS 530*/
#undef LBLOCKSIZE
#undef UNALIGNED
#undef TOO_SMALL
#define UNALIGNED(X, Y) \
(((long)X & (sizeof (long) - 1)) | ((long)Y & (sizeof (long) - 1)))
#define TOO_SMALL(LEN) ((LEN) < sizeof (long))
char *
strncpy (char *__restrict dst0,
const char *__restrict src0,
size_t count)
{
#if defined(PREFER_SIZE_OVER_SPEED) || defined(__OPTIMIZE_SIZE__)
char *dscan;
const char *sscan;
dscan = dst0;
sscan = src0;
while (count > 0)
{
--count;
if ((*dscan++ = *sscan++) == '\0')
break;
}
while (count-- > 0)
*dscan++ = '\0';
return dst0;
#else
char *dst = dst0;
const char *src = src0;
long *aligned_dst;
const long *aligned_src;
/* If SRC and DEST is aligned and count large enough, then copy words. */
if (!UNALIGNED (src, dst) && !TOO_SMALL (count))
{
aligned_dst = (long*)dst;
aligned_src = (long*)src;
/* SRC and DEST are both "long int" aligned, try to do "long int"
sized copies. */
while (count >= sizeof (long int) && !DETECTNULL(*aligned_src))
{
count -= sizeof (long int);
*aligned_dst++ = *aligned_src++;
}
dst = (char*)aligned_dst;
src = (char*)aligned_src;
}
while (count > 0)
{
--count;
if ((*dst++ = *src++) == '\0')
break;
}
while (count-- > 0)
*dst++ = '\0';
return dst0;
#endif /* not PREFER_SIZE_OVER_SPEED */
}
/*
FUNCTION
<<strnlen>>---character string length
INDEX
strnlen
SYNOPSIS
#include <string.h>
size_t strnlen(const char *<[str]>, size_t <[n]>);
DESCRIPTION
The <<strnlen>> function works out the length of the string
starting at <<*<[str]>>> by counting chararacters until it
reaches a NUL character or the maximum: <[n]> number of
characters have been inspected.
RETURNS
<<strnlen>> returns the character count or <[n]>.
PORTABILITY
<<strnlen>> is a GNU extension.
<<strnlen>> requires no supporting OS subroutines.
*/
size_t
strnlen (const char *str,
size_t n)
{
const char *start = str;
while (n-- > 0 && *str)
str++;
return str - start;
}
#ifdef __cplusplus
} /* extern "C" */
#endif