dnl x86 fat binary entrypoints. dnl Copyright 2003, 2012 Free Software Foundation, Inc. dnl This file is part of the GNU MP Library. dnl dnl The GNU MP Library is free software; you can redistribute it and/or modify dnl it under the terms of either: dnl dnl * the GNU Lesser General Public License as published by the Free dnl Software Foundation; either version 3 of the License, or (at your dnl option) any later version. dnl dnl or dnl dnl * the GNU General Public License as published by the Free Software dnl Foundation; either version 2 of the License, or (at your option) any dnl later version. dnl dnl or both in parallel, as here. dnl dnl The GNU MP Library is distributed in the hope that it will be useful, but dnl WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY dnl or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License dnl for more details. dnl dnl You should have received copies of the GNU General Public License and the dnl GNU Lesser General Public License along with the GNU MP Library. If not, dnl see https://www.gnu.org/licenses/. include(`../config.m4') dnl Forcibly disable profiling. dnl dnl The entrypoints and inits are small enough not to worry about, the real dnl routines arrived at will have any profiling. Also, the way the code dnl here ends with a jump means we won't work properly with the dnl "instrument" profiling scheme anyway. define(`WANT_PROFILING',no) TEXT dnl Usage: FAT_ENTRY(name, offset) dnl dnl Emit a fat binary entrypoint function of the given name. This is the dnl normal entry for applications, eg. __gmpn_add_n. dnl dnl The code simply jumps through the function pointer in __gmpn_cpuvec at dnl the given "offset" (in bytes). dnl dnl For non-PIC, the jumps are 5 bytes each, aligning them to 8 should be dnl fine for all x86s. dnl dnl For PIC, the jumps are 20 bytes each, and are best aligned to 16 to dnl ensure at least the first two instructions don't cross a cache line dnl boundary. dnl dnl Note the extra `' ahead of PROLOGUE obscures it from the HAVE_NATIVE dnl grepping in configure, stopping that code trying to eval something with dnl $1 in it. define(FAT_ENTRY, m4_assert_numargs(2) ` ALIGN(ifdef(`PIC',16,8)) `'PROLOGUE($1) ifdef(`PIC', ` call L(movl_eip_edx) L(entry_here$2): addl $_GLOBAL_OFFSET_TABLE_+[.-L(entry_here$2)], %edx movl GSYM_PREFIX`'__gmpn_cpuvec@GOT(%edx), %edx jmp *m4_empty_if_zero($2)(%edx) ',`dnl non-PIC jmp *GSYM_PREFIX`'__gmpn_cpuvec+$2 ') EPILOGUE() ') dnl FAT_ENTRY for each CPUVEC_FUNCS_LIST dnl define(`CPUVEC_offset',0) foreach(i, `FAT_ENTRY(MPN(i),CPUVEC_offset) define(`CPUVEC_offset',eval(CPUVEC_offset + 4))', CPUVEC_FUNCS_LIST) ifdef(`PIC',` ALIGN(8) L(movl_eip_edx): movl (%esp), %edx ret_internal ') dnl Usage: FAT_INIT(name, offset) dnl dnl Emit a fat binary initializer function of the given name. These dnl functions are the initial values for the pointers in __gmpn_cpuvec. dnl dnl The code simply calls __gmpn_cpuvec_init, and then jumps back through dnl the __gmpn_cpuvec pointer, at the given "offset" (in bytes). dnl __gmpn_cpuvec_init will have stored the address of the selected dnl implementation there. dnl dnl Only one of these routines will be executed, and only once, since after dnl that all the __gmpn_cpuvec pointers go to real routines. So there's no dnl need for anything special here, just something small and simple. To dnl keep code size down, "fat_init" is a shared bit of code, arrived at dnl with the offset in %al. %al is used since the movb instruction is 2 dnl bytes where %eax would be 4. dnl dnl Note having `PROLOGUE in FAT_INIT obscures that PROLOGUE from the dnl HAVE_NATIVE grepping in configure, preventing that code trying to eval dnl something with $1 in it. define(FAT_INIT, m4_assert_numargs(2) `PROLOGUE($1) movb $`'$2, %al jmp L(fat_init) EPILOGUE() ') L(fat_init): C al __gmpn_cpuvec byte offset movzbl %al, %eax pushl %eax ifdef(`PIC',` pushl %ebx call L(movl_eip_ebx) L(init_here): addl $_GLOBAL_OFFSET_TABLE_+[.-L(init_here)], %ebx call GSYM_PREFIX`'__gmpn_cpuvec_init@PLT movl GSYM_PREFIX`'__gmpn_cpuvec@GOT(%ebx), %edx popl %ebx popl %eax jmp *(%edx,%eax) L(movl_eip_ebx): movl (%esp), %ebx ret_internal ',`dnl non-PIC call GSYM_PREFIX`'__gmpn_cpuvec_init popl %eax jmp *GSYM_PREFIX`'__gmpn_cpuvec(%eax) ') dnl FAT_INIT for each CPUVEC_FUNCS_LIST dnl define(`CPUVEC_offset',0) foreach(i, `FAT_INIT(MPN(i`'_init),CPUVEC_offset) define(`CPUVEC_offset',eval(CPUVEC_offset + 4))', CPUVEC_FUNCS_LIST) C long __gmpn_cpuid (char dst[12], int id); C C This is called only once, so just something simple and compact is fine. defframe(PARAM_ID, 8) defframe(PARAM_DST, 4) deflit(`FRAME',0) PROLOGUE(__gmpn_cpuid) pushl %esi FRAME_pushl() pushl %ebx FRAME_pushl() movl PARAM_ID, %eax cpuid movl PARAM_DST, %esi movl %ebx, (%esi) movl %edx, 4(%esi) movl %ecx, 8(%esi) popl %ebx popl %esi ret EPILOGUE() C int __gmpn_cpuid_available (void); C C Return non-zero if the cpuid instruction is available, which means late C model 80486 and higher. 80386 and early 80486 don't have cpuid. C C The test follows Intel AP-485 application note, namely that if bit 21 is C modifiable then cpuid is supported. This test is reentrant and thread C safe, since of course any interrupt or context switch will preserve the C flags while we're tinkering with them. C C This is called only once, so just something simple and compact is fine. PROLOGUE(__gmpn_cpuid_available) pushf popl %ecx C old flags movl %ecx, %edx xorl $0x200000, %edx pushl %edx popf pushf popl %edx C tweaked flags movl $1, %eax cmpl %ecx, %edx jne L(available) xorl %eax, %eax C not changed, so cpuid not available L(available): ret EPILOGUE()