mpv/cpudetect.c

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#include "config.h"
#include "cpudetect.h"
CpuCaps gCpuCaps;
#ifdef HAVE_MALLOC_H
#include <malloc.h>
#endif
#include <stdlib.h>
#ifdef ARCH_X86
#include <stdio.h>
#ifdef __FreeBSD__
#include <sys/types.h>
#include <sys/sysctl.h>
#endif
#ifdef __linux__
#include <signal.h>
#endif
//#define X86_FXSR_MAGIC
/* Thanks to the FreeBSD project for some of this cpuid code, and
* help understanding how to use it. Thanks to the Mesa
* team for SSE support detection and more cpu detect code.
*/
/* I believe this code works. However, it has only been used on a PII and PIII */
static void check_os_katmai_support( void );
#if 1
// return TRUE if cpuid supported
static int has_cpuid()
{
int a, c;
// code from libavcodec:
__asm__ __volatile__ (
/* See if CPUID instruction is supported ... */
/* ... Get copies of EFLAGS into eax and ecx */
"pushf\n\t"
"popl %0\n\t"
"movl %0, %1\n\t"
/* ... Toggle the ID bit in one copy and store */
/* to the EFLAGS reg */
"xorl $0x200000, %0\n\t"
"push %0\n\t"
"popf\n\t"
/* ... Get the (hopefully modified) EFLAGS */
"pushf\n\t"
"popl %0\n\t"
: "=a" (a), "=c" (c)
:
: "cc"
);
return (a!=c);
}
#endif
static void
do_cpuid(unsigned int ax, unsigned int *p)
{
#if 0
__asm __volatile(
"cpuid;"
: "=a" (p[0]), "=b" (p[1]), "=c" (p[2]), "=d" (p[3])
: "0" (ax)
);
#else
// code from libavcodec:
__asm __volatile
("movl %%ebx, %%esi\n\t"
"cpuid\n\t"
"xchgl %%ebx, %%esi"
: "=a" (p[0]), "=S" (p[1]),
"=c" (p[2]), "=d" (p[3])
: "0" (ax));
#endif
}
void GetCpuCaps( CpuCaps *caps)
{
unsigned int regs[4];
unsigned int regs2[4];
caps->isX86=1;
memset(caps, 0, sizeof(*caps));
if (!has_cpuid()) {
printf("CPUID not supported!???\n");
return;
}
do_cpuid(0x00000000, regs); // get _max_ cpuid level and vendor name
printf("CPU vendor name: %.4s%.4s%.4s max cpuid level: %d\n",
(char*) (regs+1),(char*) (regs+3),(char*) (regs+2), regs[0]);
if (regs[0]>=0x00000001)
{
char *tmpstr;
do_cpuid(0x00000001, regs2);
tmpstr=GetCpuFriendlyName(regs, regs2);
printf("CPU: %s ",tmpstr);
free(tmpstr);
caps->cpuType=(regs2[0] >> 8)&0xf;
if(caps->cpuType==0xf){
// use extended family (P4, IA64)
caps->cpuType=8+((regs2[0]>>20)&255);
}
caps->cpuStepping=regs2[0] & 0xf;
printf("(Type: %d, Stepping: %d)\n",
caps->cpuType, caps->cpuStepping);
// general feature flags:
caps->hasMMX = (regs2[3] & (1 << 23 )) >> 23; // 0x0800000
caps->hasSSE = (regs2[3] & (1 << 25 )) >> 25; // 0x2000000
caps->hasSSE2 = (regs2[3] & (1 << 26 )) >> 26; // 0x4000000
caps->hasMMX2 = caps->hasSSE; // SSE cpus supports mmxext too
}
do_cpuid(0x80000000, regs);
if (regs[0]>=0x80000001) {
printf("extended cpuid-level: %d\n",regs[0]&0x7FFFFFFF);
do_cpuid(0x80000001, regs2);
caps->hasMMX |= (regs2[3] & (1 << 23 )) >> 23; // 0x0800000
caps->hasMMX2 |= (regs2[3] & (1 << 22 )) >> 22; // 0x400000
caps->has3DNow = (regs2[3] & (1 << 31 )) >> 31; //0x80000000
caps->has3DNowExt = (regs2[3] & (1 << 30 )) >> 30;
}
#if 0
printf("cpudetect: MMX=%d MMX2=%d SSE=%d SSE2=%d 3DNow=%d 3DNowExt=%d\n",
gCpuCaps.hasMMX,
gCpuCaps.hasMMX2,
gCpuCaps.hasSSE,
gCpuCaps.hasSSE2,
gCpuCaps.has3DNow,
gCpuCaps.has3DNowExt );
#endif
/* FIXME: Does SSE2 need more OS support, too? */
#if defined(__linux__) || defined(__FreeBSD__)
if (caps->hasSSE)
check_os_katmai_support();
if (!caps->hasSSE)
caps->hasSSE2 = 0;
#else
caps->hasSSE=0;
caps->hasSSE2 = 0;
#endif
// caps->has3DNow=1;
// caps->hasMMX2 = 0;
// caps->hasMMX = 0;
#ifndef HAVE_MMX
if(caps->hasMMX) printf("MMX supported but disabled\n");
caps->hasMMX=0;
#endif
#ifndef HAVE_MMX2
if(caps->hasMMX2) printf("MMX2 supported but disabled\n");
caps->hasMMX2=0;
#endif
#ifndef HAVE_SSE
if(caps->hasSSE) printf("SSE supported but disabled\n");
caps->hasSSE=0;
#endif
#ifndef HAVE_SSE2
if(caps->hasSSE2) printf("SSE2 supported but disabled\n");
caps->hasSSE2=0;
#endif
#ifndef HAVE_3DNOW
if(caps->has3DNow) printf("3DNow supported but disabled\n");
caps->has3DNow=0;
#endif
#ifndef HAVE_3DNOWEX
if(caps->has3DNowExt) printf("3DNowExt supported but disabled\n");
caps->has3DNowExt=0;
#endif
}
#define CPUID_EXTFAMILY ((regs2[0] >> 20)&0xFF) /* 27..20 */
#define CPUID_EXTMODEL ((regs2[0] >> 16)&0x0F) /* 19..16 */
#define CPUID_TYPE ((regs2[0] >> 12)&0x04) /* 13..12 */
#define CPUID_FAMILY ((regs2[0] >> 8)&0x0F) /* 11..08 */
#define CPUID_MODEL ((regs2[0] >> 4)&0x0F) /* 07..04 */
#define CPUID_STEPPING ((regs2[0] >> 0)&0x0F) /* 03..00 */
char *GetCpuFriendlyName(unsigned int regs[], unsigned int regs2[]){
#include "cputable.h" /* get cpuname and cpuvendors */
char vendor[17];
char *retname;
int i;
if (NULL==(retname=(char*)malloc(256))) {
printf("Error: GetCpuFriendlyName() not enough memory\n");
exit(1);
}
sprintf(vendor,"%.4s%.4s%.4s",(char*)(regs+1),(char*)(regs+3),(char*)(regs+2));
for(i=0; i<MAX_VENDORS; i++){
if(!strcmp(cpuvendors[i].string,vendor)){
if(cpuname[i][CPUID_FAMILY][CPUID_MODEL]){
snprintf(retname,255,"%s %s",cpuvendors[i].name,cpuname[i][CPUID_FAMILY][CPUID_MODEL]);
} else {
snprintf(retname,255,"unknown %s %d. Generation CPU",cpuvendors[i].name,CPUID_FAMILY);
printf("unknown %s CPU:\n",cpuvendors[i].name);
printf("Vendor: %s\n",cpuvendors[i].string);
printf("Type: %d\n",CPUID_TYPE);
printf("Family: %d (ext: %d)\n",CPUID_FAMILY,CPUID_EXTFAMILY);
printf("Model: %d (ext: %d)\n",CPUID_MODEL,CPUID_EXTMODEL);
printf("Stepping: %d\n",CPUID_STEPPING);
printf("Please send the above info along with the exact CPU name"
"to the MPlayer-Developers, so we can add it to the list!\n");
}
}
}
//printf("Detected CPU: %s\n", retname);
return retname;
}
#undef CPUID_EXTFAMILY
#undef CPUID_EXTMODEL
#undef CPUID_TYPE
#undef CPUID_FAMILY
#undef CPUID_MODEL
#undef CPUID_STEPPING
#if defined(__linux__) && defined(_POSIX_SOURCE) && defined(X86_FXSR_MAGIC)
static void sigill_handler_sse( int signal, struct sigcontext sc )
{
printf( "SIGILL, " );
/* Both the "xorps %%xmm0,%%xmm0" and "divps %xmm0,%%xmm1"
* instructions are 3 bytes long. We must increment the instruction
* pointer manually to avoid repeated execution of the offending
* instruction.
*
* If the SIGILL is caused by a divide-by-zero when unmasked
* exceptions aren't supported, the SIMD FPU status and control
* word will be restored at the end of the test, so we don't need
* to worry about doing it here. Besides, we may not be able to...
*/
sc.eip += 3;
gCpuCaps.hasSSE=0;
}
static void sigfpe_handler_sse( int signal, struct sigcontext sc )
{
printf( "SIGFPE, " );
if ( sc.fpstate->magic != 0xffff ) {
/* Our signal context has the extended FPU state, so reset the
* divide-by-zero exception mask and clear the divide-by-zero
* exception bit.
*/
sc.fpstate->mxcsr |= 0x00000200;
sc.fpstate->mxcsr &= 0xfffffffb;
} else {
/* If we ever get here, we're completely hosed.
*/
printf( "\n\n" );
printf( "SSE enabling test failed badly!" );
}
}
#endif /* __linux__ && _POSIX_SOURCE && X86_FXSR_MAGIC */
/* If we're running on a processor that can do SSE, let's see if we
* are allowed to or not. This will catch 2.4.0 or later kernels that
* haven't been configured for a Pentium III but are running on one,
* and RedHat patched 2.2 kernels that have broken exception handling
* support for user space apps that do SSE.
*/
static void check_os_katmai_support( void )
{
#if defined(__FreeBSD__)
int has_sse=0, ret;
size_t len=sizeof(has_sse);
ret = sysctlbyname("hw.instruction_sse", &has_sse, &len, NULL, 0);
if (ret || !has_sse)
gCpuCaps.hasSSE=0;
#elif defined(__linux__)
#if defined(_POSIX_SOURCE) && defined(X86_FXSR_MAGIC)
struct sigaction saved_sigill;
struct sigaction saved_sigfpe;
/* Save the original signal handlers.
*/
sigaction( SIGILL, NULL, &saved_sigill );
sigaction( SIGFPE, NULL, &saved_sigfpe );
signal( SIGILL, (void (*)(int))sigill_handler_sse );
signal( SIGFPE, (void (*)(int))sigfpe_handler_sse );
/* Emulate test for OSFXSR in CR4. The OS will set this bit if it
* supports the extended FPU save and restore required for SSE. If
* we execute an SSE instruction on a PIII and get a SIGILL, the OS
* doesn't support Streaming SIMD Exceptions, even if the processor
* does.
*/
if ( gCpuCaps.hasSSE ) {
printf( "Testing OS support for SSE... " );
// __asm __volatile ("xorps %%xmm0, %%xmm0");
__asm __volatile ("xorps %xmm0, %xmm0");
if ( gCpuCaps.hasSSE ) {
printf( "yes.\n" );
} else {
printf( "no!\n" );
}
}
/* Emulate test for OSXMMEXCPT in CR4. The OS will set this bit if
* it supports unmasked SIMD FPU exceptions. If we unmask the
* exceptions, do a SIMD divide-by-zero and get a SIGILL, the OS
* doesn't support unmasked SIMD FPU exceptions. If we get a SIGFPE
* as expected, we're okay but we need to clean up after it.
*
* Are we being too stringent in our requirement that the OS support
* unmasked exceptions? Certain RedHat 2.2 kernels enable SSE by
* setting CR4.OSFXSR but don't support unmasked exceptions. Win98
* doesn't even support them. We at least know the user-space SSE
* support is good in kernels that do support unmasked exceptions,
* and therefore to be safe I'm going to leave this test in here.
*/
if ( gCpuCaps.hasSSE ) {
printf( "Testing OS support for SSE unmasked exceptions... " );
// test_os_katmai_exception_support();
if ( gCpuCaps.hasSSE ) {
printf( "yes.\n" );
} else {
printf( "no!\n" );
}
}
/* Restore the original signal handlers.
*/
sigaction( SIGILL, &saved_sigill, NULL );
sigaction( SIGFPE, &saved_sigfpe, NULL );
/* If we've gotten to here and the XMM CPUID bit is still set, we're
* safe to go ahead and hook out the SSE code throughout Mesa.
*/
if ( gCpuCaps.hasSSE ) {
printf( "Tests of OS support for SSE passed.\n" );
} else {
printf( "Tests of OS support for SSE failed!\n" );
}
#else
/* We can't use POSIX signal handling to test the availability of
* SSE, so we disable it by default.
*/
printf( "Cannot test OS support for SSE, disabling to be safe.\n" );
gCpuCaps.hasSSE=0;
#endif /* _POSIX_SOURCE && X86_FXSR_MAGIC */
#else
/* Do nothing on other platforms for now.
*/
printf( "Not testing OS support for SSE, leaving disabled.\n" );
gCpuCaps.hasSSE=0;
#endif /* __linux__ */
}
#else /* ARCH_X86 */
void GetCpuCaps( CpuCaps *caps)
{
caps->cpuType=0;
caps->cpuStepping=0;
caps->hasMMX=0;
caps->hasMMX2=0;
caps->has3DNow=0;
caps->has3DNowExt=0;
caps->hasSSE=0;
caps->hasSSE2=0;
caps->isX86=0;
}
#endif /* !ARCH_X86 */