/* * kmp_utility.cpp -- Utility routines for the OpenMP support library. */ //===----------------------------------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.txt for details. // //===----------------------------------------------------------------------===// #include "kmp.h" #include "kmp_wrapper_getpid.h" #include "kmp_str.h" #include #include "kmp_i18n.h" /* ------------------------------------------------------------------------ */ /* ------------------------------------------------------------------------ */ static const char *unknown = "unknown"; #if KMP_ARCH_X86 || KMP_ARCH_X86_64 /* NOTE: If called before serial_initialize (i.e. from runtime_initialize), then */ /* the debugging package has not been initialized yet, and only "0" will print */ /* debugging output since the environment variables have not been read. */ #ifdef KMP_DEBUG static int trace_level = 5; #endif /* * LOG_ID_BITS = ( 1 + floor( log_2( max( log_per_phy - 1, 1 )))) * APIC_ID = (PHY_ID << LOG_ID_BITS) | LOG_ID * PHY_ID = APIC_ID >> LOG_ID_BITS */ int __kmp_get_physical_id( int log_per_phy, int apic_id ) { int index_lsb, index_msb, temp; if (log_per_phy > 1) { index_lsb = 0; index_msb = 31; temp = log_per_phy; while ( (temp & 1) == 0 ) { temp >>= 1; index_lsb++; } temp = log_per_phy; while ( (temp & 0x80000000)==0 ) { temp <<= 1; index_msb--; } /* If >1 bits were set in log_per_phy, choose next higher power of 2 */ if (index_lsb != index_msb) index_msb++; return ( (int) (apic_id >> index_msb) ); } return apic_id; } /* * LOG_ID_BITS = ( 1 + floor( log_2( max( log_per_phy - 1, 1 )))) * APIC_ID = (PHY_ID << LOG_ID_BITS) | LOG_ID * LOG_ID = APIC_ID & (( 1 << LOG_ID_BITS ) - 1 ) */ int __kmp_get_logical_id( int log_per_phy, int apic_id ) { unsigned current_bit; int bits_seen; if (log_per_phy <= 1) return ( 0 ); bits_seen = 0; for (current_bit = 1; log_per_phy != 0; current_bit <<= 1) { if ( log_per_phy & current_bit ) { log_per_phy &= ~current_bit; bits_seen++; } } /* If exactly 1 bit was set in log_per_phy, choose next lower power of 2 */ if (bits_seen == 1) { current_bit >>= 1; } return ( (int) ((current_bit - 1) & apic_id) ); } static kmp_uint64 __kmp_parse_frequency( // R: Frequency in Hz. char const * frequency // I: Float number and unit: MHz, GHz, or TGz. ) { double value = 0.0; char const * unit = NULL; kmp_uint64 result = 0; /* Zero is a better unknown value than all ones. */ if ( frequency == NULL ) { return result; }; // if value = strtod( frequency, (char * *) & unit ); // strtod() does not like "char const *". if ( 0 < value && value <= DBL_MAX ) { // Good value (not overflow, underflow, etc). if ( strcmp( unit, "MHz" ) == 0 ) { value = value * 1.0E+6; } else if ( strcmp( unit, "GHz" ) == 0 ) { value = value * 1.0E+9; } else if ( strcmp( unit, "THz" ) == 0 ) { value = value * 1.0E+12; } else { // Wrong unit. return result; }; // if result = value; }; // if return result; }; // func __kmp_parse_cpu_frequency void __kmp_query_cpuid( kmp_cpuinfo_t *p ) { struct kmp_cpuid buf; int max_arg; int log_per_phy; #ifdef KMP_DEBUG int cflush_size; #endif p->initialized = 1; p->sse2 = 1; // Assume SSE2 by default. __kmp_x86_cpuid( 0, 0, &buf ); KA_TRACE( trace_level, ("INFO: CPUID %d: EAX=0x%08X EBX=0x%08X ECX=0x%08X EDX=0x%08X\n", 0, buf.eax, buf.ebx, buf.ecx, buf.edx ) ); max_arg = buf.eax; p->apic_id = -1; if (max_arg >= 1) { int i; kmp_uint32 t, data[ 4 ]; __kmp_x86_cpuid( 1, 0, &buf ); KA_TRACE( trace_level, ("INFO: CPUID %d: EAX=0x%08X EBX=0x%08X ECX=0x%08X EDX=0x%08X\n", 1, buf.eax, buf.ebx, buf.ecx, buf.edx ) ); { #define get_value(reg,lo,mask) ( ( ( reg ) >> ( lo ) ) & ( mask ) ) p->signature = buf.eax; p->family = get_value( buf.eax, 20, 0xff ) + get_value( buf.eax, 8, 0x0f ); p->model = ( get_value( buf.eax, 16, 0x0f ) << 4 ) + get_value( buf.eax, 4, 0x0f ); p->stepping = get_value( buf.eax, 0, 0x0f ); #undef get_value KA_TRACE( trace_level, (" family = %d, model = %d, stepping = %d\n", p->family, p->model, p->stepping ) ); } for ( t = buf.ebx, i = 0; i < 4; t >>= 8, ++i ) { data[ i ] = (t & 0xff); }; // for p->sse2 = ( buf.edx >> 26 ) & 1; #ifdef KMP_DEBUG if ( (buf.edx >> 4) & 1 ) { /* TSC - Timestamp Counter Available */ KA_TRACE( trace_level, (" TSC" ) ); } if ( (buf.edx >> 8) & 1 ) { /* CX8 - CMPXCHG8B Instruction Available */ KA_TRACE( trace_level, (" CX8" ) ); } if ( (buf.edx >> 9) & 1 ) { /* APIC - Local APIC Present (multi-processor operation support */ KA_TRACE( trace_level, (" APIC" ) ); } if ( (buf.edx >> 15) & 1 ) { /* CMOV - Conditional MOVe Instruction Available */ KA_TRACE( trace_level, (" CMOV" ) ); } if ( (buf.edx >> 18) & 1 ) { /* PSN - Processor Serial Number Available */ KA_TRACE( trace_level, (" PSN" ) ); } if ( (buf.edx >> 19) & 1 ) { /* CLFULSH - Cache Flush Instruction Available */ cflush_size = data[ 1 ] * 8; /* Bits 15-08: CLFLUSH line size = 8 (64 bytes) */ KA_TRACE( trace_level, (" CLFLUSH(%db)", cflush_size ) ); } if ( (buf.edx >> 21) & 1 ) { /* DTES - Debug Trace & EMON Store */ KA_TRACE( trace_level, (" DTES" ) ); } if ( (buf.edx >> 22) & 1 ) { /* ACPI - ACPI Support Available */ KA_TRACE( trace_level, (" ACPI" ) ); } if ( (buf.edx >> 23) & 1 ) { /* MMX - Multimedia Extensions */ KA_TRACE( trace_level, (" MMX" ) ); } if ( (buf.edx >> 25) & 1 ) { /* SSE - SSE Instructions */ KA_TRACE( trace_level, (" SSE" ) ); } if ( (buf.edx >> 26) & 1 ) { /* SSE2 - SSE2 Instructions */ KA_TRACE( trace_level, (" SSE2" ) ); } if ( (buf.edx >> 27) & 1 ) { /* SLFSNP - Self-Snooping Cache */ KA_TRACE( trace_level, (" SLFSNP" ) ); } #endif /* KMP_DEBUG */ if ( (buf.edx >> 28) & 1 ) { /* Bits 23-16: Logical Processors per Physical Processor (1 for P4) */ log_per_phy = data[ 2 ]; p->apic_id = data[ 3 ]; /* Bits 31-24: Processor Initial APIC ID (X) */ KA_TRACE( trace_level, (" HT(%d TPUs)", log_per_phy ) ); if( log_per_phy > 1 ) { /* default to 1k FOR JT-enabled processors (4k on OS X*) */ #if KMP_OS_DARWIN p->cpu_stackoffset = 4 * 1024; #else p->cpu_stackoffset = 1 * 1024; #endif } p->physical_id = __kmp_get_physical_id( log_per_phy, p->apic_id ); p->logical_id = __kmp_get_logical_id( log_per_phy, p->apic_id ); } #ifdef KMP_DEBUG if ( (buf.edx >> 29) & 1 ) { /* ATHROTL - Automatic Throttle Control */ KA_TRACE( trace_level, (" ATHROTL" ) ); } KA_TRACE( trace_level, (" ]\n" ) ); for (i = 2; i <= max_arg; ++i) { __kmp_x86_cpuid( i, 0, &buf ); KA_TRACE( trace_level, ( "INFO: CPUID %d: EAX=0x%08X EBX=0x%08X ECX=0x%08X EDX=0x%08X\n", i, buf.eax, buf.ebx, buf.ecx, buf.edx ) ); } #endif #if KMP_USE_ADAPTIVE_LOCKS p->rtm = 0; if (max_arg > 7) { /* RTM bit CPUID.07:EBX, bit 11 */ __kmp_x86_cpuid(7, 0, &buf); p->rtm = (buf.ebx >> 11) & 1; KA_TRACE( trace_level, (" RTM" ) ); } #endif }; // if { // Parse CPU brand string for frequency, saving the string for later. int i; kmp_cpuid_t * base = (kmp_cpuid_t *)&p->name[0]; // Get CPU brand string. for ( i = 0; i < 3; ++ i ) { __kmp_x86_cpuid( 0x80000002 + i, 0, base+i ); }; // for p->name[ sizeof(p->name) - 1 ] = 0; // Just in case. ;-) KA_TRACE( trace_level, ( "cpu brand string: \"%s\"\n", &p->name[0] ) ); // Parse frequency. p->frequency = __kmp_parse_frequency( strrchr( &p->name[0], ' ' ) ); KA_TRACE( trace_level, ( "cpu frequency from brand string: %" KMP_UINT64_SPEC "\n", p->frequency ) ); } } #endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ /* ------------------------------------------------------------------------------------ */ /* ------------------------------------------------------------------------------------ */ void __kmp_expand_host_name( char *buffer, size_t size ) { KMP_DEBUG_ASSERT(size >= sizeof(unknown)); #if KMP_OS_WINDOWS { DWORD s = size; if (! GetComputerNameA( buffer, & s )) KMP_STRCPY_S( buffer, size, unknown ); } #else buffer[size - 2] = 0; if (gethostname( buffer, size ) || buffer[size - 2] != 0) KMP_STRCPY_S( buffer, size, unknown ); #endif } /* Expand the meta characters in the filename: * * Currently defined characters are: * * %H the hostname * %P the number of threads used. * %I the unique identifier for this run. */ void __kmp_expand_file_name( char *result, size_t rlen, char *pattern ) { char *pos = result, *end = result + rlen - 1; char buffer[256]; int default_cpu_width = 1; int snp_result; KMP_DEBUG_ASSERT(rlen > 0); *end = 0; { int i; for(i = __kmp_xproc; i >= 10; i /= 10, ++default_cpu_width); } if (pattern != NULL) { while (*pattern != '\0' && pos < end) { if (*pattern != '%') { *pos++ = *pattern++; } else { char *old_pattern = pattern; int width = 1; int cpu_width = default_cpu_width; ++pattern; if (*pattern >= '0' && *pattern <= '9') { width = 0; do { width = (width * 10) + *pattern++ - '0'; } while (*pattern >= '0' && *pattern <= '9'); if (width < 0 || width > 1024) width = 1; cpu_width = width; } switch (*pattern) { case 'H': case 'h': { __kmp_expand_host_name( buffer, sizeof( buffer ) ); KMP_STRNCPY( pos, buffer, end - pos + 1); if(*end == 0) { while ( *pos ) ++pos; ++pattern; } else pos = end; } break; case 'P': case 'p': { snp_result = KMP_SNPRINTF( pos, end - pos + 1, "%0*d", cpu_width, __kmp_dflt_team_nth ); if(snp_result >= 0 && snp_result <= end - pos) { while ( *pos ) ++pos; ++pattern; } else pos = end; } break; case 'I': case 'i': { pid_t id = getpid(); snp_result = KMP_SNPRINTF( pos, end - pos + 1, "%0*d", width, id ); if(snp_result >= 0 && snp_result <= end - pos) { while ( *pos ) ++pos; ++pattern; } else pos = end; break; } case '%': { *pos++ = '%'; ++pattern; break; } default: { *pos++ = '%'; pattern = old_pattern + 1; break; } } } } /* TODO: How do we get rid of this? */ if(*pattern != '\0') KMP_FATAL( FileNameTooLong ); } *pos = '\0'; }