static intx allocate_prefetch_distance() { // This method should be called before allocate_prefetch_style(). // // Hardware prefetching (distance/size in bytes): // Pentium 3 - 64 / 32 // Pentium 4 - 256 / 128 // Athlon - 64 / 32 ???? // Opteron - 128 / 64 only when 2 sequential cache lines accessed // Core - 128 / 64 // // Software prefetching (distance in bytes / instruction with best score): // Pentium 3 - 128 / prefetchnta // Pentium 4 - 512 / prefetchnta // Athlon - 128 / prefetchnta // Opteron - 256 / prefetchnta // Core - 256 / prefetchnta // It will be used only when AllocatePrefetchStyle > 0 intx count = AllocatePrefetchDistance; if (count < 0) { // default ? if (is_amd()) { // AMD if (supports_sse2()) count = 256; // Opteron else count = 128; // Athlon } else { // Intel if (supports_sse2()) if (cpu_family() == 6) { count = 256; // Pentium M, Core, Core2 } else { count = 512; // Pentium 4 } else count = 128; // Pentium 3 (and all other old CPUs) } } return count; }
void Downscaler::DownscaleInputLine() { typedef skia::ConvolutionFilter1D::Fixed FilterValue; MOZ_ASSERT(mOutputBuffer); MOZ_ASSERT(mCurrentOutLine < mTargetSize.height, "Writing past end of output"); int32_t filterOffset = 0; int32_t filterLength = 0; MOZ_ASSERT(mCurrentOutLine < mYFilter->num_values()); auto filterValues = mYFilter->FilterForValue(mCurrentOutLine, &filterOffset, &filterLength); int32_t currentOutLine = mFlipVertically ? mTargetSize.height - (mCurrentOutLine + 1) : mCurrentOutLine; MOZ_ASSERT(currentOutLine >= 0); uint8_t* outputLine = &mOutputBuffer[currentOutLine * mTargetSize.width * sizeof(uint32_t)]; skia::ConvolveVertically(static_cast<const FilterValue*>(filterValues), filterLength, mWindow.get(), mXFilter->num_values(), outputLine, mHasAlpha, supports_sse2()); mCurrentOutLine += 1; if (mCurrentOutLine == mTargetSize.height) { // We're done. return; } int32_t newFilterOffset = 0; int32_t newFilterLength = 0; GetFilterOffsetAndLength(mYFilter, mCurrentOutLine, &newFilterOffset, &newFilterLength); int diff = newFilterOffset - filterOffset; MOZ_ASSERT(diff >= 0, "Moving backwards in the filter?"); // Shift the buffer. We're just moving pointers here, so this is cheap. mLinesInBuffer -= diff; mLinesInBuffer = max(mLinesInBuffer, 0); for (int32_t i = 0; i < mLinesInBuffer; ++i) { swap(mWindow[i], mWindow[filterLength - mLinesInBuffer + i]); } }
void Downscaler::CommitRow() { MOZ_ASSERT(mOutputBuffer, "Should have a current frame"); MOZ_ASSERT(mCurrentInLine < mOriginalSize.height, "Past end of input"); MOZ_ASSERT(mCurrentOutLine < mTargetSize.height, "Past end of output"); int32_t filterOffset = 0; int32_t filterLength = 0; GetFilterOffsetAndLength(mYFilter, mCurrentOutLine, &filterOffset, &filterLength); int32_t inLineToRead = filterOffset + mLinesInBuffer; MOZ_ASSERT(mCurrentInLine <= inLineToRead, "Reading past end of input"); if (mCurrentInLine == inLineToRead) { skia::ConvolveHorizontally(mRowBuffer.get(), *mXFilter, mWindow[mLinesInBuffer++], mHasAlpha, supports_sse2()); } MOZ_ASSERT(mCurrentOutLine < mTargetSize.height, "Writing past end of output"); while (mLinesInBuffer == filterLength) { DownscaleInputLine(); if (mCurrentOutLine == mTargetSize.height) { break; // We're done. } GetFilterOffsetAndLength(mYFilter, mCurrentOutLine, &filterOffset, &filterLength); } mCurrentInLine += 1; // If we're at the end of the part of the original image that has data, commit // rows to shift us to the end. if (mCurrentInLine == (mFrameRect.y + mFrameRect.height)) { SkipToRow(mOriginalSize.height - 1); } }
void VM_Version::get_processor_features() { _cpu = 4; // 486 by default _model = 0; _stepping = 0; _cpuFeatures = 0; _logical_processors_per_package = 1; if (!Use486InstrsOnly) { // Get raw processor info getPsrInfo_stub(&_cpuid_info); assert_is_initialized(); _cpu = extended_cpu_family(); _model = extended_cpu_model(); _stepping = cpu_stepping(); if (cpu_family() > 4) { // it supports CPUID _cpuFeatures = feature_flags(); // Logical processors are only available on P4s and above, // and only if hyperthreading is available. _logical_processors_per_package = logical_processor_count(); } } _supports_cx8 = supports_cmpxchg8(); #ifdef _LP64 // OS should support SSE for x64 and hardware should support at least SSE2. if (!VM_Version::supports_sse2()) { vm_exit_during_initialization("Unknown x64 processor: SSE2 not supported"); } // in 64 bit the use of SSE2 is the minimum if (UseSSE < 2) UseSSE = 2; #endif #ifdef AMD64 // flush_icache_stub have to be generated first. // That is why Icache line size is hard coded in ICache class, // see icache_x86.hpp. It is also the reason why we can't use // clflush instruction in 32-bit VM since it could be running // on CPU which does not support it. // // The only thing we can do is to verify that flushed // ICache::line_size has correct value. guarantee(_cpuid_info.std_cpuid1_edx.bits.clflush != 0, "clflush is not supported"); // clflush_size is size in quadwords (8 bytes). guarantee(_cpuid_info.std_cpuid1_ebx.bits.clflush_size == 8, "such clflush size is not supported"); #endif // If the OS doesn't support SSE, we can't use this feature even if the HW does if (!os::supports_sse()) _cpuFeatures &= ~(CPU_SSE|CPU_SSE2|CPU_SSE3|CPU_SSSE3|CPU_SSE4A|CPU_SSE4_1|CPU_SSE4_2); if (UseSSE < 4) { _cpuFeatures &= ~CPU_SSE4_1; _cpuFeatures &= ~CPU_SSE4_2; } if (UseSSE < 3) { _cpuFeatures &= ~CPU_SSE3; _cpuFeatures &= ~CPU_SSSE3; _cpuFeatures &= ~CPU_SSE4A; } if (UseSSE < 2) _cpuFeatures &= ~CPU_SSE2; if (UseSSE < 1) _cpuFeatures &= ~CPU_SSE; if (UseAVX < 2) _cpuFeatures &= ~CPU_AVX2; if (UseAVX < 1) _cpuFeatures &= ~CPU_AVX; if (logical_processors_per_package() == 1) { // HT processor could be installed on a system which doesn't support HT. _cpuFeatures &= ~CPU_HT; } char buf[256]; jio_snprintf(buf, sizeof(buf), "(%u cores per cpu, %u threads per core) family %d model %d stepping %d%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s", cores_per_cpu(), threads_per_core(), cpu_family(), _model, _stepping, (supports_cmov() ? ", cmov" : ""), (supports_cmpxchg8() ? ", cx8" : ""), (supports_fxsr() ? ", fxsr" : ""), (supports_mmx() ? ", mmx" : ""), (supports_sse() ? ", sse" : ""), (supports_sse2() ? ", sse2" : ""), (supports_sse3() ? ", sse3" : ""), (supports_ssse3()? ", ssse3": ""), (supports_sse4_1() ? ", sse4.1" : ""), (supports_sse4_2() ? ", sse4.2" : ""), (supports_popcnt() ? ", popcnt" : ""), (supports_avx() ? ", avx" : ""), (supports_avx2() ? ", avx2" : ""), (supports_mmx_ext() ? ", mmxext" : ""), (supports_3dnow_prefetch() ? ", 3dnowpref" : ""), (supports_lzcnt() ? ", lzcnt": ""), (supports_sse4a() ? ", sse4a": ""), (supports_ht() ? ", ht": ""), (supports_tsc() ? ", tsc": ""), (supports_tscinv_bit() ? ", tscinvbit": ""), (supports_tscinv() ? ", tscinv": "")); _features_str = strdup(buf); // UseSSE is set to the smaller of what hardware supports and what // the command line requires. I.e., you cannot set UseSSE to 2 on // older Pentiums which do not support it. if (UseSSE > 4) UseSSE=4; if (UseSSE < 0) UseSSE=0; if (!supports_sse4_1()) // Drop to 3 if no SSE4 support UseSSE = MIN2((intx)3,UseSSE); if (!supports_sse3()) // Drop to 2 if no SSE3 support UseSSE = MIN2((intx)2,UseSSE); if (!supports_sse2()) // Drop to 1 if no SSE2 support UseSSE = MIN2((intx)1,UseSSE); if (!supports_sse ()) // Drop to 0 if no SSE support UseSSE = 0; if (UseAVX > 2) UseAVX=2; if (UseAVX < 0) UseAVX=0; if (!supports_avx2()) // Drop to 1 if no AVX2 support UseAVX = MIN2((intx)1,UseAVX); if (!supports_avx ()) // Drop to 0 if no AVX support UseAVX = 0; // On new cpus instructions which update whole XMM register should be used // to prevent partial register stall due to dependencies on high half. // // UseXmmLoadAndClearUpper == true --> movsd(xmm, mem) // UseXmmLoadAndClearUpper == false --> movlpd(xmm, mem) // UseXmmRegToRegMoveAll == true --> movaps(xmm, xmm), movapd(xmm, xmm). // UseXmmRegToRegMoveAll == false --> movss(xmm, xmm), movsd(xmm, xmm). if( is_amd() ) { // AMD cpus specific settings if( supports_sse2() && FLAG_IS_DEFAULT(UseAddressNop) ) { // Use it on new AMD cpus starting from Opteron. UseAddressNop = true; } if( supports_sse2() && FLAG_IS_DEFAULT(UseNewLongLShift) ) { // Use it on new AMD cpus starting from Opteron. UseNewLongLShift = true; } if( FLAG_IS_DEFAULT(UseXmmLoadAndClearUpper) ) { if( supports_sse4a() ) { UseXmmLoadAndClearUpper = true; // use movsd only on '10h' Opteron } else { UseXmmLoadAndClearUpper = false; } } if( FLAG_IS_DEFAULT(UseXmmRegToRegMoveAll) ) { if( supports_sse4a() ) { UseXmmRegToRegMoveAll = true; // use movaps, movapd only on '10h' } else { UseXmmRegToRegMoveAll = false; } } if( FLAG_IS_DEFAULT(UseXmmI2F) ) { if( supports_sse4a() ) { UseXmmI2F = true; } else { UseXmmI2F = false; } } if( FLAG_IS_DEFAULT(UseXmmI2D) ) { if( supports_sse4a() ) { UseXmmI2D = true; } else { UseXmmI2D = false; } } if( FLAG_IS_DEFAULT(UseSSE42Intrinsics) ) { if( supports_sse4_2() && UseSSE >= 4 ) { UseSSE42Intrinsics = true; } } // Use count leading zeros count instruction if available. if (supports_lzcnt()) { if (FLAG_IS_DEFAULT(UseCountLeadingZerosInstruction)) { UseCountLeadingZerosInstruction = true; } } // some defaults for AMD family 15h if ( cpu_family() == 0x15 ) { // On family 15h processors default is no sw prefetch if (FLAG_IS_DEFAULT(AllocatePrefetchStyle)) { AllocatePrefetchStyle = 0; } // Also, if some other prefetch style is specified, default instruction type is PREFETCHW if (FLAG_IS_DEFAULT(AllocatePrefetchInstr)) { AllocatePrefetchInstr = 3; } // On family 15h processors use XMM and UnalignedLoadStores for Array Copy if( FLAG_IS_DEFAULT(UseXMMForArrayCopy) ) { UseXMMForArrayCopy = true; } if( FLAG_IS_DEFAULT(UseUnalignedLoadStores) && UseXMMForArrayCopy ) { UseUnalignedLoadStores = true; } } } if( is_intel() ) { // Intel cpus specific settings if( FLAG_IS_DEFAULT(UseStoreImmI16) ) { UseStoreImmI16 = false; // don't use it on Intel cpus } if( cpu_family() == 6 || cpu_family() == 15 ) { if( FLAG_IS_DEFAULT(UseAddressNop) ) { // Use it on all Intel cpus starting from PentiumPro UseAddressNop = true; } } if( FLAG_IS_DEFAULT(UseXmmLoadAndClearUpper) ) { UseXmmLoadAndClearUpper = true; // use movsd on all Intel cpus } if( FLAG_IS_DEFAULT(UseXmmRegToRegMoveAll) ) { if( supports_sse3() ) { UseXmmRegToRegMoveAll = true; // use movaps, movapd on new Intel cpus } else { UseXmmRegToRegMoveAll = false; } } if( cpu_family() == 6 && supports_sse3() ) { // New Intel cpus #ifdef COMPILER2 if( FLAG_IS_DEFAULT(MaxLoopPad) ) { // For new Intel cpus do the next optimization: // don't align the beginning of a loop if there are enough instructions // left (NumberOfLoopInstrToAlign defined in c2_globals.hpp) // in current fetch line (OptoLoopAlignment) or the padding // is big (> MaxLoopPad). // Set MaxLoopPad to 11 for new Intel cpus to reduce number of // generated NOP instructions. 11 is the largest size of one // address NOP instruction '0F 1F' (see Assembler::nop(i)). MaxLoopPad = 11; } #endif // COMPILER2 if( FLAG_IS_DEFAULT(UseXMMForArrayCopy) ) { UseXMMForArrayCopy = true; // use SSE2 movq on new Intel cpus } if( supports_sse4_2() && supports_ht() ) { // Newest Intel cpus if( FLAG_IS_DEFAULT(UseUnalignedLoadStores) && UseXMMForArrayCopy ) { UseUnalignedLoadStores = true; // use movdqu on newest Intel cpus } } if( supports_sse4_2() && UseSSE >= 4 ) { if( FLAG_IS_DEFAULT(UseSSE42Intrinsics)) { UseSSE42Intrinsics = true; } } } } // Use population count instruction if available. if (supports_popcnt()) { if (FLAG_IS_DEFAULT(UsePopCountInstruction)) { UsePopCountInstruction = true; } } else if (UsePopCountInstruction) { warning("POPCNT instruction is not available on this CPU"); FLAG_SET_DEFAULT(UsePopCountInstruction, false); } #ifdef COMPILER2 if (UseFPUForSpilling) { if (UseSSE < 2) { // Only supported with SSE2+ FLAG_SET_DEFAULT(UseFPUForSpilling, false); } } #endif assert(0 <= ReadPrefetchInstr && ReadPrefetchInstr <= 3, "invalid value"); assert(0 <= AllocatePrefetchInstr && AllocatePrefetchInstr <= 3, "invalid value"); // set valid Prefetch instruction if( ReadPrefetchInstr < 0 ) ReadPrefetchInstr = 0; if( ReadPrefetchInstr > 3 ) ReadPrefetchInstr = 3; if( ReadPrefetchInstr == 3 && !supports_3dnow_prefetch() ) ReadPrefetchInstr = 0; if( !supports_sse() && supports_3dnow_prefetch() ) ReadPrefetchInstr = 3; if( AllocatePrefetchInstr < 0 ) AllocatePrefetchInstr = 0; if( AllocatePrefetchInstr > 3 ) AllocatePrefetchInstr = 3; if( AllocatePrefetchInstr == 3 && !supports_3dnow_prefetch() ) AllocatePrefetchInstr=0; if( !supports_sse() && supports_3dnow_prefetch() ) AllocatePrefetchInstr = 3; // Allocation prefetch settings intx cache_line_size = prefetch_data_size(); if( cache_line_size > AllocatePrefetchStepSize ) AllocatePrefetchStepSize = cache_line_size; assert(AllocatePrefetchLines > 0, "invalid value"); if( AllocatePrefetchLines < 1 ) // set valid value in product VM AllocatePrefetchLines = 3; assert(AllocateInstancePrefetchLines > 0, "invalid value"); if( AllocateInstancePrefetchLines < 1 ) // set valid value in product VM AllocateInstancePrefetchLines = 1; AllocatePrefetchDistance = allocate_prefetch_distance(); AllocatePrefetchStyle = allocate_prefetch_style(); if( is_intel() && cpu_family() == 6 && supports_sse3() ) { if( AllocatePrefetchStyle == 2 ) { // watermark prefetching on Core #ifdef _LP64 AllocatePrefetchDistance = 384; #else AllocatePrefetchDistance = 320; #endif } if( supports_sse4_2() && supports_ht() ) { // Nehalem based cpus AllocatePrefetchDistance = 192; AllocatePrefetchLines = 4; #ifdef COMPILER2 if (AggressiveOpts && FLAG_IS_DEFAULT(UseFPUForSpilling)) { FLAG_SET_DEFAULT(UseFPUForSpilling, true); } #endif } } assert(AllocatePrefetchDistance % AllocatePrefetchStepSize == 0, "invalid value"); #ifdef _LP64 // Prefetch settings PrefetchCopyIntervalInBytes = prefetch_copy_interval_in_bytes(); PrefetchScanIntervalInBytes = prefetch_scan_interval_in_bytes(); PrefetchFieldsAhead = prefetch_fields_ahead(); #endif #ifndef PRODUCT if (PrintMiscellaneous && Verbose) { tty->print_cr("Logical CPUs per core: %u", logical_processors_per_package()); tty->print("UseSSE=%d",UseSSE); if (UseAVX > 0) { tty->print(" UseAVX=%d",UseAVX); } tty->cr(); tty->print("Allocation"); if (AllocatePrefetchStyle <= 0 || UseSSE == 0 && !supports_3dnow_prefetch()) { tty->print_cr(": no prefetching"); } else { tty->print(" prefetching: "); if (UseSSE == 0 && supports_3dnow_prefetch()) { tty->print("PREFETCHW"); } else if (UseSSE >= 1) { if (AllocatePrefetchInstr == 0) { tty->print("PREFETCHNTA"); } else if (AllocatePrefetchInstr == 1) { tty->print("PREFETCHT0"); } else if (AllocatePrefetchInstr == 2) { tty->print("PREFETCHT2"); } else if (AllocatePrefetchInstr == 3) { tty->print("PREFETCHW"); } } if (AllocatePrefetchLines > 1) { tty->print_cr(" at distance %d, %d lines of %d bytes", AllocatePrefetchDistance, AllocatePrefetchLines, AllocatePrefetchStepSize); } else { tty->print_cr(" at distance %d, one line of %d bytes", AllocatePrefetchDistance, AllocatePrefetchStepSize); } } if (PrefetchCopyIntervalInBytes > 0) { tty->print_cr("PrefetchCopyIntervalInBytes %d", PrefetchCopyIntervalInBytes); } if (PrefetchScanIntervalInBytes > 0) { tty->print_cr("PrefetchScanIntervalInBytes %d", PrefetchScanIntervalInBytes); } if (PrefetchFieldsAhead > 0) { tty->print_cr("PrefetchFieldsAhead %d", PrefetchFieldsAhead); } } #endif // !PRODUCT }