/* * Copyright (C) 2017-2018 Intel Corporation * * SPDX-License-Identifier: MIT * */ #include "runtime/command_queue/local_id_gen.h" #include "runtime/helpers/aligned_memory.h" #include "runtime/utilities/cpu_info.h" #include namespace OCLRT { struct uint16x8_t; struct uint16x16_t; // This is the initial value of SIMD for local ID // computation. It correlates to the SIMD lane. // Must be 32byte aligned for AVX2 usage ALIGNAS(32) const uint16_t initialLocalID[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31}; // Lookup table for generating LocalIDs based on the SIMD of the kernel void (*LocalIDHelper::generateSimd8)(void *buffer, const std::array &localWorkgroupSize, uint16_t threadsPerWorkGroup, const std::array &dimensionsOrder) = generateLocalIDsSimd; void (*LocalIDHelper::generateSimd16)(void *buffer, const std::array &localWorkgroupSize, uint16_t threadsPerWorkGroup, const std::array &dimensionsOrder) = generateLocalIDsSimd; void (*LocalIDHelper::generateSimd32)(void *buffer, const std::array &localWorkgroupSize, uint16_t threadsPerWorkGroup, const std::array &dimensionsOrder) = generateLocalIDsSimd; // Initialize the lookup table based on CPU capabilities LocalIDHelper::LocalIDHelper() { bool supportsAVX2 = CpuInfo::getInstance().isFeatureSupported(CpuInfo::featureAvX2); if (supportsAVX2) { LocalIDHelper::generateSimd8 = generateLocalIDsSimd; LocalIDHelper::generateSimd16 = generateLocalIDsSimd; LocalIDHelper::generateSimd32 = generateLocalIDsSimd; } } LocalIDHelper LocalIDHelper::initializer; //traditional function to generate local IDs void generateLocalIDs(void *buffer, uint16_t simd, const std::array &localWorkgroupSize, const std::array &dimensionsOrder, bool isImageOnlyKernel) { auto threadsPerWorkGroup = static_cast(getThreadsPerWG(simd, localWorkgroupSize[0] * localWorkgroupSize[1] * localWorkgroupSize[2])); bool useLayoutForImages = isImageOnlyKernel && isCompatibleWithLayoutForImages(localWorkgroupSize, dimensionsOrder, simd); if (useLayoutForImages) { generateLocalIDsWithLayoutForImages(buffer, localWorkgroupSize, simd); } else if (simd == 32) { LocalIDHelper::generateSimd32(buffer, localWorkgroupSize, threadsPerWorkGroup, dimensionsOrder); } else if (simd == 16) { LocalIDHelper::generateSimd16(buffer, localWorkgroupSize, threadsPerWorkGroup, dimensionsOrder); } else { LocalIDHelper::generateSimd8(buffer, localWorkgroupSize, threadsPerWorkGroup, dimensionsOrder); } } bool isCompatibleWithLayoutForImages(const std::array &localWorkgroupSize, const std::array &dimensionsOrder, uint16_t simd) { uint8_t xMask = simd == 8u ? 0b1 : 0b11; uint8_t yMask = 0b11; return dimensionsOrder.at(0) == 0 && dimensionsOrder.at(1) == 1 && (localWorkgroupSize.at(0) & xMask) == 0 && (localWorkgroupSize.at(1) & yMask) == 0 && localWorkgroupSize.at(2) == 1u; } inline void generateLocalIDsWithLayoutForImages(void *b, const std::array &localWorkgroupSize, uint16_t simd) { uint8_t rowWidth = simd == 32u ? 32u : 16u; uint8_t xDelta = simd == 8u ? 2u : 4u; // difference between corresponding values in consecutive X rows uint8_t yDelta = (simd == 8u || localWorkgroupSize.at(1) == 4u) ? 4u : rowWidth / xDelta; // difference between corresponding values in consecutive Y rows auto buffer = reinterpret_cast(b); uint16_t offset = 0u; auto numGrfs = (localWorkgroupSize.at(0) * localWorkgroupSize.at(1) * localWorkgroupSize.at(2) + (simd - 1)) / simd; uint8_t xMask = simd == 8u ? 0b1 : 0b11; uint16_t x = 0u; uint16_t y = 0u; for (auto grfId = 0; grfId < numGrfs; grfId++) { auto rowX = buffer + offset; auto rowY = buffer + offset + rowWidth; auto rowZ = buffer + offset + 2 * rowWidth; uint16_t extraX = 0u; uint16_t extraY = 0u; for (uint8_t i = 0u; i < simd; i++) { if (i > 0) { extraX++; if (extraX == xDelta) { extraX = 0u; } if ((i & xMask) == 0) { extraY++; if (y + extraY == localWorkgroupSize.at(1)) { extraY = 0; x += xDelta; } } } if (x == localWorkgroupSize.at(0)) { x = 0u; y += yDelta; if (y >= localWorkgroupSize.at(1)) { y = 0u; } } rowX[i] = x + extraX; rowY[i] = y + extraY; rowZ[i] = 0u; } x += xDelta; offset += 3 * rowWidth; } } } // namespace OCLRT