// AsmJit - Machine code generation for C++ // // * Official AsmJit Home Page: https://asmjit.com // * Official Github Repository: https://github.com/asmjit/asmjit // // Copyright (c) 2008-2020 The AsmJit Authors // // This software is provided 'as-is', without any express or implied // warranty. In no event will the authors be held liable for any damages // arising from the use of this software. // // Permission is granted to anyone to use this software for any purpose, // including commercial applications, and to alter it and redistribute it // freely, subject to the following restrictions: // // 1. The origin of this software must not be misrepresented; you must not // claim that you wrote the original software. If you use this software // in a product, an acknowledgment in the product documentation would be // appreciated but is not required. // 2. Altered source versions must be plainly marked as such, and must not be // misrepresented as being the original software. // 3. This notice may not be removed or altered from any source distribution. #include "../core/api-build_p.h" #ifndef ASMJIT_NO_COMPILER #include "../core/rastack_p.h" #include "../core/support.h" ASMJIT_BEGIN_NAMESPACE // ============================================================================ // [asmjit::RAStackAllocator - Slots] // ============================================================================ RAStackSlot* RAStackAllocator::newSlot(uint32_t baseRegId, uint32_t size, uint32_t alignment, uint32_t flags) noexcept { if (ASMJIT_UNLIKELY(_slots.willGrow(allocator(), 1) != kErrorOk)) return nullptr; RAStackSlot* slot = allocator()->allocT(); if (ASMJIT_UNLIKELY(!slot)) return nullptr; slot->_baseRegId = uint8_t(baseRegId); slot->_alignment = uint8_t(Support::max(alignment, 1)); slot->_flags = uint16_t(flags); slot->_useCount = 0; slot->_size = size; slot->_weight = 0; slot->_offset = 0; _alignment = Support::max(_alignment, alignment); _slots.appendUnsafe(slot); return slot; } // ============================================================================ // [asmjit::RAStackAllocator - Utilities] // ============================================================================ struct RAStackGap { inline RAStackGap() noexcept : offset(0), size(0) {} inline RAStackGap(uint32_t offset, uint32_t size) noexcept : offset(offset), size(size) {} inline RAStackGap(const RAStackGap& other) noexcept : offset(other.offset), size(other.size) {} uint32_t offset; uint32_t size; }; Error RAStackAllocator::calculateStackFrame() noexcept { // Base weight added to all registers regardless of their size and alignment. uint32_t kBaseRegWeight = 16; // STEP 1: // // Update usage based on the size of the slot. We boost smaller slots in a way // that 32-bit register has higher priority than a 128-bit register, however, // if one 128-bit register is used 4 times more than some other 32-bit register // it will overweight it. for (RAStackSlot* slot : _slots) { uint32_t alignment = slot->alignment(); ASMJIT_ASSERT(alignment > 0); uint32_t power = Support::min(Support::ctz(alignment), 6); uint64_t weight; if (slot->isRegHome()) weight = kBaseRegWeight + (uint64_t(slot->useCount()) * (7 - power)); else weight = power; // If overflown, which has less chance of winning a lottery, just use max // possible weight. In such case it probably doesn't matter at all. if (weight > 0xFFFFFFFFu) weight = 0xFFFFFFFFu; slot->setWeight(uint32_t(weight)); } // STEP 2: // // Sort stack slots based on their newly calculated weight (in descending order). _slots.sort([](const RAStackSlot* a, const RAStackSlot* b) noexcept { return a->weight() > b->weight() ? 1 : a->weight() == b->weight() ? 0 : -1; }); // STEP 3: // // Calculate offset of each slot. We start from the slot that has the highest // weight and advance to slots with lower weight. It could look that offsets // start from the first slot in our list and then simply increase, but it's // not always the case as we also try to fill all gaps introduced by the fact // that slots are sorted by weight and not by size & alignment, so when we need // to align some slot we distribute the gap caused by the alignment to `gaps`. uint32_t offset = 0; ZoneVector gaps[kSizeCount - 1]; for (RAStackSlot* slot : _slots) { if (slot->isStackArg()) continue; uint32_t slotAlignment = slot->alignment(); uint32_t alignedOffset = Support::alignUp(offset, slotAlignment); // Try to find a slot within gaps first, before advancing the `offset`. bool foundGap = false; uint32_t gapSize = 0; uint32_t gapOffset = 0; { uint32_t slotSize = slot->size(); if (slotSize < (1u << uint32_t(ASMJIT_ARRAY_SIZE(gaps)))) { // Iterate from the lowest to the highest possible. uint32_t index = Support::ctz(slotSize); do { if (!gaps[index].empty()) { RAStackGap gap = gaps[index].pop(); ASMJIT_ASSERT(Support::isAligned(gap.offset, slotAlignment)); slot->setOffset(int32_t(gap.offset)); gapSize = gap.size - slotSize; gapOffset = gap.offset - slotSize; foundGap = true; break; } } while (++index < uint32_t(ASMJIT_ARRAY_SIZE(gaps))); } } // No gap found, we may create a new one(s) if the current offset is not aligned. if (!foundGap && offset != alignedOffset) { gapSize = alignedOffset - offset; gapOffset = alignedOffset; offset = alignedOffset; } // True if we have found a gap and not filled all of it or we aligned the current offset. if (gapSize) { uint32_t gapEnd = gapSize + gapOffset; while (gapOffset < gapEnd) { uint32_t index = Support::ctz(gapOffset); uint32_t slotSize = 1u << index; // Weird case, better to bail... if (gapEnd - gapOffset < slotSize) break; ASMJIT_PROPAGATE(gaps[index].append(allocator(), RAStackGap(gapOffset, slotSize))); gapOffset += slotSize; } } if (!foundGap) { ASMJIT_ASSERT(Support::isAligned(offset, slotAlignment)); slot->setOffset(int32_t(offset)); offset += slot->size(); } } _stackSize = Support::alignUp(offset, _alignment); return kErrorOk; } Error RAStackAllocator::adjustSlotOffsets(int32_t offset) noexcept { for (RAStackSlot* slot : _slots) if (!slot->isStackArg()) slot->_offset += offset; return kErrorOk; } ASMJIT_END_NAMESPACE #endif // !ASMJIT_NO_COMPILER