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https://llvm.org/docs/CodingStandards.html#use-namespace-qualifiers-to-implement-previously-declared-functions
407 lines
14 KiB
C++
407 lines
14 KiB
C++
//===- AArch64ExpandImm.h - AArch64 Immediate Expansion -------------------===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file implements the AArch64ExpandImm stuff.
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//
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//===----------------------------------------------------------------------===//
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#include "AArch64.h"
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#include "AArch64ExpandImm.h"
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#include "MCTargetDesc/AArch64AddressingModes.h"
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using namespace llvm;
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using namespace llvm::AArch64_IMM;
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/// Helper function which extracts the specified 16-bit chunk from a
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/// 64-bit value.
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static uint64_t getChunk(uint64_t Imm, unsigned ChunkIdx) {
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assert(ChunkIdx < 4 && "Out of range chunk index specified!");
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return (Imm >> (ChunkIdx * 16)) & 0xFFFF;
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}
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/// Check whether the given 16-bit chunk replicated to full 64-bit width
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/// can be materialized with an ORR instruction.
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static bool canUseOrr(uint64_t Chunk, uint64_t &Encoding) {
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Chunk = (Chunk << 48) | (Chunk << 32) | (Chunk << 16) | Chunk;
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return AArch64_AM::processLogicalImmediate(Chunk, 64, Encoding);
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}
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/// Check for identical 16-bit chunks within the constant and if so
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/// materialize them with a single ORR instruction. The remaining one or two
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/// 16-bit chunks will be materialized with MOVK instructions.
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///
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/// This allows us to materialize constants like |A|B|A|A| or |A|B|C|A| (order
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/// of the chunks doesn't matter), assuming |A|A|A|A| can be materialized with
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/// an ORR instruction.
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static bool tryToreplicateChunks(uint64_t UImm,
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SmallVectorImpl<ImmInsnModel> &Insn) {
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using CountMap = DenseMap<uint64_t, unsigned>;
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CountMap Counts;
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// Scan the constant and count how often every chunk occurs.
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for (unsigned Idx = 0; Idx < 4; ++Idx)
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++Counts[getChunk(UImm, Idx)];
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// Traverse the chunks to find one which occurs more than once.
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for (CountMap::const_iterator Chunk = Counts.begin(), End = Counts.end();
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Chunk != End; ++Chunk) {
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const uint64_t ChunkVal = Chunk->first;
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const unsigned Count = Chunk->second;
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uint64_t Encoding = 0;
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// We are looking for chunks which have two or three instances and can be
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// materialized with an ORR instruction.
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if ((Count != 2 && Count != 3) || !canUseOrr(ChunkVal, Encoding))
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continue;
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const bool CountThree = Count == 3;
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Insn.push_back({ AArch64::ORRXri, 0, Encoding });
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unsigned ShiftAmt = 0;
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uint64_t Imm16 = 0;
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// Find the first chunk not materialized with the ORR instruction.
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for (; ShiftAmt < 64; ShiftAmt += 16) {
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Imm16 = (UImm >> ShiftAmt) & 0xFFFF;
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if (Imm16 != ChunkVal)
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break;
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}
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// Create the first MOVK instruction.
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Insn.push_back({ AArch64::MOVKXi, Imm16,
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AArch64_AM::getShifterImm(AArch64_AM::LSL, ShiftAmt) });
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// In case we have three instances the whole constant is now materialized
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// and we can exit.
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if (CountThree)
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return true;
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// Find the remaining chunk which needs to be materialized.
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for (ShiftAmt += 16; ShiftAmt < 64; ShiftAmt += 16) {
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Imm16 = (UImm >> ShiftAmt) & 0xFFFF;
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if (Imm16 != ChunkVal)
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break;
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}
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Insn.push_back({ AArch64::MOVKXi, Imm16,
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AArch64_AM::getShifterImm(AArch64_AM::LSL, ShiftAmt) });
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return true;
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}
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return false;
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}
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/// Check whether this chunk matches the pattern '1...0...'. This pattern
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/// starts a contiguous sequence of ones if we look at the bits from the LSB
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/// towards the MSB.
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static bool isStartChunk(uint64_t Chunk) {
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if (Chunk == 0 || Chunk == std::numeric_limits<uint64_t>::max())
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return false;
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return isMask_64(~Chunk);
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}
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/// Check whether this chunk matches the pattern '0...1...' This pattern
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/// ends a contiguous sequence of ones if we look at the bits from the LSB
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/// towards the MSB.
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static bool isEndChunk(uint64_t Chunk) {
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if (Chunk == 0 || Chunk == std::numeric_limits<uint64_t>::max())
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return false;
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return isMask_64(Chunk);
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}
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/// Clear or set all bits in the chunk at the given index.
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static uint64_t updateImm(uint64_t Imm, unsigned Idx, bool Clear) {
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const uint64_t Mask = 0xFFFF;
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if (Clear)
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// Clear chunk in the immediate.
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Imm &= ~(Mask << (Idx * 16));
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else
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// Set all bits in the immediate for the particular chunk.
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Imm |= Mask << (Idx * 16);
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return Imm;
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}
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/// Check whether the constant contains a sequence of contiguous ones,
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/// which might be interrupted by one or two chunks. If so, materialize the
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/// sequence of contiguous ones with an ORR instruction.
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/// Materialize the chunks which are either interrupting the sequence or outside
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/// of the sequence with a MOVK instruction.
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///
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/// Assuming S is a chunk which starts the sequence (1...0...), E is a chunk
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/// which ends the sequence (0...1...). Then we are looking for constants which
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/// contain at least one S and E chunk.
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/// E.g. |E|A|B|S|, |A|E|B|S| or |A|B|E|S|.
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///
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/// We are also looking for constants like |S|A|B|E| where the contiguous
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/// sequence of ones wraps around the MSB into the LSB.
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static bool trySequenceOfOnes(uint64_t UImm,
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SmallVectorImpl<ImmInsnModel> &Insn) {
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const int NotSet = -1;
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const uint64_t Mask = 0xFFFF;
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int StartIdx = NotSet;
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int EndIdx = NotSet;
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// Try to find the chunks which start/end a contiguous sequence of ones.
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for (int Idx = 0; Idx < 4; ++Idx) {
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int64_t Chunk = getChunk(UImm, Idx);
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// Sign extend the 16-bit chunk to 64-bit.
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Chunk = (Chunk << 48) >> 48;
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if (isStartChunk(Chunk))
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StartIdx = Idx;
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else if (isEndChunk(Chunk))
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EndIdx = Idx;
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}
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// Early exit in case we can't find a start/end chunk.
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if (StartIdx == NotSet || EndIdx == NotSet)
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return false;
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// Outside of the contiguous sequence of ones everything needs to be zero.
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uint64_t Outside = 0;
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// Chunks between the start and end chunk need to have all their bits set.
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uint64_t Inside = Mask;
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// If our contiguous sequence of ones wraps around from the MSB into the LSB,
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// just swap indices and pretend we are materializing a contiguous sequence
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// of zeros surrounded by a contiguous sequence of ones.
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if (StartIdx > EndIdx) {
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std::swap(StartIdx, EndIdx);
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std::swap(Outside, Inside);
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}
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uint64_t OrrImm = UImm;
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int FirstMovkIdx = NotSet;
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int SecondMovkIdx = NotSet;
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// Find out which chunks we need to patch up to obtain a contiguous sequence
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// of ones.
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for (int Idx = 0; Idx < 4; ++Idx) {
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const uint64_t Chunk = getChunk(UImm, Idx);
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// Check whether we are looking at a chunk which is not part of the
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// contiguous sequence of ones.
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if ((Idx < StartIdx || EndIdx < Idx) && Chunk != Outside) {
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OrrImm = updateImm(OrrImm, Idx, Outside == 0);
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// Remember the index we need to patch.
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if (FirstMovkIdx == NotSet)
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FirstMovkIdx = Idx;
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else
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SecondMovkIdx = Idx;
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// Check whether we are looking a chunk which is part of the contiguous
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// sequence of ones.
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} else if (Idx > StartIdx && Idx < EndIdx && Chunk != Inside) {
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OrrImm = updateImm(OrrImm, Idx, Inside != Mask);
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// Remember the index we need to patch.
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if (FirstMovkIdx == NotSet)
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FirstMovkIdx = Idx;
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else
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SecondMovkIdx = Idx;
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}
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}
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assert(FirstMovkIdx != NotSet && "Constant materializable with single ORR!");
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// Create the ORR-immediate instruction.
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uint64_t Encoding = 0;
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AArch64_AM::processLogicalImmediate(OrrImm, 64, Encoding);
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Insn.push_back({ AArch64::ORRXri, 0, Encoding });
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const bool SingleMovk = SecondMovkIdx == NotSet;
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Insn.push_back({ AArch64::MOVKXi, getChunk(UImm, FirstMovkIdx),
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AArch64_AM::getShifterImm(AArch64_AM::LSL,
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FirstMovkIdx * 16) });
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// Early exit in case we only need to emit a single MOVK instruction.
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if (SingleMovk)
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return true;
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// Create the second MOVK instruction.
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Insn.push_back({ AArch64::MOVKXi, getChunk(UImm, SecondMovkIdx),
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AArch64_AM::getShifterImm(AArch64_AM::LSL,
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SecondMovkIdx * 16) });
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return true;
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}
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/// \brief Expand a MOVi32imm or MOVi64imm pseudo instruction to a
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/// MOVZ or MOVN of width BitSize followed by up to 3 MOVK instructions.
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static inline void expandMOVImmSimple(uint64_t Imm, unsigned BitSize,
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unsigned OneChunks, unsigned ZeroChunks,
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SmallVectorImpl<ImmInsnModel> &Insn) {
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const unsigned Mask = 0xFFFF;
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// Use a MOVZ or MOVN instruction to set the high bits, followed by one or
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// more MOVK instructions to insert additional 16-bit portions into the
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// lower bits.
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bool isNeg = false;
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// Use MOVN to materialize the high bits if we have more all one chunks
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// than all zero chunks.
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if (OneChunks > ZeroChunks) {
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isNeg = true;
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Imm = ~Imm;
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}
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unsigned FirstOpc;
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if (BitSize == 32) {
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Imm &= (1LL << 32) - 1;
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FirstOpc = (isNeg ? AArch64::MOVNWi : AArch64::MOVZWi);
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} else {
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FirstOpc = (isNeg ? AArch64::MOVNXi : AArch64::MOVZXi);
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}
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unsigned Shift = 0; // LSL amount for high bits with MOVZ/MOVN
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unsigned LastShift = 0; // LSL amount for last MOVK
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if (Imm != 0) {
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unsigned LZ = countLeadingZeros(Imm);
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unsigned TZ = countTrailingZeros(Imm);
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Shift = (TZ / 16) * 16;
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LastShift = ((63 - LZ) / 16) * 16;
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}
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unsigned Imm16 = (Imm >> Shift) & Mask;
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Insn.push_back({ FirstOpc, Imm16,
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AArch64_AM::getShifterImm(AArch64_AM::LSL, Shift) });
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if (Shift == LastShift)
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return;
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// If a MOVN was used for the high bits of a negative value, flip the rest
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// of the bits back for use with MOVK.
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if (isNeg)
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Imm = ~Imm;
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unsigned Opc = (BitSize == 32 ? AArch64::MOVKWi : AArch64::MOVKXi);
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while (Shift < LastShift) {
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Shift += 16;
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Imm16 = (Imm >> Shift) & Mask;
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if (Imm16 == (isNeg ? Mask : 0))
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continue; // This 16-bit portion is already set correctly.
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Insn.push_back({ Opc, Imm16,
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AArch64_AM::getShifterImm(AArch64_AM::LSL, Shift) });
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}
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}
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/// Expand a MOVi32imm or MOVi64imm pseudo instruction to one or more
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/// real move-immediate instructions to synthesize the immediate.
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void AArch64_IMM::expandMOVImm(uint64_t Imm, unsigned BitSize,
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SmallVectorImpl<ImmInsnModel> &Insn) {
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const unsigned Mask = 0xFFFF;
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// Scan the immediate and count the number of 16-bit chunks which are either
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// all ones or all zeros.
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unsigned OneChunks = 0;
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unsigned ZeroChunks = 0;
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for (unsigned Shift = 0; Shift < BitSize; Shift += 16) {
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const unsigned Chunk = (Imm >> Shift) & Mask;
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if (Chunk == Mask)
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OneChunks++;
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else if (Chunk == 0)
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ZeroChunks++;
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}
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// Prefer MOVZ/MOVN over ORR because of the rules for the "mov" alias.
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if ((BitSize / 16) - OneChunks <= 1 || (BitSize / 16) - ZeroChunks <= 1) {
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expandMOVImmSimple(Imm, BitSize, OneChunks, ZeroChunks, Insn);
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return;
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}
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// Try a single ORR.
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uint64_t UImm = Imm << (64 - BitSize) >> (64 - BitSize);
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uint64_t Encoding;
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if (AArch64_AM::processLogicalImmediate(UImm, BitSize, Encoding)) {
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unsigned Opc = (BitSize == 32 ? AArch64::ORRWri : AArch64::ORRXri);
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Insn.push_back({ Opc, 0, Encoding });
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return;
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}
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// One to up three instruction sequences.
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//
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// Prefer MOVZ/MOVN followed by MOVK; it's more readable, and possibly the
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// fastest sequence with fast literal generation.
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if (OneChunks >= (BitSize / 16) - 2 || ZeroChunks >= (BitSize / 16) - 2) {
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expandMOVImmSimple(Imm, BitSize, OneChunks, ZeroChunks, Insn);
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return;
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}
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assert(BitSize == 64 && "All 32-bit immediates can be expanded with a"
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"MOVZ/MOVK pair");
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// Try other two-instruction sequences.
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// 64-bit ORR followed by MOVK.
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// We try to construct the ORR immediate in three different ways: either we
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// zero out the chunk which will be replaced, we fill the chunk which will
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// be replaced with ones, or we take the bit pattern from the other half of
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// the 64-bit immediate. This is comprehensive because of the way ORR
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// immediates are constructed.
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for (unsigned Shift = 0; Shift < BitSize; Shift += 16) {
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uint64_t ShiftedMask = (0xFFFFULL << Shift);
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uint64_t ZeroChunk = UImm & ~ShiftedMask;
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uint64_t OneChunk = UImm | ShiftedMask;
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uint64_t RotatedImm = (UImm << 32) | (UImm >> 32);
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uint64_t ReplicateChunk = ZeroChunk | (RotatedImm & ShiftedMask);
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if (AArch64_AM::processLogicalImmediate(ZeroChunk, BitSize, Encoding) ||
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AArch64_AM::processLogicalImmediate(OneChunk, BitSize, Encoding) ||
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AArch64_AM::processLogicalImmediate(ReplicateChunk, BitSize,
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Encoding)) {
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// Create the ORR-immediate instruction.
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Insn.push_back({ AArch64::ORRXri, 0, Encoding });
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// Create the MOVK instruction.
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const unsigned Imm16 = getChunk(UImm, Shift / 16);
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Insn.push_back({ AArch64::MOVKXi, Imm16,
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AArch64_AM::getShifterImm(AArch64_AM::LSL, Shift) });
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return;
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}
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}
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// FIXME: Add more two-instruction sequences.
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// Three instruction sequences.
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//
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// Prefer MOVZ/MOVN followed by two MOVK; it's more readable, and possibly
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// the fastest sequence with fast literal generation. (If neither MOVK is
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// part of a fast literal generation pair, it could be slower than the
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// four-instruction sequence, but we won't worry about that for now.)
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if (OneChunks || ZeroChunks) {
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expandMOVImmSimple(Imm, BitSize, OneChunks, ZeroChunks, Insn);
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return;
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}
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// Check for identical 16-bit chunks within the constant and if so materialize
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// them with a single ORR instruction. The remaining one or two 16-bit chunks
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// will be materialized with MOVK instructions.
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if (BitSize == 64 && tryToreplicateChunks(UImm, Insn))
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return;
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// Check whether the constant contains a sequence of contiguous ones, which
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// might be interrupted by one or two chunks. If so, materialize the sequence
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// of contiguous ones with an ORR instruction. Materialize the chunks which
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// are either interrupting the sequence or outside of the sequence with a
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// MOVK instruction.
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if (BitSize == 64 && trySequenceOfOnes(UImm, Insn))
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return;
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// We found no possible two or three instruction sequence; use the general
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// four-instruction sequence.
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expandMOVImmSimple(Imm, BitSize, OneChunks, ZeroChunks, Insn);
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}
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