MIPS: Assemblers changes needed for optimizing compiler
Also add assembler tests for MIPS32.
Change-Id: I3ab1fba7f3b06eb3b5058861946d675494a30775
diff --git a/compiler/utils/mips/assembler_mips.cc b/compiler/utils/mips/assembler_mips.cc
index c5fae92..6f35e9e 100644
--- a/compiler/utils/mips/assembler_mips.cc
+++ b/compiler/utils/mips/assembler_mips.cc
@@ -19,6 +19,7 @@
#include "base/bit_utils.h"
#include "base/casts.h"
#include "entrypoints/quick/quick_entrypoints.h"
+#include "entrypoints/quick/quick_entrypoints_enum.h"
#include "memory_region.h"
#include "thread.h"
@@ -34,172 +35,193 @@
return os;
}
-void MipsAssembler::Emit(int32_t value) {
- AssemblerBuffer::EnsureCapacity ensured(&buffer_);
- buffer_.Emit<int32_t>(value);
+void MipsAssembler::FinalizeCode() {
+ for (auto& exception_block : exception_blocks_) {
+ EmitExceptionPoll(&exception_block);
+ }
+ PromoteBranches();
+}
+
+void MipsAssembler::FinalizeInstructions(const MemoryRegion& region) {
+ EmitBranches();
+ Assembler::FinalizeInstructions(region);
+}
+
+void MipsAssembler::EmitBranches() {
+ CHECK(!overwriting_);
+ // Switch from appending instructions at the end of the buffer to overwriting
+ // existing instructions (branch placeholders) in the buffer.
+ overwriting_ = true;
+ for (auto& branch : branches_) {
+ EmitBranch(&branch);
+ }
+ overwriting_ = false;
+}
+
+void MipsAssembler::Emit(uint32_t value) {
+ if (overwriting_) {
+ // Branches to labels are emitted into their placeholders here.
+ buffer_.Store<uint32_t>(overwrite_location_, value);
+ overwrite_location_ += sizeof(uint32_t);
+ } else {
+ // Other instructions are simply appended at the end here.
+ AssemblerBuffer::EnsureCapacity ensured(&buffer_);
+ buffer_.Emit<uint32_t>(value);
+ }
}
void MipsAssembler::EmitR(int opcode, Register rs, Register rt, Register rd, int shamt, int funct) {
CHECK_NE(rs, kNoRegister);
CHECK_NE(rt, kNoRegister);
CHECK_NE(rd, kNoRegister);
- int32_t encoding = opcode << kOpcodeShift |
- static_cast<int32_t>(rs) << kRsShift |
- static_cast<int32_t>(rt) << kRtShift |
- static_cast<int32_t>(rd) << kRdShift |
- shamt << kShamtShift |
- funct;
+ uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
+ static_cast<uint32_t>(rs) << kRsShift |
+ static_cast<uint32_t>(rt) << kRtShift |
+ static_cast<uint32_t>(rd) << kRdShift |
+ shamt << kShamtShift |
+ funct;
Emit(encoding);
}
void MipsAssembler::EmitI(int opcode, Register rs, Register rt, uint16_t imm) {
CHECK_NE(rs, kNoRegister);
CHECK_NE(rt, kNoRegister);
- int32_t encoding = opcode << kOpcodeShift |
- static_cast<int32_t>(rs) << kRsShift |
- static_cast<int32_t>(rt) << kRtShift |
- imm;
+ uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
+ static_cast<uint32_t>(rs) << kRsShift |
+ static_cast<uint32_t>(rt) << kRtShift |
+ imm;
Emit(encoding);
}
-void MipsAssembler::EmitJ(int opcode, int address) {
- int32_t encoding = opcode << kOpcodeShift |
- address;
+void MipsAssembler::EmitI21(int opcode, Register rs, uint32_t imm21) {
+ CHECK_NE(rs, kNoRegister);
+ CHECK(IsUint<21>(imm21)) << imm21;
+ uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
+ static_cast<uint32_t>(rs) << kRsShift |
+ imm21;
Emit(encoding);
}
-void MipsAssembler::EmitFR(int opcode, int fmt, FRegister ft, FRegister fs, FRegister fd, int funct) {
+void MipsAssembler::EmitI26(int opcode, uint32_t imm26) {
+ CHECK(IsUint<26>(imm26)) << imm26;
+ uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift | imm26;
+ Emit(encoding);
+}
+
+void MipsAssembler::EmitFR(int opcode, int fmt, FRegister ft, FRegister fs, FRegister fd,
+ int funct) {
CHECK_NE(ft, kNoFRegister);
CHECK_NE(fs, kNoFRegister);
CHECK_NE(fd, kNoFRegister);
- int32_t encoding = opcode << kOpcodeShift |
- fmt << kFmtShift |
- static_cast<int32_t>(ft) << kFtShift |
- static_cast<int32_t>(fs) << kFsShift |
- static_cast<int32_t>(fd) << kFdShift |
- funct;
+ uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
+ fmt << kFmtShift |
+ static_cast<uint32_t>(ft) << kFtShift |
+ static_cast<uint32_t>(fs) << kFsShift |
+ static_cast<uint32_t>(fd) << kFdShift |
+ funct;
Emit(encoding);
}
-void MipsAssembler::EmitFI(int opcode, int fmt, FRegister rt, uint16_t imm) {
- CHECK_NE(rt, kNoFRegister);
- int32_t encoding = opcode << kOpcodeShift |
- fmt << kFmtShift |
- static_cast<int32_t>(rt) << kRtShift |
- imm;
+void MipsAssembler::EmitFI(int opcode, int fmt, FRegister ft, uint16_t imm) {
+ CHECK_NE(ft, kNoFRegister);
+ uint32_t encoding = static_cast<uint32_t>(opcode) << kOpcodeShift |
+ fmt << kFmtShift |
+ static_cast<uint32_t>(ft) << kFtShift |
+ imm;
Emit(encoding);
}
-void MipsAssembler::EmitBranch(Register rt, Register rs, Label* label, bool equal) {
- int offset;
- if (label->IsBound()) {
- offset = label->Position() - buffer_.Size();
- } else {
- // Use the offset field of the branch instruction for linking the sites.
- offset = label->position_;
- label->LinkTo(buffer_.Size());
- }
- if (equal) {
- Beq(rt, rs, (offset >> 2) & kBranchOffsetMask);
- } else {
- Bne(rt, rs, (offset >> 2) & kBranchOffsetMask);
- }
-}
-
-void MipsAssembler::EmitJump(Label* label, bool link) {
- int offset;
- if (label->IsBound()) {
- offset = label->Position() - buffer_.Size();
- } else {
- // Use the offset field of the jump instruction for linking the sites.
- offset = label->position_;
- label->LinkTo(buffer_.Size());
- }
- if (link) {
- Jal((offset >> 2) & kJumpOffsetMask);
- } else {
- J((offset >> 2) & kJumpOffsetMask);
- }
-}
-
-int32_t MipsAssembler::EncodeBranchOffset(int offset, int32_t inst, bool is_jump) {
- CHECK_ALIGNED(offset, 4);
- CHECK(IsInt(POPCOUNT(kBranchOffsetMask), offset)) << offset;
-
- // Properly preserve only the bits supported in the instruction.
- offset >>= 2;
- if (is_jump) {
- offset &= kJumpOffsetMask;
- return (inst & ~kJumpOffsetMask) | offset;
- } else {
- offset &= kBranchOffsetMask;
- return (inst & ~kBranchOffsetMask) | offset;
- }
-}
-
-int MipsAssembler::DecodeBranchOffset(int32_t inst, bool is_jump) {
- // Sign-extend, then left-shift by 2.
- if (is_jump) {
- return (((inst & kJumpOffsetMask) << 6) >> 4);
- } else {
- return (((inst & kBranchOffsetMask) << 16) >> 14);
- }
-}
-
-void MipsAssembler::Bind(Label* label, bool is_jump) {
- CHECK(!label->IsBound());
- int bound_pc = buffer_.Size();
- while (label->IsLinked()) {
- int32_t position = label->Position();
- int32_t next = buffer_.Load<int32_t>(position);
- int32_t offset = is_jump ? bound_pc - position : bound_pc - position - 4;
- int32_t encoded = MipsAssembler::EncodeBranchOffset(offset, next, is_jump);
- buffer_.Store<int32_t>(position, encoded);
- label->position_ = MipsAssembler::DecodeBranchOffset(next, is_jump);
- }
- label->BindTo(bound_pc);
-}
-
-void MipsAssembler::Add(Register rd, Register rs, Register rt) {
- EmitR(0, rs, rt, rd, 0, 0x20);
-}
-
void MipsAssembler::Addu(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x21);
}
-void MipsAssembler::Addi(Register rt, Register rs, uint16_t imm16) {
- EmitI(0x8, rs, rt, imm16);
-}
-
void MipsAssembler::Addiu(Register rt, Register rs, uint16_t imm16) {
EmitI(0x9, rs, rt, imm16);
}
-void MipsAssembler::Sub(Register rd, Register rs, Register rt) {
- EmitR(0, rs, rt, rd, 0, 0x22);
-}
-
void MipsAssembler::Subu(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x23);
}
-void MipsAssembler::Mult(Register rs, Register rt) {
+void MipsAssembler::MultR2(Register rs, Register rt) {
+ CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x18);
}
-void MipsAssembler::Multu(Register rs, Register rt) {
+void MipsAssembler::MultuR2(Register rs, Register rt) {
+ CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x19);
}
-void MipsAssembler::Div(Register rs, Register rt) {
+void MipsAssembler::DivR2(Register rs, Register rt) {
+ CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x1a);
}
-void MipsAssembler::Divu(Register rs, Register rt) {
+void MipsAssembler::DivuR2(Register rs, Register rt) {
+ CHECK(!IsR6());
EmitR(0, rs, rt, static_cast<Register>(0), 0, 0x1b);
}
+void MipsAssembler::MulR2(Register rd, Register rs, Register rt) {
+ CHECK(!IsR6());
+ EmitR(0x1c, rs, rt, rd, 0, 2);
+}
+
+void MipsAssembler::DivR2(Register rd, Register rs, Register rt) {
+ CHECK(!IsR6());
+ DivR2(rs, rt);
+ Mflo(rd);
+}
+
+void MipsAssembler::ModR2(Register rd, Register rs, Register rt) {
+ CHECK(!IsR6());
+ DivR2(rs, rt);
+ Mfhi(rd);
+}
+
+void MipsAssembler::DivuR2(Register rd, Register rs, Register rt) {
+ CHECK(!IsR6());
+ DivuR2(rs, rt);
+ Mflo(rd);
+}
+
+void MipsAssembler::ModuR2(Register rd, Register rs, Register rt) {
+ CHECK(!IsR6());
+ DivuR2(rs, rt);
+ Mfhi(rd);
+}
+
+void MipsAssembler::MulR6(Register rd, Register rs, Register rt) {
+ CHECK(IsR6());
+ EmitR(0, rs, rt, rd, 2, 0x18);
+}
+
+void MipsAssembler::MuhuR6(Register rd, Register rs, Register rt) {
+ CHECK(IsR6());
+ EmitR(0, rs, rt, rd, 3, 0x19);
+}
+
+void MipsAssembler::DivR6(Register rd, Register rs, Register rt) {
+ CHECK(IsR6());
+ EmitR(0, rs, rt, rd, 2, 0x1a);
+}
+
+void MipsAssembler::ModR6(Register rd, Register rs, Register rt) {
+ CHECK(IsR6());
+ EmitR(0, rs, rt, rd, 3, 0x1a);
+}
+
+void MipsAssembler::DivuR6(Register rd, Register rs, Register rt) {
+ CHECK(IsR6());
+ EmitR(0, rs, rt, rd, 2, 0x1b);
+}
+
+void MipsAssembler::ModuR6(Register rd, Register rs, Register rt) {
+ CHECK(IsR6());
+ EmitR(0, rs, rt, rd, 3, 0x1b);
+}
+
void MipsAssembler::And(Register rd, Register rs, Register rt) {
EmitR(0, rs, rt, rd, 0, 0x24);
}
@@ -228,27 +250,35 @@
EmitR(0, rs, rt, rd, 0, 0x27);
}
-void MipsAssembler::Sll(Register rd, Register rs, int shamt) {
- EmitR(0, rs, static_cast<Register>(0), rd, shamt, 0x00);
+void MipsAssembler::Seb(Register rd, Register rt) {
+ EmitR(0x1f, static_cast<Register>(0), rt, rd, 0x10, 0x20);
}
-void MipsAssembler::Srl(Register rd, Register rs, int shamt) {
- EmitR(0, rs, static_cast<Register>(0), rd, shamt, 0x02);
+void MipsAssembler::Seh(Register rd, Register rt) {
+ EmitR(0x1f, static_cast<Register>(0), rt, rd, 0x18, 0x20);
}
-void MipsAssembler::Sra(Register rd, Register rs, int shamt) {
- EmitR(0, rs, static_cast<Register>(0), rd, shamt, 0x03);
+void MipsAssembler::Sll(Register rd, Register rt, int shamt) {
+ EmitR(0, static_cast<Register>(0), rt, rd, shamt, 0x00);
}
-void MipsAssembler::Sllv(Register rd, Register rs, Register rt) {
+void MipsAssembler::Srl(Register rd, Register rt, int shamt) {
+ EmitR(0, static_cast<Register>(0), rt, rd, shamt, 0x02);
+}
+
+void MipsAssembler::Sra(Register rd, Register rt, int shamt) {
+ EmitR(0, static_cast<Register>(0), rt, rd, shamt, 0x03);
+}
+
+void MipsAssembler::Sllv(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 0, 0x04);
}
-void MipsAssembler::Srlv(Register rd, Register rs, Register rt) {
+void MipsAssembler::Srlv(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 0, 0x06);
}
-void MipsAssembler::Srav(Register rd, Register rs, Register rt) {
+void MipsAssembler::Srav(Register rd, Register rt, Register rs) {
EmitR(0, rs, rt, rd, 0, 0x07);
}
@@ -276,11 +306,18 @@
EmitI(0xf, static_cast<Register>(0), rt, imm16);
}
+void MipsAssembler::Sync(uint32_t stype) {
+ EmitR(0, static_cast<Register>(0), static_cast<Register>(0), static_cast<Register>(0),
+ stype & 0x1f, 0xf);
+}
+
void MipsAssembler::Mfhi(Register rd) {
+ CHECK(!IsR6());
EmitR(0, static_cast<Register>(0), static_cast<Register>(0), rd, 0, 0x10);
}
void MipsAssembler::Mflo(Register rd) {
+ CHECK(!IsR6());
EmitR(0, static_cast<Register>(0), static_cast<Register>(0), rd, 0, 0x12);
}
@@ -312,34 +349,276 @@
EmitI(0xb, rs, rt, imm16);
}
-void MipsAssembler::Beq(Register rt, Register rs, uint16_t imm16) {
+void MipsAssembler::B(uint16_t imm16) {
+ EmitI(0x4, static_cast<Register>(0), static_cast<Register>(0), imm16);
+}
+
+void MipsAssembler::Beq(Register rs, Register rt, uint16_t imm16) {
EmitI(0x4, rs, rt, imm16);
- Nop();
}
-void MipsAssembler::Bne(Register rt, Register rs, uint16_t imm16) {
+void MipsAssembler::Bne(Register rs, Register rt, uint16_t imm16) {
EmitI(0x5, rs, rt, imm16);
- Nop();
}
-void MipsAssembler::J(uint32_t address) {
- EmitJ(0x2, address);
- Nop();
+void MipsAssembler::Beqz(Register rt, uint16_t imm16) {
+ Beq(ZERO, rt, imm16);
}
-void MipsAssembler::Jal(uint32_t address) {
- EmitJ(0x2, address);
- Nop();
+void MipsAssembler::Bnez(Register rt, uint16_t imm16) {
+ Bne(ZERO, rt, imm16);
}
-void MipsAssembler::Jr(Register rs) {
- EmitR(0, rs, static_cast<Register>(0), static_cast<Register>(0), 0, 0x09); // Jalr zero, rs
- Nop();
+void MipsAssembler::Bltz(Register rt, uint16_t imm16) {
+ EmitI(0x1, rt, static_cast<Register>(0), imm16);
+}
+
+void MipsAssembler::Bgez(Register rt, uint16_t imm16) {
+ EmitI(0x1, rt, static_cast<Register>(0x1), imm16);
+}
+
+void MipsAssembler::Blez(Register rt, uint16_t imm16) {
+ EmitI(0x6, rt, static_cast<Register>(0), imm16);
+}
+
+void MipsAssembler::Bgtz(Register rt, uint16_t imm16) {
+ EmitI(0x7, rt, static_cast<Register>(0), imm16);
+}
+
+void MipsAssembler::J(uint32_t addr26) {
+ EmitI26(0x2, addr26);
+}
+
+void MipsAssembler::Jal(uint32_t addr26) {
+ EmitI26(0x3, addr26);
+}
+
+void MipsAssembler::Jalr(Register rd, Register rs) {
+ EmitR(0, rs, static_cast<Register>(0), rd, 0, 0x09);
}
void MipsAssembler::Jalr(Register rs) {
- EmitR(0, rs, static_cast<Register>(0), RA, 0, 0x09);
- Nop();
+ Jalr(RA, rs);
+}
+
+void MipsAssembler::Jr(Register rs) {
+ Jalr(ZERO, rs);
+}
+
+void MipsAssembler::Nal() {
+ EmitI(0x1, static_cast<Register>(0), static_cast<Register>(0x10), 0);
+}
+
+void MipsAssembler::Auipc(Register rs, uint16_t imm16) {
+ CHECK(IsR6());
+ EmitI(0x3B, rs, static_cast<Register>(0x1E), imm16);
+}
+
+void MipsAssembler::Addiupc(Register rs, uint32_t imm19) {
+ CHECK(IsR6());
+ CHECK(IsUint<19>(imm19)) << imm19;
+ EmitI21(0x3B, rs, imm19);
+}
+
+void MipsAssembler::Bc(uint32_t imm26) {
+ CHECK(IsR6());
+ EmitI26(0x32, imm26);
+}
+
+void MipsAssembler::Jic(Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ EmitI(0x36, static_cast<Register>(0), rt, imm16);
+}
+
+void MipsAssembler::Jialc(Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ EmitI(0x3E, static_cast<Register>(0), rt, imm16);
+}
+
+void MipsAssembler::Bltc(Register rs, Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ CHECK_NE(rt, ZERO);
+ CHECK_NE(rs, rt);
+ EmitI(0x17, rs, rt, imm16);
+}
+
+void MipsAssembler::Bltzc(Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rt, ZERO);
+ EmitI(0x17, rt, rt, imm16);
+}
+
+void MipsAssembler::Bgtzc(Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rt, ZERO);
+ EmitI(0x17, static_cast<Register>(0), rt, imm16);
+}
+
+void MipsAssembler::Bgec(Register rs, Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ CHECK_NE(rt, ZERO);
+ CHECK_NE(rs, rt);
+ EmitI(0x16, rs, rt, imm16);
+}
+
+void MipsAssembler::Bgezc(Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rt, ZERO);
+ EmitI(0x16, rt, rt, imm16);
+}
+
+void MipsAssembler::Blezc(Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rt, ZERO);
+ EmitI(0x16, static_cast<Register>(0), rt, imm16);
+}
+
+void MipsAssembler::Bltuc(Register rs, Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ CHECK_NE(rt, ZERO);
+ CHECK_NE(rs, rt);
+ EmitI(0x7, rs, rt, imm16);
+}
+
+void MipsAssembler::Bgeuc(Register rs, Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ CHECK_NE(rt, ZERO);
+ CHECK_NE(rs, rt);
+ EmitI(0x6, rs, rt, imm16);
+}
+
+void MipsAssembler::Beqc(Register rs, Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ CHECK_NE(rt, ZERO);
+ CHECK_NE(rs, rt);
+ EmitI(0x8, std::min(rs, rt), std::max(rs, rt), imm16);
+}
+
+void MipsAssembler::Bnec(Register rs, Register rt, uint16_t imm16) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ CHECK_NE(rt, ZERO);
+ CHECK_NE(rs, rt);
+ EmitI(0x18, std::min(rs, rt), std::max(rs, rt), imm16);
+}
+
+void MipsAssembler::Beqzc(Register rs, uint32_t imm21) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ EmitI21(0x36, rs, imm21);
+}
+
+void MipsAssembler::Bnezc(Register rs, uint32_t imm21) {
+ CHECK(IsR6());
+ CHECK_NE(rs, ZERO);
+ EmitI21(0x3E, rs, imm21);
+}
+
+void MipsAssembler::EmitBcond(BranchCondition cond, Register rs, Register rt, uint16_t imm16) {
+ switch (cond) {
+ case kCondLTZ:
+ CHECK_EQ(rt, ZERO);
+ Bltz(rs, imm16);
+ break;
+ case kCondGEZ:
+ CHECK_EQ(rt, ZERO);
+ Bgez(rs, imm16);
+ break;
+ case kCondLEZ:
+ CHECK_EQ(rt, ZERO);
+ Blez(rs, imm16);
+ break;
+ case kCondGTZ:
+ CHECK_EQ(rt, ZERO);
+ Bgtz(rs, imm16);
+ break;
+ case kCondEQ:
+ Beq(rs, rt, imm16);
+ break;
+ case kCondNE:
+ Bne(rs, rt, imm16);
+ break;
+ case kCondEQZ:
+ CHECK_EQ(rt, ZERO);
+ Beqz(rs, imm16);
+ break;
+ case kCondNEZ:
+ CHECK_EQ(rt, ZERO);
+ Bnez(rs, imm16);
+ break;
+ case kCondLT:
+ case kCondGE:
+ case kCondLE:
+ case kCondGT:
+ case kCondLTU:
+ case kCondGEU:
+ case kUncond:
+ // We don't support synthetic R2 branches (preceded with slt[u]) at this level
+ // (R2 doesn't have branches to compare 2 registers using <, <=, >=, >).
+ LOG(FATAL) << "Unexpected branch condition " << cond;
+ UNREACHABLE();
+ }
+}
+
+void MipsAssembler::EmitBcondc(BranchCondition cond, Register rs, Register rt, uint32_t imm16_21) {
+ switch (cond) {
+ case kCondLT:
+ Bltc(rs, rt, imm16_21);
+ break;
+ case kCondGE:
+ Bgec(rs, rt, imm16_21);
+ break;
+ case kCondLE:
+ Bgec(rt, rs, imm16_21);
+ break;
+ case kCondGT:
+ Bltc(rt, rs, imm16_21);
+ break;
+ case kCondLTZ:
+ CHECK_EQ(rt, ZERO);
+ Bltzc(rs, imm16_21);
+ break;
+ case kCondGEZ:
+ CHECK_EQ(rt, ZERO);
+ Bgezc(rs, imm16_21);
+ break;
+ case kCondLEZ:
+ CHECK_EQ(rt, ZERO);
+ Blezc(rs, imm16_21);
+ break;
+ case kCondGTZ:
+ CHECK_EQ(rt, ZERO);
+ Bgtzc(rs, imm16_21);
+ break;
+ case kCondEQ:
+ Beqc(rs, rt, imm16_21);
+ break;
+ case kCondNE:
+ Bnec(rs, rt, imm16_21);
+ break;
+ case kCondEQZ:
+ CHECK_EQ(rt, ZERO);
+ Beqzc(rs, imm16_21);
+ break;
+ case kCondNEZ:
+ CHECK_EQ(rt, ZERO);
+ Bnezc(rs, imm16_21);
+ break;
+ case kCondLTU:
+ Bltuc(rs, rt, imm16_21);
+ break;
+ case kCondGEU:
+ Bgeuc(rs, rt, imm16_21);
+ break;
+ case kUncond:
+ LOG(FATAL) << "Unexpected branch condition " << cond;
+ UNREACHABLE();
+ }
}
void MipsAssembler::AddS(FRegister fd, FRegister fs, FRegister ft) {
@@ -358,52 +637,84 @@
EmitFR(0x11, 0x10, ft, fs, fd, 0x3);
}
-void MipsAssembler::AddD(DRegister fd, DRegister fs, DRegister ft) {
- EmitFR(0x11, 0x11, ConvertDRegToFReg(ft), ConvertDRegToFReg(fs), ConvertDRegToFReg(fd), 0x0);
+void MipsAssembler::AddD(FRegister fd, FRegister fs, FRegister ft) {
+ EmitFR(0x11, 0x11, ft, fs, fd, 0x0);
}
-void MipsAssembler::SubD(DRegister fd, DRegister fs, DRegister ft) {
- EmitFR(0x11, 0x11, ConvertDRegToFReg(ft), ConvertDRegToFReg(fs), ConvertDRegToFReg(fd), 0x1);
+void MipsAssembler::SubD(FRegister fd, FRegister fs, FRegister ft) {
+ EmitFR(0x11, 0x11, ft, fs, fd, 0x1);
}
-void MipsAssembler::MulD(DRegister fd, DRegister fs, DRegister ft) {
- EmitFR(0x11, 0x11, ConvertDRegToFReg(ft), ConvertDRegToFReg(fs), ConvertDRegToFReg(fd), 0x2);
+void MipsAssembler::MulD(FRegister fd, FRegister fs, FRegister ft) {
+ EmitFR(0x11, 0x11, ft, fs, fd, 0x2);
}
-void MipsAssembler::DivD(DRegister fd, DRegister fs, DRegister ft) {
- EmitFR(0x11, 0x11, ConvertDRegToFReg(ft), ConvertDRegToFReg(fs), ConvertDRegToFReg(fd), 0x3);
+void MipsAssembler::DivD(FRegister fd, FRegister fs, FRegister ft) {
+ EmitFR(0x11, 0x11, ft, fs, fd, 0x3);
}
void MipsAssembler::MovS(FRegister fd, FRegister fs) {
EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x6);
}
-void MipsAssembler::MovD(DRegister fd, DRegister fs) {
- EmitFR(0x11, 0x11, static_cast<FRegister>(0), ConvertDRegToFReg(fs), ConvertDRegToFReg(fd), 0x6);
+void MipsAssembler::MovD(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x6);
+}
+
+void MipsAssembler::NegS(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x7);
+}
+
+void MipsAssembler::NegD(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x7);
+}
+
+void MipsAssembler::Cvtsw(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x14, static_cast<FRegister>(0), fs, fd, 0x20);
+}
+
+void MipsAssembler::Cvtdw(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x14, static_cast<FRegister>(0), fs, fd, 0x21);
+}
+
+void MipsAssembler::Cvtsd(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x11, static_cast<FRegister>(0), fs, fd, 0x20);
+}
+
+void MipsAssembler::Cvtds(FRegister fd, FRegister fs) {
+ EmitFR(0x11, 0x10, static_cast<FRegister>(0), fs, fd, 0x21);
}
void MipsAssembler::Mfc1(Register rt, FRegister fs) {
- EmitFR(0x11, 0x00, ConvertRegToFReg(rt), fs, static_cast<FRegister>(0), 0x0);
+ EmitFR(0x11, 0x00, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
}
-void MipsAssembler::Mtc1(FRegister ft, Register rs) {
- EmitFR(0x11, 0x04, ft, ConvertRegToFReg(rs), static_cast<FRegister>(0), 0x0);
+void MipsAssembler::Mtc1(Register rt, FRegister fs) {
+ EmitFR(0x11, 0x04, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
+}
+
+void MipsAssembler::Mfhc1(Register rt, FRegister fs) {
+ EmitFR(0x11, 0x03, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
+}
+
+void MipsAssembler::Mthc1(Register rt, FRegister fs) {
+ EmitFR(0x11, 0x07, static_cast<FRegister>(rt), fs, static_cast<FRegister>(0), 0x0);
}
void MipsAssembler::Lwc1(FRegister ft, Register rs, uint16_t imm16) {
- EmitI(0x31, rs, ConvertFRegToReg(ft), imm16);
+ EmitI(0x31, rs, static_cast<Register>(ft), imm16);
}
-void MipsAssembler::Ldc1(DRegister ft, Register rs, uint16_t imm16) {
- EmitI(0x35, rs, ConvertDRegToReg(ft), imm16);
+void MipsAssembler::Ldc1(FRegister ft, Register rs, uint16_t imm16) {
+ EmitI(0x35, rs, static_cast<Register>(ft), imm16);
}
void MipsAssembler::Swc1(FRegister ft, Register rs, uint16_t imm16) {
- EmitI(0x39, rs, ConvertFRegToReg(ft), imm16);
+ EmitI(0x39, rs, static_cast<Register>(ft), imm16);
}
-void MipsAssembler::Sdc1(DRegister ft, Register rs, uint16_t imm16) {
- EmitI(0x3d, rs, ConvertDRegToReg(ft), imm16);
+void MipsAssembler::Sdc1(FRegister ft, Register rs, uint16_t imm16) {
+ EmitI(0x3d, rs, static_cast<Register>(ft), imm16);
}
void MipsAssembler::Break() {
@@ -415,63 +726,881 @@
EmitR(0x0, static_cast<Register>(0), static_cast<Register>(0), static_cast<Register>(0), 0, 0x0);
}
-void MipsAssembler::Move(Register rt, Register rs) {
- EmitI(0x9, rs, rt, 0); // Addiu
+void MipsAssembler::Move(Register rd, Register rs) {
+ Or(rd, rs, ZERO);
}
-void MipsAssembler::Clear(Register rt) {
- EmitR(0, static_cast<Register>(0), static_cast<Register>(0), rt, 0, 0x20);
+void MipsAssembler::Clear(Register rd) {
+ Move(rd, ZERO);
}
-void MipsAssembler::Not(Register rt, Register rs) {
- EmitR(0, static_cast<Register>(0), rs, rt, 0, 0x27);
+void MipsAssembler::Not(Register rd, Register rs) {
+ Nor(rd, rs, ZERO);
}
-void MipsAssembler::Mul(Register rd, Register rs, Register rt) {
- Mult(rs, rt);
- Mflo(rd);
+void MipsAssembler::Push(Register rs) {
+ IncreaseFrameSize(kMipsWordSize);
+ Sw(rs, SP, 0);
}
-void MipsAssembler::Div(Register rd, Register rs, Register rt) {
- Div(rs, rt);
- Mflo(rd);
+void MipsAssembler::Pop(Register rd) {
+ Lw(rd, SP, 0);
+ DecreaseFrameSize(kMipsWordSize);
}
-void MipsAssembler::Rem(Register rd, Register rs, Register rt) {
- Div(rs, rt);
- Mfhi(rd);
+void MipsAssembler::PopAndReturn(Register rd, Register rt) {
+ Lw(rd, SP, 0);
+ Jr(rt);
+ DecreaseFrameSize(kMipsWordSize);
}
-void MipsAssembler::AddConstant(Register rt, Register rs, int32_t value) {
- Addiu(rt, rs, value);
-}
-
-void MipsAssembler::LoadImmediate(Register rt, int32_t value) {
- Addiu(rt, ZERO, value);
-}
-
-void MipsAssembler::EmitLoad(ManagedRegister m_dst, Register src_register, int32_t src_offset,
- size_t size) {
- MipsManagedRegister dst = m_dst.AsMips();
- if (dst.IsNoRegister()) {
- CHECK_EQ(0u, size) << dst;
- } else if (dst.IsCoreRegister()) {
- CHECK_EQ(4u, size) << dst;
- LoadFromOffset(kLoadWord, dst.AsCoreRegister(), src_register, src_offset);
- } else if (dst.IsRegisterPair()) {
- CHECK_EQ(8u, size) << dst;
- LoadFromOffset(kLoadWord, dst.AsRegisterPairLow(), src_register, src_offset);
- LoadFromOffset(kLoadWord, dst.AsRegisterPairHigh(), src_register, src_offset + 4);
- } else if (dst.IsFRegister()) {
- LoadSFromOffset(dst.AsFRegister(), src_register, src_offset);
+void MipsAssembler::LoadConst32(Register rd, int32_t value) {
+ if (IsUint<16>(value)) {
+ // Use OR with (unsigned) immediate to encode 16b unsigned int.
+ Ori(rd, ZERO, value);
+ } else if (IsInt<16>(value)) {
+ // Use ADD with (signed) immediate to encode 16b signed int.
+ Addiu(rd, ZERO, value);
} else {
- CHECK(dst.IsDRegister()) << dst;
- LoadDFromOffset(dst.AsDRegister(), src_register, src_offset);
+ Lui(rd, High16Bits(value));
+ if (value & 0xFFFF)
+ Ori(rd, rd, Low16Bits(value));
+ }
+}
+
+void MipsAssembler::LoadConst64(Register reg_hi, Register reg_lo, int64_t value) {
+ LoadConst32(reg_lo, Low32Bits(value));
+ LoadConst32(reg_hi, High32Bits(value));
+}
+
+void MipsAssembler::StoreConst32ToOffset(int32_t value,
+ Register base,
+ int32_t offset,
+ Register temp) {
+ if (!IsInt<16>(offset)) {
+ CHECK_NE(temp, AT); // Must not use AT as temp, as not to overwrite the loaded value.
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+ LoadConst32(temp, value);
+ Sw(temp, base, offset);
+}
+
+void MipsAssembler::StoreConst64ToOffset(int64_t value,
+ Register base,
+ int32_t offset,
+ Register temp) {
+ // IsInt<16> must be passed a signed value.
+ if (!IsInt<16>(offset) || !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize))) {
+ CHECK_NE(temp, AT); // Must not use AT as temp, as not to overwrite the loaded value.
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+ LoadConst32(temp, Low32Bits(value));
+ Sw(temp, base, offset);
+ LoadConst32(temp, High32Bits(value));
+ Sw(temp, base, offset + kMipsWordSize);
+}
+
+void MipsAssembler::LoadSConst32(FRegister r, int32_t value, Register temp) {
+ LoadConst32(temp, value);
+ Mtc1(temp, r);
+}
+
+void MipsAssembler::LoadDConst64(FRegister rd, int64_t value, Register temp) {
+ LoadConst32(temp, Low32Bits(value));
+ Mtc1(temp, rd);
+ LoadConst32(temp, High32Bits(value));
+ Mthc1(temp, rd);
+}
+
+void MipsAssembler::Addiu32(Register rt, Register rs, int32_t value, Register temp) {
+ if (IsInt<16>(value)) {
+ Addiu(rt, rs, value);
+ } else {
+ LoadConst32(temp, value);
+ Addu(rt, rs, temp);
+ }
+}
+
+void MipsAssembler::Branch::InitShortOrLong(MipsAssembler::Branch::OffsetBits offset_size,
+ MipsAssembler::Branch::Type short_type,
+ MipsAssembler::Branch::Type long_type) {
+ type_ = (offset_size <= branch_info_[short_type].offset_size) ? short_type : long_type;
+}
+
+void MipsAssembler::Branch::InitializeType(bool is_call, bool is_r6) {
+ OffsetBits offset_size = GetOffsetSizeNeeded(location_, target_);
+ if (is_r6) {
+ // R6
+ if (is_call) {
+ InitShortOrLong(offset_size, kR6Call, kR6LongCall);
+ } else if (condition_ == kUncond) {
+ InitShortOrLong(offset_size, kR6UncondBranch, kR6LongUncondBranch);
+ } else {
+ if (condition_ == kCondEQZ || condition_ == kCondNEZ) {
+ // Special case for beqzc/bnezc with longer offset than in other b<cond>c instructions.
+ type_ = (offset_size <= kOffset23) ? kR6CondBranch : kR6LongCondBranch;
+ } else {
+ InitShortOrLong(offset_size, kR6CondBranch, kR6LongCondBranch);
+ }
+ }
+ } else {
+ // R2
+ if (is_call) {
+ InitShortOrLong(offset_size, kCall, kLongCall);
+ } else if (condition_ == kUncond) {
+ InitShortOrLong(offset_size, kUncondBranch, kLongUncondBranch);
+ } else {
+ InitShortOrLong(offset_size, kCondBranch, kLongCondBranch);
+ }
+ }
+ old_type_ = type_;
+}
+
+bool MipsAssembler::Branch::IsNop(BranchCondition condition, Register lhs, Register rhs) {
+ switch (condition) {
+ case kCondLT:
+ case kCondGT:
+ case kCondNE:
+ case kCondLTU:
+ return lhs == rhs;
+ default:
+ return false;
+ }
+}
+
+bool MipsAssembler::Branch::IsUncond(BranchCondition condition, Register lhs, Register rhs) {
+ switch (condition) {
+ case kUncond:
+ return true;
+ case kCondGE:
+ case kCondLE:
+ case kCondEQ:
+ case kCondGEU:
+ return lhs == rhs;
+ default:
+ return false;
+ }
+}
+
+MipsAssembler::Branch::Branch(bool is_r6, uint32_t location, uint32_t target)
+ : old_location_(location),
+ location_(location),
+ target_(target),
+ lhs_reg_(0),
+ rhs_reg_(0),
+ condition_(kUncond) {
+ InitializeType(false, is_r6);
+}
+
+MipsAssembler::Branch::Branch(bool is_r6,
+ uint32_t location,
+ uint32_t target,
+ MipsAssembler::BranchCondition condition,
+ Register lhs_reg,
+ Register rhs_reg)
+ : old_location_(location),
+ location_(location),
+ target_(target),
+ lhs_reg_(lhs_reg),
+ rhs_reg_(rhs_reg),
+ condition_(condition) {
+ CHECK_NE(condition, kUncond);
+ switch (condition) {
+ case kCondLT:
+ case kCondGE:
+ case kCondLE:
+ case kCondGT:
+ case kCondLTU:
+ case kCondGEU:
+ // We don't support synthetic R2 branches (preceded with slt[u]) at this level
+ // (R2 doesn't have branches to compare 2 registers using <, <=, >=, >).
+ // We leave this up to the caller.
+ CHECK(is_r6);
+ FALLTHROUGH_INTENDED;
+ case kCondEQ:
+ case kCondNE:
+ // Require registers other than 0 not only for R6, but also for R2 to catch errors.
+ // To compare with 0, use dedicated kCond*Z conditions.
+ CHECK_NE(lhs_reg, ZERO);
+ CHECK_NE(rhs_reg, ZERO);
+ break;
+ case kCondLTZ:
+ case kCondGEZ:
+ case kCondLEZ:
+ case kCondGTZ:
+ case kCondEQZ:
+ case kCondNEZ:
+ // Require registers other than 0 not only for R6, but also for R2 to catch errors.
+ CHECK_NE(lhs_reg, ZERO);
+ CHECK_EQ(rhs_reg, ZERO);
+ break;
+ case kUncond:
+ UNREACHABLE();
+ }
+ CHECK(!IsNop(condition, lhs_reg, rhs_reg));
+ if (IsUncond(condition, lhs_reg, rhs_reg)) {
+ // Branch condition is always true, make the branch unconditional.
+ condition_ = kUncond;
+ }
+ InitializeType(false, is_r6);
+}
+
+MipsAssembler::Branch::Branch(bool is_r6, uint32_t location, uint32_t target, Register indirect_reg)
+ : old_location_(location),
+ location_(location),
+ target_(target),
+ lhs_reg_(indirect_reg),
+ rhs_reg_(0),
+ condition_(kUncond) {
+ CHECK_NE(indirect_reg, ZERO);
+ CHECK_NE(indirect_reg, AT);
+ InitializeType(true, is_r6);
+}
+
+MipsAssembler::BranchCondition MipsAssembler::Branch::OppositeCondition(
+ MipsAssembler::BranchCondition cond) {
+ switch (cond) {
+ case kCondLT:
+ return kCondGE;
+ case kCondGE:
+ return kCondLT;
+ case kCondLE:
+ return kCondGT;
+ case kCondGT:
+ return kCondLE;
+ case kCondLTZ:
+ return kCondGEZ;
+ case kCondGEZ:
+ return kCondLTZ;
+ case kCondLEZ:
+ return kCondGTZ;
+ case kCondGTZ:
+ return kCondLEZ;
+ case kCondEQ:
+ return kCondNE;
+ case kCondNE:
+ return kCondEQ;
+ case kCondEQZ:
+ return kCondNEZ;
+ case kCondNEZ:
+ return kCondEQZ;
+ case kCondLTU:
+ return kCondGEU;
+ case kCondGEU:
+ return kCondLTU;
+ case kUncond:
+ LOG(FATAL) << "Unexpected branch condition " << cond;
+ }
+ UNREACHABLE();
+}
+
+MipsAssembler::Branch::Type MipsAssembler::Branch::GetType() const {
+ return type_;
+}
+
+MipsAssembler::BranchCondition MipsAssembler::Branch::GetCondition() const {
+ return condition_;
+}
+
+Register MipsAssembler::Branch::GetLeftRegister() const {
+ return static_cast<Register>(lhs_reg_);
+}
+
+Register MipsAssembler::Branch::GetRightRegister() const {
+ return static_cast<Register>(rhs_reg_);
+}
+
+uint32_t MipsAssembler::Branch::GetTarget() const {
+ return target_;
+}
+
+uint32_t MipsAssembler::Branch::GetLocation() const {
+ return location_;
+}
+
+uint32_t MipsAssembler::Branch::GetOldLocation() const {
+ return old_location_;
+}
+
+uint32_t MipsAssembler::Branch::GetLength() const {
+ return branch_info_[type_].length;
+}
+
+uint32_t MipsAssembler::Branch::GetOldLength() const {
+ return branch_info_[old_type_].length;
+}
+
+uint32_t MipsAssembler::Branch::GetSize() const {
+ return GetLength() * sizeof(uint32_t);
+}
+
+uint32_t MipsAssembler::Branch::GetOldSize() const {
+ return GetOldLength() * sizeof(uint32_t);
+}
+
+uint32_t MipsAssembler::Branch::GetEndLocation() const {
+ return GetLocation() + GetSize();
+}
+
+uint32_t MipsAssembler::Branch::GetOldEndLocation() const {
+ return GetOldLocation() + GetOldSize();
+}
+
+bool MipsAssembler::Branch::IsLong() const {
+ switch (type_) {
+ // R2 short branches.
+ case kUncondBranch:
+ case kCondBranch:
+ case kCall:
+ // R6 short branches.
+ case kR6UncondBranch:
+ case kR6CondBranch:
+ case kR6Call:
+ return false;
+ // R2 long branches.
+ case kLongUncondBranch:
+ case kLongCondBranch:
+ case kLongCall:
+ // R6 long branches.
+ case kR6LongUncondBranch:
+ case kR6LongCondBranch:
+ case kR6LongCall:
+ return true;
+ }
+ UNREACHABLE();
+}
+
+bool MipsAssembler::Branch::IsResolved() const {
+ return target_ != kUnresolved;
+}
+
+MipsAssembler::Branch::OffsetBits MipsAssembler::Branch::GetOffsetSize() const {
+ OffsetBits offset_size =
+ (type_ == kR6CondBranch && (condition_ == kCondEQZ || condition_ == kCondNEZ))
+ ? kOffset23
+ : branch_info_[type_].offset_size;
+ return offset_size;
+}
+
+MipsAssembler::Branch::OffsetBits MipsAssembler::Branch::GetOffsetSizeNeeded(uint32_t location,
+ uint32_t target) {
+ // For unresolved targets assume the shortest encoding
+ // (later it will be made longer if needed).
+ if (target == kUnresolved)
+ return kOffset16;
+ int64_t distance = static_cast<int64_t>(target) - location;
+ // To simplify calculations in composite branches consisting of multiple instructions
+ // bump up the distance by a value larger than the max byte size of a composite branch.
+ distance += (distance >= 0) ? kMaxBranchSize : -kMaxBranchSize;
+ if (IsInt<kOffset16>(distance))
+ return kOffset16;
+ else if (IsInt<kOffset18>(distance))
+ return kOffset18;
+ else if (IsInt<kOffset21>(distance))
+ return kOffset21;
+ else if (IsInt<kOffset23>(distance))
+ return kOffset23;
+ else if (IsInt<kOffset28>(distance))
+ return kOffset28;
+ return kOffset32;
+}
+
+void MipsAssembler::Branch::Resolve(uint32_t target) {
+ target_ = target;
+}
+
+void MipsAssembler::Branch::Relocate(uint32_t expand_location, uint32_t delta) {
+ if (location_ > expand_location) {
+ location_ += delta;
+ }
+ if (!IsResolved()) {
+ return; // Don't know the target yet.
+ }
+ if (target_ > expand_location) {
+ target_ += delta;
+ }
+}
+
+void MipsAssembler::Branch::PromoteToLong() {
+ switch (type_) {
+ // R2 short branches.
+ case kUncondBranch:
+ type_ = kLongUncondBranch;
+ break;
+ case kCondBranch:
+ type_ = kLongCondBranch;
+ break;
+ case kCall:
+ type_ = kLongCall;
+ break;
+ // R6 short branches.
+ case kR6UncondBranch:
+ type_ = kR6LongUncondBranch;
+ break;
+ case kR6CondBranch:
+ type_ = kR6LongCondBranch;
+ break;
+ case kR6Call:
+ type_ = kR6LongCall;
+ break;
+ default:
+ // Note: 'type_' is already long.
+ break;
+ }
+ CHECK(IsLong());
+}
+
+uint32_t MipsAssembler::Branch::PromoteIfNeeded(uint32_t max_short_distance) {
+ // If the branch is still unresolved or already long, nothing to do.
+ if (IsLong() || !IsResolved()) {
+ return 0;
+ }
+ // Promote the short branch to long if the offset size is too small
+ // to hold the distance between location_ and target_.
+ if (GetOffsetSizeNeeded(location_, target_) > GetOffsetSize()) {
+ PromoteToLong();
+ uint32_t old_size = GetOldSize();
+ uint32_t new_size = GetSize();
+ CHECK_GT(new_size, old_size);
+ return new_size - old_size;
+ }
+ // The following logic is for debugging/testing purposes.
+ // Promote some short branches to long when it's not really required.
+ if (UNLIKELY(max_short_distance != std::numeric_limits<uint32_t>::max())) {
+ int64_t distance = static_cast<int64_t>(target_) - location_;
+ distance = (distance >= 0) ? distance : -distance;
+ if (distance >= max_short_distance) {
+ PromoteToLong();
+ uint32_t old_size = GetOldSize();
+ uint32_t new_size = GetSize();
+ CHECK_GT(new_size, old_size);
+ return new_size - old_size;
+ }
+ }
+ return 0;
+}
+
+uint32_t MipsAssembler::Branch::GetOffsetLocation() const {
+ return location_ + branch_info_[type_].instr_offset * sizeof(uint32_t);
+}
+
+uint32_t MipsAssembler::Branch::GetOffset() const {
+ CHECK(IsResolved());
+ uint32_t ofs_mask = 0xFFFFFFFF >> (32 - GetOffsetSize());
+ // Calculate the byte distance between instructions and also account for
+ // different PC-relative origins.
+ uint32_t offset = target_ - GetOffsetLocation() - branch_info_[type_].pc_org * sizeof(uint32_t);
+ // Prepare the offset for encoding into the instruction(s).
+ offset = (offset & ofs_mask) >> branch_info_[type_].offset_shift;
+ return offset;
+}
+
+MipsAssembler::Branch* MipsAssembler::GetBranch(uint32_t branch_id) {
+ CHECK_LT(branch_id, branches_.size());
+ return &branches_[branch_id];
+}
+
+const MipsAssembler::Branch* MipsAssembler::GetBranch(uint32_t branch_id) const {
+ CHECK_LT(branch_id, branches_.size());
+ return &branches_[branch_id];
+}
+
+void MipsAssembler::Bind(MipsLabel* label) {
+ CHECK(!label->IsBound());
+ uint32_t bound_pc = buffer_.Size();
+
+ // Walk the list of branches referring to and preceding this label.
+ // Store the previously unknown target addresses in them.
+ while (label->IsLinked()) {
+ uint32_t branch_id = label->Position();
+ Branch* branch = GetBranch(branch_id);
+ branch->Resolve(bound_pc);
+
+ uint32_t branch_location = branch->GetLocation();
+ // Extract the location of the previous branch in the list (walking the list backwards;
+ // the previous branch ID was stored in the space reserved for this branch).
+ uint32_t prev = buffer_.Load<uint32_t>(branch_location);
+
+ // On to the previous branch in the list...
+ label->position_ = prev;
+ }
+
+ // Now make the label object contain its own location (relative to the end of the preceding
+ // branch, if any; it will be used by the branches referring to and following this label).
+ label->prev_branch_id_plus_one_ = branches_.size();
+ if (label->prev_branch_id_plus_one_) {
+ uint32_t branch_id = label->prev_branch_id_plus_one_ - 1;
+ const Branch* branch = GetBranch(branch_id);
+ bound_pc -= branch->GetEndLocation();
+ }
+ label->BindTo(bound_pc);
+}
+
+uint32_t MipsAssembler::GetLabelLocation(MipsLabel* label) const {
+ CHECK(label->IsBound());
+ uint32_t target = label->Position();
+ if (label->prev_branch_id_plus_one_) {
+ // Get label location based on the branch preceding it.
+ uint32_t branch_id = label->prev_branch_id_plus_one_ - 1;
+ const Branch* branch = GetBranch(branch_id);
+ target += branch->GetEndLocation();
+ }
+ return target;
+}
+
+uint32_t MipsAssembler::GetAdjustedPosition(uint32_t old_position) {
+ // We can reconstruct the adjustment by going through all the branches from the beginning
+ // up to the old_position. Since we expect AdjustedPosition() to be called in a loop
+ // with increasing old_position, we can use the data from last AdjustedPosition() to
+ // continue where we left off and the whole loop should be O(m+n) where m is the number
+ // of positions to adjust and n is the number of branches.
+ if (old_position < last_old_position_) {
+ last_position_adjustment_ = 0;
+ last_old_position_ = 0;
+ last_branch_id_ = 0;
+ }
+ while (last_branch_id_ != branches_.size()) {
+ const Branch* branch = GetBranch(last_branch_id_);
+ if (branch->GetLocation() >= old_position + last_position_adjustment_) {
+ break;
+ }
+ last_position_adjustment_ += branch->GetSize() - branch->GetOldSize();
+ ++last_branch_id_;
+ }
+ last_old_position_ = old_position;
+ return old_position + last_position_adjustment_;
+}
+
+void MipsAssembler::FinalizeLabeledBranch(MipsLabel* label) {
+ uint32_t length = branches_.back().GetLength();
+ if (!label->IsBound()) {
+ // Branch forward (to a following label), distance is unknown.
+ // The first branch forward will contain 0, serving as the terminator of
+ // the list of forward-reaching branches.
+ Emit(label->position_);
+ length--;
+ // Now make the label object point to this branch
+ // (this forms a linked list of branches preceding this label).
+ uint32_t branch_id = branches_.size() - 1;
+ label->LinkTo(branch_id);
+ }
+ // Reserve space for the branch.
+ while (length--) {
+ Nop();
+ }
+}
+
+void MipsAssembler::Buncond(MipsLabel* label) {
+ uint32_t target = label->IsBound() ? GetLabelLocation(label) : Branch::kUnresolved;
+ branches_.emplace_back(IsR6(), buffer_.Size(), target);
+ FinalizeLabeledBranch(label);
+}
+
+void MipsAssembler::Bcond(MipsLabel* label, BranchCondition condition, Register lhs, Register rhs) {
+ // If lhs = rhs, this can be a NOP.
+ if (Branch::IsNop(condition, lhs, rhs)) {
+ return;
+ }
+ uint32_t target = label->IsBound() ? GetLabelLocation(label) : Branch::kUnresolved;
+ branches_.emplace_back(IsR6(), buffer_.Size(), target, condition, lhs, rhs);
+ FinalizeLabeledBranch(label);
+}
+
+void MipsAssembler::Call(MipsLabel* label, Register indirect_reg) {
+ uint32_t target = label->IsBound() ? GetLabelLocation(label) : Branch::kUnresolved;
+ branches_.emplace_back(IsR6(), buffer_.Size(), target, indirect_reg);
+ FinalizeLabeledBranch(label);
+}
+
+void MipsAssembler::PromoteBranches() {
+ // Promote short branches to long as necessary.
+ bool changed;
+ do {
+ changed = false;
+ for (auto& branch : branches_) {
+ CHECK(branch.IsResolved());
+ uint32_t delta = branch.PromoteIfNeeded();
+ // If this branch has been promoted and needs to expand in size,
+ // relocate all branches by the expansion size.
+ if (delta) {
+ changed = true;
+ uint32_t expand_location = branch.GetLocation();
+ for (auto& branch2 : branches_) {
+ branch2.Relocate(expand_location, delta);
+ }
+ }
+ }
+ } while (changed);
+
+ // Account for branch expansion by resizing the code buffer
+ // and moving the code in it to its final location.
+ size_t branch_count = branches_.size();
+ if (branch_count > 0) {
+ // Resize.
+ Branch& last_branch = branches_[branch_count - 1];
+ uint32_t size_delta = last_branch.GetEndLocation() - last_branch.GetOldEndLocation();
+ uint32_t old_size = buffer_.Size();
+ buffer_.Resize(old_size + size_delta);
+ // Move the code residing between branch placeholders.
+ uint32_t end = old_size;
+ for (size_t i = branch_count; i > 0; ) {
+ Branch& branch = branches_[--i];
+ uint32_t size = end - branch.GetOldEndLocation();
+ buffer_.Move(branch.GetEndLocation(), branch.GetOldEndLocation(), size);
+ end = branch.GetOldLocation();
+ }
+ }
+}
+
+// Note: make sure branch_info_[] and EmitBranch() are kept synchronized.
+const MipsAssembler::Branch::BranchInfo MipsAssembler::Branch::branch_info_[] = {
+ // R2 short branches.
+ { 2, 0, 1, MipsAssembler::Branch::kOffset18, 2 }, // kUncondBranch
+ { 2, 0, 1, MipsAssembler::Branch::kOffset18, 2 }, // kCondBranch
+ { 5, 2, 0, MipsAssembler::Branch::kOffset16, 0 }, // kCall
+ // R2 long branches.
+ { 9, 3, 1, MipsAssembler::Branch::kOffset32, 0 }, // kLongUncondBranch
+ { 10, 4, 1, MipsAssembler::Branch::kOffset32, 0 }, // kLongCondBranch
+ { 6, 1, 1, MipsAssembler::Branch::kOffset32, 0 }, // kLongCall
+ // R6 short branches.
+ { 1, 0, 1, MipsAssembler::Branch::kOffset28, 2 }, // kR6UncondBranch
+ { 2, 0, 1, MipsAssembler::Branch::kOffset18, 2 }, // kR6CondBranch
+ // Exception: kOffset23 for beqzc/bnezc.
+ { 2, 0, 0, MipsAssembler::Branch::kOffset21, 2 }, // kR6Call
+ // R6 long branches.
+ { 2, 0, 0, MipsAssembler::Branch::kOffset32, 0 }, // kR6LongUncondBranch
+ { 3, 1, 0, MipsAssembler::Branch::kOffset32, 0 }, // kR6LongCondBranch
+ { 3, 0, 0, MipsAssembler::Branch::kOffset32, 0 }, // kR6LongCall
+};
+
+// Note: make sure branch_info_[] and mitBranch() are kept synchronized.
+void MipsAssembler::EmitBranch(MipsAssembler::Branch* branch) {
+ CHECK_EQ(overwriting_, true);
+ overwrite_location_ = branch->GetLocation();
+ uint32_t offset = branch->GetOffset();
+ BranchCondition condition = branch->GetCondition();
+ Register lhs = branch->GetLeftRegister();
+ Register rhs = branch->GetRightRegister();
+ switch (branch->GetType()) {
+ // R2 short branches.
+ case Branch::kUncondBranch:
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ B(offset);
+ Nop(); // TODO: improve by filling the delay slot.
+ break;
+ case Branch::kCondBranch:
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ EmitBcond(condition, lhs, rhs, offset);
+ Nop(); // TODO: improve by filling the delay slot.
+ break;
+ case Branch::kCall:
+ Nal();
+ Nop(); // TODO: is this NOP really needed here?
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Addiu(lhs, RA, offset);
+ Jalr(lhs);
+ Nop();
+ break;
+
+ // R2 long branches.
+ case Branch::kLongUncondBranch:
+ // To get the value of the PC register we need to use the NAL instruction.
+ // NAL clobbers the RA register. However, RA must be preserved if the
+ // method is compiled without the entry/exit sequences that would take care
+ // of preserving RA (typically, leaf methods don't preserve RA explicitly).
+ // So, we need to preserve RA in some temporary storage ourselves. The AT
+ // register can't be used for this because we need it to load a constant
+ // which will be added to the value that NAL stores in RA. And we can't
+ // use T9 for this in the context of the JNI compiler, which uses it
+ // as a scratch register (see InterproceduralScratchRegister()).
+ // If we were to add a 32-bit constant to RA using two ADDIU instructions,
+ // we'd also need to use the ROTR instruction, which requires no less than
+ // MIPSR2.
+ // Perhaps, we could use T8 or one of R2's multiplier/divider registers
+ // (LO or HI) or even a floating-point register, but that doesn't seem
+ // like a nice solution. We may want this to work on both R6 and pre-R6.
+ // For now simply use the stack for RA. This should be OK since for the
+ // vast majority of code a short PC-relative branch is sufficient.
+ // TODO: can this be improved?
+ Push(RA);
+ Nal();
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Lui(AT, High16Bits(offset));
+ Ori(AT, AT, Low16Bits(offset));
+ Addu(AT, AT, RA);
+ Lw(RA, SP, 0);
+ Jr(AT);
+ DecreaseFrameSize(kMipsWordSize);
+ break;
+ case Branch::kLongCondBranch:
+ // The comment on case 'Branch::kLongUncondBranch' applies here as well.
+ // Note: the opposite condition branch encodes 8 as the distance, which is equal to the
+ // number of instructions skipped:
+ // (PUSH(IncreaseFrameSize(ADDIU) + SW) + NAL + LUI + ORI + ADDU + LW + JR).
+ EmitBcond(Branch::OppositeCondition(condition), lhs, rhs, 8);
+ Push(RA);
+ Nal();
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Lui(AT, High16Bits(offset));
+ Ori(AT, AT, Low16Bits(offset));
+ Addu(AT, AT, RA);
+ Lw(RA, SP, 0);
+ Jr(AT);
+ DecreaseFrameSize(kMipsWordSize);
+ break;
+ case Branch::kLongCall:
+ Nal();
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Lui(AT, High16Bits(offset));
+ Ori(AT, AT, Low16Bits(offset));
+ Addu(lhs, AT, RA);
+ Jalr(lhs);
+ Nop();
+ break;
+
+ // R6 short branches.
+ case Branch::kR6UncondBranch:
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Bc(offset);
+ break;
+ case Branch::kR6CondBranch:
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ EmitBcondc(condition, lhs, rhs, offset);
+ Nop(); // TODO: improve by filling the forbidden slot.
+ break;
+ case Branch::kR6Call:
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Addiupc(lhs, offset);
+ Jialc(lhs, 0);
+ break;
+
+ // R6 long branches.
+ case Branch::kR6LongUncondBranch:
+ offset += (offset & 0x8000) << 1; // Account for sign extension in jic.
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Auipc(AT, High16Bits(offset));
+ Jic(AT, Low16Bits(offset));
+ break;
+ case Branch::kR6LongCondBranch:
+ EmitBcondc(Branch::OppositeCondition(condition), lhs, rhs, 2);
+ offset += (offset & 0x8000) << 1; // Account for sign extension in jic.
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Auipc(AT, High16Bits(offset));
+ Jic(AT, Low16Bits(offset));
+ break;
+ case Branch::kR6LongCall:
+ offset += (offset & 0x8000) << 1; // Account for sign extension in addiu.
+ CHECK_EQ(overwrite_location_, branch->GetOffsetLocation());
+ Auipc(lhs, High16Bits(offset));
+ Addiu(lhs, lhs, Low16Bits(offset));
+ Jialc(lhs, 0);
+ break;
+ }
+ CHECK_EQ(overwrite_location_, branch->GetEndLocation());
+ CHECK_LT(branch->GetSize(), static_cast<uint32_t>(Branch::kMaxBranchSize));
+}
+
+void MipsAssembler::B(MipsLabel* label) {
+ Buncond(label);
+}
+
+void MipsAssembler::Jalr(MipsLabel* label, Register indirect_reg) {
+ Call(label, indirect_reg);
+}
+
+void MipsAssembler::Beq(Register rs, Register rt, MipsLabel* label) {
+ Bcond(label, kCondEQ, rs, rt);
+}
+
+void MipsAssembler::Bne(Register rs, Register rt, MipsLabel* label) {
+ Bcond(label, kCondNE, rs, rt);
+}
+
+void MipsAssembler::Beqz(Register rt, MipsLabel* label) {
+ Bcond(label, kCondEQZ, rt);
+}
+
+void MipsAssembler::Bnez(Register rt, MipsLabel* label) {
+ Bcond(label, kCondNEZ, rt);
+}
+
+void MipsAssembler::Bltz(Register rt, MipsLabel* label) {
+ Bcond(label, kCondLTZ, rt);
+}
+
+void MipsAssembler::Bgez(Register rt, MipsLabel* label) {
+ Bcond(label, kCondGEZ, rt);
+}
+
+void MipsAssembler::Blez(Register rt, MipsLabel* label) {
+ Bcond(label, kCondLEZ, rt);
+}
+
+void MipsAssembler::Bgtz(Register rt, MipsLabel* label) {
+ Bcond(label, kCondGTZ, rt);
+}
+
+void MipsAssembler::Blt(Register rs, Register rt, MipsLabel* label) {
+ if (IsR6()) {
+ Bcond(label, kCondLT, rs, rt);
+ } else if (!Branch::IsNop(kCondLT, rs, rt)) {
+ // Synthesize the instruction (not available on R2).
+ Slt(AT, rs, rt);
+ Bnez(AT, label);
+ }
+}
+
+void MipsAssembler::Bge(Register rs, Register rt, MipsLabel* label) {
+ if (IsR6()) {
+ Bcond(label, kCondGE, rs, rt);
+ } else if (Branch::IsUncond(kCondGE, rs, rt)) {
+ B(label);
+ } else {
+ // Synthesize the instruction (not available on R2).
+ Slt(AT, rs, rt);
+ Beqz(AT, label);
+ }
+}
+
+void MipsAssembler::Bltu(Register rs, Register rt, MipsLabel* label) {
+ if (IsR6()) {
+ Bcond(label, kCondLTU, rs, rt);
+ } else if (!Branch::IsNop(kCondLTU, rs, rt)) {
+ // Synthesize the instruction (not available on R2).
+ Sltu(AT, rs, rt);
+ Bnez(AT, label);
+ }
+}
+
+void MipsAssembler::Bgeu(Register rs, Register rt, MipsLabel* label) {
+ if (IsR6()) {
+ Bcond(label, kCondGEU, rs, rt);
+ } else if (Branch::IsUncond(kCondGEU, rs, rt)) {
+ B(label);
+ } else {
+ // Synthesize the instruction (not available on R2).
+ Sltu(AT, rs, rt);
+ Beqz(AT, label);
}
}
void MipsAssembler::LoadFromOffset(LoadOperandType type, Register reg, Register base,
int32_t offset) {
+ // IsInt<16> must be passed a signed value.
+ if (!IsInt<16>(offset) ||
+ (type == kLoadDoubleword && !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+
switch (type) {
case kLoadSignedByte:
Lb(reg, base, offset);
@@ -488,8 +1617,16 @@
case kLoadWord:
Lw(reg, base, offset);
break;
- case kLoadWordPair:
- LOG(FATAL) << "UNREACHABLE";
+ case kLoadDoubleword:
+ if (reg == base) {
+ // This will clobber the base when loading the lower register. Since we have to load the
+ // higher register as well, this will fail. Solution: reverse the order.
+ Lw(static_cast<Register>(reg + 1), base, offset + kMipsWordSize);
+ Lw(reg, base, offset);
+ } else {
+ Lw(reg, base, offset);
+ Lw(static_cast<Register>(reg + 1), base, offset + kMipsWordSize);
+ }
break;
default:
LOG(FATAL) << "UNREACHABLE";
@@ -497,15 +1634,74 @@
}
void MipsAssembler::LoadSFromOffset(FRegister reg, Register base, int32_t offset) {
+ if (!IsInt<16>(offset)) {
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+
Lwc1(reg, base, offset);
}
-void MipsAssembler::LoadDFromOffset(DRegister reg, Register base, int32_t offset) {
- Ldc1(reg, base, offset);
+void MipsAssembler::LoadDFromOffset(FRegister reg, Register base, int32_t offset) {
+ // IsInt<16> must be passed a signed value.
+ if (!IsInt<16>(offset) ||
+ (!IsAligned<kMipsDoublewordSize>(offset) &&
+ !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+
+ if (offset & 0x7) {
+ if (Is32BitFPU()) {
+ Lwc1(reg, base, offset);
+ Lwc1(static_cast<FRegister>(reg + 1), base, offset + kMipsWordSize);
+ } else {
+ // 64-bit FPU.
+ Lwc1(reg, base, offset);
+ Lw(T8, base, offset + kMipsWordSize);
+ Mthc1(T8, reg);
+ }
+ } else {
+ Ldc1(reg, base, offset);
+ }
+}
+
+void MipsAssembler::EmitLoad(ManagedRegister m_dst, Register src_register, int32_t src_offset,
+ size_t size) {
+ MipsManagedRegister dst = m_dst.AsMips();
+ if (dst.IsNoRegister()) {
+ CHECK_EQ(0u, size) << dst;
+ } else if (dst.IsCoreRegister()) {
+ CHECK_EQ(kMipsWordSize, size) << dst;
+ LoadFromOffset(kLoadWord, dst.AsCoreRegister(), src_register, src_offset);
+ } else if (dst.IsRegisterPair()) {
+ CHECK_EQ(kMipsDoublewordSize, size) << dst;
+ LoadFromOffset(kLoadDoubleword, dst.AsRegisterPairLow(), src_register, src_offset);
+ } else if (dst.IsFRegister()) {
+ if (size == kMipsWordSize) {
+ LoadSFromOffset(dst.AsFRegister(), src_register, src_offset);
+ } else {
+ CHECK_EQ(kMipsDoublewordSize, size) << dst;
+ LoadDFromOffset(dst.AsFRegister(), src_register, src_offset);
+ }
+ }
}
void MipsAssembler::StoreToOffset(StoreOperandType type, Register reg, Register base,
int32_t offset) {
+ // IsInt<16> must be passed a signed value.
+ if (!IsInt<16>(offset) ||
+ (type == kStoreDoubleword && !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+
switch (type) {
case kStoreByte:
Sb(reg, base, offset);
@@ -516,8 +1712,11 @@
case kStoreWord:
Sw(reg, base, offset);
break;
- case kStoreWordPair:
- LOG(FATAL) << "UNREACHABLE";
+ case kStoreDoubleword:
+ CHECK_NE(reg, base);
+ CHECK_NE(static_cast<Register>(reg + 1), base);
+ Sw(reg, base, offset);
+ Sw(static_cast<Register>(reg + 1), base, offset + kMipsWordSize);
break;
default:
LOG(FATAL) << "UNREACHABLE";
@@ -525,11 +1724,40 @@
}
void MipsAssembler::StoreSToOffset(FRegister reg, Register base, int32_t offset) {
+ if (!IsInt<16>(offset)) {
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+
Swc1(reg, base, offset);
}
-void MipsAssembler::StoreDToOffset(DRegister reg, Register base, int32_t offset) {
- Sdc1(reg, base, offset);
+void MipsAssembler::StoreDToOffset(FRegister reg, Register base, int32_t offset) {
+ // IsInt<16> must be passed a signed value.
+ if (!IsInt<16>(offset) ||
+ (!IsAligned<kMipsDoublewordSize>(offset) &&
+ !IsInt<16>(static_cast<int32_t>(offset + kMipsWordSize)))) {
+ LoadConst32(AT, offset);
+ Addu(AT, AT, base);
+ base = AT;
+ offset = 0;
+ }
+
+ if (offset & 0x7) {
+ if (Is32BitFPU()) {
+ Swc1(reg, base, offset);
+ Swc1(static_cast<FRegister>(reg + 1), base, offset + kMipsWordSize);
+ } else {
+ // 64-bit FPU.
+ Mfhc1(T8, reg);
+ Swc1(reg, base, offset);
+ Sw(T8, base, offset + kMipsWordSize);
+ }
+ } else {
+ Sdc1(reg, base, offset);
+ }
}
static dwarf::Reg DWARFReg(Register reg) {
@@ -546,7 +1774,7 @@
// Increase frame to required size.
IncreaseFrameSize(frame_size);
- // Push callee saves and return address
+ // Push callee saves and return address.
int stack_offset = frame_size - kFramePointerSize;
StoreToOffset(kStoreWord, RA, SP, stack_offset);
cfi_.RelOffset(DWARFReg(RA), stack_offset);
@@ -569,13 +1797,13 @@
offset += spill.getSize();
} else if (reg.IsCoreRegister()) {
StoreToOffset(kStoreWord, reg.AsCoreRegister(), SP, offset);
- offset += 4;
+ offset += kMipsWordSize;
} else if (reg.IsFRegister()) {
StoreSToOffset(reg.AsFRegister(), SP, offset);
- offset += 4;
+ offset += kMipsWordSize;
} else if (reg.IsDRegister()) {
- StoreDToOffset(reg.AsDRegister(), SP, offset);
- offset += 8;
+ StoreDToOffset(reg.AsOverlappingDRegisterLow(), SP, offset);
+ offset += kMipsDoublewordSize;
}
}
}
@@ -585,7 +1813,7 @@
CHECK_ALIGNED(frame_size, kStackAlignment);
cfi_.RememberState();
- // Pop callee saves and return address
+ // Pop callee saves and return address.
int stack_offset = frame_size - (callee_save_regs.size() * kFramePointerSize) - kFramePointerSize;
for (size_t i = 0; i < callee_save_regs.size(); ++i) {
Register reg = callee_save_regs.at(i).AsMips().AsCoreRegister();
@@ -601,6 +1829,7 @@
// Then jump to the return address.
Jr(RA);
+ Nop();
// The CFI should be restored for any code that follows the exit block.
cfi_.RestoreState();
@@ -608,14 +1837,14 @@
}
void MipsAssembler::IncreaseFrameSize(size_t adjust) {
- CHECK_ALIGNED(adjust, kStackAlignment);
- AddConstant(SP, SP, -adjust);
+ CHECK_ALIGNED(adjust, kFramePointerSize);
+ Addiu32(SP, SP, -adjust);
cfi_.AdjustCFAOffset(adjust);
}
void MipsAssembler::DecreaseFrameSize(size_t adjust) {
- CHECK_ALIGNED(adjust, kStackAlignment);
- AddConstant(SP, SP, adjust);
+ CHECK_ALIGNED(adjust, kFramePointerSize);
+ Addiu32(SP, SP, adjust);
cfi_.AdjustCFAOffset(-adjust);
}
@@ -624,18 +1853,20 @@
if (src.IsNoRegister()) {
CHECK_EQ(0u, size);
} else if (src.IsCoreRegister()) {
- CHECK_EQ(4u, size);
+ CHECK_EQ(kMipsWordSize, size);
StoreToOffset(kStoreWord, src.AsCoreRegister(), SP, dest.Int32Value());
} else if (src.IsRegisterPair()) {
- CHECK_EQ(8u, size);
+ CHECK_EQ(kMipsDoublewordSize, size);
StoreToOffset(kStoreWord, src.AsRegisterPairLow(), SP, dest.Int32Value());
StoreToOffset(kStoreWord, src.AsRegisterPairHigh(),
- SP, dest.Int32Value() + 4);
+ SP, dest.Int32Value() + kMipsWordSize);
} else if (src.IsFRegister()) {
- StoreSToOffset(src.AsFRegister(), SP, dest.Int32Value());
- } else {
- CHECK(src.IsDRegister());
- StoreDToOffset(src.AsDRegister(), SP, dest.Int32Value());
+ if (size == kMipsWordSize) {
+ StoreSToOffset(src.AsFRegister(), SP, dest.Int32Value());
+ } else {
+ CHECK_EQ(kMipsDoublewordSize, size);
+ StoreDToOffset(src.AsFRegister(), SP, dest.Int32Value());
+ }
}
}
@@ -655,29 +1886,30 @@
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
- LoadImmediate(scratch.AsCoreRegister(), imm);
+ LoadConst32(scratch.AsCoreRegister(), imm);
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
}
-void MipsAssembler::StoreImmediateToThread32(ThreadOffset<4> dest, uint32_t imm,
- ManagedRegister mscratch) {
- MipsManagedRegister scratch = mscratch.AsMips();
- CHECK(scratch.IsCoreRegister()) << scratch;
- LoadImmediate(scratch.AsCoreRegister(), imm);
- StoreToOffset(kStoreWord, scratch.AsCoreRegister(), S1, dest.Int32Value());
-}
-
-void MipsAssembler::StoreStackOffsetToThread32(ThreadOffset<4> thr_offs,
- FrameOffset fr_offs,
+void MipsAssembler::StoreImmediateToThread32(ThreadOffset<kMipsWordSize> dest, uint32_t imm,
ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
- AddConstant(scratch.AsCoreRegister(), SP, fr_offs.Int32Value());
+ // Is this function even referenced anywhere else in the code?
+ LoadConst32(scratch.AsCoreRegister(), imm);
+ StoreToOffset(kStoreWord, scratch.AsCoreRegister(), S1, dest.Int32Value());
+}
+
+void MipsAssembler::StoreStackOffsetToThread32(ThreadOffset<kMipsWordSize> thr_offs,
+ FrameOffset fr_offs,
+ ManagedRegister mscratch) {
+ MipsManagedRegister scratch = mscratch.AsMips();
+ CHECK(scratch.IsCoreRegister()) << scratch;
+ Addiu32(scratch.AsCoreRegister(), SP, fr_offs.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(),
S1, thr_offs.Int32Value());
}
-void MipsAssembler::StoreStackPointerToThread32(ThreadOffset<4> thr_offs) {
+void MipsAssembler::StoreStackPointerToThread32(ThreadOffset<kMipsWordSize> thr_offs) {
StoreToOffset(kStoreWord, SP, S1, thr_offs.Int32Value());
}
@@ -687,14 +1919,15 @@
MipsManagedRegister scratch = mscratch.AsMips();
StoreToOffset(kStoreWord, src.AsCoreRegister(), SP, dest.Int32Value());
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, in_off.Int32Value());
- StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value() + 4);
+ StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value() + kMipsWordSize);
}
void MipsAssembler::Load(ManagedRegister mdest, FrameOffset src, size_t size) {
return EmitLoad(mdest, SP, src.Int32Value(), size);
}
-void MipsAssembler::LoadFromThread32(ManagedRegister mdest, ThreadOffset<4> src, size_t size) {
+void MipsAssembler::LoadFromThread32(ManagedRegister mdest,
+ ThreadOffset<kMipsWordSize> src, size_t size) {
return EmitLoad(mdest, S1, src.Int32Value(), size);
}
@@ -707,7 +1940,7 @@
void MipsAssembler::LoadRef(ManagedRegister mdest, ManagedRegister base, MemberOffset offs,
bool unpoison_reference) {
MipsManagedRegister dest = mdest.AsMips();
- CHECK(dest.IsCoreRegister() && dest.IsCoreRegister());
+ CHECK(dest.IsCoreRegister() && base.AsMips().IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(),
base.AsMips().AsCoreRegister(), offs.Int32Value());
if (kPoisonHeapReferences && unpoison_reference) {
@@ -715,16 +1948,15 @@
}
}
-void MipsAssembler::LoadRawPtr(ManagedRegister mdest, ManagedRegister base,
- Offset offs) {
+void MipsAssembler::LoadRawPtr(ManagedRegister mdest, ManagedRegister base, Offset offs) {
MipsManagedRegister dest = mdest.AsMips();
- CHECK(dest.IsCoreRegister() && dest.IsCoreRegister()) << dest;
+ CHECK(dest.IsCoreRegister() && base.AsMips().IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(),
base.AsMips().AsCoreRegister(), offs.Int32Value());
}
void MipsAssembler::LoadRawPtrFromThread32(ManagedRegister mdest,
- ThreadOffset<4> offs) {
+ ThreadOffset<kMipsWordSize> offs) {
MipsManagedRegister dest = mdest.AsMips();
CHECK(dest.IsCoreRegister());
LoadFromOffset(kLoadWord, dest.AsCoreRegister(), S1, offs.Int32Value());
@@ -738,7 +1970,7 @@
UNIMPLEMENTED(FATAL) << "no zero extension necessary for mips";
}
-void MipsAssembler::Move(ManagedRegister mdest, ManagedRegister msrc, size_t /*size*/) {
+void MipsAssembler::Move(ManagedRegister mdest, ManagedRegister msrc, size_t size) {
MipsManagedRegister dest = mdest.AsMips();
MipsManagedRegister src = msrc.AsMips();
if (!dest.Equals(src)) {
@@ -747,14 +1979,19 @@
Move(dest.AsCoreRegister(), src.AsCoreRegister());
} else if (dest.IsFRegister()) {
CHECK(src.IsFRegister()) << src;
- MovS(dest.AsFRegister(), src.AsFRegister());
+ if (size == kMipsWordSize) {
+ MovS(dest.AsFRegister(), src.AsFRegister());
+ } else {
+ CHECK_EQ(kMipsDoublewordSize, size);
+ MovD(dest.AsFRegister(), src.AsFRegister());
+ }
} else if (dest.IsDRegister()) {
CHECK(src.IsDRegister()) << src;
- MovD(dest.AsDRegister(), src.AsDRegister());
+ MovD(dest.AsOverlappingDRegisterLow(), src.AsOverlappingDRegisterLow());
} else {
CHECK(dest.IsRegisterPair()) << dest;
CHECK(src.IsRegisterPair()) << src;
- // Ensure that the first move doesn't clobber the input of the second
+ // Ensure that the first move doesn't clobber the input of the second.
if (src.AsRegisterPairHigh() != dest.AsRegisterPairLow()) {
Move(dest.AsRegisterPairLow(), src.AsRegisterPairLow());
Move(dest.AsRegisterPairHigh(), src.AsRegisterPairHigh());
@@ -766,8 +2003,7 @@
}
}
-void MipsAssembler::CopyRef(FrameOffset dest, FrameOffset src,
- ManagedRegister mscratch) {
+void MipsAssembler::CopyRef(FrameOffset dest, FrameOffset src, ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value());
@@ -775,8 +2011,8 @@
}
void MipsAssembler::CopyRawPtrFromThread32(FrameOffset fr_offs,
- ThreadOffset<4> thr_offs,
- ManagedRegister mscratch) {
+ ThreadOffset<kMipsWordSize> thr_offs,
+ ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
@@ -785,9 +2021,9 @@
SP, fr_offs.Int32Value());
}
-void MipsAssembler::CopyRawPtrToThread32(ThreadOffset<4> thr_offs,
- FrameOffset fr_offs,
- ManagedRegister mscratch) {
+void MipsAssembler::CopyRawPtrToThread32(ThreadOffset<kMipsWordSize> thr_offs,
+ FrameOffset fr_offs,
+ ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
@@ -796,26 +2032,25 @@
S1, thr_offs.Int32Value());
}
-void MipsAssembler::Copy(FrameOffset dest, FrameOffset src,
- ManagedRegister mscratch, size_t size) {
+void MipsAssembler::Copy(FrameOffset dest, FrameOffset src, ManagedRegister mscratch, size_t size) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
- CHECK(size == 4 || size == 8) << size;
- if (size == 4) {
+ CHECK(size == kMipsWordSize || size == kMipsDoublewordSize) << size;
+ if (size == kMipsWordSize) {
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
- } else if (size == 8) {
+ } else if (size == kMipsDoublewordSize) {
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value());
- LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value() + 4);
- StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value() + 4);
+ LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, src.Int32Value() + kMipsWordSize);
+ StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, dest.Int32Value() + kMipsWordSize);
}
}
void MipsAssembler::Copy(FrameOffset dest, ManagedRegister src_base, Offset src_offset,
ManagedRegister mscratch, size_t size) {
Register scratch = mscratch.AsMips().AsCoreRegister();
- CHECK_EQ(size, 4u);
+ CHECK_EQ(size, kMipsWordSize);
LoadFromOffset(kLoadWord, scratch, src_base.AsMips().AsCoreRegister(), src_offset.Int32Value());
StoreToOffset(kStoreWord, scratch, SP, dest.Int32Value());
}
@@ -823,107 +2058,117 @@
void MipsAssembler::Copy(ManagedRegister dest_base, Offset dest_offset, FrameOffset src,
ManagedRegister mscratch, size_t size) {
Register scratch = mscratch.AsMips().AsCoreRegister();
- CHECK_EQ(size, 4u);
+ CHECK_EQ(size, kMipsWordSize);
LoadFromOffset(kLoadWord, scratch, SP, src.Int32Value());
StoreToOffset(kStoreWord, scratch, dest_base.AsMips().AsCoreRegister(), dest_offset.Int32Value());
}
-void MipsAssembler::Copy(FrameOffset /*dest*/, FrameOffset /*src_base*/, Offset /*src_offset*/,
- ManagedRegister /*mscratch*/, size_t /*size*/) {
- UNIMPLEMENTED(FATAL) << "no mips implementation";
+void MipsAssembler::Copy(FrameOffset dest ATTRIBUTE_UNUSED,
+ FrameOffset src_base ATTRIBUTE_UNUSED,
+ Offset src_offset ATTRIBUTE_UNUSED,
+ ManagedRegister mscratch ATTRIBUTE_UNUSED,
+ size_t size ATTRIBUTE_UNUSED) {
+ UNIMPLEMENTED(FATAL) << "no MIPS implementation";
}
void MipsAssembler::Copy(ManagedRegister dest, Offset dest_offset,
ManagedRegister src, Offset src_offset,
ManagedRegister mscratch, size_t size) {
- CHECK_EQ(size, 4u);
+ CHECK_EQ(size, kMipsWordSize);
Register scratch = mscratch.AsMips().AsCoreRegister();
LoadFromOffset(kLoadWord, scratch, src.AsMips().AsCoreRegister(), src_offset.Int32Value());
StoreToOffset(kStoreWord, scratch, dest.AsMips().AsCoreRegister(), dest_offset.Int32Value());
}
-void MipsAssembler::Copy(FrameOffset /*dest*/, Offset /*dest_offset*/, FrameOffset /*src*/, Offset /*src_offset*/,
- ManagedRegister /*mscratch*/, size_t /*size*/) {
- UNIMPLEMENTED(FATAL) << "no mips implementation";
+void MipsAssembler::Copy(FrameOffset dest ATTRIBUTE_UNUSED,
+ Offset dest_offset ATTRIBUTE_UNUSED,
+ FrameOffset src ATTRIBUTE_UNUSED,
+ Offset src_offset ATTRIBUTE_UNUSED,
+ ManagedRegister mscratch ATTRIBUTE_UNUSED,
+ size_t size ATTRIBUTE_UNUSED) {
+ UNIMPLEMENTED(FATAL) << "no MIPS implementation";
}
void MipsAssembler::MemoryBarrier(ManagedRegister) {
- UNIMPLEMENTED(FATAL) << "no mips implementation";
+ // TODO: sync?
+ UNIMPLEMENTED(FATAL) << "no MIPS implementation";
}
void MipsAssembler::CreateHandleScopeEntry(ManagedRegister mout_reg,
- FrameOffset handle_scope_offset,
- ManagedRegister min_reg, bool null_allowed) {
+ FrameOffset handle_scope_offset,
+ ManagedRegister min_reg,
+ bool null_allowed) {
MipsManagedRegister out_reg = mout_reg.AsMips();
MipsManagedRegister in_reg = min_reg.AsMips();
CHECK(in_reg.IsNoRegister() || in_reg.IsCoreRegister()) << in_reg;
CHECK(out_reg.IsCoreRegister()) << out_reg;
if (null_allowed) {
- Label null_arg;
+ MipsLabel null_arg;
// Null values get a handle scope entry value of 0. Otherwise, the handle scope entry is
// the address in the handle scope holding the reference.
- // e.g. out_reg = (handle == 0) ? 0 : (SP+handle_offset)
+ // E.g. out_reg = (handle == 0) ? 0 : (SP+handle_offset).
if (in_reg.IsNoRegister()) {
LoadFromOffset(kLoadWord, out_reg.AsCoreRegister(),
SP, handle_scope_offset.Int32Value());
in_reg = out_reg;
}
if (!out_reg.Equals(in_reg)) {
- LoadImmediate(out_reg.AsCoreRegister(), 0);
+ LoadConst32(out_reg.AsCoreRegister(), 0);
}
- EmitBranch(in_reg.AsCoreRegister(), ZERO, &null_arg, true);
- AddConstant(out_reg.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
- Bind(&null_arg, false);
+ Beqz(in_reg.AsCoreRegister(), &null_arg);
+ Addiu32(out_reg.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
+ Bind(&null_arg);
} else {
- AddConstant(out_reg.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
+ Addiu32(out_reg.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
}
}
void MipsAssembler::CreateHandleScopeEntry(FrameOffset out_off,
- FrameOffset handle_scope_offset,
- ManagedRegister mscratch,
- bool null_allowed) {
+ FrameOffset handle_scope_offset,
+ ManagedRegister mscratch,
+ bool null_allowed) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
if (null_allowed) {
- Label null_arg;
- LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP,
- handle_scope_offset.Int32Value());
+ MipsLabel null_arg;
+ LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
// Null values get a handle scope entry value of 0. Otherwise, the handle scope entry is
// the address in the handle scope holding the reference.
- // e.g. scratch = (scratch == 0) ? 0 : (SP+handle_scope_offset)
- EmitBranch(scratch.AsCoreRegister(), ZERO, &null_arg, true);
- AddConstant(scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
- Bind(&null_arg, false);
+ // E.g. scratch = (scratch == 0) ? 0 : (SP+handle_scope_offset).
+ Beqz(scratch.AsCoreRegister(), &null_arg);
+ Addiu32(scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
+ Bind(&null_arg);
} else {
- AddConstant(scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
+ Addiu32(scratch.AsCoreRegister(), SP, handle_scope_offset.Int32Value());
}
StoreToOffset(kStoreWord, scratch.AsCoreRegister(), SP, out_off.Int32Value());
}
// Given a handle scope entry, load the associated reference.
void MipsAssembler::LoadReferenceFromHandleScope(ManagedRegister mout_reg,
- ManagedRegister min_reg) {
+ ManagedRegister min_reg) {
MipsManagedRegister out_reg = mout_reg.AsMips();
MipsManagedRegister in_reg = min_reg.AsMips();
CHECK(out_reg.IsCoreRegister()) << out_reg;
CHECK(in_reg.IsCoreRegister()) << in_reg;
- Label null_arg;
+ MipsLabel null_arg;
if (!out_reg.Equals(in_reg)) {
- LoadImmediate(out_reg.AsCoreRegister(), 0);
+ LoadConst32(out_reg.AsCoreRegister(), 0);
}
- EmitBranch(in_reg.AsCoreRegister(), ZERO, &null_arg, true);
+ Beqz(in_reg.AsCoreRegister(), &null_arg);
LoadFromOffset(kLoadWord, out_reg.AsCoreRegister(),
in_reg.AsCoreRegister(), 0);
- Bind(&null_arg, false);
+ Bind(&null_arg);
}
-void MipsAssembler::VerifyObject(ManagedRegister /*src*/, bool /*could_be_null*/) {
- // TODO: not validating references
+void MipsAssembler::VerifyObject(ManagedRegister src ATTRIBUTE_UNUSED,
+ bool could_be_null ATTRIBUTE_UNUSED) {
+ // TODO: not validating references.
}
-void MipsAssembler::VerifyObject(FrameOffset /*src*/, bool /*could_be_null*/) {
- // TODO: not validating references
+void MipsAssembler::VerifyObject(FrameOffset src ATTRIBUTE_UNUSED,
+ bool could_be_null ATTRIBUTE_UNUSED) {
+ // TODO: not validating references.
}
void MipsAssembler::Call(ManagedRegister mbase, Offset offset, ManagedRegister mscratch) {
@@ -934,22 +2179,24 @@
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
base.AsCoreRegister(), offset.Int32Value());
Jalr(scratch.AsCoreRegister());
- // TODO: place reference map on call
+ Nop();
+ // TODO: place reference map on call.
}
void MipsAssembler::Call(FrameOffset base, Offset offset, ManagedRegister mscratch) {
MipsManagedRegister scratch = mscratch.AsMips();
CHECK(scratch.IsCoreRegister()) << scratch;
// Call *(*(SP + base) + offset)
- LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
- SP, base.Int32Value());
+ LoadFromOffset(kLoadWord, scratch.AsCoreRegister(), SP, base.Int32Value());
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
scratch.AsCoreRegister(), offset.Int32Value());
Jalr(scratch.AsCoreRegister());
- // TODO: place reference map on call
+ Nop();
+ // TODO: place reference map on call.
}
-void MipsAssembler::CallFromThread32(ThreadOffset<4> /*offset*/, ManagedRegister /*mscratch*/) {
+void MipsAssembler::CallFromThread32(ThreadOffset<kMipsWordSize> offset ATTRIBUTE_UNUSED,
+ ManagedRegister mscratch ATTRIBUTE_UNUSED) {
UNIMPLEMENTED(FATAL) << "no mips implementation";
}
@@ -958,35 +2205,38 @@
}
void MipsAssembler::GetCurrentThread(FrameOffset offset,
- ManagedRegister /*mscratch*/) {
+ ManagedRegister mscratch ATTRIBUTE_UNUSED) {
StoreToOffset(kStoreWord, S1, SP, offset.Int32Value());
}
void MipsAssembler::ExceptionPoll(ManagedRegister mscratch, size_t stack_adjust) {
MipsManagedRegister scratch = mscratch.AsMips();
- MipsExceptionSlowPath* slow = new MipsExceptionSlowPath(scratch, stack_adjust);
- buffer_.EnqueueSlowPath(slow);
+ exception_blocks_.emplace_back(scratch, stack_adjust);
LoadFromOffset(kLoadWord, scratch.AsCoreRegister(),
- S1, Thread::ExceptionOffset<4>().Int32Value());
- EmitBranch(scratch.AsCoreRegister(), ZERO, slow->Entry(), false);
+ S1, Thread::ExceptionOffset<kMipsWordSize>().Int32Value());
+ // TODO: on MIPS32R6 prefer Bnezc(scratch.AsCoreRegister(), slow.Entry());
+ // as the NAL instruction (occurring in long R2 branches) may become deprecated.
+ // For now use common for R2 and R6 instructions as this code must execute on both.
+ Bnez(scratch.AsCoreRegister(), exception_blocks_.back().Entry());
}
-void MipsExceptionSlowPath::Emit(Assembler* sasm) {
- MipsAssembler* sp_asm = down_cast<MipsAssembler*>(sasm);
-#define __ sp_asm->
- __ Bind(&entry_, false);
- if (stack_adjust_ != 0) { // Fix up the frame.
- __ DecreaseFrameSize(stack_adjust_);
+void MipsAssembler::EmitExceptionPoll(MipsExceptionSlowPath* exception) {
+ Bind(exception->Entry());
+ if (exception->stack_adjust_ != 0) { // Fix up the frame.
+ DecreaseFrameSize(exception->stack_adjust_);
}
- // Pass exception object as argument
- // Don't care about preserving A0 as this call won't return
- __ Move(A0, scratch_.AsCoreRegister());
- // Set up call to Thread::Current()->pDeliverException
- __ LoadFromOffset(kLoadWord, T9, S1, QUICK_ENTRYPOINT_OFFSET(4, pDeliverException).Int32Value());
- __ Jr(T9);
- // Call never returns
- __ Break();
-#undef __
+ // Pass exception object as argument.
+ // Don't care about preserving A0 as this call won't return.
+ CheckEntrypointTypes<kQuickDeliverException, void, mirror::Object*>();
+ Move(A0, exception->scratch_.AsCoreRegister());
+ // Set up call to Thread::Current()->pDeliverException.
+ LoadFromOffset(kLoadWord, T9, S1,
+ QUICK_ENTRYPOINT_OFFSET(kMipsWordSize, pDeliverException).Int32Value());
+ Jr(T9);
+ Nop();
+
+ // Call never returns.
+ Break();
}
} // namespace mips
diff --git a/compiler/utils/mips/assembler_mips.h b/compiler/utils/mips/assembler_mips.h
index 378a59c..aa187b8 100644
--- a/compiler/utils/mips/assembler_mips.h
+++ b/compiler/utils/mips/assembler_mips.h
@@ -17,54 +17,111 @@
#ifndef ART_COMPILER_UTILS_MIPS_ASSEMBLER_MIPS_H_
#define ART_COMPILER_UTILS_MIPS_ASSEMBLER_MIPS_H_
+#include <utility>
#include <vector>
+#include "arch/mips/instruction_set_features_mips.h"
#include "base/macros.h"
#include "constants_mips.h"
#include "globals.h"
#include "managed_register_mips.h"
-#include "utils/assembler.h"
#include "offsets.h"
+#include "utils/assembler.h"
+#include "utils/label.h"
namespace art {
namespace mips {
+static constexpr size_t kMipsWordSize = 4;
+static constexpr size_t kMipsDoublewordSize = 8;
+
enum LoadOperandType {
kLoadSignedByte,
kLoadUnsignedByte,
kLoadSignedHalfword,
kLoadUnsignedHalfword,
kLoadWord,
- kLoadWordPair,
- kLoadSWord,
- kLoadDWord
+ kLoadDoubleword
};
enum StoreOperandType {
kStoreByte,
kStoreHalfword,
kStoreWord,
- kStoreWordPair,
- kStoreSWord,
- kStoreDWord
+ kStoreDoubleword
+};
+
+class MipsLabel : public Label {
+ public:
+ MipsLabel() : prev_branch_id_plus_one_(0) {}
+
+ MipsLabel(MipsLabel&& src)
+ : Label(std::move(src)), prev_branch_id_plus_one_(src.prev_branch_id_plus_one_) {}
+
+ private:
+ uint32_t prev_branch_id_plus_one_; // To get distance from preceding branch, if any.
+
+ friend class MipsAssembler;
+ DISALLOW_COPY_AND_ASSIGN(MipsLabel);
+};
+
+// Slowpath entered when Thread::Current()->_exception is non-null.
+class MipsExceptionSlowPath {
+ public:
+ explicit MipsExceptionSlowPath(MipsManagedRegister scratch, size_t stack_adjust)
+ : scratch_(scratch), stack_adjust_(stack_adjust) {}
+
+ MipsExceptionSlowPath(MipsExceptionSlowPath&& src)
+ : scratch_(std::move(src.scratch_)),
+ stack_adjust_(std::move(src.stack_adjust_)),
+ exception_entry_(std::move(src.exception_entry_)) {}
+
+ private:
+ MipsLabel* Entry() { return &exception_entry_; }
+ const MipsManagedRegister scratch_;
+ const size_t stack_adjust_;
+ MipsLabel exception_entry_;
+
+ friend class MipsAssembler;
+ DISALLOW_COPY_AND_ASSIGN(MipsExceptionSlowPath);
};
class MipsAssembler FINAL : public Assembler {
public:
- MipsAssembler() {}
- virtual ~MipsAssembler() {}
+ explicit MipsAssembler(const MipsInstructionSetFeatures* instruction_set_features = nullptr)
+ : overwriting_(false),
+ overwrite_location_(0),
+ last_position_adjustment_(0),
+ last_old_position_(0),
+ last_branch_id_(0),
+ isa_features_(instruction_set_features) {}
+
+ virtual ~MipsAssembler() {
+ for (auto& branch : branches_) {
+ CHECK(branch.IsResolved());
+ }
+ }
// Emit Machine Instructions.
- void Add(Register rd, Register rs, Register rt);
void Addu(Register rd, Register rs, Register rt);
- void Addi(Register rt, Register rs, uint16_t imm16);
void Addiu(Register rt, Register rs, uint16_t imm16);
- void Sub(Register rd, Register rs, Register rt);
void Subu(Register rd, Register rs, Register rt);
- void Mult(Register rs, Register rt);
- void Multu(Register rs, Register rt);
- void Div(Register rs, Register rt);
- void Divu(Register rs, Register rt);
+
+ void MultR2(Register rs, Register rt); // R2
+ void MultuR2(Register rs, Register rt); // R2
+ void DivR2(Register rs, Register rt); // R2
+ void DivuR2(Register rs, Register rt); // R2
+ void MulR2(Register rd, Register rs, Register rt); // R2
+ void DivR2(Register rd, Register rs, Register rt); // R2
+ void ModR2(Register rd, Register rs, Register rt); // R2
+ void DivuR2(Register rd, Register rs, Register rt); // R2
+ void ModuR2(Register rd, Register rs, Register rt); // R2
+ void MulR6(Register rd, Register rs, Register rt); // R6
+ void MuhuR6(Register rd, Register rs, Register rt); // R6
+ void DivR6(Register rd, Register rs, Register rt); // R6
+ void ModR6(Register rd, Register rs, Register rt); // R6
+ void DivuR6(Register rd, Register rs, Register rt); // R6
+ void ModuR6(Register rd, Register rs, Register rt); // R6
void And(Register rd, Register rs, Register rt);
void Andi(Register rt, Register rs, uint16_t imm16);
@@ -74,12 +131,15 @@
void Xori(Register rt, Register rs, uint16_t imm16);
void Nor(Register rd, Register rs, Register rt);
- void Sll(Register rd, Register rs, int shamt);
- void Srl(Register rd, Register rs, int shamt);
- void Sra(Register rd, Register rs, int shamt);
- void Sllv(Register rd, Register rs, Register rt);
- void Srlv(Register rd, Register rs, Register rt);
- void Srav(Register rd, Register rs, Register rt);
+ void Seb(Register rd, Register rt); // R2+
+ void Seh(Register rd, Register rt); // R2+
+
+ void Sll(Register rd, Register rt, int shamt);
+ void Srl(Register rd, Register rt, int shamt);
+ void Sra(Register rd, Register rt, int shamt);
+ void Sllv(Register rd, Register rt, Register rs);
+ void Srlv(Register rd, Register rt, Register rs);
+ void Srav(Register rd, Register rt, Register rs);
void Lb(Register rt, Register rs, uint16_t imm16);
void Lh(Register rt, Register rs, uint16_t imm16);
@@ -87,8 +147,9 @@
void Lbu(Register rt, Register rs, uint16_t imm16);
void Lhu(Register rt, Register rs, uint16_t imm16);
void Lui(Register rt, uint16_t imm16);
- void Mfhi(Register rd);
- void Mflo(Register rd);
+ void Sync(uint32_t stype);
+ void Mfhi(Register rd); // R2
+ void Mflo(Register rd); // R2
void Sb(Register rt, Register rs, uint16_t imm16);
void Sh(Register rt, Register rs, uint16_t imm16);
@@ -99,81 +160,138 @@
void Slti(Register rt, Register rs, uint16_t imm16);
void Sltiu(Register rt, Register rs, uint16_t imm16);
- void Beq(Register rt, Register rs, uint16_t imm16);
- void Bne(Register rt, Register rs, uint16_t imm16);
- void J(uint32_t address);
- void Jal(uint32_t address);
- void Jr(Register rs);
+ void B(uint16_t imm16);
+ void Beq(Register rs, Register rt, uint16_t imm16);
+ void Bne(Register rs, Register rt, uint16_t imm16);
+ void Beqz(Register rt, uint16_t imm16);
+ void Bnez(Register rt, uint16_t imm16);
+ void Bltz(Register rt, uint16_t imm16);
+ void Bgez(Register rt, uint16_t imm16);
+ void Blez(Register rt, uint16_t imm16);
+ void Bgtz(Register rt, uint16_t imm16);
+ void J(uint32_t addr26);
+ void Jal(uint32_t addr26);
+ void Jalr(Register rd, Register rs);
void Jalr(Register rs);
+ void Jr(Register rs);
+ void Nal();
+ void Auipc(Register rs, uint16_t imm16); // R6
+ void Addiupc(Register rs, uint32_t imm19); // R6
+ void Bc(uint32_t imm26); // R6
+ void Jic(Register rt, uint16_t imm16); // R6
+ void Jialc(Register rt, uint16_t imm16); // R6
+ void Bltc(Register rs, Register rt, uint16_t imm16); // R6
+ void Bltzc(Register rt, uint16_t imm16); // R6
+ void Bgtzc(Register rt, uint16_t imm16); // R6
+ void Bgec(Register rs, Register rt, uint16_t imm16); // R6
+ void Bgezc(Register rt, uint16_t imm16); // R6
+ void Blezc(Register rt, uint16_t imm16); // R6
+ void Bltuc(Register rs, Register rt, uint16_t imm16); // R6
+ void Bgeuc(Register rs, Register rt, uint16_t imm16); // R6
+ void Beqc(Register rs, Register rt, uint16_t imm16); // R6
+ void Bnec(Register rs, Register rt, uint16_t imm16); // R6
+ void Beqzc(Register rs, uint32_t imm21); // R6
+ void Bnezc(Register rs, uint32_t imm21); // R6
void AddS(FRegister fd, FRegister fs, FRegister ft);
void SubS(FRegister fd, FRegister fs, FRegister ft);
void MulS(FRegister fd, FRegister fs, FRegister ft);
void DivS(FRegister fd, FRegister fs, FRegister ft);
- void AddD(DRegister fd, DRegister fs, DRegister ft);
- void SubD(DRegister fd, DRegister fs, DRegister ft);
- void MulD(DRegister fd, DRegister fs, DRegister ft);
- void DivD(DRegister fd, DRegister fs, DRegister ft);
+ void AddD(FRegister fd, FRegister fs, FRegister ft);
+ void SubD(FRegister fd, FRegister fs, FRegister ft);
+ void MulD(FRegister fd, FRegister fs, FRegister ft);
+ void DivD(FRegister fd, FRegister fs, FRegister ft);
void MovS(FRegister fd, FRegister fs);
- void MovD(DRegister fd, DRegister fs);
+ void MovD(FRegister fd, FRegister fs);
+ void NegS(FRegister fd, FRegister fs);
+ void NegD(FRegister fd, FRegister fs);
+
+ void Cvtsw(FRegister fd, FRegister fs);
+ void Cvtdw(FRegister fd, FRegister fs);
+ void Cvtsd(FRegister fd, FRegister fs);
+ void Cvtds(FRegister fd, FRegister fs);
void Mfc1(Register rt, FRegister fs);
- void Mtc1(FRegister ft, Register rs);
+ void Mtc1(Register rt, FRegister fs);
+ void Mfhc1(Register rt, FRegister fs);
+ void Mthc1(Register rt, FRegister fs);
void Lwc1(FRegister ft, Register rs, uint16_t imm16);
- void Ldc1(DRegister ft, Register rs, uint16_t imm16);
+ void Ldc1(FRegister ft, Register rs, uint16_t imm16);
void Swc1(FRegister ft, Register rs, uint16_t imm16);
- void Sdc1(DRegister ft, Register rs, uint16_t imm16);
+ void Sdc1(FRegister ft, Register rs, uint16_t imm16);
void Break();
void Nop();
- void Move(Register rt, Register rs);
- void Clear(Register rt);
- void Not(Register rt, Register rs);
- void Mul(Register rd, Register rs, Register rt);
- void Div(Register rd, Register rs, Register rt);
- void Rem(Register rd, Register rs, Register rt);
+ void Move(Register rd, Register rs);
+ void Clear(Register rd);
+ void Not(Register rd, Register rs);
- void AddConstant(Register rt, Register rs, int32_t value);
- void LoadImmediate(Register rt, int32_t value);
+ // Higher level composite instructions.
+ void LoadConst32(Register rd, int32_t value);
+ void LoadConst64(Register reg_hi, Register reg_lo, int64_t value);
+ void LoadDConst64(FRegister rd, int64_t value, Register temp);
+ void LoadSConst32(FRegister r, int32_t value, Register temp);
+ void StoreConst32ToOffset(int32_t value, Register base, int32_t offset, Register temp);
+ void StoreConst64ToOffset(int64_t value, Register base, int32_t offset, Register temp);
+ void Addiu32(Register rt, Register rs, int32_t value, Register rtmp = AT);
+
+ // These will generate R2 branches or R6 branches as appropriate.
+ void Bind(MipsLabel* label);
+ void B(MipsLabel* label);
+ void Jalr(MipsLabel* label, Register indirect_reg);
+ void Beq(Register rs, Register rt, MipsLabel* label);
+ void Bne(Register rs, Register rt, MipsLabel* label);
+ void Beqz(Register rt, MipsLabel* label);
+ void Bnez(Register rt, MipsLabel* label);
+ void Bltz(Register rt, MipsLabel* label);
+ void Bgez(Register rt, MipsLabel* label);
+ void Blez(Register rt, MipsLabel* label);
+ void Bgtz(Register rt, MipsLabel* label);
+ void Blt(Register rs, Register rt, MipsLabel* label);
+ void Bge(Register rs, Register rt, MipsLabel* label);
+ void Bltu(Register rs, Register rt, MipsLabel* label);
+ void Bgeu(Register rs, Register rt, MipsLabel* label);
void EmitLoad(ManagedRegister m_dst, Register src_register, int32_t src_offset, size_t size);
void LoadFromOffset(LoadOperandType type, Register reg, Register base, int32_t offset);
void LoadSFromOffset(FRegister reg, Register base, int32_t offset);
- void LoadDFromOffset(DRegister reg, Register base, int32_t offset);
+ void LoadDFromOffset(FRegister reg, Register base, int32_t offset);
void StoreToOffset(StoreOperandType type, Register reg, Register base, int32_t offset);
void StoreSToOffset(FRegister reg, Register base, int32_t offset);
- void StoreDToOffset(DRegister reg, Register base, int32_t offset);
+ void StoreDToOffset(FRegister reg, Register base, int32_t offset);
// Emit data (e.g. encoded instruction or immediate) to the instruction stream.
- void Emit(int32_t value);
- void EmitBranch(Register rt, Register rs, Label* label, bool equal);
- void EmitJump(Label* label, bool link);
- void Bind(Label* label, bool is_jump);
+ void Emit(uint32_t value);
+
+ // Push/pop composite routines.
+ void Push(Register rs);
+ void Pop(Register rd);
+ void PopAndReturn(Register rd, Register rt);
void Bind(Label* label) OVERRIDE {
- Bind(label, false);
+ Bind(down_cast<MipsLabel*>(label));
}
- void Jump(Label* label) OVERRIDE {
- EmitJump(label, false);
+ void Jump(Label* label ATTRIBUTE_UNUSED) OVERRIDE {
+ UNIMPLEMENTED(FATAL) << "Do not use Jump for MIPS";
}
//
- // Overridden common assembler high-level functionality
+ // Overridden common assembler high-level functionality.
//
- // Emit code that will create an activation on the stack
+ // Emit code that will create an activation on the stack.
void BuildFrame(size_t frame_size, ManagedRegister method_reg,
const std::vector<ManagedRegister>& callee_save_regs,
const ManagedRegisterEntrySpills& entry_spills) OVERRIDE;
- // Emit code that will remove an activation from the stack
+ // Emit code that will remove an activation from the stack.
void RemoveFrame(size_t frame_size, const std::vector<ManagedRegister>& callee_save_regs)
OVERRIDE;
void IncreaseFrameSize(size_t adjust) OVERRIDE;
void DecreaseFrameSize(size_t adjust) OVERRIDE;
- // Store routines
+ // Store routines.
void Store(FrameOffset offs, ManagedRegister msrc, size_t size) OVERRIDE;
void StoreRef(FrameOffset dest, ManagedRegister msrc) OVERRIDE;
void StoreRawPtr(FrameOffset dest, ManagedRegister msrc) OVERRIDE;
@@ -191,7 +309,7 @@
void StoreSpanning(FrameOffset dest, ManagedRegister msrc, FrameOffset in_off,
ManagedRegister mscratch) OVERRIDE;
- // Load routines
+ // Load routines.
void Load(ManagedRegister mdest, FrameOffset src, size_t size) OVERRIDE;
void LoadFromThread32(ManagedRegister mdest, ThreadOffset<4> src, size_t size) OVERRIDE;
@@ -205,7 +323,7 @@
void LoadRawPtrFromThread32(ManagedRegister mdest, ThreadOffset<4> offs) OVERRIDE;
- // Copying routines
+ // Copying routines.
void Move(ManagedRegister mdest, ManagedRegister msrc, size_t size) OVERRIDE;
void CopyRawPtrFromThread32(FrameOffset fr_offs, ThreadOffset<4> thr_offs,
@@ -235,13 +353,13 @@
void MemoryBarrier(ManagedRegister) OVERRIDE;
- // Sign extension
+ // Sign extension.
void SignExtend(ManagedRegister mreg, size_t size) OVERRIDE;
- // Zero extension
+ // Zero extension.
void ZeroExtend(ManagedRegister mreg, size_t size) OVERRIDE;
- // Exploit fast access in managed code to Thread::Current()
+ // Exploit fast access in managed code to Thread::Current().
void GetCurrentThread(ManagedRegister tr) OVERRIDE;
void GetCurrentThread(FrameOffset dest_offset, ManagedRegister mscratch) OVERRIDE;
@@ -257,7 +375,7 @@
void CreateHandleScopeEntry(FrameOffset out_off, FrameOffset handlescope_offset,
ManagedRegister mscratch, bool null_allowed) OVERRIDE;
- // src holds a handle scope entry (Object**) load this into dst
+ // src holds a handle scope entry (Object**) load this into dst.
void LoadReferenceFromHandleScope(ManagedRegister dst, ManagedRegister src) OVERRIDE;
// Heap::VerifyObject on src. In some cases (such as a reference to this) we
@@ -265,7 +383,7 @@
void VerifyObject(ManagedRegister src, bool could_be_null) OVERRIDE;
void VerifyObject(FrameOffset src, bool could_be_null) OVERRIDE;
- // Call to address held at [base+offset]
+ // Call to address held at [base+offset].
void Call(ManagedRegister base, Offset offset, ManagedRegister mscratch) OVERRIDE;
void Call(FrameOffset base, Offset offset, ManagedRegister mscratch) OVERRIDE;
void CallFromThread32(ThreadOffset<4> offset, ManagedRegister mscratch) OVERRIDE;
@@ -274,43 +392,253 @@
// and branch to a ExceptionSlowPath if it is.
void ExceptionPoll(ManagedRegister mscratch, size_t stack_adjust) OVERRIDE;
+ // Emit slow paths queued during assembly and promote short branches to long if needed.
+ void FinalizeCode() OVERRIDE;
+
+ // Emit branches and finalize all instructions.
+ void FinalizeInstructions(const MemoryRegion& region);
+
+ // Returns the (always-)current location of a label (can be used in class CodeGeneratorMIPS,
+ // must be used instead of MipsLabel::GetPosition()).
+ uint32_t GetLabelLocation(MipsLabel* label) const;
+
+ // Get the final position of a label after local fixup based on the old position
+ // recorded before FinalizeCode().
+ uint32_t GetAdjustedPosition(uint32_t old_position);
+
+ enum BranchCondition {
+ kCondLT,
+ kCondGE,
+ kCondLE,
+ kCondGT,
+ kCondLTZ,
+ kCondGEZ,
+ kCondLEZ,
+ kCondGTZ,
+ kCondEQ,
+ kCondNE,
+ kCondEQZ,
+ kCondNEZ,
+ kCondLTU,
+ kCondGEU,
+ kUncond,
+ };
+ friend std::ostream& operator<<(std::ostream& os, const BranchCondition& rhs);
+
private:
+ class Branch {
+ public:
+ enum Type {
+ // R2 short branches.
+ kUncondBranch,
+ kCondBranch,
+ kCall,
+ // R2 long branches.
+ kLongUncondBranch,
+ kLongCondBranch,
+ kLongCall,
+ // R6 short branches.
+ kR6UncondBranch,
+ kR6CondBranch,
+ kR6Call,
+ // R6 long branches.
+ kR6LongUncondBranch,
+ kR6LongCondBranch,
+ kR6LongCall,
+ };
+ // Bit sizes of offsets defined as enums to minimize chance of typos.
+ enum OffsetBits {
+ kOffset16 = 16,
+ kOffset18 = 18,
+ kOffset21 = 21,
+ kOffset23 = 23,
+ kOffset28 = 28,
+ kOffset32 = 32,
+ };
+
+ static constexpr uint32_t kUnresolved = 0xffffffff; // Unresolved target_
+ static constexpr int32_t kMaxBranchLength = 32;
+ static constexpr int32_t kMaxBranchSize = kMaxBranchLength * sizeof(uint32_t);
+
+ struct BranchInfo {
+ // Branch length as a number of 4-byte-long instructions.
+ uint32_t length;
+ // Ordinal number (0-based) of the first (or the only) instruction that contains the branch's
+ // PC-relative offset (or its most significant 16-bit half, which goes first).
+ uint32_t instr_offset;
+ // Different MIPS instructions with PC-relative offsets apply said offsets to slightly
+ // different origins, e.g. to PC or PC+4. Encode the origin distance (as a number of 4-byte
+ // instructions) from the instruction containing the offset.
+ uint32_t pc_org;
+ // How large (in bits) a PC-relative offset can be for a given type of branch (kR6CondBranch
+ // is an exception: use kOffset23 for beqzc/bnezc).
+ OffsetBits offset_size;
+ // Some MIPS instructions with PC-relative offsets shift the offset by 2. Encode the shift
+ // count.
+ int offset_shift;
+ };
+ static const BranchInfo branch_info_[/* Type */];
+
+ // Unconditional branch.
+ Branch(bool is_r6, uint32_t location, uint32_t target);
+ // Conditional branch.
+ Branch(bool is_r6,
+ uint32_t location,
+ uint32_t target,
+ BranchCondition condition,
+ Register lhs_reg,
+ Register rhs_reg = ZERO);
+ // Call (branch and link) that stores the target address in a given register (i.e. T9).
+ Branch(bool is_r6, uint32_t location, uint32_t target, Register indirect_reg);
+
+ // Some conditional branches with lhs = rhs are effectively NOPs, while some
+ // others are effectively unconditional. MIPSR6 conditional branches require lhs != rhs.
+ // So, we need a way to identify such branches in order to emit no instructions for them
+ // or change them to unconditional.
+ static bool IsNop(BranchCondition condition, Register lhs, Register rhs);
+ static bool IsUncond(BranchCondition condition, Register lhs, Register rhs);
+
+ static BranchCondition OppositeCondition(BranchCondition cond);
+
+ Type GetType() const;
+ BranchCondition GetCondition() const;
+ Register GetLeftRegister() const;
+ Register GetRightRegister() const;
+ uint32_t GetTarget() const;
+ uint32_t GetLocation() const;
+ uint32_t GetOldLocation() const;
+ uint32_t GetLength() const;
+ uint32_t GetOldLength() const;
+ uint32_t GetSize() const;
+ uint32_t GetOldSize() const;
+ uint32_t GetEndLocation() const;
+ uint32_t GetOldEndLocation() const;
+ bool IsLong() const;
+ bool IsResolved() const;
+
+ // Returns the bit size of the signed offset that the branch instruction can handle.
+ OffsetBits GetOffsetSize() const;
+
+ // Calculates the distance between two byte locations in the assembler buffer and
+ // returns the number of bits needed to represent the distance as a signed integer.
+ //
+ // Branch instructions have signed offsets of 16, 19 (addiupc), 21 (beqzc/bnezc),
+ // and 26 (bc) bits, which are additionally shifted left 2 positions at run time.
+ //
+ // Composite branches (made of several instructions) with longer reach have 32-bit
+ // offsets encoded as 2 16-bit "halves" in two instructions (high half goes first).
+ // The composite branches cover the range of PC + +/-2GB.
+ //
+ // The returned values are therefore: 18, 21, 23, 28 and 32. There's also a special
+ // case with the addiu instruction and a 16 bit offset.
+ static OffsetBits GetOffsetSizeNeeded(uint32_t location, uint32_t target);
+
+ // Resolve a branch when the target is known.
+ void Resolve(uint32_t target);
+
+ // Relocate a branch by a given delta if needed due to expansion of this or another
+ // branch at a given location by this delta (just changes location_ and target_).
+ void Relocate(uint32_t expand_location, uint32_t delta);
+
+ // If the branch is short, changes its type to long.
+ void PromoteToLong();
+
+ // If necessary, updates the type by promoting a short branch to a long branch
+ // based on the branch location and target. Returns the amount (in bytes) by
+ // which the branch size has increased.
+ // max_short_distance caps the maximum distance between location_ and target_
+ // that is allowed for short branches. This is for debugging/testing purposes.
+ // max_short_distance = 0 forces all short branches to become long.
+ // Use the implicit default argument when not debugging/testing.
+ uint32_t PromoteIfNeeded(uint32_t max_short_distance = std::numeric_limits<uint32_t>::max());
+
+ // Returns the location of the instruction(s) containing the offset.
+ uint32_t GetOffsetLocation() const;
+
+ // Calculates and returns the offset ready for encoding in the branch instruction(s).
+ uint32_t GetOffset() const;
+
+ private:
+ // Completes branch construction by determining and recording its type.
+ void InitializeType(bool is_call, bool is_r6);
+ // Helper for the above.
+ void InitShortOrLong(OffsetBits ofs_size, Type short_type, Type long_type);
+
+ uint32_t old_location_; // Offset into assembler buffer in bytes.
+ uint32_t location_; // Offset into assembler buffer in bytes.
+ uint32_t target_; // Offset into assembler buffer in bytes.
+
+ uint32_t lhs_reg_ : 5; // Left-hand side register in conditional branches or
+ // indirect call register.
+ uint32_t rhs_reg_ : 5; // Right-hand side register in conditional branches.
+ BranchCondition condition_ : 5; // Condition for conditional branches.
+
+ Type type_ : 5; // Current type of the branch.
+ Type old_type_ : 5; // Initial type of the branch.
+ };
+ friend std::ostream& operator<<(std::ostream& os, const Branch::Type& rhs);
+ friend std::ostream& operator<<(std::ostream& os, const Branch::OffsetBits& rhs);
+
void EmitR(int opcode, Register rs, Register rt, Register rd, int shamt, int funct);
void EmitI(int opcode, Register rs, Register rt, uint16_t imm);
- void EmitJ(int opcode, int address);
+ void EmitI21(int opcode, Register rs, uint32_t imm21);
+ void EmitI26(int opcode, uint32_t imm26);
void EmitFR(int opcode, int fmt, FRegister ft, FRegister fs, FRegister fd, int funct);
void EmitFI(int opcode, int fmt, FRegister rt, uint16_t imm);
+ void EmitBcond(BranchCondition cond, Register rs, Register rt, uint16_t imm16);
+ void EmitBcondc(BranchCondition cond, Register rs, Register rt, uint32_t imm16_21); // R6
- int32_t EncodeBranchOffset(int offset, int32_t inst, bool is_jump);
- int DecodeBranchOffset(int32_t inst, bool is_jump);
+ void Buncond(MipsLabel* label);
+ void Bcond(MipsLabel* label, BranchCondition condition, Register lhs, Register rhs = ZERO);
+ void Call(MipsLabel* label, Register indirect_reg);
+ void FinalizeLabeledBranch(MipsLabel* label);
- FRegister ConvertDRegToFReg(DRegister reg) {
- return static_cast<FRegister>(reg * 2);
+ Branch* GetBranch(uint32_t branch_id);
+ const Branch* GetBranch(uint32_t branch_id) const;
+
+ void PromoteBranches();
+ void EmitBranch(Branch* branch);
+ void EmitBranches();
+
+ // Emits exception block.
+ void EmitExceptionPoll(MipsExceptionSlowPath* exception);
+
+ bool IsR6() const {
+ if (isa_features_ != nullptr) {
+ return isa_features_->IsR6();
+ } else {
+ return false;
+ }
}
- Register ConvertDRegToReg(DRegister reg) {
- return static_cast<Register>(reg * 2);
+
+ bool Is32BitFPU() const {
+ if (isa_features_ != nullptr) {
+ return isa_features_->Is32BitFloatingPoint();
+ } else {
+ return true;
+ }
}
- Register ConvertFRegToReg(FRegister reg) {
- return static_cast<Register>(reg);
- }
- FRegister ConvertRegToFReg(Register reg) {
- return static_cast<FRegister>(reg);
- }
+
+ // List of exception blocks to generate at the end of the code cache.
+ std::vector<MipsExceptionSlowPath> exception_blocks_;
+
+ std::vector<Branch> branches_;
+
+ // Whether appending instructions at the end of the buffer or overwriting the existing ones.
+ bool overwriting_;
+ // The current overwrite location.
+ uint32_t overwrite_location_;
+
+ // Data for AdjustedPosition(), see the description there.
+ uint32_t last_position_adjustment_;
+ uint32_t last_old_position_;
+ uint32_t last_branch_id_;
+
+ const MipsInstructionSetFeatures* isa_features_;
DISALLOW_COPY_AND_ASSIGN(MipsAssembler);
};
-// Slowpath entered when Thread::Current()->_exception is non-null
-class MipsExceptionSlowPath FINAL : public SlowPath {
- public:
- MipsExceptionSlowPath(MipsManagedRegister scratch, size_t stack_adjust)
- : scratch_(scratch), stack_adjust_(stack_adjust) {}
- virtual void Emit(Assembler *sp_asm) OVERRIDE;
- private:
- const MipsManagedRegister scratch_;
- const size_t stack_adjust_;
-};
-
} // namespace mips
} // namespace art
diff --git a/compiler/utils/mips/assembler_mips_test.cc b/compiler/utils/mips/assembler_mips_test.cc
new file mode 100644
index 0000000..063d8bd
--- /dev/null
+++ b/compiler/utils/mips/assembler_mips_test.cc
@@ -0,0 +1,1324 @@
+/*
+ * Copyright (C) 2015 The Android Open Source Project
+ *
+ * Licensed under the Apache License, Version 2.0 (the "License");
+ * you may not use this file except in compliance with the License.
+ * You may obtain a copy of the License at
+ *
+ * http://www.apache.org/licenses/LICENSE-2.0
+ *
+ * Unless required by applicable law or agreed to in writing, software
+ * distributed under the License is distributed on an "AS IS" BASIS,
+ * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ * See the License for the specific language governing permissions and
+ * limitations under the License.
+ */
+
+#include "assembler_mips.h"
+
+#include <map>
+
+#include "base/stl_util.h"
+#include "utils/assembler_test.h"
+
+namespace art {
+
+struct MIPSCpuRegisterCompare {
+ bool operator()(const mips::Register& a, const mips::Register& b) const {
+ return a < b;
+ }
+};
+
+class AssemblerMIPSTest : public AssemblerTest<mips::MipsAssembler,
+ mips::Register,
+ mips::FRegister,
+ uint32_t> {
+ public:
+ typedef AssemblerTest<mips::MipsAssembler, mips::Register, mips::FRegister, uint32_t> Base;
+
+ protected:
+ // Get the typically used name for this architecture, e.g., aarch64, x86-64, ...
+ std::string GetArchitectureString() OVERRIDE {
+ return "mips";
+ }
+
+ std::string GetAssemblerParameters() OVERRIDE {
+ return " --no-warn -32 -march=mips32r2";
+ }
+
+ std::string GetDisassembleParameters() OVERRIDE {
+ return " -D -bbinary -mmips:isa32r2";
+ }
+
+ void SetUpHelpers() OVERRIDE {
+ if (registers_.size() == 0) {
+ registers_.push_back(new mips::Register(mips::ZERO));
+ registers_.push_back(new mips::Register(mips::AT));
+ registers_.push_back(new mips::Register(mips::V0));
+ registers_.push_back(new mips::Register(mips::V1));
+ registers_.push_back(new mips::Register(mips::A0));
+ registers_.push_back(new mips::Register(mips::A1));
+ registers_.push_back(new mips::Register(mips::A2));
+ registers_.push_back(new mips::Register(mips::A3));
+ registers_.push_back(new mips::Register(mips::T0));
+ registers_.push_back(new mips::Register(mips::T1));
+ registers_.push_back(new mips::Register(mips::T2));
+ registers_.push_back(new mips::Register(mips::T3));
+ registers_.push_back(new mips::Register(mips::T4));
+ registers_.push_back(new mips::Register(mips::T5));
+ registers_.push_back(new mips::Register(mips::T6));
+ registers_.push_back(new mips::Register(mips::T7));
+ registers_.push_back(new mips::Register(mips::S0));
+ registers_.push_back(new mips::Register(mips::S1));
+ registers_.push_back(new mips::Register(mips::S2));
+ registers_.push_back(new mips::Register(mips::S3));
+ registers_.push_back(new mips::Register(mips::S4));
+ registers_.push_back(new mips::Register(mips::S5));
+ registers_.push_back(new mips::Register(mips::S6));
+ registers_.push_back(new mips::Register(mips::S7));
+ registers_.push_back(new mips::Register(mips::T8));
+ registers_.push_back(new mips::Register(mips::T9));
+ registers_.push_back(new mips::Register(mips::K0));
+ registers_.push_back(new mips::Register(mips::K1));
+ registers_.push_back(new mips::Register(mips::GP));
+ registers_.push_back(new mips::Register(mips::SP));
+ registers_.push_back(new mips::Register(mips::FP));
+ registers_.push_back(new mips::Register(mips::RA));
+
+ secondary_register_names_.emplace(mips::Register(mips::ZERO), "zero");
+ secondary_register_names_.emplace(mips::Register(mips::AT), "at");
+ secondary_register_names_.emplace(mips::Register(mips::V0), "v0");
+ secondary_register_names_.emplace(mips::Register(mips::V1), "v1");
+ secondary_register_names_.emplace(mips::Register(mips::A0), "a0");
+ secondary_register_names_.emplace(mips::Register(mips::A1), "a1");
+ secondary_register_names_.emplace(mips::Register(mips::A2), "a2");
+ secondary_register_names_.emplace(mips::Register(mips::A3), "a3");
+ secondary_register_names_.emplace(mips::Register(mips::T0), "t0");
+ secondary_register_names_.emplace(mips::Register(mips::T1), "t1");
+ secondary_register_names_.emplace(mips::Register(mips::T2), "t2");
+ secondary_register_names_.emplace(mips::Register(mips::T3), "t3");
+ secondary_register_names_.emplace(mips::Register(mips::T4), "t4");
+ secondary_register_names_.emplace(mips::Register(mips::T5), "t5");
+ secondary_register_names_.emplace(mips::Register(mips::T6), "t6");
+ secondary_register_names_.emplace(mips::Register(mips::T7), "t7");
+ secondary_register_names_.emplace(mips::Register(mips::S0), "s0");
+ secondary_register_names_.emplace(mips::Register(mips::S1), "s1");
+ secondary_register_names_.emplace(mips::Register(mips::S2), "s2");
+ secondary_register_names_.emplace(mips::Register(mips::S3), "s3");
+ secondary_register_names_.emplace(mips::Register(mips::S4), "s4");
+ secondary_register_names_.emplace(mips::Register(mips::S5), "s5");
+ secondary_register_names_.emplace(mips::Register(mips::S6), "s6");
+ secondary_register_names_.emplace(mips::Register(mips::S7), "s7");
+ secondary_register_names_.emplace(mips::Register(mips::T8), "t8");
+ secondary_register_names_.emplace(mips::Register(mips::T9), "t9");
+ secondary_register_names_.emplace(mips::Register(mips::K0), "k0");
+ secondary_register_names_.emplace(mips::Register(mips::K1), "k1");
+ secondary_register_names_.emplace(mips::Register(mips::GP), "gp");
+ secondary_register_names_.emplace(mips::Register(mips::SP), "sp");
+ secondary_register_names_.emplace(mips::Register(mips::FP), "fp");
+ secondary_register_names_.emplace(mips::Register(mips::RA), "ra");
+
+ fp_registers_.push_back(new mips::FRegister(mips::F0));
+ fp_registers_.push_back(new mips::FRegister(mips::F1));
+ fp_registers_.push_back(new mips::FRegister(mips::F2));
+ fp_registers_.push_back(new mips::FRegister(mips::F3));
+ fp_registers_.push_back(new mips::FRegister(mips::F4));
+ fp_registers_.push_back(new mips::FRegister(mips::F5));
+ fp_registers_.push_back(new mips::FRegister(mips::F6));
+ fp_registers_.push_back(new mips::FRegister(mips::F7));
+ fp_registers_.push_back(new mips::FRegister(mips::F8));
+ fp_registers_.push_back(new mips::FRegister(mips::F9));
+ fp_registers_.push_back(new mips::FRegister(mips::F10));
+ fp_registers_.push_back(new mips::FRegister(mips::F11));
+ fp_registers_.push_back(new mips::FRegister(mips::F12));
+ fp_registers_.push_back(new mips::FRegister(mips::F13));
+ fp_registers_.push_back(new mips::FRegister(mips::F14));
+ fp_registers_.push_back(new mips::FRegister(mips::F15));
+ fp_registers_.push_back(new mips::FRegister(mips::F16));
+ fp_registers_.push_back(new mips::FRegister(mips::F17));
+ fp_registers_.push_back(new mips::FRegister(mips::F18));
+ fp_registers_.push_back(new mips::FRegister(mips::F19));
+ fp_registers_.push_back(new mips::FRegister(mips::F20));
+ fp_registers_.push_back(new mips::FRegister(mips::F21));
+ fp_registers_.push_back(new mips::FRegister(mips::F22));
+ fp_registers_.push_back(new mips::FRegister(mips::F23));
+ fp_registers_.push_back(new mips::FRegister(mips::F24));
+ fp_registers_.push_back(new mips::FRegister(mips::F25));
+ fp_registers_.push_back(new mips::FRegister(mips::F26));
+ fp_registers_.push_back(new mips::FRegister(mips::F27));
+ fp_registers_.push_back(new mips::FRegister(mips::F28));
+ fp_registers_.push_back(new mips::FRegister(mips::F29));
+ fp_registers_.push_back(new mips::FRegister(mips::F30));
+ fp_registers_.push_back(new mips::FRegister(mips::F31));
+ }
+ }
+
+ void TearDown() OVERRIDE {
+ AssemblerTest::TearDown();
+ STLDeleteElements(®isters_);
+ STLDeleteElements(&fp_registers_);
+ }
+
+ std::vector<mips::Register*> GetRegisters() OVERRIDE {
+ return registers_;
+ }
+
+ std::vector<mips::FRegister*> GetFPRegisters() OVERRIDE {
+ return fp_registers_;
+ }
+
+ uint32_t CreateImmediate(int64_t imm_value) OVERRIDE {
+ return imm_value;
+ }
+
+ std::string GetSecondaryRegisterName(const mips::Register& reg) OVERRIDE {
+ CHECK(secondary_register_names_.find(reg) != secondary_register_names_.end());
+ return secondary_register_names_[reg];
+ }
+
+ std::string RepeatInsn(size_t count, const std::string& insn) {
+ std::string result;
+ for (; count != 0u; --count) {
+ result += insn;
+ }
+ return result;
+ }
+
+ private:
+ std::vector<mips::Register*> registers_;
+ std::map<mips::Register, std::string, MIPSCpuRegisterCompare> secondary_register_names_;
+
+ std::vector<mips::FRegister*> fp_registers_;
+};
+
+
+TEST_F(AssemblerMIPSTest, Toolchain) {
+ EXPECT_TRUE(CheckTools());
+}
+
+#define __ GetAssembler()->
+
+TEST_F(AssemblerMIPSTest, Addu) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Addu, "addu ${reg1}, ${reg2}, ${reg3}"), "Addu");
+}
+
+TEST_F(AssemblerMIPSTest, Addiu) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Addiu, -16, "addiu ${reg1}, ${reg2}, {imm}"), "Addiu");
+}
+
+TEST_F(AssemblerMIPSTest, Subu) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Subu, "subu ${reg1}, ${reg2}, ${reg3}"), "Subu");
+}
+
+TEST_F(AssemblerMIPSTest, MultR2) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::MultR2, "mult ${reg1}, ${reg2}"), "MultR2");
+}
+
+TEST_F(AssemblerMIPSTest, MultuR2) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::MultuR2, "multu ${reg1}, ${reg2}"), "MultuR2");
+}
+
+TEST_F(AssemblerMIPSTest, DivR2Basic) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::DivR2, "div $zero, ${reg1}, ${reg2}"), "DivR2Basic");
+}
+
+TEST_F(AssemblerMIPSTest, DivuR2Basic) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::DivuR2, "divu $zero, ${reg1}, ${reg2}"), "DivuR2Basic");
+}
+
+TEST_F(AssemblerMIPSTest, MulR2) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::MulR2, "mul ${reg1}, ${reg2}, ${reg3}"), "MulR2");
+}
+
+TEST_F(AssemblerMIPSTest, DivR2) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::DivR2, "div $zero, ${reg2}, ${reg3}\nmflo ${reg1}"),
+ "DivR2");
+}
+
+TEST_F(AssemblerMIPSTest, ModR2) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::ModR2, "div $zero, ${reg2}, ${reg3}\nmfhi ${reg1}"),
+ "ModR2");
+}
+
+TEST_F(AssemblerMIPSTest, DivuR2) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::DivuR2, "divu $zero, ${reg2}, ${reg3}\nmflo ${reg1}"),
+ "DivuR2");
+}
+
+TEST_F(AssemblerMIPSTest, ModuR2) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::ModuR2, "divu $zero, ${reg2}, ${reg3}\nmfhi ${reg1}"),
+ "ModuR2");
+}
+
+TEST_F(AssemblerMIPSTest, And) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::And, "and ${reg1}, ${reg2}, ${reg3}"), "And");
+}
+
+TEST_F(AssemblerMIPSTest, Andi) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Andi, 16, "andi ${reg1}, ${reg2}, {imm}"), "Andi");
+}
+
+TEST_F(AssemblerMIPSTest, Or) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Or, "or ${reg1}, ${reg2}, ${reg3}"), "Or");
+}
+
+TEST_F(AssemblerMIPSTest, Ori) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Ori, 16, "ori ${reg1}, ${reg2}, {imm}"), "Ori");
+}
+
+TEST_F(AssemblerMIPSTest, Xor) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Xor, "xor ${reg1}, ${reg2}, ${reg3}"), "Xor");
+}
+
+TEST_F(AssemblerMIPSTest, Xori) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Xori, 16, "xori ${reg1}, ${reg2}, {imm}"), "Xori");
+}
+
+TEST_F(AssemblerMIPSTest, Nor) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Nor, "nor ${reg1}, ${reg2}, ${reg3}"), "Nor");
+}
+
+TEST_F(AssemblerMIPSTest, Seb) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::Seb, "seb ${reg1}, ${reg2}"), "Seb");
+}
+
+TEST_F(AssemblerMIPSTest, Seh) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::Seh, "seh ${reg1}, ${reg2}"), "Seh");
+}
+
+TEST_F(AssemblerMIPSTest, Sll) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Sll, 5, "sll ${reg1}, ${reg2}, {imm}"), "Sll");
+}
+
+TEST_F(AssemblerMIPSTest, Srl) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Srl, 5, "srl ${reg1}, ${reg2}, {imm}"), "Srl");
+}
+
+TEST_F(AssemblerMIPSTest, Sra) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Sra, 5, "sra ${reg1}, ${reg2}, {imm}"), "Sra");
+}
+
+TEST_F(AssemblerMIPSTest, Sllv) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Sllv, "sllv ${reg1}, ${reg2}, ${reg3}"), "Sllv");
+}
+
+TEST_F(AssemblerMIPSTest, Srlv) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Srlv, "srlv ${reg1}, ${reg2}, ${reg3}"), "Srlv");
+}
+
+TEST_F(AssemblerMIPSTest, Srav) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Srav, "srav ${reg1}, ${reg2}, ${reg3}"), "Srav");
+}
+
+TEST_F(AssemblerMIPSTest, Lb) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Lb, -16, "lb ${reg1}, {imm}(${reg2})"), "Lb");
+}
+
+TEST_F(AssemblerMIPSTest, Lh) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Lh, -16, "lh ${reg1}, {imm}(${reg2})"), "Lh");
+}
+
+TEST_F(AssemblerMIPSTest, Lw) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Lw, -16, "lw ${reg1}, {imm}(${reg2})"), "Lw");
+}
+
+TEST_F(AssemblerMIPSTest, Lbu) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Lbu, -16, "lbu ${reg1}, {imm}(${reg2})"), "Lbu");
+}
+
+TEST_F(AssemblerMIPSTest, Lhu) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Lhu, -16, "lhu ${reg1}, {imm}(${reg2})"), "Lhu");
+}
+
+TEST_F(AssemblerMIPSTest, Lui) {
+ DriverStr(RepeatRIb(&mips::MipsAssembler::Lui, 16, "lui ${reg}, {imm}"), "Lui");
+}
+
+TEST_F(AssemblerMIPSTest, Mfhi) {
+ DriverStr(RepeatR(&mips::MipsAssembler::Mfhi, "mfhi ${reg}"), "Mfhi");
+}
+
+TEST_F(AssemblerMIPSTest, Mflo) {
+ DriverStr(RepeatR(&mips::MipsAssembler::Mflo, "mflo ${reg}"), "Mflo");
+}
+
+TEST_F(AssemblerMIPSTest, Sb) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Sb, -16, "sb ${reg1}, {imm}(${reg2})"), "Sb");
+}
+
+TEST_F(AssemblerMIPSTest, Sh) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Sh, -16, "sh ${reg1}, {imm}(${reg2})"), "Sh");
+}
+
+TEST_F(AssemblerMIPSTest, Sw) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Sw, -16, "sw ${reg1}, {imm}(${reg2})"), "Sw");
+}
+
+TEST_F(AssemblerMIPSTest, Slt) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Slt, "slt ${reg1}, ${reg2}, ${reg3}"), "Slt");
+}
+
+TEST_F(AssemblerMIPSTest, Sltu) {
+ DriverStr(RepeatRRR(&mips::MipsAssembler::Sltu, "sltu ${reg1}, ${reg2}, ${reg3}"), "Sltu");
+}
+
+TEST_F(AssemblerMIPSTest, Slti) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Slti, -16, "slti ${reg1}, ${reg2}, {imm}"), "Slti");
+}
+
+TEST_F(AssemblerMIPSTest, Sltiu) {
+ DriverStr(RepeatRRIb(&mips::MipsAssembler::Sltiu, -16, "sltiu ${reg1}, ${reg2}, {imm}"), "Sltiu");
+}
+
+TEST_F(AssemblerMIPSTest, AddS) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::AddS, "add.s ${reg1}, ${reg2}, ${reg3}"), "AddS");
+}
+
+TEST_F(AssemblerMIPSTest, AddD) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::AddD, "add.d ${reg1}, ${reg2}, ${reg3}"), "AddD");
+}
+
+TEST_F(AssemblerMIPSTest, SubS) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::SubS, "sub.s ${reg1}, ${reg2}, ${reg3}"), "SubS");
+}
+
+TEST_F(AssemblerMIPSTest, SubD) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::SubD, "sub.d ${reg1}, ${reg2}, ${reg3}"), "SubD");
+}
+
+TEST_F(AssemblerMIPSTest, MulS) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::MulS, "mul.s ${reg1}, ${reg2}, ${reg3}"), "MulS");
+}
+
+TEST_F(AssemblerMIPSTest, MulD) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::MulD, "mul.d ${reg1}, ${reg2}, ${reg3}"), "MulD");
+}
+
+TEST_F(AssemblerMIPSTest, DivS) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::DivS, "div.s ${reg1}, ${reg2}, ${reg3}"), "DivS");
+}
+
+TEST_F(AssemblerMIPSTest, DivD) {
+ DriverStr(RepeatFFF(&mips::MipsAssembler::DivD, "div.d ${reg1}, ${reg2}, ${reg3}"), "DivD");
+}
+
+TEST_F(AssemblerMIPSTest, MovS) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::MovS, "mov.s ${reg1}, ${reg2}"), "MovS");
+}
+
+TEST_F(AssemblerMIPSTest, MovD) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::MovD, "mov.d ${reg1}, ${reg2}"), "MovD");
+}
+
+TEST_F(AssemblerMIPSTest, NegS) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::NegS, "neg.s ${reg1}, ${reg2}"), "NegS");
+}
+
+TEST_F(AssemblerMIPSTest, NegD) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::NegD, "neg.d ${reg1}, ${reg2}"), "NegD");
+}
+
+TEST_F(AssemblerMIPSTest, CvtSW) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::Cvtsw, "cvt.s.w ${reg1}, ${reg2}"), "CvtSW");
+}
+
+TEST_F(AssemblerMIPSTest, CvtDW) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::Cvtdw, "cvt.d.w ${reg1}, ${reg2}"), "CvtDW");
+}
+
+TEST_F(AssemblerMIPSTest, CvtSD) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::Cvtsd, "cvt.s.d ${reg1}, ${reg2}"), "CvtSD");
+}
+
+TEST_F(AssemblerMIPSTest, CvtDS) {
+ DriverStr(RepeatFF(&mips::MipsAssembler::Cvtds, "cvt.d.s ${reg1}, ${reg2}"), "CvtDS");
+}
+
+TEST_F(AssemblerMIPSTest, Mfc1) {
+ DriverStr(RepeatRF(&mips::MipsAssembler::Mfc1, "mfc1 ${reg1}, ${reg2}"), "Mfc1");
+}
+
+TEST_F(AssemblerMIPSTest, Mtc1) {
+ DriverStr(RepeatRF(&mips::MipsAssembler::Mtc1, "mtc1 ${reg1}, ${reg2}"), "Mtc1");
+}
+
+TEST_F(AssemblerMIPSTest, Mfhc1) {
+ DriverStr(RepeatRF(&mips::MipsAssembler::Mfhc1, "mfhc1 ${reg1}, ${reg2}"), "Mfhc1");
+}
+
+TEST_F(AssemblerMIPSTest, Mthc1) {
+ DriverStr(RepeatRF(&mips::MipsAssembler::Mthc1, "mthc1 ${reg1}, ${reg2}"), "Mthc1");
+}
+
+TEST_F(AssemblerMIPSTest, Lwc1) {
+ DriverStr(RepeatFRIb(&mips::MipsAssembler::Lwc1, -16, "lwc1 ${reg1}, {imm}(${reg2})"), "Lwc1");
+}
+
+TEST_F(AssemblerMIPSTest, Ldc1) {
+ DriverStr(RepeatFRIb(&mips::MipsAssembler::Ldc1, -16, "ldc1 ${reg1}, {imm}(${reg2})"), "Ldc1");
+}
+
+TEST_F(AssemblerMIPSTest, Swc1) {
+ DriverStr(RepeatFRIb(&mips::MipsAssembler::Swc1, -16, "swc1 ${reg1}, {imm}(${reg2})"), "Swc1");
+}
+
+TEST_F(AssemblerMIPSTest, Sdc1) {
+ DriverStr(RepeatFRIb(&mips::MipsAssembler::Sdc1, -16, "sdc1 ${reg1}, {imm}(${reg2})"), "Sdc1");
+}
+
+TEST_F(AssemblerMIPSTest, Move) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::Move, "or ${reg1}, ${reg2}, $zero"), "Move");
+}
+
+TEST_F(AssemblerMIPSTest, Clear) {
+ DriverStr(RepeatR(&mips::MipsAssembler::Clear, "or ${reg}, $zero, $zero"), "Clear");
+}
+
+TEST_F(AssemblerMIPSTest, Not) {
+ DriverStr(RepeatRR(&mips::MipsAssembler::Not, "nor ${reg1}, ${reg2}, $zero"), "Not");
+}
+
+TEST_F(AssemblerMIPSTest, LoadFromOffset) {
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 0);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 256);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 1000);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 0x8000);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 0x10000);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 0x12345678);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, -256);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 0xFFFF8000);
+ __ LoadFromOffset(mips::kLoadSignedByte, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 0);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 256);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 1000);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 0x8000);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 0x10000);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 0x12345678);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, -256);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 0xFFFF8000);
+ __ LoadFromOffset(mips::kLoadUnsignedByte, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 0);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 256);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 1000);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 0x8000);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 0x10000);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 0x12345678);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, -256);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 0xFFFF8000);
+ __ LoadFromOffset(mips::kLoadSignedHalfword, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 0);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 256);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 1000);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 0x8000);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 0x10000);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 0x12345678);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, -256);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 0xFFFF8000);
+ __ LoadFromOffset(mips::kLoadUnsignedHalfword, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 0);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 256);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 1000);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 0x8000);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 0x10000);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 0x12345678);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, -256);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 0xFFFF8000);
+ __ LoadFromOffset(mips::kLoadWord, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A1, 0);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A1, mips::A0, 0);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 0);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 256);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 1000);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 0x8000);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 0x10000);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 0x12345678);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, -256);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 0xFFFF8000);
+ __ LoadFromOffset(mips::kLoadDoubleword, mips::A0, mips::A2, 0xABCDEF00);
+
+ const char* expected =
+ "lb $a0, 0($a0)\n"
+ "lb $a0, 0($a1)\n"
+ "lb $a0, 256($a1)\n"
+ "lb $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "lb $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "lb $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "lb $a0, 0($at)\n"
+ "lb $a0, -256($a1)\n"
+ "lb $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "lb $a0, 0($at)\n"
+
+ "lbu $a0, 0($a0)\n"
+ "lbu $a0, 0($a1)\n"
+ "lbu $a0, 256($a1)\n"
+ "lbu $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "lbu $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "lbu $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "lbu $a0, 0($at)\n"
+ "lbu $a0, -256($a1)\n"
+ "lbu $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "lbu $a0, 0($at)\n"
+
+ "lh $a0, 0($a0)\n"
+ "lh $a0, 0($a1)\n"
+ "lh $a0, 256($a1)\n"
+ "lh $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "lh $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "lh $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "lh $a0, 0($at)\n"
+ "lh $a0, -256($a1)\n"
+ "lh $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "lh $a0, 0($at)\n"
+
+ "lhu $a0, 0($a0)\n"
+ "lhu $a0, 0($a1)\n"
+ "lhu $a0, 256($a1)\n"
+ "lhu $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "lhu $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "lhu $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "lhu $a0, 0($at)\n"
+ "lhu $a0, -256($a1)\n"
+ "lhu $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "lhu $a0, 0($at)\n"
+
+ "lw $a0, 0($a0)\n"
+ "lw $a0, 0($a1)\n"
+ "lw $a0, 256($a1)\n"
+ "lw $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "lw $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "lw $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "lw $a0, 0($at)\n"
+ "lw $a0, -256($a1)\n"
+ "lw $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "lw $a0, 0($at)\n"
+
+ "lw $a1, 4($a0)\n"
+ "lw $a0, 0($a0)\n"
+ "lw $a0, 0($a1)\n"
+ "lw $a1, 4($a1)\n"
+ "lw $a1, 0($a0)\n"
+ "lw $a2, 4($a0)\n"
+ "lw $a0, 0($a2)\n"
+ "lw $a1, 4($a2)\n"
+ "lw $a0, 256($a2)\n"
+ "lw $a1, 260($a2)\n"
+ "lw $a0, 1000($a2)\n"
+ "lw $a1, 1004($a2)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a2\n"
+ "lw $a0, 0($at)\n"
+ "lw $a1, 4($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a2\n"
+ "lw $a0, 0($at)\n"
+ "lw $a1, 4($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a2\n"
+ "lw $a0, 0($at)\n"
+ "lw $a1, 4($at)\n"
+ "lw $a0, -256($a2)\n"
+ "lw $a1, -252($a2)\n"
+ "lw $a0, 0xFFFF8000($a2)\n"
+ "lw $a1, 0xFFFF8004($a2)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a2\n"
+ "lw $a0, 0($at)\n"
+ "lw $a1, 4($at)\n";
+ DriverStr(expected, "LoadFromOffset");
+}
+
+TEST_F(AssemblerMIPSTest, LoadSFromOffset) {
+ __ LoadSFromOffset(mips::F0, mips::A0, 0);
+ __ LoadSFromOffset(mips::F0, mips::A0, 4);
+ __ LoadSFromOffset(mips::F0, mips::A0, 256);
+ __ LoadSFromOffset(mips::F0, mips::A0, 0x8000);
+ __ LoadSFromOffset(mips::F0, mips::A0, 0x10000);
+ __ LoadSFromOffset(mips::F0, mips::A0, 0x12345678);
+ __ LoadSFromOffset(mips::F0, mips::A0, -256);
+ __ LoadSFromOffset(mips::F0, mips::A0, 0xFFFF8000);
+ __ LoadSFromOffset(mips::F0, mips::A0, 0xABCDEF00);
+
+ const char* expected =
+ "lwc1 $f0, 0($a0)\n"
+ "lwc1 $f0, 4($a0)\n"
+ "lwc1 $f0, 256($a0)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a0\n"
+ "lwc1 $f0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a0\n"
+ "lwc1 $f0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a0\n"
+ "lwc1 $f0, 0($at)\n"
+ "lwc1 $f0, -256($a0)\n"
+ "lwc1 $f0, 0xFFFF8000($a0)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a0\n"
+ "lwc1 $f0, 0($at)\n";
+ DriverStr(expected, "LoadSFromOffset");
+}
+
+
+TEST_F(AssemblerMIPSTest, LoadDFromOffset) {
+ __ LoadDFromOffset(mips::F0, mips::A0, 0);
+ __ LoadDFromOffset(mips::F0, mips::A0, 4);
+ __ LoadDFromOffset(mips::F0, mips::A0, 256);
+ __ LoadDFromOffset(mips::F0, mips::A0, 0x8000);
+ __ LoadDFromOffset(mips::F0, mips::A0, 0x10000);
+ __ LoadDFromOffset(mips::F0, mips::A0, 0x12345678);
+ __ LoadDFromOffset(mips::F0, mips::A0, -256);
+ __ LoadDFromOffset(mips::F0, mips::A0, 0xFFFF8000);
+ __ LoadDFromOffset(mips::F0, mips::A0, 0xABCDEF00);
+
+ const char* expected =
+ "ldc1 $f0, 0($a0)\n"
+ "lwc1 $f0, 4($a0)\n"
+ "lwc1 $f1, 8($a0)\n"
+ "ldc1 $f0, 256($a0)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a0\n"
+ "ldc1 $f0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a0\n"
+ "ldc1 $f0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a0\n"
+ "ldc1 $f0, 0($at)\n"
+ "ldc1 $f0, -256($a0)\n"
+ "ldc1 $f0, 0xFFFF8000($a0)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a0\n"
+ "ldc1 $f0, 0($at)\n";
+ DriverStr(expected, "LoadDFromOffset");
+}
+
+TEST_F(AssemblerMIPSTest, StoreToOffset) {
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A0, 0);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 0);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 256);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 1000);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 0x8000);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 0x10000);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 0x12345678);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, -256);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 0xFFFF8000);
+ __ StoreToOffset(mips::kStoreByte, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A0, 0);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 0);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 256);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 1000);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 0x8000);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 0x10000);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 0x12345678);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, -256);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 0xFFFF8000);
+ __ StoreToOffset(mips::kStoreHalfword, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A0, 0);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 0);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 256);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 1000);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 0x8000);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 0x10000);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 0x12345678);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, -256);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 0xFFFF8000);
+ __ StoreToOffset(mips::kStoreWord, mips::A0, mips::A1, 0xABCDEF00);
+
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 0);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 256);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 1000);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 0x8000);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 0x10000);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 0x12345678);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, -256);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 0xFFFF8000);
+ __ StoreToOffset(mips::kStoreDoubleword, mips::A0, mips::A2, 0xABCDEF00);
+
+ const char* expected =
+ "sb $a0, 0($a0)\n"
+ "sb $a0, 0($a1)\n"
+ "sb $a0, 256($a1)\n"
+ "sb $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "sb $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "sb $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "sb $a0, 0($at)\n"
+ "sb $a0, -256($a1)\n"
+ "sb $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "sb $a0, 0($at)\n"
+
+ "sh $a0, 0($a0)\n"
+ "sh $a0, 0($a1)\n"
+ "sh $a0, 256($a1)\n"
+ "sh $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "sh $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "sh $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "sh $a0, 0($at)\n"
+ "sh $a0, -256($a1)\n"
+ "sh $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "sh $a0, 0($at)\n"
+
+ "sw $a0, 0($a0)\n"
+ "sw $a0, 0($a1)\n"
+ "sw $a0, 256($a1)\n"
+ "sw $a0, 1000($a1)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a1\n"
+ "sw $a0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a1\n"
+ "sw $a0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a1\n"
+ "sw $a0, 0($at)\n"
+ "sw $a0, -256($a1)\n"
+ "sw $a0, 0xFFFF8000($a1)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a1\n"
+ "sw $a0, 0($at)\n"
+
+ "sw $a0, 0($a2)\n"
+ "sw $a1, 4($a2)\n"
+ "sw $a0, 256($a2)\n"
+ "sw $a1, 260($a2)\n"
+ "sw $a0, 1000($a2)\n"
+ "sw $a1, 1004($a2)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a2\n"
+ "sw $a0, 0($at)\n"
+ "sw $a1, 4($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a2\n"
+ "sw $a0, 0($at)\n"
+ "sw $a1, 4($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a2\n"
+ "sw $a0, 0($at)\n"
+ "sw $a1, 4($at)\n"
+ "sw $a0, -256($a2)\n"
+ "sw $a1, -252($a2)\n"
+ "sw $a0, 0xFFFF8000($a2)\n"
+ "sw $a1, 0xFFFF8004($a2)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a2\n"
+ "sw $a0, 0($at)\n"
+ "sw $a1, 4($at)\n";
+ DriverStr(expected, "StoreToOffset");
+}
+
+TEST_F(AssemblerMIPSTest, StoreSToOffset) {
+ __ StoreSToOffset(mips::F0, mips::A0, 0);
+ __ StoreSToOffset(mips::F0, mips::A0, 4);
+ __ StoreSToOffset(mips::F0, mips::A0, 256);
+ __ StoreSToOffset(mips::F0, mips::A0, 0x8000);
+ __ StoreSToOffset(mips::F0, mips::A0, 0x10000);
+ __ StoreSToOffset(mips::F0, mips::A0, 0x12345678);
+ __ StoreSToOffset(mips::F0, mips::A0, -256);
+ __ StoreSToOffset(mips::F0, mips::A0, 0xFFFF8000);
+ __ StoreSToOffset(mips::F0, mips::A0, 0xABCDEF00);
+
+ const char* expected =
+ "swc1 $f0, 0($a0)\n"
+ "swc1 $f0, 4($a0)\n"
+ "swc1 $f0, 256($a0)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a0\n"
+ "swc1 $f0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a0\n"
+ "swc1 $f0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a0\n"
+ "swc1 $f0, 0($at)\n"
+ "swc1 $f0, -256($a0)\n"
+ "swc1 $f0, 0xFFFF8000($a0)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a0\n"
+ "swc1 $f0, 0($at)\n";
+ DriverStr(expected, "StoreSToOffset");
+}
+
+TEST_F(AssemblerMIPSTest, StoreDToOffset) {
+ __ StoreDToOffset(mips::F0, mips::A0, 0);
+ __ StoreDToOffset(mips::F0, mips::A0, 4);
+ __ StoreDToOffset(mips::F0, mips::A0, 256);
+ __ StoreDToOffset(mips::F0, mips::A0, 0x8000);
+ __ StoreDToOffset(mips::F0, mips::A0, 0x10000);
+ __ StoreDToOffset(mips::F0, mips::A0, 0x12345678);
+ __ StoreDToOffset(mips::F0, mips::A0, -256);
+ __ StoreDToOffset(mips::F0, mips::A0, 0xFFFF8000);
+ __ StoreDToOffset(mips::F0, mips::A0, 0xABCDEF00);
+
+ const char* expected =
+ "sdc1 $f0, 0($a0)\n"
+ "swc1 $f0, 4($a0)\n"
+ "swc1 $f1, 8($a0)\n"
+ "sdc1 $f0, 256($a0)\n"
+ "ori $at, $zero, 0x8000\n"
+ "addu $at, $at, $a0\n"
+ "sdc1 $f0, 0($at)\n"
+ "lui $at, 1\n"
+ "addu $at, $at, $a0\n"
+ "sdc1 $f0, 0($at)\n"
+ "lui $at, 0x1234\n"
+ "ori $at, 0x5678\n"
+ "addu $at, $at, $a0\n"
+ "sdc1 $f0, 0($at)\n"
+ "sdc1 $f0, -256($a0)\n"
+ "sdc1 $f0, 0xFFFF8000($a0)\n"
+ "lui $at, 0xABCD\n"
+ "ori $at, 0xEF00\n"
+ "addu $at, $at, $a0\n"
+ "sdc1 $f0, 0($at)\n";
+ DriverStr(expected, "StoreDToOffset");
+}
+
+TEST_F(AssemblerMIPSTest, B) {
+ mips::MipsLabel label1, label2;
+ __ B(&label1);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label1);
+ __ B(&label2);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label2);
+ __ B(&label1);
+
+ std::string expected =
+ ".set noreorder\n"
+ "b 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n"
+ "b 2f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "2:\n"
+ "b 1b\n"
+ "nop\n";
+ DriverStr(expected, "B");
+}
+
+TEST_F(AssemblerMIPSTest, Beq) {
+ mips::MipsLabel label;
+ __ Beq(mips::A0, mips::A1, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Beq(mips::A2, mips::A3, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "beq $a0, $a1, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "beq $a2, $a3, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Beq");
+}
+
+TEST_F(AssemblerMIPSTest, Bne) {
+ mips::MipsLabel label;
+ __ Bne(mips::A0, mips::A1, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bne(mips::A2, mips::A3, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "bne $a0, $a1, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "bne $a2, $a3, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bne");
+}
+
+TEST_F(AssemblerMIPSTest, Beqz) {
+ mips::MipsLabel label;
+ __ Beqz(mips::A0, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Beqz(mips::A1, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "beq $zero, $a0, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "beq $zero, $a1, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Beqz");
+}
+
+TEST_F(AssemblerMIPSTest, Bnez) {
+ mips::MipsLabel label;
+ __ Bnez(mips::A0, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bnez(mips::A1, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "bne $zero, $a0, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "bne $zero, $a1, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bnez");
+}
+
+TEST_F(AssemblerMIPSTest, Bltz) {
+ mips::MipsLabel label;
+ __ Bltz(mips::A0, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bltz(mips::A1, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "bltz $a0, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "bltz $a1, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bltz");
+}
+
+TEST_F(AssemblerMIPSTest, Bgez) {
+ mips::MipsLabel label;
+ __ Bgez(mips::A0, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bgez(mips::A1, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "bgez $a0, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "bgez $a1, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bgez");
+}
+
+TEST_F(AssemblerMIPSTest, Blez) {
+ mips::MipsLabel label;
+ __ Blez(mips::A0, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Blez(mips::A1, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "blez $a0, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "blez $a1, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Blez");
+}
+
+TEST_F(AssemblerMIPSTest, Bgtz) {
+ mips::MipsLabel label;
+ __ Bgtz(mips::A0, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bgtz(mips::A1, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "bgtz $a0, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "bgtz $a1, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bgtz");
+}
+
+TEST_F(AssemblerMIPSTest, Blt) {
+ mips::MipsLabel label;
+ __ Blt(mips::A0, mips::A1, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Blt(mips::A2, mips::A3, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "slt $at, $a0, $a1\n"
+ "bne $zero, $at, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "slt $at, $a2, $a3\n"
+ "bne $zero, $at, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Blt");
+}
+
+TEST_F(AssemblerMIPSTest, Bge) {
+ mips::MipsLabel label;
+ __ Bge(mips::A0, mips::A1, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bge(mips::A2, mips::A3, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "slt $at, $a0, $a1\n"
+ "beq $zero, $at, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "slt $at, $a2, $a3\n"
+ "beq $zero, $at, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bge");
+}
+
+TEST_F(AssemblerMIPSTest, Bltu) {
+ mips::MipsLabel label;
+ __ Bltu(mips::A0, mips::A1, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bltu(mips::A2, mips::A3, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "sltu $at, $a0, $a1\n"
+ "bne $zero, $at, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "sltu $at, $a2, $a3\n"
+ "bne $zero, $at, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bltu");
+}
+
+TEST_F(AssemblerMIPSTest, Bgeu) {
+ mips::MipsLabel label;
+ __ Bgeu(mips::A0, mips::A1, &label);
+ constexpr size_t kAdduCount1 = 63;
+ for (size_t i = 0; i != kAdduCount1; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bind(&label);
+ constexpr size_t kAdduCount2 = 64;
+ for (size_t i = 0; i != kAdduCount2; ++i) {
+ __ Addu(mips::ZERO, mips::ZERO, mips::ZERO);
+ }
+ __ Bgeu(mips::A2, mips::A3, &label);
+
+ std::string expected =
+ ".set noreorder\n"
+ "sltu $at, $a0, $a1\n"
+ "beq $zero, $at, 1f\n"
+ "nop\n" +
+ RepeatInsn(kAdduCount1, "addu $zero, $zero, $zero\n") +
+ "1:\n" +
+ RepeatInsn(kAdduCount2, "addu $zero, $zero, $zero\n") +
+ "sltu $at, $a2, $a3\n"
+ "beq $zero, $at, 1b\n"
+ "nop\n";
+ DriverStr(expected, "Bgeu");
+}
+
+#undef __
+
+} // namespace art