From 26a029d407be480d791972afb5975cf62c9360a6 Mon Sep 17 00:00:00 2001
From: Daniel Baumann <daniel.baumann@progress-linux.org>
Date: Fri, 19 Apr 2024 02:47:55 +0200
Subject: Adding upstream version 124.0.1.

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
---
 .../jit/mips-shared/CodeGenerator-mips-shared.cpp  | 2453 ++++++++++++++++++++
 1 file changed, 2453 insertions(+)
 create mode 100644 js/src/jit/mips-shared/CodeGenerator-mips-shared.cpp

(limited to 'js/src/jit/mips-shared/CodeGenerator-mips-shared.cpp')

diff --git a/js/src/jit/mips-shared/CodeGenerator-mips-shared.cpp b/js/src/jit/mips-shared/CodeGenerator-mips-shared.cpp
new file mode 100644
index 0000000000..424ddab061
--- /dev/null
+++ b/js/src/jit/mips-shared/CodeGenerator-mips-shared.cpp
@@ -0,0 +1,2453 @@
+/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
+ * vim: set ts=8 sts=2 et sw=2 tw=80:
+ * This Source Code Form is subject to the terms of the Mozilla Public
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
+
+#include "jit/mips-shared/CodeGenerator-mips-shared.h"
+
+#include "mozilla/DebugOnly.h"
+#include "mozilla/MathAlgorithms.h"
+
+#include "jsnum.h"
+
+#include "jit/CodeGenerator.h"
+#include "jit/InlineScriptTree.h"
+#include "jit/JitRuntime.h"
+#include "jit/MIR.h"
+#include "jit/MIRGraph.h"
+#include "js/Conversions.h"
+#include "vm/JSContext.h"
+#include "vm/Realm.h"
+#include "vm/Shape.h"
+
+#include "jit/MacroAssembler-inl.h"
+#include "jit/shared/CodeGenerator-shared-inl.h"
+#include "vm/JSScript-inl.h"
+
+using namespace js;
+using namespace js::jit;
+
+using JS::GenericNaN;
+using JS::ToInt32;
+using mozilla::DebugOnly;
+using mozilla::FloorLog2;
+using mozilla::NegativeInfinity;
+
+// shared
+CodeGeneratorMIPSShared::CodeGeneratorMIPSShared(MIRGenerator* gen,
+                                                 LIRGraph* graph,
+                                                 MacroAssembler* masm)
+    : CodeGeneratorShared(gen, graph, masm) {}
+
+Operand CodeGeneratorMIPSShared::ToOperand(const LAllocation& a) {
+  if (a.isGeneralReg()) {
+    return Operand(a.toGeneralReg()->reg());
+  }
+  if (a.isFloatReg()) {
+    return Operand(a.toFloatReg()->reg());
+  }
+  return Operand(ToAddress(a));
+}
+
+Operand CodeGeneratorMIPSShared::ToOperand(const LAllocation* a) {
+  return ToOperand(*a);
+}
+
+Operand CodeGeneratorMIPSShared::ToOperand(const LDefinition* def) {
+  return ToOperand(def->output());
+}
+
+#ifdef JS_PUNBOX64
+Operand CodeGeneratorMIPSShared::ToOperandOrRegister64(
+    const LInt64Allocation input) {
+  return ToOperand(input.value());
+}
+#else
+Register64 CodeGeneratorMIPSShared::ToOperandOrRegister64(
+    const LInt64Allocation input) {
+  return ToRegister64(input);
+}
+#endif
+
+void CodeGeneratorMIPSShared::branchToBlock(Assembler::FloatFormat fmt,
+                                            FloatRegister lhs,
+                                            FloatRegister rhs, MBasicBlock* mir,
+                                            Assembler::DoubleCondition cond) {
+  // Skip past trivial blocks.
+  Label* label = skipTrivialBlocks(mir)->lir()->label();
+  if (fmt == Assembler::DoubleFloat) {
+    masm.branchDouble(cond, lhs, rhs, label);
+  } else {
+    masm.branchFloat(cond, lhs, rhs, label);
+  }
+}
+
+void OutOfLineBailout::accept(CodeGeneratorMIPSShared* codegen) {
+  codegen->visitOutOfLineBailout(this);
+}
+
+void CodeGenerator::visitTestIAndBranch(LTestIAndBranch* test) {
+  const LAllocation* opd = test->getOperand(0);
+  MBasicBlock* ifTrue = test->ifTrue();
+  MBasicBlock* ifFalse = test->ifFalse();
+
+  emitBranch(ToRegister(opd), Imm32(0), Assembler::NonZero, ifTrue, ifFalse);
+}
+
+void CodeGenerator::visitCompare(LCompare* comp) {
+  MCompare* mir = comp->mir();
+  Assembler::Condition cond = JSOpToCondition(mir->compareType(), comp->jsop());
+  const LAllocation* left = comp->getOperand(0);
+  const LAllocation* right = comp->getOperand(1);
+  const LDefinition* def = comp->getDef(0);
+
+#ifdef JS_CODEGEN_MIPS64
+  if (mir->compareType() == MCompare::Compare_Object ||
+      mir->compareType() == MCompare::Compare_Symbol ||
+      mir->compareType() == MCompare::Compare_UIntPtr ||
+      mir->compareType() == MCompare::Compare_WasmAnyRef) {
+    if (right->isConstant()) {
+      MOZ_ASSERT(mir->compareType() == MCompare::Compare_UIntPtr);
+      masm.cmpPtrSet(cond, ToRegister(left), Imm32(ToInt32(right)),
+                     ToRegister(def));
+    } else if (right->isGeneralReg()) {
+      masm.cmpPtrSet(cond, ToRegister(left), ToRegister(right),
+                     ToRegister(def));
+    } else {
+      masm.cmpPtrSet(cond, ToRegister(left), ToAddress(right), ToRegister(def));
+    }
+    return;
+  }
+#endif
+
+  if (right->isConstant()) {
+    masm.cmp32Set(cond, ToRegister(left), Imm32(ToInt32(right)),
+                  ToRegister(def));
+  } else if (right->isGeneralReg()) {
+    masm.cmp32Set(cond, ToRegister(left), ToRegister(right), ToRegister(def));
+  } else {
+    masm.cmp32Set(cond, ToRegister(left), ToAddress(right), ToRegister(def));
+  }
+}
+
+void CodeGenerator::visitCompareAndBranch(LCompareAndBranch* comp) {
+  MCompare* mir = comp->cmpMir();
+  Assembler::Condition cond = JSOpToCondition(mir->compareType(), comp->jsop());
+
+#ifdef JS_CODEGEN_MIPS64
+  if (mir->compareType() == MCompare::Compare_Object ||
+      mir->compareType() == MCompare::Compare_Symbol ||
+      mir->compareType() == MCompare::Compare_UIntPtr ||
+      mir->compareType() == MCompare::Compare_WasmAnyRef) {
+    if (comp->right()->isConstant()) {
+      MOZ_ASSERT(mir->compareType() == MCompare::Compare_UIntPtr);
+      emitBranch(ToRegister(comp->left()), Imm32(ToInt32(comp->right())), cond,
+                 comp->ifTrue(), comp->ifFalse());
+    } else if (comp->right()->isGeneralReg()) {
+      emitBranch(ToRegister(comp->left()), ToRegister(comp->right()), cond,
+                 comp->ifTrue(), comp->ifFalse());
+    } else {
+      masm.loadPtr(ToAddress(comp->right()), ScratchRegister);
+      emitBranch(ToRegister(comp->left()), ScratchRegister, cond,
+                 comp->ifTrue(), comp->ifFalse());
+    }
+    return;
+  }
+#endif
+
+  if (comp->right()->isConstant()) {
+    emitBranch(ToRegister(comp->left()), Imm32(ToInt32(comp->right())), cond,
+               comp->ifTrue(), comp->ifFalse());
+  } else if (comp->right()->isGeneralReg()) {
+    emitBranch(ToRegister(comp->left()), ToRegister(comp->right()), cond,
+               comp->ifTrue(), comp->ifFalse());
+  } else {
+    masm.load32(ToAddress(comp->right()), ScratchRegister);
+    emitBranch(ToRegister(comp->left()), ScratchRegister, cond, comp->ifTrue(),
+               comp->ifFalse());
+  }
+}
+
+bool CodeGeneratorMIPSShared::generateOutOfLineCode() {
+  if (!CodeGeneratorShared::generateOutOfLineCode()) {
+    return false;
+  }
+
+  if (deoptLabel_.used()) {
+    // All non-table-based bailouts will go here.
+    masm.bind(&deoptLabel_);
+
+    // Push the frame size, so the handler can recover the IonScript.
+    // Frame size is stored in 'ra' and pushed by GenerateBailoutThunk
+    // We have to use 'ra' because generateBailoutTable will implicitly do
+    // the same.
+    masm.move32(Imm32(frameSize()), ra);
+
+    TrampolinePtr handler = gen->jitRuntime()->getGenericBailoutHandler();
+    masm.jump(handler);
+  }
+
+  return !masm.oom();
+}
+
+void CodeGeneratorMIPSShared::bailoutFrom(Label* label, LSnapshot* snapshot) {
+  MOZ_ASSERT_IF(!masm.oom(), label->used());
+  MOZ_ASSERT_IF(!masm.oom(), !label->bound());
+
+  encode(snapshot);
+
+  InlineScriptTree* tree = snapshot->mir()->block()->trackedTree();
+  OutOfLineBailout* ool =
+      new (alloc()) OutOfLineBailout(snapshot, masm.framePushed());
+  addOutOfLineCode(ool,
+                   new (alloc()) BytecodeSite(tree, tree->script()->code()));
+
+  masm.retarget(label, ool->entry());
+}
+
+void CodeGeneratorMIPSShared::bailout(LSnapshot* snapshot) {
+  Label label;
+  masm.jump(&label);
+  bailoutFrom(&label, snapshot);
+}
+
+void CodeGenerator::visitMinMaxD(LMinMaxD* ins) {
+  FloatRegister first = ToFloatRegister(ins->first());
+  FloatRegister second = ToFloatRegister(ins->second());
+
+  MOZ_ASSERT(first == ToFloatRegister(ins->output()));
+
+  if (ins->mir()->isMax()) {
+    masm.maxDouble(second, first, true);
+  } else {
+    masm.minDouble(second, first, true);
+  }
+}
+
+void CodeGenerator::visitMinMaxF(LMinMaxF* ins) {
+  FloatRegister first = ToFloatRegister(ins->first());
+  FloatRegister second = ToFloatRegister(ins->second());
+
+  MOZ_ASSERT(first == ToFloatRegister(ins->output()));
+
+  if (ins->mir()->isMax()) {
+    masm.maxFloat32(second, first, true);
+  } else {
+    masm.minFloat32(second, first, true);
+  }
+}
+
+void CodeGenerator::visitAddI(LAddI* ins) {
+  const LAllocation* lhs = ins->getOperand(0);
+  const LAllocation* rhs = ins->getOperand(1);
+  const LDefinition* dest = ins->getDef(0);
+
+  MOZ_ASSERT(rhs->isConstant() || rhs->isGeneralReg());
+
+  // If there is no snapshot, we don't need to check for overflow
+  if (!ins->snapshot()) {
+    if (rhs->isConstant()) {
+      masm.ma_addu(ToRegister(dest), ToRegister(lhs), Imm32(ToInt32(rhs)));
+    } else {
+      masm.as_addu(ToRegister(dest), ToRegister(lhs), ToRegister(rhs));
+    }
+    return;
+  }
+
+  Label overflow;
+  if (rhs->isConstant()) {
+    masm.ma_add32TestOverflow(ToRegister(dest), ToRegister(lhs),
+                              Imm32(ToInt32(rhs)), &overflow);
+  } else {
+    masm.ma_add32TestOverflow(ToRegister(dest), ToRegister(lhs),
+                              ToRegister(rhs), &overflow);
+  }
+
+  bailoutFrom(&overflow, ins->snapshot());
+}
+
+void CodeGenerator::visitAddI64(LAddI64* lir) {
+  const LInt64Allocation lhs = lir->getInt64Operand(LAddI64::Lhs);
+  const LInt64Allocation rhs = lir->getInt64Operand(LAddI64::Rhs);
+
+  MOZ_ASSERT(ToOutRegister64(lir) == ToRegister64(lhs));
+
+  if (IsConstant(rhs)) {
+    masm.add64(Imm64(ToInt64(rhs)), ToRegister64(lhs));
+    return;
+  }
+
+  masm.add64(ToOperandOrRegister64(rhs), ToRegister64(lhs));
+}
+
+void CodeGenerator::visitSubI(LSubI* ins) {
+  const LAllocation* lhs = ins->getOperand(0);
+  const LAllocation* rhs = ins->getOperand(1);
+  const LDefinition* dest = ins->getDef(0);
+
+  MOZ_ASSERT(rhs->isConstant() || rhs->isGeneralReg());
+
+  // If there is no snapshot, we don't need to check for overflow
+  if (!ins->snapshot()) {
+    if (rhs->isConstant()) {
+      masm.ma_subu(ToRegister(dest), ToRegister(lhs), Imm32(ToInt32(rhs)));
+    } else {
+      masm.as_subu(ToRegister(dest), ToRegister(lhs), ToRegister(rhs));
+    }
+    return;
+  }
+
+  Label overflow;
+  if (rhs->isConstant()) {
+    masm.ma_sub32TestOverflow(ToRegister(dest), ToRegister(lhs),
+                              Imm32(ToInt32(rhs)), &overflow);
+  } else {
+    masm.ma_sub32TestOverflow(ToRegister(dest), ToRegister(lhs),
+                              ToRegister(rhs), &overflow);
+  }
+
+  bailoutFrom(&overflow, ins->snapshot());
+}
+
+void CodeGenerator::visitSubI64(LSubI64* lir) {
+  const LInt64Allocation lhs = lir->getInt64Operand(LSubI64::Lhs);
+  const LInt64Allocation rhs = lir->getInt64Operand(LSubI64::Rhs);
+
+  MOZ_ASSERT(ToOutRegister64(lir) == ToRegister64(lhs));
+
+  if (IsConstant(rhs)) {
+    masm.sub64(Imm64(ToInt64(rhs)), ToRegister64(lhs));
+    return;
+  }
+
+  masm.sub64(ToOperandOrRegister64(rhs), ToRegister64(lhs));
+}
+
+void CodeGenerator::visitMulI(LMulI* ins) {
+  const LAllocation* lhs = ins->lhs();
+  const LAllocation* rhs = ins->rhs();
+  Register dest = ToRegister(ins->output());
+  MMul* mul = ins->mir();
+
+  MOZ_ASSERT_IF(mul->mode() == MMul::Integer,
+                !mul->canBeNegativeZero() && !mul->canOverflow());
+
+  if (rhs->isConstant()) {
+    int32_t constant = ToInt32(rhs);
+    Register src = ToRegister(lhs);
+
+    // Bailout on -0.0
+    if (mul->canBeNegativeZero() && constant <= 0) {
+      Assembler::Condition cond =
+          (constant == 0) ? Assembler::LessThan : Assembler::Equal;
+      bailoutCmp32(cond, src, Imm32(0), ins->snapshot());
+    }
+
+    switch (constant) {
+      case -1:
+        if (mul->canOverflow()) {
+          bailoutCmp32(Assembler::Equal, src, Imm32(INT32_MIN),
+                       ins->snapshot());
+        }
+
+        masm.ma_negu(dest, src);
+        break;
+      case 0:
+        masm.move32(Imm32(0), dest);
+        break;
+      case 1:
+        masm.move32(src, dest);
+        break;
+      case 2:
+        if (mul->canOverflow()) {
+          Label mulTwoOverflow;
+          masm.ma_add32TestOverflow(dest, src, src, &mulTwoOverflow);
+
+          bailoutFrom(&mulTwoOverflow, ins->snapshot());
+        } else {
+          masm.as_addu(dest, src, src);
+        }
+        break;
+      default:
+        uint32_t shift = FloorLog2(constant);
+
+        if (!mul->canOverflow() && (constant > 0)) {
+          // If it cannot overflow, we can do lots of optimizations.
+          uint32_t rest = constant - (1 << shift);
+
+          // See if the constant has one bit set, meaning it can be
+          // encoded as a bitshift.
+          if ((1 << shift) == constant) {
+            masm.ma_sll(dest, src, Imm32(shift));
+            return;
+          }
+
+          // If the constant cannot be encoded as (1<<C1), see if it can
+          // be encoded as (1<<C1) | (1<<C2), which can be computed
+          // using an add and a shift.
+          uint32_t shift_rest = FloorLog2(rest);
+          if (src != dest && (1u << shift_rest) == rest) {
+            masm.ma_sll(dest, src, Imm32(shift - shift_rest));
+            masm.add32(src, dest);
+            if (shift_rest != 0) {
+              masm.ma_sll(dest, dest, Imm32(shift_rest));
+            }
+            return;
+          }
+        }
+
+        if (mul->canOverflow() && (constant > 0) && (src != dest)) {
+          // To stay on the safe side, only optimize things that are a
+          // power of 2.
+
+          if ((1 << shift) == constant) {
+            // dest = lhs * pow(2, shift)
+            masm.ma_sll(dest, src, Imm32(shift));
+            // At runtime, check (lhs == dest >> shift), if this does
+            // not hold, some bits were lost due to overflow, and the
+            // computation should be resumed as a double.
+            masm.ma_sra(ScratchRegister, dest, Imm32(shift));
+            bailoutCmp32(Assembler::NotEqual, src, ScratchRegister,
+                         ins->snapshot());
+            return;
+          }
+        }
+
+        if (mul->canOverflow()) {
+          Label mulConstOverflow;
+          masm.ma_mul32TestOverflow(dest, ToRegister(lhs), Imm32(ToInt32(rhs)),
+                                    &mulConstOverflow);
+
+          bailoutFrom(&mulConstOverflow, ins->snapshot());
+        } else {
+          masm.ma_mul(dest, src, Imm32(ToInt32(rhs)));
+        }
+        break;
+    }
+  } else {
+    Label multRegOverflow;
+
+    if (mul->canOverflow()) {
+      masm.ma_mul32TestOverflow(dest, ToRegister(lhs), ToRegister(rhs),
+                                &multRegOverflow);
+      bailoutFrom(&multRegOverflow, ins->snapshot());
+    } else {
+      masm.as_mul(dest, ToRegister(lhs), ToRegister(rhs));
+    }
+
+    if (mul->canBeNegativeZero()) {
+      Label done;
+      masm.ma_b(dest, dest, &done, Assembler::NonZero, ShortJump);
+
+      // Result is -0 if lhs or rhs is negative.
+      // In that case result must be double value so bailout
+      Register scratch = SecondScratchReg;
+      masm.as_or(scratch, ToRegister(lhs), ToRegister(rhs));
+      bailoutCmp32(Assembler::Signed, scratch, scratch, ins->snapshot());
+
+      masm.bind(&done);
+    }
+  }
+}
+
+void CodeGenerator::visitMulI64(LMulI64* lir) {
+  const LInt64Allocation lhs = lir->getInt64Operand(LMulI64::Lhs);
+  const LInt64Allocation rhs = lir->getInt64Operand(LMulI64::Rhs);
+  const Register64 output = ToOutRegister64(lir);
+  MOZ_ASSERT(ToRegister64(lhs) == output);
+
+  if (IsConstant(rhs)) {
+    int64_t constant = ToInt64(rhs);
+    switch (constant) {
+      case -1:
+        masm.neg64(ToRegister64(lhs));
+        return;
+      case 0:
+        masm.xor64(ToRegister64(lhs), ToRegister64(lhs));
+        return;
+      case 1:
+        // nop
+        return;
+      case 2:
+        masm.add64(ToRegister64(lhs), ToRegister64(lhs));
+        return;
+      default:
+        if (constant > 0) {
+          if (mozilla::IsPowerOfTwo(static_cast<uint64_t>(constant + 1))) {
+            ScratchRegisterScope scratch(masm);
+            Register64 scratch64(scratch);
+            masm.move64(ToRegister64(lhs), scratch64);
+            masm.lshift64(Imm32(FloorLog2(constant + 1)), output);
+            masm.sub64(scratch64, output);
+            return;
+          } else if (mozilla::IsPowerOfTwo(
+                         static_cast<uint64_t>(constant - 1))) {
+            ScratchRegisterScope scratch(masm);
+            Register64 scratch64(scratch);
+            masm.move64(ToRegister64(lhs), scratch64);
+            masm.lshift64(Imm32(FloorLog2(constant - 1u)), output);
+            masm.add64(scratch64, output);
+            return;
+          }
+          // Use shift if constant is power of 2.
+          int32_t shift = mozilla::FloorLog2(constant);
+          if (int64_t(1) << shift == constant) {
+            masm.lshift64(Imm32(shift), ToRegister64(lhs));
+            return;
+          }
+        }
+        Register temp = ToTempRegisterOrInvalid(lir->temp());
+        masm.mul64(Imm64(constant), ToRegister64(lhs), temp);
+    }
+  } else {
+    Register temp = ToTempRegisterOrInvalid(lir->temp());
+    masm.mul64(ToOperandOrRegister64(rhs), ToRegister64(lhs), temp);
+  }
+}
+
+void CodeGenerator::visitDivI(LDivI* ins) {
+  // Extract the registers from this instruction
+  Register lhs = ToRegister(ins->lhs());
+  Register rhs = ToRegister(ins->rhs());
+  Register dest = ToRegister(ins->output());
+  Register temp = ToRegister(ins->getTemp(0));
+  MDiv* mir = ins->mir();
+
+  Label done;
+
+  // Handle divide by zero.
+  if (mir->canBeDivideByZero()) {
+    if (mir->trapOnError()) {
+      Label nonZero;
+      masm.ma_b(rhs, rhs, &nonZero, Assembler::NonZero);
+      masm.wasmTrap(wasm::Trap::IntegerDivideByZero, mir->bytecodeOffset());
+      masm.bind(&nonZero);
+    } else if (mir->canTruncateInfinities()) {
+      // Truncated division by zero is zero (Infinity|0 == 0)
+      Label notzero;
+      masm.ma_b(rhs, rhs, &notzero, Assembler::NonZero, ShortJump);
+      masm.move32(Imm32(0), dest);
+      masm.ma_b(&done, ShortJump);
+      masm.bind(&notzero);
+    } else {
+      MOZ_ASSERT(mir->fallible());
+      bailoutCmp32(Assembler::Zero, rhs, rhs, ins->snapshot());
+    }
+  }
+
+  // Handle an integer overflow exception from -2147483648 / -1.
+  if (mir->canBeNegativeOverflow()) {
+    Label notMinInt;
+    masm.move32(Imm32(INT32_MIN), temp);
+    masm.ma_b(lhs, temp, &notMinInt, Assembler::NotEqual, ShortJump);
+
+    masm.move32(Imm32(-1), temp);
+    if (mir->trapOnError()) {
+      Label ok;
+      masm.ma_b(rhs, temp, &ok, Assembler::NotEqual);
+      masm.wasmTrap(wasm::Trap::IntegerOverflow, mir->bytecodeOffset());
+      masm.bind(&ok);
+    } else if (mir->canTruncateOverflow()) {
+      // (-INT32_MIN)|0 == INT32_MIN
+      Label skip;
+      masm.ma_b(rhs, temp, &skip, Assembler::NotEqual, ShortJump);
+      masm.move32(Imm32(INT32_MIN), dest);
+      masm.ma_b(&done, ShortJump);
+      masm.bind(&skip);
+    } else {
+      MOZ_ASSERT(mir->fallible());
+      bailoutCmp32(Assembler::Equal, rhs, temp, ins->snapshot());
+    }
+    masm.bind(&notMinInt);
+  }
+
+  // Handle negative 0. (0/-Y)
+  if (!mir->canTruncateNegativeZero() && mir->canBeNegativeZero()) {
+    Label nonzero;
+    masm.ma_b(lhs, lhs, &nonzero, Assembler::NonZero, ShortJump);
+    bailoutCmp32(Assembler::LessThan, rhs, Imm32(0), ins->snapshot());
+    masm.bind(&nonzero);
+  }
+  // Note: above safety checks could not be verified as Ion seems to be
+  // smarter and requires double arithmetic in such cases.
+
+  // All regular. Lets call div.
+  if (mir->canTruncateRemainder()) {
+#ifdef MIPSR6
+    masm.as_div(dest, lhs, rhs);
+#else
+    masm.as_div(lhs, rhs);
+    masm.as_mflo(dest);
+#endif
+  } else {
+    MOZ_ASSERT(mir->fallible());
+
+    Label remainderNonZero;
+    masm.ma_div_branch_overflow(dest, lhs, rhs, &remainderNonZero);
+    bailoutFrom(&remainderNonZero, ins->snapshot());
+  }
+
+  masm.bind(&done);
+}
+
+void CodeGenerator::visitDivPowTwoI(LDivPowTwoI* ins) {
+  Register lhs = ToRegister(ins->numerator());
+  Register dest = ToRegister(ins->output());
+  Register tmp = ToRegister(ins->getTemp(0));
+  int32_t shift = ins->shift();
+
+  if (shift != 0) {
+    MDiv* mir = ins->mir();
+    if (!mir->isTruncated()) {
+      // If the remainder is going to be != 0, bailout since this must
+      // be a double.
+      masm.ma_sll(tmp, lhs, Imm32(32 - shift));
+      bailoutCmp32(Assembler::NonZero, tmp, tmp, ins->snapshot());
+    }
+
+    if (!mir->canBeNegativeDividend()) {
+      // Numerator is unsigned, so needs no adjusting. Do the shift.
+      masm.ma_sra(dest, lhs, Imm32(shift));
+      return;
+    }
+
+    // Adjust the value so that shifting produces a correctly rounded result
+    // when the numerator is negative. See 10-1 "Signed Division by a Known
+    // Power of 2" in Henry S. Warren, Jr.'s Hacker's Delight.
+    if (shift > 1) {
+      masm.ma_sra(tmp, lhs, Imm32(31));
+      masm.ma_srl(tmp, tmp, Imm32(32 - shift));
+      masm.add32(lhs, tmp);
+    } else {
+      masm.ma_srl(tmp, lhs, Imm32(32 - shift));
+      masm.add32(lhs, tmp);
+    }
+
+    // Do the shift.
+    masm.ma_sra(dest, tmp, Imm32(shift));
+  } else {
+    masm.move32(lhs, dest);
+  }
+}
+
+void CodeGenerator::visitModI(LModI* ins) {
+  // Extract the registers from this instruction
+  Register lhs = ToRegister(ins->lhs());
+  Register rhs = ToRegister(ins->rhs());
+  Register dest = ToRegister(ins->output());
+  Register callTemp = ToRegister(ins->callTemp());
+  MMod* mir = ins->mir();
+  Label done, prevent;
+
+  masm.move32(lhs, callTemp);
+
+  // Prevent INT_MIN % -1;
+  // The integer division will give INT_MIN, but we want -(double)INT_MIN.
+  if (mir->canBeNegativeDividend()) {
+    masm.ma_b(lhs, Imm32(INT_MIN), &prevent, Assembler::NotEqual, ShortJump);
+    if (mir->isTruncated()) {
+      // (INT_MIN % -1)|0 == 0
+      Label skip;
+      masm.ma_b(rhs, Imm32(-1), &skip, Assembler::NotEqual, ShortJump);
+      masm.move32(Imm32(0), dest);
+      masm.ma_b(&done, ShortJump);
+      masm.bind(&skip);
+    } else {
+      MOZ_ASSERT(mir->fallible());
+      bailoutCmp32(Assembler::Equal, rhs, Imm32(-1), ins->snapshot());
+    }
+    masm.bind(&prevent);
+  }
+
+  // 0/X (with X < 0) is bad because both of these values *should* be
+  // doubles, and the result should be -0.0, which cannot be represented in
+  // integers. X/0 is bad because it will give garbage (or abort), when it
+  // should give either \infty, -\infty or NAN.
+
+  // Prevent 0 / X (with X < 0) and X / 0
+  // testing X / Y.  Compare Y with 0.
+  // There are three cases: (Y < 0), (Y == 0) and (Y > 0)
+  // If (Y < 0), then we compare X with 0, and bail if X == 0
+  // If (Y == 0), then we simply want to bail.
+  // if (Y > 0), we don't bail.
+
+  if (mir->canBeDivideByZero()) {
+    if (mir->isTruncated()) {
+      if (mir->trapOnError()) {
+        Label nonZero;
+        masm.ma_b(rhs, rhs, &nonZero, Assembler::NonZero);
+        masm.wasmTrap(wasm::Trap::IntegerDivideByZero, mir->bytecodeOffset());
+        masm.bind(&nonZero);
+      } else {
+        Label skip;
+        masm.ma_b(rhs, Imm32(0), &skip, Assembler::NotEqual, ShortJump);
+        masm.move32(Imm32(0), dest);
+        masm.ma_b(&done, ShortJump);
+        masm.bind(&skip);
+      }
+    } else {
+      MOZ_ASSERT(mir->fallible());
+      bailoutCmp32(Assembler::Equal, rhs, Imm32(0), ins->snapshot());
+    }
+  }
+
+  if (mir->canBeNegativeDividend()) {
+    Label notNegative;
+    masm.ma_b(rhs, Imm32(0), &notNegative, Assembler::GreaterThan, ShortJump);
+    if (mir->isTruncated()) {
+      // NaN|0 == 0 and (0 % -X)|0 == 0
+      Label skip;
+      masm.ma_b(lhs, Imm32(0), &skip, Assembler::NotEqual, ShortJump);
+      masm.move32(Imm32(0), dest);
+      masm.ma_b(&done, ShortJump);
+      masm.bind(&skip);
+    } else {
+      MOZ_ASSERT(mir->fallible());
+      bailoutCmp32(Assembler::Equal, lhs, Imm32(0), ins->snapshot());
+    }
+    masm.bind(&notNegative);
+  }
+#ifdef MIPSR6
+  masm.as_mod(dest, lhs, rhs);
+#else
+  masm.as_div(lhs, rhs);
+  masm.as_mfhi(dest);
+#endif
+
+  // If X%Y == 0 and X < 0, then we *actually* wanted to return -0.0
+  if (mir->canBeNegativeDividend()) {
+    if (mir->isTruncated()) {
+      // -0.0|0 == 0
+    } else {
+      MOZ_ASSERT(mir->fallible());
+      // See if X < 0
+      masm.ma_b(dest, Imm32(0), &done, Assembler::NotEqual, ShortJump);
+      bailoutCmp32(Assembler::Signed, callTemp, Imm32(0), ins->snapshot());
+    }
+  }
+  masm.bind(&done);
+}
+
+void CodeGenerator::visitModPowTwoI(LModPowTwoI* ins) {
+  Register in = ToRegister(ins->getOperand(0));
+  Register out = ToRegister(ins->getDef(0));
+  MMod* mir = ins->mir();
+  Label negative, done;
+
+  masm.move32(in, out);
+  masm.ma_b(in, in, &done, Assembler::Zero, ShortJump);
+  // Switch based on sign of the lhs.
+  // Positive numbers are just a bitmask
+  masm.ma_b(in, in, &negative, Assembler::Signed, ShortJump);
+  {
+    masm.and32(Imm32((1 << ins->shift()) - 1), out);
+    masm.ma_b(&done, ShortJump);
+  }
+
+  // Negative numbers need a negate, bitmask, negate
+  {
+    masm.bind(&negative);
+    masm.neg32(out);
+    masm.and32(Imm32((1 << ins->shift()) - 1), out);
+    masm.neg32(out);
+  }
+  if (mir->canBeNegativeDividend()) {
+    if (!mir->isTruncated()) {
+      MOZ_ASSERT(mir->fallible());
+      bailoutCmp32(Assembler::Equal, out, zero, ins->snapshot());
+    } else {
+      // -0|0 == 0
+    }
+  }
+  masm.bind(&done);
+}
+
+void CodeGenerator::visitModMaskI(LModMaskI* ins) {
+  Register src = ToRegister(ins->getOperand(0));
+  Register dest = ToRegister(ins->getDef(0));
+  Register tmp0 = ToRegister(ins->getTemp(0));
+  Register tmp1 = ToRegister(ins->getTemp(1));
+  MMod* mir = ins->mir();
+
+  if (!mir->isTruncated() && mir->canBeNegativeDividend()) {
+    MOZ_ASSERT(mir->fallible());
+
+    Label bail;
+    masm.ma_mod_mask(src, dest, tmp0, tmp1, ins->shift(), &bail);
+    bailoutFrom(&bail, ins->snapshot());
+  } else {
+    masm.ma_mod_mask(src, dest, tmp0, tmp1, ins->shift(), nullptr);
+  }
+}
+
+void CodeGenerator::visitBitNotI(LBitNotI* ins) {
+  const LAllocation* input = ins->getOperand(0);
+  const LDefinition* dest = ins->getDef(0);
+  MOZ_ASSERT(!input->isConstant());
+
+  masm.ma_not(ToRegister(dest), ToRegister(input));
+}
+
+void CodeGenerator::visitBitOpI(LBitOpI* ins) {
+  const LAllocation* lhs = ins->getOperand(0);
+  const LAllocation* rhs = ins->getOperand(1);
+  const LDefinition* dest = ins->getDef(0);
+  // all of these bitops should be either imm32's, or integer registers.
+  switch (ins->bitop()) {
+    case JSOp::BitOr:
+      if (rhs->isConstant()) {
+        masm.ma_or(ToRegister(dest), ToRegister(lhs), Imm32(ToInt32(rhs)));
+      } else {
+        masm.as_or(ToRegister(dest), ToRegister(lhs), ToRegister(rhs));
+      }
+      break;
+    case JSOp::BitXor:
+      if (rhs->isConstant()) {
+        masm.ma_xor(ToRegister(dest), ToRegister(lhs), Imm32(ToInt32(rhs)));
+      } else {
+        masm.as_xor(ToRegister(dest), ToRegister(lhs), ToRegister(rhs));
+      }
+      break;
+    case JSOp::BitAnd:
+      if (rhs->isConstant()) {
+        masm.ma_and(ToRegister(dest), ToRegister(lhs), Imm32(ToInt32(rhs)));
+      } else {
+        masm.as_and(ToRegister(dest), ToRegister(lhs), ToRegister(rhs));
+      }
+      break;
+    default:
+      MOZ_CRASH("unexpected binary opcode");
+  }
+}
+
+void CodeGenerator::visitBitOpI64(LBitOpI64* lir) {
+  const LInt64Allocation lhs = lir->getInt64Operand(LBitOpI64::Lhs);
+  const LInt64Allocation rhs = lir->getInt64Operand(LBitOpI64::Rhs);
+
+  MOZ_ASSERT(ToOutRegister64(lir) == ToRegister64(lhs));
+
+  switch (lir->bitop()) {
+    case JSOp::BitOr:
+      if (IsConstant(rhs)) {
+        masm.or64(Imm64(ToInt64(rhs)), ToRegister64(lhs));
+      } else {
+        masm.or64(ToOperandOrRegister64(rhs), ToRegister64(lhs));
+      }
+      break;
+    case JSOp::BitXor:
+      if (IsConstant(rhs)) {
+        masm.xor64(Imm64(ToInt64(rhs)), ToRegister64(lhs));
+      } else {
+        masm.xor64(ToOperandOrRegister64(rhs), ToRegister64(lhs));
+      }
+      break;
+    case JSOp::BitAnd:
+      if (IsConstant(rhs)) {
+        masm.and64(Imm64(ToInt64(rhs)), ToRegister64(lhs));
+      } else {
+        masm.and64(ToOperandOrRegister64(rhs), ToRegister64(lhs));
+      }
+      break;
+    default:
+      MOZ_CRASH("unexpected binary opcode");
+  }
+}
+
+void CodeGenerator::visitShiftI(LShiftI* ins) {
+  Register lhs = ToRegister(ins->lhs());
+  const LAllocation* rhs = ins->rhs();
+  Register dest = ToRegister(ins->output());
+
+  if (rhs->isConstant()) {
+    int32_t shift = ToInt32(rhs) & 0x1F;
+    switch (ins->bitop()) {
+      case JSOp::Lsh:
+        if (shift) {
+          masm.ma_sll(dest, lhs, Imm32(shift));
+        } else {
+          masm.move32(lhs, dest);
+        }
+        break;
+      case JSOp::Rsh:
+        if (shift) {
+          masm.ma_sra(dest, lhs, Imm32(shift));
+        } else {
+          masm.move32(lhs, dest);
+        }
+        break;
+      case JSOp::Ursh:
+        if (shift) {
+          masm.ma_srl(dest, lhs, Imm32(shift));
+        } else {
+          // x >>> 0 can overflow.
+          if (ins->mir()->toUrsh()->fallible()) {
+            bailoutCmp32(Assembler::LessThan, lhs, Imm32(0), ins->snapshot());
+          }
+          masm.move32(lhs, dest);
+        }
+        break;
+      default:
+        MOZ_CRASH("Unexpected shift op");
+    }
+  } else {
+    // The shift amounts should be AND'ed into the 0-31 range
+    masm.ma_and(dest, ToRegister(rhs), Imm32(0x1F));
+
+    switch (ins->bitop()) {
+      case JSOp::Lsh:
+        masm.ma_sll(dest, lhs, dest);
+        break;
+      case JSOp::Rsh:
+        masm.ma_sra(dest, lhs, dest);
+        break;
+      case JSOp::Ursh:
+        masm.ma_srl(dest, lhs, dest);
+        if (ins->mir()->toUrsh()->fallible()) {
+          // x >>> 0 can overflow.
+          bailoutCmp32(Assembler::LessThan, dest, Imm32(0), ins->snapshot());
+        }
+        break;
+      default:
+        MOZ_CRASH("Unexpected shift op");
+    }
+  }
+}
+
+void CodeGenerator::visitShiftI64(LShiftI64* lir) {
+  const LInt64Allocation lhs = lir->getInt64Operand(LShiftI64::Lhs);
+  LAllocation* rhs = lir->getOperand(LShiftI64::Rhs);
+
+  MOZ_ASSERT(ToOutRegister64(lir) == ToRegister64(lhs));
+
+  if (rhs->isConstant()) {
+    int32_t shift = int32_t(rhs->toConstant()->toInt64() & 0x3F);
+    switch (lir->bitop()) {
+      case JSOp::Lsh:
+        if (shift) {
+          masm.lshift64(Imm32(shift), ToRegister64(lhs));
+        }
+        break;
+      case JSOp::Rsh:
+        if (shift) {
+          masm.rshift64Arithmetic(Imm32(shift), ToRegister64(lhs));
+        }
+        break;
+      case JSOp::Ursh:
+        if (shift) {
+          masm.rshift64(Imm32(shift), ToRegister64(lhs));
+        }
+        break;
+      default:
+        MOZ_CRASH("Unexpected shift op");
+    }
+    return;
+  }
+
+  switch (lir->bitop()) {
+    case JSOp::Lsh:
+      masm.lshift64(ToRegister(rhs), ToRegister64(lhs));
+      break;
+    case JSOp::Rsh:
+      masm.rshift64Arithmetic(ToRegister(rhs), ToRegister64(lhs));
+      break;
+    case JSOp::Ursh:
+      masm.rshift64(ToRegister(rhs), ToRegister64(lhs));
+      break;
+    default:
+      MOZ_CRASH("Unexpected shift op");
+  }
+}
+
+void CodeGenerator::visitRotateI64(LRotateI64* lir) {
+  MRotate* mir = lir->mir();
+  LAllocation* count = lir->count();
+
+  Register64 input = ToRegister64(lir->input());
+  Register64 output = ToOutRegister64(lir);
+  Register temp = ToTempRegisterOrInvalid(lir->temp());
+
+#ifdef JS_CODEGEN_MIPS64
+  MOZ_ASSERT(input == output);
+#endif
+
+  if (count->isConstant()) {
+    int32_t c = int32_t(count->toConstant()->toInt64() & 0x3F);
+    if (!c) {
+#ifdef JS_CODEGEN_MIPS32
+      masm.move64(input, output);
+#endif
+      return;
+    }
+    if (mir->isLeftRotate()) {
+      masm.rotateLeft64(Imm32(c), input, output, temp);
+    } else {
+      masm.rotateRight64(Imm32(c), input, output, temp);
+    }
+  } else {
+    if (mir->isLeftRotate()) {
+      masm.rotateLeft64(ToRegister(count), input, output, temp);
+    } else {
+      masm.rotateRight64(ToRegister(count), input, output, temp);
+    }
+  }
+}
+
+void CodeGenerator::visitUrshD(LUrshD* ins) {
+  Register lhs = ToRegister(ins->lhs());
+  Register temp = ToRegister(ins->temp());
+
+  const LAllocation* rhs = ins->rhs();
+  FloatRegister out = ToFloatRegister(ins->output());
+
+  if (rhs->isConstant()) {
+    masm.ma_srl(temp, lhs, Imm32(ToInt32(rhs)));
+  } else {
+    masm.ma_srl(temp, lhs, ToRegister(rhs));
+  }
+
+  masm.convertUInt32ToDouble(temp, out);
+}
+
+void CodeGenerator::visitClzI(LClzI* ins) {
+  Register input = ToRegister(ins->input());
+  Register output = ToRegister(ins->output());
+
+  masm.as_clz(output, input);
+}
+
+void CodeGenerator::visitCtzI(LCtzI* ins) {
+  Register input = ToRegister(ins->input());
+  Register output = ToRegister(ins->output());
+
+  masm.ma_ctz(output, input);
+}
+
+void CodeGenerator::visitPopcntI(LPopcntI* ins) {
+  Register input = ToRegister(ins->input());
+  Register output = ToRegister(ins->output());
+  Register tmp = ToRegister(ins->temp0());
+
+  masm.popcnt32(input, output, tmp);
+}
+
+void CodeGenerator::visitPopcntI64(LPopcntI64* ins) {
+  Register64 input = ToRegister64(ins->getInt64Operand(0));
+  Register64 output = ToOutRegister64(ins);
+  Register tmp = ToRegister(ins->getTemp(0));
+
+  masm.popcnt64(input, output, tmp);
+}
+
+void CodeGenerator::visitPowHalfD(LPowHalfD* ins) {
+  FloatRegister input = ToFloatRegister(ins->input());
+  FloatRegister output = ToFloatRegister(ins->output());
+
+  Label done, skip;
+
+  // Masm.pow(-Infinity, 0.5) == Infinity.
+  masm.loadConstantDouble(NegativeInfinity<double>(), ScratchDoubleReg);
+  masm.ma_bc1d(input, ScratchDoubleReg, &skip,
+               Assembler::DoubleNotEqualOrUnordered, ShortJump);
+  masm.as_negd(output, ScratchDoubleReg);
+  masm.ma_b(&done, ShortJump);
+
+  masm.bind(&skip);
+  // Math.pow(-0, 0.5) == 0 == Math.pow(0, 0.5).
+  // Adding 0 converts any -0 to 0.
+  masm.loadConstantDouble(0.0, ScratchDoubleReg);
+  masm.as_addd(output, input, ScratchDoubleReg);
+  masm.as_sqrtd(output, output);
+
+  masm.bind(&done);
+}
+
+MoveOperand CodeGeneratorMIPSShared::toMoveOperand(LAllocation a) const {
+  if (a.isGeneralReg()) {
+    return MoveOperand(ToRegister(a));
+  }
+  if (a.isFloatReg()) {
+    return MoveOperand(ToFloatRegister(a));
+  }
+  MoveOperand::Kind kind = a.isStackArea() ? MoveOperand::Kind::EffectiveAddress
+                                           : MoveOperand::Kind::Memory;
+  Address address = ToAddress(a);
+  MOZ_ASSERT((address.offset & 3) == 0);
+  return MoveOperand(address, kind);
+}
+
+void CodeGenerator::visitMathD(LMathD* math) {
+  FloatRegister src1 = ToFloatRegister(math->getOperand(0));
+  FloatRegister src2 = ToFloatRegister(math->getOperand(1));
+  FloatRegister output = ToFloatRegister(math->getDef(0));
+
+  switch (math->jsop()) {
+    case JSOp::Add:
+      masm.as_addd(output, src1, src2);
+      break;
+    case JSOp::Sub:
+      masm.as_subd(output, src1, src2);
+      break;
+    case JSOp::Mul:
+      masm.as_muld(output, src1, src2);
+      break;
+    case JSOp::Div:
+      masm.as_divd(output, src1, src2);
+      break;
+    default:
+      MOZ_CRASH("unexpected opcode");
+  }
+}
+
+void CodeGenerator::visitMathF(LMathF* math) {
+  FloatRegister src1 = ToFloatRegister(math->getOperand(0));
+  FloatRegister src2 = ToFloatRegister(math->getOperand(1));
+  FloatRegister output = ToFloatRegister(math->getDef(0));
+
+  switch (math->jsop()) {
+    case JSOp::Add:
+      masm.as_adds(output, src1, src2);
+      break;
+    case JSOp::Sub:
+      masm.as_subs(output, src1, src2);
+      break;
+    case JSOp::Mul:
+      masm.as_muls(output, src1, src2);
+      break;
+    case JSOp::Div:
+      masm.as_divs(output, src1, src2);
+      break;
+    default:
+      MOZ_CRASH("unexpected opcode");
+  }
+}
+
+void CodeGenerator::visitTruncateDToInt32(LTruncateDToInt32* ins) {
+  emitTruncateDouble(ToFloatRegister(ins->input()), ToRegister(ins->output()),
+                     ins->mir());
+}
+
+void CodeGenerator::visitTruncateFToInt32(LTruncateFToInt32* ins) {
+  emitTruncateFloat32(ToFloatRegister(ins->input()), ToRegister(ins->output()),
+                      ins->mir());
+}
+
+void CodeGenerator::visitWasmBuiltinTruncateDToInt32(
+    LWasmBuiltinTruncateDToInt32* lir) {
+  emitTruncateDouble(ToFloatRegister(lir->getOperand(0)),
+                     ToRegister(lir->getDef(0)), lir->mir());
+}
+
+void CodeGenerator::visitWasmBuiltinTruncateFToInt32(
+    LWasmBuiltinTruncateFToInt32* lir) {
+  emitTruncateFloat32(ToFloatRegister(lir->getOperand(0)),
+                      ToRegister(lir->getDef(0)), lir->mir());
+}
+
+void CodeGenerator::visitWasmTruncateToInt32(LWasmTruncateToInt32* lir) {
+  auto input = ToFloatRegister(lir->input());
+  auto output = ToRegister(lir->output());
+
+  MWasmTruncateToInt32* mir = lir->mir();
+  MIRType fromType = mir->input()->type();
+
+  MOZ_ASSERT(fromType == MIRType::Double || fromType == MIRType::Float32);
+
+  auto* ool = new (alloc()) OutOfLineWasmTruncateCheck(mir, input, output);
+  addOutOfLineCode(ool, mir);
+
+  Label* oolEntry = ool->entry();
+  if (mir->isUnsigned()) {
+    if (fromType == MIRType::Double) {
+      masm.wasmTruncateDoubleToUInt32(input, output, mir->isSaturating(),
+                                      oolEntry);
+    } else if (fromType == MIRType::Float32) {
+      masm.wasmTruncateFloat32ToUInt32(input, output, mir->isSaturating(),
+                                       oolEntry);
+    } else {
+      MOZ_CRASH("unexpected type");
+    }
+
+    masm.bind(ool->rejoin());
+    return;
+  }
+
+  if (fromType == MIRType::Double) {
+    masm.wasmTruncateDoubleToInt32(input, output, mir->isSaturating(),
+                                   oolEntry);
+  } else if (fromType == MIRType::Float32) {
+    masm.wasmTruncateFloat32ToInt32(input, output, mir->isSaturating(),
+                                    oolEntry);
+  } else {
+    MOZ_CRASH("unexpected type");
+  }
+
+  masm.bind(ool->rejoin());
+}
+
+void CodeGeneratorMIPSShared::visitOutOfLineBailout(OutOfLineBailout* ool) {
+  // Push snapshotOffset and make sure stack is aligned.
+  masm.subPtr(Imm32(sizeof(Value)), StackPointer);
+  masm.storePtr(ImmWord(ool->snapshot()->snapshotOffset()),
+                Address(StackPointer, 0));
+
+  masm.jump(&deoptLabel_);
+}
+
+void CodeGeneratorMIPSShared::visitOutOfLineWasmTruncateCheck(
+    OutOfLineWasmTruncateCheck* ool) {
+  if (ool->toType() == MIRType::Int32) {
+    masm.outOfLineWasmTruncateToInt32Check(
+        ool->input(), ool->output(), ool->fromType(), ool->flags(),
+        ool->rejoin(), ool->bytecodeOffset());
+  } else {
+    MOZ_ASSERT(ool->toType() == MIRType::Int64);
+    masm.outOfLineWasmTruncateToInt64Check(
+        ool->input(), ool->output64(), ool->fromType(), ool->flags(),
+        ool->rejoin(), ool->bytecodeOffset());
+  }
+}
+
+void CodeGenerator::visitCopySignF(LCopySignF* ins) {
+  FloatRegister lhs = ToFloatRegister(ins->getOperand(0));
+  FloatRegister rhs = ToFloatRegister(ins->getOperand(1));
+  FloatRegister output = ToFloatRegister(ins->getDef(0));
+
+  Register lhsi = ToRegister(ins->getTemp(0));
+  Register rhsi = ToRegister(ins->getTemp(1));
+
+  masm.moveFromFloat32(lhs, lhsi);
+  masm.moveFromFloat32(rhs, rhsi);
+
+  // Combine.
+  masm.ma_ins(rhsi, lhsi, 0, 31);
+
+  masm.moveToFloat32(rhsi, output);
+}
+
+void CodeGenerator::visitCopySignD(LCopySignD* ins) {
+  FloatRegister lhs = ToFloatRegister(ins->getOperand(0));
+  FloatRegister rhs = ToFloatRegister(ins->getOperand(1));
+  FloatRegister output = ToFloatRegister(ins->getDef(0));
+
+  Register lhsi = ToRegister(ins->getTemp(0));
+  Register rhsi = ToRegister(ins->getTemp(1));
+
+  // Manipulate high words of double inputs.
+  masm.moveFromDoubleHi(lhs, lhsi);
+  masm.moveFromDoubleHi(rhs, rhsi);
+
+  // Combine.
+  masm.ma_ins(rhsi, lhsi, 0, 31);
+
+  masm.moveToDoubleHi(rhsi, output);
+}
+
+void CodeGenerator::visitValue(LValue* value) {
+  const ValueOperand out = ToOutValue(value);
+
+  masm.moveValue(value->value(), out);
+}
+
+void CodeGenerator::visitDouble(LDouble* ins) {
+  const LDefinition* out = ins->getDef(0);
+
+  masm.loadConstantDouble(ins->value(), ToFloatRegister(out));
+}
+
+void CodeGenerator::visitFloat32(LFloat32* ins) {
+  const LDefinition* out = ins->getDef(0);
+  masm.loadConstantFloat32(ins->value(), ToFloatRegister(out));
+}
+
+void CodeGenerator::visitTestDAndBranch(LTestDAndBranch* test) {
+  FloatRegister input = ToFloatRegister(test->input());
+
+  MBasicBlock* ifTrue = test->ifTrue();
+  MBasicBlock* ifFalse = test->ifFalse();
+
+  masm.loadConstantDouble(0.0, ScratchDoubleReg);
+  // If 0, or NaN, the result is false.
+
+  if (isNextBlock(ifFalse->lir())) {
+    branchToBlock(Assembler::DoubleFloat, input, ScratchDoubleReg, ifTrue,
+                  Assembler::DoubleNotEqual);
+  } else {
+    branchToBlock(Assembler::DoubleFloat, input, ScratchDoubleReg, ifFalse,
+                  Assembler::DoubleEqualOrUnordered);
+    jumpToBlock(ifTrue);
+  }
+}
+
+void CodeGenerator::visitTestFAndBranch(LTestFAndBranch* test) {
+  FloatRegister input = ToFloatRegister(test->input());
+
+  MBasicBlock* ifTrue = test->ifTrue();
+  MBasicBlock* ifFalse = test->ifFalse();
+
+  masm.loadConstantFloat32(0.0f, ScratchFloat32Reg);
+  // If 0, or NaN, the result is false.
+
+  if (isNextBlock(ifFalse->lir())) {
+    branchToBlock(Assembler::SingleFloat, input, ScratchFloat32Reg, ifTrue,
+                  Assembler::DoubleNotEqual);
+  } else {
+    branchToBlock(Assembler::SingleFloat, input, ScratchFloat32Reg, ifFalse,
+                  Assembler::DoubleEqualOrUnordered);
+    jumpToBlock(ifTrue);
+  }
+}
+
+void CodeGenerator::visitCompareD(LCompareD* comp) {
+  FloatRegister lhs = ToFloatRegister(comp->left());
+  FloatRegister rhs = ToFloatRegister(comp->right());
+  Register dest = ToRegister(comp->output());
+
+  Assembler::DoubleCondition cond = JSOpToDoubleCondition(comp->mir()->jsop());
+  masm.ma_cmp_set_double(dest, lhs, rhs, cond);
+}
+
+void CodeGenerator::visitCompareF(LCompareF* comp) {
+  FloatRegister lhs = ToFloatRegister(comp->left());
+  FloatRegister rhs = ToFloatRegister(comp->right());
+  Register dest = ToRegister(comp->output());
+
+  Assembler::DoubleCondition cond = JSOpToDoubleCondition(comp->mir()->jsop());
+  masm.ma_cmp_set_float32(dest, lhs, rhs, cond);
+}
+
+void CodeGenerator::visitCompareDAndBranch(LCompareDAndBranch* comp) {
+  FloatRegister lhs = ToFloatRegister(comp->left());
+  FloatRegister rhs = ToFloatRegister(comp->right());
+
+  Assembler::DoubleCondition cond =
+      JSOpToDoubleCondition(comp->cmpMir()->jsop());
+  MBasicBlock* ifTrue = comp->ifTrue();
+  MBasicBlock* ifFalse = comp->ifFalse();
+
+  if (isNextBlock(ifFalse->lir())) {
+    branchToBlock(Assembler::DoubleFloat, lhs, rhs, ifTrue, cond);
+  } else {
+    branchToBlock(Assembler::DoubleFloat, lhs, rhs, ifFalse,
+                  Assembler::InvertCondition(cond));
+    jumpToBlock(ifTrue);
+  }
+}
+
+void CodeGenerator::visitCompareFAndBranch(LCompareFAndBranch* comp) {
+  FloatRegister lhs = ToFloatRegister(comp->left());
+  FloatRegister rhs = ToFloatRegister(comp->right());
+
+  Assembler::DoubleCondition cond =
+      JSOpToDoubleCondition(comp->cmpMir()->jsop());
+  MBasicBlock* ifTrue = comp->ifTrue();
+  MBasicBlock* ifFalse = comp->ifFalse();
+
+  if (isNextBlock(ifFalse->lir())) {
+    branchToBlock(Assembler::SingleFloat, lhs, rhs, ifTrue, cond);
+  } else {
+    branchToBlock(Assembler::SingleFloat, lhs, rhs, ifFalse,
+                  Assembler::InvertCondition(cond));
+    jumpToBlock(ifTrue);
+  }
+}
+
+void CodeGenerator::visitBitAndAndBranch(LBitAndAndBranch* lir) {
+  if (lir->right()->isConstant()) {
+    masm.ma_and(ScratchRegister, ToRegister(lir->left()),
+                Imm32(ToInt32(lir->right())));
+  } else {
+    masm.as_and(ScratchRegister, ToRegister(lir->left()),
+                ToRegister(lir->right()));
+  }
+  emitBranch(ScratchRegister, ScratchRegister, lir->cond(), lir->ifTrue(),
+             lir->ifFalse());
+}
+
+void CodeGenerator::visitWasmUint32ToDouble(LWasmUint32ToDouble* lir) {
+  masm.convertUInt32ToDouble(ToRegister(lir->input()),
+                             ToFloatRegister(lir->output()));
+}
+
+void CodeGenerator::visitWasmUint32ToFloat32(LWasmUint32ToFloat32* lir) {
+  masm.convertUInt32ToFloat32(ToRegister(lir->input()),
+                              ToFloatRegister(lir->output()));
+}
+
+void CodeGenerator::visitNotI(LNotI* ins) {
+  masm.cmp32Set(Assembler::Equal, ToRegister(ins->input()), Imm32(0),
+                ToRegister(ins->output()));
+}
+
+void CodeGenerator::visitNotD(LNotD* ins) {
+  // Since this operation is not, we want to set a bit if
+  // the double is falsey, which means 0.0, -0.0 or NaN.
+  FloatRegister in = ToFloatRegister(ins->input());
+  Register dest = ToRegister(ins->output());
+
+  masm.loadConstantDouble(0.0, ScratchDoubleReg);
+  masm.ma_cmp_set_double(dest, in, ScratchDoubleReg,
+                         Assembler::DoubleEqualOrUnordered);
+}
+
+void CodeGenerator::visitNotF(LNotF* ins) {
+  // Since this operation is not, we want to set a bit if
+  // the float32 is falsey, which means 0.0, -0.0 or NaN.
+  FloatRegister in = ToFloatRegister(ins->input());
+  Register dest = ToRegister(ins->output());
+
+  masm.loadConstantFloat32(0.0f, ScratchFloat32Reg);
+  masm.ma_cmp_set_float32(dest, in, ScratchFloat32Reg,
+                          Assembler::DoubleEqualOrUnordered);
+}
+
+void CodeGenerator::visitMemoryBarrier(LMemoryBarrier* ins) {
+  masm.memoryBarrier(ins->type());
+}
+
+void CodeGeneratorMIPSShared::generateInvalidateEpilogue() {
+  // Ensure that there is enough space in the buffer for the OsiPoint
+  // patching to occur. Otherwise, we could overwrite the invalidation
+  // epilogue.
+  for (size_t i = 0; i < sizeof(void*); i += Assembler::NopSize()) {
+    masm.nop();
+  }
+
+  masm.bind(&invalidate_);
+
+  // Push the return address of the point that we bailed out at to the stack
+  masm.Push(ra);
+
+  // Push the Ion script onto the stack (when we determine what that
+  // pointer is).
+  invalidateEpilogueData_ = masm.pushWithPatch(ImmWord(uintptr_t(-1)));
+
+  // Jump to the invalidator which will replace the current frame.
+  TrampolinePtr thunk = gen->jitRuntime()->getInvalidationThunk();
+  masm.jump(thunk);
+}
+
+class js::jit::OutOfLineTableSwitch
+    : public OutOfLineCodeBase<CodeGeneratorMIPSShared> {
+  MTableSwitch* mir_;
+  CodeLabel jumpLabel_;
+
+  void accept(CodeGeneratorMIPSShared* codegen) {
+    codegen->visitOutOfLineTableSwitch(this);
+  }
+
+ public:
+  OutOfLineTableSwitch(MTableSwitch* mir) : mir_(mir) {}
+
+  MTableSwitch* mir() const { return mir_; }
+
+  CodeLabel* jumpLabel() { return &jumpLabel_; }
+};
+
+void CodeGeneratorMIPSShared::visitOutOfLineTableSwitch(
+    OutOfLineTableSwitch* ool) {
+  MTableSwitch* mir = ool->mir();
+
+  masm.haltingAlign(sizeof(void*));
+  masm.bind(ool->jumpLabel());
+  masm.addCodeLabel(*ool->jumpLabel());
+
+  for (size_t i = 0; i < mir->numCases(); i++) {
+    LBlock* caseblock = skipTrivialBlocks(mir->getCase(i))->lir();
+    Label* caseheader = caseblock->label();
+    uint32_t caseoffset = caseheader->offset();
+
+    // The entries of the jump table need to be absolute addresses and thus
+    // must be patched after codegen is finished.
+    CodeLabel cl;
+    masm.writeCodePointer(&cl);
+    cl.target()->bind(caseoffset);
+    masm.addCodeLabel(cl);
+  }
+}
+
+void CodeGeneratorMIPSShared::emitTableSwitchDispatch(MTableSwitch* mir,
+                                                      Register index,
+                                                      Register base) {
+  Label* defaultcase = skipTrivialBlocks(mir->getDefault())->lir()->label();
+
+  // Lower value with low value
+  if (mir->low() != 0) {
+    masm.subPtr(Imm32(mir->low()), index);
+  }
+
+  // Jump to default case if input is out of range
+  int32_t cases = mir->numCases();
+  masm.branchPtr(Assembler::AboveOrEqual, index, ImmWord(cases), defaultcase);
+
+  // To fill in the CodeLabels for the case entries, we need to first
+  // generate the case entries (we don't yet know their offsets in the
+  // instruction stream).
+  OutOfLineTableSwitch* ool = new (alloc()) OutOfLineTableSwitch(mir);
+  addOutOfLineCode(ool, mir);
+
+  // Compute the position where a pointer to the right case stands.
+  masm.ma_li(base, ool->jumpLabel());
+
+  BaseIndex pointer(base, index, ScalePointer);
+
+  // Jump to the right case
+  masm.branchToComputedAddress(pointer);
+}
+
+template <typename T>
+void CodeGeneratorMIPSShared::emitWasmLoad(T* lir) {
+  const MWasmLoad* mir = lir->mir();
+  SecondScratchRegisterScope scratch2(masm);
+
+  Register memoryBase = ToRegister(lir->memoryBase());
+  Register ptr = ToRegister(lir->ptr());
+  Register ptrScratch = InvalidReg;
+  if (!lir->ptrCopy()->isBogusTemp()) {
+    ptrScratch = ToRegister(lir->ptrCopy());
+  }
+
+  if (mir->base()->type() == MIRType::Int32) {
+    masm.move32To64ZeroExtend(ptr, Register64(scratch2));
+    ptr = scratch2;
+    ptrScratch = ptrScratch != InvalidReg ? scratch2 : InvalidReg;
+  }
+
+  if (IsUnaligned(mir->access())) {
+    if (IsFloatingPointType(mir->type())) {
+      masm.wasmUnalignedLoadFP(mir->access(), memoryBase, ptr, ptrScratch,
+                               ToFloatRegister(lir->output()),
+                               ToRegister(lir->getTemp(1)));
+    } else {
+      masm.wasmUnalignedLoad(mir->access(), memoryBase, ptr, ptrScratch,
+                             ToRegister(lir->output()),
+                             ToRegister(lir->getTemp(1)));
+    }
+  } else {
+    masm.wasmLoad(mir->access(), memoryBase, ptr, ptrScratch,
+                  ToAnyRegister(lir->output()));
+  }
+}
+
+void CodeGenerator::visitWasmLoad(LWasmLoad* lir) { emitWasmLoad(lir); }
+
+void CodeGenerator::visitWasmUnalignedLoad(LWasmUnalignedLoad* lir) {
+  emitWasmLoad(lir);
+}
+
+template <typename T>
+void CodeGeneratorMIPSShared::emitWasmStore(T* lir) {
+  const MWasmStore* mir = lir->mir();
+  SecondScratchRegisterScope scratch2(masm);
+
+  Register memoryBase = ToRegister(lir->memoryBase());
+  Register ptr = ToRegister(lir->ptr());
+  Register ptrScratch = InvalidReg;
+  if (!lir->ptrCopy()->isBogusTemp()) {
+    ptrScratch = ToRegister(lir->ptrCopy());
+  }
+
+  if (mir->base()->type() == MIRType::Int32) {
+    masm.move32To64ZeroExtend(ptr, Register64(scratch2));
+    ptr = scratch2;
+    ptrScratch = ptrScratch != InvalidReg ? scratch2 : InvalidReg;
+  }
+
+  if (IsUnaligned(mir->access())) {
+    if (mir->access().type() == Scalar::Float32 ||
+        mir->access().type() == Scalar::Float64) {
+      masm.wasmUnalignedStoreFP(mir->access(), ToFloatRegister(lir->value()),
+                                memoryBase, ptr, ptrScratch,
+                                ToRegister(lir->getTemp(1)));
+    } else {
+      masm.wasmUnalignedStore(mir->access(), ToRegister(lir->value()),
+                              memoryBase, ptr, ptrScratch,
+                              ToRegister(lir->getTemp(1)));
+    }
+  } else {
+    masm.wasmStore(mir->access(), ToAnyRegister(lir->value()), memoryBase, ptr,
+                   ptrScratch);
+  }
+}
+
+void CodeGenerator::visitWasmStore(LWasmStore* lir) { emitWasmStore(lir); }
+
+void CodeGenerator::visitWasmUnalignedStore(LWasmUnalignedStore* lir) {
+  emitWasmStore(lir);
+}
+
+void CodeGenerator::visitAsmJSLoadHeap(LAsmJSLoadHeap* ins) {
+  const MAsmJSLoadHeap* mir = ins->mir();
+  const LAllocation* ptr = ins->ptr();
+  const LDefinition* out = ins->output();
+  const LAllocation* boundsCheckLimit = ins->boundsCheckLimit();
+
+  bool isSigned;
+  int size;
+  bool isFloat = false;
+  switch (mir->access().type()) {
+    case Scalar::Int8:
+      isSigned = true;
+      size = 8;
+      break;
+    case Scalar::Uint8:
+      isSigned = false;
+      size = 8;
+      break;
+    case Scalar::Int16:
+      isSigned = true;
+      size = 16;
+      break;
+    case Scalar::Uint16:
+      isSigned = false;
+      size = 16;
+      break;
+    case Scalar::Int32:
+      isSigned = true;
+      size = 32;
+      break;
+    case Scalar::Uint32:
+      isSigned = false;
+      size = 32;
+      break;
+    case Scalar::Float64:
+      isFloat = true;
+      size = 64;
+      break;
+    case Scalar::Float32:
+      isFloat = true;
+      size = 32;
+      break;
+    default:
+      MOZ_CRASH("unexpected array type");
+  }
+
+  if (ptr->isConstant()) {
+    MOZ_ASSERT(!mir->needsBoundsCheck());
+    int32_t ptrImm = ptr->toConstant()->toInt32();
+    MOZ_ASSERT(ptrImm >= 0);
+    if (isFloat) {
+      if (size == 32) {
+        masm.loadFloat32(Address(HeapReg, ptrImm), ToFloatRegister(out));
+      } else {
+        masm.loadDouble(Address(HeapReg, ptrImm), ToFloatRegister(out));
+      }
+    } else {
+      masm.ma_load(ToRegister(out), Address(HeapReg, ptrImm),
+                   static_cast<LoadStoreSize>(size),
+                   isSigned ? SignExtend : ZeroExtend);
+    }
+    return;
+  }
+
+  Register ptrReg = ToRegister(ptr);
+
+  if (!mir->needsBoundsCheck()) {
+    if (isFloat) {
+      if (size == 32) {
+        masm.loadFloat32(BaseIndex(HeapReg, ptrReg, TimesOne),
+                         ToFloatRegister(out));
+      } else {
+        masm.loadDouble(BaseIndex(HeapReg, ptrReg, TimesOne),
+                        ToFloatRegister(out));
+      }
+    } else {
+      masm.ma_load(ToRegister(out), BaseIndex(HeapReg, ptrReg, TimesOne),
+                   static_cast<LoadStoreSize>(size),
+                   isSigned ? SignExtend : ZeroExtend);
+    }
+    return;
+  }
+
+  Label done, outOfRange;
+  masm.wasmBoundsCheck32(Assembler::AboveOrEqual, ptrReg,
+                         ToRegister(boundsCheckLimit), &outOfRange);
+  // Offset is ok, let's load value.
+  if (isFloat) {
+    if (size == 32) {
+      masm.loadFloat32(BaseIndex(HeapReg, ptrReg, TimesOne),
+                       ToFloatRegister(out));
+    } else {
+      masm.loadDouble(BaseIndex(HeapReg, ptrReg, TimesOne),
+                      ToFloatRegister(out));
+    }
+  } else {
+    masm.ma_load(ToRegister(out), BaseIndex(HeapReg, ptrReg, TimesOne),
+                 static_cast<LoadStoreSize>(size),
+                 isSigned ? SignExtend : ZeroExtend);
+  }
+  masm.ma_b(&done, ShortJump);
+  masm.bind(&outOfRange);
+  // Offset is out of range. Load default values.
+  if (isFloat) {
+    if (size == 32) {
+      masm.loadConstantFloat32(float(GenericNaN()), ToFloatRegister(out));
+    } else {
+      masm.loadConstantDouble(GenericNaN(), ToFloatRegister(out));
+    }
+  } else {
+    masm.move32(Imm32(0), ToRegister(out));
+  }
+  masm.bind(&done);
+}
+
+void CodeGenerator::visitAsmJSStoreHeap(LAsmJSStoreHeap* ins) {
+  const MAsmJSStoreHeap* mir = ins->mir();
+  const LAllocation* value = ins->value();
+  const LAllocation* ptr = ins->ptr();
+  const LAllocation* boundsCheckLimit = ins->boundsCheckLimit();
+
+  bool isSigned;
+  int size;
+  bool isFloat = false;
+  switch (mir->access().type()) {
+    case Scalar::Int8:
+      isSigned = true;
+      size = 8;
+      break;
+    case Scalar::Uint8:
+      isSigned = false;
+      size = 8;
+      break;
+    case Scalar::Int16:
+      isSigned = true;
+      size = 16;
+      break;
+    case Scalar::Uint16:
+      isSigned = false;
+      size = 16;
+      break;
+    case Scalar::Int32:
+      isSigned = true;
+      size = 32;
+      break;
+    case Scalar::Uint32:
+      isSigned = false;
+      size = 32;
+      break;
+    case Scalar::Float64:
+      isFloat = true;
+      size = 64;
+      break;
+    case Scalar::Float32:
+      isFloat = true;
+      size = 32;
+      break;
+    default:
+      MOZ_CRASH("unexpected array type");
+  }
+
+  if (ptr->isConstant()) {
+    MOZ_ASSERT(!mir->needsBoundsCheck());
+    int32_t ptrImm = ptr->toConstant()->toInt32();
+    MOZ_ASSERT(ptrImm >= 0);
+
+    if (isFloat) {
+      FloatRegister freg = ToFloatRegister(value);
+      Address addr(HeapReg, ptrImm);
+      if (size == 32) {
+        masm.storeFloat32(freg, addr);
+      } else {
+        masm.storeDouble(freg, addr);
+      }
+    } else {
+      masm.ma_store(ToRegister(value), Address(HeapReg, ptrImm),
+                    static_cast<LoadStoreSize>(size),
+                    isSigned ? SignExtend : ZeroExtend);
+    }
+    return;
+  }
+
+  Register ptrReg = ToRegister(ptr);
+  Address dstAddr(ptrReg, 0);
+
+  if (!mir->needsBoundsCheck()) {
+    if (isFloat) {
+      FloatRegister freg = ToFloatRegister(value);
+      BaseIndex bi(HeapReg, ptrReg, TimesOne);
+      if (size == 32) {
+        masm.storeFloat32(freg, bi);
+      } else {
+        masm.storeDouble(freg, bi);
+      }
+    } else {
+      masm.ma_store(ToRegister(value), BaseIndex(HeapReg, ptrReg, TimesOne),
+                    static_cast<LoadStoreSize>(size),
+                    isSigned ? SignExtend : ZeroExtend);
+    }
+    return;
+  }
+
+  Label outOfRange;
+  masm.wasmBoundsCheck32(Assembler::AboveOrEqual, ptrReg,
+                         ToRegister(boundsCheckLimit), &outOfRange);
+
+  // Offset is ok, let's store value.
+  if (isFloat) {
+    if (size == 32) {
+      masm.storeFloat32(ToFloatRegister(value),
+                        BaseIndex(HeapReg, ptrReg, TimesOne));
+    } else
+      masm.storeDouble(ToFloatRegister(value),
+                       BaseIndex(HeapReg, ptrReg, TimesOne));
+  } else {
+    masm.ma_store(ToRegister(value), BaseIndex(HeapReg, ptrReg, TimesOne),
+                  static_cast<LoadStoreSize>(size),
+                  isSigned ? SignExtend : ZeroExtend);
+  }
+
+  masm.bind(&outOfRange);
+}
+
+void CodeGenerator::visitWasmCompareExchangeHeap(
+    LWasmCompareExchangeHeap* ins) {
+  MWasmCompareExchangeHeap* mir = ins->mir();
+  Register memoryBase = ToRegister(ins->memoryBase());
+  Register ptrReg = ToRegister(ins->ptr());
+  BaseIndex srcAddr(memoryBase, ptrReg, TimesOne, mir->access().offset());
+  MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
+
+  Register oldval = ToRegister(ins->oldValue());
+  Register newval = ToRegister(ins->newValue());
+  Register valueTemp = ToTempRegisterOrInvalid(ins->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(ins->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(ins->maskTemp());
+
+  masm.wasmCompareExchange(mir->access(), srcAddr, oldval, newval, valueTemp,
+                           offsetTemp, maskTemp, ToRegister(ins->output()));
+}
+
+void CodeGenerator::visitWasmAtomicExchangeHeap(LWasmAtomicExchangeHeap* ins) {
+  MWasmAtomicExchangeHeap* mir = ins->mir();
+  Register memoryBase = ToRegister(ins->memoryBase());
+  Register ptrReg = ToRegister(ins->ptr());
+  Register value = ToRegister(ins->value());
+  BaseIndex srcAddr(memoryBase, ptrReg, TimesOne, mir->access().offset());
+  MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
+
+  Register valueTemp = ToTempRegisterOrInvalid(ins->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(ins->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(ins->maskTemp());
+
+  masm.wasmAtomicExchange(mir->access(), srcAddr, value, valueTemp, offsetTemp,
+                          maskTemp, ToRegister(ins->output()));
+}
+
+void CodeGenerator::visitWasmAtomicBinopHeap(LWasmAtomicBinopHeap* ins) {
+  MOZ_ASSERT(ins->mir()->hasUses());
+  MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
+
+  MWasmAtomicBinopHeap* mir = ins->mir();
+  Register memoryBase = ToRegister(ins->memoryBase());
+  Register ptrReg = ToRegister(ins->ptr());
+  Register valueTemp = ToTempRegisterOrInvalid(ins->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(ins->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(ins->maskTemp());
+
+  BaseIndex srcAddr(memoryBase, ptrReg, TimesOne, mir->access().offset());
+
+  masm.wasmAtomicFetchOp(mir->access(), mir->operation(),
+                         ToRegister(ins->value()), srcAddr, valueTemp,
+                         offsetTemp, maskTemp, ToRegister(ins->output()));
+}
+
+void CodeGenerator::visitWasmAtomicBinopHeapForEffect(
+    LWasmAtomicBinopHeapForEffect* ins) {
+  MOZ_ASSERT(!ins->mir()->hasUses());
+  MOZ_ASSERT(ins->addrTemp()->isBogusTemp());
+
+  MWasmAtomicBinopHeap* mir = ins->mir();
+  Register memoryBase = ToRegister(ins->memoryBase());
+  Register ptrReg = ToRegister(ins->ptr());
+  Register valueTemp = ToTempRegisterOrInvalid(ins->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(ins->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(ins->maskTemp());
+
+  BaseIndex srcAddr(memoryBase, ptrReg, TimesOne, mir->access().offset());
+  masm.wasmAtomicEffectOp(mir->access(), mir->operation(),
+                          ToRegister(ins->value()), srcAddr, valueTemp,
+                          offsetTemp, maskTemp);
+}
+
+void CodeGenerator::visitWasmStackArg(LWasmStackArg* ins) {
+  const MWasmStackArg* mir = ins->mir();
+  if (ins->arg()->isConstant()) {
+    masm.storePtr(ImmWord(ToInt32(ins->arg())),
+                  Address(StackPointer, mir->spOffset()));
+  } else {
+    if (ins->arg()->isGeneralReg()) {
+      masm.storePtr(ToRegister(ins->arg()),
+                    Address(StackPointer, mir->spOffset()));
+    } else if (mir->input()->type() == MIRType::Double) {
+      masm.storeDouble(ToFloatRegister(ins->arg()).doubleOverlay(),
+                       Address(StackPointer, mir->spOffset()));
+    } else {
+      masm.storeFloat32(ToFloatRegister(ins->arg()),
+                        Address(StackPointer, mir->spOffset()));
+    }
+  }
+}
+
+void CodeGenerator::visitWasmStackArgI64(LWasmStackArgI64* ins) {
+  const MWasmStackArg* mir = ins->mir();
+  Address dst(StackPointer, mir->spOffset());
+  if (IsConstant(ins->arg())) {
+    masm.store64(Imm64(ToInt64(ins->arg())), dst);
+  } else {
+    masm.store64(ToRegister64(ins->arg()), dst);
+  }
+}
+
+void CodeGenerator::visitWasmSelect(LWasmSelect* ins) {
+  MIRType mirType = ins->mir()->type();
+
+  Register cond = ToRegister(ins->condExpr());
+  const LAllocation* falseExpr = ins->falseExpr();
+
+  if (mirType == MIRType::Int32 || mirType == MIRType::WasmAnyRef) {
+    Register out = ToRegister(ins->output());
+    MOZ_ASSERT(ToRegister(ins->trueExpr()) == out,
+               "true expr input is reused for output");
+    if (falseExpr->isRegister()) {
+      masm.as_movz(out, ToRegister(falseExpr), cond);
+    } else {
+      masm.cmp32Load32(Assembler::Zero, cond, cond, ToAddress(falseExpr), out);
+    }
+    return;
+  }
+
+  FloatRegister out = ToFloatRegister(ins->output());
+  MOZ_ASSERT(ToFloatRegister(ins->trueExpr()) == out,
+             "true expr input is reused for output");
+
+  if (falseExpr->isFloatReg()) {
+    if (mirType == MIRType::Float32) {
+      masm.as_movz(Assembler::SingleFloat, out, ToFloatRegister(falseExpr),
+                   cond);
+    } else if (mirType == MIRType::Double) {
+      masm.as_movz(Assembler::DoubleFloat, out, ToFloatRegister(falseExpr),
+                   cond);
+    } else {
+      MOZ_CRASH("unhandled type in visitWasmSelect!");
+    }
+  } else {
+    Label done;
+    masm.ma_b(cond, cond, &done, Assembler::NonZero, ShortJump);
+
+    if (mirType == MIRType::Float32) {
+      masm.loadFloat32(ToAddress(falseExpr), out);
+    } else if (mirType == MIRType::Double) {
+      masm.loadDouble(ToAddress(falseExpr), out);
+    } else {
+      MOZ_CRASH("unhandled type in visitWasmSelect!");
+    }
+
+    masm.bind(&done);
+  }
+}
+
+// We expect to handle only the case where compare is {U,}Int32 and select is
+// {U,}Int32, and the "true" input is reused for the output.
+void CodeGenerator::visitWasmCompareAndSelect(LWasmCompareAndSelect* ins) {
+  bool cmpIs32bit = ins->compareType() == MCompare::Compare_Int32 ||
+                    ins->compareType() == MCompare::Compare_UInt32;
+  bool selIs32bit = ins->mir()->type() == MIRType::Int32;
+
+  MOZ_RELEASE_ASSERT(
+      cmpIs32bit && selIs32bit,
+      "CodeGenerator::visitWasmCompareAndSelect: unexpected types");
+
+  Register trueExprAndDest = ToRegister(ins->output());
+  MOZ_ASSERT(ToRegister(ins->ifTrueExpr()) == trueExprAndDest,
+             "true expr input is reused for output");
+
+  Assembler::Condition cond = Assembler::InvertCondition(
+      JSOpToCondition(ins->compareType(), ins->jsop()));
+  const LAllocation* rhs = ins->rightExpr();
+  const LAllocation* falseExpr = ins->ifFalseExpr();
+  Register lhs = ToRegister(ins->leftExpr());
+
+  masm.cmp32Move32(cond, lhs, ToRegister(rhs), ToRegister(falseExpr),
+                   trueExprAndDest);
+}
+
+void CodeGenerator::visitWasmReinterpret(LWasmReinterpret* lir) {
+  MOZ_ASSERT(gen->compilingWasm());
+  MWasmReinterpret* ins = lir->mir();
+
+  MIRType to = ins->type();
+  DebugOnly<MIRType> from = ins->input()->type();
+
+  switch (to) {
+    case MIRType::Int32:
+      MOZ_ASSERT(from == MIRType::Float32);
+      masm.as_mfc1(ToRegister(lir->output()), ToFloatRegister(lir->input()));
+      break;
+    case MIRType::Float32:
+      MOZ_ASSERT(from == MIRType::Int32);
+      masm.as_mtc1(ToRegister(lir->input()), ToFloatRegister(lir->output()));
+      break;
+    case MIRType::Double:
+    case MIRType::Int64:
+      MOZ_CRASH("not handled by this LIR opcode");
+    default:
+      MOZ_CRASH("unexpected WasmReinterpret");
+  }
+}
+
+void CodeGenerator::visitUDivOrMod(LUDivOrMod* ins) {
+  Register lhs = ToRegister(ins->lhs());
+  Register rhs = ToRegister(ins->rhs());
+  Register output = ToRegister(ins->output());
+  Label done;
+
+  // Prevent divide by zero.
+  if (ins->canBeDivideByZero()) {
+    if (ins->mir()->isTruncated()) {
+      if (ins->trapOnError()) {
+        Label nonZero;
+        masm.ma_b(rhs, rhs, &nonZero, Assembler::NonZero);
+        masm.wasmTrap(wasm::Trap::IntegerDivideByZero, ins->bytecodeOffset());
+        masm.bind(&nonZero);
+      } else {
+        // Infinity|0 == 0
+        Label notzero;
+        masm.ma_b(rhs, rhs, &notzero, Assembler::NonZero, ShortJump);
+        masm.move32(Imm32(0), output);
+        masm.ma_b(&done, ShortJump);
+        masm.bind(&notzero);
+      }
+    } else {
+      bailoutCmp32(Assembler::Equal, rhs, Imm32(0), ins->snapshot());
+    }
+  }
+
+#ifdef MIPSR6
+  masm.as_modu(output, lhs, rhs);
+#else
+  masm.as_divu(lhs, rhs);
+  masm.as_mfhi(output);
+#endif
+
+  // If the remainder is > 0, bailout since this must be a double.
+  if (ins->mir()->isDiv()) {
+    if (!ins->mir()->toDiv()->canTruncateRemainder()) {
+      bailoutCmp32(Assembler::NonZero, output, output, ins->snapshot());
+    }
+    // Get quotient
+#ifdef MIPSR6
+    masm.as_divu(output, lhs, rhs);
+#else
+    masm.as_mflo(output);
+#endif
+  }
+
+  if (!ins->mir()->isTruncated()) {
+    bailoutCmp32(Assembler::LessThan, output, Imm32(0), ins->snapshot());
+  }
+
+  masm.bind(&done);
+}
+
+void CodeGenerator::visitEffectiveAddress(LEffectiveAddress* ins) {
+  const MEffectiveAddress* mir = ins->mir();
+  Register base = ToRegister(ins->base());
+  Register index = ToRegister(ins->index());
+  Register output = ToRegister(ins->output());
+
+  BaseIndex address(base, index, mir->scale(), mir->displacement());
+  masm.computeEffectiveAddress(address, output);
+}
+
+void CodeGenerator::visitNegI(LNegI* ins) {
+  Register input = ToRegister(ins->input());
+  Register output = ToRegister(ins->output());
+
+  masm.ma_negu(output, input);
+}
+
+void CodeGenerator::visitNegI64(LNegI64* ins) {
+  Register64 input = ToRegister64(ins->getInt64Operand(0));
+  MOZ_ASSERT(input == ToOutRegister64(ins));
+  masm.neg64(input);
+}
+
+void CodeGenerator::visitNegD(LNegD* ins) {
+  FloatRegister input = ToFloatRegister(ins->input());
+  FloatRegister output = ToFloatRegister(ins->output());
+
+  masm.as_negd(output, input);
+}
+
+void CodeGenerator::visitNegF(LNegF* ins) {
+  FloatRegister input = ToFloatRegister(ins->input());
+  FloatRegister output = ToFloatRegister(ins->output());
+
+  masm.as_negs(output, input);
+}
+
+void CodeGenerator::visitWasmAddOffset(LWasmAddOffset* lir) {
+  MWasmAddOffset* mir = lir->mir();
+  Register base = ToRegister(lir->base());
+  Register out = ToRegister(lir->output());
+
+  Label ok;
+  masm.ma_add32TestCarry(Assembler::CarryClear, out, base, Imm32(mir->offset()),
+                         &ok);
+  masm.wasmTrap(wasm::Trap::OutOfBounds, mir->bytecodeOffset());
+  masm.bind(&ok);
+}
+
+void CodeGenerator::visitWasmAddOffset64(LWasmAddOffset64* lir) {
+  MWasmAddOffset* mir = lir->mir();
+  Register64 base = ToRegister64(lir->base());
+  Register64 out = ToOutRegister64(lir);
+
+  Label ok;
+  masm.ma_addPtrTestCarry(Assembler::CarryClear, out.reg, base.reg,
+                          ImmWord(mir->offset()), &ok);
+  masm.wasmTrap(wasm::Trap::OutOfBounds, mir->bytecodeOffset());
+  masm.bind(&ok);
+}
+
+void CodeGenerator::visitAtomicTypedArrayElementBinop(
+    LAtomicTypedArrayElementBinop* lir) {
+  MOZ_ASSERT(!lir->mir()->isForEffect());
+
+  AnyRegister output = ToAnyRegister(lir->output());
+  Register elements = ToRegister(lir->elements());
+  Register outTemp = ToTempRegisterOrInvalid(lir->temp2());
+  Register valueTemp = ToTempRegisterOrInvalid(lir->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(lir->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(lir->maskTemp());
+  Register value = ToRegister(lir->value());
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+
+  if (lir->index()->isConstant()) {
+    Address mem = ToAddress(elements, lir->index(), arrayType);
+    masm.atomicFetchOpJS(arrayType, Synchronization::Full(),
+                         lir->mir()->operation(), value, mem, valueTemp,
+                         offsetTemp, maskTemp, outTemp, output);
+  } else {
+    BaseIndex mem(elements, ToRegister(lir->index()),
+                  ScaleFromScalarType(arrayType));
+    masm.atomicFetchOpJS(arrayType, Synchronization::Full(),
+                         lir->mir()->operation(), value, mem, valueTemp,
+                         offsetTemp, maskTemp, outTemp, output);
+  }
+}
+
+void CodeGenerator::visitAtomicTypedArrayElementBinopForEffect(
+    LAtomicTypedArrayElementBinopForEffect* lir) {
+  MOZ_ASSERT(lir->mir()->isForEffect());
+
+  Register elements = ToRegister(lir->elements());
+  Register valueTemp = ToTempRegisterOrInvalid(lir->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(lir->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(lir->maskTemp());
+  Register value = ToRegister(lir->value());
+  Scalar::Type arrayType = lir->mir()->arrayType();
+
+  if (lir->index()->isConstant()) {
+    Address mem = ToAddress(elements, lir->index(), arrayType);
+    masm.atomicEffectOpJS(arrayType, Synchronization::Full(),
+                          lir->mir()->operation(), value, mem, valueTemp,
+                          offsetTemp, maskTemp);
+  } else {
+    BaseIndex mem(elements, ToRegister(lir->index()),
+                  ScaleFromScalarType(arrayType));
+    masm.atomicEffectOpJS(arrayType, Synchronization::Full(),
+                          lir->mir()->operation(), value, mem, valueTemp,
+                          offsetTemp, maskTemp);
+  }
+}
+
+void CodeGenerator::visitCompareExchangeTypedArrayElement(
+    LCompareExchangeTypedArrayElement* lir) {
+  Register elements = ToRegister(lir->elements());
+  AnyRegister output = ToAnyRegister(lir->output());
+  Register outTemp = ToTempRegisterOrInvalid(lir->temp());
+
+  Register oldval = ToRegister(lir->oldval());
+  Register newval = ToRegister(lir->newval());
+  Register valueTemp = ToTempRegisterOrInvalid(lir->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(lir->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(lir->maskTemp());
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+
+  if (lir->index()->isConstant()) {
+    Address dest = ToAddress(elements, lir->index(), arrayType);
+    masm.compareExchangeJS(arrayType, Synchronization::Full(), dest, oldval,
+                           newval, valueTemp, offsetTemp, maskTemp, outTemp,
+                           output);
+  } else {
+    BaseIndex dest(elements, ToRegister(lir->index()),
+                   ScaleFromScalarType(arrayType));
+    masm.compareExchangeJS(arrayType, Synchronization::Full(), dest, oldval,
+                           newval, valueTemp, offsetTemp, maskTemp, outTemp,
+                           output);
+  }
+}
+
+void CodeGenerator::visitAtomicExchangeTypedArrayElement(
+    LAtomicExchangeTypedArrayElement* lir) {
+  Register elements = ToRegister(lir->elements());
+  AnyRegister output = ToAnyRegister(lir->output());
+  Register outTemp = ToTempRegisterOrInvalid(lir->temp());
+
+  Register value = ToRegister(lir->value());
+  Register valueTemp = ToTempRegisterOrInvalid(lir->valueTemp());
+  Register offsetTemp = ToTempRegisterOrInvalid(lir->offsetTemp());
+  Register maskTemp = ToTempRegisterOrInvalid(lir->maskTemp());
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+
+  if (lir->index()->isConstant()) {
+    Address dest = ToAddress(elements, lir->index(), arrayType);
+    masm.atomicExchangeJS(arrayType, Synchronization::Full(), dest, value,
+                          valueTemp, offsetTemp, maskTemp, outTemp, output);
+  } else {
+    BaseIndex dest(elements, ToRegister(lir->index()),
+                   ScaleFromScalarType(arrayType));
+    masm.atomicExchangeJS(arrayType, Synchronization::Full(), dest, value,
+                          valueTemp, offsetTemp, maskTemp, outTemp, output);
+  }
+}
+
+void CodeGenerator::visitCompareExchangeTypedArrayElement64(
+    LCompareExchangeTypedArrayElement64* lir) {
+  Register elements = ToRegister(lir->elements());
+  Register oldval = ToRegister(lir->oldval());
+  Register newval = ToRegister(lir->newval());
+  Register64 temp1 = ToRegister64(lir->temp1());
+  Register64 temp2 = ToRegister64(lir->temp2());
+  Register out = ToRegister(lir->output());
+  Register64 tempOut(out);
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+
+  masm.loadBigInt64(oldval, temp1);
+  masm.loadBigInt64(newval, tempOut);
+
+  if (lir->index()->isConstant()) {
+    Address dest = ToAddress(elements, lir->index(), arrayType);
+    masm.compareExchange64(Synchronization::Full(), dest, temp1, tempOut,
+                           temp2);
+  } else {
+    BaseIndex dest(elements, ToRegister(lir->index()),
+                   ScaleFromScalarType(arrayType));
+    masm.compareExchange64(Synchronization::Full(), dest, temp1, tempOut,
+                           temp2);
+  }
+
+  emitCreateBigInt(lir, arrayType, temp2, out, temp1.scratchReg());
+}
+
+void CodeGenerator::visitAtomicExchangeTypedArrayElement64(
+    LAtomicExchangeTypedArrayElement64* lir) {
+  Register elements = ToRegister(lir->elements());
+  Register value = ToRegister(lir->value());
+  Register64 temp1 = ToRegister64(lir->temp1());
+  Register64 temp2 = Register64(ToRegister(lir->temp2()));
+  Register out = ToRegister(lir->output());
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+
+  masm.loadBigInt64(value, temp1);
+
+  if (lir->index()->isConstant()) {
+    Address dest = ToAddress(elements, lir->index(), arrayType);
+    masm.atomicExchange64(Synchronization::Full(), dest, temp1, temp2);
+  } else {
+    BaseIndex dest(elements, ToRegister(lir->index()),
+                   ScaleFromScalarType(arrayType));
+    masm.atomicExchange64(Synchronization::Full(), dest, temp1, temp2);
+  }
+
+  emitCreateBigInt(lir, arrayType, temp2, out, temp1.scratchReg());
+}
+
+void CodeGenerator::visitAtomicTypedArrayElementBinop64(
+    LAtomicTypedArrayElementBinop64* lir) {
+  MOZ_ASSERT(lir->mir()->hasUses());
+
+  Register elements = ToRegister(lir->elements());
+  Register value = ToRegister(lir->value());
+  Register64 temp1 = ToRegister64(lir->temp1());
+  Register64 temp2 = ToRegister64(lir->temp2());
+  Register out = ToRegister(lir->output());
+  Register64 tempOut = Register64(out);
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+  AtomicOp atomicOp = lir->mir()->operation();
+
+  masm.loadBigInt64(value, temp1);
+
+  if (lir->index()->isConstant()) {
+    Address dest = ToAddress(elements, lir->index(), arrayType);
+    masm.atomicFetchOp64(Synchronization::Full(), atomicOp, temp1, dest,
+                         tempOut, temp2);
+  } else {
+    BaseIndex dest(elements, ToRegister(lir->index()),
+                   ScaleFromScalarType(arrayType));
+    masm.atomicFetchOp64(Synchronization::Full(), atomicOp, temp1, dest,
+                         tempOut, temp2);
+  }
+
+  emitCreateBigInt(lir, arrayType, temp2, out, temp1.scratchReg());
+}
+
+void CodeGenerator::visitAtomicTypedArrayElementBinopForEffect64(
+    LAtomicTypedArrayElementBinopForEffect64* lir) {
+  MOZ_ASSERT(!lir->mir()->hasUses());
+
+  Register elements = ToRegister(lir->elements());
+  Register value = ToRegister(lir->value());
+  Register64 temp1 = ToRegister64(lir->temp1());
+  Register64 temp2 = ToRegister64(lir->temp2());
+
+  Scalar::Type arrayType = lir->mir()->arrayType();
+  AtomicOp atomicOp = lir->mir()->operation();
+
+  masm.loadBigInt64(value, temp1);
+
+  if (lir->index()->isConstant()) {
+    Address dest = ToAddress(elements, lir->index(), arrayType);
+    masm.atomicEffectOp64(Synchronization::Full(), atomicOp, temp1, dest,
+                          temp2);
+  } else {
+    BaseIndex dest(elements, ToRegister(lir->index()),
+                   ScaleFromScalarType(arrayType));
+    masm.atomicEffectOp64(Synchronization::Full(), atomicOp, temp1, dest,
+                          temp2);
+  }
+}
+
+void CodeGenerator::visitWasmCompareExchangeI64(LWasmCompareExchangeI64* lir) {
+  Register memoryBase = ToRegister(lir->memoryBase());
+  Register ptr = ToRegister(lir->ptr());
+  Register64 oldValue = ToRegister64(lir->oldValue());
+  Register64 newValue = ToRegister64(lir->newValue());
+  Register64 output = ToOutRegister64(lir);
+  uint32_t offset = lir->mir()->access().offset();
+
+  BaseIndex addr(memoryBase, ptr, TimesOne, offset);
+  masm.wasmCompareExchange64(lir->mir()->access(), addr, oldValue, newValue,
+                             output);
+}
+
+void CodeGenerator::visitWasmAtomicExchangeI64(LWasmAtomicExchangeI64* lir) {
+  Register memoryBase = ToRegister(lir->memoryBase());
+  Register ptr = ToRegister(lir->ptr());
+  Register64 value = ToRegister64(lir->value());
+  Register64 output = ToOutRegister64(lir);
+  uint32_t offset = lir->mir()->access().offset();
+
+  BaseIndex addr(memoryBase, ptr, TimesOne, offset);
+  masm.wasmAtomicExchange64(lir->mir()->access(), addr, value, output);
+}
+
+void CodeGenerator::visitWasmAtomicBinopI64(LWasmAtomicBinopI64* lir) {
+  Register memoryBase = ToRegister(lir->memoryBase());
+  Register ptr = ToRegister(lir->ptr());
+  Register64 value = ToRegister64(lir->value());
+  Register64 output = ToOutRegister64(lir);
+#ifdef JS_CODEGEN_MIPS32
+  Register64 temp(ToRegister(lir->getTemp(0)), ToRegister(lir->getTemp(1)));
+#else
+  Register64 temp(ToRegister(lir->getTemp(0)));
+#endif
+  uint32_t offset = lir->mir()->access().offset();
+
+  BaseIndex addr(memoryBase, ptr, TimesOne, offset);
+
+  masm.wasmAtomicFetchOp64(lir->mir()->access(), lir->mir()->operation(), value,
+                           addr, temp, output);
+}
+
+void CodeGenerator::visitNearbyInt(LNearbyInt*) { MOZ_CRASH("NYI"); }
+
+void CodeGenerator::visitNearbyIntF(LNearbyIntF*) { MOZ_CRASH("NYI"); }
+
+void CodeGenerator::visitSimd128(LSimd128* ins) { MOZ_CRASH("No SIMD"); }
+
+void CodeGenerator::visitWasmTernarySimd128(LWasmTernarySimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmBinarySimd128(LWasmBinarySimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmBinarySimd128WithConstant(
+    LWasmBinarySimd128WithConstant* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmVariableShiftSimd128(
+    LWasmVariableShiftSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmConstantShiftSimd128(
+    LWasmConstantShiftSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmSignReplicationSimd128(
+    LWasmSignReplicationSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmShuffleSimd128(LWasmShuffleSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmPermuteSimd128(LWasmPermuteSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmReplaceLaneSimd128(LWasmReplaceLaneSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmReplaceInt64LaneSimd128(
+    LWasmReplaceInt64LaneSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmScalarToSimd128(LWasmScalarToSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmInt64ToSimd128(LWasmInt64ToSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmUnarySimd128(LWasmUnarySimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmReduceSimd128(LWasmReduceSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmReduceAndBranchSimd128(
+    LWasmReduceAndBranchSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmReduceSimd128ToInt64(
+    LWasmReduceSimd128ToInt64* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmLoadLaneSimd128(LWasmLoadLaneSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
+
+void CodeGenerator::visitWasmStoreLaneSimd128(LWasmStoreLaneSimd128* ins) {
+  MOZ_CRASH("No SIMD");
+}
-- 
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