Create separate Android.mk for main build targets
The runtime, compiler, dex2oat, and oatdump now are in seperate trees
to prevent dependency creep. They can now be individually built
without rebuilding the rest of the art projects. dalvikvm and jdwpspy
were already this way. Builds in the art directory should behave as
before, building everything including tests.
Change-Id: Ic6b1151e5ed0f823c3dd301afd2b13eb2d8feb81
diff --git a/compiler/dex/quick/x86/utility_x86.cc b/compiler/dex/quick/x86/utility_x86.cc
new file mode 100644
index 0000000..fb07ff1
--- /dev/null
+++ b/compiler/dex/quick/x86/utility_x86.cc
@@ -0,0 +1,582 @@
+/*
+ * Copyright (C) 2012 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 "codegen_x86.h"
+#include "dex/quick/mir_to_lir-inl.h"
+#include "x86_lir.h"
+
+namespace art {
+
+/* This file contains codegen for the X86 ISA */
+
+LIR* X86Mir2Lir::OpFpRegCopy(int r_dest, int r_src)
+{
+ int opcode;
+ /* must be both DOUBLE or both not DOUBLE */
+ DCHECK_EQ(X86_DOUBLEREG(r_dest), X86_DOUBLEREG(r_src));
+ if (X86_DOUBLEREG(r_dest)) {
+ opcode = kX86MovsdRR;
+ } else {
+ if (X86_SINGLEREG(r_dest)) {
+ if (X86_SINGLEREG(r_src)) {
+ opcode = kX86MovssRR;
+ } else { // Fpr <- Gpr
+ opcode = kX86MovdxrRR;
+ }
+ } else { // Gpr <- Fpr
+ DCHECK(X86_SINGLEREG(r_src));
+ opcode = kX86MovdrxRR;
+ }
+ }
+ DCHECK_NE((EncodingMap[opcode].flags & IS_BINARY_OP), 0ULL);
+ LIR* res = RawLIR(current_dalvik_offset_, opcode, r_dest, r_src);
+ if (r_dest == r_src) {
+ res->flags.is_nop = true;
+ }
+ return res;
+}
+
+bool X86Mir2Lir::InexpensiveConstantInt(int32_t value)
+{
+ return true;
+}
+
+bool X86Mir2Lir::InexpensiveConstantFloat(int32_t value)
+{
+ return false;
+}
+
+bool X86Mir2Lir::InexpensiveConstantLong(int64_t value)
+{
+ return true;
+}
+
+bool X86Mir2Lir::InexpensiveConstantDouble(int64_t value)
+{
+ return false; // TUNING
+}
+
+/*
+ * Load a immediate using a shortcut if possible; otherwise
+ * grab from the per-translation literal pool. If target is
+ * a high register, build constant into a low register and copy.
+ *
+ * No additional register clobbering operation performed. Use this version when
+ * 1) r_dest is freshly returned from AllocTemp or
+ * 2) The codegen is under fixed register usage
+ */
+LIR* X86Mir2Lir::LoadConstantNoClobber(int r_dest, int value)
+{
+ int r_dest_save = r_dest;
+ if (X86_FPREG(r_dest)) {
+ if (value == 0) {
+ return NewLIR2(kX86XorpsRR, r_dest, r_dest);
+ }
+ DCHECK(X86_SINGLEREG(r_dest));
+ r_dest = AllocTemp();
+ }
+
+ LIR *res;
+ if (value == 0) {
+ res = NewLIR2(kX86Xor32RR, r_dest, r_dest);
+ } else {
+ // Note, there is no byte immediate form of a 32 bit immediate move.
+ res = NewLIR2(kX86Mov32RI, r_dest, value);
+ }
+
+ if (X86_FPREG(r_dest_save)) {
+ NewLIR2(kX86MovdxrRR, r_dest_save, r_dest);
+ FreeTemp(r_dest);
+ }
+
+ return res;
+}
+
+LIR* X86Mir2Lir::OpUnconditionalBranch(LIR* target)
+{
+ LIR* res = NewLIR1(kX86Jmp8, 0 /* offset to be patched during assembly*/ );
+ res->target = target;
+ return res;
+}
+
+LIR* X86Mir2Lir::OpCondBranch(ConditionCode cc, LIR* target)
+{
+ LIR* branch = NewLIR2(kX86Jcc8, 0 /* offset to be patched */,
+ X86ConditionEncoding(cc));
+ branch->target = target;
+ return branch;
+}
+
+LIR* X86Mir2Lir::OpReg(OpKind op, int r_dest_src)
+{
+ X86OpCode opcode = kX86Bkpt;
+ switch (op) {
+ case kOpNeg: opcode = kX86Neg32R; break;
+ case kOpNot: opcode = kX86Not32R; break;
+ case kOpBlx: opcode = kX86CallR; break;
+ default:
+ LOG(FATAL) << "Bad case in OpReg " << op;
+ }
+ return NewLIR1(opcode, r_dest_src);
+}
+
+LIR* X86Mir2Lir::OpRegImm(OpKind op, int r_dest_src1, int value)
+{
+ X86OpCode opcode = kX86Bkpt;
+ bool byte_imm = IS_SIMM8(value);
+ DCHECK(!X86_FPREG(r_dest_src1));
+ switch (op) {
+ case kOpLsl: opcode = kX86Sal32RI; break;
+ case kOpLsr: opcode = kX86Shr32RI; break;
+ case kOpAsr: opcode = kX86Sar32RI; break;
+ case kOpAdd: opcode = byte_imm ? kX86Add32RI8 : kX86Add32RI; break;
+ case kOpOr: opcode = byte_imm ? kX86Or32RI8 : kX86Or32RI; break;
+ case kOpAdc: opcode = byte_imm ? kX86Adc32RI8 : kX86Adc32RI; break;
+ //case kOpSbb: opcode = kX86Sbb32RI; break;
+ case kOpAnd: opcode = byte_imm ? kX86And32RI8 : kX86And32RI; break;
+ case kOpSub: opcode = byte_imm ? kX86Sub32RI8 : kX86Sub32RI; break;
+ case kOpXor: opcode = byte_imm ? kX86Xor32RI8 : kX86Xor32RI; break;
+ case kOpCmp: opcode = byte_imm ? kX86Cmp32RI8 : kX86Cmp32RI; break;
+ case kOpMov: return LoadConstantNoClobber(r_dest_src1, value);
+ case kOpMul:
+ opcode = byte_imm ? kX86Imul32RRI8 : kX86Imul32RRI;
+ return NewLIR3(opcode, r_dest_src1, r_dest_src1, value);
+ default:
+ LOG(FATAL) << "Bad case in OpRegImm " << op;
+ }
+ return NewLIR2(opcode, r_dest_src1, value);
+}
+
+LIR* X86Mir2Lir::OpRegReg(OpKind op, int r_dest_src1, int r_src2)
+{
+ X86OpCode opcode = kX86Nop;
+ bool src2_must_be_cx = false;
+ switch (op) {
+ // X86 unary opcodes
+ case kOpMvn:
+ OpRegCopy(r_dest_src1, r_src2);
+ return OpReg(kOpNot, r_dest_src1);
+ case kOpNeg:
+ OpRegCopy(r_dest_src1, r_src2);
+ return OpReg(kOpNeg, r_dest_src1);
+ // X86 binary opcodes
+ case kOpSub: opcode = kX86Sub32RR; break;
+ case kOpSbc: opcode = kX86Sbb32RR; break;
+ case kOpLsl: opcode = kX86Sal32RC; src2_must_be_cx = true; break;
+ case kOpLsr: opcode = kX86Shr32RC; src2_must_be_cx = true; break;
+ case kOpAsr: opcode = kX86Sar32RC; src2_must_be_cx = true; break;
+ case kOpMov: opcode = kX86Mov32RR; break;
+ case kOpCmp: opcode = kX86Cmp32RR; break;
+ case kOpAdd: opcode = kX86Add32RR; break;
+ case kOpAdc: opcode = kX86Adc32RR; break;
+ case kOpAnd: opcode = kX86And32RR; break;
+ case kOpOr: opcode = kX86Or32RR; break;
+ case kOpXor: opcode = kX86Xor32RR; break;
+ case kOp2Byte:
+ // Use shifts instead of a byte operand if the source can't be byte accessed.
+ if (r_src2 >= 4) {
+ NewLIR2(kX86Mov32RR, r_dest_src1, r_src2);
+ NewLIR2(kX86Sal32RI, r_dest_src1, 24);
+ return NewLIR2(kX86Sar32RI, r_dest_src1, 24);
+ } else {
+ opcode = kX86Movsx8RR;
+ }
+ break;
+ case kOp2Short: opcode = kX86Movsx16RR; break;
+ case kOp2Char: opcode = kX86Movzx16RR; break;
+ case kOpMul: opcode = kX86Imul32RR; break;
+ default:
+ LOG(FATAL) << "Bad case in OpRegReg " << op;
+ break;
+ }
+ CHECK(!src2_must_be_cx || r_src2 == rCX);
+ return NewLIR2(opcode, r_dest_src1, r_src2);
+}
+
+LIR* X86Mir2Lir::OpRegMem(OpKind op, int r_dest, int rBase,
+ int offset)
+{
+ X86OpCode opcode = kX86Nop;
+ switch (op) {
+ // X86 binary opcodes
+ case kOpSub: opcode = kX86Sub32RM; break;
+ case kOpMov: opcode = kX86Mov32RM; break;
+ case kOpCmp: opcode = kX86Cmp32RM; break;
+ case kOpAdd: opcode = kX86Add32RM; break;
+ case kOpAnd: opcode = kX86And32RM; break;
+ case kOpOr: opcode = kX86Or32RM; break;
+ case kOpXor: opcode = kX86Xor32RM; break;
+ case kOp2Byte: opcode = kX86Movsx8RM; break;
+ case kOp2Short: opcode = kX86Movsx16RM; break;
+ case kOp2Char: opcode = kX86Movzx16RM; break;
+ case kOpMul:
+ default:
+ LOG(FATAL) << "Bad case in OpRegMem " << op;
+ break;
+ }
+ return NewLIR3(opcode, r_dest, rBase, offset);
+}
+
+LIR* X86Mir2Lir::OpRegRegReg(OpKind op, int r_dest, int r_src1,
+ int r_src2)
+{
+ if (r_dest != r_src1 && r_dest != r_src2) {
+ if (op == kOpAdd) { // lea special case, except can't encode rbp as base
+ if (r_src1 == r_src2) {
+ OpRegCopy(r_dest, r_src1);
+ return OpRegImm(kOpLsl, r_dest, 1);
+ } else if (r_src1 != rBP) {
+ return NewLIR5(kX86Lea32RA, r_dest, r_src1 /* base */,
+ r_src2 /* index */, 0 /* scale */, 0 /* disp */);
+ } else {
+ return NewLIR5(kX86Lea32RA, r_dest, r_src2 /* base */,
+ r_src1 /* index */, 0 /* scale */, 0 /* disp */);
+ }
+ } else {
+ OpRegCopy(r_dest, r_src1);
+ return OpRegReg(op, r_dest, r_src2);
+ }
+ } else if (r_dest == r_src1) {
+ return OpRegReg(op, r_dest, r_src2);
+ } else { // r_dest == r_src2
+ switch (op) {
+ case kOpSub: // non-commutative
+ OpReg(kOpNeg, r_dest);
+ op = kOpAdd;
+ break;
+ case kOpSbc:
+ case kOpLsl: case kOpLsr: case kOpAsr: case kOpRor: {
+ int t_reg = AllocTemp();
+ OpRegCopy(t_reg, r_src1);
+ OpRegReg(op, t_reg, r_src2);
+ LIR* res = OpRegCopy(r_dest, t_reg);
+ FreeTemp(t_reg);
+ return res;
+ }
+ case kOpAdd: // commutative
+ case kOpOr:
+ case kOpAdc:
+ case kOpAnd:
+ case kOpXor:
+ break;
+ default:
+ LOG(FATAL) << "Bad case in OpRegRegReg " << op;
+ }
+ return OpRegReg(op, r_dest, r_src1);
+ }
+}
+
+LIR* X86Mir2Lir::OpRegRegImm(OpKind op, int r_dest, int r_src,
+ int value)
+{
+ if (op == kOpMul) {
+ X86OpCode opcode = IS_SIMM8(value) ? kX86Imul32RRI8 : kX86Imul32RRI;
+ return NewLIR3(opcode, r_dest, r_src, value);
+ } else if (op == kOpAnd) {
+ if (value == 0xFF && r_src < 4) {
+ return NewLIR2(kX86Movzx8RR, r_dest, r_src);
+ } else if (value == 0xFFFF) {
+ return NewLIR2(kX86Movzx16RR, r_dest, r_src);
+ }
+ }
+ if (r_dest != r_src) {
+ if (false && op == kOpLsl && value >= 0 && value <= 3) { // lea shift special case
+ // TODO: fix bug in LEA encoding when disp == 0
+ return NewLIR5(kX86Lea32RA, r_dest, r5sib_no_base /* base */,
+ r_src /* index */, value /* scale */, 0 /* disp */);
+ } else if (op == kOpAdd) { // lea add special case
+ return NewLIR5(kX86Lea32RA, r_dest, r_src /* base */,
+ r4sib_no_index /* index */, 0 /* scale */, value /* disp */);
+ }
+ OpRegCopy(r_dest, r_src);
+ }
+ return OpRegImm(op, r_dest, value);
+}
+
+LIR* X86Mir2Lir::OpThreadMem(OpKind op, int thread_offset)
+{
+ X86OpCode opcode = kX86Bkpt;
+ switch (op) {
+ case kOpBlx: opcode = kX86CallT; break;
+ default:
+ LOG(FATAL) << "Bad opcode: " << op;
+ break;
+ }
+ return NewLIR1(opcode, thread_offset);
+}
+
+LIR* X86Mir2Lir::OpMem(OpKind op, int rBase, int disp)
+{
+ X86OpCode opcode = kX86Bkpt;
+ switch (op) {
+ case kOpBlx: opcode = kX86CallM; break;
+ default:
+ LOG(FATAL) << "Bad opcode: " << op;
+ break;
+ }
+ return NewLIR2(opcode, rBase, disp);
+}
+
+LIR* X86Mir2Lir::LoadConstantWide(int r_dest_lo, int r_dest_hi, int64_t value)
+{
+ int32_t val_lo = Low32Bits(value);
+ int32_t val_hi = High32Bits(value);
+ LIR *res;
+ if (X86_FPREG(r_dest_lo)) {
+ DCHECK(X86_FPREG(r_dest_hi)); // ignore r_dest_hi
+ if (value == 0) {
+ return NewLIR2(kX86XorpsRR, r_dest_lo, r_dest_lo);
+ } else {
+ if (val_lo == 0) {
+ res = NewLIR2(kX86XorpsRR, r_dest_lo, r_dest_lo);
+ } else {
+ res = LoadConstantNoClobber(r_dest_lo, val_lo);
+ }
+ if (val_hi != 0) {
+ LoadConstantNoClobber(r_dest_hi, val_hi);
+ NewLIR2(kX86PsllqRI, r_dest_hi, 32);
+ NewLIR2(kX86OrpsRR, r_dest_lo, r_dest_hi);
+ }
+ }
+ } else {
+ res = LoadConstantNoClobber(r_dest_lo, val_lo);
+ LoadConstantNoClobber(r_dest_hi, val_hi);
+ }
+ return res;
+}
+
+LIR* X86Mir2Lir::LoadBaseIndexedDisp(int rBase, int r_index, int scale,
+ int displacement, int r_dest, int r_dest_hi, OpSize size,
+ int s_reg) {
+ LIR *load = NULL;
+ LIR *load2 = NULL;
+ bool is_array = r_index != INVALID_REG;
+ bool pair = false;
+ bool is64bit = false;
+ X86OpCode opcode = kX86Nop;
+ switch (size) {
+ case kLong:
+ case kDouble:
+ is64bit = true;
+ if (X86_FPREG(r_dest)) {
+ opcode = is_array ? kX86MovsdRA : kX86MovsdRM;
+ if (X86_SINGLEREG(r_dest)) {
+ DCHECK(X86_FPREG(r_dest_hi));
+ DCHECK_EQ(r_dest, (r_dest_hi - 1));
+ r_dest = S2d(r_dest, r_dest_hi);
+ }
+ r_dest_hi = r_dest + 1;
+ } else {
+ pair = true;
+ opcode = is_array ? kX86Mov32RA : kX86Mov32RM;
+ }
+ // TODO: double store is to unaligned address
+ DCHECK_EQ((displacement & 0x3), 0);
+ break;
+ case kWord:
+ case kSingle:
+ opcode = is_array ? kX86Mov32RA : kX86Mov32RM;
+ if (X86_FPREG(r_dest)) {
+ opcode = is_array ? kX86MovssRA : kX86MovssRM;
+ DCHECK(X86_SINGLEREG(r_dest));
+ }
+ DCHECK_EQ((displacement & 0x3), 0);
+ break;
+ case kUnsignedHalf:
+ opcode = is_array ? kX86Movzx16RA : kX86Movzx16RM;
+ DCHECK_EQ((displacement & 0x1), 0);
+ break;
+ case kSignedHalf:
+ opcode = is_array ? kX86Movsx16RA : kX86Movsx16RM;
+ DCHECK_EQ((displacement & 0x1), 0);
+ break;
+ case kUnsignedByte:
+ opcode = is_array ? kX86Movzx8RA : kX86Movzx8RM;
+ break;
+ case kSignedByte:
+ opcode = is_array ? kX86Movsx8RA : kX86Movsx8RM;
+ break;
+ default:
+ LOG(FATAL) << "Bad case in LoadBaseIndexedDispBody";
+ }
+
+ if (!is_array) {
+ if (!pair) {
+ load = NewLIR3(opcode, r_dest, rBase, displacement + LOWORD_OFFSET);
+ } else {
+ if (rBase == r_dest) {
+ load2 = NewLIR3(opcode, r_dest_hi, rBase,
+ displacement + HIWORD_OFFSET);
+ load = NewLIR3(opcode, r_dest, rBase, displacement + LOWORD_OFFSET);
+ } else {
+ load = NewLIR3(opcode, r_dest, rBase, displacement + LOWORD_OFFSET);
+ load2 = NewLIR3(opcode, r_dest_hi, rBase,
+ displacement + HIWORD_OFFSET);
+ }
+ }
+ if (rBase == rX86_SP) {
+ AnnotateDalvikRegAccess(load, (displacement + (pair ? LOWORD_OFFSET : 0)) >> 2,
+ true /* is_load */, is64bit);
+ if (pair) {
+ AnnotateDalvikRegAccess(load2, (displacement + HIWORD_OFFSET) >> 2,
+ true /* is_load */, is64bit);
+ }
+ }
+ } else {
+ if (!pair) {
+ load = NewLIR5(opcode, r_dest, rBase, r_index, scale,
+ displacement + LOWORD_OFFSET);
+ } else {
+ if (rBase == r_dest) {
+ load2 = NewLIR5(opcode, r_dest_hi, rBase, r_index, scale,
+ displacement + HIWORD_OFFSET);
+ load = NewLIR5(opcode, r_dest, rBase, r_index, scale,
+ displacement + LOWORD_OFFSET);
+ } else {
+ load = NewLIR5(opcode, r_dest, rBase, r_index, scale,
+ displacement + LOWORD_OFFSET);
+ load2 = NewLIR5(opcode, r_dest_hi, rBase, r_index, scale,
+ displacement + HIWORD_OFFSET);
+ }
+ }
+ }
+
+ return load;
+}
+
+/* Load value from base + scaled index. */
+LIR* X86Mir2Lir::LoadBaseIndexed(int rBase,
+ int r_index, int r_dest, int scale, OpSize size) {
+ return LoadBaseIndexedDisp(rBase, r_index, scale, 0,
+ r_dest, INVALID_REG, size, INVALID_SREG);
+}
+
+LIR* X86Mir2Lir::LoadBaseDisp(int rBase, int displacement,
+ int r_dest, OpSize size, int s_reg) {
+ return LoadBaseIndexedDisp(rBase, INVALID_REG, 0, displacement,
+ r_dest, INVALID_REG, size, s_reg);
+}
+
+LIR* X86Mir2Lir::LoadBaseDispWide(int rBase, int displacement,
+ int r_dest_lo, int r_dest_hi, int s_reg) {
+ return LoadBaseIndexedDisp(rBase, INVALID_REG, 0, displacement,
+ r_dest_lo, r_dest_hi, kLong, s_reg);
+}
+
+LIR* X86Mir2Lir::StoreBaseIndexedDisp(int rBase, int r_index, int scale,
+ int displacement, int r_src, int r_src_hi, OpSize size,
+ int s_reg) {
+ LIR *store = NULL;
+ LIR *store2 = NULL;
+ bool is_array = r_index != INVALID_REG;
+ bool pair = false;
+ bool is64bit = false;
+ X86OpCode opcode = kX86Nop;
+ switch (size) {
+ case kLong:
+ case kDouble:
+ is64bit = true;
+ if (X86_FPREG(r_src)) {
+ opcode = is_array ? kX86MovsdAR : kX86MovsdMR;
+ if (X86_SINGLEREG(r_src)) {
+ DCHECK(X86_FPREG(r_src_hi));
+ DCHECK_EQ(r_src, (r_src_hi - 1));
+ r_src = S2d(r_src, r_src_hi);
+ }
+ r_src_hi = r_src + 1;
+ } else {
+ pair = true;
+ opcode = is_array ? kX86Mov32AR : kX86Mov32MR;
+ }
+ // TODO: double store is to unaligned address
+ DCHECK_EQ((displacement & 0x3), 0);
+ break;
+ case kWord:
+ case kSingle:
+ opcode = is_array ? kX86Mov32AR : kX86Mov32MR;
+ if (X86_FPREG(r_src)) {
+ opcode = is_array ? kX86MovssAR : kX86MovssMR;
+ DCHECK(X86_SINGLEREG(r_src));
+ }
+ DCHECK_EQ((displacement & 0x3), 0);
+ break;
+ case kUnsignedHalf:
+ case kSignedHalf:
+ opcode = is_array ? kX86Mov16AR : kX86Mov16MR;
+ DCHECK_EQ((displacement & 0x1), 0);
+ break;
+ case kUnsignedByte:
+ case kSignedByte:
+ opcode = is_array ? kX86Mov8AR : kX86Mov8MR;
+ break;
+ default:
+ LOG(FATAL) << "Bad case in LoadBaseIndexedDispBody";
+ }
+
+ if (!is_array) {
+ if (!pair) {
+ store = NewLIR3(opcode, rBase, displacement + LOWORD_OFFSET, r_src);
+ } else {
+ store = NewLIR3(opcode, rBase, displacement + LOWORD_OFFSET, r_src);
+ store2 = NewLIR3(opcode, rBase, displacement + HIWORD_OFFSET, r_src_hi);
+ }
+ if (rBase == rX86_SP) {
+ AnnotateDalvikRegAccess(store, (displacement + (pair ? LOWORD_OFFSET : 0)) >> 2,
+ false /* is_load */, is64bit);
+ if (pair) {
+ AnnotateDalvikRegAccess(store2, (displacement + HIWORD_OFFSET) >> 2,
+ false /* is_load */, is64bit);
+ }
+ }
+ } else {
+ if (!pair) {
+ store = NewLIR5(opcode, rBase, r_index, scale,
+ displacement + LOWORD_OFFSET, r_src);
+ } else {
+ store = NewLIR5(opcode, rBase, r_index, scale,
+ displacement + LOWORD_OFFSET, r_src);
+ store2 = NewLIR5(opcode, rBase, r_index, scale,
+ displacement + HIWORD_OFFSET, r_src_hi);
+ }
+ }
+
+ return store;
+}
+
+/* store value base base + scaled index. */
+LIR* X86Mir2Lir::StoreBaseIndexed(int rBase, int r_index, int r_src,
+ int scale, OpSize size)
+{
+ return StoreBaseIndexedDisp(rBase, r_index, scale, 0,
+ r_src, INVALID_REG, size, INVALID_SREG);
+}
+
+LIR* X86Mir2Lir::StoreBaseDisp(int rBase, int displacement,
+ int r_src, OpSize size)
+{
+ return StoreBaseIndexedDisp(rBase, INVALID_REG, 0,
+ displacement, r_src, INVALID_REG, size,
+ INVALID_SREG);
+}
+
+LIR* X86Mir2Lir::StoreBaseDispWide(int rBase, int displacement,
+ int r_src_lo, int r_src_hi)
+{
+ return StoreBaseIndexedDisp(rBase, INVALID_REG, 0, displacement,
+ r_src_lo, r_src_hi, kLong, INVALID_SREG);
+}
+
+} // namespace art