Blame - compiler/dex/quick/gen_invoke.cc - platform_art

2013-07-12 13:46:57 -0700

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/*

*

* Licensed under the Apache License, Version 2.0 (the "License");

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* you may not use this file except in compliance with the License.

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* You may obtain a copy of the License at

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*

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* http://www.apache.org/licenses/LICENSE-2.0

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*

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* Unless required by applicable law or agreed to in writing, software

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* distributed under the License is distributed on an "AS IS" BASIS,

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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

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* See the License for the specific language governing permissions and

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* limitations under the License.

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*/

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#include "dex/compiler_ir.h"

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#include "dex/frontend.h"

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#include "dex/quick/dex_file_method_inliner.h"

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#include "dex/quick/dex_file_to_method_inliner_map.h"

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#include "dex_file-inl.h"

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#include "entrypoints/quick/quick_entrypoints.h"

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#include "invoke_type.h"

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#include "mirror/array.h"

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#include "mirror/string.h"

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#include "mir_to_lir-inl.h"

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#include "x86/codegen_x86.h"

namespace art {

/*

* This source files contains "gen" codegen routines that should

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* be applicable to most targets. Only mid-level support utilities

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* and "op" calls may be used here.

*/

/*

* To save scheduling time, helper calls are broken into two parts: generation of

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* the helper target address, and the actuall call to the helper. Because x86

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* has a memory call operation, part 1 is a NOP for x86. For other targets,

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* load arguments between the two parts.

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*/

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int Mir2Lir::CallHelperSetup(ThreadOffset helper_offset) {

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return (cu_->instruction_set == kX86) ? 0 : LoadHelper(helper_offset);

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}

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/* NOTE: if r_tgt is a temp, it will be freed following use */

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LIR* Mir2Lir::CallHelper(int r_tgt, ThreadOffset helper_offset, bool safepoint_pc) {

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LIR* call_inst;

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if (cu_->instruction_set == kX86) {

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call_inst = OpThreadMem(kOpBlx, helper_offset);

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} else {

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call_inst = OpReg(kOpBlx, r_tgt);

FreeTemp(r_tgt);

}

if (safepoint_pc) {

MarkSafepointPC(call_inst);

}

return call_inst;

}

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void Mir2Lir::CallRuntimeHelperImm(ThreadOffset helper_offset, int arg0, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Ian Rogers

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void Mir2Lir::CallRuntimeHelperReg(ThreadOffset helper_offset, int arg0, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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OpRegCopy(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Ian Rogers

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void Mir2Lir::CallRuntimeHelperRegLocation(ThreadOffset helper_offset, RegLocation arg0,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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if (arg0.wide == 0) {

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LoadValueDirectFixed(arg0, TargetReg(kArg0));

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} else {

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LoadValueDirectWideFixed(arg0, TargetReg(kArg0), TargetReg(kArg1));

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}

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Ian Rogers

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void Mir2Lir::CallRuntimeHelperImmImm(ThreadOffset helper_offset, int arg0, int arg1,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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LoadConstant(TargetReg(kArg0), arg0);

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LoadConstant(TargetReg(kArg1), arg1);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Ian Rogers

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void Mir2Lir::CallRuntimeHelperImmRegLocation(ThreadOffset helper_offset, int arg0,

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RegLocation arg1, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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if (arg1.wide == 0) {

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LoadValueDirectFixed(arg1, TargetReg(kArg1));

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} else {

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LoadValueDirectWideFixed(arg1, TargetReg(kArg1), TargetReg(kArg2));

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}

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperRegLocationImm(ThreadOffset helper_offset, RegLocation arg0, int arg1,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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LoadValueDirectFixed(arg0, TargetReg(kArg0));

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LoadConstant(TargetReg(kArg1), arg1);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperImmReg(ThreadOffset helper_offset, int arg0, int arg1,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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OpRegCopy(TargetReg(kArg1), arg1);

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperRegImm(ThreadOffset helper_offset, int arg0, int arg1,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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OpRegCopy(TargetReg(kArg0), arg0);

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LoadConstant(TargetReg(kArg1), arg1);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperImmMethod(ThreadOffset helper_offset, int arg0, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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LoadCurrMethodDirect(TargetReg(kArg1));

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Hiroshi Yamauchi

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void Mir2Lir::CallRuntimeHelperRegMethod(ThreadOffset helper_offset, int arg0, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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DCHECK_NE(TargetReg(kArg1), arg0);

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if (TargetReg(kArg0) != arg0) {

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OpRegCopy(TargetReg(kArg0), arg0);

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}

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LoadCurrMethodDirect(TargetReg(kArg1));

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Hiroshi Yamauchi

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void Mir2Lir::CallRuntimeHelperRegMethodRegLocation(ThreadOffset helper_offset, int arg0,

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RegLocation arg2, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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DCHECK_NE(TargetReg(kArg1), arg0);

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if (TargetReg(kArg0) != arg0) {

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OpRegCopy(TargetReg(kArg0), arg0);

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}

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LoadCurrMethodDirect(TargetReg(kArg1));

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LoadValueDirectFixed(arg2, TargetReg(kArg2));

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperRegLocationRegLocation(ThreadOffset helper_offset, RegLocation arg0,

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RegLocation arg1, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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if (arg0.wide == 0) {

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LoadValueDirectFixed(arg0, arg0.fp ? TargetReg(kFArg0) : TargetReg(kArg0));

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if (arg1.wide == 0) {

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if (cu_->instruction_set == kMips) {

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LoadValueDirectFixed(arg1, arg1.fp ? TargetReg(kFArg2) : TargetReg(kArg1));

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} else {

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LoadValueDirectFixed(arg1, TargetReg(kArg1));

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}

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} else {

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if (cu_->instruction_set == kMips) {

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LoadValueDirectWideFixed(arg1, arg1.fp ? TargetReg(kFArg2) : TargetReg(kArg1), arg1.fp ? TargetReg(kFArg3) : TargetReg(kArg2));

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} else {

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LoadValueDirectWideFixed(arg1, TargetReg(kArg1), TargetReg(kArg2));

}

}

} else {

LoadValueDirectWideFixed(arg0, arg0.fp ? TargetReg(kFArg0) : TargetReg(kArg0), arg0.fp ? TargetReg(kFArg1) : TargetReg(kArg1));

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if (arg1.wide == 0) {

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LoadValueDirectFixed(arg1, arg1.fp ? TargetReg(kFArg2) : TargetReg(kArg2));

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} else {

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LoadValueDirectWideFixed(arg1, arg1.fp ? TargetReg(kFArg2) : TargetReg(kArg2), arg1.fp ? TargetReg(kFArg3) : TargetReg(kArg3));

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}

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}

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperRegReg(ThreadOffset helper_offset, int arg0, int arg1,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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DCHECK_NE(TargetReg(kArg0), arg1); // check copy into arg0 won't clobber arg1

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OpRegCopy(TargetReg(kArg0), arg0);

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OpRegCopy(TargetReg(kArg1), arg1);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperRegRegImm(ThreadOffset helper_offset, int arg0, int arg1,

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int arg2, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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DCHECK_NE(TargetReg(kArg0), arg1); // check copy into arg0 won't clobber arg1

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OpRegCopy(TargetReg(kArg0), arg0);

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OpRegCopy(TargetReg(kArg1), arg1);

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LoadConstant(TargetReg(kArg2), arg2);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperImmMethodRegLocation(ThreadOffset helper_offset,

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int arg0, RegLocation arg2, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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LoadValueDirectFixed(arg2, TargetReg(kArg2));

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LoadCurrMethodDirect(TargetReg(kArg1));

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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void Mir2Lir::CallRuntimeHelperImmMethodImm(ThreadOffset helper_offset, int arg0,

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int arg2, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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LoadCurrMethodDirect(TargetReg(kArg1));

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LoadConstant(TargetReg(kArg2), arg2);

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Ian Rogers

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void Mir2Lir::CallRuntimeHelperImmRegLocationRegLocation(ThreadOffset helper_offset,

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int arg0, RegLocation arg1,

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RegLocation arg2, bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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DCHECK_EQ(arg1.wide, 0U);

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LoadValueDirectFixed(arg1, TargetReg(kArg1));

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if (arg2.wide == 0) {

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LoadValueDirectFixed(arg2, TargetReg(kArg2));

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} else {

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LoadValueDirectWideFixed(arg2, TargetReg(kArg2), TargetReg(kArg3));

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}

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LoadConstant(TargetReg(kArg0), arg0);

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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Ian Rogers

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void Mir2Lir::CallRuntimeHelperRegLocationRegLocationRegLocation(ThreadOffset helper_offset,

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RegLocation arg0, RegLocation arg1,

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RegLocation arg2,

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bool safepoint_pc) {

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int r_tgt = CallHelperSetup(helper_offset);

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DCHECK_EQ(arg0.wide, 0U);

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LoadValueDirectFixed(arg0, TargetReg(kArg0));

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DCHECK_EQ(arg1.wide, 0U);

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LoadValueDirectFixed(arg1, TargetReg(kArg1));

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DCHECK_EQ(arg1.wide, 0U);

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LoadValueDirectFixed(arg2, TargetReg(kArg2));

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ClobberCallerSave();

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CallHelper(r_tgt, helper_offset, safepoint_pc);

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}

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/*

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* If there are any ins passed in registers that have not been promoted

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* to a callee-save register, flush them to the frame. Perform intial

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* assignment of promoted arguments.

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*

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* ArgLocs is an array of location records describing the incoming arguments

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* with one location record per word of argument.

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*/

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void Mir2Lir::FlushIns(RegLocation* ArgLocs, RegLocation rl_method) {

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/*

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* Dummy up a RegLocation for the incoming Method*

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* It will attempt to keep kArg0 live (or copy it to home location

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* if promoted).

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*/

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RegLocation rl_src = rl_method;

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rl_src.location = kLocPhysReg;

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rl_src.low_reg = TargetReg(kArg0);

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rl_src.home = false;

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MarkLive(rl_src.low_reg, rl_src.s_reg_low);

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StoreValue(rl_method, rl_src);

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// If Method* has been promoted, explicitly flush

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if (rl_method.location == kLocPhysReg) {

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StoreWordDisp(TargetReg(kSp), 0, TargetReg(kArg0));

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}

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if (cu_->num_ins == 0)

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return;

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const int num_arg_regs = 3;

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static SpecialTargetRegister arg_regs[] = {kArg1, kArg2, kArg3};

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int start_vreg = cu_->num_dalvik_registers - cu_->num_ins;

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/*

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* Copy incoming arguments to their proper home locations.

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* NOTE: an older version of dx had an issue in which

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* it would reuse static method argument registers.

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* This could result in the same Dalvik virtual register

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* being promoted to both core and fp regs. To account for this,

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* we only copy to the corresponding promoted physical register

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* if it matches the type of the SSA name for the incoming

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* argument. It is also possible that long and double arguments

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* end up half-promoted. In those cases, we must flush the promoted

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* half to memory as well.

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*/

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for (int i = 0; i < cu_->num_ins; i++) {

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PromotionMap* v_map = &promotion_map_[start_vreg + i];

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if (i < num_arg_regs) {

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// If arriving in register

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bool need_flush = true;

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RegLocation* t_loc = &ArgLocs[i];

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if ((v_map->core_location == kLocPhysReg) && !t_loc->fp) {

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OpRegCopy(v_map->core_reg, TargetReg(arg_regs[i]));

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need_flush = false;

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} else if ((v_map->fp_location == kLocPhysReg) && t_loc->fp) {

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OpRegCopy(v_map->FpReg, TargetReg(arg_regs[i]));

need_flush = false;

} else {

need_flush = true;

}

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2013-09-14 08:21:05 -0700

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// For wide args, force flush if not fully promoted

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if (t_loc->wide) {

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PromotionMap* p_map = v_map + (t_loc->high_word ? -1 : +1);

buzbee

d0a03b8

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// Is only half promoted?

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need_flush |= (p_map->core_location != v_map->core_location) ||

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(p_map->fp_location != v_map->fp_location);

buzbee

d0a03b8

2013-09-14 08:21:05 -0700

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if ((cu_->instruction_set == kThumb2) && t_loc->fp && !need_flush) {

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/*

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* In Arm, a double is represented as a pair of consecutive single float

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* registers starting at an even number. It's possible that both Dalvik vRegs

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* representing the incoming double were independently promoted as singles - but

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* not in a form usable as a double. If so, we need to flush - even though the

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* incoming arg appears fully in register. At this point in the code, both

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* halves of the double are promoted. Make sure they are in a usable form.

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*/

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int lowreg_index = start_vreg + i + (t_loc->high_word ? -1 : 0);

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int low_reg = promotion_map_[lowreg_index].FpReg;

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int high_reg = promotion_map_[lowreg_index + 1].FpReg;

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if (((low_reg & 0x1) != 0) || (high_reg != (low_reg + 1))) {

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need_flush = true;

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}

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}

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}

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if (need_flush) {

353

StoreBaseDisp(TargetReg(kSp), SRegOffset(start_vreg + i),

354

TargetReg(arg_regs[i]), kWord);

355

}

356

} else {

357

// If arriving in frame & promoted

358

if (v_map->core_location == kLocPhysReg) {

359

LoadWordDisp(TargetReg(kSp), SRegOffset(start_vreg + i),

360

v_map->core_reg);

361

}

362

if (v_map->fp_location == kLocPhysReg) {

363

LoadWordDisp(TargetReg(kSp), SRegOffset(start_vreg + i),

v_map->FpReg);

}

}

}

}

/*

* Bit of a hack here - in the absence of a real scheduling pass,

372

* emit the next instruction in static & direct invoke sequences.

373

*/

374

static int NextSDCallInsn(CompilationUnit* cu, CallInfo* info,

375

int state, const MethodReference& target_method,

376

uint32_t unused,

377

uintptr_t direct_code, uintptr_t direct_method,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

378

InvokeType type) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

379

Mir2Lir* cg = static_cast<Mir2Lir*>(cu->cg.get());

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

380

if (direct_code != 0 && direct_method != 0) {

381

switch (state) {

382

case 0: // Get the current Method* [sets kArg0]

383

if (direct_code != static_cast<unsigned int>(-1)) {

Ian Rogers

83883d7

2013-10-21 21:07:24 -0700

[diff] [blame]

384

if (cu->instruction_set != kX86) {

385

cg->LoadConstant(cg->TargetReg(kInvokeTgt), direct_code);

386

}

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

387

} else if (cu->instruction_set != kX86) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

388

CHECK_EQ(cu->dex_file, target_method.dex_file);

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

389

cg->LoadCodeAddress(target_method.dex_method_index, type, kInvokeTgt);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

390

}

391

if (direct_method != static_cast<unsigned int>(-1)) {

392

cg->LoadConstant(cg->TargetReg(kArg0), direct_method);

393

} else {

394

CHECK_EQ(cu->dex_file, target_method.dex_file);

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

395

cg->LoadMethodAddress(target_method.dex_method_index, type, kArg0);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

}

break;

default:

return -1;

}

} else {

switch (state) {

case 0: // Get the current Method* [sets kArg0]

404

// TUNING: we can save a reg copy if Method* has been promoted.

405

cg->LoadCurrMethodDirect(cg->TargetReg(kArg0));

406

break;

407

case 1: // Get method->dex_cache_resolved_methods_

408

cg->LoadWordDisp(cg->TargetReg(kArg0),

Brian Carlstrom

ea46f95

2013-07-30 01:26:50 -0700

[diff] [blame]

409

mirror::ArtMethod::DexCacheResolvedMethodsOffset().Int32Value(), cg->TargetReg(kArg0));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

410

// Set up direct code if known.

411

if (direct_code != 0) {

412

if (direct_code != static_cast<unsigned int>(-1)) {

413

cg->LoadConstant(cg->TargetReg(kInvokeTgt), direct_code);

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

414

} else if (cu->instruction_set != kX86) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

415

CHECK_EQ(cu->dex_file, target_method.dex_file);

Ian Rogers

83883d7

2013-10-21 21:07:24 -0700

[diff] [blame]

416

CHECK_LT(target_method.dex_method_index, target_method.dex_file->NumMethodIds());

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

417

cg->LoadCodeAddress(target_method.dex_method_index, type, kInvokeTgt);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

}

}

break;

case 2: // Grab target method*

422

CHECK_EQ(cu->dex_file, target_method.dex_file);

423

cg->LoadWordDisp(cg->TargetReg(kArg0),

424

mirror::Array::DataOffset(sizeof(mirror::Object*)).Int32Value() +

425

(target_method.dex_method_index * 4),

426

cg-> TargetReg(kArg0));

427

break;

428

case 3: // Grab the code from the method*

429

if (cu->instruction_set != kX86) {

430

if (direct_code == 0) {

431

cg->LoadWordDisp(cg->TargetReg(kArg0),

Ian Rogers

ef7d42f

2014-01-06 12:55:46 -0800

[diff] [blame]

432

mirror::ArtMethod::EntryPointFromQuickCompiledCodeOffset().Int32Value(),

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

433

cg->TargetReg(kInvokeTgt));

}

break;

}

// Intentional fallthrough for x86

default:

return -1;

}

}

return state + 1;

}

/*

* Bit of a hack here - in the absence of a real scheduling pass,

447

* emit the next instruction in a virtual invoke sequence.

448

* We can use kLr as a temp prior to target address loading

449

* Note also that we'll load the first argument ("this") into

450

* kArg1 here rather than the standard LoadArgRegs.

451

*/

452

static int NextVCallInsn(CompilationUnit* cu, CallInfo* info,

453

int state, const MethodReference& target_method,

454

uint32_t method_idx, uintptr_t unused, uintptr_t unused2,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

455

InvokeType unused3) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

456

Mir2Lir* cg = static_cast<Mir2Lir*>(cu->cg.get());

457

/*

458

* This is the fast path in which the target virtual method is

459

* fully resolved at compile time.

460

*/

461

switch (state) {

462

case 0: { // Get "this" [set kArg1]

463

RegLocation rl_arg = info->args[0];

464

cg->LoadValueDirectFixed(rl_arg, cg->TargetReg(kArg1));

465

break;

466

}

Brian Carlstrom

2013-07-26 10:54:15 -0700

[diff] [blame]

467

case 1: // Is "this" null? [use kArg1]

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

468

cg->GenNullCheck(info->args[0].s_reg_low, cg->TargetReg(kArg1), info->opt_flags);

469

// get this->klass_ [use kArg1, set kInvokeTgt]

470

cg->LoadWordDisp(cg->TargetReg(kArg1), mirror::Object::ClassOffset().Int32Value(),

471

cg->TargetReg(kInvokeTgt));

472

break;

Brian Carlstrom

2013-07-26 10:54:15 -0700

[diff] [blame]

473

case 2: // Get this->klass_->vtable [usr kInvokeTgt, set kInvokeTgt]

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

474

cg->LoadWordDisp(cg->TargetReg(kInvokeTgt), mirror::Class::VTableOffset().Int32Value(),

475

cg->TargetReg(kInvokeTgt));

476

break;

Brian Carlstrom

2013-07-26 10:54:15 -0700

[diff] [blame]

477

case 3: // Get target method [use kInvokeTgt, set kArg0]

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

478

cg->LoadWordDisp(cg->TargetReg(kInvokeTgt), (method_idx * 4) +

479

mirror::Array::DataOffset(sizeof(mirror::Object*)).Int32Value(),

480

cg->TargetReg(kArg0));

481

break;

Brian Carlstrom

2013-07-26 10:54:15 -0700

[diff] [blame]

482

case 4: // Get the compiled code address [uses kArg0, sets kInvokeTgt]

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

483

if (cu->instruction_set != kX86) {

484

cg->LoadWordDisp(cg->TargetReg(kArg0),

Ian Rogers

ef7d42f

2014-01-06 12:55:46 -0800

[diff] [blame]

485

mirror::ArtMethod::EntryPointFromQuickCompiledCodeOffset().Int32Value(),

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

486

cg->TargetReg(kInvokeTgt));

487

break;

488

}

489

// Intentional fallthrough for X86

default:

return -1;

}

return state + 1;

}

/*

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

497

* Emit the next instruction in an invoke interface sequence. This will do a lookup in the

498

* class's IMT, calling either the actual method or art_quick_imt_conflict_trampoline if

499

* more than one interface method map to the same index. Note also that we'll load the first

500

* argument ("this") into kArg1 here rather than the standard LoadArgRegs.

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

501

*/

502

static int NextInterfaceCallInsn(CompilationUnit* cu, CallInfo* info, int state,

503

const MethodReference& target_method,

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

504

uint32_t method_idx, uintptr_t unused,

505

uintptr_t direct_method, InvokeType unused2) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

506

Mir2Lir* cg = static_cast<Mir2Lir*>(cu->cg.get());

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

507

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

508

switch (state) {

509

case 0: // Set target method index in case of conflict [set kHiddenArg, kHiddenFpArg (x86)]

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

510

CHECK_EQ(cu->dex_file, target_method.dex_file);

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

511

CHECK_LT(target_method.dex_method_index, target_method.dex_file->NumMethodIds());

512

cg->LoadConstant(cg->TargetReg(kHiddenArg), target_method.dex_method_index);

513

if (cu->instruction_set == kX86) {

514

cg->OpRegCopy(cg->TargetReg(kHiddenFpArg), cg->TargetReg(kHiddenArg));

515

}

516

break;

517

case 1: { // Get "this" [set kArg1]

518

RegLocation rl_arg = info->args[0];

519

cg->LoadValueDirectFixed(rl_arg, cg->TargetReg(kArg1));

520

break;

521

}

522

case 2: // Is "this" null? [use kArg1]

523

cg->GenNullCheck(info->args[0].s_reg_low, cg->TargetReg(kArg1), info->opt_flags);

524

// Get this->klass_ [use kArg1, set kInvokeTgt]

525

cg->LoadWordDisp(cg->TargetReg(kArg1), mirror::Object::ClassOffset().Int32Value(),

526

cg->TargetReg(kInvokeTgt));

527

break;

528

case 3: // Get this->klass_->imtable [use kInvokeTgt, set kInvokeTgt]

529

cg->LoadWordDisp(cg->TargetReg(kInvokeTgt), mirror::Class::ImTableOffset().Int32Value(),

530

cg->TargetReg(kInvokeTgt));

531

break;

532

case 4: // Get target method [use kInvokeTgt, set kArg0]

533

cg->LoadWordDisp(cg->TargetReg(kInvokeTgt), ((method_idx % ClassLinker::kImtSize) * 4) +

534

mirror::Array::DataOffset(sizeof(mirror::Object*)).Int32Value(),

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

535

cg->TargetReg(kArg0));

536

break;

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

537

case 5: // Get the compiled code address [use kArg0, set kInvokeTgt]

538

if (cu->instruction_set != kX86) {

539

cg->LoadWordDisp(cg->TargetReg(kArg0),

Ian Rogers

ef7d42f

2014-01-06 12:55:46 -0800

[diff] [blame]

540

mirror::ArtMethod::EntryPointFromQuickCompiledCodeOffset().Int32Value(),

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

541

cg->TargetReg(kInvokeTgt));

542

break;

543

}

544

// Intentional fallthrough for X86

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

545

default:

546

return -1;

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

}

return state + 1;

}

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

551

static int NextInvokeInsnSP(CompilationUnit* cu, CallInfo* info, ThreadOffset trampoline,

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

552

int state, const MethodReference& target_method,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

553

uint32_t method_idx) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

554

Mir2Lir* cg = static_cast<Mir2Lir*>(cu->cg.get());

555

/*

556

* This handles the case in which the base method is not fully

557

* resolved at compile time, we bail to a runtime helper.

558

*/

559

if (state == 0) {

560

if (cu->instruction_set != kX86) {

561

// Load trampoline target

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

562

cg->LoadWordDisp(cg->TargetReg(kSelf), trampoline.Int32Value(), cg->TargetReg(kInvokeTgt));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

563

}

564

// Load kArg0 with method index

565

CHECK_EQ(cu->dex_file, target_method.dex_file);

566

cg->LoadConstant(cg->TargetReg(kArg0), target_method.dex_method_index);

return 1;

}

return -1;

}

static int NextStaticCallInsnSP(CompilationUnit* cu, CallInfo* info,

573

int state,

574

const MethodReference& target_method,

575

uint32_t method_idx,

576

uintptr_t unused, uintptr_t unused2,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

577

InvokeType unused3) {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

578

ThreadOffset trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeStaticTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

579

return NextInvokeInsnSP(cu, info, trampoline, state, target_method, 0);

580

}

581

582

static int NextDirectCallInsnSP(CompilationUnit* cu, CallInfo* info, int state,

583

const MethodReference& target_method,

584

uint32_t method_idx, uintptr_t unused,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

585

uintptr_t unused2, InvokeType unused3) {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

586

ThreadOffset trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeDirectTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

587

return NextInvokeInsnSP(cu, info, trampoline, state, target_method, 0);

588

}

589

590

static int NextSuperCallInsnSP(CompilationUnit* cu, CallInfo* info, int state,

591

const MethodReference& target_method,

592

uint32_t method_idx, uintptr_t unused,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

593

uintptr_t unused2, InvokeType unused3) {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

594

ThreadOffset trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeSuperTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

595

return NextInvokeInsnSP(cu, info, trampoline, state, target_method, 0);

596

}

597

598

static int NextVCallInsnSP(CompilationUnit* cu, CallInfo* info, int state,

599

const MethodReference& target_method,

600

uint32_t method_idx, uintptr_t unused,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

601

uintptr_t unused2, InvokeType unused3) {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

602

ThreadOffset trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeVirtualTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

603

return NextInvokeInsnSP(cu, info, trampoline, state, target_method, 0);

604

}

605

606

static int NextInterfaceCallInsnWithAccessCheck(CompilationUnit* cu,

607

CallInfo* info, int state,

608

const MethodReference& target_method,

609

uint32_t unused,

610

uintptr_t unused2, uintptr_t unused3,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

611

InvokeType unused4) {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

612

ThreadOffset trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeInterfaceTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

613

return NextInvokeInsnSP(cu, info, trampoline, state, target_method, 0);

614

}

615

616

int Mir2Lir::LoadArgRegs(CallInfo* info, int call_state,

617

NextCallInsn next_call_insn,

618

const MethodReference& target_method,

619

uint32_t vtable_idx, uintptr_t direct_code,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

620

uintptr_t direct_method, InvokeType type, bool skip_this) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

621

int last_arg_reg = TargetReg(kArg3);

622

int next_reg = TargetReg(kArg1);

int next_arg = 0;

if (skip_this) {

next_reg++;

next_arg++;

}

for (; (next_reg <= last_arg_reg) && (next_arg < info->num_arg_words); next_reg++) {

629

RegLocation rl_arg = info->args[next_arg++];

630

rl_arg = UpdateRawLoc(rl_arg);

631

if (rl_arg.wide && (next_reg <= TargetReg(kArg2))) {

632

LoadValueDirectWideFixed(rl_arg, next_reg, next_reg + 1);

next_reg++;

next_arg++;

} else {

if (rl_arg.wide) {

rl_arg.wide = false;

rl_arg.is_const = false;

639

}

640

LoadValueDirectFixed(rl_arg, next_reg);

641

}

642

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

643

direct_code, direct_method, type);

}

return call_state;

}

/*

* Load up to 5 arguments, the first three of which will be in

650

* kArg1 .. kArg3. On entry kArg0 contains the current method pointer,

651

* and as part of the load sequence, it must be replaced with

652

* the target method pointer. Note, this may also be called

653

* for "range" variants if the number of arguments is 5 or fewer.

654

*/

655

int Mir2Lir::GenDalvikArgsNoRange(CallInfo* info,

656

int call_state, LIR** pcrLabel, NextCallInsn next_call_insn,

657

const MethodReference& target_method,

658

uint32_t vtable_idx, uintptr_t direct_code,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

659

uintptr_t direct_method, InvokeType type, bool skip_this) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

660

RegLocation rl_arg;

661

662

/* If no arguments, just return */

663

if (info->num_arg_words == 0)

664

return call_state;

665

666

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

667

direct_code, direct_method, type);

668

669

DCHECK_LE(info->num_arg_words, 5);

670

if (info->num_arg_words > 3) {

671

int32_t next_use = 3;

Brian Carlstrom

2013-07-26 10:54:15 -0700

[diff] [blame]

672

// Detect special case of wide arg spanning arg3/arg4

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

673

RegLocation rl_use0 = info->args[0];

674

RegLocation rl_use1 = info->args[1];

675

RegLocation rl_use2 = info->args[2];

676

if (((!rl_use0.wide && !rl_use1.wide) || rl_use0.wide) &&

677

rl_use2.wide) {

678

int reg = -1;

679

// Wide spans, we need the 2nd half of uses[2].

680

rl_arg = UpdateLocWide(rl_use2);

681

if (rl_arg.location == kLocPhysReg) {

682

reg = rl_arg.high_reg;

683

} else {

684

// kArg2 & rArg3 can safely be used here

685

reg = TargetReg(kArg3);

686

LoadWordDisp(TargetReg(kSp), SRegOffset(rl_arg.s_reg_low) + 4, reg);

687

call_state = next_call_insn(cu_, info, call_state, target_method,

688

vtable_idx, direct_code, direct_method, type);

689

}

690

StoreBaseDisp(TargetReg(kSp), (next_use + 1) * 4, reg, kWord);

691

StoreBaseDisp(TargetReg(kSp), 16 /* (3+1)*4 */, reg, kWord);

692

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

693

direct_code, direct_method, type);

694

next_use++;

695

}

696

// Loop through the rest

697

while (next_use < info->num_arg_words) {

698

int low_reg;

699

int high_reg = -1;

700

rl_arg = info->args[next_use];

701

rl_arg = UpdateRawLoc(rl_arg);

702

if (rl_arg.location == kLocPhysReg) {

703

low_reg = rl_arg.low_reg;

704

high_reg = rl_arg.high_reg;

705

} else {

706

low_reg = TargetReg(kArg2);

707

if (rl_arg.wide) {

708

high_reg = TargetReg(kArg3);

709

LoadValueDirectWideFixed(rl_arg, low_reg, high_reg);

710

} else {

711

LoadValueDirectFixed(rl_arg, low_reg);

712

}

713

call_state = next_call_insn(cu_, info, call_state, target_method,

714

vtable_idx, direct_code, direct_method, type);

715

}

716

int outs_offset = (next_use + 1) * 4;

717

if (rl_arg.wide) {

718

StoreBaseDispWide(TargetReg(kSp), outs_offset, low_reg, high_reg);

719

next_use += 2;

720

} else {

721

StoreWordDisp(TargetReg(kSp), outs_offset, low_reg);

722

next_use++;

723

}

724

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

725

direct_code, direct_method, type);

}

}

call_state = LoadArgRegs(info, call_state, next_call_insn,

730

target_method, vtable_idx, direct_code, direct_method,

type, skip_this);

if (pcrLabel) {

*pcrLabel = GenNullCheck(info->args[0].s_reg_low, TargetReg(kArg1), info->opt_flags);

}

return call_state;

}

/*

* May have 0+ arguments (also used for jumbo). Note that

741

* source virtual registers may be in physical registers, so may

742

* need to be flushed to home location before copying. This

743

* applies to arg3 and above (see below).

744

*

745

* Two general strategies:

746

* If < 20 arguments

747

* Pass args 3-18 using vldm/vstm block copy

748

* Pass arg0, arg1 & arg2 in kArg1-kArg3

749

* If 20+ arguments

750

* Pass args arg19+ using memcpy block copy

751

* Pass arg0, arg1 & arg2 in kArg1-kArg3

752

*

753

*/

754

int Mir2Lir::GenDalvikArgsRange(CallInfo* info, int call_state,

755

LIR** pcrLabel, NextCallInsn next_call_insn,

756

const MethodReference& target_method,

757

uint32_t vtable_idx, uintptr_t direct_code, uintptr_t direct_method,

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

758

InvokeType type, bool skip_this) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

759

// If we can treat it as non-range (Jumbo ops will use range form)

760

if (info->num_arg_words <= 5)

761

return GenDalvikArgsNoRange(info, call_state, pcrLabel,

762

next_call_insn, target_method, vtable_idx,

763

direct_code, direct_method, type, skip_this);

764

/*

765

* First load the non-register arguments. Both forms expect all

766

* of the source arguments to be in their home frame location, so

767

* scan the s_reg names and flush any that have been promoted to

768

* frame backing storage.

769

*/

770

// Scan the rest of the args - if in phys_reg flush to memory

771

for (int next_arg = 0; next_arg < info->num_arg_words;) {

772

RegLocation loc = info->args[next_arg];

773

if (loc.wide) {

774

loc = UpdateLocWide(loc);

775

if ((next_arg >= 2) && (loc.location == kLocPhysReg)) {

776

StoreBaseDispWide(TargetReg(kSp), SRegOffset(loc.s_reg_low),

777

loc.low_reg, loc.high_reg);

}

next_arg += 2;

} else {

loc = UpdateLoc(loc);

782

if ((next_arg >= 3) && (loc.location == kLocPhysReg)) {

783

StoreBaseDisp(TargetReg(kSp), SRegOffset(loc.s_reg_low),

loc.low_reg, kWord);

}

next_arg++;

}

}

Razvan A Lupusoru

2014-01-29 16:02:57 -0800

[diff] [blame]

790

// Logic below assumes that Method pointer is at offset zero from SP.

791

DCHECK_EQ(VRegOffset(static_cast<int>(kVRegMethodPtrBaseReg)), 0);

792

793

// The first 3 arguments are passed via registers.

794

// TODO: For 64-bit, instead of hardcoding 4 for Method* size, we should either

795

// get size of uintptr_t or size of object reference according to model being used.

796

int outs_offset = 4 /* Method* */ + (3 * sizeof(uint32_t));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

797

int start_offset = SRegOffset(info->args[3].s_reg_low);

Razvan A Lupusoru

2c498d1

2014-01-29 16:02:57 -0800

[diff] [blame]

798

int regs_left_to_pass_via_stack = info->num_arg_words - 3;

799

DCHECK_GT(regs_left_to_pass_via_stack, 0);

800

801

if (cu_->instruction_set == kThumb2 && regs_left_to_pass_via_stack <= 16) {

802

// Use vldm/vstm pair using kArg3 as a temp

803

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

804

direct_code, direct_method, type);

805

OpRegRegImm(kOpAdd, TargetReg(kArg3), TargetReg(kSp), start_offset);

806

LIR* ld = OpVldm(TargetReg(kArg3), regs_left_to_pass_via_stack);

807

// TUNING: loosen barrier

808

ld->u.m.def_mask = ENCODE_ALL;

809

SetMemRefType(ld, true /* is_load */, kDalvikReg);

810

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

811

direct_code, direct_method, type);

812

OpRegRegImm(kOpAdd, TargetReg(kArg3), TargetReg(kSp), 4 /* Method* */ + (3 * 4));

813

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

814

direct_code, direct_method, type);

815

LIR* st = OpVstm(TargetReg(kArg3), regs_left_to_pass_via_stack);

816

SetMemRefType(st, false /* is_load */, kDalvikReg);

817

st->u.m.def_mask = ENCODE_ALL;

818

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

819

direct_code, direct_method, type);

820

} else if (cu_->instruction_set == kX86) {

821

int current_src_offset = start_offset;

822

int current_dest_offset = outs_offset;

823

824

while (regs_left_to_pass_via_stack > 0) {

825

// This is based on the knowledge that the stack itself is 16-byte aligned.

826

bool src_is_16b_aligned = (current_src_offset & 0xF) == 0;

827

bool dest_is_16b_aligned = (current_dest_offset & 0xF) == 0;

828

size_t bytes_to_move;

829

830

/*

831

* The amount to move defaults to 32-bit. If there are 4 registers left to move, then do a

832

* a 128-bit move because we won't get the chance to try to aligned. If there are more than

833

* 4 registers left to move, consider doing a 128-bit only if either src or dest are aligned.

834

* We do this because we could potentially do a smaller move to align.

835

*/

836

if (regs_left_to_pass_via_stack == 4 ||

837

(regs_left_to_pass_via_stack > 4 && (src_is_16b_aligned || dest_is_16b_aligned))) {

838

// Moving 128-bits via xmm register.

839

bytes_to_move = sizeof(uint32_t) * 4;

840

841

// Allocate a free xmm temp. Since we are working through the calling sequence,

842

// we expect to have an xmm temporary available.

843

int temp = AllocTempDouble();

CHECK_GT(temp, 0);

LIR* ld1 = nullptr;

LIR* ld2 = nullptr;

LIR* st1 = nullptr;

LIR* st2 = nullptr;

/*

* The logic is similar for both loads and stores. If we have 16-byte alignment,

853

* do an aligned move. If we have 8-byte alignment, then do the move in two

854

* parts. This approach prevents possible cache line splits. Finally, fall back

855

* to doing an unaligned move. In most cases we likely won't split the cache

856

* line but we cannot prove it and thus take a conservative approach.

857

*/

858

bool src_is_8b_aligned = (current_src_offset & 0x7) == 0;

859

bool dest_is_8b_aligned = (current_dest_offset & 0x7) == 0;

860

861

if (src_is_16b_aligned) {

862

ld1 = OpMovRegMem(temp, TargetReg(kSp), current_src_offset, kMovA128FP);

863

} else if (src_is_8b_aligned) {

864

ld1 = OpMovRegMem(temp, TargetReg(kSp), current_src_offset, kMovLo128FP);

865

ld2 = OpMovRegMem(temp, TargetReg(kSp), current_src_offset + (bytes_to_move >> 1), kMovHi128FP);

866

} else {

867

ld1 = OpMovRegMem(temp, TargetReg(kSp), current_src_offset, kMovU128FP);

868

}

869

870

if (dest_is_16b_aligned) {

871

st1 = OpMovMemReg(TargetReg(kSp), current_dest_offset, temp, kMovA128FP);

872

} else if (dest_is_8b_aligned) {

873

st1 = OpMovMemReg(TargetReg(kSp), current_dest_offset, temp, kMovLo128FP);

874

st2 = OpMovMemReg(TargetReg(kSp), current_dest_offset + (bytes_to_move >> 1), temp, kMovHi128FP);

875

} else {

876

st1 = OpMovMemReg(TargetReg(kSp), current_dest_offset, temp, kMovU128FP);

877

}

878

879

// TODO If we could keep track of aliasing information for memory accesses that are wider

880

// than 64-bit, we wouldn't need to set up a barrier.

881

if (ld1 != nullptr) {

882

if (ld2 != nullptr) {

883

// For 64-bit load we can actually set up the aliasing information.

884

AnnotateDalvikRegAccess(ld1, current_src_offset >> 2, true, true);

885

AnnotateDalvikRegAccess(ld2, (current_src_offset + (bytes_to_move >> 1)) >> 2, true, true);

886

} else {

887

// Set barrier for 128-bit load.

888

SetMemRefType(ld1, true /* is_load */, kDalvikReg);

889

ld1->u.m.def_mask = ENCODE_ALL;

890

}

891

}

892

if (st1 != nullptr) {

893

if (st2 != nullptr) {

894

// For 64-bit store we can actually set up the aliasing information.

895

AnnotateDalvikRegAccess(st1, current_dest_offset >> 2, false, true);

896

AnnotateDalvikRegAccess(st2, (current_dest_offset + (bytes_to_move >> 1)) >> 2, false, true);

897

} else {

898

// Set barrier for 128-bit store.

899

SetMemRefType(st1, false /* is_load */, kDalvikReg);

900

st1->u.m.def_mask = ENCODE_ALL;

}

}

// Free the temporary used for the data movement.

905

FreeTemp(temp);

906

} else {

907

// Moving 32-bits via general purpose register.

908

bytes_to_move = sizeof(uint32_t);

909

910

// Instead of allocating a new temp, simply reuse one of the registers being used

911

// for argument passing.

912

int temp = TargetReg(kArg3);

913

914

// Now load the argument VR and store to the outs.

915

LoadWordDisp(TargetReg(kSp), current_src_offset, temp);

916

StoreWordDisp(TargetReg(kSp), current_dest_offset, temp);

917

}

918

919

current_src_offset += bytes_to_move;

920

current_dest_offset += bytes_to_move;

921

regs_left_to_pass_via_stack -= (bytes_to_move >> 2);

922

}

923

} else {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

924

// Generate memcpy

925

OpRegRegImm(kOpAdd, TargetReg(kArg0), TargetReg(kSp), outs_offset);

926

OpRegRegImm(kOpAdd, TargetReg(kArg1), TargetReg(kSp), start_offset);

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

927

CallRuntimeHelperRegRegImm(QUICK_ENTRYPOINT_OFFSET(pMemcpy), TargetReg(kArg0),

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

928

TargetReg(kArg1), (info->num_arg_words - 3) * 4, false);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

929

}

930

931

call_state = LoadArgRegs(info, call_state, next_call_insn,

932

target_method, vtable_idx, direct_code, direct_method,

933

type, skip_this);

934

935

call_state = next_call_insn(cu_, info, call_state, target_method, vtable_idx,

936

direct_code, direct_method, type);

937

if (pcrLabel) {

938

*pcrLabel = GenNullCheck(info->args[0].s_reg_low, TargetReg(kArg1), info->opt_flags);

}

return call_state;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

943

RegLocation Mir2Lir::InlineTarget(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

944

RegLocation res;

945

if (info->result.location == kLocInvalid) {

946

res = GetReturn(false);

} else {

res = info->result;

}

return res;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

953

RegLocation Mir2Lir::InlineTargetWide(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

954

RegLocation res;

955

if (info->result.location == kLocInvalid) {

956

res = GetReturnWide(false);

} else {

res = info->result;

}

return res;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

963

bool Mir2Lir::GenInlinedCharAt(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

964

if (cu_->instruction_set == kMips) {

965

// TODO - add Mips implementation

966

return false;

967

}

968

// Location of reference to data array

969

int value_offset = mirror::String::ValueOffset().Int32Value();

970

// Location of count

971

int count_offset = mirror::String::CountOffset().Int32Value();

972

// Starting offset within data array

973

int offset_offset = mirror::String::OffsetOffset().Int32Value();

974

// Start of char data with array_

975

int data_offset = mirror::Array::DataOffset(sizeof(uint16_t)).Int32Value();

976

977

RegLocation rl_obj = info->args[0];

978

RegLocation rl_idx = info->args[1];

979

rl_obj = LoadValue(rl_obj, kCoreReg);

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

980

// X86 wants to avoid putting a constant index into a register.

981

if (!(cu_->instruction_set == kX86 && rl_idx.is_const)) {

982

rl_idx = LoadValue(rl_idx, kCoreReg);

983

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

984

int reg_max;

985

GenNullCheck(rl_obj.s_reg_low, rl_obj.low_reg, info->opt_flags);

986

bool range_check = (!(info->opt_flags & MIR_IGNORE_RANGE_CHECK));

987

LIR* launch_pad = NULL;

988

int reg_off = INVALID_REG;

989

int reg_ptr = INVALID_REG;

990

if (cu_->instruction_set != kX86) {

991

reg_off = AllocTemp();

992

reg_ptr = AllocTemp();

993

if (range_check) {

994

reg_max = AllocTemp();

995

LoadWordDisp(rl_obj.low_reg, count_offset, reg_max);

996

}

997

LoadWordDisp(rl_obj.low_reg, offset_offset, reg_off);

998

LoadWordDisp(rl_obj.low_reg, value_offset, reg_ptr);

999

if (range_check) {

1000

// Set up a launch pad to allow retry in case of bounds violation */

buzbee

2013-10-11 15:24:55 -0700

[diff] [blame]

1001

launch_pad = RawLIR(0, kPseudoIntrinsicRetry, WrapPointer(info));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1002

intrinsic_launchpads_.Insert(launch_pad);

1003

OpRegReg(kOpCmp, rl_idx.low_reg, reg_max);

1004

FreeTemp(reg_max);

Vladimir Marko

58af1f9

2013-12-19 13:31:15 +0000

[diff] [blame]

1005

OpCondBranch(kCondUge, launch_pad);

Brian Carlstrom

6f485c6

2013-07-18 15:35:35 -0700

[diff] [blame]

1006

}

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

1007

OpRegImm(kOpAdd, reg_ptr, data_offset);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1008

} else {

1009

if (range_check) {

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

1010

// On x86, we can compare to memory directly

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1011

// Set up a launch pad to allow retry in case of bounds violation */

buzbee

2013-10-11 15:24:55 -0700

[diff] [blame]

1012

launch_pad = RawLIR(0, kPseudoIntrinsicRetry, WrapPointer(info));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1013

intrinsic_launchpads_.Insert(launch_pad);

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

1014

if (rl_idx.is_const) {

1015

OpCmpMemImmBranch(kCondUlt, INVALID_REG, rl_obj.low_reg, count_offset,

1016

mir_graph_->ConstantValue(rl_idx.orig_sreg), launch_pad);

1017

} else {

1018

OpRegMem(kOpCmp, rl_idx.low_reg, rl_obj.low_reg, count_offset);

1019

OpCondBranch(kCondUge, launch_pad);

1020

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1021

}

1022

reg_off = AllocTemp();

1023

reg_ptr = AllocTemp();

1024

LoadWordDisp(rl_obj.low_reg, offset_offset, reg_off);

1025

LoadWordDisp(rl_obj.low_reg, value_offset, reg_ptr);

1026

}

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

1027

if (rl_idx.is_const) {

1028

OpRegImm(kOpAdd, reg_off, mir_graph_->ConstantValue(rl_idx.orig_sreg));

1029

} else {

1030

OpRegReg(kOpAdd, reg_off, rl_idx.low_reg);

1031

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1032

FreeTemp(rl_obj.low_reg);

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

1033

if (rl_idx.low_reg != INVALID_REG) {

1034

FreeTemp(rl_idx.low_reg);

1035

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1036

RegLocation rl_dest = InlineTarget(info);

1037

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

Mark Mendell

2014-02-06 05:24:20 -0800

[diff] [blame]

1038

if (cu_->instruction_set != kX86) {

1039

LoadBaseIndexed(reg_ptr, reg_off, rl_result.low_reg, 1, kUnsignedHalf);

1040

} else {

1041

LoadBaseIndexedDisp(reg_ptr, reg_off, 1, data_offset, rl_result.low_reg,

1042

INVALID_REG, kUnsignedHalf, INVALID_SREG);

1043

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1044

FreeTemp(reg_off);

1045

FreeTemp(reg_ptr);

1046

StoreValue(rl_dest, rl_result);

1047

if (range_check) {

1048

launch_pad->operands[2] = 0; // no resumption

1049

}

1050

// Record that we've already inlined & null checked

1051

info->opt_flags |= (MIR_INLINED | MIR_IGNORE_NULL_CHECK);

return true;

}

// Generates an inlined String.is_empty or String.length.

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1056

bool Mir2Lir::GenInlinedStringIsEmptyOrLength(CallInfo* info, bool is_empty) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1057

if (cu_->instruction_set == kMips) {

1058

// TODO - add Mips implementation

1059

return false;

1060

}

1061

// dst = src.length();

1062

RegLocation rl_obj = info->args[0];

1063

rl_obj = LoadValue(rl_obj, kCoreReg);

1064

RegLocation rl_dest = InlineTarget(info);

1065

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1066

GenNullCheck(rl_obj.s_reg_low, rl_obj.low_reg, info->opt_flags);

1067

LoadWordDisp(rl_obj.low_reg, mirror::String::CountOffset().Int32Value(), rl_result.low_reg);

1068

if (is_empty) {

1069

// dst = (dst == 0);

1070

if (cu_->instruction_set == kThumb2) {

1071

int t_reg = AllocTemp();

1072

OpRegReg(kOpNeg, t_reg, rl_result.low_reg);

1073

OpRegRegReg(kOpAdc, rl_result.low_reg, rl_result.low_reg, t_reg);

1074

} else {

1075

DCHECK_EQ(cu_->instruction_set, kX86);

1076

OpRegImm(kOpSub, rl_result.low_reg, 1);

1077

OpRegImm(kOpLsr, rl_result.low_reg, 31);

1078

}

1079

}

1080

StoreValue(rl_dest, rl_result);

return true;

}

Vladimir Marko

2013-10-29 17:40:46 +0000

[diff] [blame]

1084

bool Mir2Lir::GenInlinedReverseBytes(CallInfo* info, OpSize size) {

1085

if (cu_->instruction_set == kMips) {

1086

// TODO - add Mips implementation

1087

return false;

1088

}

1089

RegLocation rl_src_i = info->args[0];

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

1090

RegLocation rl_dest = (size == kLong) ? InlineTargetWide(info) : InlineTarget(info); // result reg

Vladimir Marko

6bdf1ff

2013-10-29 17:40:46 +0000

[diff] [blame]

1091

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1092

if (size == kLong) {

1093

RegLocation rl_i = LoadValueWide(rl_src_i, kCoreReg);

Vladimir Marko

f246af2

2013-11-27 12:30:15 +0000

[diff] [blame]

1094

int r_i_low = rl_i.low_reg;

1095

if (rl_i.low_reg == rl_result.low_reg) {

1096

// First REV shall clobber rl_result.low_reg, save the value in a temp for the second REV.

1097

r_i_low = AllocTemp();

1098

OpRegCopy(r_i_low, rl_i.low_reg);

1099

}

Vladimir Marko

6bdf1ff

2013-10-29 17:40:46 +0000

[diff] [blame]

1100

OpRegReg(kOpRev, rl_result.low_reg, rl_i.high_reg);

Vladimir Marko

f246af2

2013-11-27 12:30:15 +0000

[diff] [blame]

1101

OpRegReg(kOpRev, rl_result.high_reg, r_i_low);

1102

if (rl_i.low_reg == rl_result.low_reg) {

1103

FreeTemp(r_i_low);

1104

}

Vladimir Marko

6bdf1ff

2013-10-29 17:40:46 +0000

[diff] [blame]

1105

StoreValueWide(rl_dest, rl_result);

1106

} else {

1107

DCHECK(size == kWord || size == kSignedHalf);

1108

OpKind op = (size == kWord) ? kOpRev : kOpRevsh;

1109

RegLocation rl_i = LoadValue(rl_src_i, kCoreReg);

1110

OpRegReg(op, rl_result.low_reg, rl_i.low_reg);

1111

StoreValue(rl_dest, rl_result);

}

return true;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1116

bool Mir2Lir::GenInlinedAbsInt(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1117

if (cu_->instruction_set == kMips) {

1118

// TODO - add Mips implementation

1119

return false;

1120

}

1121

RegLocation rl_src = info->args[0];

1122

rl_src = LoadValue(rl_src, kCoreReg);

1123

RegLocation rl_dest = InlineTarget(info);

1124

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1125

int sign_reg = AllocTemp();

1126

// abs(x) = y<=x>>31, (x+y)^y.

1127

OpRegRegImm(kOpAsr, sign_reg, rl_src.low_reg, 31);

1128

OpRegRegReg(kOpAdd, rl_result.low_reg, rl_src.low_reg, sign_reg);

1129

OpRegReg(kOpXor, rl_result.low_reg, sign_reg);

1130

StoreValue(rl_dest, rl_result);

return true;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1134

bool Mir2Lir::GenInlinedAbsLong(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1135

if (cu_->instruction_set == kMips) {

1136

// TODO - add Mips implementation

1137

return false;

1138

}

1139

if (cu_->instruction_set == kThumb2) {

1140

RegLocation rl_src = info->args[0];

1141

rl_src = LoadValueWide(rl_src, kCoreReg);

1142

RegLocation rl_dest = InlineTargetWide(info);

1143

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1144

int sign_reg = AllocTemp();

1145

// abs(x) = y<=x>>31, (x+y)^y.

1146

OpRegRegImm(kOpAsr, sign_reg, rl_src.high_reg, 31);

1147

OpRegRegReg(kOpAdd, rl_result.low_reg, rl_src.low_reg, sign_reg);

1148

OpRegRegReg(kOpAdc, rl_result.high_reg, rl_src.high_reg, sign_reg);

1149

OpRegReg(kOpXor, rl_result.low_reg, sign_reg);

1150

OpRegReg(kOpXor, rl_result.high_reg, sign_reg);

1151

StoreValueWide(rl_dest, rl_result);

1152

return true;

1153

} else {

1154

DCHECK_EQ(cu_->instruction_set, kX86);

1155

// Reuse source registers to avoid running out of temps

1156

RegLocation rl_src = info->args[0];

1157

rl_src = LoadValueWide(rl_src, kCoreReg);

1158

RegLocation rl_dest = InlineTargetWide(info);

1159

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1160

OpRegCopyWide(rl_result.low_reg, rl_result.high_reg, rl_src.low_reg, rl_src.high_reg);

1161

FreeTemp(rl_src.low_reg);

1162

FreeTemp(rl_src.high_reg);

1163

int sign_reg = AllocTemp();

1164

// abs(x) = y<=x>>31, (x+y)^y.

1165

OpRegRegImm(kOpAsr, sign_reg, rl_result.high_reg, 31);

1166

OpRegReg(kOpAdd, rl_result.low_reg, sign_reg);

1167

OpRegReg(kOpAdc, rl_result.high_reg, sign_reg);

1168

OpRegReg(kOpXor, rl_result.low_reg, sign_reg);

1169

OpRegReg(kOpXor, rl_result.high_reg, sign_reg);

1170

StoreValueWide(rl_dest, rl_result);

return true;

}

}

Yixin Shou

2014-02-07 05:09:30 -0800

[diff] [blame]

1175

bool Mir2Lir::GenInlinedAbsFloat(CallInfo* info) {

1176

if (cu_->instruction_set == kMips) {

1177

// TODO - add Mips implementation

1178

return false;

1179

}

1180

RegLocation rl_src = info->args[0];

1181

rl_src = LoadValue(rl_src, kCoreReg);

1182

RegLocation rl_dest = InlineTarget(info);

1183

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1184

int signMask = AllocTemp();

1185

LoadConstant(signMask, 0x7fffffff);

1186

OpRegRegReg(kOpAnd, rl_result.low_reg, rl_src.low_reg, signMask);

1187

FreeTemp(signMask);

1188

StoreValue(rl_dest, rl_result);

return true;

}

bool Mir2Lir::GenInlinedAbsDouble(CallInfo* info) {

1193

if (cu_->instruction_set == kMips) {

1194

// TODO - add Mips implementation

1195

return false;

1196

}

1197

RegLocation rl_src = info->args[0];

1198

rl_src = LoadValueWide(rl_src, kCoreReg);

1199

RegLocation rl_dest = InlineTargetWide(info);

1200

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1201

OpRegCopyWide(rl_result.low_reg, rl_result.high_reg, rl_src.low_reg, rl_src.high_reg);

1202

FreeTemp(rl_src.low_reg);

1203

FreeTemp(rl_src.high_reg);

1204

int signMask = AllocTemp();

1205

LoadConstant(signMask, 0x7fffffff);

1206

OpRegReg(kOpAnd, rl_result.high_reg, signMask);

1207

FreeTemp(signMask);

1208

StoreValueWide(rl_dest, rl_result);

return true;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1212

bool Mir2Lir::GenInlinedFloatCvt(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1213

if (cu_->instruction_set == kMips) {

1214

// TODO - add Mips implementation

1215

return false;

1216

}

1217

RegLocation rl_src = info->args[0];

1218

RegLocation rl_dest = InlineTarget(info);

1219

StoreValue(rl_dest, rl_src);

return true;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1223

bool Mir2Lir::GenInlinedDoubleCvt(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1224

if (cu_->instruction_set == kMips) {

1225

// TODO - add Mips implementation

1226

return false;

1227

}

1228

RegLocation rl_src = info->args[0];

1229

RegLocation rl_dest = InlineTargetWide(info);

1230

StoreValueWide(rl_dest, rl_src);

return true;

}

/*

* Fast string.index_of(I) & (II). Tests for simple case of char <= 0xffff,

1236

* otherwise bails to standard library code.

1237

*/

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1238

bool Mir2Lir::GenInlinedIndexOf(CallInfo* info, bool zero_based) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1239

if (cu_->instruction_set == kMips) {

1240

// TODO - add Mips implementation

1241

return false;

1242

}

Vladimir Marko

2013-12-09 16:31:19 +0000

[diff] [blame]

1243

ClobberCallerSave();

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1244

LockCallTemps(); // Using fixed registers

1245

int reg_ptr = TargetReg(kArg0);

1246

int reg_char = TargetReg(kArg1);

1247

int reg_start = TargetReg(kArg2);

1248

1249

RegLocation rl_obj = info->args[0];

1250

RegLocation rl_char = info->args[1];

1251

RegLocation rl_start = info->args[2];

1252

LoadValueDirectFixed(rl_obj, reg_ptr);

1253

LoadValueDirectFixed(rl_char, reg_char);

1254

if (zero_based) {

1255

LoadConstant(reg_start, 0);

1256

} else {

1257

LoadValueDirectFixed(rl_start, reg_start);

1258

}

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1259

int r_tgt = (cu_->instruction_set != kX86) ? LoadHelper(QUICK_ENTRYPOINT_OFFSET(pIndexOf)) : 0;

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1260

GenNullCheck(rl_obj.s_reg_low, reg_ptr, info->opt_flags);

buzbee

2013-10-11 15:24:55 -0700

[diff] [blame]

1261

LIR* launch_pad = RawLIR(0, kPseudoIntrinsicRetry, WrapPointer(info));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1262

intrinsic_launchpads_.Insert(launch_pad);

1263

OpCmpImmBranch(kCondGt, reg_char, 0xFFFF, launch_pad);

1264

// NOTE: not a safepoint

1265

if (cu_->instruction_set != kX86) {

1266

OpReg(kOpBlx, r_tgt);

1267

} else {

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1268

OpThreadMem(kOpBlx, QUICK_ENTRYPOINT_OFFSET(pIndexOf));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1269

}

1270

LIR* resume_tgt = NewLIR0(kPseudoTargetLabel);

buzbee

2013-10-11 15:24:55 -0700

[diff] [blame]

1271

launch_pad->operands[2] = WrapPointer(resume_tgt);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1272

// Record that we've already inlined & null checked

1273

info->opt_flags |= (MIR_INLINED | MIR_IGNORE_NULL_CHECK);

1274

RegLocation rl_return = GetReturn(false);

1275

RegLocation rl_dest = InlineTarget(info);

1276

StoreValue(rl_dest, rl_return);

return true;

}

/* Fast string.compareTo(Ljava/lang/string;)I. */

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1281

bool Mir2Lir::GenInlinedStringCompareTo(CallInfo* info) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1282

if (cu_->instruction_set == kMips) {

1283

// TODO - add Mips implementation

1284

return false;

1285

}

Vladimir Marko

2013-12-09 16:31:19 +0000

[diff] [blame]

1286

ClobberCallerSave();

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1287

LockCallTemps(); // Using fixed registers

1288

int reg_this = TargetReg(kArg0);

1289

int reg_cmp = TargetReg(kArg1);

1290

1291

RegLocation rl_this = info->args[0];

1292

RegLocation rl_cmp = info->args[1];

1293

LoadValueDirectFixed(rl_this, reg_this);

1294

LoadValueDirectFixed(rl_cmp, reg_cmp);

1295

int r_tgt = (cu_->instruction_set != kX86) ?

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1296

LoadHelper(QUICK_ENTRYPOINT_OFFSET(pStringCompareTo)) : 0;

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1297

GenNullCheck(rl_this.s_reg_low, reg_this, info->opt_flags);

Brian Carlstrom

2013-07-26 10:54:15 -0700

[diff] [blame]

1298

// TUNING: check if rl_cmp.s_reg_low is already null checked

buzbee

2013-10-11 15:24:55 -0700

[diff] [blame]

1299

LIR* launch_pad = RawLIR(0, kPseudoIntrinsicRetry, WrapPointer(info));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1300

intrinsic_launchpads_.Insert(launch_pad);

1301

OpCmpImmBranch(kCondEq, reg_cmp, 0, launch_pad);

1302

// NOTE: not a safepoint

1303

if (cu_->instruction_set != kX86) {

1304

OpReg(kOpBlx, r_tgt);

1305

} else {

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1306

OpThreadMem(kOpBlx, QUICK_ENTRYPOINT_OFFSET(pStringCompareTo));

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1307

}

1308

launch_pad->operands[2] = 0; // No return possible

1309

// Record that we've already inlined & null checked

1310

info->opt_flags |= (MIR_INLINED | MIR_IGNORE_NULL_CHECK);

1311

RegLocation rl_return = GetReturn(false);

1312

RegLocation rl_dest = InlineTarget(info);

1313

StoreValue(rl_dest, rl_return);

return true;

}

bool Mir2Lir::GenInlinedCurrentThread(CallInfo* info) {

1318

RegLocation rl_dest = InlineTarget(info);

1319

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

1320

ThreadOffset offset = Thread::PeerOffset();

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1321

if (cu_->instruction_set == kThumb2 || cu_->instruction_set == kMips) {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

1322

LoadWordDisp(TargetReg(kSelf), offset.Int32Value(), rl_result.low_reg);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1323

} else {

1324

CHECK(cu_->instruction_set == kX86);

Brian Carlstrom

2d88862

2013-07-18 17:02:00 -0700

[diff] [blame]

1325

reinterpret_cast<X86Mir2Lir*>(this)->OpRegThreadMem(kOpMov, rl_result.low_reg, offset);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1326

}

1327

StoreValue(rl_dest, rl_result);

return true;

}

bool Mir2Lir::GenInlinedUnsafeGet(CallInfo* info,

1332

bool is_long, bool is_volatile) {

1333

if (cu_->instruction_set == kMips) {

1334

// TODO - add Mips implementation

1335

return false;

1336

}

1337

// Unused - RegLocation rl_src_unsafe = info->args[0];

1338

RegLocation rl_src_obj = info->args[1]; // Object

1339

RegLocation rl_src_offset = info->args[2]; // long low

1340

rl_src_offset.wide = 0; // ignore high half in info->args[3]

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

1341

RegLocation rl_dest = is_long ? InlineTargetWide(info) : InlineTarget(info); // result reg

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1342

if (is_volatile) {

1343

GenMemBarrier(kLoadLoad);

1344

}

1345

RegLocation rl_object = LoadValue(rl_src_obj, kCoreReg);

1346

RegLocation rl_offset = LoadValue(rl_src_offset, kCoreReg);

1347

RegLocation rl_result = EvalLoc(rl_dest, kCoreReg, true);

1348

if (is_long) {

1349

OpRegReg(kOpAdd, rl_object.low_reg, rl_offset.low_reg);

1350

LoadBaseDispWide(rl_object.low_reg, 0, rl_result.low_reg, rl_result.high_reg, INVALID_SREG);

1351

StoreValueWide(rl_dest, rl_result);

1352

} else {

1353

LoadBaseIndexed(rl_object.low_reg, rl_offset.low_reg, rl_result.low_reg, 0, kWord);

1354

StoreValue(rl_dest, rl_result);

}

return true;

}

bool Mir2Lir::GenInlinedUnsafePut(CallInfo* info, bool is_long,

1360

bool is_object, bool is_volatile, bool is_ordered) {

1361

if (cu_->instruction_set == kMips) {

1362

// TODO - add Mips implementation

1363

return false;

1364

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1365

// Unused - RegLocation rl_src_unsafe = info->args[0];

1366

RegLocation rl_src_obj = info->args[1]; // Object

1367

RegLocation rl_src_offset = info->args[2]; // long low

1368

rl_src_offset.wide = 0; // ignore high half in info->args[3]

1369

RegLocation rl_src_value = info->args[4]; // value to store

1370

if (is_volatile || is_ordered) {

1371

GenMemBarrier(kStoreStore);

1372

}

1373

RegLocation rl_object = LoadValue(rl_src_obj, kCoreReg);

1374

RegLocation rl_offset = LoadValue(rl_src_offset, kCoreReg);

1375

RegLocation rl_value;

1376

if (is_long) {

1377

rl_value = LoadValueWide(rl_src_value, kCoreReg);

1378

OpRegReg(kOpAdd, rl_object.low_reg, rl_offset.low_reg);

1379

StoreBaseDispWide(rl_object.low_reg, 0, rl_value.low_reg, rl_value.high_reg);

1380

} else {

1381

rl_value = LoadValue(rl_src_value, kCoreReg);

1382

StoreBaseIndexed(rl_object.low_reg, rl_offset.low_reg, rl_value.low_reg, 0, kWord);

1383

}

Mark Mendell

df8ee2e

2014-01-27 16:37:47 -0800

[diff] [blame]

1384

1385

// Free up the temp early, to ensure x86 doesn't run out of temporaries in MarkGCCard.

1386

FreeTemp(rl_offset.low_reg);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1387

if (is_volatile) {

1388

GenMemBarrier(kStoreLoad);

1389

}

1390

if (is_object) {

1391

MarkGCCard(rl_value.low_reg, rl_object.low_reg);

}

return true;

}

Brian Carlstrom

2013-07-17 17:44:30 -0700

[diff] [blame]

1396

void Mir2Lir::GenInvoke(CallInfo* info) {

Vladimir Marko

5c96e6b

2013-11-14 15:34:17 +0000

[diff] [blame]

1397

if (!(info->opt_flags & MIR_INLINED)) {

Vladimir Marko

5816ed4

2013-11-27 17:04:20 +0000

[diff] [blame]

1398

DCHECK(cu_->compiler_driver->GetMethodInlinerMap() != nullptr);

1399

if (cu_->compiler_driver->GetMethodInlinerMap()->GetMethodInliner(cu_->dex_file)

1400

->GenIntrinsic(this, info)) {

Vladimir Marko

5c96e6b

2013-11-14 15:34:17 +0000

[diff] [blame]

1401

return;

1402

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1403

}

1404

InvokeType original_type = info->type; // avoiding mutation by ComputeInvokeInfo

1405

int call_state = 0;

1406

LIR* null_ck;

1407

LIR** p_null_ck = NULL;

1408

NextCallInsn next_call_insn;

1409

FlushAllRegs(); /* Everything to home location */

1410

// Explicit register usage

1411

LockCallTemps();

1412

1413

DexCompilationUnit* cUnit = mir_graph_->GetCurrentDexCompilationUnit();

1414

MethodReference target_method(cUnit->GetDexFile(), info->index);

1415

int vtable_idx;

1416

uintptr_t direct_code;

1417

uintptr_t direct_method;

1418

bool skip_this;

1419

bool fast_path =

1420

cu_->compiler_driver->ComputeInvokeInfo(mir_graph_->GetCurrentDexCompilationUnit(),

1421

current_dalvik_offset_,

Ian Rogers

65ec92c

2013-09-06 10:49:58 -0700

[diff] [blame]

1422

true, true,

1423

&info->type, &target_method,

1424

&vtable_idx,

1425

&direct_code, &direct_method) && !SLOW_INVOKE_PATH;

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1426

if (info->type == kInterface) {

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1427

next_call_insn = fast_path ? NextInterfaceCallInsn : NextInterfaceCallInsnWithAccessCheck;

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

1428

skip_this = fast_path;

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1429

} else if (info->type == kDirect) {

1430

if (fast_path) {

1431

p_null_ck = &null_ck;

1432

}

1433

next_call_insn = fast_path ? NextSDCallInsn : NextDirectCallInsnSP;

1434

skip_this = false;

1435

} else if (info->type == kStatic) {

1436

next_call_insn = fast_path ? NextSDCallInsn : NextStaticCallInsnSP;

1437

skip_this = false;

1438

} else if (info->type == kSuper) {

1439

DCHECK(!fast_path); // Fast path is a direct call.

1440

next_call_insn = NextSuperCallInsnSP;

1441

skip_this = false;

1442

} else {

1443

DCHECK_EQ(info->type, kVirtual);

1444

next_call_insn = fast_path ? NextVCallInsn : NextVCallInsnSP;

1445

skip_this = fast_path;

1446

}

1447

if (!info->is_range) {

1448

call_state = GenDalvikArgsNoRange(info, call_state, p_null_ck,

1449

next_call_insn, target_method,

1450

vtable_idx, direct_code, direct_method,

1451

original_type, skip_this);

1452

} else {

1453

call_state = GenDalvikArgsRange(info, call_state, p_null_ck,

1454

next_call_insn, target_method, vtable_idx,

1455

direct_code, direct_method, original_type,

1456

skip_this);

1457

}

1458

// Finish up any of the call sequence not interleaved in arg loading

1459

while (call_state >= 0) {

1460

call_state = next_call_insn(cu_, info, call_state, target_method,

1461

vtable_idx, direct_code, direct_method,

original_type);

}

LIR* call_inst;

if (cu_->instruction_set != kX86) {

1466

call_inst = OpReg(kOpBlx, TargetReg(kInvokeTgt));

1467

} else {

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

1468

if (fast_path) {

Mark Mendell

2014-02-06 11:02:52 -0800

[diff] [blame]

1469

if (direct_code == static_cast<unsigned int>(-1)) {

1470

// We can have the linker fixup a call relative.

1471

call_inst =

1472

reinterpret_cast<X86Mir2Lir*>(this)->CallWithLinkerFixup(

1473

target_method.dex_method_index, info->type);

1474

} else {

1475

call_inst = OpMem(kOpBlx, TargetReg(kArg0),

1476

mirror::ArtMethod::EntryPointFromQuickCompiledCodeOffset().Int32Value());

1477

}

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1478

} else {

Ian Rogers

2013-08-05 10:56:33 -0700

[diff] [blame]

1479

ThreadOffset trampoline(-1);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1480

switch (info->type) {

1481

case kInterface:

Jeff Hao

2013-10-23 16:24:40 -0700

[diff] [blame]

1482

trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeInterfaceTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1483

break;

1484

case kDirect:

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1485

trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeDirectTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1486

break;

1487

case kStatic:

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1488

trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeStaticTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1489

break;

1490

case kSuper:

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1491

trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeSuperTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1492

break;

1493

case kVirtual:

Ian Rogers

2013-07-29 11:07:13 -0700

[diff] [blame]

1494

trampoline = QUICK_ENTRYPOINT_OFFSET(pInvokeVirtualTrampolineWithAccessCheck);

Brian Carlstrom

2013-07-12 13:46:57 -0700

[diff] [blame]

1495

break;

1496

default:

1497

LOG(FATAL) << "Unexpected invoke type";

1498

}

1499

call_inst = OpThreadMem(kOpBlx, trampoline);

1500

}

1501

}

1502

MarkSafepointPC(call_inst);

1503

Vladimir Marko

2013-12-09 16:31:19 +0000

[diff] [blame]

1504

ClobberCallerSave();

Brian Carlstrom