compiler/linker/arm64/relative_patcher_arm64.cc - platform/art - Git at Google

 /*
  * Copyright (C) 2015 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "linker/arm64/relative_patcher_arm64.h"

 #include "arch/arm64/instruction_set_features_arm64.h"
 #include "compiled_method.h"
 #include "driver/compiler_driver.h"
 #include "mirror/art_method.h"
 #include "utils/arm64/assembler_arm64.h"
 #include "oat.h"
 #include "output_stream.h"

 namespace art {
 namespace linker {

 Arm64RelativePatcher::Arm64RelativePatcher(RelativePatcherTargetProvider* provider,
                                            const Arm64InstructionSetFeatures* features)
     : ArmBaseRelativePatcher(provider, kArm64, CompileThunkCode(),
                              kMaxPositiveDisplacement, kMaxNegativeDisplacement),
       fix_cortex_a53_843419_(features->NeedFixCortexA53_843419()),
       reserved_adrp_thunks_(0u),
       processed_adrp_thunks_(0u) {
   if (fix_cortex_a53_843419_) {
     adrp_thunk_locations_.reserve(16u);
     current_method_thunks_.reserve(16u * kAdrpThunkSize);
   }
 }

 uint32_t Arm64RelativePatcher::ReserveSpace(uint32_t offset,
                                             const CompiledMethod* compiled_method,
                                             MethodReference method_ref) {
   if (!fix_cortex_a53_843419_) {
     DCHECK(adrp_thunk_locations_.empty());
     return ReserveSpaceInternal(offset, compiled_method, method_ref, 0u);
   }

   // Add thunks for previous method if any.
   if (reserved_adrp_thunks_ != adrp_thunk_locations_.size()) {
     size_t num_adrp_thunks = adrp_thunk_locations_.size() - reserved_adrp_thunks_;
     offset = CompiledMethod::AlignCode(offset, kArm64) + kAdrpThunkSize * num_adrp_thunks;
     reserved_adrp_thunks_ = adrp_thunk_locations_.size();
   }

   // Count the number of ADRP insns as the upper bound on the number of thunks needed
   // and use it to reserve space for other linker patches.
   size_t num_adrp = 0u;
   if (LIKELY(compiled_method != nullptr)) {
     for (const LinkerPatch& patch : compiled_method->GetPatches()) {
       if (patch.Type() == kLinkerPatchDexCacheArray &&
           patch.LiteralOffset() == patch.PcInsnOffset()) {  // ADRP patch
         ++num_adrp;
       }
     }
   }
   offset = ReserveSpaceInternal(offset, compiled_method, method_ref, kAdrpThunkSize * num_adrp);
   if (num_adrp == 0u) {
     return offset;
   }

   // Now that we have the actual offset where the code will be placed, locate the ADRP insns
   // that actually require the thunk.
   uint32_t quick_code_offset = compiled_method->AlignCode(offset) + sizeof(OatQuickMethodHeader);
   ArrayRef<const uint8_t> code(*compiled_method->GetQuickCode());
   uint32_t thunk_offset = compiled_method->AlignCode(quick_code_offset + code.size());
   DCHECK(compiled_method != nullptr);
   for (const LinkerPatch& patch : compiled_method->GetPatches()) {
     if (patch.Type() == kLinkerPatchDexCacheArray &&
         patch.LiteralOffset() == patch.PcInsnOffset()) {  // ADRP patch
       uint32_t patch_offset = quick_code_offset + patch.LiteralOffset();
       if (NeedsErratum843419Thunk(code, patch.LiteralOffset(), patch_offset)) {
         adrp_thunk_locations_.emplace_back(patch_offset, thunk_offset);
         thunk_offset += kAdrpThunkSize;
       }
     }
   }
   return offset;
 }

 uint32_t Arm64RelativePatcher::WriteThunks(OutputStream* out, uint32_t offset) {
   if (fix_cortex_a53_843419_) {
     if (!current_method_thunks_.empty()) {
       uint32_t aligned_offset = CompiledMethod::AlignCode(offset, kArm64);
       if (kIsDebugBuild) {
         CHECK(IsAligned<kAdrpThunkSize>(current_method_thunks_.size()));
         size_t num_thunks = current_method_thunks_.size() / kAdrpThunkSize;
         CHECK_LE(num_thunks, processed_adrp_thunks_);
         for (size_t i = 0u; i != num_thunks; ++i) {
           const auto& entry = adrp_thunk_locations_[processed_adrp_thunks_ - num_thunks + i];
           CHECK_EQ(entry.second, aligned_offset + i * kAdrpThunkSize);
         }
       }
       uint32_t aligned_code_delta = aligned_offset - offset;
       if (aligned_code_delta != 0u && !WriteCodeAlignment(out, aligned_code_delta)) {
         return 0u;
       }
       if (!WriteMiscThunk(out, ArrayRef<const uint8_t>(current_method_thunks_))) {
         return 0u;
       }
       offset = aligned_offset + current_method_thunks_.size();
       current_method_thunks_.clear();
     }
   }
   return ArmBaseRelativePatcher::WriteThunks(out, offset);
 }

 void Arm64RelativePatcher::PatchCall(std::vector<uint8_t>* code, uint32_t literal_offset,
                                      uint32_t patch_offset, uint32_t target_offset) {
   DCHECK_LE(literal_offset + 4u, code->size());
   DCHECK_EQ(literal_offset & 3u, 0u);
   DCHECK_EQ(patch_offset & 3u, 0u);
   DCHECK_EQ(target_offset & 3u, 0u);
   uint32_t displacement = CalculateDisplacement(patch_offset, target_offset & ~1u);
   DCHECK_EQ(displacement & 3u, 0u);
   DCHECK((displacement >> 27) == 0u || (displacement >> 27) == 31u);  // 28-bit signed.
   uint32_t insn = (displacement & 0x0fffffffu) >> 2;
   insn |= 0x94000000;  // BL

   // Check that we're just overwriting an existing BL.
   DCHECK_EQ(GetInsn(code, literal_offset) & 0xfc000000u, 0x94000000u);
   // Write the new BL.
   SetInsn(code, literal_offset, insn);
 }

 void Arm64RelativePatcher::PatchDexCacheReference(std::vector<uint8_t>* code,
                                                   const LinkerPatch& patch,
                                                   uint32_t patch_offset,
                                                   uint32_t target_offset) {
   DCHECK_EQ(patch_offset & 3u, 0u);
   DCHECK_EQ(target_offset & 3u, 0u);
   uint32_t literal_offset = patch.LiteralOffset();
   uint32_t insn = GetInsn(code, literal_offset);
   uint32_t pc_insn_offset = patch.PcInsnOffset();
   uint32_t disp = target_offset - ((patch_offset - literal_offset + pc_insn_offset) & ~0xfffu);
   if (literal_offset == pc_insn_offset) {
     // Check it's an ADRP with imm == 0 (unset).
     DCHECK_EQ((insn & 0xffffffe0u), 0x90000000u)
         << literal_offset << ", " << pc_insn_offset << ", 0x" << std::hex << insn;
     if (fix_cortex_a53_843419_ && processed_adrp_thunks_ != adrp_thunk_locations_.size() &&
         adrp_thunk_locations_[processed_adrp_thunks_].first == patch_offset) {
       DCHECK(NeedsErratum843419Thunk(ArrayRef<const uint8_t>(*code),
                                      literal_offset, patch_offset));
       uint32_t thunk_offset = adrp_thunk_locations_[processed_adrp_thunks_].second;
       uint32_t adrp_disp = target_offset - (thunk_offset & ~0xfffu);
       uint32_t adrp = PatchAdrp(insn, adrp_disp);

       uint32_t out_disp = thunk_offset - patch_offset;
       DCHECK_EQ(out_disp & 3u, 0u);
       DCHECK((out_disp >> 27) == 0u || (out_disp >> 27) == 31u);  // 28-bit signed.
       insn = (out_disp & 0x0fffffffu) >> 2;
       insn |= 0x14000000;  // B <thunk>

       uint32_t back_disp = -out_disp;
       DCHECK_EQ(back_disp & 3u, 0u);
       DCHECK((back_disp >> 27) == 0u || (back_disp >> 27) == 31u);  // 28-bit signed.
       uint32_t b_back = (back_disp & 0x0fffffffu) >> 2;
       b_back |= 0x14000000;  // B <back>
       size_t thunks_code_offset = current_method_thunks_.size();
       current_method_thunks_.resize(thunks_code_offset + kAdrpThunkSize);
       SetInsn(&current_method_thunks_, thunks_code_offset, adrp);
       SetInsn(&current_method_thunks_, thunks_code_offset + 4u, b_back);
       static_assert(kAdrpThunkSize == 2 * 4u, "thunk has 2 instructions");

       processed_adrp_thunks_ += 1u;
     } else {
       insn = PatchAdrp(insn, disp);
     }
     // Write the new ADRP (or B to the erratum 843419 thunk).
     SetInsn(code, literal_offset, insn);
   } else {
     DCHECK_EQ(insn & 0xfffffc00, 0xb9400000);  // LDR 32-bit with imm12 == 0 (unset).
     if (kIsDebugBuild) {
       uint32_t adrp = GetInsn(code, pc_insn_offset);
       if ((adrp & 0x9f000000u) != 0x90000000u) {
         CHECK(fix_cortex_a53_843419_);
         CHECK_EQ(adrp & 0xfc000000u, 0x14000000u);  // B <thunk>
         CHECK(IsAligned<kAdrpThunkSize>(current_method_thunks_.size()));
         size_t num_thunks = current_method_thunks_.size() / kAdrpThunkSize;
         CHECK_LE(num_thunks, processed_adrp_thunks_);
         uint32_t b_offset = patch_offset - literal_offset + pc_insn_offset;
         for (size_t i = processed_adrp_thunks_ - num_thunks; ; ++i) {
           CHECK_NE(i, processed_adrp_thunks_);
           if (adrp_thunk_locations_[i].first == b_offset) {
             size_t idx = num_thunks - (processed_adrp_thunks_ - i);
             adrp = GetInsn(&current_method_thunks_, idx * kAdrpThunkSize);
             break;
           }
         }
       }
       CHECK_EQ(adrp & 0x9f00001fu,                    // Check that pc_insn_offset points
                0x90000000 | ((insn >> 5) & 0x1fu));   // to ADRP with matching register.
     }
     uint32_t imm12 = (disp & 0xfffu) >> 2;
     insn = (insn & ~(0xfffu << 10)) | (imm12 << 10);
     SetInsn(code, literal_offset, insn);
   }
 }

 std::vector<uint8_t> Arm64RelativePatcher::CompileThunkCode() {
   // The thunk just uses the entry point in the ArtMethod. This works even for calls
   // to the generic JNI and interpreter trampolines.
   arm64::Arm64Assembler assembler;
   Offset offset(mirror::ArtMethod::EntryPointFromQuickCompiledCodeOffset(
       kArm64PointerSize).Int32Value());
   assembler.JumpTo(ManagedRegister(arm64::X0), offset, ManagedRegister(arm64::IP0));
   // Ensure we emit the literal pool.
   assembler.EmitSlowPaths();
   std::vector<uint8_t> thunk_code(assembler.CodeSize());
   MemoryRegion code(thunk_code.data(), thunk_code.size());
   assembler.FinalizeInstructions(code);
   return thunk_code;
 }

 uint32_t Arm64RelativePatcher::PatchAdrp(uint32_t adrp, uint32_t disp) {
   return (adrp & 0x9f00001fu) |  // Clear offset bits, keep ADRP with destination reg.
       // Bottom 12 bits are ignored, the next 2 lowest bits are encoded in bits 29-30.
       ((disp & 0x00003000u) << (29 - 12)) |
       // The next 16 bits are encoded in bits 5-22.
       ((disp & 0xffffc000u) >> (12 + 2 - 5)) |
       // Since the target_offset is based on the beginning of the oat file and the
       // image space precedes the oat file, the target_offset into image space will
       // be negative yet passed as uint32_t. Therefore we limit the displacement
       // to +-2GiB (rather than the maximim +-4GiB) and determine the sign bit from
       // the highest bit of the displacement. This is encoded in bit 23.
       ((disp & 0x80000000u) >> (31 - 23));
 }

 bool Arm64RelativePatcher::NeedsErratum843419Thunk(ArrayRef<const uint8_t> code,
                                                    uint32_t literal_offset,
                                                    uint32_t patch_offset) {
   DCHECK_EQ(patch_offset & 0x3u, 0u);
   if ((patch_offset & 0xff8) == 0xff8) {  // ...ff8 or ...ffc
     uint32_t adrp = GetInsn(code, literal_offset);
     DCHECK_EQ(adrp & 0xff000000, 0x90000000);
     // TODO: Improve the check. For now, we're just checking if the next insn is
     // the LDR using the result of the ADRP, otherwise we implement the workaround.
     uint32_t next_insn = GetInsn(code, literal_offset + 4u);
     bool ok = (next_insn & 0xffc00000) == 0xb9400000 &&  // LDR <Wt>, [<Xn>, #pimm]
         (((next_insn >> 5) ^ adrp) & 0x1f) == 0;         // <Xn> == ADRP destination reg
     return !ok;
   }
   return false;
 }

 void Arm64RelativePatcher::SetInsn(std::vector<uint8_t>* code, uint32_t offset, uint32_t value) {
   DCHECK_LE(offset + 4u, code->size());
   DCHECK_EQ(offset & 3u, 0u);
   uint8_t* addr = &(*code)[offset];
   addr[0] = (value >> 0) & 0xff;
   addr[1] = (value >> 8) & 0xff;
   addr[2] = (value >> 16) & 0xff;
   addr[3] = (value >> 24) & 0xff;
 }

 uint32_t Arm64RelativePatcher::GetInsn(ArrayRef<const uint8_t> code, uint32_t offset) {
   DCHECK_LE(offset + 4u, code.size());
   DCHECK_EQ(offset & 3u, 0u);
   const uint8_t* addr = &code[offset];
   return
       (static_cast<uint32_t>(addr[0]) << 0) +
       (static_cast<uint32_t>(addr[1]) << 8) +
       (static_cast<uint32_t>(addr[2]) << 16)+
       (static_cast<uint32_t>(addr[3]) << 24);
 }

 template <typename Alloc>
 uint32_t Arm64RelativePatcher::GetInsn(std::vector<uint8_t, Alloc>* code, uint32_t offset) {
   return GetInsn(ArrayRef<const uint8_t>(*code), offset);
 }

 }  // namespace linker
 }  // namespace art
	/*
	* Copyright (C) 2015 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "linker/arm64/relative_patcher_arm64.h"

	#include "arch/arm64/instruction_set_features_arm64.h"
	#include "compiled_method.h"
	#include "driver/compiler_driver.h"
	#include "mirror/art_method.h"
	#include "utils/arm64/assembler_arm64.h"
	#include "oat.h"
	#include "output_stream.h"

	namespace art {
	namespace linker {

	Arm64RelativePatcher::Arm64RelativePatcher(RelativePatcherTargetProvider* provider,
	const Arm64InstructionSetFeatures* features)
	: ArmBaseRelativePatcher(provider, kArm64, CompileThunkCode(),
	kMaxPositiveDisplacement, kMaxNegativeDisplacement),
	fix_cortex_a53_843419_(features->NeedFixCortexA53_843419()),
	reserved_adrp_thunks_(0u),
	processed_adrp_thunks_(0u) {
	if (fix_cortex_a53_843419_) {
	adrp_thunk_locations_.reserve(16u);
	current_method_thunks_.reserve(16u * kAdrpThunkSize);
	}
	}

	uint32_t Arm64RelativePatcher::ReserveSpace(uint32_t offset,
	const CompiledMethod* compiled_method,
	MethodReference method_ref) {
	if (!fix_cortex_a53_843419_) {
	DCHECK(adrp_thunk_locations_.empty());
	return ReserveSpaceInternal(offset, compiled_method, method_ref, 0u);
	}

	// Add thunks for previous method if any.
	if (reserved_adrp_thunks_ != adrp_thunk_locations_.size()) {
	size_t num_adrp_thunks = adrp_thunk_locations_.size() - reserved_adrp_thunks_;
	offset = CompiledMethod::AlignCode(offset, kArm64) + kAdrpThunkSize * num_adrp_thunks;
	reserved_adrp_thunks_ = adrp_thunk_locations_.size();
	}

	// Count the number of ADRP insns as the upper bound on the number of thunks needed
	// and use it to reserve space for other linker patches.
	size_t num_adrp = 0u;
	if (LIKELY(compiled_method != nullptr)) {
	for (const LinkerPatch& patch : compiled_method->GetPatches()) {
	if (patch.Type() == kLinkerPatchDexCacheArray &&
	patch.LiteralOffset() == patch.PcInsnOffset()) { // ADRP patch
	++num_adrp;
	}
	}
	}
	offset = ReserveSpaceInternal(offset, compiled_method, method_ref, kAdrpThunkSize * num_adrp);
	if (num_adrp == 0u) {
	return offset;
	}

	// Now that we have the actual offset where the code will be placed, locate the ADRP insns
	// that actually require the thunk.
	uint32_t quick_code_offset = compiled_method->AlignCode(offset) + sizeof(OatQuickMethodHeader);
	ArrayRef<const uint8_t> code(*compiled_method->GetQuickCode());
	uint32_t thunk_offset = compiled_method->AlignCode(quick_code_offset + code.size());
	DCHECK(compiled_method != nullptr);
	for (const LinkerPatch& patch : compiled_method->GetPatches()) {
	if (patch.Type() == kLinkerPatchDexCacheArray &&
	patch.LiteralOffset() == patch.PcInsnOffset()) { // ADRP patch
	uint32_t patch_offset = quick_code_offset + patch.LiteralOffset();
	if (NeedsErratum843419Thunk(code, patch.LiteralOffset(), patch_offset)) {
	adrp_thunk_locations_.emplace_back(patch_offset, thunk_offset);
	thunk_offset += kAdrpThunkSize;
	}
	}
	}
	return offset;
	}

	uint32_t Arm64RelativePatcher::WriteThunks(OutputStream* out, uint32_t offset) {
	if (fix_cortex_a53_843419_) {
	if (!current_method_thunks_.empty()) {
	uint32_t aligned_offset = CompiledMethod::AlignCode(offset, kArm64);
	if (kIsDebugBuild) {
	CHECK(IsAligned<kAdrpThunkSize>(current_method_thunks_.size()));
	size_t num_thunks = current_method_thunks_.size() / kAdrpThunkSize;
	CHECK_LE(num_thunks, processed_adrp_thunks_);
	for (size_t i = 0u; i != num_thunks; ++i) {
	const auto& entry = adrp_thunk_locations_[processed_adrp_thunks_ - num_thunks + i];
	CHECK_EQ(entry.second, aligned_offset + i * kAdrpThunkSize);
	}
	}
	uint32_t aligned_code_delta = aligned_offset - offset;
	if (aligned_code_delta != 0u && !WriteCodeAlignment(out, aligned_code_delta)) {
	return 0u;
	}
	if (!WriteMiscThunk(out, ArrayRef<const uint8_t>(current_method_thunks_))) {
	return 0u;
	}
	offset = aligned_offset + current_method_thunks_.size();
	current_method_thunks_.clear();
	}
	}
	return ArmBaseRelativePatcher::WriteThunks(out, offset);
	}

	void Arm64RelativePatcher::PatchCall(std::vector<uint8_t>* code, uint32_t literal_offset,
	uint32_t patch_offset, uint32_t target_offset) {
	DCHECK_LE(literal_offset + 4u, code->size());
	DCHECK_EQ(literal_offset & 3u, 0u);
	DCHECK_EQ(patch_offset & 3u, 0u);
	DCHECK_EQ(target_offset & 3u, 0u);
	uint32_t displacement = CalculateDisplacement(patch_offset, target_offset & ~1u);
	DCHECK_EQ(displacement & 3u, 0u);
	DCHECK((displacement >> 27) == 0u \|\| (displacement >> 27) == 31u); // 28-bit signed.
	uint32_t insn = (displacement & 0x0fffffffu) >> 2;
	insn \|= 0x94000000; // BL

	// Check that we're just overwriting an existing BL.
	DCHECK_EQ(GetInsn(code, literal_offset) & 0xfc000000u, 0x94000000u);
	// Write the new BL.
	SetInsn(code, literal_offset, insn);
	}

	void Arm64RelativePatcher::PatchDexCacheReference(std::vector<uint8_t>* code,
	const LinkerPatch& patch,
	uint32_t patch_offset,
	uint32_t target_offset) {
	DCHECK_EQ(patch_offset & 3u, 0u);
	DCHECK_EQ(target_offset & 3u, 0u);
	uint32_t literal_offset = patch.LiteralOffset();
	uint32_t insn = GetInsn(code, literal_offset);
	uint32_t pc_insn_offset = patch.PcInsnOffset();
	uint32_t disp = target_offset - ((patch_offset - literal_offset + pc_insn_offset) & ~0xfffu);
	if (literal_offset == pc_insn_offset) {
	// Check it's an ADRP with imm == 0 (unset).
	DCHECK_EQ((insn & 0xffffffe0u), 0x90000000u)
	<< literal_offset << ", " << pc_insn_offset << ", 0x" << std::hex << insn;
	if (fix_cortex_a53_843419_ && processed_adrp_thunks_ != adrp_thunk_locations_.size() &&
	adrp_thunk_locations_[processed_adrp_thunks_].first == patch_offset) {
	DCHECK(NeedsErratum843419Thunk(ArrayRef<const uint8_t>(*code),
	literal_offset, patch_offset));
	uint32_t thunk_offset = adrp_thunk_locations_[processed_adrp_thunks_].second;
	uint32_t adrp_disp = target_offset - (thunk_offset & ~0xfffu);
	uint32_t adrp = PatchAdrp(insn, adrp_disp);

	uint32_t out_disp = thunk_offset - patch_offset;
	DCHECK_EQ(out_disp & 3u, 0u);
	DCHECK((out_disp >> 27) == 0u \|\| (out_disp >> 27) == 31u); // 28-bit signed.
	insn = (out_disp & 0x0fffffffu) >> 2;
	insn \|= 0x14000000; // B <thunk>

	uint32_t back_disp = -out_disp;
	DCHECK_EQ(back_disp & 3u, 0u);
	DCHECK((back_disp >> 27) == 0u \|\| (back_disp >> 27) == 31u); // 28-bit signed.
	uint32_t b_back = (back_disp & 0x0fffffffu) >> 2;
	b_back \|= 0x14000000; // B <back>
	size_t thunks_code_offset = current_method_thunks_.size();
	current_method_thunks_.resize(thunks_code_offset + kAdrpThunkSize);
	SetInsn(&current_method_thunks_, thunks_code_offset, adrp);
	SetInsn(&current_method_thunks_, thunks_code_offset + 4u, b_back);
	static_assert(kAdrpThunkSize == 2 * 4u, "thunk has 2 instructions");

	processed_adrp_thunks_ += 1u;
	} else {
	insn = PatchAdrp(insn, disp);
	}
	// Write the new ADRP (or B to the erratum 843419 thunk).
	SetInsn(code, literal_offset, insn);
	} else {
	DCHECK_EQ(insn & 0xfffffc00, 0xb9400000); // LDR 32-bit with imm12 == 0 (unset).
	if (kIsDebugBuild) {
	uint32_t adrp = GetInsn(code, pc_insn_offset);
	if ((adrp & 0x9f000000u) != 0x90000000u) {
	CHECK(fix_cortex_a53_843419_);
	CHECK_EQ(adrp & 0xfc000000u, 0x14000000u); // B <thunk>
	CHECK(IsAligned<kAdrpThunkSize>(current_method_thunks_.size()));
	size_t num_thunks = current_method_thunks_.size() / kAdrpThunkSize;
	CHECK_LE(num_thunks, processed_adrp_thunks_);
	uint32_t b_offset = patch_offset - literal_offset + pc_insn_offset;
	for (size_t i = processed_adrp_thunks_ - num_thunks; ; ++i) {
	CHECK_NE(i, processed_adrp_thunks_);
	if (adrp_thunk_locations_[i].first == b_offset) {
	size_t idx = num_thunks - (processed_adrp_thunks_ - i);
	adrp = GetInsn(&current_method_thunks_, idx * kAdrpThunkSize);
	break;
	}
	}
	}
	CHECK_EQ(adrp & 0x9f00001fu, // Check that pc_insn_offset points
	0x90000000 \| ((insn >> 5) & 0x1fu)); // to ADRP with matching register.
	}
	uint32_t imm12 = (disp & 0xfffu) >> 2;
	insn = (insn & ~(0xfffu << 10)) \| (imm12 << 10);
	SetInsn(code, literal_offset, insn);
	}
	}

	std::vector<uint8_t> Arm64RelativePatcher::CompileThunkCode() {
	// The thunk just uses the entry point in the ArtMethod. This works even for calls
	// to the generic JNI and interpreter trampolines.
	arm64::Arm64Assembler assembler;
	Offset offset(mirror::ArtMethod::EntryPointFromQuickCompiledCodeOffset(
	kArm64PointerSize).Int32Value());
	assembler.JumpTo(ManagedRegister(arm64::X0), offset, ManagedRegister(arm64::IP0));
	// Ensure we emit the literal pool.
	assembler.EmitSlowPaths();
	std::vector<uint8_t> thunk_code(assembler.CodeSize());
	MemoryRegion code(thunk_code.data(), thunk_code.size());
	assembler.FinalizeInstructions(code);
	return thunk_code;
	}

	uint32_t Arm64RelativePatcher::PatchAdrp(uint32_t adrp, uint32_t disp) {
	return (adrp & 0x9f00001fu) \| // Clear offset bits, keep ADRP with destination reg.
	// Bottom 12 bits are ignored, the next 2 lowest bits are encoded in bits 29-30.
	((disp & 0x00003000u) << (29 - 12)) \|
	// The next 16 bits are encoded in bits 5-22.
	((disp & 0xffffc000u) >> (12 + 2 - 5)) \|
	// Since the target_offset is based on the beginning of the oat file and the
	// image space precedes the oat file, the target_offset into image space will
	// be negative yet passed as uint32_t. Therefore we limit the displacement
	// to +-2GiB (rather than the maximim +-4GiB) and determine the sign bit from
	// the highest bit of the displacement. This is encoded in bit 23.
	((disp & 0x80000000u) >> (31 - 23));
	}

	bool Arm64RelativePatcher::NeedsErratum843419Thunk(ArrayRef<const uint8_t> code,
	uint32_t literal_offset,
	uint32_t patch_offset) {
	DCHECK_EQ(patch_offset & 0x3u, 0u);
	if ((patch_offset & 0xff8) == 0xff8) { // ...ff8 or ...ffc
	uint32_t adrp = GetInsn(code, literal_offset);
	DCHECK_EQ(adrp & 0xff000000, 0x90000000);
	// TODO: Improve the check. For now, we're just checking if the next insn is
	// the LDR using the result of the ADRP, otherwise we implement the workaround.
	uint32_t next_insn = GetInsn(code, literal_offset + 4u);
	bool ok = (next_insn & 0xffc00000) == 0xb9400000 && // LDR <Wt>, [<Xn>, #pimm]
	(((next_insn >> 5) ^ adrp) & 0x1f) == 0; // <Xn> == ADRP destination reg
	return !ok;
	}
	return false;
	}

	void Arm64RelativePatcher::SetInsn(std::vector<uint8_t>* code, uint32_t offset, uint32_t value) {
	DCHECK_LE(offset + 4u, code->size());
	DCHECK_EQ(offset & 3u, 0u);
	uint8_t* addr = &(*code)[offset];
	addr[0] = (value >> 0) & 0xff;
	addr[1] = (value >> 8) & 0xff;
	addr[2] = (value >> 16) & 0xff;
	addr[3] = (value >> 24) & 0xff;
	}

	uint32_t Arm64RelativePatcher::GetInsn(ArrayRef<const uint8_t> code, uint32_t offset) {
	DCHECK_LE(offset + 4u, code.size());
	DCHECK_EQ(offset & 3u, 0u);
	const uint8_t* addr = &code[offset];
	return
	(static_cast<uint32_t>(addr[0]) << 0) +
	(static_cast<uint32_t>(addr[1]) << 8) +
	(static_cast<uint32_t>(addr[2]) << 16)+
	(static_cast<uint32_t>(addr[3]) << 24);
	}

	template <typename Alloc>
	uint32_t Arm64RelativePatcher::GetInsn(std::vector<uint8_t, Alloc>* code, uint32_t offset) {
	return GetInsn(ArrayRef<const uint8_t>(*code), offset);
	}

	} // namespace linker
	} // namespace art