compiler/jni/quick/x86/calling_convention_x86.cc - LeafOS-Project/android_art - Gitiles

 /*
  * Copyright (C) 2011 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 "calling_convention_x86.h"

 #include "base/logging.h"
 #include "handle_scope-inl.h"
 #include "utils/x86/managed_register_x86.h"

 namespace art {
 namespace x86 {

 static_assert(kX86PointerSize == PointerSize::k32, "Unexpected x86 pointer size");

 static constexpr ManagedRegister kCalleeSaveRegisters[] = {
     // Core registers.
     X86ManagedRegister::FromCpuRegister(EBP),
     X86ManagedRegister::FromCpuRegister(ESI),
     X86ManagedRegister::FromCpuRegister(EDI),
     // No hard float callee saves.
 };

 static constexpr uint32_t CalculateCoreCalleeSpillMask() {
   // The spilled PC gets a special marker.
   uint32_t result = 1 << kNumberOfCpuRegisters;
   for (auto&& r : kCalleeSaveRegisters) {
     if (r.AsX86().IsCpuRegister()) {
       result |= (1 << r.AsX86().AsCpuRegister());
     }
   }
   return result;
 }

 static constexpr uint32_t kCoreCalleeSpillMask = CalculateCoreCalleeSpillMask();
 static constexpr uint32_t kFpCalleeSpillMask = 0u;

 // Calling convention

 ManagedRegister X86ManagedRuntimeCallingConvention::InterproceduralScratchRegister() {
   return X86ManagedRegister::FromCpuRegister(ECX);
 }

 ManagedRegister X86JniCallingConvention::InterproceduralScratchRegister() {
   return X86ManagedRegister::FromCpuRegister(ECX);
 }

 ManagedRegister X86JniCallingConvention::ReturnScratchRegister() const {
   return ManagedRegister::NoRegister();  // No free regs, so assembler uses push/pop
 }

 static ManagedRegister ReturnRegisterForShorty(const char* shorty, bool jni) {
   if (shorty[0] == 'F' || shorty[0] == 'D') {
     if (jni) {
       return X86ManagedRegister::FromX87Register(ST0);
     } else {
       return X86ManagedRegister::FromXmmRegister(XMM0);
     }
   } else if (shorty[0] == 'J') {
     return X86ManagedRegister::FromRegisterPair(EAX_EDX);
   } else if (shorty[0] == 'V') {
     return ManagedRegister::NoRegister();
   } else {
     return X86ManagedRegister::FromCpuRegister(EAX);
   }
 }

 ManagedRegister X86ManagedRuntimeCallingConvention::ReturnRegister() {
   return ReturnRegisterForShorty(GetShorty(), false);
 }

 ManagedRegister X86JniCallingConvention::ReturnRegister() {
   return ReturnRegisterForShorty(GetShorty(), true);
 }

 ManagedRegister X86JniCallingConvention::IntReturnRegister() {
   return X86ManagedRegister::FromCpuRegister(EAX);
 }

 // Managed runtime calling convention

 ManagedRegister X86ManagedRuntimeCallingConvention::MethodRegister() {
   return X86ManagedRegister::FromCpuRegister(EAX);
 }

 bool X86ManagedRuntimeCallingConvention::IsCurrentParamInRegister() {
   return false;  // Everything is passed by stack
 }

 bool X86ManagedRuntimeCallingConvention::IsCurrentParamOnStack() {
   // We assume all parameters are on stack, args coming via registers are spilled as entry_spills.
   return true;
 }

 ManagedRegister X86ManagedRuntimeCallingConvention::CurrentParamRegister() {
   ManagedRegister res = ManagedRegister::NoRegister();
   if (!IsCurrentParamAFloatOrDouble()) {
     switch (gpr_arg_count_) {
       case 0:
         res = X86ManagedRegister::FromCpuRegister(ECX);
         break;
       case 1:
         res = X86ManagedRegister::FromCpuRegister(EDX);
         break;
       case 2:
         // Don't split a long between the last register and the stack.
         if (IsCurrentParamALong()) {
           return ManagedRegister::NoRegister();
         }
         res = X86ManagedRegister::FromCpuRegister(EBX);
         break;
     }
   } else if (itr_float_and_doubles_ < 4) {
     // First four float parameters are passed via XMM0..XMM3
     res = X86ManagedRegister::FromXmmRegister(
                                  static_cast<XmmRegister>(XMM0 + itr_float_and_doubles_));
   }
   return res;
 }

 ManagedRegister X86ManagedRuntimeCallingConvention::CurrentParamHighLongRegister() {
   ManagedRegister res = ManagedRegister::NoRegister();
   DCHECK(IsCurrentParamALong());
   switch (gpr_arg_count_) {
     case 0: res = X86ManagedRegister::FromCpuRegister(EDX); break;
     case 1: res = X86ManagedRegister::FromCpuRegister(EBX); break;
   }
   return res;
 }

 FrameOffset X86ManagedRuntimeCallingConvention::CurrentParamStackOffset() {
   return FrameOffset(displacement_.Int32Value() +   // displacement
                      kFramePointerSize +                 // Method*
                      (itr_slots_ * kFramePointerSize));  // offset into in args
 }

 const ManagedRegisterEntrySpills& X86ManagedRuntimeCallingConvention::EntrySpills() {
   // We spill the argument registers on X86 to free them up for scratch use, we then assume
   // all arguments are on the stack.
   if (entry_spills_.size() == 0) {
     ResetIterator(FrameOffset(0));
     while (HasNext()) {
       ManagedRegister in_reg = CurrentParamRegister();
       bool is_long = IsCurrentParamALong();
       if (!in_reg.IsNoRegister()) {
         int32_t size = IsParamADouble(itr_args_) ? 8 : 4;
         int32_t spill_offset = CurrentParamStackOffset().Uint32Value();
         ManagedRegisterSpill spill(in_reg, size, spill_offset);
         entry_spills_.push_back(spill);
         if (is_long) {
           // special case, as we need a second register here.
           in_reg = CurrentParamHighLongRegister();
           DCHECK(!in_reg.IsNoRegister());
           // We have to spill the second half of the long.
           ManagedRegisterSpill spill2(in_reg, size, spill_offset + 4);
           entry_spills_.push_back(spill2);
         }

         // Keep track of the number of GPRs allocated.
         if (!IsCurrentParamAFloatOrDouble()) {
           if (is_long) {
             // Long was allocated in 2 registers.
             gpr_arg_count_ += 2;
           } else {
             gpr_arg_count_++;
           }
         }
       } else if (is_long) {
         // We need to skip the unused last register, which is empty.
         // If we are already out of registers, this is harmless.
         gpr_arg_count_ += 2;
       }
       Next();
     }
   }
   return entry_spills_;
 }

 // JNI calling convention

 X86JniCallingConvention::X86JniCallingConvention(bool is_static, bool is_synchronized,
                                                  const char* shorty)
     : JniCallingConvention(is_static, is_synchronized, shorty, kX86PointerSize) {
 }

 uint32_t X86JniCallingConvention::CoreSpillMask() const {
   return kCoreCalleeSpillMask;
 }

 uint32_t X86JniCallingConvention::FpSpillMask() const {
   return kFpCalleeSpillMask;
 }

 size_t X86JniCallingConvention::FrameSize() {
   // Method*, return address and callee save area size, local reference segment state
   size_t frame_data_size = static_cast<size_t>(kX86PointerSize) +
       (2 + CalleeSaveRegisters().size()) * kFramePointerSize;
   // References plus 2 words for HandleScope header
   size_t handle_scope_size = HandleScope::SizeOf(kX86PointerSize, ReferenceCount());
   // Plus return value spill area size
   return RoundUp(frame_data_size + handle_scope_size + SizeOfReturnValue(), kStackAlignment);
 }

 size_t X86JniCallingConvention::OutArgSize() {
   return RoundUp(NumberOfOutgoingStackArgs() * kFramePointerSize, kStackAlignment);
 }

 ArrayRef<const ManagedRegister> X86JniCallingConvention::CalleeSaveRegisters() const {
   return ArrayRef<const ManagedRegister>(kCalleeSaveRegisters);
 }

 bool X86JniCallingConvention::IsCurrentParamInRegister() {
   return false;  // Everything is passed by stack.
 }

 bool X86JniCallingConvention::IsCurrentParamOnStack() {
   return true;  // Everything is passed by stack.
 }

 ManagedRegister X86JniCallingConvention::CurrentParamRegister() {
   LOG(FATAL) << "Should not reach here";
   return ManagedRegister::NoRegister();
 }

 FrameOffset X86JniCallingConvention::CurrentParamStackOffset() {
   return FrameOffset(displacement_.Int32Value() - OutArgSize() + (itr_slots_ * kFramePointerSize));
 }

 size_t X86JniCallingConvention::NumberOfOutgoingStackArgs() {
   size_t static_args = IsStatic() ? 1 : 0;  // count jclass
   // regular argument parameters and this
   size_t param_args = NumArgs() + NumLongOrDoubleArgs();
   // count JNIEnv* and return pc (pushed after Method*)
   size_t total_args = static_args + param_args + 2;
   return total_args;
 }

 }  // namespace x86
 }  // namespace art
	/*
	* Copyright (C) 2011 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 "calling_convention_x86.h"

	#include "base/logging.h"
	#include "handle_scope-inl.h"
	#include "utils/x86/managed_register_x86.h"

	namespace art {
	namespace x86 {

	static_assert(kX86PointerSize == PointerSize::k32, "Unexpected x86 pointer size");

	static constexpr ManagedRegister kCalleeSaveRegisters[] = {
	// Core registers.
	X86ManagedRegister::FromCpuRegister(EBP),
	X86ManagedRegister::FromCpuRegister(ESI),
	X86ManagedRegister::FromCpuRegister(EDI),
	// No hard float callee saves.
	};

	static constexpr uint32_t CalculateCoreCalleeSpillMask() {
	// The spilled PC gets a special marker.
	uint32_t result = 1 << kNumberOfCpuRegisters;
	for (auto&& r : kCalleeSaveRegisters) {
	if (r.AsX86().IsCpuRegister()) {
	result \|= (1 << r.AsX86().AsCpuRegister());
	}
	}
	return result;
	}

	static constexpr uint32_t kCoreCalleeSpillMask = CalculateCoreCalleeSpillMask();
	static constexpr uint32_t kFpCalleeSpillMask = 0u;

	// Calling convention

	ManagedRegister X86ManagedRuntimeCallingConvention::InterproceduralScratchRegister() {
	return X86ManagedRegister::FromCpuRegister(ECX);
	}

	ManagedRegister X86JniCallingConvention::InterproceduralScratchRegister() {
	return X86ManagedRegister::FromCpuRegister(ECX);
	}

	ManagedRegister X86JniCallingConvention::ReturnScratchRegister() const {
	return ManagedRegister::NoRegister(); // No free regs, so assembler uses push/pop
	}

	static ManagedRegister ReturnRegisterForShorty(const char* shorty, bool jni) {
	if (shorty[0] == 'F' \|\| shorty[0] == 'D') {
	if (jni) {
	return X86ManagedRegister::FromX87Register(ST0);
	} else {
	return X86ManagedRegister::FromXmmRegister(XMM0);
	}
	} else if (shorty[0] == 'J') {
	return X86ManagedRegister::FromRegisterPair(EAX_EDX);
	} else if (shorty[0] == 'V') {
	return ManagedRegister::NoRegister();
	} else {
	return X86ManagedRegister::FromCpuRegister(EAX);
	}
	}

	ManagedRegister X86ManagedRuntimeCallingConvention::ReturnRegister() {
	return ReturnRegisterForShorty(GetShorty(), false);
	}

	ManagedRegister X86JniCallingConvention::ReturnRegister() {
	return ReturnRegisterForShorty(GetShorty(), true);
	}

	ManagedRegister X86JniCallingConvention::IntReturnRegister() {
	return X86ManagedRegister::FromCpuRegister(EAX);
	}

	// Managed runtime calling convention

	ManagedRegister X86ManagedRuntimeCallingConvention::MethodRegister() {
	return X86ManagedRegister::FromCpuRegister(EAX);
	}

	bool X86ManagedRuntimeCallingConvention::IsCurrentParamInRegister() {
	return false; // Everything is passed by stack
	}

	bool X86ManagedRuntimeCallingConvention::IsCurrentParamOnStack() {
	// We assume all parameters are on stack, args coming via registers are spilled as entry_spills.
	return true;
	}

	ManagedRegister X86ManagedRuntimeCallingConvention::CurrentParamRegister() {
	ManagedRegister res = ManagedRegister::NoRegister();
	if (!IsCurrentParamAFloatOrDouble()) {
	switch (gpr_arg_count_) {
	case 0:
	res = X86ManagedRegister::FromCpuRegister(ECX);
	break;
	case 1:
	res = X86ManagedRegister::FromCpuRegister(EDX);
	break;
	case 2:
	// Don't split a long between the last register and the stack.
	if (IsCurrentParamALong()) {
	return ManagedRegister::NoRegister();
	}
	res = X86ManagedRegister::FromCpuRegister(EBX);
	break;
	}
	} else if (itr_float_and_doubles_ < 4) {
	// First four float parameters are passed via XMM0..XMM3
	res = X86ManagedRegister::FromXmmRegister(
	static_cast<XmmRegister>(XMM0 + itr_float_and_doubles_));
	}
	return res;
	}

	ManagedRegister X86ManagedRuntimeCallingConvention::CurrentParamHighLongRegister() {
	ManagedRegister res = ManagedRegister::NoRegister();
	DCHECK(IsCurrentParamALong());
	switch (gpr_arg_count_) {
	case 0: res = X86ManagedRegister::FromCpuRegister(EDX); break;
	case 1: res = X86ManagedRegister::FromCpuRegister(EBX); break;
	}
	return res;
	}

	FrameOffset X86ManagedRuntimeCallingConvention::CurrentParamStackOffset() {
	return FrameOffset(displacement_.Int32Value() + // displacement
	kFramePointerSize + // Method*
	(itr_slots_ * kFramePointerSize)); // offset into in args
	}

	const ManagedRegisterEntrySpills& X86ManagedRuntimeCallingConvention::EntrySpills() {
	// We spill the argument registers on X86 to free them up for scratch use, we then assume
	// all arguments are on the stack.
	if (entry_spills_.size() == 0) {
	ResetIterator(FrameOffset(0));
	while (HasNext()) {
	ManagedRegister in_reg = CurrentParamRegister();
	bool is_long = IsCurrentParamALong();
	if (!in_reg.IsNoRegister()) {
	int32_t size = IsParamADouble(itr_args_) ? 8 : 4;
	int32_t spill_offset = CurrentParamStackOffset().Uint32Value();
	ManagedRegisterSpill spill(in_reg, size, spill_offset);
	entry_spills_.push_back(spill);
	if (is_long) {
	// special case, as we need a second register here.
	in_reg = CurrentParamHighLongRegister();
	DCHECK(!in_reg.IsNoRegister());
	// We have to spill the second half of the long.
	ManagedRegisterSpill spill2(in_reg, size, spill_offset + 4);
	entry_spills_.push_back(spill2);
	}

	// Keep track of the number of GPRs allocated.
	if (!IsCurrentParamAFloatOrDouble()) {
	if (is_long) {
	// Long was allocated in 2 registers.
	gpr_arg_count_ += 2;
	} else {
	gpr_arg_count_++;
	}
	}
	} else if (is_long) {
	// We need to skip the unused last register, which is empty.
	// If we are already out of registers, this is harmless.
	gpr_arg_count_ += 2;
	}
	Next();
	}
	}
	return entry_spills_;
	}

	// JNI calling convention

	X86JniCallingConvention::X86JniCallingConvention(bool is_static, bool is_synchronized,
	const char* shorty)
	: JniCallingConvention(is_static, is_synchronized, shorty, kX86PointerSize) {
	}

	uint32_t X86JniCallingConvention::CoreSpillMask() const {
	return kCoreCalleeSpillMask;
	}

	uint32_t X86JniCallingConvention::FpSpillMask() const {
	return kFpCalleeSpillMask;
	}

	size_t X86JniCallingConvention::FrameSize() {
	// Method*, return address and callee save area size, local reference segment state
	size_t frame_data_size = static_cast<size_t>(kX86PointerSize) +
	(2 + CalleeSaveRegisters().size()) * kFramePointerSize;
	// References plus 2 words for HandleScope header
	size_t handle_scope_size = HandleScope::SizeOf(kX86PointerSize, ReferenceCount());
	// Plus return value spill area size
	return RoundUp(frame_data_size + handle_scope_size + SizeOfReturnValue(), kStackAlignment);
	}

	size_t X86JniCallingConvention::OutArgSize() {
	return RoundUp(NumberOfOutgoingStackArgs() * kFramePointerSize, kStackAlignment);
	}

	ArrayRef<const ManagedRegister> X86JniCallingConvention::CalleeSaveRegisters() const {
	return ArrayRef<const ManagedRegister>(kCalleeSaveRegisters);
	}

	bool X86JniCallingConvention::IsCurrentParamInRegister() {
	return false; // Everything is passed by stack.
	}

	bool X86JniCallingConvention::IsCurrentParamOnStack() {
	return true; // Everything is passed by stack.
	}

	ManagedRegister X86JniCallingConvention::CurrentParamRegister() {
	LOG(FATAL) << "Should not reach here";
	return ManagedRegister::NoRegister();
	}

	FrameOffset X86JniCallingConvention::CurrentParamStackOffset() {
	return FrameOffset(displacement_.Int32Value() - OutArgSize() + (itr_slots_ * kFramePointerSize));
	}

	size_t X86JniCallingConvention::NumberOfOutgoingStackArgs() {
	size_t static_args = IsStatic() ? 1 : 0; // count jclass
	// regular argument parameters and this
	size_t param_args = NumArgs() + NumLongOrDoubleArgs();
	// count JNIEnv* and return pc (pushed after Method*)
	size_t total_args = static_args + param_args + 2;
	return total_args;
	}

	} // namespace x86
	} // namespace art