runtime/vm/runtime_entry_arm64.cc - sdk.git - Git at Google

 // Copyright (c) 2014, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "vm/globals.h"
 #if defined(TARGET_ARCH_ARM64)

 #include "vm/runtime_entry.h"

 #include "vm/simulator.h"
 #include "vm/stub_code.h"

 #if !defined(DART_PRECOMPILED_RUNTIME)
 #include "vm/compiler/assembler/assembler.h"
 #endif  // !defined(DART_PRECOMPILED_RUNTIME)

 namespace dart {

 #define __ assembler->

 uword RuntimeEntry::GetEntryPoint() const {
   // Compute the effective address. When running under the simulator,
   // this is a redirection address that forces the simulator to call
   // into the runtime system.
   uword entry = reinterpret_cast<uword>(function());
 #if defined(USING_SIMULATOR)
   // Redirection to leaf runtime calls supports a maximum of 4 arguments passed
   // in registers (maximum 2 double arguments for leaf float runtime calls).
   ASSERT(argument_count() >= 0);
   ASSERT(!is_leaf() || (!is_float() && (argument_count() <= 4)) ||
          (argument_count() <= 2));
   Simulator::CallKind call_kind =
       is_leaf() ? (is_float() ? Simulator::kLeafFloatRuntimeCall
                               : Simulator::kLeafRuntimeCall)
                 : Simulator::kRuntimeCall;
   entry =
       Simulator::RedirectExternalReference(entry, call_kind, argument_count());
 #endif
   return entry;
 }

 #if !defined(DART_PRECOMPILED_RUNTIME)
 // Generate code to call into the stub which will call the runtime
 // function. Input for the stub is as follows:
 //   SP : points to the arguments and return value array.
 //   R5 : address of the runtime function to call.
 //   R4 : number of arguments to the call.
 void RuntimeEntry::CallInternal(const RuntimeEntry* runtime_entry,
                                 compiler::Assembler* assembler,
                                 intptr_t argument_count) {
   if (runtime_entry->is_leaf()) {
     ASSERT(argument_count == runtime_entry->argument_count());
     // Since we are entering C++ code, we must restore the C stack pointer from
     // the stack limit to an aligned value nearer to the top of the stack.
     // We cache the Dart stack pointer and the stack limit in callee-saved
     // registers, then align and call, restoring CSP and SP on return from the
     // call.
     // This sequence may occur in an intrinsic, so don't use registers an
     // intrinsic must preserve.
     COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch1 != CODE_REG);
     COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch2 != CODE_REG);
     COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch1 != ARGS_DESC_REG);
     COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch2 != ARGS_DESC_REG);
     __ mov(kCallLeafRuntimeCalleeSaveScratch1, CSP);
     __ mov(kCallLeafRuntimeCalleeSaveScratch2, SP);
     __ ReserveAlignedFrameSpace(0);
     __ mov(CSP, SP);
     __ ldr(TMP,
            compiler::Address(THR, Thread::OffsetFromThread(runtime_entry)));
     __ str(TMP, compiler::Address(THR, Thread::vm_tag_offset()));
     __ blr(TMP);
     __ LoadImmediate(TMP, VMTag::kDartTagId);
     __ str(TMP, compiler::Address(THR, Thread::vm_tag_offset()));
     __ mov(SP, kCallLeafRuntimeCalleeSaveScratch2);
     __ mov(CSP, kCallLeafRuntimeCalleeSaveScratch1);
     // These registers must be preserved by runtime functions, otherwise
     // we'd need to restore them here.
     COMPILE_ASSERT(IsCalleeSavedRegister(THR));
     COMPILE_ASSERT(IsCalleeSavedRegister(PP));
     COMPILE_ASSERT(IsCalleeSavedRegister(CODE_REG));
     COMPILE_ASSERT(IsCalleeSavedRegister(NULL_REG));
     COMPILE_ASSERT(IsCalleeSavedRegister(HEAP_BITS));
     COMPILE_ASSERT(IsCalleeSavedRegister(DISPATCH_TABLE_REG));
   } else {
     // Argument count is not checked here, but in the runtime entry for a more
     // informative error message.
     __ ldr(R5, compiler::Address(THR, Thread::OffsetFromThread(runtime_entry)));
     __ LoadImmediate(R4, argument_count);
     __ BranchLinkToRuntime();
   }
 }
 #endif  // !defined(DART_PRECOMPILED_RUNTIME)

 }  // namespace dart

 #endif  // defined TARGET_ARCH_ARM64
	// Copyright (c) 2014, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "vm/globals.h"
	#if defined(TARGET_ARCH_ARM64)

	#include "vm/runtime_entry.h"

	#include "vm/simulator.h"
	#include "vm/stub_code.h"

	#if !defined(DART_PRECOMPILED_RUNTIME)
	#include "vm/compiler/assembler/assembler.h"
	#endif // !defined(DART_PRECOMPILED_RUNTIME)

	namespace dart {

	#define __ assembler->

	uword RuntimeEntry::GetEntryPoint() const {
	// Compute the effective address. When running under the simulator,
	// this is a redirection address that forces the simulator to call
	// into the runtime system.
	uword entry = reinterpret_cast<uword>(function());
	#if defined(USING_SIMULATOR)
	// Redirection to leaf runtime calls supports a maximum of 4 arguments passed
	// in registers (maximum 2 double arguments for leaf float runtime calls).
	ASSERT(argument_count() >= 0);
	ASSERT(!is_leaf() \|\| (!is_float() && (argument_count() <= 4)) \|\|
	(argument_count() <= 2));
	Simulator::CallKind call_kind =
	is_leaf() ? (is_float() ? Simulator::kLeafFloatRuntimeCall
	: Simulator::kLeafRuntimeCall)
	: Simulator::kRuntimeCall;
	entry =
	Simulator::RedirectExternalReference(entry, call_kind, argument_count());
	#endif
	return entry;
	}

	#if !defined(DART_PRECOMPILED_RUNTIME)
	// Generate code to call into the stub which will call the runtime
	// function. Input for the stub is as follows:
	// SP : points to the arguments and return value array.
	// R5 : address of the runtime function to call.
	// R4 : number of arguments to the call.
	void RuntimeEntry::CallInternal(const RuntimeEntry* runtime_entry,
	compiler::Assembler* assembler,
	intptr_t argument_count) {
	if (runtime_entry->is_leaf()) {
	ASSERT(argument_count == runtime_entry->argument_count());
	// Since we are entering C++ code, we must restore the C stack pointer from
	// the stack limit to an aligned value nearer to the top of the stack.
	// We cache the Dart stack pointer and the stack limit in callee-saved
	// registers, then align and call, restoring CSP and SP on return from the
	// call.
	// This sequence may occur in an intrinsic, so don't use registers an
	// intrinsic must preserve.
	COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch1 != CODE_REG);
	COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch2 != CODE_REG);
	COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch1 != ARGS_DESC_REG);
	COMPILE_ASSERT(kCallLeafRuntimeCalleeSaveScratch2 != ARGS_DESC_REG);
	__ mov(kCallLeafRuntimeCalleeSaveScratch1, CSP);
	__ mov(kCallLeafRuntimeCalleeSaveScratch2, SP);
	__ ReserveAlignedFrameSpace(0);
	__ mov(CSP, SP);
	__ ldr(TMP,
	compiler::Address(THR, Thread::OffsetFromThread(runtime_entry)));
	__ str(TMP, compiler::Address(THR, Thread::vm_tag_offset()));
	__ blr(TMP);
	__ LoadImmediate(TMP, VMTag::kDartTagId);
	__ str(TMP, compiler::Address(THR, Thread::vm_tag_offset()));
	__ mov(SP, kCallLeafRuntimeCalleeSaveScratch2);
	__ mov(CSP, kCallLeafRuntimeCalleeSaveScratch1);
	// These registers must be preserved by runtime functions, otherwise
	// we'd need to restore them here.
	COMPILE_ASSERT(IsCalleeSavedRegister(THR));
	COMPILE_ASSERT(IsCalleeSavedRegister(PP));
	COMPILE_ASSERT(IsCalleeSavedRegister(CODE_REG));
	COMPILE_ASSERT(IsCalleeSavedRegister(NULL_REG));
	COMPILE_ASSERT(IsCalleeSavedRegister(HEAP_BITS));
	COMPILE_ASSERT(IsCalleeSavedRegister(DISPATCH_TABLE_REG));
	} else {
	// Argument count is not checked here, but in the runtime entry for a more
	// informative error message.
	__ ldr(R5, compiler::Address(THR, Thread::OffsetFromThread(runtime_entry)));
	__ LoadImmediate(R4, argument_count);
	__ BranchLinkToRuntime();
	}
	}
	#endif // !defined(DART_PRECOMPILED_RUNTIME)

	} // namespace dart

	#endif // defined TARGET_ARCH_ARM64