vm/InlineNative.h - platform/dalvik-snapshot - Git at Google

 /*
  * Copyright (C) 2008 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.
  */

 /*
  * Inlined native functions.
  */
 #ifndef DALVIK_INLINENATIVE_H_
 #define DALVIK_INLINENATIVE_H_

 /* startup/shutdown */
 bool dvmInlineNativeStartup(void);
 void dvmInlineNativeShutdown(void);

 Method* dvmFindInlinableMethod(const char* classDescriptor,
     const char* methodName, const char* methodSignature);

 /*
  * Basic 4-argument inline operation handler.
  */
 typedef bool (*InlineOp4Func)(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
     JValue* pResult);

 /*
  * Table of inline operations.
  *
  * Try to keep this at a power-of-two size, so we don't have to multiply.
  *
  * TODO: might be to our advantage to generate a compact jump table on
  * the heap at runtime (or just declare two static tables, one with full
  * info and one with just function pointers).  Especially useful if we decide
  * to support other method call forms, e.g. /range.  We can also just
  * generate assembly code that knows how many args it needs and has the
  * target address embedded.
  */
 struct InlineOperation {
     InlineOp4Func   func;               /* MUST be first entry */
     const char*     classDescriptor;
     const char*     methodName;
     const char*     methodSignature;
 };

 /*
  * Must be kept in sync w/ gDvmInlineOpsTable in InlineNative.c
  *
  * You should also add a test to libcore's IntrinsicTest.
  */
 enum NativeInlineOps {
     INLINE_EMPTYINLINEMETHOD = 0,
     INLINE_STRING_CHARAT = 1,
     INLINE_STRING_COMPARETO = 2,
     INLINE_STRING_EQUALS = 3,
     INLINE_STRING_FASTINDEXOF_II = 4,
     INLINE_STRING_IS_EMPTY = 5,
     INLINE_STRING_LENGTH = 6,
     INLINE_MATH_ABS_INT = 7,
     INLINE_MATH_ABS_LONG = 8,
     INLINE_MATH_ABS_FLOAT = 9,
     INLINE_MATH_ABS_DOUBLE = 10,
     INLINE_MATH_MIN_INT = 11,
     INLINE_MATH_MAX_INT = 12,
     INLINE_MATH_SQRT = 13,
     INLINE_MATH_COS = 14,
     INLINE_MATH_SIN = 15,
     INLINE_FLOAT_TO_INT_BITS = 16,
     INLINE_FLOAT_TO_RAW_INT_BITS = 17,
     INLINE_INT_BITS_TO_FLOAT = 18,
     INLINE_DOUBLE_TO_LONG_BITS = 19,
     INLINE_DOUBLE_TO_RAW_LONG_BITS = 20,
     INLINE_LONG_BITS_TO_DOUBLE = 21,
 };

 /*
  * Get the inlineops table.
  */
 const InlineOperation* dvmGetInlineOpsTable(void);
 int dvmGetInlineOpsTableLength(void);

 /*
  * The table, exposed so we can access it with C inlines.  Prefer access
  * through dvmGetInlineOpsTable().
  */
 extern const InlineOperation gDvmInlineOpsTable[];

 /*
  * Perform the operation specified by "opIndex".
  *
  * We want the arguments to appear in the first 4 registers so they can
  * be passed straight through to the handler function.  Ideally on ARM
  * they'll go into r0-r3 and stay there.
  *
  * Returns "true" if everything went normally, "false" if an exception
  * was thrown.
  */
 INLINE bool dvmPerformInlineOp4Std(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
     JValue* pResult, int opIndex)
 {
     return (*gDvmInlineOpsTable[opIndex].func)(arg0, arg1, arg2, arg3, pResult);
 }

 /*
  * Like the "std" version, but will emit profiling info.
  */
 bool dvmPerformInlineOp4Dbg(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
     JValue* pResult, int opIndex);

 /*
  * Return method & populate the table on first use.
  */
 extern "C" Method* dvmResolveInlineNative(int opIndex);

 /*
  * The actual inline native definitions.
  */
 bool javaLangString_charAt(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                            JValue* pResult);

 bool javaLangString_compareTo(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                               JValue* pResult);

 bool javaLangString_equals(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                            JValue* pResult);

 bool javaLangString_length(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                            JValue* pResult);

 bool javaLangString_isEmpty(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                             JValue* pResult);

 bool javaLangString_fastIndexOf_II(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                                    JValue* pResult);

 bool javaLangMath_abs_int(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                           JValue* pResult);

 bool javaLangMath_abs_long(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                            JValue* pResult);

 bool javaLangMath_abs_float(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                             JValue* pResult);

 bool javaLangMath_abs_double(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                              JValue* pResult);

 bool javaLangMath_min_int(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                           JValue* pResult);

 bool javaLangMath_max_int(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                           JValue* pResult);

 bool javaLangMath_sqrt(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                        JValue* pResult);

 bool javaLangMath_cos(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                       JValue* pResult);

 bool javaLangMath_sin(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
                       JValue* pResult);

 bool javaLangFloat_floatToIntBits(u4 arg0, u4 arg1, u4 arg2, u4 arg,
                                   JValue* pResult);

 bool javaLangFloat_floatToRawIntBits(u4 arg0, u4 arg1, u4 arg2, u4 arg,
                                      JValue* pResult);

 bool javaLangFloat_intBitsToFloat(u4 arg0, u4 arg1, u4 arg2, u4 arg,
                                   JValue* pResult);

 bool javaLangDouble_doubleToLongBits(u4 arg0, u4 arg1, u4 arg2, u4 arg,
                                      JValue* pResult);

 bool javaLangDouble_longBitsToDouble(u4 arg0, u4 arg1, u4 arg2, u4 arg,
                                      JValue* pResult);

 bool javaLangDouble_doubleToRawLongBits(u4 arg0, u4 arg1, u4 arg2,
                                         u4 arg, JValue* pResult);

 bool javaLangDouble_longBitsToDouble(u4 arg0, u4 arg1, u4 arg2, u4 arg,
                                      JValue* pResult);

 #endif  // DALVIK_INLINENATIVE_H_
	/*
	* Copyright (C) 2008 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.
	*/

	/*
	* Inlined native functions.
	*/
	#ifndef DALVIK_INLINENATIVE_H_
	#define DALVIK_INLINENATIVE_H_

	/* startup/shutdown */
	bool dvmInlineNativeStartup(void);
	void dvmInlineNativeShutdown(void);

	Method* dvmFindInlinableMethod(const char* classDescriptor,
	const char* methodName, const char* methodSignature);

	/*
	* Basic 4-argument inline operation handler.
	*/
	typedef bool (*InlineOp4Func)(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	/*
	* Table of inline operations.
	*
	* Try to keep this at a power-of-two size, so we don't have to multiply.
	*
	* TODO: might be to our advantage to generate a compact jump table on
	* the heap at runtime (or just declare two static tables, one with full
	* info and one with just function pointers). Especially useful if we decide
	* to support other method call forms, e.g. /range. We can also just
	* generate assembly code that knows how many args it needs and has the
	* target address embedded.
	*/
	struct InlineOperation {
	InlineOp4Func func; /* MUST be first entry */
	const char* classDescriptor;
	const char* methodName;
	const char* methodSignature;
	};

	/*
	* Must be kept in sync w/ gDvmInlineOpsTable in InlineNative.c
	*
	* You should also add a test to libcore's IntrinsicTest.
	*/
	enum NativeInlineOps {
	INLINE_EMPTYINLINEMETHOD = 0,
	INLINE_STRING_CHARAT = 1,
	INLINE_STRING_COMPARETO = 2,
	INLINE_STRING_EQUALS = 3,
	INLINE_STRING_FASTINDEXOF_II = 4,
	INLINE_STRING_IS_EMPTY = 5,
	INLINE_STRING_LENGTH = 6,
	INLINE_MATH_ABS_INT = 7,
	INLINE_MATH_ABS_LONG = 8,
	INLINE_MATH_ABS_FLOAT = 9,
	INLINE_MATH_ABS_DOUBLE = 10,
	INLINE_MATH_MIN_INT = 11,
	INLINE_MATH_MAX_INT = 12,
	INLINE_MATH_SQRT = 13,
	INLINE_MATH_COS = 14,
	INLINE_MATH_SIN = 15,
	INLINE_FLOAT_TO_INT_BITS = 16,
	INLINE_FLOAT_TO_RAW_INT_BITS = 17,
	INLINE_INT_BITS_TO_FLOAT = 18,
	INLINE_DOUBLE_TO_LONG_BITS = 19,
	INLINE_DOUBLE_TO_RAW_LONG_BITS = 20,
	INLINE_LONG_BITS_TO_DOUBLE = 21,
	};

	/*
	* Get the inlineops table.
	*/
	const InlineOperation* dvmGetInlineOpsTable(void);
	int dvmGetInlineOpsTableLength(void);

	/*
	* The table, exposed so we can access it with C inlines. Prefer access
	* through dvmGetInlineOpsTable().
	*/
	extern const InlineOperation gDvmInlineOpsTable[];

	/*
	* Perform the operation specified by "opIndex".
	*
	* We want the arguments to appear in the first 4 registers so they can
	* be passed straight through to the handler function. Ideally on ARM
	* they'll go into r0-r3 and stay there.
	*
	* Returns "true" if everything went normally, "false" if an exception
	* was thrown.
	*/
	INLINE bool dvmPerformInlineOp4Std(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult, int opIndex)
	{
	return (*gDvmInlineOpsTable[opIndex].func)(arg0, arg1, arg2, arg3, pResult);
	}

	/*
	* Like the "std" version, but will emit profiling info.
	*/
	bool dvmPerformInlineOp4Dbg(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult, int opIndex);

	/*
	* Return method & populate the table on first use.
	*/
	extern "C" Method* dvmResolveInlineNative(int opIndex);

	/*
	* The actual inline native definitions.
	*/
	bool javaLangString_charAt(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangString_compareTo(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangString_equals(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangString_length(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangString_isEmpty(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangString_fastIndexOf_II(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_abs_int(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_abs_long(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_abs_float(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_abs_double(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_min_int(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_max_int(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_sqrt(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_cos(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangMath_sin(u4 arg0, u4 arg1, u4 arg2, u4 arg3,
	JValue* pResult);

	bool javaLangFloat_floatToIntBits(u4 arg0, u4 arg1, u4 arg2, u4 arg,
	JValue* pResult);

	bool javaLangFloat_floatToRawIntBits(u4 arg0, u4 arg1, u4 arg2, u4 arg,
	JValue* pResult);

	bool javaLangFloat_intBitsToFloat(u4 arg0, u4 arg1, u4 arg2, u4 arg,
	JValue* pResult);

	bool javaLangDouble_doubleToLongBits(u4 arg0, u4 arg1, u4 arg2, u4 arg,
	JValue* pResult);

	bool javaLangDouble_longBitsToDouble(u4 arg0, u4 arg1, u4 arg2, u4 arg,
	JValue* pResult);

	bool javaLangDouble_doubleToRawLongBits(u4 arg0, u4 arg1, u4 arg2,
	u4 arg, JValue* pResult);

	bool javaLangDouble_longBitsToDouble(u4 arg0, u4 arg1, u4 arg2, u4 arg,
	JValue* pResult);

	#endif // DALVIK_INLINENATIVE_H_