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lxdream.org :: lxdream/src/sh4/ia32abi.h
lxdream 0.9.1
released Jun 29
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filename src/sh4/ia32abi.h
changeset 570:d2893980fbf5
prev569:a1c49e1e8776
next571:9bc09948d0f2
author nkeynes
date Sun Jan 06 12:24:18 2008 +0000 (14 years ago)
branchlxdream-mmu
permissions -rw-r--r--
last change Change to generate different code for mmu on/off cases
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     1 /**
     2  * $Id$
     3  * 
     4  * Provides the implementation for the ia32 ABI (eg prologue, epilogue, and
     5  * calling conventions)
     6  *
     7  * Copyright (c) 2007 Nathan Keynes.
     8  *
     9  * This program is free software; you can redistribute it and/or modify
    10  * it under the terms of the GNU General Public License as published by
    11  * the Free Software Foundation; either version 2 of the License, or
    12  * (at your option) any later version.
    13  *
    14  * This program is distributed in the hope that it will be useful,
    15  * but WITHOUT ANY WARRANTY; without even the implied warranty of
    16  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    17  * GNU General Public License for more details.
    18  */
    20 #ifndef __lxdream_ia32abi_H
    21 #define __lxdream_ia32abi_H 1
    23 #define load_ptr( reg, ptr ) load_imm32( reg, (uint32_t)ptr );
    25 /**
    26  * Note: clobbers EAX to make the indirect call - this isn't usually
    27  * a problem since the callee will usually clobber it anyway.
    28  */
    29 #define CALL_FUNC0_SIZE 7
    30 static inline void call_func0( void *ptr )
    31 {
    32     load_imm32(R_EAX, (uint32_t)ptr);
    33     CALL_r32(R_EAX);
    34 }
    36 #define CALL_FUNC1_SIZE 11
    37 static inline void call_func1( void *ptr, int arg1 )
    38 {
    39     PUSH_r32(arg1);
    40     call_func0(ptr);
    41     ADD_imm8s_r32( 4, R_ESP );
    42 }
    44 #define CALL_FUNC2_SIZE 12
    45 static inline void call_func2( void *ptr, int arg1, int arg2 )
    46 {
    47     PUSH_r32(arg2);
    48     PUSH_r32(arg1);
    49     call_func0(ptr);
    50     ADD_imm8s_r32( 8, R_ESP );
    51 }
    53 /**
    54  * Write a double (64-bit) value into memory, with the first word in arg2a, and
    55  * the second in arg2b
    56  * NB: 30 bytes
    57  */
    58 #define MEM_WRITE_DOUBLE_SIZE 30
    59 static inline void MEM_WRITE_DOUBLE( int addr, int arg2a, int arg2b )
    60 {
    61     ADD_imm8s_r32( 4, addr );
    62     PUSH_r32(arg2b);
    63     PUSH_r32(addr);
    64     ADD_imm8s_r32( -4, addr );
    65     PUSH_r32(arg2a);
    66     PUSH_r32(addr);
    67     call_func0(sh4_write_long);
    68     ADD_imm8s_r32( 8, R_ESP );
    69     call_func0(sh4_write_long);
    70     ADD_imm8s_r32( 8, R_ESP );
    71 }
    73 /**
    74  * Read a double (64-bit) value from memory, writing the first word into arg2a
    75  * and the second into arg2b. The addr must not be in EAX
    76  * NB: 27 bytes
    77  */
    78 #define MEM_READ_DOUBLE_SIZE 27
    79 static inline void MEM_READ_DOUBLE( int addr, int arg2a, int arg2b )
    80 {
    81     PUSH_r32(addr);
    82     call_func0(sh4_read_long);
    83     POP_r32(addr);
    84     PUSH_r32(R_EAX);
    85     ADD_imm8s_r32( 4, addr );
    86     PUSH_r32(addr);
    87     call_func0(sh4_read_long);
    88     ADD_imm8s_r32( 4, R_ESP );
    89     MOV_r32_r32( R_EAX, arg2b );
    90     POP_r32(arg2a);
    91 }
    93 #define EXIT_BLOCK_SIZE 29
    96 /**
    97  * Emit the 'start of block' assembly. Sets up the stack frame and save
    98  * SI/DI as required
    99  */
   100 void sh4_translate_begin_block( sh4addr_t pc ) 
   101 {
   102     PUSH_r32(R_EBP);
   103     /* mov &sh4r, ebp */
   104     load_ptr( R_EBP, &sh4r );
   106     sh4_x86.in_delay_slot = FALSE;
   107     sh4_x86.priv_checked = FALSE;
   108     sh4_x86.fpuen_checked = FALSE;
   109     sh4_x86.branch_taken = FALSE;
   110     sh4_x86.backpatch_posn = 0;
   111     sh4_x86.block_start_pc = pc;
   112     sh4_x86.tlb_on = MMIO_READ(MMU,MMUCR)&MMUCR_AT;
   113     sh4_x86.tstate = TSTATE_NONE;
   114 #ifdef STACK_ALIGN
   115 	sh4_x86.stack_posn = 8;
   116 #endif
   117 }
   119 /**
   120  * Exit the block with sh4r.pc already written
   121  * Bytes: 15
   122  */
   123 void exit_block_pcset( sh4addr_t pc )
   124 {
   125     load_imm32( R_ECX, ((pc - sh4_x86.block_start_pc)>>1)*sh4_cpu_period ); // 5
   126     ADD_r32_sh4r( R_ECX, REG_OFFSET(slice_cycle) );    // 6
   127     load_spreg( R_EAX, REG_OFFSET(pc) );
   128     if( sh4_x86.tlb_on ) {
   129 	call_func1(xlat_get_code_by_vma,R_EAX);
   130     } else {
   131 	call_func1(xlat_get_code,R_EAX);
   132     } 
   133     POP_r32(R_EBP);
   134     RET();
   135 }
   137 /**
   138  * Exit the block to an absolute PC
   139  */
   140 void exit_block( sh4addr_t pc, sh4addr_t endpc )
   141 {
   142     load_imm32( R_ECX, pc );                            // 5
   143     store_spreg( R_ECX, REG_OFFSET(pc) );               // 3
   144     MOV_moff32_EAX( xlat_get_lut_entry(pc) ); // 5
   145     AND_imm8s_r32( 0xFC, R_EAX ); // 3
   146     load_imm32( R_ECX, ((endpc - sh4_x86.block_start_pc)>>1)*sh4_cpu_period ); // 5
   147     ADD_r32_sh4r( R_ECX, REG_OFFSET(slice_cycle) );     // 6
   148     POP_r32(R_EBP);
   149     RET();
   150 }
   152 /**
   153  * Write the block trailer (exception handling block)
   154  */
   155 void sh4_translate_end_block( sh4addr_t pc ) {
   156     if( sh4_x86.branch_taken == FALSE ) {
   157 	// Didn't exit unconditionally already, so write the termination here
   158 	exit_block( pc, pc );
   159     }
   160     if( sh4_x86.backpatch_posn != 0 ) {
   161 	unsigned int i;
   162 	// Raise exception
   163 	uint8_t *end_ptr = xlat_output;
   164 	load_spreg( R_ECX, REG_OFFSET(pc) );
   165 	ADD_r32_r32( R_EDX, R_ECX );
   166 	ADD_r32_r32( R_EDX, R_ECX );
   167 	store_spreg( R_ECX, REG_OFFSET(pc) );
   168 	MOV_moff32_EAX( &sh4_cpu_period );
   169 	MUL_r32( R_EDX );
   170 	ADD_r32_sh4r( R_EAX, REG_OFFSET(slice_cycle) );
   172 	call_func0( sh4_raise_exception );
   173 	ADD_imm8s_r32( 4, R_ESP );
   174 	load_spreg( R_EAX, REG_OFFSET(pc) );
   175 	if( sh4_x86.tlb_on ) {
   176 	    call_func1(xlat_get_code_by_vma,R_EAX);
   177 	} else {
   178 	    call_func1(xlat_get_code,R_EAX);
   179 	}
   180 	POP_r32(R_EBP);
   181 	RET();
   183 	// Exception already raised - just cleanup
   184 	uint8_t *preexc_ptr = xlat_output;
   185 	load_imm32( R_ECX, sh4_x86.block_start_pc );
   186 	ADD_r32_r32( R_EDX, R_ECX );
   187 	ADD_r32_r32( R_EDX, R_ECX );
   188 	store_spreg( R_ECX, REG_OFFSET(spc) );
   189 	MOV_moff32_EAX( &sh4_cpu_period );
   190 	MUL_r32( R_EDX );
   191 	ADD_r32_sh4r( R_EAX, REG_OFFSET(slice_cycle) );
   192 	load_spreg( R_EAX, REG_OFFSET(pc) );
   193 	if( sh4_x86.tlb_on ) {
   194 	    call_func1(xlat_get_code_by_vma,R_EAX);
   195 	} else {
   196 	    call_func1(xlat_get_code,R_EAX);
   197 	}
   198 	POP_r32(R_EBP);
   199 	RET();
   201 	for( i=0; i< sh4_x86.backpatch_posn; i++ ) {
   202 	    *sh4_x86.backpatch_list[i].fixup_addr =
   203 		xlat_output - ((uint8_t *)sh4_x86.backpatch_list[i].fixup_addr) - 4;
   204 	    if( sh4_x86.backpatch_list[i].exc_code == -1 ) {
   205 		load_imm32( R_EDX, sh4_x86.backpatch_list[i].fixup_icount );
   206 		int rel = preexc_ptr - xlat_output;
   207 		JMP_rel(rel);
   208 	    } else {
   209 		PUSH_imm32( sh4_x86.backpatch_list[i].exc_code );
   210 		load_imm32( R_EDX, sh4_x86.backpatch_list[i].fixup_icount );
   211 		int rel = end_ptr - xlat_output;
   212 		JMP_rel(rel);
   213 	    }
   214 	}
   215     }
   216 }
   218 #endif
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