filename | src/sh4/ia32abi.h |
changeset | 577:a181aeacd6e8 |
prev | 571:9bc09948d0f2 |
author | nkeynes |
date | Mon Jan 14 10:23:49 2008 +0000 (16 years ago) |
branch | lxdream-mmu |
permissions | -rw-r--r-- |
last change | Remove asm file and convert to inline (easier to cope with platform conventions) Add breakpoint support Add MMU store-queue support |
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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(R_ECX);
84 PUSH_r32(R_EAX);
85 ADD_imm8s_r32( 4, R_ECX );
86 PUSH_r32(R_ECX);
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 /**
94 * Emit the 'start of block' assembly. Sets up the stack frame and save
95 * SI/DI as required
96 */
97 void sh4_translate_begin_block( sh4addr_t pc )
98 {
99 PUSH_r32(R_EBP);
100 /* mov &sh4r, ebp */
101 load_ptr( R_EBP, &sh4r );
103 sh4_x86.in_delay_slot = FALSE;
104 sh4_x86.priv_checked = FALSE;
105 sh4_x86.fpuen_checked = FALSE;
106 sh4_x86.branch_taken = FALSE;
107 sh4_x86.backpatch_posn = 0;
108 sh4_x86.recovery_posn = 0;
109 sh4_x86.block_start_pc = pc;
110 sh4_x86.tlb_on = IS_MMU_ENABLED();
111 sh4_x86.tstate = TSTATE_NONE;
112 #ifdef STACK_ALIGN
113 sh4_x86.stack_posn = 8;
114 #endif
115 }
117 /**
118 * Exit the block with sh4r.pc already written
119 * Bytes: 15
120 */
121 void exit_block_pcset( sh4addr_t pc )
122 {
123 load_imm32( R_ECX, ((pc - sh4_x86.block_start_pc)>>1)*sh4_cpu_period ); // 5
124 ADD_r32_sh4r( R_ECX, REG_OFFSET(slice_cycle) ); // 6
125 load_spreg( R_EAX, REG_OFFSET(pc) );
126 if( sh4_x86.tlb_on ) {
127 call_func1(xlat_get_code_by_vma,R_EAX);
128 } else {
129 call_func1(xlat_get_code,R_EAX);
130 }
131 POP_r32(R_EBP);
132 RET();
133 }
135 #define EXIT_BLOCK_SIZE(pc) (24 + (IS_IN_ICACHE(pc)?5:CALL_FUNC1_SIZE))
138 /**
139 * Exit the block to an absolute PC
140 */
141 void exit_block( sh4addr_t pc, sh4addr_t endpc )
142 {
143 load_imm32( R_ECX, pc ); // 5
144 store_spreg( R_ECX, REG_OFFSET(pc) ); // 3
145 if( IS_IN_ICACHE(pc) ) {
146 MOV_moff32_EAX( xlat_get_lut_entry(GET_ICACHE_PHYS(pc)) ); // 5
147 } else if( sh4_x86.tlb_on ) {
148 call_func1(xlat_get_code_by_vma,R_ECX);
149 } else {
150 call_func1(xlat_get_code,R_ECX);
151 }
152 AND_imm8s_r32( 0xFC, R_EAX ); // 3
153 load_imm32( R_ECX, ((endpc - sh4_x86.block_start_pc)>>1)*sh4_cpu_period ); // 5
154 ADD_r32_sh4r( R_ECX, REG_OFFSET(slice_cycle) ); // 6
155 POP_r32(R_EBP);
156 RET();
157 }
159 #define EXIT_BLOCK_REL_SIZE(pc) (27 + (IS_IN_ICACHE(pc)?5:CALL_FUNC1_SIZE))
161 /**
162 * Exit the block to a relative PC
163 */
164 void exit_block_rel( sh4addr_t pc, sh4addr_t endpc )
165 {
166 load_imm32( R_ECX, pc - sh4_x86.block_start_pc ); // 5
167 ADD_sh4r_r32( R_PC, R_ECX );
168 store_spreg( R_ECX, REG_OFFSET(pc) ); // 3
169 if( IS_IN_ICACHE(pc) ) {
170 MOV_moff32_EAX( xlat_get_lut_entry(GET_ICACHE_PHYS(pc)) ); // 5
171 } else if( sh4_x86.tlb_on ) {
172 call_func1(xlat_get_code_by_vma,R_ECX);
173 } else {
174 call_func1(xlat_get_code,R_ECX);
175 }
176 AND_imm8s_r32( 0xFC, R_EAX ); // 3
177 load_imm32( R_ECX, ((endpc - sh4_x86.block_start_pc)>>1)*sh4_cpu_period ); // 5
178 ADD_r32_sh4r( R_ECX, REG_OFFSET(slice_cycle) ); // 6
179 POP_r32(R_EBP);
180 RET();
181 }
183 /**
184 * Write the block trailer (exception handling block)
185 */
186 void sh4_translate_end_block( sh4addr_t pc ) {
187 if( sh4_x86.branch_taken == FALSE ) {
188 // Didn't exit unconditionally already, so write the termination here
189 exit_block_rel( pc, pc );
190 }
191 if( sh4_x86.backpatch_posn != 0 ) {
192 unsigned int i;
193 // Raise exception
194 uint8_t *end_ptr = xlat_output;
195 MOV_r32_r32( R_EDX, R_ECX );
196 ADD_r32_r32( R_EDX, R_ECX );
197 ADD_r32_sh4r( R_ECX, R_PC );
198 MOV_moff32_EAX( &sh4_cpu_period );
199 MUL_r32( R_EDX );
200 ADD_r32_sh4r( R_EAX, REG_OFFSET(slice_cycle) );
202 call_func0( sh4_raise_exception );
203 ADD_imm8s_r32( 4, R_ESP );
204 load_spreg( R_EAX, R_PC );
205 if( sh4_x86.tlb_on ) {
206 call_func1(xlat_get_code_by_vma,R_EAX);
207 } else {
208 call_func1(xlat_get_code,R_EAX);
209 }
210 POP_r32(R_EBP);
211 RET();
213 // Exception already raised - just cleanup
214 uint8_t *preexc_ptr = xlat_output;
215 MOV_r32_r32( R_EDX, R_ECX );
216 ADD_r32_r32( R_EDX, R_ECX );
217 ADD_r32_sh4r( R_ECX, R_SPC );
218 MOV_moff32_EAX( &sh4_cpu_period );
219 MUL_r32( R_EDX );
220 ADD_r32_sh4r( R_EAX, REG_OFFSET(slice_cycle) );
221 load_spreg( R_EAX, R_PC );
222 if( sh4_x86.tlb_on ) {
223 call_func1(xlat_get_code_by_vma,R_EAX);
224 } else {
225 call_func1(xlat_get_code,R_EAX);
226 }
227 POP_r32(R_EBP);
228 RET();
230 for( i=0; i< sh4_x86.backpatch_posn; i++ ) {
231 *sh4_x86.backpatch_list[i].fixup_addr =
232 xlat_output - ((uint8_t *)sh4_x86.backpatch_list[i].fixup_addr) - 4;
233 if( sh4_x86.backpatch_list[i].exc_code == -1 ) {
234 load_imm32( R_EDX, sh4_x86.backpatch_list[i].fixup_icount );
235 int rel = preexc_ptr - xlat_output;
236 JMP_rel(rel);
237 } else {
238 PUSH_imm32( sh4_x86.backpatch_list[i].exc_code );
239 load_imm32( R_EDX, sh4_x86.backpatch_list[i].fixup_icount );
240 int rel = end_ptr - xlat_output;
241 JMP_rel(rel);
242 }
243 }
244 }
245 }
247 void *xlat_get_native_pc()
248 {
249 void *result = NULL;
250 asm(
251 "mov %%ebp, %%eax\n\t"
252 "mov $0x8, %%ecx\n\t"
253 "mov %1, %%edx\n"
254 "frame_loop: test %%eax, %%eax\n\t"
255 "je frame_not_found\n\t"
256 "cmp (%%eax), %%edx\n\t"
257 "je frame_found\n\t"
258 "sub $0x1, %%ecx\n\t"
259 "je frame_not_found\n\t"
260 "movl (%%eax), %%eax\n\t"
261 "jmp frame_loop\n"
262 "frame_found: movl 0x4(%%eax), %0\n"
263 "frame_not_found:"
264 : "=r" (result)
265 : "r" (&sh4r)
266 : "eax", "ecx", "edx" );
267 return result;
268 }
270 #endif
.