2 * $Id: xltcache.c,v 1.4 2007-09-16 06:59:47 nkeynes Exp $
4 * Translation cache management. This part is architecture independent.
6 * Copyright (c) 2005 Nathan Keynes.
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation; either version 2 of the License, or
11 * (at your option) any later version.
13 * This program is distributed in the hope that it will be useful,
14 * but WITHOUT ANY WARRANTY; without even the implied warranty of
15 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 * GNU General Public License for more details.
19 #include "sh4/xltcache.h"
20 #include "dreamcast.h"
24 #define XLAT_LUT_PAGE_BITS 12
25 #define XLAT_LUT_TOTAL_BITS 28
26 #define XLAT_LUT_PAGE(addr) (((addr)>>13) & 0xFFFF)
27 #define XLAT_LUT_ENTRY(addr) (((addr)&0x1FFE) >> 1)
29 #define XLAT_LUT_PAGES (1<<(XLAT_LUT_TOTAL_BITS-XLAT_LUT_PAGE_BITS))
30 #define XLAT_LUT_PAGE_ENTRIES (1<<XLAT_LUT_PAGE_BITS)
31 #define XLAT_LUT_PAGE_SIZE (XLAT_LUT_PAGE_ENTRIES * sizeof(void *))
33 #define XLAT_LUT_ENTRY_EMPTY (void *)0
34 #define XLAT_LUT_ENTRY_USED (void *)1
36 #define NEXT(block) ( (xlat_cache_block_t)&((block)->code[(block)->size]))
37 #define BLOCK_FOR_CODE(code) (((xlat_cache_block_t)code)-1)
38 #define IS_ENTRY_POINT(ent) (ent > XLAT_LUT_ENTRY_USED)
39 #define IS_ENTRY_USED(ent) (ent != XLAT_LUT_ENTRY_EMPTY)
41 #define MIN_BLOCK_SIZE 32
42 #define MIN_TOTAL_SIZE (sizeof(struct xlat_cache_block)+MIN_BLOCK_SIZE)
44 #define BLOCK_INACTIVE 0
45 #define BLOCK_ACTIVE 1
48 xlat_cache_block_t xlat_new_cache;
49 xlat_cache_block_t xlat_new_cache_ptr;
50 xlat_cache_block_t xlat_new_create_ptr;
51 xlat_cache_block_t xlat_temp_cache;
52 xlat_cache_block_t xlat_temp_cache_ptr;
53 xlat_cache_block_t xlat_old_cache;
54 xlat_cache_block_t xlat_old_cache_ptr;
55 static void ***xlat_lut;
56 static void **xlat_lut2; /* second-tier page info */
57 static gboolean xlat_initialized = FALSE;
59 void xlat_cache_init()
61 if( !xlat_initialized ) {
62 xlat_initialized = TRUE;
63 xlat_new_cache = mmap( NULL, XLAT_NEW_CACHE_SIZE, PROT_EXEC|PROT_READ|PROT_WRITE,
64 MAP_PRIVATE|MAP_ANONYMOUS, -1, 0 );
65 xlat_temp_cache = mmap( NULL, XLAT_TEMP_CACHE_SIZE, PROT_EXEC|PROT_READ|PROT_WRITE,
66 MAP_PRIVATE|MAP_ANONYMOUS, -1, 0 );
67 xlat_old_cache = mmap( NULL, XLAT_OLD_CACHE_SIZE, PROT_EXEC|PROT_READ|PROT_WRITE,
68 MAP_PRIVATE|MAP_ANONYMOUS, -1, 0 );
69 xlat_new_cache_ptr = xlat_new_cache;
70 xlat_temp_cache_ptr = xlat_temp_cache;
71 xlat_old_cache_ptr = xlat_old_cache;
72 xlat_new_create_ptr = xlat_new_cache;
74 xlat_lut = mmap( NULL, XLAT_LUT_PAGES*sizeof(void *), PROT_READ|PROT_WRITE,
75 MAP_PRIVATE|MAP_ANONYMOUS, -1, 0);
76 memset( xlat_lut, 0, XLAT_LUT_PAGES*sizeof(void *) );
82 * Reset the cache structure to its default state
84 void xlat_flush_cache()
86 xlat_cache_block_t tmp;
88 xlat_new_cache_ptr = xlat_new_cache;
89 xlat_new_cache_ptr->active = 0;
90 xlat_new_cache_ptr->size = XLAT_NEW_CACHE_SIZE - 2*sizeof(struct xlat_cache_block);
91 tmp = NEXT(xlat_new_cache_ptr);
94 xlat_temp_cache_ptr = xlat_temp_cache;
95 xlat_temp_cache_ptr->active = 0;
96 xlat_temp_cache_ptr->size = XLAT_TEMP_CACHE_SIZE - 2*sizeof(struct xlat_cache_block);
97 tmp = NEXT(xlat_temp_cache_ptr);
100 xlat_old_cache_ptr = xlat_old_cache;
101 xlat_old_cache_ptr->active = 0;
102 xlat_old_cache_ptr->size = XLAT_OLD_CACHE_SIZE - 2*sizeof(struct xlat_cache_block);
103 tmp = NEXT(xlat_old_cache_ptr);
106 for( i=0; i<XLAT_LUT_PAGES; i++ ) {
107 if( xlat_lut[i] != NULL ) {
108 memset( xlat_lut[i], 0, XLAT_LUT_PAGE_SIZE );
113 void xlat_flush_page( sh4addr_t address )
116 void **page = xlat_lut[XLAT_LUT_PAGE(address)];
117 for( i=0; i<XLAT_LUT_PAGE_ENTRIES; i++ ) {
118 if( IS_ENTRY_POINT(page[i]) ) {
119 BLOCK_FOR_CODE(page[i])->active = 0;
125 void *xlat_get_code( sh4addr_t address )
127 void **page = xlat_lut[XLAT_LUT_PAGE(address)];
131 void *result = page[XLAT_LUT_ENTRY(address)];
132 if( result == ((void *)(1)) ) {
139 uint32_t xlat_get_block_size( void *block )
141 xlat_cache_block_t xlt = (xlat_cache_block_t)(((char *)block)-sizeof(struct xlat_cache_block));
146 * Cut the specified block so that it has the given size, with the remaining data
147 * forming a new free block. If the free block would be less than the minimum size,
148 * the cut is not performed.
149 * @return the next block after the (possibly cut) block.
151 static inline xlat_cache_block_t xlat_cut_block( xlat_cache_block_t block, int cutsize )
153 if( block->size > cutsize + MIN_TOTAL_SIZE ) {
154 int oldsize = block->size;
155 block->size = cutsize;
156 xlat_cache_block_t next = NEXT(block);
158 next->size = oldsize - cutsize - sizeof(struct xlat_cache_block);
166 * Promote a block in temp space (or elsewhere for that matter) to old space.
168 * @param block to promote.
170 static void xlat_promote_to_old_space( xlat_cache_block_t block )
172 int allocation = -sizeof(struct xlat_cache_block);
173 int size = block->size;
174 xlat_cache_block_t curr = xlat_old_cache_ptr;
175 xlat_cache_block_t start_block = curr;
177 allocation += curr->size + sizeof(struct xlat_cache_block);
179 if( allocation > size ) {
182 if( curr->size == 0 ) { /* End-of-cache Sentinel */
183 /* Leave what we just released as free space and start again from the
186 start_block->active = 0;
187 start_block->size = allocation;
188 allocation = -sizeof(struct xlat_cache_block);
189 start_block = curr = xlat_old_cache;
192 start_block->active = 1;
193 start_block->size = allocation;
194 start_block->lut_entry = block->lut_entry;
195 *block->lut_entry = &start_block->code;
196 memcpy( start_block->code, block->code, block->size );
197 xlat_old_cache_ptr = xlat_cut_block(start_block, size );
198 if( xlat_old_cache_ptr->size == 0 ) {
199 xlat_old_cache_ptr = xlat_old_cache;
204 * Similarly to the above method, promotes a block to temp space.
205 * TODO: Try to combine these - they're nearly identical
207 void xlat_promote_to_temp_space( xlat_cache_block_t block )
209 int size = block->size;
210 int allocation = -sizeof(struct xlat_cache_block);
211 xlat_cache_block_t curr = xlat_temp_cache_ptr;
212 xlat_cache_block_t start_block = curr;
214 if( curr->active == BLOCK_USED ) {
215 xlat_promote_to_old_space( curr );
217 allocation += curr->size + sizeof(struct xlat_cache_block);
219 if( allocation > size ) {
222 if( curr->size == 0 ) { /* End-of-cache Sentinel */
223 /* Leave what we just released as free space and start again from the
226 start_block->active = 0;
227 start_block->size = allocation;
228 allocation = -sizeof(struct xlat_cache_block);
229 start_block = curr = xlat_temp_cache;
232 start_block->active = 1;
233 start_block->size = allocation;
234 start_block->lut_entry = block->lut_entry;
235 *block->lut_entry = &start_block->code;
236 memcpy( start_block->code, block->code, block->size );
237 xlat_temp_cache_ptr = xlat_cut_block(start_block, size );
238 if( xlat_temp_cache_ptr->size == 0 ) {
239 xlat_temp_cache_ptr = xlat_temp_cache;
245 * Returns the next block in the new cache list that can be written to by the
246 * translator. If the next block is active, it is evicted first.
248 xlat_cache_block_t xlat_start_block( sh4addr_t address )
250 if( xlat_new_cache_ptr->size == 0 ) {
251 xlat_new_cache_ptr = xlat_new_cache;
254 if( xlat_new_cache_ptr->active ) {
255 xlat_promote_to_temp_space( xlat_new_cache_ptr );
257 xlat_new_create_ptr = xlat_new_cache_ptr;
258 xlat_new_create_ptr->active = 1;
259 xlat_new_cache_ptr = NEXT(xlat_new_cache_ptr);
261 /* Add the LUT entry for the block */
262 if( xlat_lut[XLAT_LUT_PAGE(address)] == NULL ) {
263 xlat_lut[XLAT_LUT_PAGE(address)] =
264 mmap( NULL, XLAT_LUT_PAGE_SIZE, PROT_READ|PROT_WRITE,
265 MAP_PRIVATE|MAP_ANONYMOUS, -1, 0 );
266 memset( xlat_lut[XLAT_LUT_PAGE(address)], 0, XLAT_LUT_PAGE_SIZE );
269 if( IS_ENTRY_POINT(xlat_lut[XLAT_LUT_PAGE(address)][XLAT_LUT_ENTRY(address)]) ) {
270 xlat_cache_block_t oldblock = BLOCK_FOR_CODE(xlat_lut[XLAT_LUT_PAGE(address)][XLAT_LUT_ENTRY(address)]);
271 oldblock->active = 0;
274 xlat_lut[XLAT_LUT_PAGE(address)][XLAT_LUT_ENTRY(address)] =
275 &xlat_new_create_ptr->code;
276 xlat_new_create_ptr->lut_entry = xlat_lut[XLAT_LUT_PAGE(address)] + XLAT_LUT_ENTRY(address);
278 return xlat_new_create_ptr;
281 xlat_cache_block_t xlat_extend_block()
283 if( xlat_new_cache_ptr->size == 0 ) {
284 /* Migrate to the front of the cache to keep it contiguous */
285 xlat_new_create_ptr->active = 0;
286 char *olddata = xlat_new_create_ptr->code;
287 int oldsize = xlat_new_create_ptr->size;
288 int size = oldsize + MIN_BLOCK_SIZE; /* minimum expansion */
289 void **lut_entry = xlat_new_create_ptr->lut_entry;
290 int allocation = -sizeof(struct xlat_cache_block);
291 xlat_new_cache_ptr = xlat_new_cache;
293 if( xlat_new_cache_ptr->active ) {
294 xlat_promote_to_temp_space( xlat_new_cache_ptr );
296 allocation += xlat_new_cache_ptr->size + sizeof(struct xlat_cache_block);
297 xlat_new_cache_ptr = NEXT(xlat_new_cache_ptr);
298 } while( allocation < size );
299 xlat_new_create_ptr = xlat_new_cache;
300 xlat_new_create_ptr->active = 1;
301 xlat_new_create_ptr->size = allocation;
302 xlat_new_create_ptr->lut_entry = lut_entry;
303 *lut_entry = &xlat_new_create_ptr->code;
304 memmove( xlat_new_create_ptr->code, olddata, oldsize );
306 if( xlat_new_cache_ptr->active ) {
307 xlat_promote_to_temp_space( xlat_new_cache_ptr );
309 xlat_new_create_ptr->size += xlat_new_cache_ptr->size + sizeof(struct xlat_cache_block);
310 xlat_new_cache_ptr = NEXT(xlat_new_cache_ptr);
312 return xlat_new_create_ptr;
316 void xlat_commit_block( uint32_t destsize, uint32_t srcsize )
318 void **ptr = xlat_new_create_ptr->lut_entry;
319 void **endptr = ptr + (srcsize>>2);
320 while( ptr < endptr ) {
322 *ptr = XLAT_LUT_ENTRY_USED;
327 xlat_new_cache_ptr = xlat_cut_block( xlat_new_create_ptr, destsize );
330 void xlat_delete_block( xlat_cache_block_t block )
333 *block->lut_entry = NULL;
336 void xlat_check_cache_integrity( xlat_cache_block_t cache, xlat_cache_block_t ptr, int size )
339 xlat_cache_block_t tail =
340 (xlat_cache_block_t)(((char *)cache) + size - sizeof(struct xlat_cache_block));
342 assert( tail->active == 1 );
343 assert( tail->size == 0 );
344 while( cache < tail ) {
345 assert( cache->active >= 0 && cache->active <= 2 );
346 assert( cache->size >= 0 && cache->size < size );
352 assert( cache == tail );
353 assert( foundptr == 1 );
356 void xlat_check_integrity( )
358 xlat_check_cache_integrity( xlat_new_cache, xlat_new_cache_ptr, XLAT_NEW_CACHE_SIZE );
359 xlat_check_cache_integrity( xlat_temp_cache, xlat_temp_cache_ptr, XLAT_TEMP_CACHE_SIZE );
360 xlat_check_cache_integrity( xlat_old_cache, xlat_old_cache_ptr, XLAT_OLD_CACHE_SIZE );
364 void xlat_disasm_block( FILE *out, void *block )
366 uint32_t buflen = xlat_get_block_size(block);
367 x86_set_symtab( NULL, 0 );
368 x86_disasm_block( out, block, buflen );
.