filename | src/sh4/mmu.c |
changeset | 1217:677b1d85f1b4 |
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author | nkeynes |
date | Tue Feb 28 17:25:26 2012 +1000 (12 years ago) |
permissions | -rw-r--r-- |
last change | Implement display output for the GLES2 case (no fixed function rendering) |
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1 /**
2 * $Id$
3 *
4 * SH4 MMU implementation based on address space page maps. This module
5 * is responsible for all address decoding functions.
6 *
7 * Copyright (c) 2005 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 */
19 #define MODULE sh4_module
21 #include <stdio.h>
22 #include <assert.h>
23 #include "sh4/sh4mmio.h"
24 #include "sh4/sh4core.h"
25 #include "sh4/sh4trans.h"
26 #include "dreamcast.h"
27 #include "mem.h"
28 #include "mmu.h"
30 /* An entry is a 1K entry if it's one of the mmu_utlb_1k_pages entries */
31 #define IS_1K_PAGE_ENTRY(ent) ( ((uintptr_t)(((struct utlb_1k_entry *)ent) - &mmu_utlb_1k_pages[0])) < UTLB_ENTRY_COUNT )
33 /* Primary address space (used directly by SH4 cores) */
34 mem_region_fn_t *sh4_address_space;
35 mem_region_fn_t *sh4_user_address_space;
37 /* External address space (usually the same as the global ext_address_space) */
38 static mem_region_fn_t *sh4_ext_address_space;
40 /* Accessed from the UTLB accessor methods */
41 uint32_t mmu_urc;
42 uint32_t mmu_urb;
43 static gboolean mmu_urc_overflow; /* If true, urc was set >= urb */
45 /* Module globals */
46 static struct itlb_entry mmu_itlb[ITLB_ENTRY_COUNT];
47 static struct utlb_entry mmu_utlb[UTLB_ENTRY_COUNT];
48 static struct utlb_page_entry mmu_utlb_pages[UTLB_ENTRY_COUNT];
49 static uint32_t mmu_lrui;
50 static uint32_t mmu_asid; // current asid
51 static struct utlb_default_regions *mmu_user_storequeue_regions;
53 /* Structures for 1K page handling */
54 static struct utlb_1k_entry mmu_utlb_1k_pages[UTLB_ENTRY_COUNT];
55 static int mmu_utlb_1k_free_list[UTLB_ENTRY_COUNT];
56 static int mmu_utlb_1k_free_index;
59 /* Function prototypes */
60 static void mmu_invalidate_tlb();
61 static void mmu_utlb_register_all();
62 static void mmu_utlb_remove_entry(int);
63 static void mmu_utlb_insert_entry(int);
64 static void mmu_register_mem_region( uint32_t start, uint32_t end, mem_region_fn_t fn );
65 static void mmu_register_user_mem_region( uint32_t start, uint32_t end, mem_region_fn_t fn );
66 static void mmu_set_tlb_enabled( int tlb_on );
67 static void mmu_set_tlb_asid( uint32_t asid );
68 static void mmu_set_storequeue_protected( int protected, int tlb_on );
69 static gboolean mmu_utlb_map_pages( mem_region_fn_t priv_page, mem_region_fn_t user_page, sh4addr_t start_addr, int npages );
70 static void mmu_utlb_remap_pages( gboolean remap_priv, gboolean remap_user, int entryNo );
71 static gboolean mmu_utlb_unmap_pages( gboolean unmap_priv, gboolean unmap_user, sh4addr_t start_addr, int npages );
72 static gboolean mmu_ext_page_remapped( sh4addr_t page, mem_region_fn_t fn, void *user_data );
73 static void mmu_utlb_1k_init();
74 static struct utlb_1k_entry *mmu_utlb_1k_alloc();
75 static void mmu_utlb_1k_free( struct utlb_1k_entry *entry );
76 static int mmu_read_urc();
78 static void FASTCALL tlb_miss_read( sh4addr_t addr, void *exc );
79 static int32_t FASTCALL tlb_protected_read( sh4addr_t addr, void *exc );
80 static void FASTCALL tlb_protected_write( sh4addr_t addr, uint32_t val, void *exc );
81 static int32_t FASTCALL tlb_protected_read_for_write( sh4addr_t addr, void *exc );
82 static void FASTCALL tlb_initial_write( sh4addr_t addr, uint32_t val, void *exc );
83 static int32_t FASTCALL tlb_initial_read_for_write( sh4addr_t addr, void *exc );
84 static uint32_t get_tlb_size_mask( uint32_t flags );
85 static uint32_t get_tlb_size_pages( uint32_t flags );
87 #define DEFAULT_REGIONS 0
88 #define DEFAULT_STOREQUEUE_REGIONS 1
89 #define DEFAULT_STOREQUEUE_SQMD_REGIONS 2
91 static struct utlb_default_regions mmu_default_regions[3] = {
92 { &mem_region_tlb_miss, &mem_region_tlb_protected, &mem_region_tlb_multihit },
93 { &p4_region_storequeue_miss, &p4_region_storequeue_protected, &p4_region_storequeue_multihit },
94 { &p4_region_storequeue_sqmd_miss, &p4_region_storequeue_sqmd_protected, &p4_region_storequeue_sqmd_multihit } };
96 #define IS_STOREQUEUE_PROTECTED() (mmu_user_storequeue_regions == &mmu_default_regions[DEFAULT_STOREQUEUE_SQMD_REGIONS])
98 #ifndef SH4_TRANSLATOR
99 /* Dummy MMU vtable functions */
100 void mmu_utlb_init_vtable( struct utlb_entry *ent, struct utlb_page_entry *page, gboolean writable )
101 {
102 }
103 void mmu_utlb_init_storequeue_vtable( struct utlb_entry *ent, struct utlb_page_entry *page )
104 {
105 }
106 void mmu_utlb_1k_init_vtable( struct utlb_1k_entry *entry )
107 {
108 }
109 #endif
111 /*********************** Module public functions ****************************/
113 /**
114 * Allocate memory for the address space maps, and initialize them according
115 * to the default (reset) values. (TLB is disabled by default)
116 */
118 void MMU_init()
119 {
120 sh4_ext_address_space = ext_address_space;
121 sh4_address_space = mem_alloc_pages( sizeof(mem_region_fn_t) * 256 );
122 sh4_user_address_space = mem_alloc_pages( sizeof(mem_region_fn_t) * 256 );
123 mmu_user_storequeue_regions = &mmu_default_regions[DEFAULT_STOREQUEUE_REGIONS];
125 mmu_set_tlb_enabled(0);
126 mmu_register_user_mem_region( 0x80000000, 0x00000000, &mem_region_address_error );
127 mmu_register_user_mem_region( 0xE0000000, 0xE4000000, &p4_region_storequeue );
129 /* Setup P4 tlb/cache access regions */
130 mmu_register_mem_region( 0xE0000000, 0xE4000000, &p4_region_storequeue );
131 mmu_register_mem_region( 0xE4000000, 0xF0000000, &mem_region_unmapped );
132 mmu_register_mem_region( 0xF0000000, 0xF1000000, &p4_region_icache_addr );
133 mmu_register_mem_region( 0xF1000000, 0xF2000000, &p4_region_icache_data );
134 mmu_register_mem_region( 0xF2000000, 0xF3000000, &p4_region_itlb_addr );
135 mmu_register_mem_region( 0xF3000000, 0xF4000000, &p4_region_itlb_data );
136 mmu_register_mem_region( 0xF4000000, 0xF5000000, &p4_region_ocache_addr );
137 mmu_register_mem_region( 0xF5000000, 0xF6000000, &p4_region_ocache_data );
138 mmu_register_mem_region( 0xF6000000, 0xF7000000, &p4_region_utlb_addr );
139 mmu_register_mem_region( 0xF7000000, 0xF8000000, &p4_region_utlb_data );
140 mmu_register_mem_region( 0xF8000000, 0x00000000, &mem_region_unmapped );
142 /* Setup P4 control region */
143 mmu_register_mem_region( 0xFF000000, 0xFF001000, &mmio_region_MMU.fn );
144 mmu_register_mem_region( 0xFF100000, 0xFF101000, &mmio_region_PMM.fn );
145 mmu_register_mem_region( 0xFF200000, 0xFF201000, &mmio_region_UBC.fn );
146 mmu_register_mem_region( 0xFF800000, 0xFF801000, &mmio_region_BSC.fn );
147 mmu_register_mem_region( 0xFF900000, 0xFFA00000, &mem_region_unmapped ); // SDMR2 + SDMR3
148 mmu_register_mem_region( 0xFFA00000, 0xFFA01000, &mmio_region_DMAC.fn );
149 mmu_register_mem_region( 0xFFC00000, 0xFFC01000, &mmio_region_CPG.fn );
150 mmu_register_mem_region( 0xFFC80000, 0xFFC81000, &mmio_region_RTC.fn );
151 mmu_register_mem_region( 0xFFD00000, 0xFFD01000, &mmio_region_INTC.fn );
152 mmu_register_mem_region( 0xFFD80000, 0xFFD81000, &mmio_region_TMU.fn );
153 mmu_register_mem_region( 0xFFE00000, 0xFFE01000, &mmio_region_SCI.fn );
154 mmu_register_mem_region( 0xFFE80000, 0xFFE81000, &mmio_region_SCIF.fn );
155 mmu_register_mem_region( 0xFFF00000, 0xFFF01000, &mem_region_unmapped ); // H-UDI
157 register_mem_page_remapped_hook( mmu_ext_page_remapped, NULL );
158 mmu_utlb_1k_init();
160 /* Ensure the code regions are executable. Although it might
161 * be more portable to mmap these at runtime rather than using static decls
162 */
163 mem_unprotect( mmu_utlb_pages, sizeof(mmu_utlb_pages) );
164 mem_unprotect( mmu_utlb_1k_pages, sizeof(mmu_utlb_1k_pages) );
165 }
167 void MMU_reset()
168 {
169 mmio_region_MMU_write( CCR, 0 );
170 mmio_region_MMU_write( MMUCR, 0 );
171 }
173 void MMU_save_state( FILE *f )
174 {
175 mmu_read_urc();
176 fwrite( &mmu_itlb, sizeof(mmu_itlb), 1, f );
177 fwrite( &mmu_utlb, sizeof(mmu_utlb), 1, f );
178 fwrite( &mmu_urc, sizeof(mmu_urc), 1, f );
179 fwrite( &mmu_urb, sizeof(mmu_urb), 1, f );
180 fwrite( &mmu_lrui, sizeof(mmu_lrui), 1, f );
181 fwrite( &mmu_asid, sizeof(mmu_asid), 1, f );
182 }
184 int MMU_load_state( FILE *f )
185 {
186 if( fread( &mmu_itlb, sizeof(mmu_itlb), 1, f ) != 1 ) {
187 return 1;
188 }
189 if( fread( &mmu_utlb, sizeof(mmu_utlb), 1, f ) != 1 ) {
190 return 1;
191 }
192 if( fread( &mmu_urc, sizeof(mmu_urc), 1, f ) != 1 ) {
193 return 1;
194 }
195 if( fread( &mmu_urc, sizeof(mmu_urb), 1, f ) != 1 ) {
196 return 1;
197 }
198 if( fread( &mmu_lrui, sizeof(mmu_lrui), 1, f ) != 1 ) {
199 return 1;
200 }
201 if( fread( &mmu_asid, sizeof(mmu_asid), 1, f ) != 1 ) {
202 return 1;
203 }
205 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
206 mmu_urc_overflow = mmu_urc >= mmu_urb;
207 mmu_set_tlb_enabled(mmucr&MMUCR_AT);
208 mmu_set_storequeue_protected(mmucr&MMUCR_SQMD, mmucr&MMUCR_AT);
209 return 0;
210 }
212 /**
213 * LDTLB instruction implementation. Copies PTEH, PTEL and PTEA into the UTLB
214 * entry identified by MMUCR.URC. Does not modify MMUCR or the ITLB.
215 */
216 void MMU_ldtlb()
217 {
218 int urc = mmu_read_urc();
219 if( IS_TLB_ENABLED() && mmu_utlb[urc].flags & TLB_VALID )
220 mmu_utlb_remove_entry( urc );
221 mmu_utlb[urc].vpn = MMIO_READ(MMU, PTEH) & 0xFFFFFC00;
222 mmu_utlb[urc].asid = MMIO_READ(MMU, PTEH) & 0x000000FF;
223 mmu_utlb[urc].ppn = MMIO_READ(MMU, PTEL) & 0x1FFFFC00;
224 mmu_utlb[urc].flags = MMIO_READ(MMU, PTEL) & 0x00001FF;
225 mmu_utlb[urc].pcmcia = MMIO_READ(MMU, PTEA);
226 mmu_utlb[urc].mask = get_tlb_size_mask(mmu_utlb[urc].flags);
227 if( IS_TLB_ENABLED() && mmu_utlb[urc].flags & TLB_VALID )
228 mmu_utlb_insert_entry( urc );
229 }
232 MMIO_REGION_READ_FN( MMU, reg )
233 {
234 reg &= 0xFFF;
235 switch( reg ) {
236 case MMUCR:
237 return MMIO_READ( MMU, MMUCR) | (mmu_read_urc()<<10) | ((mmu_urb&0x3F)<<18) | (mmu_lrui<<26);
238 default:
239 return MMIO_READ( MMU, reg );
240 }
241 }
243 MMIO_REGION_READ_DEFSUBFNS(MMU)
245 MMIO_REGION_WRITE_FN( MMU, reg, val )
246 {
247 uint32_t tmp;
248 reg &= 0xFFF;
249 switch(reg) {
250 case SH4VER:
251 return;
252 case PTEH:
253 val &= 0xFFFFFCFF;
254 if( (val & 0xFF) != mmu_asid ) {
255 mmu_set_tlb_asid( val&0xFF );
256 }
257 break;
258 case PTEL:
259 val &= 0x1FFFFDFF;
260 break;
261 case PTEA:
262 val &= 0x0000000F;
263 break;
264 case TRA:
265 val &= 0x000003FC;
266 break;
267 case EXPEVT:
268 case INTEVT:
269 val &= 0x00000FFF;
270 break;
271 case MMUCR:
272 if( val & MMUCR_TI ) {
273 mmu_invalidate_tlb();
274 }
275 mmu_urc = (val >> 10) & 0x3F;
276 mmu_urb = (val >> 18) & 0x3F;
277 if( mmu_urb == 0 ) {
278 mmu_urb = 0x40;
279 } else if( mmu_urc >= mmu_urb ) {
280 mmu_urc_overflow = TRUE;
281 }
282 mmu_lrui = (val >> 26) & 0x3F;
283 val &= 0x00000301;
284 tmp = MMIO_READ( MMU, MMUCR );
285 if( (val ^ tmp) & (MMUCR_SQMD) ) {
286 mmu_set_storequeue_protected( val & MMUCR_SQMD, val&MMUCR_AT );
287 }
288 if( (val ^ tmp) & (MMUCR_AT) ) {
289 // AT flag has changed state - flush the xlt cache as all bets
290 // are off now. We also need to force an immediate exit from the
291 // current block
292 mmu_set_tlb_enabled( val & MMUCR_AT );
293 MMIO_WRITE( MMU, MMUCR, val );
294 sh4_core_exit( CORE_EXIT_FLUSH_ICACHE );
295 xlat_flush_cache(); // If we're not running, flush the cache anyway
296 }
297 break;
298 case CCR:
299 CCN_set_cache_control( val );
300 val &= 0x81A7;
301 break;
302 case MMUUNK1:
303 /* Note that if the high bit is set, this appears to reset the machine.
304 * Not emulating this behaviour yet until we know why...
305 */
306 val &= 0x00010007;
307 break;
308 case QACR0:
309 case QACR1:
310 val &= 0x0000001C;
311 break;
312 case PMCR1:
313 PMM_write_control(0, val);
314 val &= 0x0000C13F;
315 break;
316 case PMCR2:
317 PMM_write_control(1, val);
318 val &= 0x0000C13F;
319 break;
320 default:
321 break;
322 }
323 MMIO_WRITE( MMU, reg, val );
324 }
326 /********************** 1K Page handling ***********************/
327 /* Since we use 4K pages as our native page size, 1K pages need a bit of extra
328 * effort to manage - we justify this on the basis that most programs won't
329 * actually use 1K pages, so we may as well optimize for the common case.
330 *
331 * Implementation uses an intermediate page entry (the utlb_1k_entry) that
332 * redirects requests to the 'real' page entry. These are allocated on an
333 * as-needed basis, and returned to the pool when all subpages are empty.
334 */
335 static void mmu_utlb_1k_init()
336 {
337 int i;
338 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
339 mmu_utlb_1k_free_list[i] = i;
340 mmu_utlb_1k_init_vtable( &mmu_utlb_1k_pages[i] );
341 }
342 mmu_utlb_1k_free_index = 0;
343 }
345 static struct utlb_1k_entry *mmu_utlb_1k_alloc()
346 {
347 assert( mmu_utlb_1k_free_index < UTLB_ENTRY_COUNT );
348 struct utlb_1k_entry *entry = &mmu_utlb_1k_pages[mmu_utlb_1k_free_list[mmu_utlb_1k_free_index++]];
349 return entry;
350 }
352 static void mmu_utlb_1k_free( struct utlb_1k_entry *ent )
353 {
354 unsigned int entryNo = ent - &mmu_utlb_1k_pages[0];
355 assert( entryNo < UTLB_ENTRY_COUNT );
356 assert( mmu_utlb_1k_free_index > 0 );
357 mmu_utlb_1k_free_list[--mmu_utlb_1k_free_index] = entryNo;
358 }
361 /********************** Address space maintenance *************************/
363 mem_region_fn_t *mmu_set_ext_address_space( mem_region_fn_t *ext )
364 {
365 mem_region_fn_t *old_ext = sh4_ext_address_space;
366 sh4_ext_address_space = ext;
367 mmu_set_tlb_enabled(IS_TLB_ENABLED());
368 return old_ext;
369 }
371 /**
372 * MMU accessor functions just increment URC - fixup here if necessary
373 */
374 static int mmu_read_urc()
375 {
376 if( mmu_urc_overflow ) {
377 if( mmu_urc >= 0x40 ) {
378 mmu_urc_overflow = FALSE;
379 mmu_urc -= 0x40;
380 mmu_urc %= mmu_urb;
381 }
382 } else {
383 mmu_urc %= mmu_urb;
384 }
385 return mmu_urc;
386 }
388 static void mmu_register_mem_region( uint32_t start, uint32_t end, mem_region_fn_t fn )
389 {
390 int count = (end - start) >> 12;
391 mem_region_fn_t *ptr = &sh4_address_space[start>>12];
392 while( count-- > 0 ) {
393 *ptr++ = fn;
394 }
395 }
396 static void mmu_register_user_mem_region( uint32_t start, uint32_t end, mem_region_fn_t fn )
397 {
398 int count = (end - start) >> 12;
399 mem_region_fn_t *ptr = &sh4_user_address_space[start>>12];
400 while( count-- > 0 ) {
401 *ptr++ = fn;
402 }
403 }
405 static gboolean mmu_ext_page_remapped( sh4addr_t page, mem_region_fn_t fn, void *user_data )
406 {
407 unsigned int i;
408 if( (MMIO_READ(MMU,MMUCR)) & MMUCR_AT ) {
409 /* TLB on */
410 sh4_address_space[(page|0x80000000)>>12] = fn; /* Direct map to P1 and P2 */
411 sh4_address_space[(page|0xA0000000)>>12] = fn;
412 /* Scan UTLB and update any direct-referencing entries */
413 } else {
414 /* Direct map to U0, P0, P1, P2, P3 */
415 for( i=0; i<= 0xC0000000; i+= 0x20000000 ) {
416 sh4_address_space[(page|i)>>12] = fn;
417 }
418 for( i=0; i < 0x80000000; i+= 0x20000000 ) {
419 sh4_user_address_space[(page|i)>>12] = fn;
420 }
421 }
422 return TRUE;
423 }
425 static void mmu_set_tlb_enabled( int tlb_on )
426 {
427 mem_region_fn_t *ptr, *uptr;
428 int i;
430 /* Reset the storequeue area */
432 if( tlb_on ) {
433 mmu_register_mem_region(0x00000000, 0x80000000, &mem_region_tlb_miss );
434 mmu_register_mem_region(0xC0000000, 0xE0000000, &mem_region_tlb_miss );
435 mmu_register_user_mem_region(0x00000000, 0x80000000, &mem_region_tlb_miss );
437 /* Default SQ prefetch goes to TLB miss (?) */
438 mmu_register_mem_region( 0xE0000000, 0xE4000000, &p4_region_storequeue_miss );
439 mmu_register_user_mem_region( 0xE0000000, 0xE4000000, mmu_user_storequeue_regions->tlb_miss );
440 mmu_utlb_register_all();
441 } else {
442 for( i=0, ptr = sh4_address_space; i<7; i++, ptr += LXDREAM_PAGE_TABLE_ENTRIES ) {
443 memcpy( ptr, sh4_ext_address_space, sizeof(mem_region_fn_t) * LXDREAM_PAGE_TABLE_ENTRIES );
444 }
445 for( i=0, ptr = sh4_user_address_space; i<4; i++, ptr += LXDREAM_PAGE_TABLE_ENTRIES ) {
446 memcpy( ptr, sh4_ext_address_space, sizeof(mem_region_fn_t) * LXDREAM_PAGE_TABLE_ENTRIES );
447 }
449 mmu_register_mem_region( 0xE0000000, 0xE4000000, &p4_region_storequeue );
450 if( IS_STOREQUEUE_PROTECTED() ) {
451 mmu_register_user_mem_region( 0xE0000000, 0xE4000000, &p4_region_storequeue_sqmd );
452 } else {
453 mmu_register_user_mem_region( 0xE0000000, 0xE4000000, &p4_region_storequeue );
454 }
455 }
457 }
459 /**
460 * Flip the SQMD switch - this is rather expensive, so will need to be changed if
461 * anything expects to do this frequently.
462 */
463 static void mmu_set_storequeue_protected( int protected, int tlb_on )
464 {
465 mem_region_fn_t nontlb_region;
466 int i;
468 if( protected ) {
469 mmu_user_storequeue_regions = &mmu_default_regions[DEFAULT_STOREQUEUE_SQMD_REGIONS];
470 nontlb_region = &p4_region_storequeue_sqmd;
471 } else {
472 mmu_user_storequeue_regions = &mmu_default_regions[DEFAULT_STOREQUEUE_REGIONS];
473 nontlb_region = &p4_region_storequeue;
474 }
476 if( tlb_on ) {
477 mmu_register_user_mem_region( 0xE0000000, 0xE4000000, mmu_user_storequeue_regions->tlb_miss );
478 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
479 if( (mmu_utlb[i].vpn & 0xFC000000) == 0xE0000000 ) {
480 mmu_utlb_insert_entry(i);
481 }
482 }
483 } else {
484 mmu_register_user_mem_region( 0xE0000000, 0xE4000000, nontlb_region );
485 }
487 }
489 static void mmu_set_tlb_asid( uint32_t asid )
490 {
491 if( IS_TLB_ENABLED() ) {
492 /* Scan for pages that need to be remapped */
493 int i;
494 if( IS_SV_ENABLED() ) {
495 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
496 if( mmu_utlb[i].asid == mmu_asid &&
497 (mmu_utlb[i].flags & (TLB_VALID|TLB_SHARE)) == (TLB_VALID) ) {
498 // Matches old ASID - unmap out
499 if( !mmu_utlb_unmap_pages( FALSE, TRUE, mmu_utlb[i].vpn&mmu_utlb[i].mask,
500 get_tlb_size_pages(mmu_utlb[i].flags) ) )
501 mmu_utlb_remap_pages( FALSE, TRUE, i );
502 }
503 }
504 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
505 if( mmu_utlb[i].asid == asid &&
506 (mmu_utlb[i].flags & (TLB_VALID|TLB_SHARE)) == (TLB_VALID) ) {
507 // Matches new ASID - map in
508 mmu_utlb_map_pages( NULL, mmu_utlb_pages[i].user_fn,
509 mmu_utlb[i].vpn&mmu_utlb[i].mask,
510 get_tlb_size_pages(mmu_utlb[i].flags) );
511 }
512 }
513 } else {
514 // Remap both Priv+user pages
515 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
516 if( mmu_utlb[i].asid == mmu_asid &&
517 (mmu_utlb[i].flags & (TLB_VALID|TLB_SHARE)) == (TLB_VALID) ) {
518 if( !mmu_utlb_unmap_pages( TRUE, TRUE, mmu_utlb[i].vpn&mmu_utlb[i].mask,
519 get_tlb_size_pages(mmu_utlb[i].flags) ) )
520 mmu_utlb_remap_pages( TRUE, TRUE, i );
521 }
522 }
523 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
524 if( mmu_utlb[i].asid == asid &&
525 (mmu_utlb[i].flags & (TLB_VALID|TLB_SHARE)) == (TLB_VALID) ) {
526 mmu_utlb_map_pages( &mmu_utlb_pages[i].fn, mmu_utlb_pages[i].user_fn,
527 mmu_utlb[i].vpn&mmu_utlb[i].mask,
528 get_tlb_size_pages(mmu_utlb[i].flags) );
529 }
530 }
531 }
532 sh4_icache.page_vma = -1; // invalidate icache as asid has changed
533 }
534 mmu_asid = asid;
535 }
537 static uint32_t get_tlb_size_mask( uint32_t flags )
538 {
539 switch( flags & TLB_SIZE_MASK ) {
540 case TLB_SIZE_1K: return MASK_1K;
541 case TLB_SIZE_4K: return MASK_4K;
542 case TLB_SIZE_64K: return MASK_64K;
543 case TLB_SIZE_1M: return MASK_1M;
544 default: return 0; /* Unreachable */
545 }
546 }
547 static uint32_t get_tlb_size_pages( uint32_t flags )
548 {
549 switch( flags & TLB_SIZE_MASK ) {
550 case TLB_SIZE_1K: return 0;
551 case TLB_SIZE_4K: return 1;
552 case TLB_SIZE_64K: return 16;
553 case TLB_SIZE_1M: return 256;
554 default: return 0; /* Unreachable */
555 }
556 }
558 /**
559 * Add a new TLB entry mapping to the address space table. If any of the pages
560 * are already mapped, they are mapped to the TLB multi-hit page instead.
561 * @return FALSE if a TLB multihit situation was detected, otherwise TRUE.
562 */
563 static gboolean mmu_utlb_map_pages( mem_region_fn_t priv_page, mem_region_fn_t user_page, sh4addr_t start_addr, int npages )
564 {
565 mem_region_fn_t *ptr = &sh4_address_space[start_addr >> 12];
566 mem_region_fn_t *uptr = &sh4_user_address_space[start_addr >> 12];
567 struct utlb_default_regions *privdefs = &mmu_default_regions[DEFAULT_REGIONS];
568 struct utlb_default_regions *userdefs = privdefs;
570 gboolean mapping_ok = TRUE;
571 int i;
573 if( (start_addr & 0xFC000000) == 0xE0000000 ) {
574 /* Storequeue mapping */
575 privdefs = &mmu_default_regions[DEFAULT_STOREQUEUE_REGIONS];
576 userdefs = mmu_user_storequeue_regions;
577 } else if( (start_addr & 0xE0000000) == 0xC0000000 ) {
578 user_page = NULL; /* No user access to P3 region */
579 } else if( start_addr >= 0x80000000 ) {
580 return TRUE; // No mapping - legal but meaningless
581 }
583 if( npages == 0 ) {
584 struct utlb_1k_entry *ent;
585 int i, idx = (start_addr >> 10) & 0x03;
586 if( IS_1K_PAGE_ENTRY(*ptr) ) {
587 ent = (struct utlb_1k_entry *)*ptr;
588 } else {
589 ent = mmu_utlb_1k_alloc();
590 /* New 1K struct - init to previous contents of region */
591 for( i=0; i<4; i++ ) {
592 ent->subpages[i] = *ptr;
593 ent->user_subpages[i] = *uptr;
594 }
595 *ptr = &ent->fn;
596 *uptr = &ent->user_fn;
597 }
599 if( priv_page != NULL ) {
600 if( ent->subpages[idx] == privdefs->tlb_miss ) {
601 ent->subpages[idx] = priv_page;
602 } else {
603 mapping_ok = FALSE;
604 ent->subpages[idx] = privdefs->tlb_multihit;
605 }
606 }
607 if( user_page != NULL ) {
608 if( ent->user_subpages[idx] == userdefs->tlb_miss ) {
609 ent->user_subpages[idx] = user_page;
610 } else {
611 mapping_ok = FALSE;
612 ent->user_subpages[idx] = userdefs->tlb_multihit;
613 }
614 }
616 } else {
617 if( priv_page != NULL ) {
618 /* Privileged mapping only */
619 for( i=0; i<npages; i++ ) {
620 if( *ptr == privdefs->tlb_miss ) {
621 *ptr++ = priv_page;
622 } else {
623 mapping_ok = FALSE;
624 *ptr++ = privdefs->tlb_multihit;
625 }
626 }
627 }
628 if( user_page != NULL ) {
629 /* User mapping only (eg ASID change remap w/ SV=1) */
630 for( i=0; i<npages; i++ ) {
631 if( *uptr == userdefs->tlb_miss ) {
632 *uptr++ = user_page;
633 } else {
634 mapping_ok = FALSE;
635 *uptr++ = userdefs->tlb_multihit;
636 }
637 }
638 }
639 }
641 return mapping_ok;
642 }
644 /**
645 * Remap any pages within the region covered by entryNo, but not including
646 * entryNo itself. This is used to reestablish pages that were previously
647 * covered by a multi-hit exception region when one of the pages is removed.
648 */
649 static void mmu_utlb_remap_pages( gboolean remap_priv, gboolean remap_user, int entryNo )
650 {
651 int mask = mmu_utlb[entryNo].mask;
652 uint32_t remap_addr = mmu_utlb[entryNo].vpn & mask;
653 int i;
655 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
656 if( i != entryNo && (mmu_utlb[i].vpn & mask) == remap_addr && (mmu_utlb[i].flags & TLB_VALID) ) {
657 /* Overlapping region */
658 mem_region_fn_t priv_page = (remap_priv ? &mmu_utlb_pages[i].fn : NULL);
659 mem_region_fn_t user_page = (remap_priv ? mmu_utlb_pages[i].user_fn : NULL);
660 uint32_t start_addr;
661 int npages;
663 if( mmu_utlb[i].mask >= mask ) {
664 /* entry is no larger than the area we're replacing - map completely */
665 start_addr = mmu_utlb[i].vpn & mmu_utlb[i].mask;
666 npages = get_tlb_size_pages( mmu_utlb[i].flags );
667 } else {
668 /* Otherwise map subset - region covered by removed page */
669 start_addr = remap_addr;
670 npages = get_tlb_size_pages( mmu_utlb[entryNo].flags );
671 }
673 if( (mmu_utlb[i].flags & TLB_SHARE) || mmu_utlb[i].asid == mmu_asid ) {
674 mmu_utlb_map_pages( priv_page, user_page, start_addr, npages );
675 } else if( IS_SV_ENABLED() ) {
676 mmu_utlb_map_pages( priv_page, NULL, start_addr, npages );
677 }
679 }
680 }
681 }
683 /**
684 * Remove a previous TLB mapping (replacing them with the TLB miss region).
685 * @return FALSE if any pages were previously mapped to the TLB multihit page,
686 * otherwise TRUE. In either case, all pages in the region are cleared to TLB miss.
687 */
688 static gboolean mmu_utlb_unmap_pages( gboolean unmap_priv, gboolean unmap_user, sh4addr_t start_addr, int npages )
689 {
690 mem_region_fn_t *ptr = &sh4_address_space[start_addr >> 12];
691 mem_region_fn_t *uptr = &sh4_user_address_space[start_addr >> 12];
692 struct utlb_default_regions *privdefs = &mmu_default_regions[DEFAULT_REGIONS];
693 struct utlb_default_regions *userdefs = privdefs;
695 gboolean unmapping_ok = TRUE;
696 int i;
698 if( (start_addr & 0xFC000000) == 0xE0000000 ) {
699 /* Storequeue mapping */
700 privdefs = &mmu_default_regions[DEFAULT_STOREQUEUE_REGIONS];
701 userdefs = mmu_user_storequeue_regions;
702 } else if( (start_addr & 0xE0000000) == 0xC0000000 ) {
703 unmap_user = FALSE;
704 } else if( start_addr >= 0x80000000 ) {
705 return TRUE; // No mapping - legal but meaningless
706 }
708 if( npages == 0 ) { // 1K page
709 assert( IS_1K_PAGE_ENTRY( *ptr ) );
710 struct utlb_1k_entry *ent = (struct utlb_1k_entry *)*ptr;
711 int i, idx = (start_addr >> 10) & 0x03, mergeable=1;
712 if( ent->subpages[idx] == privdefs->tlb_multihit ) {
713 unmapping_ok = FALSE;
714 }
715 if( unmap_priv )
716 ent->subpages[idx] = privdefs->tlb_miss;
717 if( unmap_user )
718 ent->user_subpages[idx] = userdefs->tlb_miss;
720 /* If all 4 subpages have the same content, merge them together and
721 * release the 1K entry
722 */
723 mem_region_fn_t priv_page = ent->subpages[0];
724 mem_region_fn_t user_page = ent->user_subpages[0];
725 for( i=1; i<4; i++ ) {
726 if( priv_page != ent->subpages[i] || user_page != ent->user_subpages[i] ) {
727 mergeable = 0;
728 break;
729 }
730 }
731 if( mergeable ) {
732 mmu_utlb_1k_free(ent);
733 *ptr = priv_page;
734 *uptr = user_page;
735 }
736 } else {
737 if( unmap_priv ) {
738 /* Privileged (un)mapping */
739 for( i=0; i<npages; i++ ) {
740 if( *ptr == privdefs->tlb_multihit ) {
741 unmapping_ok = FALSE;
742 }
743 *ptr++ = privdefs->tlb_miss;
744 }
745 }
746 if( unmap_user ) {
747 /* User (un)mapping */
748 for( i=0; i<npages; i++ ) {
749 if( *uptr == userdefs->tlb_multihit ) {
750 unmapping_ok = FALSE;
751 }
752 *uptr++ = userdefs->tlb_miss;
753 }
754 }
755 }
757 return unmapping_ok;
758 }
760 static void mmu_utlb_insert_entry( int entry )
761 {
762 struct utlb_entry *ent = &mmu_utlb[entry];
763 mem_region_fn_t page = &mmu_utlb_pages[entry].fn;
764 mem_region_fn_t upage;
765 sh4addr_t start_addr = ent->vpn & ent->mask;
766 int npages = get_tlb_size_pages(ent->flags);
768 if( (start_addr & 0xFC000000) == 0xE0000000 ) {
769 /* Store queue mappings are a bit different - normal access is fixed to
770 * the store queue register block, and we only map prefetches through
771 * the TLB
772 */
773 mmu_utlb_init_storequeue_vtable( ent, &mmu_utlb_pages[entry] );
775 if( (ent->flags & TLB_USERMODE) == 0 ) {
776 upage = mmu_user_storequeue_regions->tlb_prot;
777 } else if( IS_STOREQUEUE_PROTECTED() ) {
778 upage = &p4_region_storequeue_sqmd;
779 } else {
780 upage = page;
781 }
783 } else {
785 if( (ent->flags & TLB_USERMODE) == 0 ) {
786 upage = &mem_region_tlb_protected;
787 } else {
788 upage = page;
789 }
791 if( (ent->flags & TLB_WRITABLE) == 0 ) {
792 page->write_long = (mem_write_fn_t)tlb_protected_write;
793 page->write_word = (mem_write_fn_t)tlb_protected_write;
794 page->write_byte = (mem_write_fn_t)tlb_protected_write;
795 page->write_burst = (mem_write_burst_fn_t)tlb_protected_write;
796 page->read_byte_for_write = (mem_read_fn_t)tlb_protected_read_for_write;
797 mmu_utlb_init_vtable( ent, &mmu_utlb_pages[entry], FALSE );
798 } else if( (ent->flags & TLB_DIRTY) == 0 ) {
799 page->write_long = (mem_write_fn_t)tlb_initial_write;
800 page->write_word = (mem_write_fn_t)tlb_initial_write;
801 page->write_byte = (mem_write_fn_t)tlb_initial_write;
802 page->write_burst = (mem_write_burst_fn_t)tlb_initial_write;
803 page->read_byte_for_write = (mem_read_fn_t)tlb_initial_read_for_write;
804 mmu_utlb_init_vtable( ent, &mmu_utlb_pages[entry], FALSE );
805 } else {
806 mmu_utlb_init_vtable( ent, &mmu_utlb_pages[entry], TRUE );
807 }
808 }
810 mmu_utlb_pages[entry].user_fn = upage;
812 /* Is page visible? */
813 if( (ent->flags & TLB_SHARE) || ent->asid == mmu_asid ) {
814 mmu_utlb_map_pages( page, upage, start_addr, npages );
815 } else if( IS_SV_ENABLED() ) {
816 mmu_utlb_map_pages( page, NULL, start_addr, npages );
817 }
818 }
820 static void mmu_utlb_remove_entry( int entry )
821 {
822 int i, j;
823 struct utlb_entry *ent = &mmu_utlb[entry];
824 sh4addr_t start_addr = ent->vpn&ent->mask;
825 mem_region_fn_t *ptr = &sh4_address_space[start_addr >> 12];
826 mem_region_fn_t *uptr = &sh4_user_address_space[start_addr >> 12];
827 gboolean unmap_user;
828 int npages = get_tlb_size_pages(ent->flags);
830 if( (ent->flags & TLB_SHARE) || ent->asid == mmu_asid ) {
831 unmap_user = TRUE;
832 } else if( IS_SV_ENABLED() ) {
833 unmap_user = FALSE;
834 } else {
835 return; // Not mapped
836 }
838 gboolean clean_unmap = mmu_utlb_unmap_pages( TRUE, unmap_user, start_addr, npages );
840 if( !clean_unmap ) {
841 mmu_utlb_remap_pages( TRUE, unmap_user, entry );
842 }
843 }
845 static void mmu_utlb_register_all()
846 {
847 int i;
848 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
849 if( mmu_utlb[i].flags & TLB_VALID )
850 mmu_utlb_insert_entry( i );
851 }
852 }
854 static void mmu_invalidate_tlb()
855 {
856 int i;
857 for( i=0; i<ITLB_ENTRY_COUNT; i++ ) {
858 mmu_itlb[i].flags &= (~TLB_VALID);
859 }
860 if( IS_TLB_ENABLED() ) {
861 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
862 if( mmu_utlb[i].flags & TLB_VALID ) {
863 mmu_utlb_remove_entry( i );
864 }
865 }
866 }
867 for( i=0; i<UTLB_ENTRY_COUNT; i++ ) {
868 mmu_utlb[i].flags &= (~TLB_VALID);
869 }
870 }
872 /******************************************************************************/
873 /* MMU TLB address translation */
874 /******************************************************************************/
876 /**
877 * Translate a 32-bit address into a UTLB entry number. Does not check for
878 * page protection etc.
879 * @return the entryNo if found, -1 if not found, and -2 for a multi-hit.
880 */
881 int mmu_utlb_entry_for_vpn( uint32_t vpn )
882 {
883 mmu_urc++;
884 mem_region_fn_t fn = sh4_address_space[vpn>>12];
885 if( fn >= &mmu_utlb_pages[0].fn && fn < &mmu_utlb_pages[UTLB_ENTRY_COUNT].fn ) {
886 return ((struct utlb_page_entry *)fn) - &mmu_utlb_pages[0];
887 } else if( fn >= &mmu_utlb_1k_pages[0].fn && fn < &mmu_utlb_1k_pages[UTLB_ENTRY_COUNT].fn ) {
888 struct utlb_1k_entry *ent = (struct utlb_1k_entry *)fn;
889 fn = ent->subpages[(vpn>>10)&0x03];
890 if( fn >= &mmu_utlb_pages[0].fn && fn < &mmu_utlb_pages[UTLB_ENTRY_COUNT].fn ) {
891 return ((struct utlb_page_entry *)fn) - &mmu_utlb_pages[0];
892 }
893 }
894 if( fn == &mem_region_tlb_multihit ) {
895 return -2;
896 } else {
897 return -1;
898 }
899 }
902 /**
903 * Perform the actual utlb lookup w/ asid matching.
904 * Possible utcomes are:
905 * 0..63 Single match - good, return entry found
906 * -1 No match - raise a tlb data miss exception
907 * -2 Multiple matches - raise a multi-hit exception (reset)
908 * @param vpn virtual address to resolve
909 * @return the resultant UTLB entry, or an error.
910 */
911 static inline int mmu_utlb_lookup_vpn_asid( uint32_t vpn )
912 {
913 int result = -1;
914 unsigned int i;
916 mmu_urc++;
917 if( mmu_urc == mmu_urb || mmu_urc == 0x40 ) {
918 mmu_urc = 0;
919 }
921 for( i = 0; i < UTLB_ENTRY_COUNT; i++ ) {
922 if( (mmu_utlb[i].flags & TLB_VALID) &&
923 ((mmu_utlb[i].flags & TLB_SHARE) || mmu_asid == mmu_utlb[i].asid) &&
924 ((mmu_utlb[i].vpn ^ vpn) & mmu_utlb[i].mask) == 0 ) {
925 if( result != -1 ) {
926 return -2;
927 }
928 result = i;
929 }
930 }
931 return result;
932 }
934 /**
935 * Perform the actual utlb lookup matching on vpn only
936 * Possible utcomes are:
937 * 0..63 Single match - good, return entry found
938 * -1 No match - raise a tlb data miss exception
939 * -2 Multiple matches - raise a multi-hit exception (reset)
940 * @param vpn virtual address to resolve
941 * @return the resultant UTLB entry, or an error.
942 */
943 static inline int mmu_utlb_lookup_vpn( uint32_t vpn )
944 {
945 int result = -1;
946 unsigned int i;
948 mmu_urc++;
949 if( mmu_urc == mmu_urb || mmu_urc == 0x40 ) {
950 mmu_urc = 0;
951 }
953 for( i = 0; i < UTLB_ENTRY_COUNT; i++ ) {
954 if( (mmu_utlb[i].flags & TLB_VALID) &&
955 ((mmu_utlb[i].vpn ^ vpn) & mmu_utlb[i].mask) == 0 ) {
956 if( result != -1 ) {
957 return -2;
958 }
959 result = i;
960 }
961 }
963 return result;
964 }
966 /**
967 * Update the ITLB by replacing the LRU entry with the specified UTLB entry.
968 * @return the number (0-3) of the replaced entry.
969 */
970 static int inline mmu_itlb_update_from_utlb( int entryNo )
971 {
972 int replace;
973 /* Determine entry to replace based on lrui */
974 if( (mmu_lrui & 0x38) == 0x38 ) {
975 replace = 0;
976 mmu_lrui = mmu_lrui & 0x07;
977 } else if( (mmu_lrui & 0x26) == 0x06 ) {
978 replace = 1;
979 mmu_lrui = (mmu_lrui & 0x19) | 0x20;
980 } else if( (mmu_lrui & 0x15) == 0x01 ) {
981 replace = 2;
982 mmu_lrui = (mmu_lrui & 0x3E) | 0x14;
983 } else { // Note - gets invalid entries too
984 replace = 3;
985 mmu_lrui = (mmu_lrui | 0x0B);
986 }
988 mmu_itlb[replace].vpn = mmu_utlb[entryNo].vpn;
989 mmu_itlb[replace].mask = mmu_utlb[entryNo].mask;
990 mmu_itlb[replace].ppn = mmu_utlb[entryNo].ppn;
991 mmu_itlb[replace].asid = mmu_utlb[entryNo].asid;
992 mmu_itlb[replace].flags = mmu_utlb[entryNo].flags & 0x01DA;
993 return replace;
994 }
996 /**
997 * Perform the actual itlb lookup w/ asid protection
998 * Possible utcomes are:
999 * 0..63 Single match - good, return entry found
1000 * -1 No match - raise a tlb data miss exception
1001 * -2 Multiple matches - raise a multi-hit exception (reset)
1002 * @param vpn virtual address to resolve
1003 * @return the resultant ITLB entry, or an error.
1004 */
1005 static inline int mmu_itlb_lookup_vpn_asid( uint32_t vpn )
1006 {
1007 int result = -1;
1008 unsigned int i;
1010 for( i = 0; i < ITLB_ENTRY_COUNT; i++ ) {
1011 if( (mmu_itlb[i].flags & TLB_VALID) &&
1012 ((mmu_itlb[i].flags & TLB_SHARE) || mmu_asid == mmu_itlb[i].asid) &&
1013 ((mmu_itlb[i].vpn ^ vpn) & mmu_itlb[i].mask) == 0 ) {
1014 if( result != -1 ) {
1015 return -2;
1016 }
1017 result = i;
1018 }
1019 }
1021 if( result == -1 ) {
1022 int utlbEntry = mmu_utlb_entry_for_vpn( vpn );
1023 if( utlbEntry < 0 ) {
1024 return utlbEntry;
1025 } else {
1026 return mmu_itlb_update_from_utlb( utlbEntry );
1027 }
1028 }
1030 switch( result ) {
1031 case 0: mmu_lrui = (mmu_lrui & 0x07); break;
1032 case 1: mmu_lrui = (mmu_lrui & 0x19) | 0x20; break;
1033 case 2: mmu_lrui = (mmu_lrui & 0x3E) | 0x14; break;
1034 case 3: mmu_lrui = (mmu_lrui | 0x0B); break;
1035 }
1037 return result;
1038 }
1040 /**
1041 * Perform the actual itlb lookup on vpn only
1042 * Possible utcomes are:
1043 * 0..63 Single match - good, return entry found
1044 * -1 No match - raise a tlb data miss exception
1045 * -2 Multiple matches - raise a multi-hit exception (reset)
1046 * @param vpn virtual address to resolve
1047 * @return the resultant ITLB entry, or an error.
1048 */
1049 static inline int mmu_itlb_lookup_vpn( uint32_t vpn )
1050 {
1051 int result = -1;
1052 unsigned int i;
1054 for( i = 0; i < ITLB_ENTRY_COUNT; i++ ) {
1055 if( (mmu_itlb[i].flags & TLB_VALID) &&
1056 ((mmu_itlb[i].vpn ^ vpn) & mmu_itlb[i].mask) == 0 ) {
1057 if( result != -1 ) {
1058 return -2;
1059 }
1060 result = i;
1061 }
1062 }
1064 if( result == -1 ) {
1065 int utlbEntry = mmu_utlb_lookup_vpn( vpn );
1066 if( utlbEntry < 0 ) {
1067 return utlbEntry;
1068 } else {
1069 return mmu_itlb_update_from_utlb( utlbEntry );
1070 }
1071 }
1073 switch( result ) {
1074 case 0: mmu_lrui = (mmu_lrui & 0x07); break;
1075 case 1: mmu_lrui = (mmu_lrui & 0x19) | 0x20; break;
1076 case 2: mmu_lrui = (mmu_lrui & 0x3E) | 0x14; break;
1077 case 3: mmu_lrui = (mmu_lrui | 0x0B); break;
1078 }
1080 return result;
1081 }
1083 /**
1084 * Update the icache for an untranslated address
1085 */
1086 static inline void mmu_update_icache_phys( sh4addr_t addr )
1087 {
1088 if( (addr & 0x1C000000) == 0x0C000000 ) {
1089 /* Main ram */
1090 sh4_icache.page_vma = addr & 0xFF000000;
1091 sh4_icache.page_ppa = 0x0C000000;
1092 sh4_icache.mask = 0xFF000000;
1093 sh4_icache.page = dc_main_ram;
1094 } else if( (addr & 0x1FE00000) == 0 ) {
1095 /* BIOS ROM */
1096 sh4_icache.page_vma = addr & 0xFFE00000;
1097 sh4_icache.page_ppa = 0;
1098 sh4_icache.mask = 0xFFE00000;
1099 sh4_icache.page = dc_boot_rom;
1100 } else {
1101 /* not supported */
1102 sh4_icache.page_vma = -1;
1103 }
1104 }
1106 /**
1107 * Update the sh4_icache structure to describe the page(s) containing the
1108 * given vma. If the address does not reference a RAM/ROM region, the icache
1109 * will be invalidated instead.
1110 * If AT is on, this method will raise TLB exceptions normally
1111 * (hence this method should only be used immediately prior to execution of
1112 * code), and otherwise will set the icache according to the matching TLB entry.
1113 * If AT is off, this method will set the entire referenced RAM/ROM region in
1114 * the icache.
1115 * @return TRUE if the update completed (successfully or otherwise), FALSE
1116 * if an exception was raised.
1117 */
1118 gboolean FASTCALL mmu_update_icache( sh4vma_t addr )
1119 {
1120 int entryNo;
1121 if( IS_SH4_PRIVMODE() ) {
1122 if( addr & 0x80000000 ) {
1123 if( addr < 0xC0000000 ) {
1124 /* P1, P2 and P4 regions are pass-through (no translation) */
1125 mmu_update_icache_phys(addr);
1126 return TRUE;
1127 } else if( addr >= 0xE0000000 && addr < 0xFFFFFF00 ) {
1128 RAISE_MEM_ERROR(EXC_DATA_ADDR_READ, addr);
1129 return FALSE;
1130 }
1131 }
1133 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
1134 if( (mmucr & MMUCR_AT) == 0 ) {
1135 mmu_update_icache_phys(addr);
1136 return TRUE;
1137 }
1139 if( (mmucr & MMUCR_SV) == 0 )
1140 entryNo = mmu_itlb_lookup_vpn_asid( addr );
1141 else
1142 entryNo = mmu_itlb_lookup_vpn( addr );
1143 } else {
1144 if( addr & 0x80000000 ) {
1145 RAISE_MEM_ERROR(EXC_DATA_ADDR_READ, addr);
1146 return FALSE;
1147 }
1149 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
1150 if( (mmucr & MMUCR_AT) == 0 ) {
1151 mmu_update_icache_phys(addr);
1152 return TRUE;
1153 }
1155 entryNo = mmu_itlb_lookup_vpn_asid( addr );
1157 if( entryNo != -1 && (mmu_itlb[entryNo].flags & TLB_USERMODE) == 0 ) {
1158 RAISE_MEM_ERROR(EXC_TLB_PROT_READ, addr);
1159 return FALSE;
1160 }
1161 }
1163 switch(entryNo) {
1164 case -1:
1165 RAISE_TLB_ERROR(EXC_TLB_MISS_READ, addr);
1166 return FALSE;
1167 case -2:
1168 RAISE_TLB_MULTIHIT_ERROR(addr);
1169 return FALSE;
1170 default:
1171 sh4_icache.page_ppa = mmu_itlb[entryNo].ppn & mmu_itlb[entryNo].mask;
1172 sh4_icache.page = mem_get_region( sh4_icache.page_ppa );
1173 if( sh4_icache.page == NULL ) {
1174 sh4_icache.page_vma = -1;
1175 } else {
1176 sh4_icache.page_vma = mmu_itlb[entryNo].vpn & mmu_itlb[entryNo].mask;
1177 sh4_icache.mask = mmu_itlb[entryNo].mask;
1178 }
1179 return TRUE;
1180 }
1181 }
1183 /**
1184 * Translate address for disassembly purposes (ie performs an instruction
1185 * lookup) - does not raise exceptions or modify any state, and ignores
1186 * protection bits. Returns the translated address, or MMU_VMA_ERROR
1187 * on translation failure.
1188 */
1189 sh4addr_t FASTCALL mmu_vma_to_phys_disasm( sh4vma_t vma )
1190 {
1191 if( vma & 0x80000000 ) {
1192 if( vma < 0xC0000000 ) {
1193 /* P1, P2 and P4 regions are pass-through (no translation) */
1194 return VMA_TO_EXT_ADDR(vma);
1195 } else if( vma >= 0xE0000000 && vma < 0xFFFFFF00 ) {
1196 /* Not translatable */
1197 return MMU_VMA_ERROR;
1198 }
1199 }
1201 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
1202 if( (mmucr & MMUCR_AT) == 0 ) {
1203 return VMA_TO_EXT_ADDR(vma);
1204 }
1206 int entryNo = mmu_itlb_lookup_vpn( vma );
1207 if( entryNo == -2 ) {
1208 entryNo = mmu_itlb_lookup_vpn_asid( vma );
1209 }
1210 if( entryNo < 0 ) {
1211 return MMU_VMA_ERROR;
1212 } else {
1213 return (mmu_itlb[entryNo].ppn & mmu_itlb[entryNo].mask) |
1214 (vma & (~mmu_itlb[entryNo].mask));
1215 }
1216 }
1218 /**
1219 * Translate a virtual to physical address for reading, raising exceptions as
1220 * observed.
1221 * @param addr Pointer to the virtual memory address. On successful return,
1222 * will be updated to contain the physical address.
1223 */
1224 mem_region_fn_t FASTCALL mmu_get_region_for_vma_read( sh4vma_t *paddr )
1225 {
1226 sh4vma_t addr = *paddr;
1227 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
1228 if( addr & 0x80000000 ) {
1229 if( IS_SH4_PRIVMODE() ) {
1230 if( addr >= 0xE0000000 ) {
1231 return sh4_address_space[((uint32_t)addr)>>12]; /* P4 - passthrough */
1232 } else if( addr < 0xC0000000 ) {
1233 /* P1, P2 regions are pass-through (no translation) */
1234 return sh4_ext_address_space[VMA_TO_EXT_ADDR(addr)>>12];
1235 }
1236 } else {
1237 if( addr >= 0xE0000000 && addr < 0xE4000000 &&
1238 ((mmucr&MMUCR_SQMD) == 0) ) {
1239 /* Conditional user-mode access to the store-queue (no translation) */
1240 return &p4_region_storequeue;
1241 }
1242 sh4_raise_exception(EXC_DATA_ADDR_READ);
1243 return NULL;
1244 }
1245 }
1247 if( (mmucr & MMUCR_AT) == 0 ) {
1248 return sh4_ext_address_space[VMA_TO_EXT_ADDR(addr)>>12];
1249 }
1251 /* If we get this far, translation is required */
1252 int entryNo;
1253 if( ((mmucr & MMUCR_SV) == 0) || !IS_SH4_PRIVMODE() ) {
1254 entryNo = mmu_utlb_lookup_vpn_asid( addr );
1255 } else {
1256 entryNo = mmu_utlb_lookup_vpn( addr );
1257 }
1259 switch(entryNo) {
1260 case -1:
1261 RAISE_TLB_ERROR(EXC_TLB_MISS_READ,addr);
1262 return NULL;
1263 case -2:
1264 RAISE_TLB_MULTIHIT_ERROR(addr);
1265 return NULL;
1266 default:
1267 if( (mmu_utlb[entryNo].flags & TLB_USERMODE) == 0 &&
1268 !IS_SH4_PRIVMODE() ) {
1269 /* protection violation */
1270 RAISE_MEM_ERROR(EXC_TLB_PROT_READ,addr);
1271 return NULL;
1272 }
1274 /* finally generate the target address */
1275 sh4addr_t pma = (mmu_utlb[entryNo].ppn & mmu_utlb[entryNo].mask) |
1276 (addr & (~mmu_utlb[entryNo].mask));
1277 if( pma > 0x1C000000 ) { // Remap 1Cxx .. 1Fxx region to P4
1278 addr = pma | 0xE0000000;
1279 *paddr = addr;
1280 return sh4_address_space[addr>>12];
1281 } else {
1282 *paddr = pma;
1283 return sh4_ext_address_space[pma>>12];
1284 }
1285 }
1286 }
1288 /**
1289 * Translate a virtual to physical address for prefetch, which mostly
1290 * does not raise exceptions.
1291 * @param addr Pointer to the virtual memory address. On successful return,
1292 * will be updated to contain the physical address.
1293 */
1294 mem_region_fn_t FASTCALL mmu_get_region_for_vma_prefetch( sh4vma_t *paddr )
1295 {
1296 sh4vma_t addr = *paddr;
1297 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
1298 if( addr & 0x80000000 ) {
1299 if( IS_SH4_PRIVMODE() ) {
1300 if( addr >= 0xE0000000 ) {
1301 return sh4_address_space[((uint32_t)addr)>>12]; /* P4 - passthrough */
1302 } else if( addr < 0xC0000000 ) {
1303 /* P1, P2 regions are pass-through (no translation) */
1304 return sh4_ext_address_space[VMA_TO_EXT_ADDR(addr)>>12];
1305 }
1306 } else {
1307 if( addr >= 0xE0000000 && addr < 0xE4000000 &&
1308 ((mmucr&MMUCR_SQMD) == 0) ) {
1309 /* Conditional user-mode access to the store-queue (no translation) */
1310 return &p4_region_storequeue;
1311 }
1312 sh4_raise_exception(EXC_DATA_ADDR_READ);
1313 return NULL;
1314 }
1315 }
1317 if( (mmucr & MMUCR_AT) == 0 ) {
1318 return sh4_ext_address_space[VMA_TO_EXT_ADDR(addr)>>12];
1319 }
1321 /* If we get this far, translation is required */
1322 int entryNo;
1323 if( ((mmucr & MMUCR_SV) == 0) || !IS_SH4_PRIVMODE() ) {
1324 entryNo = mmu_utlb_lookup_vpn_asid( addr );
1325 } else {
1326 entryNo = mmu_utlb_lookup_vpn( addr );
1327 }
1329 switch(entryNo) {
1330 case -1:
1331 return &mem_region_unmapped;
1332 case -2:
1333 RAISE_TLB_MULTIHIT_ERROR(addr);
1334 return NULL;
1335 default:
1336 if( (mmu_utlb[entryNo].flags & TLB_USERMODE) == 0 &&
1337 !IS_SH4_PRIVMODE() ) {
1338 /* protection violation */
1339 return &mem_region_unmapped;
1340 }
1342 /* finally generate the target address */
1343 sh4addr_t pma = (mmu_utlb[entryNo].ppn & mmu_utlb[entryNo].mask) |
1344 (addr & (~mmu_utlb[entryNo].mask));
1345 if( pma > 0x1C000000 ) { // Remap 1Cxx .. 1Fxx region to P4
1346 addr = pma | 0xE0000000;
1347 *paddr = addr;
1348 return sh4_address_space[addr>>12];
1349 } else {
1350 *paddr = pma;
1351 return sh4_ext_address_space[pma>>12];
1352 }
1353 }
1354 }
1356 /**
1357 * Translate a virtual to physical address for writing, raising exceptions as
1358 * observed.
1359 */
1360 mem_region_fn_t FASTCALL mmu_get_region_for_vma_write( sh4vma_t *paddr )
1361 {
1362 sh4vma_t addr = *paddr;
1363 uint32_t mmucr = MMIO_READ(MMU,MMUCR);
1364 if( addr & 0x80000000 ) {
1365 if( IS_SH4_PRIVMODE() ) {
1366 if( addr >= 0xE0000000 ) {
1367 return sh4_address_space[((uint32_t)addr)>>12]; /* P4 - passthrough */
1368 } else if( addr < 0xC0000000 ) {
1369 /* P1, P2 regions are pass-through (no translation) */
1370 return sh4_ext_address_space[VMA_TO_EXT_ADDR(addr)>>12];
1371 }
1372 } else {
1373 if( addr >= 0xE0000000 && addr < 0xE4000000 &&
1374 ((mmucr&MMUCR_SQMD) == 0) ) {
1375 /* Conditional user-mode access to the store-queue (no translation) */
1376 return &p4_region_storequeue;
1377 }
1378 sh4_raise_exception(EXC_DATA_ADDR_WRITE);
1379 return NULL;
1380 }
1381 }
1383 if( (mmucr & MMUCR_AT) == 0 ) {
1384 return sh4_ext_address_space[VMA_TO_EXT_ADDR(addr)>>12];
1385 }
1387 /* If we get this far, translation is required */
1388 int entryNo;
1389 if( ((mmucr & MMUCR_SV) == 0) || !IS_SH4_PRIVMODE() ) {
1390 entryNo = mmu_utlb_lookup_vpn_asid( addr );
1391 } else {
1392 entryNo = mmu_utlb_lookup_vpn( addr );
1393 }
1395 switch(entryNo) {
1396 case -1:
1397 RAISE_TLB_ERROR(EXC_TLB_MISS_WRITE,addr);
1398 return NULL;
1399 case -2:
1400 RAISE_TLB_MULTIHIT_ERROR(addr);
1401 return NULL;
1402 default:
1403 if( IS_SH4_PRIVMODE() ? ((mmu_utlb[entryNo].flags & TLB_WRITABLE) == 0)
1404 : ((mmu_utlb[entryNo].flags & TLB_USERWRITABLE) != TLB_USERWRITABLE) ) {
1405 /* protection violation */
1406 RAISE_MEM_ERROR(EXC_TLB_PROT_WRITE,addr);
1407 return NULL;
1408 }
1410 if( (mmu_utlb[entryNo].flags & TLB_DIRTY) == 0 ) {
1411 RAISE_MEM_ERROR(EXC_INIT_PAGE_WRITE, addr);
1412 return NULL;
1413 }
1415 /* finally generate the target address */
1416 sh4addr_t pma = (mmu_utlb[entryNo].ppn & mmu_utlb[entryNo].mask) |
1417 (addr & (~mmu_utlb[entryNo].mask));
1418 if( pma > 0x1C000000 ) { // Remap 1Cxx .. 1Fxx region to P4
1419 addr = pma | 0xE0000000;
1420 *paddr = addr;
1421 return sh4_address_space[addr>>12];
1422 } else {
1423 *paddr = pma;
1424 return sh4_ext_address_space[pma>>12];
1425 }
1426 }
1427 }
1431 /********************** TLB Direct-Access Regions ***************************/
1432 #define ITLB_ENTRY(addr) ((addr>>7)&0x03)
1434 int32_t FASTCALL mmu_itlb_addr_read( sh4addr_t addr )
1435 {
1436 struct itlb_entry *ent = &mmu_itlb[ITLB_ENTRY(addr)];
1437 return ent->vpn | ent->asid | (ent->flags & TLB_VALID);
1438 }
1440 void FASTCALL mmu_itlb_addr_write( sh4addr_t addr, uint32_t val )
1441 {
1442 struct itlb_entry *ent = &mmu_itlb[ITLB_ENTRY(addr)];
1443 ent->vpn = val & 0xFFFFFC00;
1444 ent->asid = val & 0x000000FF;
1445 ent->flags = (ent->flags & ~(TLB_VALID)) | (val&TLB_VALID);
1446 }
1448 int32_t FASTCALL mmu_itlb_data_read( sh4addr_t addr )
1449 {
1450 struct itlb_entry *ent = &mmu_itlb[ITLB_ENTRY(addr)];
1451 return (ent->ppn & 0x1FFFFC00) | ent->flags;
1452 }
1454 void FASTCALL mmu_itlb_data_write( sh4addr_t addr, uint32_t val )
1455 {
1456 struct itlb_entry *ent = &mmu_itlb[ITLB_ENTRY(addr)];
1457 ent->ppn = val & 0x1FFFFC00;
1458 ent->flags = val & 0x00001DA;
1459 ent->mask = get_tlb_size_mask(val);
1460 if( ent->ppn >= 0x1C000000 )
1461 ent->ppn |= 0xE0000000;
1462 }
1464 #define UTLB_ENTRY(addr) ((addr>>8)&0x3F)
1465 #define UTLB_ASSOC(addr) (addr&0x80)
1466 #define UTLB_DATA2(addr) (addr&0x00800000)
1468 int32_t FASTCALL mmu_utlb_addr_read( sh4addr_t addr )
1469 {
1470 struct utlb_entry *ent = &mmu_utlb[UTLB_ENTRY(addr)];
1471 return ent->vpn | ent->asid | (ent->flags & TLB_VALID) |
1472 ((ent->flags & TLB_DIRTY)<<7);
1473 }
1474 int32_t FASTCALL mmu_utlb_data_read( sh4addr_t addr )
1475 {
1476 struct utlb_entry *ent = &mmu_utlb[UTLB_ENTRY(addr)];
1477 if( UTLB_DATA2(addr) ) {
1478 return ent->pcmcia;
1479 } else {
1480 return (ent->ppn&0x1FFFFC00) | ent->flags;
1481 }
1482 }
1484 /**
1485 * Find a UTLB entry for the associative TLB write - same as the normal
1486 * lookup but ignores the valid bit.
1487 */
1488 static inline int mmu_utlb_lookup_assoc( uint32_t vpn, uint32_t asid )
1489 {
1490 int result = -1;
1491 unsigned int i;
1492 for( i = 0; i < UTLB_ENTRY_COUNT; i++ ) {
1493 if( (mmu_utlb[i].flags & TLB_VALID) &&
1494 ((mmu_utlb[i].flags & TLB_SHARE) || asid == mmu_utlb[i].asid) &&
1495 ((mmu_utlb[i].vpn ^ vpn) & mmu_utlb[i].mask) == 0 ) {
1496 if( result != -1 ) {
1497 fprintf( stderr, "TLB Multi hit: %d %d\n", result, i );
1498 return -2;
1499 }
1500 result = i;
1501 }
1502 }
1503 return result;
1504 }
1506 /**
1507 * Find a ITLB entry for the associative TLB write - same as the normal
1508 * lookup but ignores the valid bit.
1509 */
1510 static inline int mmu_itlb_lookup_assoc( uint32_t vpn, uint32_t asid )
1511 {
1512 int result = -1;
1513 unsigned int i;
1514 for( i = 0; i < ITLB_ENTRY_COUNT; i++ ) {
1515 if( (mmu_itlb[i].flags & TLB_VALID) &&
1516 ((mmu_itlb[i].flags & TLB_SHARE) || asid == mmu_itlb[i].asid) &&
1517 ((mmu_itlb[i].vpn ^ vpn) & mmu_itlb[i].mask) == 0 ) {
1518 if( result != -1 ) {
1519 return -2;
1520 }
1521 result = i;
1522 }
1523 }
1524 return result;
1525 }
1527 void FASTCALL mmu_utlb_addr_write( sh4addr_t addr, uint32_t val, void *exc )
1528 {
1529 if( UTLB_ASSOC(addr) ) {
1530 int utlb = mmu_utlb_lookup_assoc( val, mmu_asid );
1531 if( utlb >= 0 ) {
1532 struct utlb_entry *ent = &mmu_utlb[utlb];
1533 uint32_t old_flags = ent->flags;
1534 ent->flags = ent->flags & ~(TLB_DIRTY|TLB_VALID);
1535 ent->flags |= (val & TLB_VALID);
1536 ent->flags |= ((val & 0x200)>>7);
1537 if( IS_TLB_ENABLED() && ((old_flags^ent->flags) & (TLB_VALID|TLB_DIRTY)) != 0 ) {
1538 if( old_flags & TLB_VALID )
1539 mmu_utlb_remove_entry( utlb );
1540 if( ent->flags & TLB_VALID )
1541 mmu_utlb_insert_entry( utlb );
1542 }
1543 }
1545 int itlb = mmu_itlb_lookup_assoc( val, mmu_asid );
1546 if( itlb >= 0 ) {
1547 struct itlb_entry *ent = &mmu_itlb[itlb];
1548 ent->flags = (ent->flags & (~TLB_VALID)) | (val & TLB_VALID);
1549 }
1551 if( itlb == -2 || utlb == -2 ) {
1552 RAISE_TLB_MULTIHIT_ERROR(addr); /* FIXME: should this only be raised if TLB is enabled? */
1553 SH4_EXCEPTION_EXIT();
1554 return;
1555 }
1556 } else {
1557 struct utlb_entry *ent = &mmu_utlb[UTLB_ENTRY(addr)];
1558 if( IS_TLB_ENABLED() && ent->flags & TLB_VALID )
1559 mmu_utlb_remove_entry( UTLB_ENTRY(addr) );
1560 ent->vpn = (val & 0xFFFFFC00);
1561 ent->asid = (val & 0xFF);
1562 ent->flags = (ent->flags & ~(TLB_DIRTY|TLB_VALID));
1563 ent->flags |= (val & TLB_VALID);
1564 ent->flags |= ((val & 0x200)>>7);
1565 if( IS_TLB_ENABLED() && ent->flags & TLB_VALID )
1566 mmu_utlb_insert_entry( UTLB_ENTRY(addr) );
1567 }
1568 }
1570 void FASTCALL mmu_utlb_data_write( sh4addr_t addr, uint32_t val )
1571 {
1572 struct utlb_entry *ent = &mmu_utlb[UTLB_ENTRY(addr)];
1573 if( UTLB_DATA2(addr) ) {
1574 ent->pcmcia = val & 0x0000000F;
1575 } else {
1576 if( IS_TLB_ENABLED() && ent->flags & TLB_VALID )
1577 mmu_utlb_remove_entry( UTLB_ENTRY(addr) );
1578 ent->ppn = (val & 0x1FFFFC00);
1579 ent->flags = (val & 0x000001FF);
1580 ent->mask = get_tlb_size_mask(val);
1581 if( IS_TLB_ENABLED() && ent->flags & TLB_VALID )
1582 mmu_utlb_insert_entry( UTLB_ENTRY(addr) );
1583 }
1584 }
1586 struct mem_region_fn p4_region_itlb_addr = {
1587 mmu_itlb_addr_read, mmu_itlb_addr_write,
1588 mmu_itlb_addr_read, mmu_itlb_addr_write,
1589 mmu_itlb_addr_read, mmu_itlb_addr_write,
1590 unmapped_read_burst, unmapped_write_burst,
1591 unmapped_prefetch, mmu_itlb_addr_read };
1592 struct mem_region_fn p4_region_itlb_data = {
1593 mmu_itlb_data_read, mmu_itlb_data_write,
1594 mmu_itlb_data_read, mmu_itlb_data_write,
1595 mmu_itlb_data_read, mmu_itlb_data_write,
1596 unmapped_read_burst, unmapped_write_burst,
1597 unmapped_prefetch, mmu_itlb_data_read };
1598 struct mem_region_fn p4_region_utlb_addr = {
1599 mmu_utlb_addr_read, (mem_write_fn_t)mmu_utlb_addr_write,
1600 mmu_utlb_addr_read, (mem_write_fn_t)mmu_utlb_addr_write,
1601 mmu_utlb_addr_read, (mem_write_fn_t)mmu_utlb_addr_write,
1602 unmapped_read_burst, unmapped_write_burst,
1603 unmapped_prefetch, mmu_utlb_addr_read };
1604 struct mem_region_fn p4_region_utlb_data = {
1605 mmu_utlb_data_read, mmu_utlb_data_write,
1606 mmu_utlb_data_read, mmu_utlb_data_write,
1607 mmu_utlb_data_read, mmu_utlb_data_write,
1608 unmapped_read_burst, unmapped_write_burst,
1609 unmapped_prefetch, mmu_utlb_data_read };
1611 /********************** Error regions **************************/
1613 static void FASTCALL address_error_read( sh4addr_t addr, void *exc )
1614 {
1615 RAISE_MEM_ERROR(EXC_DATA_ADDR_READ, addr);
1616 SH4_EXCEPTION_EXIT();
1617 }
1619 static void FASTCALL address_error_read_for_write( sh4addr_t addr, void *exc )
1620 {
1621 RAISE_MEM_ERROR(EXC_DATA_ADDR_WRITE, addr);
1622 SH4_EXCEPTION_EXIT();
1623 }
1625 static void FASTCALL address_error_read_burst( unsigned char *dest, sh4addr_t addr, void *exc )
1626 {
1627 RAISE_MEM_ERROR(EXC_DATA_ADDR_READ, addr);
1628 SH4_EXCEPTION_EXIT();
1629 }
1631 static void FASTCALL address_error_write( sh4addr_t addr, uint32_t val, void *exc )
1632 {
1633 RAISE_MEM_ERROR(EXC_DATA_ADDR_WRITE, addr);
1634 SH4_EXCEPTION_EXIT();
1635 }
1637 static void FASTCALL tlb_miss_read( sh4addr_t addr, void *exc )
1638 {
1639 mmu_urc++;
1640 RAISE_TLB_ERROR(EXC_TLB_MISS_READ, addr);
1641 SH4_EXCEPTION_EXIT();
1642 }
1644 static void FASTCALL tlb_miss_read_for_write( sh4addr_t addr, void *exc )
1645 {
1646 mmu_urc++;
1647 RAISE_TLB_ERROR(EXC_TLB_MISS_WRITE, addr);
1648 SH4_EXCEPTION_EXIT();
1649 }
1651 static void FASTCALL tlb_miss_read_burst( unsigned char *dest, sh4addr_t addr, void *exc )
1652 {
1653 mmu_urc++;
1654 RAISE_TLB_ERROR(EXC_TLB_MISS_READ, addr);
1655 SH4_EXCEPTION_EXIT();
1656 }
1658 static void FASTCALL tlb_miss_write( sh4addr_t addr, uint32_t val, void *exc )
1659 {
1660 mmu_urc++;
1661 RAISE_TLB_ERROR(EXC_TLB_MISS_WRITE, addr);
1662 SH4_EXCEPTION_EXIT();
1663 }
1665 static int32_t FASTCALL tlb_protected_read( sh4addr_t addr, void *exc )
1666 {
1667 mmu_urc++;
1668 RAISE_MEM_ERROR(EXC_TLB_PROT_READ, addr);
1669 SH4_EXCEPTION_EXIT();
1670 return 0;
1671 }
1673 static int32_t FASTCALL tlb_protected_read_for_write( sh4addr_t addr, void *exc )
1674 {
1675 mmu_urc++;
1676 RAISE_MEM_ERROR(EXC_TLB_PROT_WRITE, addr);
1677 SH4_EXCEPTION_EXIT();
1678 return 0;
1679 }
1681 static int32_t FASTCALL tlb_protected_read_burst( unsigned char *dest, sh4addr_t addr, void *exc )
1682 {
1683 mmu_urc++;
1684 RAISE_MEM_ERROR(EXC_TLB_PROT_READ, addr);
1685 SH4_EXCEPTION_EXIT();
1686 return 0;
1687 }
1689 static void FASTCALL tlb_protected_write( sh4addr_t addr, uint32_t val, void *exc )
1690 {
1691 mmu_urc++;
1692 RAISE_MEM_ERROR(EXC_TLB_PROT_WRITE, addr);
1693 SH4_EXCEPTION_EXIT();
1694 }
1696 static void FASTCALL tlb_initial_write( sh4addr_t addr, uint32_t val, void *exc )
1697 {
1698 mmu_urc++;
1699 RAISE_MEM_ERROR(EXC_INIT_PAGE_WRITE, addr);
1700 SH4_EXCEPTION_EXIT();
1701 }
1703 static int32_t FASTCALL tlb_initial_read_for_write( sh4addr_t addr, void *exc )
1704 {
1705 mmu_urc++;
1706 RAISE_MEM_ERROR(EXC_INIT_PAGE_WRITE, addr);
1707 SH4_EXCEPTION_EXIT();
1708 return 0;
1709 }
1711 static int32_t FASTCALL tlb_multi_hit_read( sh4addr_t addr, void *exc )
1712 {
1713 sh4_raise_tlb_multihit(addr);
1714 SH4_EXCEPTION_EXIT();
1715 return 0;
1716 }
1718 static int32_t FASTCALL tlb_multi_hit_read_burst( unsigned char *dest, sh4addr_t addr, void *exc )
1719 {
1720 sh4_raise_tlb_multihit(addr);
1721 SH4_EXCEPTION_EXIT();
1722 return 0;
1723 }
1724 static void FASTCALL tlb_multi_hit_write( sh4addr_t addr, uint32_t val, void *exc )
1725 {
1726 sh4_raise_tlb_multihit(addr);
1727 SH4_EXCEPTION_EXIT();
1728 }
1730 /**
1731 * Note: Per sec 4.6.4 of the SH7750 manual, SQ
1732 */
1733 struct mem_region_fn mem_region_address_error = {
1734 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1735 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1736 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1737 (mem_read_burst_fn_t)address_error_read_burst, (mem_write_burst_fn_t)address_error_write,
1738 unmapped_prefetch, (mem_read_fn_t)address_error_read_for_write };
1740 struct mem_region_fn mem_region_tlb_miss = {
1741 (mem_read_fn_t)tlb_miss_read, (mem_write_fn_t)tlb_miss_write,
1742 (mem_read_fn_t)tlb_miss_read, (mem_write_fn_t)tlb_miss_write,
1743 (mem_read_fn_t)tlb_miss_read, (mem_write_fn_t)tlb_miss_write,
1744 (mem_read_burst_fn_t)tlb_miss_read_burst, (mem_write_burst_fn_t)tlb_miss_write,
1745 unmapped_prefetch, (mem_read_fn_t)tlb_miss_read_for_write };
1747 struct mem_region_fn mem_region_tlb_protected = {
1748 (mem_read_fn_t)tlb_protected_read, (mem_write_fn_t)tlb_protected_write,
1749 (mem_read_fn_t)tlb_protected_read, (mem_write_fn_t)tlb_protected_write,
1750 (mem_read_fn_t)tlb_protected_read, (mem_write_fn_t)tlb_protected_write,
1751 (mem_read_burst_fn_t)tlb_protected_read_burst, (mem_write_burst_fn_t)tlb_protected_write,
1752 unmapped_prefetch, (mem_read_fn_t)tlb_protected_read_for_write };
1754 struct mem_region_fn mem_region_tlb_multihit = {
1755 (mem_read_fn_t)tlb_multi_hit_read, (mem_write_fn_t)tlb_multi_hit_write,
1756 (mem_read_fn_t)tlb_multi_hit_read, (mem_write_fn_t)tlb_multi_hit_write,
1757 (mem_read_fn_t)tlb_multi_hit_read, (mem_write_fn_t)tlb_multi_hit_write,
1758 (mem_read_burst_fn_t)tlb_multi_hit_read_burst, (mem_write_burst_fn_t)tlb_multi_hit_write,
1759 (mem_prefetch_fn_t)tlb_multi_hit_read, (mem_read_fn_t)tlb_multi_hit_read };
1762 /* Store-queue regions */
1763 /* These are a bit of a pain - the first 8 fields are controlled by SQMD, while
1764 * the final (prefetch) is controlled by the actual TLB settings (plus SQMD in
1765 * some cases), in contrast to the ordinary fields above.
1766 *
1767 * There is probably a simpler way to do this.
1768 */
1770 struct mem_region_fn p4_region_storequeue = {
1771 ccn_storequeue_read_long, ccn_storequeue_write_long,
1772 unmapped_read_long, unmapped_write_long, /* TESTME: Officially only long access is supported */
1773 unmapped_read_long, unmapped_write_long,
1774 unmapped_read_burst, unmapped_write_burst,
1775 ccn_storequeue_prefetch, unmapped_read_long };
1777 struct mem_region_fn p4_region_storequeue_miss = {
1778 ccn_storequeue_read_long, ccn_storequeue_write_long,
1779 unmapped_read_long, unmapped_write_long, /* TESTME: Officially only long access is supported */
1780 unmapped_read_long, unmapped_write_long,
1781 unmapped_read_burst, unmapped_write_burst,
1782 (mem_prefetch_fn_t)tlb_miss_read, unmapped_read_long };
1784 struct mem_region_fn p4_region_storequeue_multihit = {
1785 ccn_storequeue_read_long, ccn_storequeue_write_long,
1786 unmapped_read_long, unmapped_write_long, /* TESTME: Officially only long access is supported */
1787 unmapped_read_long, unmapped_write_long,
1788 unmapped_read_burst, unmapped_write_burst,
1789 (mem_prefetch_fn_t)tlb_multi_hit_read, unmapped_read_long };
1791 struct mem_region_fn p4_region_storequeue_protected = {
1792 ccn_storequeue_read_long, ccn_storequeue_write_long,
1793 unmapped_read_long, unmapped_write_long,
1794 unmapped_read_long, unmapped_write_long,
1795 unmapped_read_burst, unmapped_write_burst,
1796 (mem_prefetch_fn_t)tlb_protected_read, unmapped_read_long };
1798 struct mem_region_fn p4_region_storequeue_sqmd = {
1799 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1800 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1801 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1802 (mem_read_burst_fn_t)address_error_read_burst, (mem_write_burst_fn_t)address_error_write,
1803 (mem_prefetch_fn_t)address_error_read, (mem_read_fn_t)address_error_read_for_write };
1805 struct mem_region_fn p4_region_storequeue_sqmd_miss = {
1806 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1807 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1808 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1809 (mem_read_burst_fn_t)address_error_read_burst, (mem_write_burst_fn_t)address_error_write,
1810 (mem_prefetch_fn_t)tlb_miss_read, (mem_read_fn_t)address_error_read_for_write };
1812 struct mem_region_fn p4_region_storequeue_sqmd_multihit = {
1813 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1814 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1815 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1816 (mem_read_burst_fn_t)address_error_read_burst, (mem_write_burst_fn_t)address_error_write,
1817 (mem_prefetch_fn_t)tlb_multi_hit_read, (mem_read_fn_t)address_error_read_for_write };
1819 struct mem_region_fn p4_region_storequeue_sqmd_protected = {
1820 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1821 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1822 (mem_read_fn_t)address_error_read, (mem_write_fn_t)address_error_write,
1823 (mem_read_burst_fn_t)address_error_read_burst, (mem_write_burst_fn_t)address_error_write,
1824 (mem_prefetch_fn_t)tlb_protected_read, (mem_read_fn_t)address_error_read_for_write };
.