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1	b92e5a22	bellard	/*
2	b92e5a22	bellard	* Software MMU support
3	5fafdf24	ths	*
4	b92e5a22	bellard	* Copyright (c) 2003 Fabrice Bellard
5	b92e5a22	bellard	*
6	b92e5a22	bellard	* This library is free software; you can redistribute it and/or
7	b92e5a22	bellard	* modify it under the terms of the GNU Lesser General Public
8	b92e5a22	bellard	* License as published by the Free Software Foundation; either
9	b92e5a22	bellard	* version 2 of the License, or (at your option) any later version.
10	b92e5a22	bellard	*
11	b92e5a22	bellard	* This library is distributed in the hope that it will be useful,
12	b92e5a22	bellard	* but WITHOUT ANY WARRANTY; without even the implied warranty of
13	b92e5a22	bellard	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14	b92e5a22	bellard	* Lesser General Public License for more details.
15	b92e5a22	bellard	*
16	b92e5a22	bellard	* You should have received a copy of the GNU Lesser General Public
17	b92e5a22	bellard	* License along with this library; if not, write to the Free Software
18	b92e5a22	bellard	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
19	b92e5a22	bellard	*/
20	b92e5a22	bellard	#if DATA_SIZE == 8
21	b92e5a22	bellard	#define SUFFIX q
22	61382a50	bellard	#define USUFFIX q
23	b92e5a22	bellard	#define DATA_TYPE uint64_t
24	b92e5a22	bellard	#elif DATA_SIZE == 4
25	b92e5a22	bellard	#define SUFFIX l
26	61382a50	bellard	#define USUFFIX l
27	b92e5a22	bellard	#define DATA_TYPE uint32_t
28	b92e5a22	bellard	#elif DATA_SIZE == 2
29	b92e5a22	bellard	#define SUFFIX w
30	61382a50	bellard	#define USUFFIX uw
31	b92e5a22	bellard	#define DATA_TYPE uint16_t
32	b92e5a22	bellard	#define DATA_STYPE int16_t
33	b92e5a22	bellard	#elif DATA_SIZE == 1
34	b92e5a22	bellard	#define SUFFIX b
35	61382a50	bellard	#define USUFFIX ub
36	b92e5a22	bellard	#define DATA_TYPE uint8_t
37	b92e5a22	bellard	#define DATA_STYPE int8_t
38	b92e5a22	bellard	#else
39	b92e5a22	bellard	#error unsupported data size
40	b92e5a22	bellard	#endif
41	b92e5a22	bellard
42	6ebbf390	j_mayer	#if ACCESS_TYPE < (NB_MMU_MODES)
43	61382a50	bellard
44	6ebbf390	j_mayer	#define CPU_MMU_INDEX ACCESS_TYPE
45	61382a50	bellard	#define MMUSUFFIX _mmu
46	61382a50	bellard
47	6ebbf390	j_mayer	#elif ACCESS_TYPE == (NB_MMU_MODES)
48	61382a50	bellard
49	6ebbf390	j_mayer	#define CPU_MMU_INDEX (cpu_mmu_index(env))
50	61382a50	bellard	#define MMUSUFFIX _mmu
51	61382a50	bellard
52	6ebbf390	j_mayer	#elif ACCESS_TYPE == (NB_MMU_MODES + 1)
53	61382a50	bellard
54	6ebbf390	j_mayer	#define CPU_MMU_INDEX (cpu_mmu_index(env))
55	61382a50	bellard	#define MMUSUFFIX _cmmu
56	61382a50	bellard
57	b92e5a22	bellard	#else
58	61382a50	bellard	#error invalid ACCESS_TYPE
59	b92e5a22	bellard	#endif
60	b92e5a22	bellard
61	b92e5a22	bellard	#if DATA_SIZE == 8
62	b92e5a22	bellard	#define RES_TYPE uint64_t
63	b92e5a22	bellard	#else
64	b92e5a22	bellard	#define RES_TYPE int
65	b92e5a22	bellard	#endif
66	b92e5a22	bellard
67	6ebbf390	j_mayer	#if ACCESS_TYPE == (NB_MMU_MODES + 1)
68	84b7b8e7	bellard	#define ADDR_READ addr_code
69	84b7b8e7	bellard	#else
70	84b7b8e7	bellard	#define ADDR_READ addr_read
71	84b7b8e7	bellard	#endif
72	b92e5a22	bellard
73	d656469f	bellard	DATA_TYPE REGPARM glue(glue(__ld, SUFFIX), MMUSUFFIX)(target_ulong addr,
74	6ebbf390	j_mayer	int mmu_idx);
75	d656469f	bellard	void REGPARM glue(glue(__st, SUFFIX), MMUSUFFIX)(target_ulong addr, DATA_TYPE v, int mmu_idx);
76	b92e5a22	bellard
77	c27004ec	bellard	#if (DATA_SIZE <= 4) && (TARGET_LONG_BITS == 32) && defined(__i386__) && \
78	6ebbf390	j_mayer	(ACCESS_TYPE < NB_MMU_MODES) && defined(ASM_SOFTMMU)
79	e16c53fa	bellard
80	c27004ec	bellard	static inline RES_TYPE glue(glue(ld, USUFFIX), MEMSUFFIX)(target_ulong ptr)
81	e16c53fa	bellard	{
82	e16c53fa	bellard	int res;
83	e16c53fa	bellard
84	e16c53fa	bellard	asm volatile ("movl %1, %%edx\n"
85	e16c53fa	bellard	"movl %1, %%eax\n"
86	e16c53fa	bellard	"shrl %3, %%edx\n"
87	e16c53fa	bellard	"andl %4, %%eax\n"
88	e16c53fa	bellard	"andl %2, %%edx\n"
89	e16c53fa	bellard	"leal %5(%%edx, %%ebp), %%edx\n"
90	e16c53fa	bellard	"cmpl (%%edx), %%eax\n"
91	e16c53fa	bellard	"movl %1, %%eax\n"
92	e16c53fa	bellard	"je 1f\n"
93	d656469f	bellard	"movl %6, %%edx\n"
94	e16c53fa	bellard	"call %7\n"
95	e16c53fa	bellard	"movl %%eax, %0\n"
96	e16c53fa	bellard	"jmp 2f\n"
97	e16c53fa	bellard	"1:\n"
98	84b7b8e7	bellard	"addl 12(%%edx), %%eax\n"
99	e16c53fa	bellard	#if DATA_SIZE == 1
100	e16c53fa	bellard	"movzbl (%%eax), %0\n"
101	e16c53fa	bellard	#elif DATA_SIZE == 2
102	e16c53fa	bellard	"movzwl (%%eax), %0\n"
103	e16c53fa	bellard	#elif DATA_SIZE == 4
104	e16c53fa	bellard	"movl (%%eax), %0\n"
105	e16c53fa	bellard	#else
106	e16c53fa	bellard	#error unsupported size
107	e16c53fa	bellard	#endif
108	e16c53fa	bellard	"2:\n"
109	e16c53fa	bellard	: "=r" (res)
110	5fafdf24	ths	: "r" (ptr),
111	5fafdf24	ths	"i" ((CPU_TLB_SIZE - 1) << CPU_TLB_ENTRY_BITS),
112	5fafdf24	ths	"i" (TARGET_PAGE_BITS - CPU_TLB_ENTRY_BITS),
113	e16c53fa	bellard	"i" (TARGET_PAGE_MASK \| (DATA_SIZE - 1)),
114	6ebbf390	j_mayer	"m" ((uint32_t )offsetof(CPUState, tlb_table[CPU_MMU_INDEX][0].addr_read)),
115	6ebbf390	j_mayer	"i" (CPU_MMU_INDEX),
116	e16c53fa	bellard	"m" ((uint8_t )&glue(glue(__ld, SUFFIX), MMUSUFFIX))
117	e16c53fa	bellard	: "%eax", "%ecx", "%edx", "memory", "cc");
118	e16c53fa	bellard	return res;
119	e16c53fa	bellard	}
120	e16c53fa	bellard
121	e16c53fa	bellard	#if DATA_SIZE <= 2
122	c27004ec	bellard	static inline int glue(glue(lds, SUFFIX), MEMSUFFIX)(target_ulong ptr)
123	e16c53fa	bellard	{
124	e16c53fa	bellard	int res;
125	e16c53fa	bellard
126	e16c53fa	bellard	asm volatile ("movl %1, %%edx\n"
127	e16c53fa	bellard	"movl %1, %%eax\n"
128	e16c53fa	bellard	"shrl %3, %%edx\n"
129	e16c53fa	bellard	"andl %4, %%eax\n"
130	e16c53fa	bellard	"andl %2, %%edx\n"
131	e16c53fa	bellard	"leal %5(%%edx, %%ebp), %%edx\n"
132	e16c53fa	bellard	"cmpl (%%edx), %%eax\n"
133	e16c53fa	bellard	"movl %1, %%eax\n"
134	e16c53fa	bellard	"je 1f\n"
135	d656469f	bellard	"movl %6, %%edx\n"
136	e16c53fa	bellard	"call %7\n"
137	e16c53fa	bellard	#if DATA_SIZE == 1
138	e16c53fa	bellard	"movsbl %%al, %0\n"
139	e16c53fa	bellard	#elif DATA_SIZE == 2
140	e16c53fa	bellard	"movswl %%ax, %0\n"
141	e16c53fa	bellard	#else
142	e16c53fa	bellard	#error unsupported size
143	e16c53fa	bellard	#endif
144	e16c53fa	bellard	"jmp 2f\n"
145	e16c53fa	bellard	"1:\n"
146	84b7b8e7	bellard	"addl 12(%%edx), %%eax\n"
147	e16c53fa	bellard	#if DATA_SIZE == 1
148	e16c53fa	bellard	"movsbl (%%eax), %0\n"
149	e16c53fa	bellard	#elif DATA_SIZE == 2
150	e16c53fa	bellard	"movswl (%%eax), %0\n"
151	e16c53fa	bellard	#else
152	e16c53fa	bellard	#error unsupported size
153	e16c53fa	bellard	#endif
154	e16c53fa	bellard	"2:\n"
155	e16c53fa	bellard	: "=r" (res)
156	5fafdf24	ths	: "r" (ptr),
157	5fafdf24	ths	"i" ((CPU_TLB_SIZE - 1) << CPU_TLB_ENTRY_BITS),
158	5fafdf24	ths	"i" (TARGET_PAGE_BITS - CPU_TLB_ENTRY_BITS),
159	e16c53fa	bellard	"i" (TARGET_PAGE_MASK \| (DATA_SIZE - 1)),
160	6ebbf390	j_mayer	"m" ((uint32_t )offsetof(CPUState, tlb_table[CPU_MMU_INDEX][0].addr_read)),
161	6ebbf390	j_mayer	"i" (CPU_MMU_INDEX),
162	e16c53fa	bellard	"m" ((uint8_t )&glue(glue(__ld, SUFFIX), MMUSUFFIX))
163	e16c53fa	bellard	: "%eax", "%ecx", "%edx", "memory", "cc");
164	e16c53fa	bellard	return res;
165	e16c53fa	bellard	}
166	e16c53fa	bellard	#endif
167	e16c53fa	bellard
168	c27004ec	bellard	static inline void glue(glue(st, SUFFIX), MEMSUFFIX)(target_ulong ptr, RES_TYPE v)
169	e16c53fa	bellard	{
170	e16c53fa	bellard	asm volatile ("movl %0, %%edx\n"
171	e16c53fa	bellard	"movl %0, %%eax\n"
172	e16c53fa	bellard	"shrl %3, %%edx\n"
173	e16c53fa	bellard	"andl %4, %%eax\n"
174	e16c53fa	bellard	"andl %2, %%edx\n"
175	e16c53fa	bellard	"leal %5(%%edx, %%ebp), %%edx\n"
176	e16c53fa	bellard	"cmpl (%%edx), %%eax\n"
177	e16c53fa	bellard	"movl %0, %%eax\n"
178	e16c53fa	bellard	"je 1f\n"
179	e16c53fa	bellard	#if DATA_SIZE == 1
180	e16c53fa	bellard	"movzbl %b1, %%edx\n"
181	e16c53fa	bellard	#elif DATA_SIZE == 2
182	e16c53fa	bellard	"movzwl %w1, %%edx\n"
183	e16c53fa	bellard	#elif DATA_SIZE == 4
184	e16c53fa	bellard	"movl %1, %%edx\n"
185	e16c53fa	bellard	#else
186	e16c53fa	bellard	#error unsupported size
187	e16c53fa	bellard	#endif
188	d656469f	bellard	"movl %6, %%ecx\n"
189	e16c53fa	bellard	"call %7\n"
190	e16c53fa	bellard	"jmp 2f\n"
191	e16c53fa	bellard	"1:\n"
192	84b7b8e7	bellard	"addl 8(%%edx), %%eax\n"
193	e16c53fa	bellard	#if DATA_SIZE == 1
194	e16c53fa	bellard	"movb %b1, (%%eax)\n"
195	e16c53fa	bellard	#elif DATA_SIZE == 2
196	e16c53fa	bellard	"movw %w1, (%%eax)\n"
197	e16c53fa	bellard	#elif DATA_SIZE == 4
198	e16c53fa	bellard	"movl %1, (%%eax)\n"
199	e16c53fa	bellard	#else
200	e16c53fa	bellard	#error unsupported size
201	e16c53fa	bellard	#endif
202	e16c53fa	bellard	"2:\n"
203	5fafdf24	ths	:
204	5fafdf24	ths	: "r" (ptr),
205	f220f4e3	bellard	#if DATA_SIZE == 1
206	f220f4e3	bellard	"q" (v),
207	f220f4e3	bellard	#else
208	5fafdf24	ths	"r" (v),
209	f220f4e3	bellard	#endif
210	5fafdf24	ths	"i" ((CPU_TLB_SIZE - 1) << CPU_TLB_ENTRY_BITS),
211	5fafdf24	ths	"i" (TARGET_PAGE_BITS - CPU_TLB_ENTRY_BITS),
212	e16c53fa	bellard	"i" (TARGET_PAGE_MASK \| (DATA_SIZE - 1)),
213	6ebbf390	j_mayer	"m" ((uint32_t )offsetof(CPUState, tlb_table[CPU_MMU_INDEX][0].addr_write)),
214	6ebbf390	j_mayer	"i" (CPU_MMU_INDEX),
215	e16c53fa	bellard	"m" ((uint8_t )&glue(glue(__st, SUFFIX), MMUSUFFIX))
216	e16c53fa	bellard	: "%eax", "%ecx", "%edx", "memory", "cc");
217	e16c53fa	bellard	}
218	e16c53fa	bellard
219	e16c53fa	bellard	#else
220	e16c53fa	bellard
221	e16c53fa	bellard	/* generic load/store macros */
222	e16c53fa	bellard
223	c27004ec	bellard	static inline RES_TYPE glue(glue(ld, USUFFIX), MEMSUFFIX)(target_ulong ptr)
224	b92e5a22	bellard	{
225	b92e5a22	bellard	int index;
226	b92e5a22	bellard	RES_TYPE res;
227	c27004ec	bellard	target_ulong addr;
228	c27004ec	bellard	unsigned long physaddr;
229	6ebbf390	j_mayer	int mmu_idx;
230	61382a50	bellard
231	c27004ec	bellard	addr = ptr;
232	b92e5a22	bellard	index = (addr >> TARGET_PAGE_BITS) & (CPU_TLB_SIZE - 1);
233	6ebbf390	j_mayer	mmu_idx = CPU_MMU_INDEX;
234	6ebbf390	j_mayer	if (__builtin_expect(env->tlb_table[mmu_idx][index].ADDR_READ !=
235	b92e5a22	bellard	(addr & (TARGET_PAGE_MASK \| (DATA_SIZE - 1))), 0)) {
236	6ebbf390	j_mayer	res = glue(glue(__ld, SUFFIX), MMUSUFFIX)(addr, mmu_idx);
237	b92e5a22	bellard	} else {
238	6ebbf390	j_mayer	physaddr = addr + env->tlb_table[mmu_idx][index].addend;
239	61382a50	bellard	res = glue(glue(ld, USUFFIX), _raw)((uint8_t *)physaddr);
240	b92e5a22	bellard	}
241	b92e5a22	bellard	return res;
242	b92e5a22	bellard	}
243	b92e5a22	bellard
244	b92e5a22	bellard	#if DATA_SIZE <= 2
245	c27004ec	bellard	static inline int glue(glue(lds, SUFFIX), MEMSUFFIX)(target_ulong ptr)
246	b92e5a22	bellard	{
247	b92e5a22	bellard	int res, index;
248	c27004ec	bellard	target_ulong addr;
249	c27004ec	bellard	unsigned long physaddr;
250	6ebbf390	j_mayer	int mmu_idx;
251	61382a50	bellard
252	c27004ec	bellard	addr = ptr;
253	b92e5a22	bellard	index = (addr >> TARGET_PAGE_BITS) & (CPU_TLB_SIZE - 1);
254	6ebbf390	j_mayer	mmu_idx = CPU_MMU_INDEX;
255	6ebbf390	j_mayer	if (__builtin_expect(env->tlb_table[mmu_idx][index].ADDR_READ !=
256	b92e5a22	bellard	(addr & (TARGET_PAGE_MASK \| (DATA_SIZE - 1))), 0)) {
257	6ebbf390	j_mayer	res = (DATA_STYPE)glue(glue(__ld, SUFFIX), MMUSUFFIX)(addr, mmu_idx);
258	b92e5a22	bellard	} else {
259	6ebbf390	j_mayer	physaddr = addr + env->tlb_table[mmu_idx][index].addend;
260	b92e5a22	bellard	res = glue(glue(lds, SUFFIX), _raw)((uint8_t *)physaddr);
261	b92e5a22	bellard	}
262	b92e5a22	bellard	return res;
263	b92e5a22	bellard	}
264	b92e5a22	bellard	#endif
265	b92e5a22	bellard
266	6ebbf390	j_mayer	#if ACCESS_TYPE != (NB_MMU_MODES + 1)
267	84b7b8e7	bellard
268	e16c53fa	bellard	/* generic store macro */
269	e16c53fa	bellard
270	c27004ec	bellard	static inline void glue(glue(st, SUFFIX), MEMSUFFIX)(target_ulong ptr, RES_TYPE v)
271	b92e5a22	bellard	{
272	b92e5a22	bellard	int index;
273	c27004ec	bellard	target_ulong addr;
274	c27004ec	bellard	unsigned long physaddr;
275	6ebbf390	j_mayer	int mmu_idx;
276	61382a50	bellard
277	c27004ec	bellard	addr = ptr;
278	b92e5a22	bellard	index = (addr >> TARGET_PAGE_BITS) & (CPU_TLB_SIZE - 1);
279	6ebbf390	j_mayer	mmu_idx = CPU_MMU_INDEX;
280	6ebbf390	j_mayer	if (__builtin_expect(env->tlb_table[mmu_idx][index].addr_write !=
281	b92e5a22	bellard	(addr & (TARGET_PAGE_MASK \| (DATA_SIZE - 1))), 0)) {
282	6ebbf390	j_mayer	glue(glue(__st, SUFFIX), MMUSUFFIX)(addr, v, mmu_idx);
283	b92e5a22	bellard	} else {
284	6ebbf390	j_mayer	physaddr = addr + env->tlb_table[mmu_idx][index].addend;
285	b92e5a22	bellard	glue(glue(st, SUFFIX), _raw)((uint8_t *)physaddr, v);
286	b92e5a22	bellard	}
287	b92e5a22	bellard	}
288	b92e5a22	bellard
289	6ebbf390	j_mayer	#endif /* ACCESS_TYPE != (NB_MMU_MODES + 1) */
290	84b7b8e7	bellard
291	84b7b8e7	bellard	#endif /* !asm */
292	84b7b8e7	bellard
293	6ebbf390	j_mayer	#if ACCESS_TYPE != (NB_MMU_MODES + 1)
294	e16c53fa	bellard
295	2d603d22	bellard	#if DATA_SIZE == 8
296	3f87bf69	bellard	static inline float64 glue(ldfq, MEMSUFFIX)(target_ulong ptr)
297	2d603d22	bellard	{
298	2d603d22	bellard	union {
299	3f87bf69	bellard	float64 d;
300	2d603d22	bellard	uint64_t i;
301	2d603d22	bellard	} u;
302	2d603d22	bellard	u.i = glue(ldq, MEMSUFFIX)(ptr);
303	2d603d22	bellard	return u.d;
304	2d603d22	bellard	}
305	2d603d22	bellard
306	3f87bf69	bellard	static inline void glue(stfq, MEMSUFFIX)(target_ulong ptr, float64 v)
307	2d603d22	bellard	{
308	2d603d22	bellard	union {
309	3f87bf69	bellard	float64 d;
310	2d603d22	bellard	uint64_t i;
311	2d603d22	bellard	} u;
312	2d603d22	bellard	u.d = v;
313	2d603d22	bellard	glue(stq, MEMSUFFIX)(ptr, u.i);
314	2d603d22	bellard	}
315	2d603d22	bellard	#endif /* DATA_SIZE == 8 */
316	2d603d22	bellard
317	2d603d22	bellard	#if DATA_SIZE == 4
318	3f87bf69	bellard	static inline float32 glue(ldfl, MEMSUFFIX)(target_ulong ptr)
319	2d603d22	bellard	{
320	2d603d22	bellard	union {
321	3f87bf69	bellard	float32 f;
322	2d603d22	bellard	uint32_t i;
323	2d603d22	bellard	} u;
324	2d603d22	bellard	u.i = glue(ldl, MEMSUFFIX)(ptr);
325	2d603d22	bellard	return u.f;
326	2d603d22	bellard	}
327	2d603d22	bellard
328	3f87bf69	bellard	static inline void glue(stfl, MEMSUFFIX)(target_ulong ptr, float32 v)
329	2d603d22	bellard	{
330	2d603d22	bellard	union {
331	3f87bf69	bellard	float32 f;
332	2d603d22	bellard	uint32_t i;
333	2d603d22	bellard	} u;
334	2d603d22	bellard	u.f = v;
335	2d603d22	bellard	glue(stl, MEMSUFFIX)(ptr, u.i);
336	2d603d22	bellard	}
337	2d603d22	bellard	#endif /* DATA_SIZE == 4 */
338	2d603d22	bellard
339	6ebbf390	j_mayer	#endif /* ACCESS_TYPE != (NB_MMU_MODES + 1) */
340	84b7b8e7	bellard
341	b92e5a22	bellard	#undef RES_TYPE
342	b92e5a22	bellard	#undef DATA_TYPE
343	b92e5a22	bellard	#undef DATA_STYPE
344	b92e5a22	bellard	#undef SUFFIX
345	61382a50	bellard	#undef USUFFIX
346	b92e5a22	bellard	#undef DATA_SIZE
347	6ebbf390	j_mayer	#undef CPU_MMU_INDEX
348	61382a50	bellard	#undef MMUSUFFIX
349	84b7b8e7	bellard	#undef ADDR_READ

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