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1	79aceca5	bellard	/*
2	79aceca5	bellard	* PPC emulation for qemu: main translation routines.
3	79aceca5	bellard	*
4	79aceca5	bellard	* Copyright (c) 2003 Jocelyn Mayer
5	79aceca5	bellard	*
6	79aceca5	bellard	* This library is free software; you can redistribute it and/or
7	79aceca5	bellard	* modify it under the terms of the GNU Lesser General Public
8	79aceca5	bellard	* License as published by the Free Software Foundation; either
9	79aceca5	bellard	* version 2 of the License, or (at your option) any later version.
10	79aceca5	bellard	*
11	79aceca5	bellard	* This library is distributed in the hope that it will be useful,
12	79aceca5	bellard	* but WITHOUT ANY WARRANTY; without even the implied warranty of
13	79aceca5	bellard	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14	79aceca5	bellard	* Lesser General Public License for more details.
15	79aceca5	bellard	*
16	79aceca5	bellard	* You should have received a copy of the GNU Lesser General Public
17	79aceca5	bellard	* License along with this library; if not, write to the Free Software
18	79aceca5	bellard	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
19	79aceca5	bellard	*/
20	c6a1c22b	bellard	#include <stdarg.h>
21	c6a1c22b	bellard	#include <stdlib.h>
22	c6a1c22b	bellard	#include <stdio.h>
23	c6a1c22b	bellard	#include <string.h>
24	c6a1c22b	bellard	#include <inttypes.h>
25	c6a1c22b	bellard
26	79aceca5	bellard	#include "cpu.h"
27	c6a1c22b	bellard	#include "exec-all.h"
28	79aceca5	bellard	#include "disas.h"
29	79aceca5	bellard
30	79aceca5	bellard	//#define DO_SINGLE_STEP
31	9fddaa0c	bellard	//#define PPC_DEBUG_DISAS
32	79aceca5	bellard
33	79aceca5	bellard	enum {
34	79aceca5	bellard	#define DEF(s, n, copy_size) INDEX_op_ ## s,
35	79aceca5	bellard	#include "opc.h"
36	79aceca5	bellard	#undef DEF
37	79aceca5	bellard	NB_OPS,
38	79aceca5	bellard	};
39	79aceca5	bellard
40	79aceca5	bellard	static uint16_t *gen_opc_ptr;
41	79aceca5	bellard	static uint32_t *gen_opparam_ptr;
42	79aceca5	bellard
43	79aceca5	bellard	#include "gen-op.h"
44	28b6751f	bellard
45	28b6751f	bellard	#define GEN8(func, NAME) \
46	9a64fbe4	bellard	static GenOpFunc *NAME ## _table [8] = { \
47	9a64fbe4	bellard	NAME ## 0, NAME ## 1, NAME ## 2, NAME ## 3, \
48	9a64fbe4	bellard	NAME ## 4, NAME ## 5, NAME ## 6, NAME ## 7, \
49	9a64fbe4	bellard	}; \
50	9a64fbe4	bellard	static inline void func(int n) \
51	9a64fbe4	bellard	{ \
52	9a64fbe4	bellard	NAME ## _table[n](); \
53	9a64fbe4	bellard	}
54	9a64fbe4	bellard
55	9a64fbe4	bellard	#define GEN16(func, NAME) \
56	9a64fbe4	bellard	static GenOpFunc *NAME ## _table [16] = { \
57	9a64fbe4	bellard	NAME ## 0, NAME ## 1, NAME ## 2, NAME ## 3, \
58	9a64fbe4	bellard	NAME ## 4, NAME ## 5, NAME ## 6, NAME ## 7, \
59	9a64fbe4	bellard	NAME ## 8, NAME ## 9, NAME ## 10, NAME ## 11, \
60	9a64fbe4	bellard	NAME ## 12, NAME ## 13, NAME ## 14, NAME ## 15, \
61	9a64fbe4	bellard	}; \
62	9a64fbe4	bellard	static inline void func(int n) \
63	9a64fbe4	bellard	{ \
64	9a64fbe4	bellard	NAME ## _table[n](); \
65	28b6751f	bellard	}
66	28b6751f	bellard
67	28b6751f	bellard	#define GEN32(func, NAME) \
68	9a64fbe4	bellard	static GenOpFunc *NAME ## _table [32] = { \
69	9a64fbe4	bellard	NAME ## 0, NAME ## 1, NAME ## 2, NAME ## 3, \
70	9a64fbe4	bellard	NAME ## 4, NAME ## 5, NAME ## 6, NAME ## 7, \
71	9a64fbe4	bellard	NAME ## 8, NAME ## 9, NAME ## 10, NAME ## 11, \
72	9a64fbe4	bellard	NAME ## 12, NAME ## 13, NAME ## 14, NAME ## 15, \
73	9a64fbe4	bellard	NAME ## 16, NAME ## 17, NAME ## 18, NAME ## 19, \
74	9a64fbe4	bellard	NAME ## 20, NAME ## 21, NAME ## 22, NAME ## 23, \
75	9a64fbe4	bellard	NAME ## 24, NAME ## 25, NAME ## 26, NAME ## 27, \
76	9a64fbe4	bellard	NAME ## 28, NAME ## 29, NAME ## 30, NAME ## 31, \
77	9a64fbe4	bellard	}; \
78	9a64fbe4	bellard	static inline void func(int n) \
79	9a64fbe4	bellard	{ \
80	9a64fbe4	bellard	NAME ## _table[n](); \
81	9a64fbe4	bellard	}
82	9a64fbe4	bellard
83	9a64fbe4	bellard	/* Condition register moves */
84	9a64fbe4	bellard	GEN8(gen_op_load_crf_T0, gen_op_load_crf_T0_crf);
85	9a64fbe4	bellard	GEN8(gen_op_load_crf_T1, gen_op_load_crf_T1_crf);
86	9a64fbe4	bellard	GEN8(gen_op_store_T0_crf, gen_op_store_T0_crf_crf);
87	9a64fbe4	bellard	GEN8(gen_op_store_T1_crf, gen_op_store_T1_crf_crf);
88	28b6751f	bellard
89	fb0eaffc	bellard	/* Floating point condition and status register moves */
90	fb0eaffc	bellard	GEN8(gen_op_load_fpscr_T0, gen_op_load_fpscr_T0_fpscr);
91	fb0eaffc	bellard	GEN8(gen_op_store_T0_fpscr, gen_op_store_T0_fpscr_fpscr);
92	fb0eaffc	bellard	GEN8(gen_op_clear_fpscr, gen_op_clear_fpscr_fpscr);
93	fb0eaffc	bellard	static GenOpFunc1 *gen_op_store_T0_fpscri_fpscr_table[8] = {
94	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr0,
95	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr1,
96	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr2,
97	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr3,
98	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr4,
99	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr5,
100	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr6,
101	fb0eaffc	bellard	&gen_op_store_T0_fpscri_fpscr7,
102	fb0eaffc	bellard	};
103	fb0eaffc	bellard	static inline void gen_op_store_T0_fpscri(int n, uint8_t param)
104	fb0eaffc	bellard	{
105	fb0eaffc	bellard	(*gen_op_store_T0_fpscri_fpscr_table[n])(param);
106	fb0eaffc	bellard	}
107	fb0eaffc	bellard
108	9a64fbe4	bellard	/* Segment register moves */
109	9a64fbe4	bellard	GEN16(gen_op_load_sr, gen_op_load_sr);
110	9a64fbe4	bellard	GEN16(gen_op_store_sr, gen_op_store_sr);
111	28b6751f	bellard
112	9a64fbe4	bellard	/* General purpose registers moves */
113	9a64fbe4	bellard	GEN32(gen_op_load_gpr_T0, gen_op_load_gpr_T0_gpr);
114	9a64fbe4	bellard	GEN32(gen_op_load_gpr_T1, gen_op_load_gpr_T1_gpr);
115	9a64fbe4	bellard	GEN32(gen_op_load_gpr_T2, gen_op_load_gpr_T2_gpr);
116	9a64fbe4	bellard
117	9a64fbe4	bellard	GEN32(gen_op_store_T0_gpr, gen_op_store_T0_gpr_gpr);
118	9a64fbe4	bellard	GEN32(gen_op_store_T1_gpr, gen_op_store_T1_gpr_gpr);
119	9a64fbe4	bellard	GEN32(gen_op_store_T2_gpr, gen_op_store_T2_gpr_gpr);
120	28b6751f	bellard
121	fb0eaffc	bellard	/* floating point registers moves */
122	fb0eaffc	bellard	GEN32(gen_op_load_fpr_FT0, gen_op_load_fpr_FT0_fpr);
123	fb0eaffc	bellard	GEN32(gen_op_load_fpr_FT1, gen_op_load_fpr_FT1_fpr);
124	fb0eaffc	bellard	GEN32(gen_op_load_fpr_FT2, gen_op_load_fpr_FT2_fpr);
125	fb0eaffc	bellard	GEN32(gen_op_store_FT0_fpr, gen_op_store_FT0_fpr_fpr);
126	fb0eaffc	bellard	GEN32(gen_op_store_FT1_fpr, gen_op_store_FT1_fpr_fpr);
127	fb0eaffc	bellard	GEN32(gen_op_store_FT2_fpr, gen_op_store_FT2_fpr_fpr);
128	79aceca5	bellard
129	79aceca5	bellard	static uint8_t spr_access[1024 / 2];
130	79aceca5	bellard
131	79aceca5	bellard	/* internal defines */
132	79aceca5	bellard	typedef struct DisasContext {
133	79aceca5	bellard	struct TranslationBlock *tb;
134	0fa85d43	bellard	target_ulong nip;
135	79aceca5	bellard	uint32_t opcode;
136	9a64fbe4	bellard	uint32_t exception;
137	9a64fbe4	bellard	/* Execution mode */
138	9a64fbe4	bellard	#if !defined(CONFIG_USER_ONLY)
139	79aceca5	bellard	int supervisor;
140	9a64fbe4	bellard	#endif
141	9a64fbe4	bellard	/* Routine used to access memory */
142	9a64fbe4	bellard	int mem_idx;
143	79aceca5	bellard	} DisasContext;
144	79aceca5	bellard
145	79aceca5	bellard	typedef struct opc_handler_t {
146	79aceca5	bellard	/* invalid bits */
147	79aceca5	bellard	uint32_t inval;
148	9a64fbe4	bellard	/* instruction type */
149	9a64fbe4	bellard	uint32_t type;
150	79aceca5	bellard	/* handler */
151	79aceca5	bellard	void (handler)(DisasContext ctx);
152	79aceca5	bellard	} opc_handler_t;
153	79aceca5	bellard
154	9fddaa0c	bellard	#define RET_EXCP(ctx, excp, error) \
155	79aceca5	bellard	do { \
156	9fddaa0c	bellard	if ((ctx)->exception == EXCP_NONE) { \
157	9fddaa0c	bellard	gen_op_update_nip((ctx)->nip); \
158	9fddaa0c	bellard	} \
159	9fddaa0c	bellard	gen_op_raise_exception_err((excp), (error)); \
160	9fddaa0c	bellard	ctx->exception = (excp); \
161	79aceca5	bellard	} while (0)
162	79aceca5	bellard
163	9fddaa0c	bellard	#define RET_INVAL(ctx) \
164	9fddaa0c	bellard	RET_EXCP((ctx), EXCP_PROGRAM, EXCP_INVAL \| EXCP_INVAL_INVAL)
165	9fddaa0c	bellard
166	9fddaa0c	bellard	#define RET_PRIVOPC(ctx) \
167	9fddaa0c	bellard	RET_EXCP((ctx), EXCP_PROGRAM, EXCP_INVAL \| EXCP_PRIV_OPC)
168	9a64fbe4	bellard
169	9fddaa0c	bellard	#define RET_PRIVREG(ctx) \
170	9fddaa0c	bellard	RET_EXCP((ctx), EXCP_PROGRAM, EXCP_INVAL \| EXCP_PRIV_REG)
171	9a64fbe4	bellard
172	9fddaa0c	bellard	#define RET_MTMSR(ctx) \
173	9fddaa0c	bellard	RET_EXCP((ctx), EXCP_MTMSR, 0)
174	79aceca5	bellard
175	79aceca5	bellard	#define GEN_HANDLER(name, opc1, opc2, opc3, inval, type) \
176	79aceca5	bellard	static void gen_##name (DisasContext *ctx); \
177	79aceca5	bellard	GEN_OPCODE(name, opc1, opc2, opc3, inval, type); \
178	79aceca5	bellard	static void gen_##name (DisasContext *ctx)
179	79aceca5	bellard
180	79aceca5	bellard	typedef struct opcode_t {
181	79aceca5	bellard	unsigned char opc1, opc2, opc3;
182	79aceca5	bellard	opc_handler_t handler;
183	79aceca5	bellard	} opcode_t;
184	79aceca5	bellard
185	79aceca5	bellard	/* Instruction decoding */
186	79aceca5	bellard	#define EXTRACT_HELPER(name, shift, nb) \
187	79aceca5	bellard	static inline uint32_t name (uint32_t opcode) \
188	79aceca5	bellard	{ \
189	79aceca5	bellard	return (opcode >> (shift)) & ((1 << (nb)) - 1); \
190	79aceca5	bellard	}
191	79aceca5	bellard
192	79aceca5	bellard	#define EXTRACT_SHELPER(name, shift, nb) \
193	79aceca5	bellard	static inline int32_t name (uint32_t opcode) \
194	79aceca5	bellard	{ \
195	79aceca5	bellard	return s_ext16((opcode >> (shift)) & ((1 << (nb)) - 1)); \
196	79aceca5	bellard	}
197	79aceca5	bellard
198	79aceca5	bellard	/* Opcode part 1 */
199	79aceca5	bellard	EXTRACT_HELPER(opc1, 26, 6);
200	79aceca5	bellard	/* Opcode part 2 */
201	79aceca5	bellard	EXTRACT_HELPER(opc2, 1, 5);
202	79aceca5	bellard	/* Opcode part 3 */
203	79aceca5	bellard	EXTRACT_HELPER(opc3, 6, 5);
204	79aceca5	bellard	/* Update Cr0 flags */
205	79aceca5	bellard	EXTRACT_HELPER(Rc, 0, 1);
206	79aceca5	bellard	/* Destination */
207	79aceca5	bellard	EXTRACT_HELPER(rD, 21, 5);
208	79aceca5	bellard	/* Source */
209	79aceca5	bellard	EXTRACT_HELPER(rS, 21, 5);
210	79aceca5	bellard	/* First operand */
211	79aceca5	bellard	EXTRACT_HELPER(rA, 16, 5);
212	79aceca5	bellard	/* Second operand */
213	79aceca5	bellard	EXTRACT_HELPER(rB, 11, 5);
214	79aceca5	bellard	/* Third operand */
215	79aceca5	bellard	EXTRACT_HELPER(rC, 6, 5);
216	79aceca5	bellard	/* Get CRn */
217	79aceca5	bellard	EXTRACT_HELPER(crfD, 23, 3);
218	79aceca5	bellard	EXTRACT_HELPER(crfS, 18, 3);
219	79aceca5	bellard	EXTRACT_HELPER(crbD, 21, 5);
220	79aceca5	bellard	EXTRACT_HELPER(crbA, 16, 5);
221	79aceca5	bellard	EXTRACT_HELPER(crbB, 11, 5);
222	79aceca5	bellard	/* SPR / TBL */
223	79aceca5	bellard	EXTRACT_HELPER(SPR, 11, 10);
224	79aceca5	bellard	/* Get constants */
225	79aceca5	bellard	EXTRACT_HELPER(IMM, 12, 8);
226	79aceca5	bellard	/* 16 bits signed immediate value */
227	79aceca5	bellard	EXTRACT_SHELPER(SIMM, 0, 16);
228	79aceca5	bellard	/* 16 bits unsigned immediate value */
229	79aceca5	bellard	EXTRACT_HELPER(UIMM, 0, 16);
230	79aceca5	bellard	/* Bit count */
231	79aceca5	bellard	EXTRACT_HELPER(NB, 11, 5);
232	79aceca5	bellard	/* Shift count */
233	79aceca5	bellard	EXTRACT_HELPER(SH, 11, 5);
234	79aceca5	bellard	/* Mask start */
235	79aceca5	bellard	EXTRACT_HELPER(MB, 6, 5);
236	79aceca5	bellard	/* Mask end */
237	79aceca5	bellard	EXTRACT_HELPER(ME, 1, 5);
238	fb0eaffc	bellard	/* Trap operand */
239	fb0eaffc	bellard	EXTRACT_HELPER(TO, 21, 5);
240	79aceca5	bellard
241	79aceca5	bellard	EXTRACT_HELPER(CRM, 12, 8);
242	79aceca5	bellard	EXTRACT_HELPER(FM, 17, 8);
243	79aceca5	bellard	EXTRACT_HELPER(SR, 16, 4);
244	fb0eaffc	bellard	EXTRACT_HELPER(FPIMM, 20, 4);
245	fb0eaffc	bellard
246	79aceca5	bellard	/* Jump target decoding */
247	79aceca5	bellard	/* Displacement */
248	79aceca5	bellard	EXTRACT_SHELPER(d, 0, 16);
249	79aceca5	bellard	/* Immediate address */
250	79aceca5	bellard	static inline uint32_t LI (uint32_t opcode)
251	79aceca5	bellard	{
252	79aceca5	bellard	return (opcode >> 0) & 0x03FFFFFC;
253	79aceca5	bellard	}
254	79aceca5	bellard
255	79aceca5	bellard	static inline uint32_t BD (uint32_t opcode)
256	79aceca5	bellard	{
257	79aceca5	bellard	return (opcode >> 0) & 0xFFFC;
258	79aceca5	bellard	}
259	79aceca5	bellard
260	79aceca5	bellard	EXTRACT_HELPER(BO, 21, 5);
261	79aceca5	bellard	EXTRACT_HELPER(BI, 16, 5);
262	79aceca5	bellard	/* Absolute/relative address */
263	79aceca5	bellard	EXTRACT_HELPER(AA, 1, 1);
264	79aceca5	bellard	/* Link */
265	79aceca5	bellard	EXTRACT_HELPER(LK, 0, 1);
266	79aceca5	bellard
267	79aceca5	bellard	/* Create a mask between <start> and <end> bits */
268	79aceca5	bellard	static inline uint32_t MASK (uint32_t start, uint32_t end)
269	79aceca5	bellard	{
270	79aceca5	bellard	uint32_t ret;
271	79aceca5	bellard
272	79aceca5	bellard	ret = (((uint32_t)(-1)) >> (start)) ^ (((uint32_t)(-1) >> (end)) >> 1);
273	79aceca5	bellard	if (start > end)
274	79aceca5	bellard	return ~ret;
275	79aceca5	bellard
276	79aceca5	bellard	return ret;
277	79aceca5	bellard	}
278	79aceca5	bellard
279	1b039c09	bellard	#if defined(__APPLE__)
280	933dc6eb	bellard	#define OPCODES_SECTION \
281	1b039c09	bellard	__attribute__ ((section("__TEXT,__opcodes"), unused, aligned (8) ))
282	933dc6eb	bellard	#else
283	1b039c09	bellard	#define OPCODES_SECTION \
284	1b039c09	bellard	__attribute__ ((section(".opcodes"), unused, aligned (8) ))
285	933dc6eb	bellard	#endif
286	933dc6eb	bellard
287	79aceca5	bellard	#define GEN_OPCODE(name, op1, op2, op3, invl, _typ) \
288	933dc6eb	bellard	OPCODES_SECTION static opcode_t opc_##name = { \
289	79aceca5	bellard	.opc1 = op1, \
290	79aceca5	bellard	.opc2 = op2, \
291	79aceca5	bellard	.opc3 = op3, \
292	79aceca5	bellard	.handler = { \
293	79aceca5	bellard	.inval = invl, \
294	9a64fbe4	bellard	.type = _typ, \
295	79aceca5	bellard	.handler = &gen_##name, \
296	79aceca5	bellard	}, \
297	79aceca5	bellard	}
298	79aceca5	bellard
299	79aceca5	bellard	#define GEN_OPCODE_MARK(name) \
300	933dc6eb	bellard	OPCODES_SECTION static opcode_t opc_##name = { \
301	79aceca5	bellard	.opc1 = 0xFF, \
302	79aceca5	bellard	.opc2 = 0xFF, \
303	79aceca5	bellard	.opc3 = 0xFF, \
304	79aceca5	bellard	.handler = { \
305	79aceca5	bellard	.inval = 0x00000000, \
306	9a64fbe4	bellard	.type = 0x00, \
307	79aceca5	bellard	.handler = NULL, \
308	79aceca5	bellard	}, \
309	79aceca5	bellard	}
310	79aceca5	bellard
311	79aceca5	bellard	/* Start opcode list */
312	79aceca5	bellard	GEN_OPCODE_MARK(start);
313	79aceca5	bellard
314	79aceca5	bellard	/* Invalid instruction */
315	9a64fbe4	bellard	GEN_HANDLER(invalid, 0x00, 0x00, 0x00, 0xFFFFFFFF, PPC_NONE)
316	9a64fbe4	bellard	{
317	9fddaa0c	bellard	RET_INVAL(ctx);
318	9a64fbe4	bellard	}
319	9a64fbe4	bellard
320	9a64fbe4	bellard	/* Special opcode to stop emulation */
321	9a64fbe4	bellard	GEN_HANDLER(stop, 0x06, 0x00, 0xFF, 0x03FFFFC1, PPC_COMMON)
322	79aceca5	bellard	{
323	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_HLT, 0);
324	9a64fbe4	bellard	}
325	9a64fbe4	bellard
326	9a64fbe4	bellard	/* Special opcode to call open-firmware */
327	9a64fbe4	bellard	GEN_HANDLER(of_enter, 0x06, 0x01, 0xFF, 0x03FFFFC1, PPC_COMMON)
328	9a64fbe4	bellard	{
329	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_OFCALL, 0);
330	9a64fbe4	bellard	}
331	9a64fbe4	bellard
332	9a64fbe4	bellard	/* Special opcode to call RTAS */
333	9a64fbe4	bellard	GEN_HANDLER(rtas_enter, 0x06, 0x02, 0xFF, 0x03FFFFC1, PPC_COMMON)
334	9a64fbe4	bellard	{
335	9a64fbe4	bellard	printf("RTAS entry point !\n");
336	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_RTASCALL, 0);
337	79aceca5	bellard	}
338	79aceca5	bellard
339	79aceca5	bellard	static opc_handler_t invalid_handler = {
340	79aceca5	bellard	.inval = 0xFFFFFFFF,
341	9a64fbe4	bellard	.type = PPC_NONE,
342	79aceca5	bellard	.handler = gen_invalid,
343	79aceca5	bellard	};
344	79aceca5	bellard
345	79aceca5	bellard	/* Integer arithmetic */
346	79aceca5	bellard	#define __GEN_INT_ARITH2(name, opc1, opc2, opc3, inval) \
347	79aceca5	bellard	GEN_HANDLER(name, opc1, opc2, opc3, inval, PPC_INTEGER) \
348	79aceca5	bellard	{ \
349	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
350	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
351	79aceca5	bellard	gen_op_##name(); \
352	79aceca5	bellard	if (Rc(ctx->opcode) != 0) \
353	79aceca5	bellard	gen_op_set_Rc0(); \
354	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode)); \
355	79aceca5	bellard	}
356	79aceca5	bellard
357	79aceca5	bellard	#define __GEN_INT_ARITH2_O(name, opc1, opc2, opc3, inval) \
358	79aceca5	bellard	GEN_HANDLER(name, opc1, opc2, opc3, inval, PPC_INTEGER) \
359	79aceca5	bellard	{ \
360	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
361	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
362	79aceca5	bellard	gen_op_##name(); \
363	79aceca5	bellard	if (Rc(ctx->opcode) != 0) \
364	79aceca5	bellard	gen_op_set_Rc0_ov(); \
365	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode)); \
366	79aceca5	bellard	}
367	79aceca5	bellard
368	79aceca5	bellard	#define __GEN_INT_ARITH1(name, opc1, opc2, opc3) \
369	79aceca5	bellard	GEN_HANDLER(name, opc1, opc2, opc3, 0x0000F800, PPC_INTEGER) \
370	79aceca5	bellard	{ \
371	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
372	79aceca5	bellard	gen_op_##name(); \
373	79aceca5	bellard	if (Rc(ctx->opcode) != 0) \
374	79aceca5	bellard	gen_op_set_Rc0(); \
375	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode)); \
376	79aceca5	bellard	}
377	79aceca5	bellard	#define __GEN_INT_ARITH1_O(name, opc1, opc2, opc3) \
378	79aceca5	bellard	GEN_HANDLER(name, opc1, opc2, opc3, 0x0000F800, PPC_INTEGER) \
379	79aceca5	bellard	{ \
380	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
381	79aceca5	bellard	gen_op_##name(); \
382	79aceca5	bellard	if (Rc(ctx->opcode) != 0) \
383	79aceca5	bellard	gen_op_set_Rc0_ov(); \
384	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode)); \
385	79aceca5	bellard	}
386	79aceca5	bellard
387	79aceca5	bellard	/* Two operands arithmetic functions */
388	79aceca5	bellard	#define GEN_INT_ARITH2(name, opc1, opc2, opc3) \
389	79aceca5	bellard	__GEN_INT_ARITH2(name, opc1, opc2, opc3, 0x00000000) \
390	79aceca5	bellard	__GEN_INT_ARITH2_O(name##o, opc1, opc2, opc3 \| 0x10, 0x00000000)
391	79aceca5	bellard
392	79aceca5	bellard	/* Two operands arithmetic functions with no overflow allowed */
393	79aceca5	bellard	#define GEN_INT_ARITHN(name, opc1, opc2, opc3) \
394	79aceca5	bellard	__GEN_INT_ARITH2(name, opc1, opc2, opc3, 0x00000400)
395	79aceca5	bellard
396	79aceca5	bellard	/* One operand arithmetic functions */
397	79aceca5	bellard	#define GEN_INT_ARITH1(name, opc1, opc2, opc3) \
398	79aceca5	bellard	__GEN_INT_ARITH1(name, opc1, opc2, opc3) \
399	79aceca5	bellard	__GEN_INT_ARITH1_O(name##o, opc1, opc2, opc3 \| 0x10)
400	79aceca5	bellard
401	79aceca5	bellard	/* add add. addo addo. */
402	79aceca5	bellard	GEN_INT_ARITH2 (add, 0x1F, 0x0A, 0x08);
403	79aceca5	bellard	/* addc addc. addco addco. */
404	79aceca5	bellard	GEN_INT_ARITH2 (addc, 0x1F, 0x0A, 0x00);
405	79aceca5	bellard	/* adde adde. addeo addeo. */
406	79aceca5	bellard	GEN_INT_ARITH2 (adde, 0x1F, 0x0A, 0x04);
407	79aceca5	bellard	/* addme addme. addmeo addmeo. */
408	79aceca5	bellard	GEN_INT_ARITH1 (addme, 0x1F, 0x0A, 0x07);
409	79aceca5	bellard	/* addze addze. addzeo addzeo. */
410	79aceca5	bellard	GEN_INT_ARITH1 (addze, 0x1F, 0x0A, 0x06);
411	79aceca5	bellard	/* divw divw. divwo divwo. */
412	79aceca5	bellard	GEN_INT_ARITH2 (divw, 0x1F, 0x0B, 0x0F);
413	79aceca5	bellard	/* divwu divwu. divwuo divwuo. */
414	79aceca5	bellard	GEN_INT_ARITH2 (divwu, 0x1F, 0x0B, 0x0E);
415	79aceca5	bellard	/* mulhw mulhw. */
416	79aceca5	bellard	GEN_INT_ARITHN (mulhw, 0x1F, 0x0B, 0x02);
417	79aceca5	bellard	/* mulhwu mulhwu. */
418	79aceca5	bellard	GEN_INT_ARITHN (mulhwu, 0x1F, 0x0B, 0x00);
419	79aceca5	bellard	/* mullw mullw. mullwo mullwo. */
420	79aceca5	bellard	GEN_INT_ARITH2 (mullw, 0x1F, 0x0B, 0x07);
421	79aceca5	bellard	/* neg neg. nego nego. */
422	79aceca5	bellard	GEN_INT_ARITH1 (neg, 0x1F, 0x08, 0x03);
423	79aceca5	bellard	/* subf subf. subfo subfo. */
424	79aceca5	bellard	GEN_INT_ARITH2 (subf, 0x1F, 0x08, 0x01);
425	79aceca5	bellard	/* subfc subfc. subfco subfco. */
426	79aceca5	bellard	GEN_INT_ARITH2 (subfc, 0x1F, 0x08, 0x00);
427	79aceca5	bellard	/* subfe subfe. subfeo subfeo. */
428	79aceca5	bellard	GEN_INT_ARITH2 (subfe, 0x1F, 0x08, 0x04);
429	79aceca5	bellard	/* subfme subfme. subfmeo subfmeo. */
430	79aceca5	bellard	GEN_INT_ARITH1 (subfme, 0x1F, 0x08, 0x07);
431	79aceca5	bellard	/* subfze subfze. subfzeo subfzeo. */
432	79aceca5	bellard	GEN_INT_ARITH1 (subfze, 0x1F, 0x08, 0x06);
433	79aceca5	bellard	/* addi */
434	79aceca5	bellard	GEN_HANDLER(addi, 0x0E, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
435	79aceca5	bellard	{
436	79aceca5	bellard	int32_t simm = SIMM(ctx->opcode);
437	79aceca5	bellard
438	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
439	79aceca5	bellard	gen_op_set_T0(simm);
440	79aceca5	bellard	} else {
441	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
442	79aceca5	bellard	gen_op_addi(simm);
443	79aceca5	bellard	}
444	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
445	79aceca5	bellard	}
446	79aceca5	bellard	/* addic */
447	79aceca5	bellard	GEN_HANDLER(addic, 0x0C, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
448	79aceca5	bellard	{
449	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
450	79aceca5	bellard	gen_op_addic(SIMM(ctx->opcode));
451	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
452	79aceca5	bellard	}
453	79aceca5	bellard	/* addic. */
454	79aceca5	bellard	GEN_HANDLER(addic_, 0x0D, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
455	79aceca5	bellard	{
456	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
457	79aceca5	bellard	gen_op_addic(SIMM(ctx->opcode));
458	79aceca5	bellard	gen_op_set_Rc0();
459	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
460	79aceca5	bellard	}
461	79aceca5	bellard	/* addis */
462	79aceca5	bellard	GEN_HANDLER(addis, 0x0F, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
463	79aceca5	bellard	{
464	79aceca5	bellard	int32_t simm = SIMM(ctx->opcode);
465	79aceca5	bellard
466	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
467	79aceca5	bellard	gen_op_set_T0(simm << 16);
468	79aceca5	bellard	} else {
469	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
470	79aceca5	bellard	gen_op_addi(simm << 16);
471	79aceca5	bellard	}
472	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
473	79aceca5	bellard	}
474	79aceca5	bellard	/* mulli */
475	79aceca5	bellard	GEN_HANDLER(mulli, 0x07, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
476	79aceca5	bellard	{
477	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
478	79aceca5	bellard	gen_op_mulli(SIMM(ctx->opcode));
479	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
480	79aceca5	bellard	}
481	79aceca5	bellard	/* subfic */
482	79aceca5	bellard	GEN_HANDLER(subfic, 0x08, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
483	79aceca5	bellard	{
484	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
485	79aceca5	bellard	gen_op_subfic(SIMM(ctx->opcode));
486	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
487	79aceca5	bellard	}
488	79aceca5	bellard
489	79aceca5	bellard	/* Integer comparison */
490	79aceca5	bellard	#define GEN_CMP(name, opc) \
491	79aceca5	bellard	GEN_HANDLER(name, 0x1F, 0x00, opc, 0x00400000, PPC_INTEGER) \
492	79aceca5	bellard	{ \
493	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
494	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
495	79aceca5	bellard	gen_op_##name(); \
496	79aceca5	bellard	gen_op_store_T0_crf(crfD(ctx->opcode)); \
497	79aceca5	bellard	}
498	79aceca5	bellard
499	79aceca5	bellard	/* cmp */
500	79aceca5	bellard	GEN_CMP(cmp, 0x00);
501	79aceca5	bellard	/* cmpi */
502	79aceca5	bellard	GEN_HANDLER(cmpi, 0x0B, 0xFF, 0xFF, 0x00400000, PPC_INTEGER)
503	79aceca5	bellard	{
504	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
505	79aceca5	bellard	gen_op_cmpi(SIMM(ctx->opcode));
506	79aceca5	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
507	79aceca5	bellard	}
508	79aceca5	bellard	/* cmpl */
509	79aceca5	bellard	GEN_CMP(cmpl, 0x01);
510	79aceca5	bellard	/* cmpli */
511	79aceca5	bellard	GEN_HANDLER(cmpli, 0x0A, 0xFF, 0xFF, 0x00400000, PPC_INTEGER)
512	79aceca5	bellard	{
513	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
514	79aceca5	bellard	gen_op_cmpli(UIMM(ctx->opcode));
515	79aceca5	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
516	79aceca5	bellard	}
517	79aceca5	bellard
518	79aceca5	bellard	/* Integer logical */
519	79aceca5	bellard	#define __GEN_LOGICAL2(name, opc2, opc3) \
520	79aceca5	bellard	GEN_HANDLER(name, 0x1F, opc2, opc3, 0x00000000, PPC_INTEGER) \
521	79aceca5	bellard	{ \
522	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode)); \
523	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
524	79aceca5	bellard	gen_op_##name(); \
525	79aceca5	bellard	if (Rc(ctx->opcode) != 0) \
526	79aceca5	bellard	gen_op_set_Rc0(); \
527	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
528	79aceca5	bellard	}
529	79aceca5	bellard	#define GEN_LOGICAL2(name, opc) \
530	79aceca5	bellard	__GEN_LOGICAL2(name, 0x1C, opc)
531	79aceca5	bellard
532	79aceca5	bellard	#define GEN_LOGICAL1(name, opc) \
533	79aceca5	bellard	GEN_HANDLER(name, 0x1F, 0x1A, opc, 0x00000000, PPC_INTEGER) \
534	79aceca5	bellard	{ \
535	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode)); \
536	79aceca5	bellard	gen_op_##name(); \
537	79aceca5	bellard	if (Rc(ctx->opcode) != 0) \
538	79aceca5	bellard	gen_op_set_Rc0(); \
539	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
540	79aceca5	bellard	}
541	79aceca5	bellard
542	79aceca5	bellard	/* and & and. */
543	79aceca5	bellard	GEN_LOGICAL2(and, 0x00);
544	79aceca5	bellard	/* andc & andc. */
545	79aceca5	bellard	GEN_LOGICAL2(andc, 0x01);
546	79aceca5	bellard	/* andi. */
547	79aceca5	bellard	GEN_HANDLER(andi_, 0x1C, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
548	79aceca5	bellard	{
549	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
550	79aceca5	bellard	gen_op_andi_(UIMM(ctx->opcode));
551	79aceca5	bellard	gen_op_set_Rc0();
552	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
553	79aceca5	bellard	}
554	79aceca5	bellard	/* andis. */
555	79aceca5	bellard	GEN_HANDLER(andis_, 0x1D, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
556	79aceca5	bellard	{
557	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
558	79aceca5	bellard	gen_op_andi_(UIMM(ctx->opcode) << 16);
559	79aceca5	bellard	gen_op_set_Rc0();
560	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
561	79aceca5	bellard	}
562	79aceca5	bellard
563	79aceca5	bellard	/* cntlzw */
564	79aceca5	bellard	GEN_LOGICAL1(cntlzw, 0x00);
565	79aceca5	bellard	/* eqv & eqv. */
566	79aceca5	bellard	GEN_LOGICAL2(eqv, 0x08);
567	79aceca5	bellard	/* extsb & extsb. */
568	79aceca5	bellard	GEN_LOGICAL1(extsb, 0x1D);
569	79aceca5	bellard	/* extsh & extsh. */
570	79aceca5	bellard	GEN_LOGICAL1(extsh, 0x1C);
571	79aceca5	bellard	/* nand & nand. */
572	79aceca5	bellard	GEN_LOGICAL2(nand, 0x0E);
573	79aceca5	bellard	/* nor & nor. */
574	79aceca5	bellard	GEN_LOGICAL2(nor, 0x03);
575	9a64fbe4	bellard
576	79aceca5	bellard	/* or & or. */
577	9a64fbe4	bellard	GEN_HANDLER(or, 0x1F, 0x1C, 0x0D, 0x00000000, PPC_INTEGER)
578	9a64fbe4	bellard	{
579	9a64fbe4	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
580	9a64fbe4	bellard	/* Optimisation for mr case */
581	9a64fbe4	bellard	if (rS(ctx->opcode) != rB(ctx->opcode)) {
582	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
583	9a64fbe4	bellard	gen_op_or();
584	9a64fbe4	bellard	}
585	9a64fbe4	bellard	if (Rc(ctx->opcode) != 0)
586	9a64fbe4	bellard	gen_op_set_Rc0();
587	9a64fbe4	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
588	9a64fbe4	bellard	}
589	9a64fbe4	bellard
590	79aceca5	bellard	/* orc & orc. */
591	79aceca5	bellard	GEN_LOGICAL2(orc, 0x0C);
592	79aceca5	bellard	/* xor & xor. */
593	9a64fbe4	bellard	GEN_HANDLER(xor, 0x1F, 0x1C, 0x09, 0x00000000, PPC_INTEGER)
594	9a64fbe4	bellard	{
595	9a64fbe4	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
596	9a64fbe4	bellard	/* Optimisation for "set to zero" case */
597	9a64fbe4	bellard	if (rS(ctx->opcode) != rB(ctx->opcode)) {
598	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
599	9a64fbe4	bellard	gen_op_xor();
600	9a64fbe4	bellard	} else {
601	9a64fbe4	bellard	gen_op_set_T0(0);
602	9a64fbe4	bellard	}
603	9a64fbe4	bellard	if (Rc(ctx->opcode) != 0)
604	9a64fbe4	bellard	gen_op_set_Rc0();
605	9a64fbe4	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
606	9a64fbe4	bellard	}
607	79aceca5	bellard	/* ori */
608	79aceca5	bellard	GEN_HANDLER(ori, 0x18, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
609	79aceca5	bellard	{
610	79aceca5	bellard	uint32_t uimm = UIMM(ctx->opcode);
611	79aceca5	bellard
612	9a64fbe4	bellard	if (rS(ctx->opcode) == rA(ctx->opcode) && uimm == 0) {
613	9a64fbe4	bellard	/* NOP */
614	9a64fbe4	bellard	return;
615	79aceca5	bellard	}
616	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
617	9a64fbe4	bellard	if (uimm != 0)
618	79aceca5	bellard	gen_op_ori(uimm);
619	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
620	79aceca5	bellard	}
621	79aceca5	bellard	/* oris */
622	79aceca5	bellard	GEN_HANDLER(oris, 0x19, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
623	79aceca5	bellard	{
624	79aceca5	bellard	uint32_t uimm = UIMM(ctx->opcode);
625	79aceca5	bellard
626	9a64fbe4	bellard	if (rS(ctx->opcode) == rA(ctx->opcode) && uimm == 0) {
627	9a64fbe4	bellard	/* NOP */
628	9a64fbe4	bellard	return;
629	79aceca5	bellard	}
630	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
631	9a64fbe4	bellard	if (uimm != 0)
632	79aceca5	bellard	gen_op_ori(uimm << 16);
633	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
634	79aceca5	bellard	}
635	79aceca5	bellard	/* xori */
636	79aceca5	bellard	GEN_HANDLER(xori, 0x1A, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
637	79aceca5	bellard	{
638	9a64fbe4	bellard	uint32_t uimm = UIMM(ctx->opcode);
639	9a64fbe4	bellard
640	9a64fbe4	bellard	if (rS(ctx->opcode) == rA(ctx->opcode) && uimm == 0) {
641	9a64fbe4	bellard	/* NOP */
642	9a64fbe4	bellard	return;
643	9a64fbe4	bellard	}
644	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
645	9a64fbe4	bellard	if (uimm != 0)
646	4b3686fa	bellard	gen_op_xori(uimm);
647	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
648	79aceca5	bellard	}
649	79aceca5	bellard
650	79aceca5	bellard	/* xoris */
651	79aceca5	bellard	GEN_HANDLER(xoris, 0x1B, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
652	79aceca5	bellard	{
653	9a64fbe4	bellard	uint32_t uimm = UIMM(ctx->opcode);
654	9a64fbe4	bellard
655	9a64fbe4	bellard	if (rS(ctx->opcode) == rA(ctx->opcode) && uimm == 0) {
656	9a64fbe4	bellard	/* NOP */
657	9a64fbe4	bellard	return;
658	9a64fbe4	bellard	}
659	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
660	9a64fbe4	bellard	if (uimm != 0)
661	4b3686fa	bellard	gen_op_xori(uimm << 16);
662	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
663	79aceca5	bellard	}
664	79aceca5	bellard
665	79aceca5	bellard	/* Integer rotate */
666	79aceca5	bellard	/* rlwimi & rlwimi. */
667	79aceca5	bellard	GEN_HANDLER(rlwimi, 0x14, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
668	79aceca5	bellard	{
669	79aceca5	bellard	uint32_t mb, me;
670	79aceca5	bellard
671	79aceca5	bellard	mb = MB(ctx->opcode);
672	79aceca5	bellard	me = ME(ctx->opcode);
673	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
674	fb0eaffc	bellard	gen_op_load_gpr_T1(rA(ctx->opcode));
675	79aceca5	bellard	gen_op_rlwimi(SH(ctx->opcode), MASK(mb, me), ~MASK(mb, me));
676	79aceca5	bellard	if (Rc(ctx->opcode) != 0)
677	79aceca5	bellard	gen_op_set_Rc0();
678	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
679	79aceca5	bellard	}
680	79aceca5	bellard	/* rlwinm & rlwinm. */
681	79aceca5	bellard	GEN_HANDLER(rlwinm, 0x15, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
682	79aceca5	bellard	{
683	79aceca5	bellard	uint32_t mb, me, sh;
684	79aceca5	bellard
685	79aceca5	bellard	sh = SH(ctx->opcode);
686	79aceca5	bellard	mb = MB(ctx->opcode);
687	79aceca5	bellard	me = ME(ctx->opcode);
688	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
689	4b3686fa	bellard	#if 1 // TRY
690	4b3686fa	bellard	if (sh == 0) {
691	4b3686fa	bellard	gen_op_andi_(MASK(mb, me));
692	4b3686fa	bellard	goto store;
693	4b3686fa	bellard	}
694	4b3686fa	bellard	#endif
695	79aceca5	bellard	if (mb == 0) {
696	79aceca5	bellard	if (me == 31) {
697	79aceca5	bellard	gen_op_rotlwi(sh);
698	79aceca5	bellard	goto store;
699	4b3686fa	bellard	#if 0
700	79aceca5	bellard	} else if (me == (31 - sh)) {
701	79aceca5	bellard	gen_op_slwi(sh);
702	79aceca5	bellard	goto store;
703	4b3686fa	bellard	#endif
704	79aceca5	bellard	}
705	79aceca5	bellard	} else if (me == 31) {
706	4b3686fa	bellard	#if 0
707	79aceca5	bellard	if (sh == (32 - mb)) {
708	79aceca5	bellard	gen_op_srwi(mb);
709	79aceca5	bellard	goto store;
710	79aceca5	bellard	}
711	4b3686fa	bellard	#endif
712	79aceca5	bellard	}
713	79aceca5	bellard	gen_op_rlwinm(sh, MASK(mb, me));
714	79aceca5	bellard	store:
715	79aceca5	bellard	if (Rc(ctx->opcode) != 0)
716	79aceca5	bellard	gen_op_set_Rc0();
717	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
718	79aceca5	bellard	}
719	79aceca5	bellard	/* rlwnm & rlwnm. */
720	79aceca5	bellard	GEN_HANDLER(rlwnm, 0x17, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
721	79aceca5	bellard	{
722	79aceca5	bellard	uint32_t mb, me;
723	79aceca5	bellard
724	79aceca5	bellard	mb = MB(ctx->opcode);
725	79aceca5	bellard	me = ME(ctx->opcode);
726	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
727	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
728	79aceca5	bellard	if (mb == 0 && me == 31) {
729	79aceca5	bellard	gen_op_rotl();
730	79aceca5	bellard	} else
731	79aceca5	bellard	{
732	79aceca5	bellard	gen_op_rlwnm(MASK(mb, me));
733	79aceca5	bellard	}
734	79aceca5	bellard	if (Rc(ctx->opcode) != 0)
735	79aceca5	bellard	gen_op_set_Rc0();
736	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
737	79aceca5	bellard	}
738	79aceca5	bellard
739	79aceca5	bellard	/* Integer shift */
740	79aceca5	bellard	/* slw & slw. */
741	79aceca5	bellard	__GEN_LOGICAL2(slw, 0x18, 0x00);
742	79aceca5	bellard	/* sraw & sraw. */
743	79aceca5	bellard	__GEN_LOGICAL2(sraw, 0x18, 0x18);
744	79aceca5	bellard	/* srawi & srawi. */
745	79aceca5	bellard	GEN_HANDLER(srawi, 0x1F, 0x18, 0x19, 0x00000000, PPC_INTEGER)
746	79aceca5	bellard	{
747	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
748	79aceca5	bellard	gen_op_srawi(SH(ctx->opcode), MASK(32 - SH(ctx->opcode), 31));
749	79aceca5	bellard	if (Rc(ctx->opcode) != 0)
750	79aceca5	bellard	gen_op_set_Rc0();
751	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode));
752	79aceca5	bellard	}
753	79aceca5	bellard	/* srw & srw. */
754	79aceca5	bellard	__GEN_LOGICAL2(srw, 0x18, 0x10);
755	79aceca5	bellard
756	79aceca5	bellard	/* Floating-Point arithmetic */
757	9a64fbe4	bellard	#define _GEN_FLOAT_ACB(name, op1, op2) \
758	9a64fbe4	bellard	GEN_HANDLER(f##name, op1, op2, 0xFF, 0x00000000, PPC_FLOAT) \
759	9a64fbe4	bellard	{ \
760	9a64fbe4	bellard	gen_op_reset_scrfx(); \
761	9a64fbe4	bellard	gen_op_load_fpr_FT0(rA(ctx->opcode)); \
762	9a64fbe4	bellard	gen_op_load_fpr_FT1(rC(ctx->opcode)); \
763	9a64fbe4	bellard	gen_op_load_fpr_FT2(rB(ctx->opcode)); \
764	9a64fbe4	bellard	gen_op_f##name(); \
765	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode)); \
766	9a64fbe4	bellard	if (Rc(ctx->opcode)) \
767	9a64fbe4	bellard	gen_op_set_Rc1(); \
768	9a64fbe4	bellard	}
769	9a64fbe4	bellard
770	9a64fbe4	bellard	#define GEN_FLOAT_ACB(name, op2) \
771	9a64fbe4	bellard	_GEN_FLOAT_ACB(name, 0x3F, op2); \
772	9a64fbe4	bellard	_GEN_FLOAT_ACB(name##s, 0x3B, op2);
773	9a64fbe4	bellard
774	9a64fbe4	bellard	#define _GEN_FLOAT_AB(name, op1, op2, inval) \
775	9a64fbe4	bellard	GEN_HANDLER(f##name, op1, op2, 0xFF, inval, PPC_FLOAT) \
776	9a64fbe4	bellard	{ \
777	9a64fbe4	bellard	gen_op_reset_scrfx(); \
778	9a64fbe4	bellard	gen_op_load_fpr_FT0(rA(ctx->opcode)); \
779	9a64fbe4	bellard	gen_op_load_fpr_FT1(rB(ctx->opcode)); \
780	9a64fbe4	bellard	gen_op_f##name(); \
781	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode)); \
782	9a64fbe4	bellard	if (Rc(ctx->opcode)) \
783	9a64fbe4	bellard	gen_op_set_Rc1(); \
784	9a64fbe4	bellard	}
785	9a64fbe4	bellard	#define GEN_FLOAT_AB(name, op2, inval) \
786	9a64fbe4	bellard	_GEN_FLOAT_AB(name, 0x3F, op2, inval); \
787	9a64fbe4	bellard	_GEN_FLOAT_AB(name##s, 0x3B, op2, inval);
788	9a64fbe4	bellard
789	9a64fbe4	bellard	#define _GEN_FLOAT_AC(name, op1, op2, inval) \
790	9a64fbe4	bellard	GEN_HANDLER(f##name, op1, op2, 0xFF, inval, PPC_FLOAT) \
791	9a64fbe4	bellard	{ \
792	9a64fbe4	bellard	gen_op_reset_scrfx(); \
793	9a64fbe4	bellard	gen_op_load_fpr_FT0(rA(ctx->opcode)); \
794	9a64fbe4	bellard	gen_op_load_fpr_FT1(rC(ctx->opcode)); \
795	9a64fbe4	bellard	gen_op_f##name(); \
796	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode)); \
797	9a64fbe4	bellard	if (Rc(ctx->opcode)) \
798	9a64fbe4	bellard	gen_op_set_Rc1(); \
799	9a64fbe4	bellard	}
800	9a64fbe4	bellard	#define GEN_FLOAT_AC(name, op2, inval) \
801	9a64fbe4	bellard	_GEN_FLOAT_AC(name, 0x3F, op2, inval); \
802	9a64fbe4	bellard	_GEN_FLOAT_AC(name##s, 0x3B, op2, inval);
803	9a64fbe4	bellard
804	9a64fbe4	bellard	#define GEN_FLOAT_B(name, op2, op3) \
805	9a64fbe4	bellard	GEN_HANDLER(f##name, 0x3F, op2, op3, 0x001F0000, PPC_FLOAT) \
806	9a64fbe4	bellard	{ \
807	9a64fbe4	bellard	gen_op_reset_scrfx(); \
808	9a64fbe4	bellard	gen_op_load_fpr_FT0(rB(ctx->opcode)); \
809	9a64fbe4	bellard	gen_op_f##name(); \
810	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode)); \
811	9a64fbe4	bellard	if (Rc(ctx->opcode)) \
812	9a64fbe4	bellard	gen_op_set_Rc1(); \
813	79aceca5	bellard	}
814	79aceca5	bellard
815	9a64fbe4	bellard	#define GEN_FLOAT_BS(name, op2) \
816	9a64fbe4	bellard	GEN_HANDLER(f##name, 0x3F, op2, 0xFF, 0x001F07C0, PPC_FLOAT) \
817	9a64fbe4	bellard	{ \
818	9a64fbe4	bellard	gen_op_reset_scrfx(); \
819	9a64fbe4	bellard	gen_op_load_fpr_FT0(rB(ctx->opcode)); \
820	9a64fbe4	bellard	gen_op_f##name(); \
821	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode)); \
822	9a64fbe4	bellard	if (Rc(ctx->opcode)) \
823	9a64fbe4	bellard	gen_op_set_Rc1(); \
824	79aceca5	bellard	}
825	79aceca5	bellard
826	9a64fbe4	bellard	/* fadd - fadds */
827	9a64fbe4	bellard	GEN_FLOAT_AB(add, 0x15, 0x000007C0);
828	79aceca5	bellard	/* fdiv */
829	9a64fbe4	bellard	GEN_FLOAT_AB(div, 0x12, 0x000007C0);
830	79aceca5	bellard	/* fmul */
831	9a64fbe4	bellard	GEN_FLOAT_AC(mul, 0x19, 0x0000F800);
832	79aceca5	bellard
833	79aceca5	bellard	/* fres */
834	9a64fbe4	bellard	GEN_FLOAT_BS(res, 0x18);
835	79aceca5	bellard
836	79aceca5	bellard	/* frsqrte */
837	9a64fbe4	bellard	GEN_FLOAT_BS(rsqrte, 0x1A);
838	79aceca5	bellard
839	79aceca5	bellard	/* fsel */
840	9a64fbe4	bellard	_GEN_FLOAT_ACB(sel, 0x3F, 0x17);
841	79aceca5	bellard	/* fsub */
842	9a64fbe4	bellard	GEN_FLOAT_AB(sub, 0x14, 0x000007C0);
843	79aceca5	bellard	/* Optional: */
844	79aceca5	bellard	/* fsqrt */
845	9a64fbe4	bellard	GEN_FLOAT_BS(sqrt, 0x16);
846	79aceca5	bellard
847	9a64fbe4	bellard	GEN_HANDLER(fsqrts, 0x3B, 0x16, 0xFF, 0x001F07C0, PPC_FLOAT_OPT)
848	79aceca5	bellard	{
849	9a64fbe4	bellard	gen_op_reset_scrfx();
850	9a64fbe4	bellard	gen_op_load_fpr_FT0(rB(ctx->opcode));
851	9a64fbe4	bellard	gen_op_fsqrts();
852	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode));
853	9a64fbe4	bellard	if (Rc(ctx->opcode))
854	9a64fbe4	bellard	gen_op_set_Rc1();
855	79aceca5	bellard	}
856	79aceca5	bellard
857	79aceca5	bellard	/* Floating-Point multiply-and-add */
858	79aceca5	bellard	/* fmadd */
859	9a64fbe4	bellard	GEN_FLOAT_ACB(madd, 0x1D);
860	79aceca5	bellard	/* fmsub */
861	9a64fbe4	bellard	GEN_FLOAT_ACB(msub, 0x1C);
862	79aceca5	bellard	/* fnmadd */
863	9a64fbe4	bellard	GEN_FLOAT_ACB(nmadd, 0x1F);
864	79aceca5	bellard	/* fnmsub */
865	9a64fbe4	bellard	GEN_FLOAT_ACB(nmsub, 0x1E);
866	79aceca5	bellard
867	79aceca5	bellard	/* Floating-Point round & convert */
868	79aceca5	bellard	/* fctiw */
869	9a64fbe4	bellard	GEN_FLOAT_B(ctiw, 0x0E, 0x00);
870	79aceca5	bellard	/* fctiwz */
871	9a64fbe4	bellard	GEN_FLOAT_B(ctiwz, 0x0F, 0x00);
872	79aceca5	bellard	/* frsp */
873	9a64fbe4	bellard	GEN_FLOAT_B(rsp, 0x0C, 0x00);
874	79aceca5	bellard
875	79aceca5	bellard	/* Floating-Point compare */
876	79aceca5	bellard	/* fcmpo */
877	79aceca5	bellard	GEN_HANDLER(fcmpo, 0x3F, 0x00, 0x00, 0x00600001, PPC_FLOAT)
878	79aceca5	bellard	{
879	9a64fbe4	bellard	gen_op_reset_scrfx();
880	9a64fbe4	bellard	gen_op_load_fpr_FT0(rA(ctx->opcode));
881	9a64fbe4	bellard	gen_op_load_fpr_FT1(rB(ctx->opcode));
882	9a64fbe4	bellard	gen_op_fcmpo();
883	9a64fbe4	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
884	79aceca5	bellard	}
885	79aceca5	bellard
886	79aceca5	bellard	/* fcmpu */
887	79aceca5	bellard	GEN_HANDLER(fcmpu, 0x3F, 0x00, 0x01, 0x00600001, PPC_FLOAT)
888	79aceca5	bellard	{
889	9a64fbe4	bellard	gen_op_reset_scrfx();
890	9a64fbe4	bellard	gen_op_load_fpr_FT0(rA(ctx->opcode));
891	9a64fbe4	bellard	gen_op_load_fpr_FT1(rB(ctx->opcode));
892	9a64fbe4	bellard	gen_op_fcmpu();
893	9a64fbe4	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
894	79aceca5	bellard	}
895	79aceca5	bellard
896	9a64fbe4	bellard	/* Floating-point move */
897	9a64fbe4	bellard	/* fabs */
898	9a64fbe4	bellard	GEN_FLOAT_B(abs, 0x08, 0x08);
899	9a64fbe4	bellard
900	9a64fbe4	bellard	/* fmr - fmr. */
901	9a64fbe4	bellard	GEN_HANDLER(fmr, 0x3F, 0x08, 0x02, 0x001F0000, PPC_FLOAT)
902	9a64fbe4	bellard	{
903	9a64fbe4	bellard	gen_op_reset_scrfx();
904	9a64fbe4	bellard	gen_op_load_fpr_FT0(rB(ctx->opcode));
905	9a64fbe4	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode));
906	9a64fbe4	bellard	if (Rc(ctx->opcode))
907	9a64fbe4	bellard	gen_op_set_Rc1();
908	9a64fbe4	bellard	}
909	9a64fbe4	bellard
910	9a64fbe4	bellard	/* fnabs */
911	9a64fbe4	bellard	GEN_FLOAT_B(nabs, 0x08, 0x04);
912	9a64fbe4	bellard	/* fneg */
913	9a64fbe4	bellard	GEN_FLOAT_B(neg, 0x08, 0x01);
914	9a64fbe4	bellard
915	79aceca5	bellard	/* Floating-Point status & ctrl register */
916	79aceca5	bellard	/* mcrfs */
917	79aceca5	bellard	GEN_HANDLER(mcrfs, 0x3F, 0x00, 0x02, 0x0063F801, PPC_FLOAT)
918	79aceca5	bellard	{
919	fb0eaffc	bellard	gen_op_load_fpscr_T0(crfS(ctx->opcode));
920	fb0eaffc	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
921	fb0eaffc	bellard	gen_op_clear_fpscr(crfS(ctx->opcode));
922	79aceca5	bellard	}
923	79aceca5	bellard
924	79aceca5	bellard	/* mffs */
925	79aceca5	bellard	GEN_HANDLER(mffs, 0x3F, 0x07, 0x12, 0x001FF800, PPC_FLOAT)
926	79aceca5	bellard	{
927	28b6751f	bellard	gen_op_load_fpscr();
928	fb0eaffc	bellard	gen_op_store_FT0_fpr(rD(ctx->opcode));
929	fb0eaffc	bellard	if (Rc(ctx->opcode))
930	fb0eaffc	bellard	gen_op_set_Rc1();
931	79aceca5	bellard	}
932	79aceca5	bellard
933	79aceca5	bellard	/* mtfsb0 */
934	79aceca5	bellard	GEN_HANDLER(mtfsb0, 0x3F, 0x06, 0x02, 0x001FF800, PPC_FLOAT)
935	79aceca5	bellard	{
936	fb0eaffc	bellard	uint8_t crb;
937	fb0eaffc	bellard
938	fb0eaffc	bellard	crb = crbD(ctx->opcode) >> 2;
939	fb0eaffc	bellard	gen_op_load_fpscr_T0(crb);
940	fb0eaffc	bellard	gen_op_andi_(~(1 << (crbD(ctx->opcode) & 0x03)));
941	fb0eaffc	bellard	gen_op_store_T0_fpscr(crb);
942	fb0eaffc	bellard	if (Rc(ctx->opcode))
943	fb0eaffc	bellard	gen_op_set_Rc1();
944	79aceca5	bellard	}
945	79aceca5	bellard
946	79aceca5	bellard	/* mtfsb1 */
947	79aceca5	bellard	GEN_HANDLER(mtfsb1, 0x3F, 0x06, 0x01, 0x001FF800, PPC_FLOAT)
948	79aceca5	bellard	{
949	fb0eaffc	bellard	uint8_t crb;
950	fb0eaffc	bellard
951	fb0eaffc	bellard	crb = crbD(ctx->opcode) >> 2;
952	fb0eaffc	bellard	gen_op_load_fpscr_T0(crb);
953	fb0eaffc	bellard	gen_op_ori(1 << (crbD(ctx->opcode) & 0x03));
954	fb0eaffc	bellard	gen_op_store_T0_fpscr(crb);
955	fb0eaffc	bellard	if (Rc(ctx->opcode))
956	fb0eaffc	bellard	gen_op_set_Rc1();
957	79aceca5	bellard	}
958	79aceca5	bellard
959	79aceca5	bellard	/* mtfsf */
960	79aceca5	bellard	GEN_HANDLER(mtfsf, 0x3F, 0x07, 0x16, 0x02010000, PPC_FLOAT)
961	79aceca5	bellard	{
962	fb0eaffc	bellard	gen_op_load_fpr_FT0(rB(ctx->opcode));
963	28b6751f	bellard	gen_op_store_fpscr(FM(ctx->opcode));
964	fb0eaffc	bellard	if (Rc(ctx->opcode))
965	fb0eaffc	bellard	gen_op_set_Rc1();
966	79aceca5	bellard	}
967	79aceca5	bellard
968	79aceca5	bellard	/* mtfsfi */
969	79aceca5	bellard	GEN_HANDLER(mtfsfi, 0x3F, 0x06, 0x04, 0x006f0800, PPC_FLOAT)
970	79aceca5	bellard	{
971	fb0eaffc	bellard	gen_op_store_T0_fpscri(crbD(ctx->opcode) >> 2, FPIMM(ctx->opcode));
972	fb0eaffc	bellard	if (Rc(ctx->opcode))
973	fb0eaffc	bellard	gen_op_set_Rc1();
974	79aceca5	bellard	}
975	79aceca5	bellard
976	79aceca5	bellard	/* Integer load */
977	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
978	9a64fbe4	bellard	#define op_ldst(name) gen_op_##name##_raw()
979	9a64fbe4	bellard	#define OP_LD_TABLE(width)
980	9a64fbe4	bellard	#define OP_ST_TABLE(width)
981	9a64fbe4	bellard	#else
982	9a64fbe4	bellard	#define op_ldst(name) (*gen_op_##name[ctx->mem_idx])()
983	9a64fbe4	bellard	#define OP_LD_TABLE(width) \
984	9a64fbe4	bellard	static GenOpFunc *gen_op_l##width[] = { \
985	9a64fbe4	bellard	&gen_op_l##width##_user, \
986	9a64fbe4	bellard	&gen_op_l##width##_kernel, \
987	9a64fbe4	bellard	}
988	9a64fbe4	bellard	#define OP_ST_TABLE(width) \
989	9a64fbe4	bellard	static GenOpFunc *gen_op_st##width[] = { \
990	9a64fbe4	bellard	&gen_op_st##width##_user, \
991	9a64fbe4	bellard	&gen_op_st##width##_kernel, \
992	9a64fbe4	bellard	}
993	9a64fbe4	bellard	#endif
994	9a64fbe4	bellard
995	9a64fbe4	bellard	#define GEN_LD(width, opc) \
996	79aceca5	bellard	GEN_HANDLER(l##width, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
997	79aceca5	bellard	{ \
998	79aceca5	bellard	uint32_t simm = SIMM(ctx->opcode); \
999	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1000	9a64fbe4	bellard	gen_op_set_T0(simm); \
1001	79aceca5	bellard	} else { \
1002	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1003	9a64fbe4	bellard	if (simm != 0) \
1004	9a64fbe4	bellard	gen_op_addi(simm); \
1005	79aceca5	bellard	} \
1006	9a64fbe4	bellard	op_ldst(l##width); \
1007	79aceca5	bellard	gen_op_store_T1_gpr(rD(ctx->opcode)); \
1008	79aceca5	bellard	}
1009	79aceca5	bellard
1010	9a64fbe4	bellard	#define GEN_LDU(width, opc) \
1011	79aceca5	bellard	GEN_HANDLER(l##width##u, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1012	79aceca5	bellard	{ \
1013	9a64fbe4	bellard	uint32_t simm = SIMM(ctx->opcode); \
1014	79aceca5	bellard	if (rA(ctx->opcode) == 0 \|\| \
1015	9a64fbe4	bellard	rA(ctx->opcode) == rD(ctx->opcode)) { \
1016	9fddaa0c	bellard	RET_INVAL(ctx); \
1017	9fddaa0c	bellard	return; \
1018	9a64fbe4	bellard	} \
1019	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1020	9a64fbe4	bellard	if (simm != 0) \
1021	9a64fbe4	bellard	gen_op_addi(simm); \
1022	9a64fbe4	bellard	op_ldst(l##width); \
1023	79aceca5	bellard	gen_op_store_T1_gpr(rD(ctx->opcode)); \
1024	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1025	79aceca5	bellard	}
1026	79aceca5	bellard
1027	9a64fbe4	bellard	#define GEN_LDUX(width, opc) \
1028	79aceca5	bellard	GEN_HANDLER(l##width##ux, 0x1F, 0x17, opc, 0x00000001, PPC_INTEGER) \
1029	79aceca5	bellard	{ \
1030	79aceca5	bellard	if (rA(ctx->opcode) == 0 \|\| \
1031	9a64fbe4	bellard	rA(ctx->opcode) == rD(ctx->opcode)) { \
1032	9fddaa0c	bellard	RET_INVAL(ctx); \
1033	9fddaa0c	bellard	return; \
1034	9a64fbe4	bellard	} \
1035	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1036	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1037	9a64fbe4	bellard	gen_op_add(); \
1038	9a64fbe4	bellard	op_ldst(l##width); \
1039	79aceca5	bellard	gen_op_store_T1_gpr(rD(ctx->opcode)); \
1040	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1041	79aceca5	bellard	}
1042	79aceca5	bellard
1043	9a64fbe4	bellard	#define GEN_LDX(width, opc2, opc3) \
1044	79aceca5	bellard	GEN_HANDLER(l##width##x, 0x1F, opc2, opc3, 0x00000001, PPC_INTEGER) \
1045	79aceca5	bellard	{ \
1046	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1047	79aceca5	bellard	gen_op_load_gpr_T0(rB(ctx->opcode)); \
1048	79aceca5	bellard	} else { \
1049	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1050	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1051	9a64fbe4	bellard	gen_op_add(); \
1052	79aceca5	bellard	} \
1053	9a64fbe4	bellard	op_ldst(l##width); \
1054	79aceca5	bellard	gen_op_store_T1_gpr(rD(ctx->opcode)); \
1055	79aceca5	bellard	}
1056	79aceca5	bellard
1057	9a64fbe4	bellard	#define GEN_LDS(width, op) \
1058	9a64fbe4	bellard	OP_LD_TABLE(width); \
1059	9a64fbe4	bellard	GEN_LD(width, op \| 0x20); \
1060	9a64fbe4	bellard	GEN_LDU(width, op \| 0x21); \
1061	9a64fbe4	bellard	GEN_LDUX(width, op \| 0x01); \
1062	9a64fbe4	bellard	GEN_LDX(width, 0x17, op \| 0x00)
1063	79aceca5	bellard
1064	79aceca5	bellard	/* lbz lbzu lbzux lbzx */
1065	9a64fbe4	bellard	GEN_LDS(bz, 0x02);
1066	79aceca5	bellard	/* lha lhau lhaux lhax */
1067	9a64fbe4	bellard	GEN_LDS(ha, 0x0A);
1068	79aceca5	bellard	/* lhz lhzu lhzux lhzx */
1069	9a64fbe4	bellard	GEN_LDS(hz, 0x08);
1070	79aceca5	bellard	/* lwz lwzu lwzux lwzx */
1071	9a64fbe4	bellard	GEN_LDS(wz, 0x00);
1072	79aceca5	bellard
1073	79aceca5	bellard	/* Integer store */
1074	9a64fbe4	bellard	#define GEN_ST(width, opc) \
1075	79aceca5	bellard	GEN_HANDLER(st##width, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1076	79aceca5	bellard	{ \
1077	79aceca5	bellard	uint32_t simm = SIMM(ctx->opcode); \
1078	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1079	9a64fbe4	bellard	gen_op_set_T0(simm); \
1080	79aceca5	bellard	} else { \
1081	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1082	9a64fbe4	bellard	if (simm != 0) \
1083	9a64fbe4	bellard	gen_op_addi(simm); \
1084	79aceca5	bellard	} \
1085	9a64fbe4	bellard	gen_op_load_gpr_T1(rS(ctx->opcode)); \
1086	9a64fbe4	bellard	op_ldst(st##width); \
1087	79aceca5	bellard	}
1088	79aceca5	bellard
1089	9a64fbe4	bellard	#define GEN_STU(width, opc) \
1090	79aceca5	bellard	GEN_HANDLER(st##width##u, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1091	79aceca5	bellard	{ \
1092	9a64fbe4	bellard	uint32_t simm = SIMM(ctx->opcode); \
1093	9a64fbe4	bellard	if (rA(ctx->opcode) == 0) { \
1094	9fddaa0c	bellard	RET_INVAL(ctx); \
1095	9fddaa0c	bellard	return; \
1096	9a64fbe4	bellard	} \
1097	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1098	9a64fbe4	bellard	if (simm != 0) \
1099	9a64fbe4	bellard	gen_op_addi(simm); \
1100	79aceca5	bellard	gen_op_load_gpr_T1(rS(ctx->opcode)); \
1101	9a64fbe4	bellard	op_ldst(st##width); \
1102	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1103	79aceca5	bellard	}
1104	79aceca5	bellard
1105	9a64fbe4	bellard	#define GEN_STUX(width, opc) \
1106	79aceca5	bellard	GEN_HANDLER(st##width##ux, 0x1F, 0x17, opc, 0x00000001, PPC_INTEGER) \
1107	79aceca5	bellard	{ \
1108	9a64fbe4	bellard	if (rA(ctx->opcode) == 0) { \
1109	9fddaa0c	bellard	RET_INVAL(ctx); \
1110	9fddaa0c	bellard	return; \
1111	9a64fbe4	bellard	} \
1112	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1113	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1114	9a64fbe4	bellard	gen_op_add(); \
1115	9a64fbe4	bellard	gen_op_load_gpr_T1(rS(ctx->opcode)); \
1116	9a64fbe4	bellard	op_ldst(st##width); \
1117	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1118	79aceca5	bellard	}
1119	79aceca5	bellard
1120	9a64fbe4	bellard	#define GEN_STX(width, opc2, opc3) \
1121	79aceca5	bellard	GEN_HANDLER(st##width##x, 0x1F, opc2, opc3, 0x00000001, PPC_INTEGER) \
1122	79aceca5	bellard	{ \
1123	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1124	79aceca5	bellard	gen_op_load_gpr_T0(rB(ctx->opcode)); \
1125	79aceca5	bellard	} else { \
1126	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1127	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1128	9a64fbe4	bellard	gen_op_add(); \
1129	79aceca5	bellard	} \
1130	9a64fbe4	bellard	gen_op_load_gpr_T1(rS(ctx->opcode)); \
1131	9a64fbe4	bellard	op_ldst(st##width); \
1132	79aceca5	bellard	}
1133	79aceca5	bellard
1134	9a64fbe4	bellard	#define GEN_STS(width, op) \
1135	9a64fbe4	bellard	OP_ST_TABLE(width); \
1136	9a64fbe4	bellard	GEN_ST(width, op \| 0x20); \
1137	9a64fbe4	bellard	GEN_STU(width, op \| 0x21); \
1138	9a64fbe4	bellard	GEN_STUX(width, op \| 0x01); \
1139	9a64fbe4	bellard	GEN_STX(width, 0x17, op \| 0x00)
1140	79aceca5	bellard
1141	79aceca5	bellard	/* stb stbu stbux stbx */
1142	9a64fbe4	bellard	GEN_STS(b, 0x06);
1143	79aceca5	bellard	/* sth sthu sthux sthx */
1144	9a64fbe4	bellard	GEN_STS(h, 0x0C);
1145	79aceca5	bellard	/* stw stwu stwux stwx */
1146	9a64fbe4	bellard	GEN_STS(w, 0x04);
1147	79aceca5	bellard
1148	79aceca5	bellard	/* Integer load and store with byte reverse */
1149	79aceca5	bellard	/* lhbrx */
1150	9a64fbe4	bellard	OP_LD_TABLE(hbr);
1151	9a64fbe4	bellard	GEN_LDX(hbr, 0x16, 0x18);
1152	79aceca5	bellard	/* lwbrx */
1153	9a64fbe4	bellard	OP_LD_TABLE(wbr);
1154	9a64fbe4	bellard	GEN_LDX(wbr, 0x16, 0x10);
1155	79aceca5	bellard	/* sthbrx */
1156	9a64fbe4	bellard	OP_ST_TABLE(hbr);
1157	9a64fbe4	bellard	GEN_STX(hbr, 0x16, 0x1C);
1158	79aceca5	bellard	/* stwbrx */
1159	9a64fbe4	bellard	OP_ST_TABLE(wbr);
1160	9a64fbe4	bellard	GEN_STX(wbr, 0x16, 0x14);
1161	79aceca5	bellard
1162	79aceca5	bellard	/* Integer load and store multiple */
1163	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1164	9a64fbe4	bellard	#define op_ldstm(name, reg) gen_op_##name##_raw(reg)
1165	9a64fbe4	bellard	#else
1166	9a64fbe4	bellard	#define op_ldstm(name, reg) (*gen_op_##name[ctx->mem_idx])(reg)
1167	9a64fbe4	bellard	static GenOpFunc1 *gen_op_lmw[] = {
1168	9a64fbe4	bellard	&gen_op_lmw_user,
1169	9a64fbe4	bellard	&gen_op_lmw_kernel,
1170	9a64fbe4	bellard	};
1171	9a64fbe4	bellard	static GenOpFunc1 *gen_op_stmw[] = {
1172	9a64fbe4	bellard	&gen_op_stmw_user,
1173	9a64fbe4	bellard	&gen_op_stmw_kernel,
1174	9a64fbe4	bellard	};
1175	9a64fbe4	bellard	#endif
1176	9a64fbe4	bellard
1177	79aceca5	bellard	/* lmw */
1178	79aceca5	bellard	GEN_HANDLER(lmw, 0x2E, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
1179	79aceca5	bellard	{
1180	9a64fbe4	bellard	int simm = SIMM(ctx->opcode);
1181	9a64fbe4	bellard
1182	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
1183	9a64fbe4	bellard	gen_op_set_T0(simm);
1184	79aceca5	bellard	} else {
1185	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1186	9a64fbe4	bellard	if (simm != 0)
1187	9a64fbe4	bellard	gen_op_addi(simm);
1188	79aceca5	bellard	}
1189	9a64fbe4	bellard	op_ldstm(lmw, rD(ctx->opcode));
1190	79aceca5	bellard	}
1191	79aceca5	bellard
1192	79aceca5	bellard	/* stmw */
1193	79aceca5	bellard	GEN_HANDLER(stmw, 0x2F, 0xFF, 0xFF, 0x00000000, PPC_INTEGER)
1194	79aceca5	bellard	{
1195	9a64fbe4	bellard	int simm = SIMM(ctx->opcode);
1196	9a64fbe4	bellard
1197	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
1198	9a64fbe4	bellard	gen_op_set_T0(simm);
1199	79aceca5	bellard	} else {
1200	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1201	9a64fbe4	bellard	if (simm != 0)
1202	9a64fbe4	bellard	gen_op_addi(simm);
1203	79aceca5	bellard	}
1204	9a64fbe4	bellard	op_ldstm(stmw, rS(ctx->opcode));
1205	79aceca5	bellard	}
1206	79aceca5	bellard
1207	79aceca5	bellard	/* Integer load and store strings */
1208	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1209	9a64fbe4	bellard	#define op_ldsts(name, start) gen_op_##name##_raw(start)
1210	9a64fbe4	bellard	#define op_ldstsx(name, rd, ra, rb) gen_op_##name##_raw(rd, ra, rb)
1211	9a64fbe4	bellard	#else
1212	9a64fbe4	bellard	#define op_ldsts(name, start) (*gen_op_##name[ctx->mem_idx])(start)
1213	9a64fbe4	bellard	#define op_ldstsx(name, rd, ra, rb) (*gen_op_##name[ctx->mem_idx])(rd, ra, rb)
1214	9a64fbe4	bellard	static GenOpFunc1 *gen_op_lswi[] = {
1215	9a64fbe4	bellard	&gen_op_lswi_user,
1216	9a64fbe4	bellard	&gen_op_lswi_kernel,
1217	9a64fbe4	bellard	};
1218	9a64fbe4	bellard	static GenOpFunc3 *gen_op_lswx[] = {
1219	9a64fbe4	bellard	&gen_op_lswx_user,
1220	9a64fbe4	bellard	&gen_op_lswx_kernel,
1221	9a64fbe4	bellard	};
1222	9a64fbe4	bellard	static GenOpFunc1 *gen_op_stsw[] = {
1223	9a64fbe4	bellard	&gen_op_stsw_user,
1224	9a64fbe4	bellard	&gen_op_stsw_kernel,
1225	9a64fbe4	bellard	};
1226	9a64fbe4	bellard	#endif
1227	9a64fbe4	bellard
1228	79aceca5	bellard	/* lswi */
1229	9a64fbe4	bellard	/* PPC32 specification says we must generate an exception if
1230	9a64fbe4	bellard	* rA is in the range of registers to be loaded.
1231	9a64fbe4	bellard	* In an other hand, IBM says this is valid, but rA won't be loaded.
1232	9a64fbe4	bellard	* For now, I'll follow the spec...
1233	9a64fbe4	bellard	*/
1234	79aceca5	bellard	GEN_HANDLER(lswi, 0x1F, 0x15, 0x12, 0x00000001, PPC_INTEGER)
1235	79aceca5	bellard	{
1236	79aceca5	bellard	int nb = NB(ctx->opcode);
1237	79aceca5	bellard	int start = rD(ctx->opcode);
1238	9a64fbe4	bellard	int ra = rA(ctx->opcode);
1239	79aceca5	bellard	int nr;
1240	79aceca5	bellard
1241	79aceca5	bellard	if (nb == 0)
1242	79aceca5	bellard	nb = 32;
1243	79aceca5	bellard	nr = nb / 4;
1244	297d8e62	bellard	if (((start + nr) > 32 && start <= ra && (start + nr - 32) > ra) \|\|
1245	297d8e62	bellard	((start + nr) <= 32 && start <= ra && (start + nr) > ra)) {
1246	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_PROGRAM, EXCP_INVAL \| EXCP_INVAL_LSWX);
1247	9fddaa0c	bellard	return;
1248	297d8e62	bellard	}
1249	9a64fbe4	bellard	if (ra == 0) {
1250	79aceca5	bellard	gen_op_set_T0(0);
1251	79aceca5	bellard	} else {
1252	9a64fbe4	bellard	gen_op_load_gpr_T0(ra);
1253	79aceca5	bellard	}
1254	9a64fbe4	bellard	gen_op_set_T1(nb);
1255	9a64fbe4	bellard	op_ldsts(lswi, start);
1256	79aceca5	bellard	}
1257	79aceca5	bellard
1258	79aceca5	bellard	/* lswx */
1259	79aceca5	bellard	GEN_HANDLER(lswx, 0x1F, 0x15, 0x10, 0x00000001, PPC_INTEGER)
1260	79aceca5	bellard	{
1261	9a64fbe4	bellard	int ra = rA(ctx->opcode);
1262	9a64fbe4	bellard	int rb = rB(ctx->opcode);
1263	9a64fbe4	bellard
1264	9a64fbe4	bellard	if (ra == 0) {
1265	9a64fbe4	bellard	gen_op_load_gpr_T0(rb);
1266	9a64fbe4	bellard	ra = rb;
1267	79aceca5	bellard	} else {
1268	9a64fbe4	bellard	gen_op_load_gpr_T0(ra);
1269	9a64fbe4	bellard	gen_op_load_gpr_T1(rb);
1270	9a64fbe4	bellard	gen_op_add();
1271	79aceca5	bellard	}
1272	9a64fbe4	bellard	gen_op_load_xer_bc();
1273	9a64fbe4	bellard	op_ldstsx(lswx, rD(ctx->opcode), ra, rb);
1274	79aceca5	bellard	}
1275	79aceca5	bellard
1276	79aceca5	bellard	/* stswi */
1277	79aceca5	bellard	GEN_HANDLER(stswi, 0x1F, 0x15, 0x16, 0x00000001, PPC_INTEGER)
1278	79aceca5	bellard	{
1279	4b3686fa	bellard	int nb = NB(ctx->opcode);
1280	4b3686fa	bellard
1281	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
1282	79aceca5	bellard	gen_op_set_T0(0);
1283	79aceca5	bellard	} else {
1284	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1285	79aceca5	bellard	}
1286	4b3686fa	bellard	if (nb == 0)
1287	4b3686fa	bellard	nb = 32;
1288	4b3686fa	bellard	gen_op_set_T1(nb);
1289	9a64fbe4	bellard	op_ldsts(stsw, rS(ctx->opcode));
1290	79aceca5	bellard	}
1291	79aceca5	bellard
1292	79aceca5	bellard	/* stswx */
1293	79aceca5	bellard	GEN_HANDLER(stswx, 0x1F, 0x15, 0x14, 0x00000001, PPC_INTEGER)
1294	79aceca5	bellard	{
1295	9a64fbe4	bellard	int ra = rA(ctx->opcode);
1296	9a64fbe4	bellard
1297	9a64fbe4	bellard	if (ra == 0) {
1298	9a64fbe4	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
1299	9a64fbe4	bellard	ra = rB(ctx->opcode);
1300	79aceca5	bellard	} else {
1301	9a64fbe4	bellard	gen_op_load_gpr_T0(ra);
1302	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
1303	9a64fbe4	bellard	gen_op_add();
1304	79aceca5	bellard	}
1305	9a64fbe4	bellard	gen_op_load_xer_bc();
1306	9a64fbe4	bellard	op_ldsts(stsw, rS(ctx->opcode));
1307	79aceca5	bellard	}
1308	79aceca5	bellard
1309	79aceca5	bellard	/* Memory synchronisation */
1310	79aceca5	bellard	/* eieio */
1311	79aceca5	bellard	GEN_HANDLER(eieio, 0x1F, 0x16, 0x1A, 0x03FF0801, PPC_MEM)
1312	79aceca5	bellard	{
1313	79aceca5	bellard	}
1314	79aceca5	bellard
1315	79aceca5	bellard	/* isync */
1316	79aceca5	bellard	GEN_HANDLER(isync, 0x13, 0x16, 0xFF, 0x03FF0801, PPC_MEM)
1317	79aceca5	bellard	{
1318	79aceca5	bellard	}
1319	79aceca5	bellard
1320	79aceca5	bellard	/* lwarx */
1321	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1322	985a19d6	bellard	#define op_lwarx() gen_op_lwarx_raw()
1323	9a64fbe4	bellard	#define op_stwcx() gen_op_stwcx_raw()
1324	9a64fbe4	bellard	#else
1325	985a19d6	bellard	#define op_lwarx() (*gen_op_lwarx[ctx->mem_idx])()
1326	985a19d6	bellard	static GenOpFunc *gen_op_lwarx[] = {
1327	985a19d6	bellard	&gen_op_lwarx_user,
1328	985a19d6	bellard	&gen_op_lwarx_kernel,
1329	985a19d6	bellard	};
1330	9a64fbe4	bellard	#define op_stwcx() (*gen_op_stwcx[ctx->mem_idx])()
1331	9a64fbe4	bellard	static GenOpFunc *gen_op_stwcx[] = {
1332	9a64fbe4	bellard	&gen_op_stwcx_user,
1333	9a64fbe4	bellard	&gen_op_stwcx_kernel,
1334	9a64fbe4	bellard	};
1335	9a64fbe4	bellard	#endif
1336	9a64fbe4	bellard
1337	9a64fbe4	bellard	GEN_HANDLER(lwarx, 0x1F, 0x14, 0xFF, 0x00000001, PPC_RES)
1338	79aceca5	bellard	{
1339	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
1340	79aceca5	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
1341	79aceca5	bellard	} else {
1342	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1343	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
1344	9a64fbe4	bellard	gen_op_add();
1345	79aceca5	bellard	}
1346	985a19d6	bellard	op_lwarx();
1347	79aceca5	bellard	gen_op_store_T1_gpr(rD(ctx->opcode));
1348	79aceca5	bellard	}
1349	79aceca5	bellard
1350	79aceca5	bellard	/* stwcx. */
1351	9a64fbe4	bellard	GEN_HANDLER(stwcx_, 0x1F, 0x16, 0x04, 0x00000000, PPC_RES)
1352	79aceca5	bellard	{
1353	79aceca5	bellard	if (rA(ctx->opcode) == 0) {
1354	79aceca5	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
1355	79aceca5	bellard	} else {
1356	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1357	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
1358	9a64fbe4	bellard	gen_op_add();
1359	79aceca5	bellard	}
1360	9a64fbe4	bellard	gen_op_load_gpr_T1(rS(ctx->opcode));
1361	9a64fbe4	bellard	op_stwcx();
1362	79aceca5	bellard	}
1363	79aceca5	bellard
1364	79aceca5	bellard	/* sync */
1365	79aceca5	bellard	GEN_HANDLER(sync, 0x1F, 0x16, 0x12, 0x03FF0801, PPC_MEM)
1366	79aceca5	bellard	{
1367	79aceca5	bellard	}
1368	79aceca5	bellard
1369	79aceca5	bellard	/* Floating-point load */
1370	9a64fbe4	bellard	#define GEN_LDF(width, opc) \
1371	9a64fbe4	bellard	GEN_HANDLER(l##width, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1372	79aceca5	bellard	{ \
1373	79aceca5	bellard	uint32_t simm = SIMM(ctx->opcode); \
1374	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1375	9a64fbe4	bellard	gen_op_set_T0(simm); \
1376	79aceca5	bellard	} else { \
1377	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1378	9a64fbe4	bellard	if (simm != 0) \
1379	9a64fbe4	bellard	gen_op_addi(simm); \
1380	79aceca5	bellard	} \
1381	9a64fbe4	bellard	op_ldst(l##width); \
1382	9a64fbe4	bellard	gen_op_store_FT1_fpr(rD(ctx->opcode)); \
1383	79aceca5	bellard	}
1384	79aceca5	bellard
1385	9a64fbe4	bellard	#define GEN_LDUF(width, opc) \
1386	9a64fbe4	bellard	GEN_HANDLER(l##width##u, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1387	79aceca5	bellard	{ \
1388	9a64fbe4	bellard	uint32_t simm = SIMM(ctx->opcode); \
1389	79aceca5	bellard	if (rA(ctx->opcode) == 0 \|\| \
1390	9a64fbe4	bellard	rA(ctx->opcode) == rD(ctx->opcode)) { \
1391	9fddaa0c	bellard	RET_INVAL(ctx); \
1392	9fddaa0c	bellard	return; \
1393	9a64fbe4	bellard	} \
1394	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1395	9a64fbe4	bellard	if (simm != 0) \
1396	9a64fbe4	bellard	gen_op_addi(simm); \
1397	9a64fbe4	bellard	op_ldst(l##width); \
1398	9a64fbe4	bellard	gen_op_store_FT1_fpr(rD(ctx->opcode)); \
1399	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1400	79aceca5	bellard	}
1401	79aceca5	bellard
1402	9a64fbe4	bellard	#define GEN_LDUXF(width, opc) \
1403	9a64fbe4	bellard	GEN_HANDLER(l##width##ux, 0x1F, 0x17, opc, 0x00000001, PPC_INTEGER) \
1404	79aceca5	bellard	{ \
1405	79aceca5	bellard	if (rA(ctx->opcode) == 0 \|\| \
1406	9a64fbe4	bellard	rA(ctx->opcode) == rD(ctx->opcode)) { \
1407	9fddaa0c	bellard	RET_INVAL(ctx); \
1408	9fddaa0c	bellard	return; \
1409	9a64fbe4	bellard	} \
1410	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1411	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1412	9a64fbe4	bellard	gen_op_add(); \
1413	9a64fbe4	bellard	op_ldst(l##width); \
1414	9a64fbe4	bellard	gen_op_store_FT1_fpr(rD(ctx->opcode)); \
1415	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1416	79aceca5	bellard	}
1417	79aceca5	bellard
1418	9a64fbe4	bellard	#define GEN_LDXF(width, opc2, opc3) \
1419	9a64fbe4	bellard	GEN_HANDLER(l##width##x, 0x1F, opc2, opc3, 0x00000001, PPC_INTEGER) \
1420	79aceca5	bellard	{ \
1421	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1422	79aceca5	bellard	gen_op_load_gpr_T0(rB(ctx->opcode)); \
1423	79aceca5	bellard	} else { \
1424	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1425	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1426	9a64fbe4	bellard	gen_op_add(); \
1427	79aceca5	bellard	} \
1428	9a64fbe4	bellard	op_ldst(l##width); \
1429	9a64fbe4	bellard	gen_op_store_FT1_fpr(rD(ctx->opcode)); \
1430	79aceca5	bellard	}
1431	79aceca5	bellard
1432	9a64fbe4	bellard	#define GEN_LDFS(width, op) \
1433	9a64fbe4	bellard	OP_LD_TABLE(width); \
1434	9a64fbe4	bellard	GEN_LDF(width, op \| 0x20); \
1435	9a64fbe4	bellard	GEN_LDUF(width, op \| 0x21); \
1436	9a64fbe4	bellard	GEN_LDUXF(width, op \| 0x01); \
1437	9a64fbe4	bellard	GEN_LDXF(width, 0x17, op \| 0x00)
1438	79aceca5	bellard
1439	79aceca5	bellard	/* lfd lfdu lfdux lfdx */
1440	9a64fbe4	bellard	GEN_LDFS(fd, 0x12);
1441	79aceca5	bellard	/* lfs lfsu lfsux lfsx */
1442	9a64fbe4	bellard	GEN_LDFS(fs, 0x10);
1443	79aceca5	bellard
1444	79aceca5	bellard	/* Floating-point store */
1445	79aceca5	bellard	#define GEN_STF(width, opc) \
1446	9a64fbe4	bellard	GEN_HANDLER(st##width, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1447	79aceca5	bellard	{ \
1448	79aceca5	bellard	uint32_t simm = SIMM(ctx->opcode); \
1449	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1450	9a64fbe4	bellard	gen_op_set_T0(simm); \
1451	79aceca5	bellard	} else { \
1452	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1453	9a64fbe4	bellard	if (simm != 0) \
1454	9a64fbe4	bellard	gen_op_addi(simm); \
1455	79aceca5	bellard	} \
1456	9a64fbe4	bellard	gen_op_load_fpr_FT1(rS(ctx->opcode)); \
1457	9a64fbe4	bellard	op_ldst(st##width); \
1458	79aceca5	bellard	}
1459	79aceca5	bellard
1460	9a64fbe4	bellard	#define GEN_STUF(width, opc) \
1461	9a64fbe4	bellard	GEN_HANDLER(st##width##u, opc, 0xFF, 0xFF, 0x00000000, PPC_INTEGER) \
1462	79aceca5	bellard	{ \
1463	9a64fbe4	bellard	uint32_t simm = SIMM(ctx->opcode); \
1464	9a64fbe4	bellard	if (rA(ctx->opcode) == 0) { \
1465	9fddaa0c	bellard	RET_INVAL(ctx); \
1466	9fddaa0c	bellard	return; \
1467	9a64fbe4	bellard	} \
1468	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1469	9a64fbe4	bellard	if (simm != 0) \
1470	9a64fbe4	bellard	gen_op_addi(simm); \
1471	9a64fbe4	bellard	gen_op_load_fpr_FT1(rS(ctx->opcode)); \
1472	9a64fbe4	bellard	op_ldst(st##width); \
1473	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1474	79aceca5	bellard	}
1475	79aceca5	bellard
1476	9a64fbe4	bellard	#define GEN_STUXF(width, opc) \
1477	9a64fbe4	bellard	GEN_HANDLER(st##width##ux, 0x1F, 0x17, opc, 0x00000001, PPC_INTEGER) \
1478	79aceca5	bellard	{ \
1479	9a64fbe4	bellard	if (rA(ctx->opcode) == 0) { \
1480	9fddaa0c	bellard	RET_INVAL(ctx); \
1481	9fddaa0c	bellard	return; \
1482	9a64fbe4	bellard	} \
1483	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1484	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1485	9a64fbe4	bellard	gen_op_add(); \
1486	9a64fbe4	bellard	gen_op_load_fpr_FT1(rS(ctx->opcode)); \
1487	9a64fbe4	bellard	op_ldst(st##width); \
1488	79aceca5	bellard	gen_op_store_T0_gpr(rA(ctx->opcode)); \
1489	79aceca5	bellard	}
1490	79aceca5	bellard
1491	9a64fbe4	bellard	#define GEN_STXF(width, opc2, opc3) \
1492	9a64fbe4	bellard	GEN_HANDLER(st##width##x, 0x1F, opc2, opc3, 0x00000001, PPC_INTEGER) \
1493	79aceca5	bellard	{ \
1494	79aceca5	bellard	if (rA(ctx->opcode) == 0) { \
1495	79aceca5	bellard	gen_op_load_gpr_T0(rB(ctx->opcode)); \
1496	79aceca5	bellard	} else { \
1497	79aceca5	bellard	gen_op_load_gpr_T0(rA(ctx->opcode)); \
1498	79aceca5	bellard	gen_op_load_gpr_T1(rB(ctx->opcode)); \
1499	9a64fbe4	bellard	gen_op_add(); \
1500	79aceca5	bellard	} \
1501	9a64fbe4	bellard	gen_op_load_fpr_FT1(rS(ctx->opcode)); \
1502	9a64fbe4	bellard	op_ldst(st##width); \
1503	79aceca5	bellard	}
1504	79aceca5	bellard
1505	9a64fbe4	bellard	#define GEN_STFS(width, op) \
1506	9a64fbe4	bellard	OP_ST_TABLE(width); \
1507	9a64fbe4	bellard	GEN_STF(width, op \| 0x20); \
1508	9a64fbe4	bellard	GEN_STUF(width, op \| 0x21); \
1509	9a64fbe4	bellard	GEN_STUXF(width, op \| 0x01); \
1510	9a64fbe4	bellard	GEN_STXF(width, 0x17, op \| 0x00)
1511	79aceca5	bellard
1512	79aceca5	bellard	/* stfd stfdu stfdux stfdx */
1513	9a64fbe4	bellard	GEN_STFS(fd, 0x16);
1514	79aceca5	bellard	/* stfs stfsu stfsux stfsx */
1515	9a64fbe4	bellard	GEN_STFS(fs, 0x14);
1516	79aceca5	bellard
1517	79aceca5	bellard	/* Optional: */
1518	79aceca5	bellard	/* stfiwx */
1519	79aceca5	bellard	GEN_HANDLER(stfiwx, 0x1F, 0x17, 0x1E, 0x00000001, PPC_FLOAT)
1520	79aceca5	bellard	{
1521	9fddaa0c	bellard	RET_INVAL(ctx);
1522	79aceca5	bellard	}
1523	79aceca5	bellard
1524	79aceca5	bellard	/* Branch */
1525	79aceca5	bellard
1526	79aceca5	bellard	/* b ba bl bla */
1527	79aceca5	bellard	GEN_HANDLER(b, 0x12, 0xFF, 0xFF, 0x00000000, PPC_FLOW)
1528	79aceca5	bellard	{
1529	38a64f9d	bellard	uint32_t li, target;
1530	38a64f9d	bellard
1531	38a64f9d	bellard	/* sign extend LI */
1532	38a64f9d	bellard	li = ((int32_t)LI(ctx->opcode) << 6) >> 6;
1533	79aceca5	bellard
1534	79aceca5	bellard	if (AA(ctx->opcode) == 0)
1535	046d6672	bellard	target = ctx->nip + li - 4;
1536	79aceca5	bellard	else
1537	9a64fbe4	bellard	target = li;
1538	9a64fbe4	bellard	if (LK(ctx->opcode)) {
1539	046d6672	bellard	gen_op_setlr(ctx->nip);
1540	9a64fbe4	bellard	}
1541	e98a6e40	bellard	gen_op_b((long)ctx->tb, target);
1542	9a64fbe4	bellard	ctx->exception = EXCP_BRANCH;
1543	79aceca5	bellard	}
1544	79aceca5	bellard
1545	e98a6e40	bellard	#define BCOND_IM 0
1546	e98a6e40	bellard	#define BCOND_LR 1
1547	e98a6e40	bellard	#define BCOND_CTR 2
1548	e98a6e40	bellard
1549	e98a6e40	bellard	static inline void gen_bcond(DisasContext *ctx, int type)
1550	e98a6e40	bellard	{
1551	e98a6e40	bellard	uint32_t target = 0;
1552	e98a6e40	bellard	uint32_t bo = BO(ctx->opcode);
1553	e98a6e40	bellard	uint32_t bi = BI(ctx->opcode);
1554	e98a6e40	bellard	uint32_t mask;
1555	e98a6e40	bellard	uint32_t li;
1556	e98a6e40	bellard
1557	e98a6e40	bellard	if ((bo & 0x4) == 0)
1558	e98a6e40	bellard	gen_op_dec_ctr();
1559	e98a6e40	bellard	switch(type) {
1560	e98a6e40	bellard	case BCOND_IM:
1561	e98a6e40	bellard	li = s_ext16(BD(ctx->opcode));
1562	e98a6e40	bellard	if (AA(ctx->opcode) == 0) {
1563	046d6672	bellard	target = ctx->nip + li - 4;
1564	e98a6e40	bellard	} else {
1565	e98a6e40	bellard	target = li;
1566	e98a6e40	bellard	}
1567	e98a6e40	bellard	break;
1568	e98a6e40	bellard	case BCOND_CTR:
1569	e98a6e40	bellard	gen_op_movl_T1_ctr();
1570	e98a6e40	bellard	break;
1571	e98a6e40	bellard	default:
1572	e98a6e40	bellard	case BCOND_LR:
1573	e98a6e40	bellard	gen_op_movl_T1_lr();
1574	e98a6e40	bellard	break;
1575	e98a6e40	bellard	}
1576	e98a6e40	bellard	if (LK(ctx->opcode)) {
1577	046d6672	bellard	gen_op_setlr(ctx->nip);
1578	e98a6e40	bellard	}
1579	e98a6e40	bellard	if (bo & 0x10) {
1580	e98a6e40	bellard	/* No CR condition */
1581	e98a6e40	bellard	switch (bo & 0x6) {
1582	e98a6e40	bellard	case 0:
1583	e98a6e40	bellard	gen_op_test_ctr();
1584	e98a6e40	bellard	break;
1585	e98a6e40	bellard	case 2:
1586	e98a6e40	bellard	gen_op_test_ctrz();
1587	e98a6e40	bellard	break;
1588	e98a6e40	bellard	default:
1589	e98a6e40	bellard	case 4:
1590	e98a6e40	bellard	case 6:
1591	e98a6e40	bellard	if (type == BCOND_IM) {
1592	e98a6e40	bellard	gen_op_b((long)ctx->tb, target);
1593	e98a6e40	bellard	} else {
1594	e98a6e40	bellard	gen_op_b_T1();
1595	e98a6e40	bellard	}
1596	e98a6e40	bellard	goto no_test;
1597	e98a6e40	bellard	}
1598	e98a6e40	bellard	} else {
1599	e98a6e40	bellard	mask = 1 << (3 - (bi & 0x03));
1600	e98a6e40	bellard	gen_op_load_crf_T0(bi >> 2);
1601	e98a6e40	bellard	if (bo & 0x8) {
1602	e98a6e40	bellard	switch (bo & 0x6) {
1603	e98a6e40	bellard	case 0:
1604	e98a6e40	bellard	gen_op_test_ctr_true(mask);
1605	e98a6e40	bellard	break;
1606	e98a6e40	bellard	case 2:
1607	e98a6e40	bellard	gen_op_test_ctrz_true(mask);
1608	e98a6e40	bellard	break;
1609	e98a6e40	bellard	default:
1610	e98a6e40	bellard	case 4:
1611	e98a6e40	bellard	case 6:
1612	e98a6e40	bellard	gen_op_test_true(mask);
1613	e98a6e40	bellard	break;
1614	e98a6e40	bellard	}
1615	e98a6e40	bellard	} else {
1616	e98a6e40	bellard	switch (bo & 0x6) {
1617	e98a6e40	bellard	case 0:
1618	e98a6e40	bellard	gen_op_test_ctr_false(mask);
1619	e98a6e40	bellard	break;
1620	e98a6e40	bellard	case 2:
1621	e98a6e40	bellard	gen_op_test_ctrz_false(mask);
1622	e98a6e40	bellard	break;
1623	e98a6e40	bellard	default:
1624	e98a6e40	bellard	case 4:
1625	e98a6e40	bellard	case 6:
1626	e98a6e40	bellard	gen_op_test_false(mask);
1627	e98a6e40	bellard	break;
1628	e98a6e40	bellard	}
1629	e98a6e40	bellard	}
1630	e98a6e40	bellard	}
1631	e98a6e40	bellard	if (type == BCOND_IM) {
1632	046d6672	bellard	gen_op_btest((long)ctx->tb, target, ctx->nip);
1633	e98a6e40	bellard	} else {
1634	046d6672	bellard	gen_op_btest_T1(ctx->nip);
1635	e98a6e40	bellard	}
1636	e98a6e40	bellard	no_test:
1637	e98a6e40	bellard	ctx->exception = EXCP_BRANCH;
1638	e98a6e40	bellard	}
1639	e98a6e40	bellard
1640	e98a6e40	bellard	GEN_HANDLER(bc, 0x10, 0xFF, 0xFF, 0x00000000, PPC_FLOW)
1641	e98a6e40	bellard	{
1642	e98a6e40	bellard	gen_bcond(ctx, BCOND_IM);
1643	e98a6e40	bellard	}
1644	e98a6e40	bellard
1645	e98a6e40	bellard	GEN_HANDLER(bcctr, 0x13, 0x10, 0x10, 0x00000000, PPC_FLOW)
1646	e98a6e40	bellard	{
1647	e98a6e40	bellard	gen_bcond(ctx, BCOND_CTR);
1648	e98a6e40	bellard	}
1649	e98a6e40	bellard
1650	e98a6e40	bellard	GEN_HANDLER(bclr, 0x13, 0x10, 0x00, 0x00000000, PPC_FLOW)
1651	e98a6e40	bellard	{
1652	e98a6e40	bellard	gen_bcond(ctx, BCOND_LR);
1653	e98a6e40	bellard	}
1654	79aceca5	bellard
1655	79aceca5	bellard	/* Condition register logical */
1656	79aceca5	bellard	#define GEN_CRLOGIC(op, opc) \
1657	79aceca5	bellard	GEN_HANDLER(cr##op, 0x13, 0x01, opc, 0x00000001, PPC_INTEGER) \
1658	79aceca5	bellard	{ \
1659	79aceca5	bellard	gen_op_load_crf_T0(crbA(ctx->opcode) >> 2); \
1660	79aceca5	bellard	gen_op_getbit_T0(3 - (crbA(ctx->opcode) & 0x03)); \
1661	79aceca5	bellard	gen_op_load_crf_T1(crbB(ctx->opcode) >> 2); \
1662	79aceca5	bellard	gen_op_getbit_T1(3 - (crbB(ctx->opcode) & 0x03)); \
1663	79aceca5	bellard	gen_op_##op(); \
1664	79aceca5	bellard	gen_op_load_crf_T1(crbD(ctx->opcode) >> 2); \
1665	79aceca5	bellard	gen_op_setcrfbit(~(1 << (3 - (crbD(ctx->opcode) & 0x03))), \
1666	79aceca5	bellard	3 - (crbD(ctx->opcode) & 0x03)); \
1667	79aceca5	bellard	gen_op_store_T1_crf(crbD(ctx->opcode) >> 2); \
1668	79aceca5	bellard	}
1669	79aceca5	bellard
1670	79aceca5	bellard	/* crand */
1671	79aceca5	bellard	GEN_CRLOGIC(and, 0x08)
1672	79aceca5	bellard	/* crandc */
1673	79aceca5	bellard	GEN_CRLOGIC(andc, 0x04)
1674	79aceca5	bellard	/* creqv */
1675	79aceca5	bellard	GEN_CRLOGIC(eqv, 0x09)
1676	79aceca5	bellard	/* crnand */
1677	79aceca5	bellard	GEN_CRLOGIC(nand, 0x07)
1678	79aceca5	bellard	/* crnor */
1679	79aceca5	bellard	GEN_CRLOGIC(nor, 0x01)
1680	79aceca5	bellard	/* cror */
1681	79aceca5	bellard	GEN_CRLOGIC(or, 0x0E)
1682	79aceca5	bellard	/* crorc */
1683	79aceca5	bellard	GEN_CRLOGIC(orc, 0x0D)
1684	79aceca5	bellard	/* crxor */
1685	79aceca5	bellard	GEN_CRLOGIC(xor, 0x06)
1686	79aceca5	bellard	/* mcrf */
1687	79aceca5	bellard	GEN_HANDLER(mcrf, 0x13, 0x00, 0xFF, 0x00000001, PPC_INTEGER)
1688	79aceca5	bellard	{
1689	79aceca5	bellard	gen_op_load_crf_T0(crfS(ctx->opcode));
1690	79aceca5	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
1691	79aceca5	bellard	}
1692	79aceca5	bellard
1693	79aceca5	bellard	/* System linkage */
1694	79aceca5	bellard	/* rfi (supervisor only) */
1695	79aceca5	bellard	GEN_HANDLER(rfi, 0x13, 0x12, 0xFF, 0x03FF8001, PPC_FLOW)
1696	79aceca5	bellard	{
1697	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1698	9fddaa0c	bellard	RET_PRIVOPC(ctx);
1699	9a64fbe4	bellard	#else
1700	9a64fbe4	bellard	/* Restore CPU state */
1701	9a64fbe4	bellard	if (!ctx->supervisor) {
1702	9fddaa0c	bellard	RET_PRIVOPC(ctx);
1703	9fddaa0c	bellard	return;
1704	9a64fbe4	bellard	}
1705	9a64fbe4	bellard	gen_op_rfi();
1706	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_RFI, 0);
1707	9a64fbe4	bellard	#endif
1708	79aceca5	bellard	}
1709	79aceca5	bellard
1710	79aceca5	bellard	/* sc */
1711	79aceca5	bellard	GEN_HANDLER(sc, 0x11, 0xFF, 0xFF, 0x03FFFFFD, PPC_FLOW)
1712	79aceca5	bellard	{
1713	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1714	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_SYSCALL_USER, 0);
1715	9a64fbe4	bellard	#else
1716	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_SYSCALL, 0);
1717	9a64fbe4	bellard	#endif
1718	79aceca5	bellard	}
1719	79aceca5	bellard
1720	79aceca5	bellard	/* Trap */
1721	79aceca5	bellard	/* tw */
1722	79aceca5	bellard	GEN_HANDLER(tw, 0x1F, 0x04, 0xFF, 0x00000001, PPC_FLOW)
1723	79aceca5	bellard	{
1724	9a64fbe4	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1725	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
1726	9a64fbe4	bellard	gen_op_tw(TO(ctx->opcode));
1727	79aceca5	bellard	}
1728	79aceca5	bellard
1729	79aceca5	bellard	/* twi */
1730	79aceca5	bellard	GEN_HANDLER(twi, 0x03, 0xFF, 0xFF, 0x00000000, PPC_FLOW)
1731	79aceca5	bellard	{
1732	9a64fbe4	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
1733	9a64fbe4	bellard	#if 0
1734	9a64fbe4	bellard	printf("%s: param=0x%04x T0=0x%04x\n", __func__,
1735	9a64fbe4	bellard	SIMM(ctx->opcode), TO(ctx->opcode));
1736	9a64fbe4	bellard	#endif
1737	9a64fbe4	bellard	gen_op_twi(SIMM(ctx->opcode), TO(ctx->opcode));
1738	79aceca5	bellard	}
1739	79aceca5	bellard
1740	79aceca5	bellard	/* Processor control */
1741	79aceca5	bellard	static inline int check_spr_access (int spr, int rw, int supervisor)
1742	79aceca5	bellard	{
1743	79aceca5	bellard	uint32_t rights = spr_access[spr >> 1] >> (4 * (spr & 1));
1744	79aceca5	bellard
1745	9a64fbe4	bellard	#if 0
1746	9a64fbe4	bellard	if (spr != LR && spr != CTR) {
1747	9a64fbe4	bellard	if (loglevel > 0) {
1748	9a64fbe4	bellard	fprintf(logfile, "%s reg=%d s=%d rw=%d r=0x%02x 0x%02x\n", __func__,
1749	9a64fbe4	bellard	SPR_ENCODE(spr), supervisor, rw, rights,
1750	9a64fbe4	bellard	(rights >> ((2 * supervisor) + rw)) & 1);
1751	9a64fbe4	bellard	} else {
1752	9a64fbe4	bellard	printf("%s reg=%d s=%d rw=%d r=0x%02x 0x%02x\n", __func__,
1753	9a64fbe4	bellard	SPR_ENCODE(spr), supervisor, rw, rights,
1754	9a64fbe4	bellard	(rights >> ((2 * supervisor) + rw)) & 1);
1755	9a64fbe4	bellard	}
1756	9a64fbe4	bellard	}
1757	9a64fbe4	bellard	#endif
1758	9a64fbe4	bellard	if (rights == 0)
1759	9a64fbe4	bellard	return -1;
1760	79aceca5	bellard	rights = rights >> (2 * supervisor);
1761	79aceca5	bellard	rights = rights >> rw;
1762	79aceca5	bellard
1763	79aceca5	bellard	return rights & 1;
1764	79aceca5	bellard	}
1765	79aceca5	bellard
1766	79aceca5	bellard	/* mcrxr */
1767	79aceca5	bellard	GEN_HANDLER(mcrxr, 0x1F, 0x00, 0x10, 0x007FF801, PPC_MISC)
1768	79aceca5	bellard	{
1769	79aceca5	bellard	gen_op_load_xer_cr();
1770	79aceca5	bellard	gen_op_store_T0_crf(crfD(ctx->opcode));
1771	79aceca5	bellard	gen_op_clear_xer_cr();
1772	79aceca5	bellard	}
1773	79aceca5	bellard
1774	79aceca5	bellard	/* mfcr */
1775	79aceca5	bellard	GEN_HANDLER(mfcr, 0x1F, 0x13, 0x00, 0x001FF801, PPC_MISC)
1776	79aceca5	bellard	{
1777	79aceca5	bellard	gen_op_load_cr();
1778	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
1779	79aceca5	bellard	}
1780	79aceca5	bellard
1781	79aceca5	bellard	/* mfmsr */
1782	79aceca5	bellard	GEN_HANDLER(mfmsr, 0x1F, 0x13, 0x02, 0x001FF801, PPC_MISC)
1783	79aceca5	bellard	{
1784	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1785	9fddaa0c	bellard	RET_PRIVREG(ctx);
1786	9a64fbe4	bellard	#else
1787	9a64fbe4	bellard	if (!ctx->supervisor) {
1788	9fddaa0c	bellard	RET_PRIVREG(ctx);
1789	9fddaa0c	bellard	return;
1790	9a64fbe4	bellard	}
1791	79aceca5	bellard	gen_op_load_msr();
1792	79aceca5	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
1793	9a64fbe4	bellard	#endif
1794	79aceca5	bellard	}
1795	79aceca5	bellard
1796	79aceca5	bellard	/* mfspr */
1797	79aceca5	bellard	GEN_HANDLER(mfspr, 0x1F, 0x13, 0x0A, 0x00000001, PPC_MISC)
1798	79aceca5	bellard	{
1799	79aceca5	bellard	uint32_t sprn = SPR(ctx->opcode);
1800	79aceca5	bellard
1801	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1802	9a64fbe4	bellard	switch (check_spr_access(sprn, 0, 0))
1803	9a64fbe4	bellard	#else
1804	9a64fbe4	bellard	switch (check_spr_access(sprn, 0, ctx->supervisor))
1805	9a64fbe4	bellard	#endif
1806	9a64fbe4	bellard	{
1807	9a64fbe4	bellard	case -1:
1808	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_PROGRAM, EXCP_INVAL \| EXCP_INVAL_SPR);
1809	9fddaa0c	bellard	return;
1810	9a64fbe4	bellard	case 0:
1811	9fddaa0c	bellard	RET_PRIVREG(ctx);
1812	9fddaa0c	bellard	return;
1813	9a64fbe4	bellard	default:
1814	9a64fbe4	bellard	break;
1815	79aceca5	bellard	}
1816	9a64fbe4	bellard	switch (sprn) {
1817	9a64fbe4	bellard	case XER:
1818	79aceca5	bellard	gen_op_load_xer();
1819	79aceca5	bellard	break;
1820	9a64fbe4	bellard	case LR:
1821	9a64fbe4	bellard	gen_op_load_lr();
1822	9a64fbe4	bellard	break;
1823	9a64fbe4	bellard	case CTR:
1824	9a64fbe4	bellard	gen_op_load_ctr();
1825	9a64fbe4	bellard	break;
1826	9a64fbe4	bellard	case IBAT0U:
1827	9a64fbe4	bellard	gen_op_load_ibat(0, 0);
1828	9a64fbe4	bellard	break;
1829	9a64fbe4	bellard	case IBAT1U:
1830	9a64fbe4	bellard	gen_op_load_ibat(0, 1);
1831	9a64fbe4	bellard	break;
1832	9a64fbe4	bellard	case IBAT2U:
1833	9a64fbe4	bellard	gen_op_load_ibat(0, 2);
1834	9a64fbe4	bellard	break;
1835	9a64fbe4	bellard	case IBAT3U:
1836	9a64fbe4	bellard	gen_op_load_ibat(0, 3);
1837	9a64fbe4	bellard	break;
1838	9a64fbe4	bellard	case IBAT4U:
1839	9a64fbe4	bellard	gen_op_load_ibat(0, 4);
1840	9a64fbe4	bellard	break;
1841	9a64fbe4	bellard	case IBAT5U:
1842	9a64fbe4	bellard	gen_op_load_ibat(0, 5);
1843	9a64fbe4	bellard	break;
1844	9a64fbe4	bellard	case IBAT6U:
1845	9a64fbe4	bellard	gen_op_load_ibat(0, 6);
1846	9a64fbe4	bellard	break;
1847	9a64fbe4	bellard	case IBAT7U:
1848	9a64fbe4	bellard	gen_op_load_ibat(0, 7);
1849	9a64fbe4	bellard	break;
1850	9a64fbe4	bellard	case IBAT0L:
1851	9a64fbe4	bellard	gen_op_load_ibat(1, 0);
1852	9a64fbe4	bellard	break;
1853	9a64fbe4	bellard	case IBAT1L:
1854	9a64fbe4	bellard	gen_op_load_ibat(1, 1);
1855	9a64fbe4	bellard	break;
1856	9a64fbe4	bellard	case IBAT2L:
1857	9a64fbe4	bellard	gen_op_load_ibat(1, 2);
1858	9a64fbe4	bellard	break;
1859	9a64fbe4	bellard	case IBAT3L:
1860	9a64fbe4	bellard	gen_op_load_ibat(1, 3);
1861	9a64fbe4	bellard	break;
1862	9a64fbe4	bellard	case IBAT4L:
1863	9a64fbe4	bellard	gen_op_load_ibat(1, 4);
1864	9a64fbe4	bellard	break;
1865	9a64fbe4	bellard	case IBAT5L:
1866	9a64fbe4	bellard	gen_op_load_ibat(1, 5);
1867	9a64fbe4	bellard	break;
1868	9a64fbe4	bellard	case IBAT6L:
1869	9a64fbe4	bellard	gen_op_load_ibat(1, 6);
1870	9a64fbe4	bellard	break;
1871	9a64fbe4	bellard	case IBAT7L:
1872	9a64fbe4	bellard	gen_op_load_ibat(1, 7);
1873	9a64fbe4	bellard	break;
1874	9a64fbe4	bellard	case DBAT0U:
1875	9a64fbe4	bellard	gen_op_load_dbat(0, 0);
1876	9a64fbe4	bellard	break;
1877	9a64fbe4	bellard	case DBAT1U:
1878	9a64fbe4	bellard	gen_op_load_dbat(0, 1);
1879	9a64fbe4	bellard	break;
1880	9a64fbe4	bellard	case DBAT2U:
1881	9a64fbe4	bellard	gen_op_load_dbat(0, 2);
1882	9a64fbe4	bellard	break;
1883	9a64fbe4	bellard	case DBAT3U:
1884	9a64fbe4	bellard	gen_op_load_dbat(0, 3);
1885	9a64fbe4	bellard	break;
1886	9a64fbe4	bellard	case DBAT4U:
1887	9a64fbe4	bellard	gen_op_load_dbat(0, 4);
1888	9a64fbe4	bellard	break;
1889	9a64fbe4	bellard	case DBAT5U:
1890	9a64fbe4	bellard	gen_op_load_dbat(0, 5);
1891	9a64fbe4	bellard	break;
1892	9a64fbe4	bellard	case DBAT6U:
1893	9a64fbe4	bellard	gen_op_load_dbat(0, 6);
1894	9a64fbe4	bellard	break;
1895	9a64fbe4	bellard	case DBAT7U:
1896	9a64fbe4	bellard	gen_op_load_dbat(0, 7);
1897	9a64fbe4	bellard	break;
1898	9a64fbe4	bellard	case DBAT0L:
1899	9a64fbe4	bellard	gen_op_load_dbat(1, 0);
1900	9a64fbe4	bellard	break;
1901	9a64fbe4	bellard	case DBAT1L:
1902	9a64fbe4	bellard	gen_op_load_dbat(1, 1);
1903	9a64fbe4	bellard	break;
1904	9a64fbe4	bellard	case DBAT2L:
1905	9a64fbe4	bellard	gen_op_load_dbat(1, 2);
1906	9a64fbe4	bellard	break;
1907	9a64fbe4	bellard	case DBAT3L:
1908	9a64fbe4	bellard	gen_op_load_dbat(1, 3);
1909	9a64fbe4	bellard	break;
1910	9a64fbe4	bellard	case DBAT4L:
1911	9a64fbe4	bellard	gen_op_load_dbat(1, 4);
1912	9a64fbe4	bellard	break;
1913	9a64fbe4	bellard	case DBAT5L:
1914	9a64fbe4	bellard	gen_op_load_dbat(1, 5);
1915	9a64fbe4	bellard	break;
1916	9a64fbe4	bellard	case DBAT6L:
1917	9a64fbe4	bellard	gen_op_load_dbat(1, 6);
1918	9a64fbe4	bellard	break;
1919	9a64fbe4	bellard	case DBAT7L:
1920	9a64fbe4	bellard	gen_op_load_dbat(1, 7);
1921	9a64fbe4	bellard	break;
1922	9a64fbe4	bellard	case SDR1:
1923	9a64fbe4	bellard	gen_op_load_sdr1();
1924	9a64fbe4	bellard	break;
1925	9a64fbe4	bellard	case V_TBL:
1926	9fddaa0c	bellard	gen_op_load_tbl();
1927	79aceca5	bellard	break;
1928	9a64fbe4	bellard	case V_TBU:
1929	9fddaa0c	bellard	gen_op_load_tbu();
1930	9a64fbe4	bellard	break;
1931	9a64fbe4	bellard	case DECR:
1932	9fddaa0c	bellard	gen_op_load_decr();
1933	79aceca5	bellard	break;
1934	79aceca5	bellard	default:
1935	79aceca5	bellard	gen_op_load_spr(sprn);
1936	79aceca5	bellard	break;
1937	79aceca5	bellard	}
1938	9a64fbe4	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
1939	79aceca5	bellard	}
1940	79aceca5	bellard
1941	79aceca5	bellard	/* mftb */
1942	79aceca5	bellard	GEN_HANDLER(mftb, 0x1F, 0x13, 0x0B, 0x00000001, PPC_MISC)
1943	79aceca5	bellard	{
1944	79aceca5	bellard	uint32_t sprn = SPR(ctx->opcode);
1945	79aceca5	bellard
1946	79aceca5	bellard	/* We need to update the time base before reading it */
1947	9a64fbe4	bellard	switch (sprn) {
1948	9a64fbe4	bellard	case V_TBL:
1949	9fddaa0c	bellard	gen_op_load_tbl();
1950	79aceca5	bellard	break;
1951	9a64fbe4	bellard	case V_TBU:
1952	9fddaa0c	bellard	gen_op_load_tbu();
1953	79aceca5	bellard	break;
1954	79aceca5	bellard	default:
1955	9fddaa0c	bellard	RET_INVAL(ctx);
1956	9fddaa0c	bellard	return;
1957	79aceca5	bellard	}
1958	9a64fbe4	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
1959	79aceca5	bellard	}
1960	79aceca5	bellard
1961	79aceca5	bellard	/* mtcrf */
1962	79aceca5	bellard	GEN_HANDLER(mtcrf, 0x1F, 0x10, 0x04, 0x00100801, PPC_MISC)
1963	79aceca5	bellard	{
1964	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
1965	79aceca5	bellard	gen_op_store_cr(CRM(ctx->opcode));
1966	79aceca5	bellard	}
1967	79aceca5	bellard
1968	79aceca5	bellard	/* mtmsr */
1969	79aceca5	bellard	GEN_HANDLER(mtmsr, 0x1F, 0x12, 0x04, 0x001FF801, PPC_MISC)
1970	79aceca5	bellard	{
1971	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1972	9fddaa0c	bellard	RET_PRIVREG(ctx);
1973	9a64fbe4	bellard	#else
1974	9a64fbe4	bellard	if (!ctx->supervisor) {
1975	9fddaa0c	bellard	RET_PRIVREG(ctx);
1976	9fddaa0c	bellard	return;
1977	9a64fbe4	bellard	}
1978	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
1979	79aceca5	bellard	gen_op_store_msr();
1980	79aceca5	bellard	/* Must stop the translation as machine state (may have) changed */
1981	9fddaa0c	bellard	RET_MTMSR(ctx);
1982	9a64fbe4	bellard	#endif
1983	79aceca5	bellard	}
1984	79aceca5	bellard
1985	79aceca5	bellard	/* mtspr */
1986	79aceca5	bellard	GEN_HANDLER(mtspr, 0x1F, 0x13, 0x0E, 0x00000001, PPC_MISC)
1987	79aceca5	bellard	{
1988	79aceca5	bellard	uint32_t sprn = SPR(ctx->opcode);
1989	79aceca5	bellard
1990	9a64fbe4	bellard	#if 0
1991	9a64fbe4	bellard	if (loglevel > 0) {
1992	9a64fbe4	bellard	fprintf(logfile, "MTSPR %d src=%d (%d)\n", SPR_ENCODE(sprn),
1993	9a64fbe4	bellard	rS(ctx->opcode), sprn);
1994	9a64fbe4	bellard	}
1995	9a64fbe4	bellard	#endif
1996	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
1997	9a64fbe4	bellard	switch (check_spr_access(sprn, 1, 0))
1998	9a64fbe4	bellard	#else
1999	9a64fbe4	bellard	switch (check_spr_access(sprn, 1, ctx->supervisor))
2000	9a64fbe4	bellard	#endif
2001	9a64fbe4	bellard	{
2002	9a64fbe4	bellard	case -1:
2003	9fddaa0c	bellard	RET_EXCP(ctx, EXCP_PROGRAM, EXCP_INVAL \| EXCP_INVAL_SPR);
2004	9a64fbe4	bellard	break;
2005	9a64fbe4	bellard	case 0:
2006	9fddaa0c	bellard	RET_PRIVREG(ctx);
2007	9a64fbe4	bellard	break;
2008	9a64fbe4	bellard	default:
2009	9a64fbe4	bellard	break;
2010	9a64fbe4	bellard	}
2011	79aceca5	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
2012	9a64fbe4	bellard	switch (sprn) {
2013	9a64fbe4	bellard	case XER:
2014	79aceca5	bellard	gen_op_store_xer();
2015	9a64fbe4	bellard	break;
2016	9a64fbe4	bellard	case LR:
2017	9a64fbe4	bellard	gen_op_store_lr();
2018	9a64fbe4	bellard	break;
2019	9a64fbe4	bellard	case CTR:
2020	9a64fbe4	bellard	gen_op_store_ctr();
2021	9a64fbe4	bellard	break;
2022	9a64fbe4	bellard	case IBAT0U:
2023	9a64fbe4	bellard	gen_op_store_ibat(0, 0);
2024	4b3686fa	bellard	RET_MTMSR(ctx);
2025	9a64fbe4	bellard	break;
2026	9a64fbe4	bellard	case IBAT1U:
2027	9a64fbe4	bellard	gen_op_store_ibat(0, 1);
2028	4b3686fa	bellard	RET_MTMSR(ctx);
2029	9a64fbe4	bellard	break;
2030	9a64fbe4	bellard	case IBAT2U:
2031	9a64fbe4	bellard	gen_op_store_ibat(0, 2);
2032	4b3686fa	bellard	RET_MTMSR(ctx);
2033	9a64fbe4	bellard	break;
2034	9a64fbe4	bellard	case IBAT3U:
2035	9a64fbe4	bellard	gen_op_store_ibat(0, 3);
2036	4b3686fa	bellard	RET_MTMSR(ctx);
2037	9a64fbe4	bellard	break;
2038	9a64fbe4	bellard	case IBAT4U:
2039	9a64fbe4	bellard	gen_op_store_ibat(0, 4);
2040	4b3686fa	bellard	RET_MTMSR(ctx);
2041	9a64fbe4	bellard	break;
2042	9a64fbe4	bellard	case IBAT5U:
2043	9a64fbe4	bellard	gen_op_store_ibat(0, 5);
2044	4b3686fa	bellard	RET_MTMSR(ctx);
2045	9a64fbe4	bellard	break;
2046	9a64fbe4	bellard	case IBAT6U:
2047	9a64fbe4	bellard	gen_op_store_ibat(0, 6);
2048	4b3686fa	bellard	RET_MTMSR(ctx);
2049	9a64fbe4	bellard	break;
2050	9a64fbe4	bellard	case IBAT7U:
2051	9a64fbe4	bellard	gen_op_store_ibat(0, 7);
2052	4b3686fa	bellard	RET_MTMSR(ctx);
2053	9a64fbe4	bellard	break;
2054	9a64fbe4	bellard	case IBAT0L:
2055	9a64fbe4	bellard	gen_op_store_ibat(1, 0);
2056	4b3686fa	bellard	RET_MTMSR(ctx);
2057	9a64fbe4	bellard	break;
2058	9a64fbe4	bellard	case IBAT1L:
2059	9a64fbe4	bellard	gen_op_store_ibat(1, 1);
2060	4b3686fa	bellard	RET_MTMSR(ctx);
2061	9a64fbe4	bellard	break;
2062	9a64fbe4	bellard	case IBAT2L:
2063	9a64fbe4	bellard	gen_op_store_ibat(1, 2);
2064	4b3686fa	bellard	RET_MTMSR(ctx);
2065	9a64fbe4	bellard	break;
2066	9a64fbe4	bellard	case IBAT3L:
2067	9a64fbe4	bellard	gen_op_store_ibat(1, 3);
2068	4b3686fa	bellard	RET_MTMSR(ctx);
2069	9a64fbe4	bellard	break;
2070	9a64fbe4	bellard	case IBAT4L:
2071	9a64fbe4	bellard	gen_op_store_ibat(1, 4);
2072	4b3686fa	bellard	RET_MTMSR(ctx);
2073	9a64fbe4	bellard	break;
2074	9a64fbe4	bellard	case IBAT5L:
2075	9a64fbe4	bellard	gen_op_store_ibat(1, 5);
2076	4b3686fa	bellard	RET_MTMSR(ctx);
2077	9a64fbe4	bellard	break;
2078	9a64fbe4	bellard	case IBAT6L:
2079	9a64fbe4	bellard	gen_op_store_ibat(1, 6);
2080	4b3686fa	bellard	RET_MTMSR(ctx);
2081	9a64fbe4	bellard	break;
2082	9a64fbe4	bellard	case IBAT7L:
2083	9a64fbe4	bellard	gen_op_store_ibat(1, 7);
2084	4b3686fa	bellard	RET_MTMSR(ctx);
2085	9a64fbe4	bellard	break;
2086	9a64fbe4	bellard	case DBAT0U:
2087	9a64fbe4	bellard	gen_op_store_dbat(0, 0);
2088	4b3686fa	bellard	RET_MTMSR(ctx);
2089	9a64fbe4	bellard	break;
2090	9a64fbe4	bellard	case DBAT1U:
2091	9a64fbe4	bellard	gen_op_store_dbat(0, 1);
2092	4b3686fa	bellard	RET_MTMSR(ctx);
2093	9a64fbe4	bellard	break;
2094	9a64fbe4	bellard	case DBAT2U:
2095	9a64fbe4	bellard	gen_op_store_dbat(0, 2);
2096	4b3686fa	bellard	RET_MTMSR(ctx);
2097	9a64fbe4	bellard	break;
2098	9a64fbe4	bellard	case DBAT3U:
2099	9a64fbe4	bellard	gen_op_store_dbat(0, 3);
2100	4b3686fa	bellard	RET_MTMSR(ctx);
2101	9a64fbe4	bellard	break;
2102	9a64fbe4	bellard	case DBAT4U:
2103	9a64fbe4	bellard	gen_op_store_dbat(0, 4);
2104	4b3686fa	bellard	RET_MTMSR(ctx);
2105	9a64fbe4	bellard	break;
2106	9a64fbe4	bellard	case DBAT5U:
2107	9a64fbe4	bellard	gen_op_store_dbat(0, 5);
2108	4b3686fa	bellard	RET_MTMSR(ctx);
2109	9a64fbe4	bellard	break;
2110	9a64fbe4	bellard	case DBAT6U:
2111	9a64fbe4	bellard	gen_op_store_dbat(0, 6);
2112	4b3686fa	bellard	RET_MTMSR(ctx);
2113	9a64fbe4	bellard	break;
2114	9a64fbe4	bellard	case DBAT7U:
2115	9a64fbe4	bellard	gen_op_store_dbat(0, 7);
2116	4b3686fa	bellard	RET_MTMSR(ctx);
2117	9a64fbe4	bellard	break;
2118	9a64fbe4	bellard	case DBAT0L:
2119	9a64fbe4	bellard	gen_op_store_dbat(1, 0);
2120	4b3686fa	bellard	RET_MTMSR(ctx);
2121	9a64fbe4	bellard	break;
2122	9a64fbe4	bellard	case DBAT1L:
2123	9a64fbe4	bellard	gen_op_store_dbat(1, 1);
2124	4b3686fa	bellard	RET_MTMSR(ctx);
2125	9a64fbe4	bellard	break;
2126	9a64fbe4	bellard	case DBAT2L:
2127	9a64fbe4	bellard	gen_op_store_dbat(1, 2);
2128	4b3686fa	bellard	RET_MTMSR(ctx);
2129	9a64fbe4	bellard	break;
2130	9a64fbe4	bellard	case DBAT3L:
2131	9a64fbe4	bellard	gen_op_store_dbat(1, 3);
2132	4b3686fa	bellard	RET_MTMSR(ctx);
2133	9a64fbe4	bellard	break;
2134	9a64fbe4	bellard	case DBAT4L:
2135	9a64fbe4	bellard	gen_op_store_dbat(1, 4);
2136	4b3686fa	bellard	RET_MTMSR(ctx);
2137	9a64fbe4	bellard	break;
2138	9a64fbe4	bellard	case DBAT5L:
2139	9a64fbe4	bellard	gen_op_store_dbat(1, 5);
2140	4b3686fa	bellard	RET_MTMSR(ctx);
2141	9a64fbe4	bellard	break;
2142	9a64fbe4	bellard	case DBAT6L:
2143	9a64fbe4	bellard	gen_op_store_dbat(1, 6);
2144	4b3686fa	bellard	RET_MTMSR(ctx);
2145	9a64fbe4	bellard	break;
2146	9a64fbe4	bellard	case DBAT7L:
2147	9a64fbe4	bellard	gen_op_store_dbat(1, 7);
2148	4b3686fa	bellard	RET_MTMSR(ctx);
2149	9a64fbe4	bellard	break;
2150	9a64fbe4	bellard	case SDR1:
2151	9a64fbe4	bellard	gen_op_store_sdr1();
2152	4b3686fa	bellard	RET_MTMSR(ctx);
2153	9a64fbe4	bellard	break;
2154	9a64fbe4	bellard	case O_TBL:
2155	9fddaa0c	bellard	gen_op_store_tbl();
2156	9a64fbe4	bellard	break;
2157	9a64fbe4	bellard	case O_TBU:
2158	9fddaa0c	bellard	gen_op_store_tbu();
2159	9a64fbe4	bellard	break;
2160	9a64fbe4	bellard	case DECR:
2161	9a64fbe4	bellard	gen_op_store_decr();
2162	9a64fbe4	bellard	break;
2163	4b3686fa	bellard	#if 0
2164	4b3686fa	bellard	case HID0:
2165	4b3686fa	bellard	gen_op_store_hid0();
2166	4b3686fa	bellard	break;
2167	4b3686fa	bellard	#endif
2168	9a64fbe4	bellard	default:
2169	79aceca5	bellard	gen_op_store_spr(sprn);
2170	9a64fbe4	bellard	break;
2171	79aceca5	bellard	}
2172	79aceca5	bellard	}
2173	79aceca5	bellard
2174	79aceca5	bellard	/* Cache management */
2175	79aceca5	bellard	/* For now, all those will be implemented as nop:
2176	79aceca5	bellard	* this is valid, regarding the PowerPC specs...
2177	9a64fbe4	bellard	* We just have to flush tb while invalidating instruction cache lines...
2178	79aceca5	bellard	*/
2179	79aceca5	bellard	/* dcbf */
2180	9a64fbe4	bellard	GEN_HANDLER(dcbf, 0x1F, 0x16, 0x02, 0x03E00001, PPC_CACHE)
2181	79aceca5	bellard	{
2182	a541f297	bellard	if (rA(ctx->opcode) == 0) {
2183	a541f297	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2184	a541f297	bellard	} else {
2185	a541f297	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2186	a541f297	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2187	a541f297	bellard	gen_op_add();
2188	a541f297	bellard	}
2189	a541f297	bellard	op_ldst(lbz);
2190	79aceca5	bellard	}
2191	79aceca5	bellard
2192	79aceca5	bellard	/* dcbi (Supervisor only) */
2193	9a64fbe4	bellard	GEN_HANDLER(dcbi, 0x1F, 0x16, 0x0E, 0x03E00001, PPC_CACHE)
2194	79aceca5	bellard	{
2195	a541f297	bellard	#if defined(CONFIG_USER_ONLY)
2196	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2197	a541f297	bellard	#else
2198	a541f297	bellard	if (!ctx->supervisor) {
2199	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2200	9fddaa0c	bellard	return;
2201	9a64fbe4	bellard	}
2202	a541f297	bellard	if (rA(ctx->opcode) == 0) {
2203	a541f297	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2204	a541f297	bellard	} else {
2205	a541f297	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2206	a541f297	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2207	a541f297	bellard	gen_op_add();
2208	a541f297	bellard	}
2209	a541f297	bellard	op_ldst(lbz);
2210	a541f297	bellard	op_ldst(stb);
2211	a541f297	bellard	#endif
2212	79aceca5	bellard	}
2213	79aceca5	bellard
2214	79aceca5	bellard	/* dcdst */
2215	9a64fbe4	bellard	GEN_HANDLER(dcbst, 0x1F, 0x16, 0x01, 0x03E00001, PPC_CACHE)
2216	79aceca5	bellard	{
2217	a541f297	bellard	if (rA(ctx->opcode) == 0) {
2218	a541f297	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2219	a541f297	bellard	} else {
2220	a541f297	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2221	a541f297	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2222	a541f297	bellard	gen_op_add();
2223	a541f297	bellard	}
2224	a541f297	bellard	op_ldst(lbz);
2225	79aceca5	bellard	}
2226	79aceca5	bellard
2227	79aceca5	bellard	/* dcbt */
2228	9a64fbe4	bellard	GEN_HANDLER(dcbt, 0x1F, 0x16, 0x08, 0x03E00001, PPC_CACHE)
2229	79aceca5	bellard	{
2230	79aceca5	bellard	}
2231	79aceca5	bellard
2232	79aceca5	bellard	/* dcbtst */
2233	9a64fbe4	bellard	GEN_HANDLER(dcbtst, 0x1F, 0x16, 0x07, 0x03E00001, PPC_CACHE)
2234	79aceca5	bellard	{
2235	79aceca5	bellard	}
2236	79aceca5	bellard
2237	79aceca5	bellard	/* dcbz */
2238	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2239	9a64fbe4	bellard	#define op_dcbz() gen_op_dcbz_raw()
2240	9a64fbe4	bellard	#else
2241	9a64fbe4	bellard	#define op_dcbz() (*gen_op_dcbz[ctx->mem_idx])()
2242	9a64fbe4	bellard	static GenOpFunc *gen_op_dcbz[] = {
2243	9a64fbe4	bellard	&gen_op_dcbz_user,
2244	9a64fbe4	bellard	&gen_op_dcbz_kernel,
2245	9a64fbe4	bellard	};
2246	9a64fbe4	bellard	#endif
2247	9a64fbe4	bellard
2248	9a64fbe4	bellard	GEN_HANDLER(dcbz, 0x1F, 0x16, 0x1F, 0x03E00001, PPC_CACHE)
2249	79aceca5	bellard	{
2250	fb0eaffc	bellard	if (rA(ctx->opcode) == 0) {
2251	fb0eaffc	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2252	fb0eaffc	bellard	} else {
2253	fb0eaffc	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2254	fb0eaffc	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2255	9a64fbe4	bellard	gen_op_add();
2256	fb0eaffc	bellard	}
2257	9a64fbe4	bellard	op_dcbz();
2258	4b3686fa	bellard	gen_op_check_reservation();
2259	79aceca5	bellard	}
2260	79aceca5	bellard
2261	79aceca5	bellard	/* icbi */
2262	9a64fbe4	bellard	GEN_HANDLER(icbi, 0x1F, 0x16, 0x1E, 0x03E00001, PPC_CACHE)
2263	79aceca5	bellard	{
2264	fb0eaffc	bellard	if (rA(ctx->opcode) == 0) {
2265	fb0eaffc	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2266	fb0eaffc	bellard	} else {
2267	fb0eaffc	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2268	fb0eaffc	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2269	9a64fbe4	bellard	gen_op_add();
2270	fb0eaffc	bellard	}
2271	9a64fbe4	bellard	gen_op_icbi();
2272	79aceca5	bellard	}
2273	79aceca5	bellard
2274	79aceca5	bellard	/* Optional: */
2275	79aceca5	bellard	/* dcba */
2276	9a64fbe4	bellard	GEN_HANDLER(dcba, 0x1F, 0x16, 0x07, 0x03E00001, PPC_CACHE_OPT)
2277	79aceca5	bellard	{
2278	79aceca5	bellard	}
2279	79aceca5	bellard
2280	79aceca5	bellard	/* Segment register manipulation */
2281	79aceca5	bellard	/* Supervisor only: */
2282	79aceca5	bellard	/* mfsr */
2283	79aceca5	bellard	GEN_HANDLER(mfsr, 0x1F, 0x13, 0x12, 0x0010F801, PPC_SEGMENT)
2284	79aceca5	bellard	{
2285	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2286	9fddaa0c	bellard	RET_PRIVREG(ctx);
2287	9a64fbe4	bellard	#else
2288	9a64fbe4	bellard	if (!ctx->supervisor) {
2289	9fddaa0c	bellard	RET_PRIVREG(ctx);
2290	9fddaa0c	bellard	return;
2291	9a64fbe4	bellard	}
2292	9a64fbe4	bellard	gen_op_load_sr(SR(ctx->opcode));
2293	9a64fbe4	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
2294	9a64fbe4	bellard	#endif
2295	79aceca5	bellard	}
2296	79aceca5	bellard
2297	79aceca5	bellard	/* mfsrin */
2298	9a64fbe4	bellard	GEN_HANDLER(mfsrin, 0x1F, 0x13, 0x14, 0x001F0001, PPC_SEGMENT)
2299	79aceca5	bellard	{
2300	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2301	9fddaa0c	bellard	RET_PRIVREG(ctx);
2302	9a64fbe4	bellard	#else
2303	9a64fbe4	bellard	if (!ctx->supervisor) {
2304	9fddaa0c	bellard	RET_PRIVREG(ctx);
2305	9fddaa0c	bellard	return;
2306	9a64fbe4	bellard	}
2307	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2308	9a64fbe4	bellard	gen_op_load_srin();
2309	9a64fbe4	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
2310	9a64fbe4	bellard	#endif
2311	79aceca5	bellard	}
2312	79aceca5	bellard
2313	79aceca5	bellard	/* mtsr */
2314	e63c59cb	bellard	GEN_HANDLER(mtsr, 0x1F, 0x12, 0x06, 0x0010F801, PPC_SEGMENT)
2315	79aceca5	bellard	{
2316	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2317	9fddaa0c	bellard	RET_PRIVREG(ctx);
2318	9a64fbe4	bellard	#else
2319	9a64fbe4	bellard	if (!ctx->supervisor) {
2320	9fddaa0c	bellard	RET_PRIVREG(ctx);
2321	9fddaa0c	bellard	return;
2322	9a64fbe4	bellard	}
2323	9a64fbe4	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
2324	9a64fbe4	bellard	gen_op_store_sr(SR(ctx->opcode));
2325	9a64fbe4	bellard	#endif
2326	79aceca5	bellard	}
2327	79aceca5	bellard
2328	79aceca5	bellard	/* mtsrin */
2329	9a64fbe4	bellard	GEN_HANDLER(mtsrin, 0x1F, 0x12, 0x07, 0x001F0001, PPC_SEGMENT)
2330	79aceca5	bellard	{
2331	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2332	9fddaa0c	bellard	RET_PRIVREG(ctx);
2333	9a64fbe4	bellard	#else
2334	9a64fbe4	bellard	if (!ctx->supervisor) {
2335	9fddaa0c	bellard	RET_PRIVREG(ctx);
2336	9fddaa0c	bellard	return;
2337	9a64fbe4	bellard	}
2338	9a64fbe4	bellard	gen_op_load_gpr_T0(rS(ctx->opcode));
2339	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2340	9a64fbe4	bellard	gen_op_store_srin();
2341	9a64fbe4	bellard	#endif
2342	79aceca5	bellard	}
2343	79aceca5	bellard
2344	79aceca5	bellard	/* Lookaside buffer management */
2345	79aceca5	bellard	/* Optional & supervisor only: */
2346	79aceca5	bellard	/* tlbia */
2347	9a64fbe4	bellard	GEN_HANDLER(tlbia, 0x1F, 0x12, 0x0B, 0x03FFFC01, PPC_MEM_OPT)
2348	79aceca5	bellard	{
2349	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2350	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2351	9a64fbe4	bellard	#else
2352	9a64fbe4	bellard	if (!ctx->supervisor) {
2353	9fddaa0c	bellard	if (loglevel)
2354	9fddaa0c	bellard	fprintf(logfile, "%s: ! supervisor\n", __func__);
2355	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2356	9fddaa0c	bellard	return;
2357	9a64fbe4	bellard	}
2358	9a64fbe4	bellard	gen_op_tlbia();
2359	4b3686fa	bellard	RET_MTMSR(ctx);
2360	9a64fbe4	bellard	#endif
2361	79aceca5	bellard	}
2362	79aceca5	bellard
2363	79aceca5	bellard	/* tlbie */
2364	9a64fbe4	bellard	GEN_HANDLER(tlbie, 0x1F, 0x12, 0x09, 0x03FF0001, PPC_MEM)
2365	79aceca5	bellard	{
2366	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2367	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2368	9a64fbe4	bellard	#else
2369	9a64fbe4	bellard	if (!ctx->supervisor) {
2370	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2371	9fddaa0c	bellard	return;
2372	9a64fbe4	bellard	}
2373	9a64fbe4	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2374	9a64fbe4	bellard	gen_op_tlbie();
2375	4b3686fa	bellard	RET_MTMSR(ctx);
2376	9a64fbe4	bellard	#endif
2377	79aceca5	bellard	}
2378	79aceca5	bellard
2379	79aceca5	bellard	/* tlbsync */
2380	e63c59cb	bellard	GEN_HANDLER(tlbsync, 0x1F, 0x16, 0x11, 0x03FFF801, PPC_MEM)
2381	79aceca5	bellard	{
2382	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2383	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2384	9a64fbe4	bellard	#else
2385	9a64fbe4	bellard	if (!ctx->supervisor) {
2386	9fddaa0c	bellard	RET_PRIVOPC(ctx);
2387	9fddaa0c	bellard	return;
2388	9a64fbe4	bellard	}
2389	9a64fbe4	bellard	/* This has no effect: it should ensure that all previous
2390	9a64fbe4	bellard	* tlbie have completed
2391	9a64fbe4	bellard	*/
2392	4b3686fa	bellard	RET_MTMSR(ctx);
2393	9a64fbe4	bellard	#endif
2394	79aceca5	bellard	}
2395	79aceca5	bellard
2396	79aceca5	bellard	/* External control */
2397	79aceca5	bellard	/* Optional: */
2398	79aceca5	bellard	/* eciwx */
2399	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
2400	9a64fbe4	bellard	#define op_eciwx() gen_op_eciwx_raw()
2401	9a64fbe4	bellard	#define op_ecowx() gen_op_ecowx_raw()
2402	9a64fbe4	bellard	#else
2403	9a64fbe4	bellard	#define op_eciwx() (*gen_op_eciwx[ctx->mem_idx])()
2404	9a64fbe4	bellard	#define op_ecowx() (*gen_op_ecowx[ctx->mem_idx])()
2405	9a64fbe4	bellard	static GenOpFunc *gen_op_eciwx[] = {
2406	9a64fbe4	bellard	&gen_op_eciwx_user,
2407	9a64fbe4	bellard	&gen_op_eciwx_kernel,
2408	9a64fbe4	bellard	};
2409	9a64fbe4	bellard	static GenOpFunc *gen_op_ecowx[] = {
2410	9a64fbe4	bellard	&gen_op_ecowx_user,
2411	9a64fbe4	bellard	&gen_op_ecowx_kernel,
2412	9a64fbe4	bellard	};
2413	9a64fbe4	bellard	#endif
2414	9a64fbe4	bellard
2415	79aceca5	bellard	GEN_HANDLER(eciwx, 0x1F, 0x16, 0x0D, 0x00000001, PPC_EXTERN)
2416	79aceca5	bellard	{
2417	9a64fbe4	bellard	/* Should check EAR[E] & alignment ! */
2418	9a64fbe4	bellard	if (rA(ctx->opcode) == 0) {
2419	9a64fbe4	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2420	9a64fbe4	bellard	} else {
2421	9a64fbe4	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2422	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2423	9a64fbe4	bellard	gen_op_add();
2424	9a64fbe4	bellard	}
2425	9a64fbe4	bellard	op_eciwx();
2426	9a64fbe4	bellard	gen_op_store_T0_gpr(rD(ctx->opcode));
2427	79aceca5	bellard	}
2428	79aceca5	bellard
2429	79aceca5	bellard	/* ecowx */
2430	79aceca5	bellard	GEN_HANDLER(ecowx, 0x1F, 0x16, 0x09, 0x00000001, PPC_EXTERN)
2431	79aceca5	bellard	{
2432	9a64fbe4	bellard	/* Should check EAR[E] & alignment ! */
2433	9a64fbe4	bellard	if (rA(ctx->opcode) == 0) {
2434	9a64fbe4	bellard	gen_op_load_gpr_T0(rB(ctx->opcode));
2435	9a64fbe4	bellard	} else {
2436	9a64fbe4	bellard	gen_op_load_gpr_T0(rA(ctx->opcode));
2437	9a64fbe4	bellard	gen_op_load_gpr_T1(rB(ctx->opcode));
2438	9a64fbe4	bellard	gen_op_add();
2439	9a64fbe4	bellard	}
2440	9a64fbe4	bellard	gen_op_load_gpr_T2(rS(ctx->opcode));
2441	9a64fbe4	bellard	op_ecowx();
2442	79aceca5	bellard	}
2443	79aceca5	bellard
2444	79aceca5	bellard	/* End opcode list */
2445	79aceca5	bellard	GEN_OPCODE_MARK(end);
2446	79aceca5	bellard
2447	79aceca5	bellard	/*****************************************************************************/
2448	9a64fbe4	bellard	#include <stdlib.h>
2449	79aceca5	bellard	#include <string.h>
2450	9a64fbe4	bellard
2451	9a64fbe4	bellard	int fflush (FILE *stream);
2452	79aceca5	bellard
2453	79aceca5	bellard	/* Main ppc opcodes table:
2454	79aceca5	bellard	* at init, all opcodes are invalids
2455	79aceca5	bellard	*/
2456	79aceca5	bellard	static opc_handler_t *ppc_opcodes[0x40];
2457	79aceca5	bellard
2458	79aceca5	bellard	/* Opcode types */
2459	79aceca5	bellard	enum {
2460	79aceca5	bellard	PPC_DIRECT = 0, /* Opcode routine */
2461	79aceca5	bellard	PPC_INDIRECT = 1, /* Indirect opcode table */
2462	79aceca5	bellard	};
2463	79aceca5	bellard
2464	79aceca5	bellard	static inline int is_indirect_opcode (void *handler)
2465	79aceca5	bellard	{
2466	79aceca5	bellard	return ((unsigned long)handler & 0x03) == PPC_INDIRECT;
2467	79aceca5	bellard	}
2468	79aceca5	bellard
2469	79aceca5	bellard	static inline opc_handler_t *ind_table(void handler)
2470	79aceca5	bellard	{
2471	79aceca5	bellard	return (opc_handler_t **)((unsigned long)handler & ~3);
2472	79aceca5	bellard	}
2473	79aceca5	bellard
2474	9a64fbe4	bellard	/* Instruction table creation */
2475	79aceca5	bellard	/* Opcodes tables creation */
2476	79aceca5	bellard	static void fill_new_table (opc_handler_t **table, int len)
2477	79aceca5	bellard	{
2478	79aceca5	bellard	int i;
2479	79aceca5	bellard
2480	79aceca5	bellard	for (i = 0; i < len; i++)
2481	79aceca5	bellard	table[i] = &invalid_handler;
2482	79aceca5	bellard	}
2483	79aceca5	bellard
2484	79aceca5	bellard	static int create_new_table (opc_handler_t **table, unsigned char idx)
2485	79aceca5	bellard	{
2486	79aceca5	bellard	opc_handler_t **tmp;
2487	79aceca5	bellard
2488	79aceca5	bellard	tmp = malloc(0x20 * sizeof(opc_handler_t));
2489	79aceca5	bellard	if (tmp == NULL)
2490	79aceca5	bellard	return -1;
2491	79aceca5	bellard	fill_new_table(tmp, 0x20);
2492	79aceca5	bellard	table[idx] = (opc_handler_t *)((unsigned long)tmp \| PPC_INDIRECT);
2493	79aceca5	bellard
2494	79aceca5	bellard	return 0;
2495	79aceca5	bellard	}
2496	79aceca5	bellard
2497	79aceca5	bellard	static int insert_in_table (opc_handler_t **table, unsigned char idx,
2498	79aceca5	bellard	opc_handler_t *handler)
2499	79aceca5	bellard	{
2500	79aceca5	bellard	if (table[idx] != &invalid_handler)
2501	79aceca5	bellard	return -1;
2502	79aceca5	bellard	table[idx] = handler;
2503	79aceca5	bellard
2504	79aceca5	bellard	return 0;
2505	79aceca5	bellard	}
2506	79aceca5	bellard
2507	9a64fbe4	bellard	static int register_direct_insn (opc_handler_t **ppc_opcodes,
2508	9a64fbe4	bellard	unsigned char idx, opc_handler_t *handler)
2509	79aceca5	bellard	{
2510	79aceca5	bellard	if (insert_in_table(ppc_opcodes, idx, handler) < 0) {
2511	9a64fbe4	bellard	printf("*** ERROR: opcode %02x already assigned in main "
2512	79aceca5	bellard	"opcode table\n", idx);
2513	79aceca5	bellard	return -1;
2514	79aceca5	bellard	}
2515	79aceca5	bellard
2516	79aceca5	bellard	return 0;
2517	79aceca5	bellard	}
2518	79aceca5	bellard
2519	79aceca5	bellard	static int register_ind_in_table (opc_handler_t **table,
2520	79aceca5	bellard	unsigned char idx1, unsigned char idx2,
2521	79aceca5	bellard	opc_handler_t *handler)
2522	79aceca5	bellard	{
2523	79aceca5	bellard	if (table[idx1] == &invalid_handler) {
2524	79aceca5	bellard	if (create_new_table(table, idx1) < 0) {
2525	9a64fbe4	bellard	printf("*** ERROR: unable to create indirect table "
2526	79aceca5	bellard	"idx=%02x\n", idx1);
2527	79aceca5	bellard	return -1;
2528	79aceca5	bellard	}
2529	79aceca5	bellard	} else {
2530	79aceca5	bellard	if (!is_indirect_opcode(table[idx1])) {
2531	9a64fbe4	bellard	printf("*** ERROR: idx %02x already assigned to a direct "
2532	79aceca5	bellard	"opcode\n", idx1);
2533	79aceca5	bellard	return -1;
2534	79aceca5	bellard	}
2535	79aceca5	bellard	}
2536	79aceca5	bellard	if (handler != NULL &&
2537	79aceca5	bellard	insert_in_table(ind_table(table[idx1]), idx2, handler) < 0) {
2538	9a64fbe4	bellard	printf("*** ERROR: opcode %02x already assigned in "
2539	79aceca5	bellard	"opcode table %02x\n", idx2, idx1);
2540	79aceca5	bellard	return -1;
2541	79aceca5	bellard	}
2542	79aceca5	bellard
2543	79aceca5	bellard	return 0;
2544	79aceca5	bellard	}
2545	79aceca5	bellard
2546	9a64fbe4	bellard	static int register_ind_insn (opc_handler_t **ppc_opcodes,
2547	9a64fbe4	bellard	unsigned char idx1, unsigned char idx2,
2548	79aceca5	bellard	opc_handler_t *handler)
2549	79aceca5	bellard	{
2550	79aceca5	bellard	int ret;
2551	79aceca5	bellard
2552	79aceca5	bellard	ret = register_ind_in_table(ppc_opcodes, idx1, idx2, handler);
2553	79aceca5	bellard
2554	79aceca5	bellard	return ret;
2555	79aceca5	bellard	}
2556	79aceca5	bellard
2557	9a64fbe4	bellard	static int register_dblind_insn (opc_handler_t **ppc_opcodes,
2558	9a64fbe4	bellard	unsigned char idx1, unsigned char idx2,
2559	79aceca5	bellard	unsigned char idx3, opc_handler_t *handler)
2560	79aceca5	bellard	{
2561	79aceca5	bellard	if (register_ind_in_table(ppc_opcodes, idx1, idx2, NULL) < 0) {
2562	9a64fbe4	bellard	printf("*** ERROR: unable to join indirect table idx "
2563	79aceca5	bellard	"[%02x-%02x]\n", idx1, idx2);
2564	79aceca5	bellard	return -1;
2565	79aceca5	bellard	}
2566	79aceca5	bellard	if (register_ind_in_table(ind_table(ppc_opcodes[idx1]), idx2, idx3,
2567	79aceca5	bellard	handler) < 0) {
2568	9a64fbe4	bellard	printf("*** ERROR: unable to insert opcode "
2569	79aceca5	bellard	"[%02x-%02x-%02x]\n", idx1, idx2, idx3);
2570	79aceca5	bellard	return -1;
2571	79aceca5	bellard	}
2572	79aceca5	bellard
2573	79aceca5	bellard	return 0;
2574	79aceca5	bellard	}
2575	79aceca5	bellard
2576	9a64fbe4	bellard	static int register_insn (opc_handler_t *ppc_opcodes, opcode_t insn)
2577	79aceca5	bellard	{
2578	79aceca5	bellard	if (insn->opc2 != 0xFF) {
2579	79aceca5	bellard	if (insn->opc3 != 0xFF) {
2580	9a64fbe4	bellard	if (register_dblind_insn(ppc_opcodes, insn->opc1, insn->opc2,
2581	9a64fbe4	bellard	insn->opc3, &insn->handler) < 0)
2582	79aceca5	bellard	return -1;
2583	79aceca5	bellard	} else {
2584	9a64fbe4	bellard	if (register_ind_insn(ppc_opcodes, insn->opc1,
2585	9a64fbe4	bellard	insn->opc2, &insn->handler) < 0)
2586	79aceca5	bellard	return -1;
2587	79aceca5	bellard	}
2588	79aceca5	bellard	} else {
2589	9a64fbe4	bellard	if (register_direct_insn(ppc_opcodes, insn->opc1, &insn->handler) < 0)
2590	79aceca5	bellard	return -1;
2591	79aceca5	bellard	}
2592	79aceca5	bellard
2593	79aceca5	bellard	return 0;
2594	79aceca5	bellard	}
2595	79aceca5	bellard
2596	79aceca5	bellard	static int test_opcode_table (opc_handler_t **table, int len)
2597	79aceca5	bellard	{
2598	79aceca5	bellard	int i, count, tmp;
2599	79aceca5	bellard
2600	79aceca5	bellard	for (i = 0, count = 0; i < len; i++) {
2601	79aceca5	bellard	/* Consistency fixup */
2602	79aceca5	bellard	if (table[i] == NULL)
2603	79aceca5	bellard	table[i] = &invalid_handler;
2604	79aceca5	bellard	if (table[i] != &invalid_handler) {
2605	79aceca5	bellard	if (is_indirect_opcode(table[i])) {
2606	79aceca5	bellard	tmp = test_opcode_table(ind_table(table[i]), 0x20);
2607	79aceca5	bellard	if (tmp == 0) {
2608	79aceca5	bellard	free(table[i]);
2609	79aceca5	bellard	table[i] = &invalid_handler;
2610	79aceca5	bellard	} else {
2611	79aceca5	bellard	count++;
2612	79aceca5	bellard	}
2613	79aceca5	bellard	} else {
2614	79aceca5	bellard	count++;
2615	79aceca5	bellard	}
2616	79aceca5	bellard	}
2617	79aceca5	bellard	}
2618	79aceca5	bellard
2619	79aceca5	bellard	return count;
2620	79aceca5	bellard	}
2621	79aceca5	bellard
2622	9a64fbe4	bellard	static void fix_opcode_tables (opc_handler_t **ppc_opcodes)
2623	79aceca5	bellard	{
2624	79aceca5	bellard	if (test_opcode_table(ppc_opcodes, 0x40) == 0)
2625	9a64fbe4	bellard	printf("*** WARNING: no opcode defined !\n");
2626	79aceca5	bellard	}
2627	79aceca5	bellard
2628	9a64fbe4	bellard	#define SPR_RIGHTS(rw, priv) (1 << ((2 * (priv)) + (rw)))
2629	79aceca5	bellard	#define SPR_UR SPR_RIGHTS(0, 0)
2630	79aceca5	bellard	#define SPR_UW SPR_RIGHTS(1, 0)
2631	79aceca5	bellard	#define SPR_SR SPR_RIGHTS(0, 1)
2632	79aceca5	bellard	#define SPR_SW SPR_RIGHTS(1, 1)
2633	79aceca5	bellard
2634	79aceca5	bellard	#define spr_set_rights(spr, rights) \
2635	79aceca5	bellard	do { \
2636	79aceca5	bellard	spr_access[(spr) >> 1] \|= ((rights) << (4 * ((spr) & 1))); \
2637	79aceca5	bellard	} while (0)
2638	79aceca5	bellard
2639	9a64fbe4	bellard	static void init_spr_rights (uint32_t pvr)
2640	79aceca5	bellard	{
2641	79aceca5	bellard	/* XER (SPR 1) */
2642	9a64fbe4	bellard	spr_set_rights(XER, SPR_UR \| SPR_UW \| SPR_SR \| SPR_SW);
2643	79aceca5	bellard	/* LR (SPR 8) */
2644	9a64fbe4	bellard	spr_set_rights(LR, SPR_UR \| SPR_UW \| SPR_SR \| SPR_SW);
2645	79aceca5	bellard	/* CTR (SPR 9) */
2646	9a64fbe4	bellard	spr_set_rights(CTR, SPR_UR \| SPR_UW \| SPR_SR \| SPR_SW);
2647	79aceca5	bellard	/* TBL (SPR 268) */
2648	9a64fbe4	bellard	spr_set_rights(V_TBL, SPR_UR \| SPR_SR);
2649	79aceca5	bellard	/* TBU (SPR 269) */
2650	9a64fbe4	bellard	spr_set_rights(V_TBU, SPR_UR \| SPR_SR);
2651	79aceca5	bellard	/* DSISR (SPR 18) */
2652	9a64fbe4	bellard	spr_set_rights(DSISR, SPR_SR \| SPR_SW);
2653	79aceca5	bellard	/* DAR (SPR 19) */
2654	9a64fbe4	bellard	spr_set_rights(DAR, SPR_SR \| SPR_SW);
2655	79aceca5	bellard	/* DEC (SPR 22) */
2656	9a64fbe4	bellard	spr_set_rights(DECR, SPR_SR \| SPR_SW);
2657	79aceca5	bellard	/* SDR1 (SPR 25) */
2658	9a64fbe4	bellard	spr_set_rights(SDR1, SPR_SR \| SPR_SW);
2659	9a64fbe4	bellard	/* SRR0 (SPR 26) */
2660	9a64fbe4	bellard	spr_set_rights(SRR0, SPR_SR \| SPR_SW);
2661	9a64fbe4	bellard	/* SRR1 (SPR 27) */
2662	9a64fbe4	bellard	spr_set_rights(SRR1, SPR_SR \| SPR_SW);
2663	79aceca5	bellard	/* SPRG0 (SPR 272) */
2664	9a64fbe4	bellard	spr_set_rights(SPRG0, SPR_SR \| SPR_SW);
2665	79aceca5	bellard	/* SPRG1 (SPR 273) */
2666	9a64fbe4	bellard	spr_set_rights(SPRG1, SPR_SR \| SPR_SW);
2667	79aceca5	bellard	/* SPRG2 (SPR 274) */
2668	9a64fbe4	bellard	spr_set_rights(SPRG2, SPR_SR \| SPR_SW);
2669	79aceca5	bellard	/* SPRG3 (SPR 275) */
2670	9a64fbe4	bellard	spr_set_rights(SPRG3, SPR_SR \| SPR_SW);
2671	79aceca5	bellard	/* ASR (SPR 280) */
2672	9a64fbe4	bellard	spr_set_rights(ASR, SPR_SR \| SPR_SW);
2673	79aceca5	bellard	/* EAR (SPR 282) */
2674	9a64fbe4	bellard	spr_set_rights(EAR, SPR_SR \| SPR_SW);
2675	9a64fbe4	bellard	/* TBL (SPR 284) */
2676	9a64fbe4	bellard	spr_set_rights(O_TBL, SPR_SW);
2677	9a64fbe4	bellard	/* TBU (SPR 285) */
2678	9a64fbe4	bellard	spr_set_rights(O_TBU, SPR_SW);
2679	9a64fbe4	bellard	/* PVR (SPR 287) */
2680	9a64fbe4	bellard	spr_set_rights(PVR, SPR_SR);
2681	79aceca5	bellard	/* IBAT0U (SPR 528) */
2682	9a64fbe4	bellard	spr_set_rights(IBAT0U, SPR_SR \| SPR_SW);
2683	79aceca5	bellard	/* IBAT0L (SPR 529) */
2684	9a64fbe4	bellard	spr_set_rights(IBAT0L, SPR_SR \| SPR_SW);
2685	79aceca5	bellard	/* IBAT1U (SPR 530) */
2686	9a64fbe4	bellard	spr_set_rights(IBAT1U, SPR_SR \| SPR_SW);
2687	79aceca5	bellard	/* IBAT1L (SPR 531) */
2688	9a64fbe4	bellard	spr_set_rights(IBAT1L, SPR_SR \| SPR_SW);
2689	79aceca5	bellard	/* IBAT2U (SPR 532) */
2690	9a64fbe4	bellard	spr_set_rights(IBAT2U, SPR_SR \| SPR_SW);
2691	79aceca5	bellard	/* IBAT2L (SPR 533) */
2692	9a64fbe4	bellard	spr_set_rights(IBAT2L, SPR_SR \| SPR_SW);
2693	79aceca5	bellard	/* IBAT3U (SPR 534) */
2694	9a64fbe4	bellard	spr_set_rights(IBAT3U, SPR_SR \| SPR_SW);
2695	79aceca5	bellard	/* IBAT3L (SPR 535) */
2696	9a64fbe4	bellard	spr_set_rights(IBAT3L, SPR_SR \| SPR_SW);
2697	79aceca5	bellard	/* DBAT0U (SPR 536) */
2698	9a64fbe4	bellard	spr_set_rights(DBAT0U, SPR_SR \| SPR_SW);
2699	79aceca5	bellard	/* DBAT0L (SPR 537) */
2700	9a64fbe4	bellard	spr_set_rights(DBAT0L, SPR_SR \| SPR_SW);
2701	79aceca5	bellard	/* DBAT1U (SPR 538) */
2702	9a64fbe4	bellard	spr_set_rights(DBAT1U, SPR_SR \| SPR_SW);
2703	79aceca5	bellard	/* DBAT1L (SPR 539) */
2704	9a64fbe4	bellard	spr_set_rights(DBAT1L, SPR_SR \| SPR_SW);
2705	79aceca5	bellard	/* DBAT2U (SPR 540) */
2706	9a64fbe4	bellard	spr_set_rights(DBAT2U, SPR_SR \| SPR_SW);
2707	79aceca5	bellard	/* DBAT2L (SPR 541) */
2708	9a64fbe4	bellard	spr_set_rights(DBAT2L, SPR_SR \| SPR_SW);
2709	79aceca5	bellard	/* DBAT3U (SPR 542) */
2710	9a64fbe4	bellard	spr_set_rights(DBAT3U, SPR_SR \| SPR_SW);
2711	79aceca5	bellard	/* DBAT3L (SPR 543) */
2712	9a64fbe4	bellard	spr_set_rights(DBAT3L, SPR_SR \| SPR_SW);
2713	79aceca5	bellard	/* FPECR (SPR 1022) */
2714	9a64fbe4	bellard	spr_set_rights(FPECR, SPR_SR \| SPR_SW);
2715	4b3686fa	bellard	/* Special registers for PPC 604 */
2716	4b3686fa	bellard	if ((pvr & 0xFFFF0000) == 0x00040000) {
2717	4b3686fa	bellard	/* IABR */
2718	4b3686fa	bellard	spr_set_rights(IABR , SPR_SR \| SPR_SW);
2719	4b3686fa	bellard	/* DABR (SPR 1013) */
2720	4b3686fa	bellard	spr_set_rights(DABR, SPR_SR \| SPR_SW);
2721	4b3686fa	bellard	/* HID0 */
2722	4b3686fa	bellard	spr_set_rights(HID0, SPR_SR \| SPR_SW);
2723	4b3686fa	bellard	/* PIR */
2724	9a64fbe4	bellard	spr_set_rights(PIR, SPR_SR \| SPR_SW);
2725	4b3686fa	bellard	/* PMC1 */
2726	4b3686fa	bellard	spr_set_rights(PMC1, SPR_SR \| SPR_SW);
2727	4b3686fa	bellard	/* PMC2 */
2728	4b3686fa	bellard	spr_set_rights(PMC2, SPR_SR \| SPR_SW);
2729	4b3686fa	bellard	/* MMCR0 */
2730	4b3686fa	bellard	spr_set_rights(MMCR0, SPR_SR \| SPR_SW);
2731	4b3686fa	bellard	/* SIA */
2732	4b3686fa	bellard	spr_set_rights(SIA, SPR_SR \| SPR_SW);
2733	4b3686fa	bellard	/* SDA */
2734	4b3686fa	bellard	spr_set_rights(SDA, SPR_SR \| SPR_SW);
2735	4b3686fa	bellard	}
2736	9a64fbe4	bellard	/* Special registers for MPC740/745/750/755 (aka G3) & IBM 750 */
2737	9a64fbe4	bellard	if ((pvr & 0xFFFF0000) == 0x00080000 \|\|
2738	9a64fbe4	bellard	(pvr & 0xFFFF0000) == 0x70000000) {
2739	9a64fbe4	bellard	/* HID0 */
2740	4b3686fa	bellard	spr_set_rights(HID0, SPR_SR \| SPR_SW);
2741	9a64fbe4	bellard	/* HID1 */
2742	4b3686fa	bellard	spr_set_rights(HID1, SPR_SR \| SPR_SW);
2743	9a64fbe4	bellard	/* IABR */
2744	4b3686fa	bellard	spr_set_rights(IABR, SPR_SR \| SPR_SW);
2745	9a64fbe4	bellard	/* ICTC */
2746	4b3686fa	bellard	spr_set_rights(ICTC, SPR_SR \| SPR_SW);
2747	9a64fbe4	bellard	/* L2CR */
2748	4b3686fa	bellard	spr_set_rights(L2CR, SPR_SR \| SPR_SW);
2749	9a64fbe4	bellard	/* MMCR0 */
2750	4b3686fa	bellard	spr_set_rights(MMCR0, SPR_SR \| SPR_SW);
2751	9a64fbe4	bellard	/* MMCR1 */
2752	4b3686fa	bellard	spr_set_rights(MMCR1, SPR_SR \| SPR_SW);
2753	9a64fbe4	bellard	/* PMC1 */
2754	4b3686fa	bellard	spr_set_rights(PMC1, SPR_SR \| SPR_SW);
2755	9a64fbe4	bellard	/* PMC2 */
2756	4b3686fa	bellard	spr_set_rights(PMC2, SPR_SR \| SPR_SW);
2757	9a64fbe4	bellard	/* PMC3 */
2758	4b3686fa	bellard	spr_set_rights(PMC3, SPR_SR \| SPR_SW);
2759	9a64fbe4	bellard	/* PMC4 */
2760	4b3686fa	bellard	spr_set_rights(PMC4, SPR_SR \| SPR_SW);
2761	9a64fbe4	bellard	/* SIA */
2762	4b3686fa	bellard	spr_set_rights(SIA, SPR_SR \| SPR_SW);
2763	4b3686fa	bellard	/* SDA */
2764	4b3686fa	bellard	spr_set_rights(SDA, SPR_SR \| SPR_SW);
2765	9a64fbe4	bellard	/* THRM1 */
2766	4b3686fa	bellard	spr_set_rights(THRM1, SPR_SR \| SPR_SW);
2767	9a64fbe4	bellard	/* THRM2 */
2768	4b3686fa	bellard	spr_set_rights(THRM2, SPR_SR \| SPR_SW);
2769	9a64fbe4	bellard	/* THRM3 */
2770	4b3686fa	bellard	spr_set_rights(THRM3, SPR_SR \| SPR_SW);
2771	9a64fbe4	bellard	/* UMMCR0 */
2772	4b3686fa	bellard	spr_set_rights(UMMCR0, SPR_UR \| SPR_UW);
2773	9a64fbe4	bellard	/* UMMCR1 */
2774	4b3686fa	bellard	spr_set_rights(UMMCR1, SPR_UR \| SPR_UW);
2775	9a64fbe4	bellard	/* UPMC1 */
2776	4b3686fa	bellard	spr_set_rights(UPMC1, SPR_UR \| SPR_UW);
2777	9a64fbe4	bellard	/* UPMC2 */
2778	4b3686fa	bellard	spr_set_rights(UPMC2, SPR_UR \| SPR_UW);
2779	9a64fbe4	bellard	/* UPMC3 */
2780	4b3686fa	bellard	spr_set_rights(UPMC3, SPR_UR \| SPR_UW);
2781	9a64fbe4	bellard	/* UPMC4 */
2782	4b3686fa	bellard	spr_set_rights(UPMC4, SPR_UR \| SPR_UW);
2783	9a64fbe4	bellard	/* USIA */
2784	4b3686fa	bellard	spr_set_rights(USIA, SPR_UR \| SPR_UW);
2785	9a64fbe4	bellard	}
2786	9a64fbe4	bellard	/* MPC755 has special registers */
2787	9a64fbe4	bellard	if (pvr == 0x00083100) {
2788	9a64fbe4	bellard	/* SPRG4 */
2789	9a64fbe4	bellard	spr_set_rights(SPRG4, SPR_SR \| SPR_SW);
2790	9a64fbe4	bellard	/* SPRG5 */
2791	9a64fbe4	bellard	spr_set_rights(SPRG5, SPR_SR \| SPR_SW);
2792	9a64fbe4	bellard	/* SPRG6 */
2793	9a64fbe4	bellard	spr_set_rights(SPRG6, SPR_SR \| SPR_SW);
2794	9a64fbe4	bellard	/* SPRG7 */
2795	9a64fbe4	bellard	spr_set_rights(SPRG7, SPR_SR \| SPR_SW);
2796	9a64fbe4	bellard	/* IBAT4U */
2797	9a64fbe4	bellard	spr_set_rights(IBAT4U, SPR_SR \| SPR_SW);
2798	9a64fbe4	bellard	/* IBAT4L */
2799	9a64fbe4	bellard	spr_set_rights(IBAT4L, SPR_SR \| SPR_SW);
2800	9a64fbe4	bellard	/* IBAT5U */
2801	9a64fbe4	bellard	spr_set_rights(IBAT5U, SPR_SR \| SPR_SW);
2802	9a64fbe4	bellard	/* IBAT5L */
2803	9a64fbe4	bellard	spr_set_rights(IBAT5L, SPR_SR \| SPR_SW);
2804	9a64fbe4	bellard	/* IBAT6U */
2805	9a64fbe4	bellard	spr_set_rights(IBAT6U, SPR_SR \| SPR_SW);
2806	9a64fbe4	bellard	/* IBAT6L */
2807	9a64fbe4	bellard	spr_set_rights(IBAT6L, SPR_SR \| SPR_SW);
2808	9a64fbe4	bellard	/* IBAT7U */
2809	9a64fbe4	bellard	spr_set_rights(IBAT7U, SPR_SR \| SPR_SW);
2810	9a64fbe4	bellard	/* IBAT7L */
2811	9a64fbe4	bellard	spr_set_rights(IBAT7L, SPR_SR \| SPR_SW);
2812	9a64fbe4	bellard	/* DBAT4U */
2813	9a64fbe4	bellard	spr_set_rights(DBAT4U, SPR_SR \| SPR_SW);
2814	9a64fbe4	bellard	/* DBAT4L */
2815	9a64fbe4	bellard	spr_set_rights(DBAT4L, SPR_SR \| SPR_SW);
2816	9a64fbe4	bellard	/* DBAT5U */
2817	9a64fbe4	bellard	spr_set_rights(DBAT5U, SPR_SR \| SPR_SW);
2818	9a64fbe4	bellard	/* DBAT5L */
2819	9a64fbe4	bellard	spr_set_rights(DBAT5L, SPR_SR \| SPR_SW);
2820	9a64fbe4	bellard	/* DBAT6U */
2821	9a64fbe4	bellard	spr_set_rights(DBAT6U, SPR_SR \| SPR_SW);
2822	9a64fbe4	bellard	/* DBAT6L */
2823	9a64fbe4	bellard	spr_set_rights(DBAT6L, SPR_SR \| SPR_SW);
2824	9a64fbe4	bellard	/* DBAT7U */
2825	9a64fbe4	bellard	spr_set_rights(DBAT7U, SPR_SR \| SPR_SW);
2826	9a64fbe4	bellard	/* DBAT7L */
2827	9a64fbe4	bellard	spr_set_rights(DBAT7L, SPR_SR \| SPR_SW);
2828	9a64fbe4	bellard	/* DMISS */
2829	4b3686fa	bellard	spr_set_rights(DMISS, SPR_SR \| SPR_SW);
2830	9a64fbe4	bellard	/* DCMP */
2831	4b3686fa	bellard	spr_set_rights(DCMP, SPR_SR \| SPR_SW);
2832	9a64fbe4	bellard	/* DHASH1 */
2833	4b3686fa	bellard	spr_set_rights(DHASH1, SPR_SR \| SPR_SW);
2834	9a64fbe4	bellard	/* DHASH2 */
2835	4b3686fa	bellard	spr_set_rights(DHASH2, SPR_SR \| SPR_SW);
2836	9a64fbe4	bellard	/* IMISS */
2837	4b3686fa	bellard	spr_set_rights(IMISS, SPR_SR \| SPR_SW);
2838	9a64fbe4	bellard	/* ICMP */
2839	4b3686fa	bellard	spr_set_rights(ICMP, SPR_SR \| SPR_SW);
2840	9a64fbe4	bellard	/* RPA */
2841	4b3686fa	bellard	spr_set_rights(RPA, SPR_SR \| SPR_SW);
2842	9a64fbe4	bellard	/* HID2 */
2843	4b3686fa	bellard	spr_set_rights(HID2, SPR_SR \| SPR_SW);
2844	9a64fbe4	bellard	/* L2PM */
2845	4b3686fa	bellard	spr_set_rights(L2PM, SPR_SR \| SPR_SW);
2846	9a64fbe4	bellard	}
2847	79aceca5	bellard	}
2848	79aceca5	bellard
2849	9a64fbe4	bellard	/*****************************************************************************/
2850	9a64fbe4	bellard	/* PPC "main stream" common instructions (no optional ones) */
2851	79aceca5	bellard
2852	79aceca5	bellard	typedef struct ppc_proc_t {
2853	79aceca5	bellard	int flags;
2854	79aceca5	bellard	void *specific;
2855	79aceca5	bellard	} ppc_proc_t;
2856	79aceca5	bellard
2857	79aceca5	bellard	typedef struct ppc_def_t {
2858	79aceca5	bellard	unsigned long pvr;
2859	79aceca5	bellard	unsigned long pvr_mask;
2860	79aceca5	bellard	ppc_proc_t *proc;
2861	79aceca5	bellard	} ppc_def_t;
2862	79aceca5	bellard
2863	79aceca5	bellard	static ppc_proc_t ppc_proc_common = {
2864	79aceca5	bellard	.flags = PPC_COMMON,
2865	79aceca5	bellard	.specific = NULL,
2866	79aceca5	bellard	};
2867	79aceca5	bellard
2868	9a64fbe4	bellard	static ppc_proc_t ppc_proc_G3 = {
2869	9a64fbe4	bellard	.flags = PPC_750,
2870	9a64fbe4	bellard	.specific = NULL,
2871	9a64fbe4	bellard	};
2872	9a64fbe4	bellard
2873	79aceca5	bellard	static ppc_def_t ppc_defs[] =
2874	79aceca5	bellard	{
2875	9a64fbe4	bellard	/* MPC740/745/750/755 (G3) */
2876	9a64fbe4	bellard	{
2877	9a64fbe4	bellard	.pvr = 0x00080000,
2878	9a64fbe4	bellard	.pvr_mask = 0xFFFF0000,
2879	9a64fbe4	bellard	.proc = &ppc_proc_G3,
2880	9a64fbe4	bellard	},
2881	9a64fbe4	bellard	/* IBM 750FX (G3 embedded) */
2882	9a64fbe4	bellard	{
2883	9a64fbe4	bellard	.pvr = 0x70000000,
2884	9a64fbe4	bellard	.pvr_mask = 0xFFFF0000,
2885	9a64fbe4	bellard	.proc = &ppc_proc_G3,
2886	9a64fbe4	bellard	},
2887	9a64fbe4	bellard	/* Fallback (generic PPC) */
2888	79aceca5	bellard	{
2889	79aceca5	bellard	.pvr = 0x00000000,
2890	79aceca5	bellard	.pvr_mask = 0x00000000,
2891	79aceca5	bellard	.proc = &ppc_proc_common,
2892	79aceca5	bellard	},
2893	79aceca5	bellard	};
2894	79aceca5	bellard
2895	9a64fbe4	bellard	static int create_ppc_proc (opc_handler_t **ppc_opcodes, unsigned long pvr)
2896	79aceca5	bellard	{
2897	79aceca5	bellard	opcode_t *opc;
2898	79aceca5	bellard	int i, flags;
2899	79aceca5	bellard
2900	79aceca5	bellard	fill_new_table(ppc_opcodes, 0x40);
2901	79aceca5	bellard	for (i = 0; ; i++) {
2902	79aceca5	bellard	if ((ppc_defs[i].pvr & ppc_defs[i].pvr_mask) ==
2903	79aceca5	bellard	(pvr & ppc_defs[i].pvr_mask)) {
2904	79aceca5	bellard	flags = ppc_defs[i].proc->flags;
2905	79aceca5	bellard	break;
2906	79aceca5	bellard	}
2907	79aceca5	bellard	}
2908	79aceca5	bellard
2909	79aceca5	bellard	for (opc = &opc_start + 1; opc != &opc_end; opc++) {
2910	9a64fbe4	bellard	if ((opc->handler.type & flags) != 0)
2911	9a64fbe4	bellard	if (register_insn(ppc_opcodes, opc) < 0) {
2912	9a64fbe4	bellard	printf("*** ERROR initializing PPC instruction "
2913	79aceca5	bellard	"0x%02x 0x%02x 0x%02x\n", opc->opc1, opc->opc2,
2914	79aceca5	bellard	opc->opc3);
2915	79aceca5	bellard	return -1;
2916	79aceca5	bellard	}
2917	79aceca5	bellard	}
2918	9a64fbe4	bellard	fix_opcode_tables(ppc_opcodes);
2919	79aceca5	bellard
2920	79aceca5	bellard	return 0;
2921	79aceca5	bellard	}
2922	79aceca5	bellard
2923	9a64fbe4	bellard
2924	79aceca5	bellard	/*****************************************************************************/
2925	9a64fbe4	bellard	/* Misc PPC helpers */
2926	79aceca5	bellard
2927	7fe48483	bellard	void cpu_dump_state(CPUState env, FILE f,
2928	7fe48483	bellard	int (cpu_fprintf)(FILE f, const char *fmt, ...),
2929	7fe48483	bellard	int flags)
2930	79aceca5	bellard	{
2931	79aceca5	bellard	int i;
2932	79aceca5	bellard
2933	7fe48483	bellard	cpu_fprintf(f, "nip=0x%08x LR=0x%08x CTR=0x%08x XER=0x%08x "
2934	9a64fbe4	bellard	"MSR=0x%08x\n", env->nip, env->lr, env->ctr,
2935	a541f297	bellard	_load_xer(env), _load_msr(env));
2936	79aceca5	bellard	for (i = 0; i < 32; i++) {
2937	79aceca5	bellard	if ((i & 7) == 0)
2938	7fe48483	bellard	cpu_fprintf(f, "GPR%02d:", i);
2939	7fe48483	bellard	cpu_fprintf(f, " %08x", env->gpr[i]);
2940	79aceca5	bellard	if ((i & 7) == 7)
2941	7fe48483	bellard	cpu_fprintf(f, "\n");
2942	79aceca5	bellard	}
2943	7fe48483	bellard	cpu_fprintf(f, "CR: 0x");
2944	79aceca5	bellard	for (i = 0; i < 8; i++)
2945	7fe48483	bellard	cpu_fprintf(f, "%01x", env->crf[i]);
2946	7fe48483	bellard	cpu_fprintf(f, " [");
2947	79aceca5	bellard	for (i = 0; i < 8; i++) {
2948	79aceca5	bellard	char a = '-';
2949	79aceca5	bellard	if (env->crf[i] & 0x08)
2950	79aceca5	bellard	a = 'L';
2951	79aceca5	bellard	else if (env->crf[i] & 0x04)
2952	79aceca5	bellard	a = 'G';
2953	79aceca5	bellard	else if (env->crf[i] & 0x02)
2954	79aceca5	bellard	a = 'E';
2955	7fe48483	bellard	cpu_fprintf(f, " %c%c", a, env->crf[i] & 0x01 ? 'O' : ' ');
2956	79aceca5	bellard	}
2957	7fe48483	bellard	cpu_fprintf(f, " ] ");
2958	7fe48483	bellard	cpu_fprintf(f, "TB: 0x%08x %08x\n", cpu_ppc_load_tbu(env),
2959	9fddaa0c	bellard	cpu_ppc_load_tbl(env));
2960	79aceca5	bellard	for (i = 0; i < 16; i++) {
2961	79aceca5	bellard	if ((i & 3) == 0)
2962	7fe48483	bellard	cpu_fprintf(f, "FPR%02d:", i);
2963	7fe48483	bellard	cpu_fprintf(f, " %016llx", ((uint64_t )&env->fpr[i]));
2964	79aceca5	bellard	if ((i & 3) == 3)
2965	7fe48483	bellard	cpu_fprintf(f, "\n");
2966	79aceca5	bellard	}
2967	7fe48483	bellard	cpu_fprintf(f, "SRR0 0x%08x SRR1 0x%08x DECR=0x%08x\n",
2968	9fddaa0c	bellard	env->spr[SRR0], env->spr[SRR1], cpu_ppc_load_decr(env));
2969	7fe48483	bellard	cpu_fprintf(f, "reservation 0x%08x\n", env->reserve);
2970	79aceca5	bellard	}
2971	79aceca5	bellard
2972	9a64fbe4	bellard	#if !defined(CONFIG_USER_ONLY) && defined (USE_OPENFIRMWARE)
2973	9a64fbe4	bellard	int setup_machine (CPUPPCState *env, uint32_t mid);
2974	9a64fbe4	bellard	#endif
2975	9a64fbe4	bellard
2976	79aceca5	bellard	CPUPPCState *cpu_ppc_init(void)
2977	79aceca5	bellard	{
2978	79aceca5	bellard	CPUPPCState *env;
2979	79aceca5	bellard
2980	79aceca5	bellard	cpu_exec_init();
2981	79aceca5	bellard
2982	4b3686fa	bellard	env = qemu_mallocz(sizeof(CPUPPCState));
2983	79aceca5	bellard	if (!env)
2984	79aceca5	bellard	return NULL;
2985	9a64fbe4	bellard	#if !defined(CONFIG_USER_ONLY) && defined (USE_OPEN_FIRMWARE)
2986	9a64fbe4	bellard	setup_machine(env, 0);
2987	9a64fbe4	bellard	#else
2988	9a64fbe4	bellard	// env->spr[PVR] = 0; /* Basic PPC */
2989	9a64fbe4	bellard	env->spr[PVR] = 0x00080100; /* G3 CPU */
2990	9a64fbe4	bellard	// env->spr[PVR] = 0x00083100; /* MPC755 (G3 embedded) */
2991	9a64fbe4	bellard	// env->spr[PVR] = 0x00070100; /* IBM 750FX */
2992	9a64fbe4	bellard	#endif
2993	ad081323	bellard	tlb_flush(env, 1);
2994	9a64fbe4	bellard	#if defined (DO_SINGLE_STEP)
2995	9a64fbe4	bellard	/* Single step trace mode */
2996	9a64fbe4	bellard	msr_se = 1;
2997	9a64fbe4	bellard	#endif
2998	4b3686fa	bellard	msr_fp = 1; /* Allow floating point exceptions */
2999	4b3686fa	bellard	msr_me = 1; /* Allow machine check exceptions */
3000	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
3001	9a64fbe4	bellard	msr_pr = 1;
3002	4b3686fa	bellard	cpu_ppc_register(env, 0x00080000);
3003	4b3686fa	bellard	#else
3004	4b3686fa	bellard	env->nip = 0xFFFFFFFC;
3005	9a64fbe4	bellard	#endif
3006	7496f526	bellard	cpu_single_env = env;
3007	79aceca5	bellard	return env;
3008	79aceca5	bellard	}
3009	79aceca5	bellard
3010	4b3686fa	bellard	int cpu_ppc_register (CPUPPCState *env, uint32_t pvr)
3011	4b3686fa	bellard	{
3012	4b3686fa	bellard	env->spr[PVR] = pvr;
3013	4b3686fa	bellard	if (create_ppc_proc(ppc_opcodes, env->spr[PVR]) < 0)
3014	4b3686fa	bellard	return -1;
3015	4b3686fa	bellard	init_spr_rights(env->spr[PVR]);
3016	4b3686fa	bellard
3017	4b3686fa	bellard	return 0;
3018	4b3686fa	bellard	}
3019	4b3686fa	bellard
3020	79aceca5	bellard	void cpu_ppc_close(CPUPPCState *env)
3021	79aceca5	bellard	{
3022	79aceca5	bellard	/* Should also remove all opcode tables... */
3023	79aceca5	bellard	free(env);
3024	79aceca5	bellard	}
3025	79aceca5	bellard
3026	9a64fbe4	bellard	/*****************************************************************************/
3027	79aceca5	bellard	int gen_intermediate_code_internal (CPUState env, TranslationBlock tb,
3028	79aceca5	bellard	int search_pc)
3029	79aceca5	bellard	{
3030	9fddaa0c	bellard	DisasContext ctx, *ctxp = &ctx;
3031	79aceca5	bellard	opc_handler_t *table, handler;
3032	0fa85d43	bellard	target_ulong pc_start;
3033	79aceca5	bellard	uint16_t *gen_opc_end;
3034	79aceca5	bellard	int j, lj = -1;
3035	79aceca5	bellard
3036	79aceca5	bellard	pc_start = tb->pc;
3037	79aceca5	bellard	gen_opc_ptr = gen_opc_buf;
3038	79aceca5	bellard	gen_opc_end = gen_opc_buf + OPC_MAX_SIZE;
3039	79aceca5	bellard	gen_opparam_ptr = gen_opparam_buf;
3040	046d6672	bellard	ctx.nip = pc_start;
3041	79aceca5	bellard	ctx.tb = tb;
3042	9a64fbe4	bellard	ctx.exception = EXCP_NONE;
3043	9a64fbe4	bellard	#if defined(CONFIG_USER_ONLY)
3044	9a64fbe4	bellard	ctx.mem_idx = 0;
3045	9a64fbe4	bellard	#else
3046	9a64fbe4	bellard	ctx.supervisor = 1 - msr_pr;
3047	9a64fbe4	bellard	ctx.mem_idx = (1 - msr_pr);
3048	9a64fbe4	bellard	#endif
3049	9a64fbe4	bellard	#if defined (DO_SINGLE_STEP)
3050	9a64fbe4	bellard	/* Single step trace mode */
3051	9a64fbe4	bellard	msr_se = 1;
3052	9a64fbe4	bellard	#endif
3053	9a64fbe4	bellard	/* Set env in case of segfault during code fetch */
3054	9a64fbe4	bellard	while (ctx.exception == EXCP_NONE && gen_opc_ptr < gen_opc_end) {
3055	79aceca5	bellard	if (search_pc) {
3056	79aceca5	bellard	j = gen_opc_ptr - gen_opc_buf;
3057	79aceca5	bellard	if (lj < j) {
3058	79aceca5	bellard	lj++;
3059	79aceca5	bellard	while (lj < j)
3060	79aceca5	bellard	gen_opc_instr_start[lj++] = 0;
3061	046d6672	bellard	gen_opc_pc[lj] = ctx.nip;
3062	79aceca5	bellard	gen_opc_instr_start[lj] = 1;
3063	79aceca5	bellard	}
3064	79aceca5	bellard	}
3065	9fddaa0c	bellard	#if defined PPC_DEBUG_DISAS
3066	9fddaa0c	bellard	if (loglevel & CPU_LOG_TB_IN_ASM) {
3067	79aceca5	bellard	fprintf(logfile, "----------------\n");
3068	046d6672	bellard	fprintf(logfile, "nip=%08x super=%d ir=%d\n",
3069	9a64fbe4	bellard	ctx.nip, 1 - msr_pr, msr_ir);
3070	9a64fbe4	bellard	}
3071	9a64fbe4	bellard	#endif
3072	0fa85d43	bellard	ctx.opcode = ldl_code(ctx.nip);
3073	9fddaa0c	bellard	#if defined PPC_DEBUG_DISAS
3074	9fddaa0c	bellard	if (loglevel & CPU_LOG_TB_IN_ASM) {
3075	9a64fbe4	bellard	fprintf(logfile, "translate opcode %08x (%02x %02x %02x)\n",
3076	9a64fbe4	bellard	ctx.opcode, opc1(ctx.opcode), opc2(ctx.opcode),
3077	9a64fbe4	bellard	opc3(ctx.opcode));
3078	79aceca5	bellard	}
3079	79aceca5	bellard	#endif
3080	046d6672	bellard	ctx.nip += 4;
3081	79aceca5	bellard	table = ppc_opcodes;
3082	79aceca5	bellard	handler = table[opc1(ctx.opcode)];
3083	79aceca5	bellard	if (is_indirect_opcode(handler)) {
3084	79aceca5	bellard	table = ind_table(handler);
3085	79aceca5	bellard	handler = table[opc2(ctx.opcode)];
3086	79aceca5	bellard	if (is_indirect_opcode(handler)) {
3087	79aceca5	bellard	table = ind_table(handler);
3088	79aceca5	bellard	handler = table[opc3(ctx.opcode)];
3089	79aceca5	bellard	}
3090	79aceca5	bellard	}
3091	79aceca5	bellard	/* Is opcode REALLY valid ? */
3092	79aceca5	bellard	if (handler->handler == &gen_invalid) {
3093	4b3686fa	bellard	if (loglevel > 0) {
3094	79aceca5	bellard	fprintf(logfile, "invalid/unsupported opcode: "
3095	4b3686fa	bellard	"%02x - %02x - %02x (%08x) 0x%08x %d\n",
3096	9a64fbe4	bellard	opc1(ctx.opcode), opc2(ctx.opcode),
3097	4b3686fa	bellard	opc3(ctx.opcode), ctx.opcode, ctx.nip - 4, msr_ir);
3098	4b3686fa	bellard	} else {
3099	4b3686fa	bellard	printf("invalid/unsupported opcode: "
3100	4b3686fa	bellard	"%02x - %02x - %02x (%08x) 0x%08x %d\n",
3101	4b3686fa	bellard	opc1(ctx.opcode), opc2(ctx.opcode),
3102	4b3686fa	bellard	opc3(ctx.opcode), ctx.opcode, ctx.nip - 4, msr_ir);
3103	4b3686fa	bellard	}
3104	79aceca5	bellard	} else {
3105	4b3686fa	bellard	if ((ctx.opcode & handler->inval) != 0) {
3106	4b3686fa	bellard	if (loglevel > 0) {
3107	79aceca5	bellard	fprintf(logfile, "invalid bits: %08x for opcode: "
3108	046d6672	bellard	"%02x -%02x - %02x (0x%08x) (0x%08x)\n",
3109	79aceca5	bellard	ctx.opcode & handler->inval, opc1(ctx.opcode),
3110	79aceca5	bellard	opc2(ctx.opcode), opc3(ctx.opcode),
3111	046d6672	bellard	ctx.opcode, ctx.nip - 4);
3112	9a64fbe4	bellard	} else {
3113	9a64fbe4	bellard	printf("invalid bits: %08x for opcode: "
3114	046d6672	bellard	"%02x -%02x - %02x (0x%08x) (0x%08x)\n",
3115	9a64fbe4	bellard	ctx.opcode & handler->inval, opc1(ctx.opcode),
3116	9a64fbe4	bellard	opc2(ctx.opcode), opc3(ctx.opcode),
3117	046d6672	bellard	ctx.opcode, ctx.nip - 4);
3118	9a64fbe4	bellard	}
3119	4b3686fa	bellard	RET_INVAL(ctxp);
3120	4b3686fa	bellard	break;
3121	79aceca5	bellard	}
3122	79aceca5	bellard	}
3123	4b3686fa	bellard	(*(handler->handler))(&ctx);
3124	9a64fbe4	bellard	/* Check trace mode exceptions */
3125	9a64fbe4	bellard	if ((msr_be && ctx.exception == EXCP_BRANCH) \|\|
3126	9a64fbe4	bellard	/* Check in single step trace mode
3127	9a64fbe4	bellard	* we need to stop except if:
3128	9a64fbe4	bellard	* - rfi, trap or syscall
3129	9a64fbe4	bellard	* - first instruction of an exception handler
3130	9a64fbe4	bellard	*/
3131	046d6672	bellard	(msr_se && (ctx.nip < 0x100 \|\|
3132	046d6672	bellard	ctx.nip > 0xF00 \|\|
3133	046d6672	bellard	(ctx.nip & 0xFC) != 0x04) &&
3134	9a64fbe4	bellard	ctx.exception != EXCP_SYSCALL && ctx.exception != EXCP_RFI &&
3135	9a64fbe4	bellard	ctx.exception != EXCP_TRAP)) {
3136	9fddaa0c	bellard	RET_EXCP(ctxp, EXCP_TRACE, 0);
3137	9a64fbe4	bellard	}
3138	a541f297	bellard	/* if we reach a page boundary, stop generation */
3139	046d6672	bellard	if ((ctx.nip & (TARGET_PAGE_SIZE - 1)) == 0) {
3140	9fddaa0c	bellard	RET_EXCP(ctxp, EXCP_BRANCH, 0);
3141	79aceca5	bellard	}
3142	9a64fbe4	bellard	}
3143	9fddaa0c	bellard	if (ctx.exception == EXCP_NONE) {
3144	9fddaa0c	bellard	gen_op_b((unsigned long)ctx.tb, ctx.nip);
3145	9fddaa0c	bellard	} else if (ctx.exception != EXCP_BRANCH) {
3146	9fddaa0c	bellard	gen_op_set_T0(0);
3147	9a64fbe4	bellard	}
3148	9a64fbe4	bellard	#if 1
3149	79aceca5	bellard	/* TO BE FIXED: T0 hasn't got a proper value, which makes tb_add_jump
3150	79aceca5	bellard	* do bad business and then qemu crashes !
3151	79aceca5	bellard	*/
3152	79aceca5	bellard	gen_op_set_T0(0);
3153	9a64fbe4	bellard	#endif
3154	79aceca5	bellard	/* Generate the return instruction */
3155	79aceca5	bellard	gen_op_exit_tb();
3156	79aceca5	bellard	*gen_opc_ptr = INDEX_op_end;
3157	9a64fbe4	bellard	if (search_pc) {
3158	9a64fbe4	bellard	j = gen_opc_ptr - gen_opc_buf;
3159	9a64fbe4	bellard	lj++;
3160	9a64fbe4	bellard	while (lj <= j)
3161	9a64fbe4	bellard	gen_opc_instr_start[lj++] = 0;
3162	79aceca5	bellard	tb->size = 0;
3163	985a19d6	bellard	#if 0
3164	9a64fbe4	bellard	if (loglevel > 0) {
3165	9a64fbe4	bellard	page_dump(logfile);
3166	9a64fbe4	bellard	}
3167	985a19d6	bellard	#endif
3168	9a64fbe4	bellard	} else {
3169	046d6672	bellard	tb->size = ctx.nip - pc_start;
3170	9a64fbe4	bellard	}
3171	79aceca5	bellard	#ifdef DEBUG_DISAS
3172	9fddaa0c	bellard	if (loglevel & CPU_LOG_TB_CPU) {
3173	9a64fbe4	bellard	fprintf(logfile, "---------------- excp: %04x\n", ctx.exception);
3174	7fe48483	bellard	cpu_dump_state(env, logfile, fprintf, 0);
3175	9fddaa0c	bellard	}
3176	9fddaa0c	bellard	if (loglevel & CPU_LOG_TB_IN_ASM) {
3177	0fa85d43	bellard	fprintf(logfile, "IN: %s\n", lookup_symbol(pc_start));
3178	0fa85d43	bellard	target_disas(logfile, pc_start, ctx.nip - pc_start, 0);
3179	79aceca5	bellard	fprintf(logfile, "\n");
3180	9fddaa0c	bellard	}
3181	9fddaa0c	bellard	if (loglevel & CPU_LOG_TB_OP) {
3182	79aceca5	bellard	fprintf(logfile, "OP:\n");
3183	79aceca5	bellard	dump_ops(gen_opc_buf, gen_opparam_buf);
3184	79aceca5	bellard	fprintf(logfile, "\n");
3185	79aceca5	bellard	}
3186	79aceca5	bellard	#endif
3187	79aceca5	bellard	return 0;
3188	79aceca5	bellard	}
3189	79aceca5	bellard
3190	9a64fbe4	bellard	int gen_intermediate_code (CPUState env, struct TranslationBlock tb)
3191	79aceca5	bellard	{
3192	79aceca5	bellard	return gen_intermediate_code_internal(env, tb, 0);
3193	79aceca5	bellard	}
3194	79aceca5	bellard
3195	9a64fbe4	bellard	int gen_intermediate_code_pc (CPUState env, struct TranslationBlock tb)
3196	79aceca5	bellard	{
3197	79aceca5	bellard	return gen_intermediate_code_internal(env, tb, 1);
3198	79aceca5	bellard	}

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