1	/*
2	* Copyright 2005 Nicolai Haehnle et al.
3	* Copyright 2008 Advanced Micro Devices, Inc.
4	* Copyright 2009 Jerome Glisse.
5	*
6	* Permission is hereby granted, free of charge, to any person obtaining a
7	* copy of this software and associated documentation files (the "Software"),
8	* to deal in the Software without restriction, including without limitation
9	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
10	* and/or sell copies of the Software, and to permit persons to whom the
11	* Software is furnished to do so, subject to the following conditions:
12	*
13	* The above copyright notice and this permission notice shall be included in
14	* all copies or substantial portions of the Software.
15	*
16	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
17	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
18	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
19	* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
20	* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
21	* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
22	* OTHER DEALINGS IN THE SOFTWARE.
23	*
24	* Authors: Nicolai Haehnle
25	* Jerome Glisse
26	*/
27	#ifndef _R300_REG_H_
28	#define _R300_REG_H_
29
30	#define R300_SURF_TILE_MACRO (1<<16)
31	#define R300_SURF_TILE_MICRO (2<<16)
32	#define R300_SURF_TILE_BOTH (3<<16)
33
34
35	#define R300_MC_INIT_MISC_LAT_TIMER 0x180
36	# define R300_MC_MISC__MC_CPR_INIT_LAT_SHIFT 0
37	# define R300_MC_MISC__MC_VF_INIT_LAT_SHIFT 4
38	# define R300_MC_MISC__MC_DISP0R_INIT_LAT_SHIFT 8
39	# define R300_MC_MISC__MC_DISP1R_INIT_LAT_SHIFT 12
40	# define R300_MC_MISC__MC_FIXED_INIT_LAT_SHIFT 16
41	# define R300_MC_MISC__MC_E2R_INIT_LAT_SHIFT 20
42	# define R300_MC_MISC__MC_SAME_PAGE_PRIO_SHIFT 24
43	# define R300_MC_MISC__MC_GLOBW_INIT_LAT_SHIFT 28
44
45	#define R300_MC_INIT_GFX_LAT_TIMER 0x154
46	# define R300_MC_MISC__MC_G3D0R_INIT_LAT_SHIFT 0
47	# define R300_MC_MISC__MC_G3D1R_INIT_LAT_SHIFT 4
48	# define R300_MC_MISC__MC_G3D2R_INIT_LAT_SHIFT 8
49	# define R300_MC_MISC__MC_G3D3R_INIT_LAT_SHIFT 12
50	# define R300_MC_MISC__MC_TX0R_INIT_LAT_SHIFT 16
51	# define R300_MC_MISC__MC_TX1R_INIT_LAT_SHIFT 20
52	# define R300_MC_MISC__MC_GLOBR_INIT_LAT_SHIFT 24
53	# define R300_MC_MISC__MC_GLOBW_FULL_LAT_SHIFT 28
54
55	/*
56	* This file contains registers and constants for the R300. They have been
57	* found mostly by examining command buffers captured using glxtest, as well
58	* as by extrapolating some known registers and constants from the R200.
59	* I am fairly certain that they are correct unless stated otherwise
60	* in comments.
61	*/
62
63	#define R300_SE_VPORT_XSCALE 0x1D98
64	#define R300_SE_VPORT_XOFFSET 0x1D9C
65	#define R300_SE_VPORT_YSCALE 0x1DA0
66	#define R300_SE_VPORT_YOFFSET 0x1DA4
67	#define R300_SE_VPORT_ZSCALE 0x1DA8
68	#define R300_SE_VPORT_ZOFFSET 0x1DAC
69
70
71	/*
72	* Vertex Array Processing (VAP) Control
73	* Stolen from r200 code from Christoph Brill (It's a guess!)
74	*/
75	#define R300_VAP_CNTL 0x2080
76
77	/* This register is written directly and also starts data section
78	* in many 3d CP_PACKET3's
79	*/
80	#define R300_VAP_VF_CNTL 0x2084
81	# define R300_VAP_VF_CNTL__PRIM_TYPE__SHIFT 0
82	# define R300_VAP_VF_CNTL__PRIM_NONE (0<<0)
83	# define R300_VAP_VF_CNTL__PRIM_POINTS (1<<0)
84	# define R300_VAP_VF_CNTL__PRIM_LINES (2<<0)
85	# define R300_VAP_VF_CNTL__PRIM_LINE_STRIP (3<<0)
86	# define R300_VAP_VF_CNTL__PRIM_TRIANGLES (4<<0)
87	# define R300_VAP_VF_CNTL__PRIM_TRIANGLE_FAN (5<<0)
88	# define R300_VAP_VF_CNTL__PRIM_TRIANGLE_STRIP (6<<0)
89	# define R300_VAP_VF_CNTL__PRIM_LINE_LOOP (12<<0)
90	# define R300_VAP_VF_CNTL__PRIM_QUADS (13<<0)
91	# define R300_VAP_VF_CNTL__PRIM_QUAD_STRIP (14<<0)
92	# define R300_VAP_VF_CNTL__PRIM_POLYGON (15<<0)
93
94	# define R300_VAP_VF_CNTL__PRIM_WALK__SHIFT 4
95	/* State based - direct writes to registers trigger vertex
96	generation */
97	# define R300_VAP_VF_CNTL__PRIM_WALK_STATE_BASED (0<<4)
98	# define R300_VAP_VF_CNTL__PRIM_WALK_INDICES (1<<4)
99	# define R300_VAP_VF_CNTL__PRIM_WALK_VERTEX_LIST (2<<4)
100	# define R300_VAP_VF_CNTL__PRIM_WALK_VERTEX_EMBEDDED (3<<4)
101
102	/* I don't think I saw these three used.. */
103	# define R300_VAP_VF_CNTL__COLOR_ORDER__SHIFT 6
104	# define R300_VAP_VF_CNTL__TCL_OUTPUT_CTL_ENA__SHIFT 9
105	# define R300_VAP_VF_CNTL__PROG_STREAM_ENA__SHIFT 10
106
107	/* index size - when not set the indices are assumed to be 16 bit */
108	# define R300_VAP_VF_CNTL__INDEX_SIZE_32bit (1<<11)
109	/* number of vertices */
110	# define R300_VAP_VF_CNTL__NUM_VERTICES__SHIFT 16
111
112	/* BEGIN: Wild guesses */
113	#define R300_VAP_OUTPUT_VTX_FMT_0 0x2090
114	# define R300_VAP_OUTPUT_VTX_FMT_0__POS_PRESENT (1<<0)
115	# define R300_VAP_OUTPUT_VTX_FMT_0__COLOR_PRESENT (1<<1)
116	# define R300_VAP_OUTPUT_VTX_FMT_0__COLOR_1_PRESENT (1<<2) /* GUESS */
117	# define R300_VAP_OUTPUT_VTX_FMT_0__COLOR_2_PRESENT (1<<3) /* GUESS */
118	# define R300_VAP_OUTPUT_VTX_FMT_0__COLOR_3_PRESENT (1<<4) /* GUESS */
119	# define R300_VAP_OUTPUT_VTX_FMT_0__PT_SIZE_PRESENT (1<<16) /* GUESS */
120
121	#define R300_VAP_OUTPUT_VTX_FMT_1 0x2094
122	/* each of the following is 3 bits wide, specifies number
123	of components */
124	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_0_COMP_CNT_SHIFT 0
125	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_1_COMP_CNT_SHIFT 3
126	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_2_COMP_CNT_SHIFT 6
127	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_3_COMP_CNT_SHIFT 9
128	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_4_COMP_CNT_SHIFT 12
129	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_5_COMP_CNT_SHIFT 15
130	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_6_COMP_CNT_SHIFT 18
131	# define R300_VAP_OUTPUT_VTX_FMT_1__TEX_7_COMP_CNT_SHIFT 21
132	/* END: Wild guesses */
133
134	#define R300_SE_VTE_CNTL 0x20b0
135	# define R300_VPORT_X_SCALE_ENA 0x00000001
136	# define R300_VPORT_X_OFFSET_ENA 0x00000002
137	# define R300_VPORT_Y_SCALE_ENA 0x00000004
138	# define R300_VPORT_Y_OFFSET_ENA 0x00000008
139	# define R300_VPORT_Z_SCALE_ENA 0x00000010
140	# define R300_VPORT_Z_OFFSET_ENA 0x00000020
141	# define R300_VTX_XY_FMT 0x00000100
142	# define R300_VTX_Z_FMT 0x00000200
143	# define R300_VTX_W0_FMT 0x00000400
144	# define R300_VTX_W0_NORMALIZE 0x00000800
145	# define R300_VTX_ST_DENORMALIZED 0x00001000
146
147	/* BEGIN: Vertex data assembly - lots of uncertainties */
148
149	/* gap */
150
151	#define R300_VAP_CNTL_STATUS 0x2140
152	# define R300_VC_NO_SWAP (0 << 0)
153	# define R300_VC_16BIT_SWAP (1 << 0)
154	# define R300_VC_32BIT_SWAP (2 << 0)
155	# define R300_VAP_TCL_BYPASS (1 << 8)
156
157	/* gap */
158
159	/* Where do we get our vertex data?
160	*
161	* Vertex data either comes either from immediate mode registers or from
162	* vertex arrays.
163	* There appears to be no mixed mode (though we can force the pitch of
164	* vertex arrays to 0, effectively reusing the same element over and over
165	* again).
166	*
167	* Immediate mode is controlled by the INPUT_CNTL registers. I am not sure
168	* if these registers influence vertex array processing.
169	*
170	* Vertex arrays are controlled via the 3D_LOAD_VBPNTR packet3.
171	*
172	* In both cases, vertex attributes are then passed through INPUT_ROUTE.
173	*
174	* Beginning with INPUT_ROUTE_0_0 is a list of WORDs that route vertex data
175	* into the vertex processor's input registers.
176	* The first word routes the first input, the second word the second, etc.
177	* The corresponding input is routed into the register with the given index.
178	* The list is ended by a word with INPUT_ROUTE_END set.
179	*
180	* Always set COMPONENTS_4 in immediate mode.
181	*/
182
183	#define R300_VAP_INPUT_ROUTE_0_0 0x2150
184	# define R300_INPUT_ROUTE_COMPONENTS_1 (0 << 0)
185	# define R300_INPUT_ROUTE_COMPONENTS_2 (1 << 0)
186	# define R300_INPUT_ROUTE_COMPONENTS_3 (2 << 0)
187	# define R300_INPUT_ROUTE_COMPONENTS_4 (3 << 0)
188	# define R300_INPUT_ROUTE_COMPONENTS_RGBA (4 << 0) /* GUESS */
189	# define R300_VAP_INPUT_ROUTE_IDX_SHIFT 8
190	# define R300_VAP_INPUT_ROUTE_IDX_MASK (31 << 8) /* GUESS */
191	# define R300_VAP_INPUT_ROUTE_END (1 << 13)
192	# define R300_INPUT_ROUTE_IMMEDIATE_MODE (0 << 14) /* GUESS */
193	# define R300_INPUT_ROUTE_FLOAT (1 << 14) /* GUESS */
194	# define R300_INPUT_ROUTE_UNSIGNED_BYTE (2 << 14) /* GUESS */
195	# define R300_INPUT_ROUTE_FLOAT_COLOR (3 << 14) /* GUESS */
196	#define R300_VAP_INPUT_ROUTE_0_1 0x2154
197	#define R300_VAP_INPUT_ROUTE_0_2 0x2158
198	#define R300_VAP_INPUT_ROUTE_0_3 0x215C
199	#define R300_VAP_INPUT_ROUTE_0_4 0x2160
200	#define R300_VAP_INPUT_ROUTE_0_5 0x2164
201	#define R300_VAP_INPUT_ROUTE_0_6 0x2168
202	#define R300_VAP_INPUT_ROUTE_0_7 0x216C
203
204	/* gap */
205
206	/* Notes:
207	* - always set up to produce at least two attributes:
208	* if vertex program uses only position, fglrx will set normal, too
209	* - INPUT_CNTL_0_COLOR and INPUT_CNTL_COLOR bits are always equal.
210	*/
211	#define R300_VAP_INPUT_CNTL_0 0x2180
212	# define R300_INPUT_CNTL_0_COLOR 0x00000001
213	#define R300_VAP_INPUT_CNTL_1 0x2184
214	# define R300_INPUT_CNTL_POS 0x00000001
215	# define R300_INPUT_CNTL_NORMAL 0x00000002
216	# define R300_INPUT_CNTL_COLOR 0x00000004
217	# define R300_INPUT_CNTL_TC0 0x00000400
218	# define R300_INPUT_CNTL_TC1 0x00000800
219	# define R300_INPUT_CNTL_TC2 0x00001000 /* GUESS */
220	# define R300_INPUT_CNTL_TC3 0x00002000 /* GUESS */
221	# define R300_INPUT_CNTL_TC4 0x00004000 /* GUESS */
222	# define R300_INPUT_CNTL_TC5 0x00008000 /* GUESS */
223	# define R300_INPUT_CNTL_TC6 0x00010000 /* GUESS */
224	# define R300_INPUT_CNTL_TC7 0x00020000 /* GUESS */
225
226	/* gap */
227
228	/* Words parallel to INPUT_ROUTE_0; All words that are active in INPUT_ROUTE_0
229	* are set to a swizzling bit pattern, other words are 0.
230	*
231	* In immediate mode, the pattern is always set to xyzw. In vertex array
232	* mode, the swizzling pattern is e.g. used to set zw components in texture
233	* coordinates with only tweo components.
234	*/
235	#define R300_VAP_INPUT_ROUTE_1_0 0x21E0
236	# define R300_INPUT_ROUTE_SELECT_X 0
237	# define R300_INPUT_ROUTE_SELECT_Y 1
238	# define R300_INPUT_ROUTE_SELECT_Z 2
239	# define R300_INPUT_ROUTE_SELECT_W 3
240	# define R300_INPUT_ROUTE_SELECT_ZERO 4
241	# define R300_INPUT_ROUTE_SELECT_ONE 5
242	# define R300_INPUT_ROUTE_SELECT_MASK 7
243	# define R300_INPUT_ROUTE_X_SHIFT 0
244	# define R300_INPUT_ROUTE_Y_SHIFT 3
245	# define R300_INPUT_ROUTE_Z_SHIFT 6
246	# define R300_INPUT_ROUTE_W_SHIFT 9
247	# define R300_INPUT_ROUTE_ENABLE (15 << 12)
248	#define R300_VAP_INPUT_ROUTE_1_1 0x21E4
249	#define R300_VAP_INPUT_ROUTE_1_2 0x21E8
250	#define R300_VAP_INPUT_ROUTE_1_3 0x21EC
251	#define R300_VAP_INPUT_ROUTE_1_4 0x21F0
252	#define R300_VAP_INPUT_ROUTE_1_5 0x21F4
253	#define R300_VAP_INPUT_ROUTE_1_6 0x21F8
254	#define R300_VAP_INPUT_ROUTE_1_7 0x21FC
255
256	/* END: Vertex data assembly */
257
258	/* gap */
259
260	/* BEGIN: Upload vertex program and data */
261
262	/*
263	* The programmable vertex shader unit has a memory bank of unknown size
264	* that can be written to in 16 byte units by writing the address into
265	* UPLOAD_ADDRESS, followed by data in UPLOAD_DATA (multiples of 4 DWORDs).
266	*
267	* Pointers into the memory bank are always in multiples of 16 bytes.
268	*
269	* The memory bank is divided into areas with fixed meaning.
270	*
271	* Starting at address UPLOAD_PROGRAM: Vertex program instructions.
272	* Native limits reported by drivers from ATI suggest size 256 (i.e. 4KB),
273	* whereas the difference between known addresses suggests size 512.
274	*
275	* Starting at address UPLOAD_PARAMETERS: Vertex program parameters.
276	* Native reported limits and the VPI layout suggest size 256, whereas
277	* difference between known addresses suggests size 512.
278	*
279	* At address UPLOAD_POINTSIZE is a vector (0, 0, ps, 0), where ps is the
280	* floating point pointsize. The exact purpose of this state is uncertain,
281	* as there is also the R300_RE_POINTSIZE register.
282	*
283	* Multiple vertex programs and parameter sets can be loaded at once,
284	* which could explain the size discrepancy.
285	*/
286	#define R300_VAP_PVS_UPLOAD_ADDRESS 0x2200
287	# define R300_PVS_UPLOAD_PROGRAM 0x00000000
288	# define R300_PVS_UPLOAD_PARAMETERS 0x00000200
289	# define R300_PVS_UPLOAD_POINTSIZE 0x00000406
290
291	/* gap */
292
293	#define R300_VAP_PVS_UPLOAD_DATA 0x2208
294
295	/* END: Upload vertex program and data */
296
297	/* gap */
298
299	/* I do not know the purpose of this register. However, I do know that
300	* it is set to 221C_CLEAR for clear operations and to 221C_NORMAL
301	* for normal rendering.
302	*/
303	#define R300_VAP_UNKNOWN_221C 0x221C
304	# define R300_221C_NORMAL 0x00000000
305	# define R300_221C_CLEAR 0x0001C000
306
307	/* These seem to be per-pixel and per-vertex X and Y clipping planes. The first
308	* plane is per-pixel and the second plane is per-vertex.
309	*
310	* This was determined by experimentation alone but I believe it is correct.
311	*
312	* These registers are called X_QUAD0_1_FL to X_QUAD0_4_FL by glxtest.
313	*/
314	#define R300_VAP_CLIP_X_0 0x2220
315	#define R300_VAP_CLIP_X_1 0x2224
316	#define R300_VAP_CLIP_Y_0 0x2228
317	#define R300_VAP_CLIP_Y_1 0x2230
318
319	/* gap */
320
321	/* Sometimes, END_OF_PKT and 0x2284=0 are the only commands sent between
322	* rendering commands and overwriting vertex program parameters.
323	* Therefore, I suspect writing zero to 0x2284 synchronizes the engine and
324	* avoids bugs caused by still running shaders reading bad data from memory.
325	*/
326	#define R300_VAP_PVS_STATE_FLUSH_REG 0x2284
327
328	/* Absolutely no clue what this register is about. */
329	#define R300_VAP_UNKNOWN_2288 0x2288
330	# define R300_2288_R300 0x00750000 /* -- nh */
331	# define R300_2288_RV350 0x0000FFFF /* -- Vladimir */
332
333	/* gap */
334
335	/* Addresses are relative to the vertex program instruction area of the
336	* memory bank. PROGRAM_END points to the last instruction of the active
337	* program
338	*
339	* The meaning of the two UNKNOWN fields is obviously not known. However,
340	* experiments so far have shown that both *must* point to an instruction
341	* inside the vertex program, otherwise the GPU locks up.
342	*
343	* fglrx usually sets CNTL_3_UNKNOWN to the end of the program and
344	* R300_PVS_CNTL_1_POS_END_SHIFT points to instruction where last write to
345	* position takes place.
346	*
347	* Most likely this is used to ignore rest of the program in cases
348	* where group of verts arent visible. For some reason this "section"
349	* is sometimes accepted other instruction that have no relationship with
350	* position calculations.
351	*/
352	#define R300_VAP_PVS_CNTL_1 0x22D0
353	# define R300_PVS_CNTL_1_PROGRAM_START_SHIFT 0
354	# define R300_PVS_CNTL_1_POS_END_SHIFT 10
355	# define R300_PVS_CNTL_1_PROGRAM_END_SHIFT 20
356	/* Addresses are relative the vertex program parameters area. */
357	#define R300_VAP_PVS_CNTL_2 0x22D4
358	# define R300_PVS_CNTL_2_PARAM_OFFSET_SHIFT 0
359	# define R300_PVS_CNTL_2_PARAM_COUNT_SHIFT 16
360	#define R300_VAP_PVS_CNTL_3 0x22D8
361	# define R300_PVS_CNTL_3_PROGRAM_UNKNOWN_SHIFT 10
362	# define R300_PVS_CNTL_3_PROGRAM_UNKNOWN2_SHIFT 0
363
364	/* The entire range from 0x2300 to 0x2AC inclusive seems to be used for
365	* immediate vertices
366	*/
367	#define R300_VAP_VTX_COLOR_R 0x2464
368	#define R300_VAP_VTX_COLOR_G 0x2468
369	#define R300_VAP_VTX_COLOR_B 0x246C
370	#define R300_VAP_VTX_POS_0_X_1 0x2490 /* used for glVertex2*() */
371	#define R300_VAP_VTX_POS_0_Y_1 0x2494
372	#define R300_VAP_VTX_COLOR_PKD 0x249C /* RGBA */
373	#define R300_VAP_VTX_POS_0_X_2 0x24A0 /* used for glVertex3*() */
374	#define R300_VAP_VTX_POS_0_Y_2 0x24A4
375	#define R300_VAP_VTX_POS_0_Z_2 0x24A8
376	/* write 0 to indicate end of packet? */
377	#define R300_VAP_VTX_END_OF_PKT 0x24AC
378
379	/* gap */
380
381	/* These are values from r300_reg/r300_reg.h - they are known to be correct
382	* and are here so we can use one register file instead of several
383	* - Vladimir
384	*/
385	#define R300_GB_VAP_RASTER_VTX_FMT_0 0x4000
386	# define R300_GB_VAP_RASTER_VTX_FMT_0__POS_PRESENT (1<<0)
387	# define R300_GB_VAP_RASTER_VTX_FMT_0__COLOR_0_PRESENT (1<<1)
388	# define R300_GB_VAP_RASTER_VTX_FMT_0__COLOR_1_PRESENT (1<<2)
389	# define R300_GB_VAP_RASTER_VTX_FMT_0__COLOR_2_PRESENT (1<<3)
390	# define R300_GB_VAP_RASTER_VTX_FMT_0__COLOR_3_PRESENT (1<<4)
391	# define R300_GB_VAP_RASTER_VTX_FMT_0__COLOR_SPACE (0xf<<5)
392	# define R300_GB_VAP_RASTER_VTX_FMT_0__PT_SIZE_PRESENT (0x1<<16)
393
394	#define R300_GB_VAP_RASTER_VTX_FMT_1 0x4004
395	/* each of the following is 3 bits wide, specifies number
396	of components */
397	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_0_COMP_CNT_SHIFT 0
398	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_1_COMP_CNT_SHIFT 3
399	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_2_COMP_CNT_SHIFT 6
400	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_3_COMP_CNT_SHIFT 9
401	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_4_COMP_CNT_SHIFT 12
402	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_5_COMP_CNT_SHIFT 15
403	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_6_COMP_CNT_SHIFT 18
404	# define R300_GB_VAP_RASTER_VTX_FMT_1__TEX_7_COMP_CNT_SHIFT 21
405
406	/* UNK30 seems to enables point to quad transformation on textures
407	* (or something closely related to that).
408	* This bit is rather fatal at the time being due to lackings at pixel
409	* shader side
410	*/
411	#define R300_GB_ENABLE 0x4008
412	# define R300_GB_POINT_STUFF_ENABLE (1<<0)
413	# define R300_GB_LINE_STUFF_ENABLE (1<<1)
414	# define R300_GB_TRIANGLE_STUFF_ENABLE (1<<2)
415	# define R300_GB_STENCIL_AUTO_ENABLE (1<<4)
416	# define R300_GB_UNK31 (1<<31)
417	/* each of the following is 2 bits wide */
418	#define R300_GB_TEX_REPLICATE 0
419	#define R300_GB_TEX_ST 1
420	#define R300_GB_TEX_STR 2
421	# define R300_GB_TEX0_SOURCE_SHIFT 16
422	# define R300_GB_TEX1_SOURCE_SHIFT 18
423	# define R300_GB_TEX2_SOURCE_SHIFT 20
424	# define R300_GB_TEX3_SOURCE_SHIFT 22
425	# define R300_GB_TEX4_SOURCE_SHIFT 24
426	# define R300_GB_TEX5_SOURCE_SHIFT 26
427	# define R300_GB_TEX6_SOURCE_SHIFT 28
428	# define R300_GB_TEX7_SOURCE_SHIFT 30
429
430	/* MSPOS - positions for multisample antialiasing (?) */
431	#define R300_GB_MSPOS0 0x4010
432	/* shifts - each of the fields is 4 bits */
433	# define R300_GB_MSPOS0__MS_X0_SHIFT 0
434	# define R300_GB_MSPOS0__MS_Y0_SHIFT 4
435	# define R300_GB_MSPOS0__MS_X1_SHIFT 8
436	# define R300_GB_MSPOS0__MS_Y1_SHIFT 12
437	# define R300_GB_MSPOS0__MS_X2_SHIFT 16
438	# define R300_GB_MSPOS0__MS_Y2_SHIFT 20
439	# define R300_GB_MSPOS0__MSBD0_Y 24
440	# define R300_GB_MSPOS0__MSBD0_X 28
441
442	#define R300_GB_MSPOS1 0x4014
443	# define R300_GB_MSPOS1__MS_X3_SHIFT 0
444	# define R300_GB_MSPOS1__MS_Y3_SHIFT 4
445	# define R300_GB_MSPOS1__MS_X4_SHIFT 8
446	# define R300_GB_MSPOS1__MS_Y4_SHIFT 12
447	# define R300_GB_MSPOS1__MS_X5_SHIFT 16
448	# define R300_GB_MSPOS1__MS_Y5_SHIFT 20
449	# define R300_GB_MSPOS1__MSBD1 24
450
451
452	#define R300_GB_TILE_CONFIG 0x4018
453	# define R300_GB_TILE_ENABLE (1<<0)
454	# define R300_GB_TILE_PIPE_COUNT_RV300 0
455	# define R300_GB_TILE_PIPE_COUNT_R300 (3<<1)
456	# define R300_GB_TILE_PIPE_COUNT_R420 (7<<1)
457	# define R300_GB_TILE_PIPE_COUNT_RV410 (3<<1)
458	# define R300_GB_TILE_SIZE_8 0
459	# define R300_GB_TILE_SIZE_16 (1<<4)
460	# define R300_GB_TILE_SIZE_32 (2<<4)
461	# define R300_GB_SUPER_SIZE_1 (0<<6)
462	# define R300_GB_SUPER_SIZE_2 (1<<6)
463	# define R300_GB_SUPER_SIZE_4 (2<<6)
464	# define R300_GB_SUPER_SIZE_8 (3<<6)
465	# define R300_GB_SUPER_SIZE_16 (4<<6)
466	# define R300_GB_SUPER_SIZE_32 (5<<6)
467	# define R300_GB_SUPER_SIZE_64 (6<<6)
468	# define R300_GB_SUPER_SIZE_128 (7<<6)
469	# define R300_GB_SUPER_X_SHIFT 9 /* 3 bits wide */
470	# define R300_GB_SUPER_Y_SHIFT 12 /* 3 bits wide */
471	# define R300_GB_SUPER_TILE_A 0
472	# define R300_GB_SUPER_TILE_B (1<<15)
473	# define R300_GB_SUBPIXEL_1_12 0
474	# define R300_GB_SUBPIXEL_1_16 (1<<16)
475
476	#define R300_GB_FIFO_SIZE 0x4024
477	/* each of the following is 2 bits wide */
478	#define R300_GB_FIFO_SIZE_32 0
479	#define R300_GB_FIFO_SIZE_64 1
480	#define R300_GB_FIFO_SIZE_128 2
481	#define R300_GB_FIFO_SIZE_256 3
482	# define R300_SC_IFIFO_SIZE_SHIFT 0
483	# define R300_SC_TZFIFO_SIZE_SHIFT 2
484	# define R300_SC_BFIFO_SIZE_SHIFT 4
485
486	# define R300_US_OFIFO_SIZE_SHIFT 12
487	# define R300_US_WFIFO_SIZE_SHIFT 14
488	/* the following use the same constants as above, but meaning is
489	is times 2 (i.e. instead of 32 words it means 64 */
490	# define R300_RS_TFIFO_SIZE_SHIFT 6
491	# define R300_RS_CFIFO_SIZE_SHIFT 8
492	# define R300_US_RAM_SIZE_SHIFT 10
493	/* watermarks, 3 bits wide */
494	# define R300_RS_HIGHWATER_COL_SHIFT 16
495	# define R300_RS_HIGHWATER_TEX_SHIFT 19
496	# define R300_OFIFO_HIGHWATER_SHIFT 22 /* two bits only */
497	# define R300_CUBE_FIFO_HIGHWATER_COL_SHIFT 24
498
499	#define R300_GB_SELECT 0x401C
500	# define R300_GB_FOG_SELECT_C0A 0
501	# define R300_GB_FOG_SELECT_C1A 1
502	# define R300_GB_FOG_SELECT_C2A 2
503	# define R300_GB_FOG_SELECT_C3A 3
504	# define R300_GB_FOG_SELECT_1_1_W 4
505	# define R300_GB_FOG_SELECT_Z 5
506	# define R300_GB_DEPTH_SELECT_Z 0
507	# define R300_GB_DEPTH_SELECT_1_1_W (1<<3)
508	# define R300_GB_W_SELECT_1_W 0
509	# define R300_GB_W_SELECT_1 (1<<4)
510
511	#define R300_GB_AA_CONFIG 0x4020
512	# define R300_AA_DISABLE 0x00
513	# define R300_AA_ENABLE 0x01
514	# define R300_AA_SUBSAMPLES_2 0
515	# define R300_AA_SUBSAMPLES_3 (1<<1)
516	# define R300_AA_SUBSAMPLES_4 (2<<1)
517	# define R300_AA_SUBSAMPLES_6 (3<<1)
518
519	/* gap */
520
521	/* Zero to flush caches. */
522	#define R300_TX_INVALTAGS 0x4100
523	#define R300_TX_FLUSH 0x0
524
525	/* The upper enable bits are guessed, based on fglrx reported limits. */
526	#define R300_TX_ENABLE 0x4104
527	# define R300_TX_ENABLE_0 (1 << 0)
528	# define R300_TX_ENABLE_1 (1 << 1)
529	# define R300_TX_ENABLE_2 (1 << 2)
530	# define R300_TX_ENABLE_3 (1 << 3)
531	# define R300_TX_ENABLE_4 (1 << 4)
532	# define R300_TX_ENABLE_5 (1 << 5)
533	# define R300_TX_ENABLE_6 (1 << 6)
534	# define R300_TX_ENABLE_7 (1 << 7)
535	# define R300_TX_ENABLE_8 (1 << 8)
536	# define R300_TX_ENABLE_9 (1 << 9)
537	# define R300_TX_ENABLE_10 (1 << 10)
538	# define R300_TX_ENABLE_11 (1 << 11)
539	# define R300_TX_ENABLE_12 (1 << 12)
540	# define R300_TX_ENABLE_13 (1 << 13)
541	# define R300_TX_ENABLE_14 (1 << 14)
542	# define R300_TX_ENABLE_15 (1 << 15)
543
544	/* The pointsize is given in multiples of 6. The pointsize can be
545	* enormous: Clear() renders a single point that fills the entire
546	* framebuffer.
547	*/
548	#define R300_RE_POINTSIZE 0x421C
549	# define R300_POINTSIZE_Y_SHIFT 0
550	# define R300_POINTSIZE_Y_MASK (0xFFFF << 0) /* GUESS */
551	# define R300_POINTSIZE_X_SHIFT 16
552	# define R300_POINTSIZE_X_MASK (0xFFFF << 16) /* GUESS */
553	# define R300_POINTSIZE_MAX (R300_POINTSIZE_Y_MASK / 6)
554
555	/* The line width is given in multiples of 6.
556	* In default mode lines are classified as vertical lines.
557	* HO: horizontal
558	* VE: vertical or horizontal
559	* HO & VE: no classification
560	*/
561	#define R300_RE_LINE_CNT 0x4234
562	# define R300_LINESIZE_SHIFT 0
563	# define R300_LINESIZE_MASK (0xFFFF << 0) /* GUESS */
564	# define R300_LINESIZE_MAX (R300_LINESIZE_MASK / 6)
565	# define R300_LINE_CNT_HO (1 << 16)
566	# define R300_LINE_CNT_VE (1 << 17)
567
568	/* Some sort of scale or clamp value for texcoordless textures. */
569	#define R300_RE_UNK4238 0x4238
570
571	/* Something shade related */
572	#define R300_RE_SHADE 0x4274
573
574	#define R300_RE_SHADE_MODEL 0x4278
575	# define R300_RE_SHADE_MODEL_SMOOTH 0x3aaaa
576	# define R300_RE_SHADE_MODEL_FLAT 0x39595
577
578	/* Dangerous */
579	#define R300_RE_POLYGON_MODE 0x4288
580	# define R300_PM_ENABLED (1 << 0)
581	# define R300_PM_FRONT_POINT (0 << 0)
582	# define R300_PM_BACK_POINT (0 << 0)
583	# define R300_PM_FRONT_LINE (1 << 4)
584	# define R300_PM_FRONT_FILL (1 << 5)
585	# define R300_PM_BACK_LINE (1 << 7)
586	# define R300_PM_BACK_FILL (1 << 8)
587
588	/* Fog parameters */
589	#define R300_RE_FOG_SCALE 0x4294
590	#define R300_RE_FOG_START 0x4298
591
592	/* Not sure why there are duplicate of factor and constant values.
593	* My best guess so far is that there are separate zbiases for test and write.
594	* Ordering might be wrong.
595	* Some of the tests indicate that fgl has a fallback implementation of zbias
596	* via pixel shaders.
597	*/
598	#define R300_RE_ZBIAS_CNTL 0x42A0 /* GUESS */
599	#define R300_RE_ZBIAS_T_FACTOR 0x42A4
600	#define R300_RE_ZBIAS_T_CONSTANT 0x42A8
601	#define R300_RE_ZBIAS_W_FACTOR 0x42AC
602	#define R300_RE_ZBIAS_W_CONSTANT 0x42B0
603
604	/* This register needs to be set to (1<<1) for RV350 to correctly
605	* perform depth test (see --vb-triangles in r300_demo)
606	* Don't know about other chips. - Vladimir
607	* This is set to 3 when GL_POLYGON_OFFSET_FILL is on.
608	* My guess is that there are two bits for each zbias primitive
609	* (FILL, LINE, POINT).
610	* One to enable depth test and one for depth write.
611	* Yet this doesn't explain why depth writes work ...
612	*/
613	#define R300_RE_OCCLUSION_CNTL 0x42B4
614	# define R300_OCCLUSION_ON (1<<1)
615
616	#define R300_RE_CULL_CNTL 0x42B8
617	# define R300_CULL_FRONT (1 << 0)
618	# define R300_CULL_BACK (1 << 1)
619	# define R300_FRONT_FACE_CCW (0 << 2)
620	# define R300_FRONT_FACE_CW (1 << 2)
621
622
623	/* BEGIN: Rasterization / Interpolators - many guesses */
624
625	/* 0_UNKNOWN_18 has always been set except for clear operations.
626	* TC_CNT is the number of incoming texture coordinate sets (i.e. it depends
627	* on the vertex program, *not* the fragment program)
628	*/
629	#define R300_RS_CNTL_0 0x4300
630	# define R300_RS_CNTL_TC_CNT_SHIFT 2
631	# define R300_RS_CNTL_TC_CNT_MASK (7 << 2)
632	/* number of color interpolators used */
633	# define R300_RS_CNTL_CI_CNT_SHIFT 7
634	# define R300_RS_CNTL_0_UNKNOWN_18 (1 << 18)
635	/* Guess: RS_CNTL_1 holds the index of the highest used RS_ROUTE_n
636	register. */
637	#define R300_RS_CNTL_1 0x4304
638
639	/* gap */
640
641	/* Only used for texture coordinates.
642	* Use the source field to route texture coordinate input from the
643	* vertex program to the desired interpolator. Note that the source
644	* field is relative to the outputs the vertex program *actually*
645	* writes. If a vertex program only writes texcoord[1], this will
646	* be source index 0.
647	* Set INTERP_USED on all interpolators that produce data used by
648	* the fragment program. INTERP_USED looks like a swizzling mask,
649	* but I haven't seen it used that way.
650	*
651	* Note: The _UNKNOWN constants are always set in their respective
652	* register. I don't know if this is necessary.
653	*/
654	#define R300_RS_INTERP_0 0x4310
655	#define R300_RS_INTERP_1 0x4314
656	# define R300_RS_INTERP_1_UNKNOWN 0x40
657	#define R300_RS_INTERP_2 0x4318
658	# define R300_RS_INTERP_2_UNKNOWN 0x80
659	#define R300_RS_INTERP_3 0x431C
660	# define R300_RS_INTERP_3_UNKNOWN 0xC0
661	#define R300_RS_INTERP_4 0x4320
662	#define R300_RS_INTERP_5 0x4324
663	#define R300_RS_INTERP_6 0x4328
664	#define R300_RS_INTERP_7 0x432C
665	# define R300_RS_INTERP_SRC_SHIFT 2
666	# define R300_RS_INTERP_SRC_MASK (7 << 2)
667	# define R300_RS_INTERP_USED 0x00D10000
668
669	/* These DWORDs control how vertex data is routed into fragment program
670	* registers, after interpolators.
671	*/
672	#define R300_RS_ROUTE_0 0x4330
673	#define R300_RS_ROUTE_1 0x4334
674	#define R300_RS_ROUTE_2 0x4338
675	#define R300_RS_ROUTE_3 0x433C /* GUESS */
676	#define R300_RS_ROUTE_4 0x4340 /* GUESS */
677	#define R300_RS_ROUTE_5 0x4344 /* GUESS */
678	#define R300_RS_ROUTE_6 0x4348 /* GUESS */
679	#define R300_RS_ROUTE_7 0x434C /* GUESS */
680	# define R300_RS_ROUTE_SOURCE_INTERP_0 0
681	# define R300_RS_ROUTE_SOURCE_INTERP_1 1
682	# define R300_RS_ROUTE_SOURCE_INTERP_2 2
683	# define R300_RS_ROUTE_SOURCE_INTERP_3 3
684	# define R300_RS_ROUTE_SOURCE_INTERP_4 4
685	# define R300_RS_ROUTE_SOURCE_INTERP_5 5 /* GUESS */
686	# define R300_RS_ROUTE_SOURCE_INTERP_6 6 /* GUESS */
687	# define R300_RS_ROUTE_SOURCE_INTERP_7 7 /* GUESS */
688	# define R300_RS_ROUTE_ENABLE (1 << 3) /* GUESS */
689	# define R300_RS_ROUTE_DEST_SHIFT 6
690	# define R300_RS_ROUTE_DEST_MASK (31 << 6) /* GUESS */
691
692	/* Special handling for color: When the fragment program uses color,
693	* the ROUTE_0_COLOR bit is set and ROUTE_0_COLOR_DEST contains the
694	* color register index.
695	*
696	* Apperently you may set the R300_RS_ROUTE_0_COLOR bit, but not provide any
697	* R300_RS_ROUTE_0_COLOR_DEST value; this setup is used for clearing the state.
698	* See r300_ioctl.c:r300EmitClearState. I'm not sure if this setup is strictly
699	* correct or not. - Oliver.
700	*/
701	# define R300_RS_ROUTE_0_COLOR (1 << 14)
702	# define R300_RS_ROUTE_0_COLOR_DEST_SHIFT 17
703	# define R300_RS_ROUTE_0_COLOR_DEST_MASK (31 << 17) /* GUESS */
704	/* As above, but for secondary color */
705	# define R300_RS_ROUTE_1_COLOR1 (1 << 14)
706	# define R300_RS_ROUTE_1_COLOR1_DEST_SHIFT 17
707	# define R300_RS_ROUTE_1_COLOR1_DEST_MASK (31 << 17)
708	# define R300_RS_ROUTE_1_UNKNOWN11 (1 << 11)
709	/* END: Rasterization / Interpolators - many guesses */
710
711	/* Hierarchical Z Enable */
712	#define R300_SC_HYPERZ 0x43a4
713	# define R300_SC_HYPERZ_DISABLE (0 << 0)
714	# define R300_SC_HYPERZ_ENABLE (1 << 0)
715	# define R300_SC_HYPERZ_MIN (0 << 1)
716	# define R300_SC_HYPERZ_MAX (1 << 1)
717	# define R300_SC_HYPERZ_ADJ_256 (0 << 2)
718	# define R300_SC_HYPERZ_ADJ_128 (1 << 2)
719	# define R300_SC_HYPERZ_ADJ_64 (2 << 2)
720	# define R300_SC_HYPERZ_ADJ_32 (3 << 2)
721	# define R300_SC_HYPERZ_ADJ_16 (4 << 2)
722	# define R300_SC_HYPERZ_ADJ_8 (5 << 2)
723	# define R300_SC_HYPERZ_ADJ_4 (6 << 2)
724	# define R300_SC_HYPERZ_ADJ_2 (7 << 2)
725	# define R300_SC_HYPERZ_HZ_Z0MIN_NO (0 << 5)
726	# define R300_SC_HYPERZ_HZ_Z0MIN (1 << 5)
727	# define R300_SC_HYPERZ_HZ_Z0MAX_NO (0 << 6)
728	# define R300_SC_HYPERZ_HZ_Z0MAX (1 << 6)
729
730	#define R300_SC_EDGERULE 0x43a8
731
732	/* BEGIN: Scissors and cliprects */
733
734	/* There are four clipping rectangles. Their corner coordinates are inclusive.
735	* Every pixel is assigned a number from 0 and 15 by setting bits 0-3 depending
736	* on whether the pixel is inside cliprects 0-3, respectively. For example,
737	* if a pixel is inside cliprects 0 and 1, but outside 2 and 3, it is assigned
738	* the number 3 (binary 0011).
739	* Iff the bit corresponding to the pixel's number in RE_CLIPRECT_CNTL is set,
740	* the pixel is rasterized.
741	*
742	* In addition to this, there is a scissors rectangle. Only pixels inside the
743	* scissors rectangle are drawn. (coordinates are inclusive)
744	*
745	* For some reason, the top-left corner of the framebuffer is at (1440, 1440)
746	* for the purpose of clipping and scissors.
747	*/
748	#define R300_RE_CLIPRECT_TL_0 0x43B0
749	#define R300_RE_CLIPRECT_BR_0 0x43B4
750	#define R300_RE_CLIPRECT_TL_1 0x43B8
751	#define R300_RE_CLIPRECT_BR_1 0x43BC
752	#define R300_RE_CLIPRECT_TL_2 0x43C0
753	#define R300_RE_CLIPRECT_BR_2 0x43C4
754	#define R300_RE_CLIPRECT_TL_3 0x43C8
755	#define R300_RE_CLIPRECT_BR_3 0x43CC
756	# define R300_CLIPRECT_OFFSET 1440
757	# define R300_CLIPRECT_MASK 0x1FFF
758	# define R300_CLIPRECT_X_SHIFT 0
759	# define R300_CLIPRECT_X_MASK (0x1FFF << 0)
760	# define R300_CLIPRECT_Y_SHIFT 13
761	# define R300_CLIPRECT_Y_MASK (0x1FFF << 13)
762	#define R300_RE_CLIPRECT_CNTL 0x43D0
763	# define R300_CLIP_OUT (1 << 0)
764	# define R300_CLIP_0 (1 << 1)
765	# define R300_CLIP_1 (1 << 2)
766	# define R300_CLIP_10 (1 << 3)
767	# define R300_CLIP_2 (1 << 4)
768	# define R300_CLIP_20 (1 << 5)
769	# define R300_CLIP_21 (1 << 6)
770	# define R300_CLIP_210 (1 << 7)
771	# define R300_CLIP_3 (1 << 8)
772	# define R300_CLIP_30 (1 << 9)
773	# define R300_CLIP_31 (1 << 10)
774	# define R300_CLIP_310 (1 << 11)
775	# define R300_CLIP_32 (1 << 12)
776	# define R300_CLIP_320 (1 << 13)
777	# define R300_CLIP_321 (1 << 14)
778	# define R300_CLIP_3210 (1 << 15)
779
780	/* gap */
781
782	#define R300_RE_SCISSORS_TL 0x43E0
783	#define R300_RE_SCISSORS_BR 0x43E4
784	# define R300_SCISSORS_OFFSET 1440
785	# define R300_SCISSORS_X_SHIFT 0
786	# define R300_SCISSORS_X_MASK (0x1FFF << 0)
787	# define R300_SCISSORS_Y_SHIFT 13
788	# define R300_SCISSORS_Y_MASK (0x1FFF << 13)
789	/* END: Scissors and cliprects */
790
791	/* BEGIN: Texture specification */
792
793	/*
794	* The texture specification dwords are grouped by meaning and not by texture
795	* unit. This means that e.g. the offset for texture image unit N is found in
796	* register TX_OFFSET_0 + (4*N)
797	*/
798	#define R300_TX_FILTER_0 0x4400
799	# define R300_TX_REPEAT 0
800	# define R300_TX_MIRRORED 1
801	# define R300_TX_CLAMP 4
802	# define R300_TX_CLAMP_TO_EDGE 2
803	# define R300_TX_CLAMP_TO_BORDER 6
804	# define R300_TX_WRAP_S_SHIFT 0
805	# define R300_TX_WRAP_S_MASK (7 << 0)
806	# define R300_TX_WRAP_T_SHIFT 3
807	# define R300_TX_WRAP_T_MASK (7 << 3)
808	# define R300_TX_WRAP_Q_SHIFT 6
809	# define R300_TX_WRAP_Q_MASK (7 << 6)
810	# define R300_TX_MAG_FILTER_NEAREST (1 << 9)
811	# define R300_TX_MAG_FILTER_LINEAR (2 << 9)
812	# define R300_TX_MAG_FILTER_MASK (3 << 9)
813	# define R300_TX_MIN_FILTER_NEAREST (1 << 11)
814	# define R300_TX_MIN_FILTER_LINEAR (2 << 11)
815	# define R300_TX_MIN_FILTER_NEAREST_MIP_NEAREST (5 << 11)
816	# define R300_TX_MIN_FILTER_NEAREST_MIP_LINEAR (9 << 11)
817	# define R300_TX_MIN_FILTER_LINEAR_MIP_NEAREST (6 << 11)
818	# define R300_TX_MIN_FILTER_LINEAR_MIP_LINEAR (10 << 11)
819
820	/* NOTE: NEAREST doesn't seem to exist.
821	* Im not seting MAG_FILTER_MASK and (3 << 11) on for all
822	* anisotropy modes because that would void selected mag filter
823	*/
824	# define R300_TX_MIN_FILTER_ANISO_NEAREST (0 << 13)
825	# define R300_TX_MIN_FILTER_ANISO_LINEAR (0 << 13)
826	# define R300_TX_MIN_FILTER_ANISO_NEAREST_MIP_NEAREST (1 << 13)
827	# define R300_TX_MIN_FILTER_ANISO_NEAREST_MIP_LINEAR (2 << 13)
828	# define R300_TX_MIN_FILTER_MASK ( (15 << 11) | (3 << 13) )
829	# define R300_TX_MAX_ANISO_1_TO_1 (0 << 21)
830	# define R300_TX_MAX_ANISO_2_TO_1 (2 << 21)
831	# define R300_TX_MAX_ANISO_4_TO_1 (4 << 21)
832	# define R300_TX_MAX_ANISO_8_TO_1 (6 << 21)
833	# define R300_TX_MAX_ANISO_16_TO_1 (8 << 21)
834	# define R300_TX_MAX_ANISO_MASK (14 << 21)
835
836	#define R300_TX_FILTER1_0 0x4440
837	# define R300_CHROMA_KEY_MODE_DISABLE 0
838	# define R300_CHROMA_KEY_FORCE 1
839	# define R300_CHROMA_KEY_BLEND 2
840	# define R300_MC_ROUND_NORMAL (0<<2)
841	# define R300_MC_ROUND_MPEG4 (1<<2)
842	# define R300_LOD_BIAS_MASK 0x1fff
843	# define R300_EDGE_ANISO_EDGE_DIAG (0<<13)
844	# define R300_EDGE_ANISO_EDGE_ONLY (1<<13)
845	# define R300_MC_COORD_TRUNCATE_DISABLE (0<<14)
846	# define R300_MC_COORD_TRUNCATE_MPEG (1<<14)
847	# define R300_TX_TRI_PERF_0_8 (0<<15)
848	# define R300_TX_TRI_PERF_1_8 (1<<15)
849	# define R300_TX_TRI_PERF_1_4 (2<<15)
850	# define R300_TX_TRI_PERF_3_8 (3<<15)
851	# define R300_ANISO_THRESHOLD_MASK (7<<17)
852
853	#define R300_TX_SIZE_0 0x4480
854	# define R300_TX_WIDTHMASK_SHIFT 0
855	# define R300_TX_WIDTHMASK_MASK (2047 << 0)
856	# define R300_TX_HEIGHTMASK_SHIFT 11
857	# define R300_TX_HEIGHTMASK_MASK (2047 << 11)
858	# define R300_TX_UNK23 (1 << 23)
859	# define R300_TX_MAX_MIP_LEVEL_SHIFT 26
860	# define R300_TX_MAX_MIP_LEVEL_MASK (0xf << 26)
861	# define R300_TX_SIZE_PROJECTED (1<<30)
862	# define R300_TX_SIZE_TXPITCH_EN (1<<31)
863	#define R300_TX_FORMAT_0 0x44C0
864	/* The interpretation of the format word by Wladimir van der Laan */
865	/* The X, Y, Z and W refer to the layout of the components.
866	They are given meanings as R, G, B and Alpha by the swizzle
867	specification */
868	# define R300_TX_FORMAT_X8 0x0
869	# define R300_TX_FORMAT_X16 0x1
870	# define R300_TX_FORMAT_Y4X4 0x2
871	# define R300_TX_FORMAT_Y8X8 0x3
872	# define R300_TX_FORMAT_Y16X16 0x4
873	# define R300_TX_FORMAT_Z3Y3X2 0x5
874	# define R300_TX_FORMAT_Z5Y6X5 0x6
875	# define R300_TX_FORMAT_Z6Y5X5 0x7
876	# define R300_TX_FORMAT_Z11Y11X10 0x8
877	# define R300_TX_FORMAT_Z10Y11X11 0x9
878	# define R300_TX_FORMAT_W4Z4Y4X4 0xA
879	# define R300_TX_FORMAT_W1Z5Y5X5 0xB
880	# define R300_TX_FORMAT_W8Z8Y8X8 0xC
881	# define R300_TX_FORMAT_W2Z10Y10X10 0xD
882	# define R300_TX_FORMAT_W16Z16Y16X16 0xE
883	# define R300_TX_FORMAT_DXT1 0xF
884	# define R300_TX_FORMAT_DXT3 0x10
885	# define R300_TX_FORMAT_DXT5 0x11
886	# define R300_TX_FORMAT_D3DMFT_CxV8U8 0x12 /* no swizzle */
887	# define R300_TX_FORMAT_A8R8G8B8 0x13 /* no swizzle */
888	# define R300_TX_FORMAT_B8G8_B8G8 0x14 /* no swizzle */
889	# define R300_TX_FORMAT_G8R8_G8B8 0x15 /* no swizzle */
890	/* 0x16 - some 16 bit green format.. ?? */
891	# define R300_TX_FORMAT_UNK25 (1 << 25) /* no swizzle */
892	# define R300_TX_FORMAT_CUBIC_MAP (1 << 26)
893
894	/* gap */
895	/* Floating point formats */
896	/* Note - hardware supports both 16 and 32 bit floating point */
897	# define R300_TX_FORMAT_FL_I16 0x18
898	# define R300_TX_FORMAT_FL_I16A16 0x19
899	# define R300_TX_FORMAT_FL_R16G16B16A16 0x1A
900	# define R300_TX_FORMAT_FL_I32 0x1B
901	# define R300_TX_FORMAT_FL_I32A32 0x1C
902	# define R300_TX_FORMAT_FL_R32G32B32A32 0x1D
903	# define R300_TX_FORMAT_ATI2N 0x1F
904	/* alpha modes, convenience mostly */
905	/* if you have alpha, pick constant appropriate to the
906	number of channels (1 for I8, 2 for I8A8, 4 for R8G8B8A8, etc */
907	# define R300_TX_FORMAT_ALPHA_1CH 0x000
908	# define R300_TX_FORMAT_ALPHA_2CH 0x200
909	# define R300_TX_FORMAT_ALPHA_4CH 0x600
910	# define R300_TX_FORMAT_ALPHA_NONE 0xA00
911	/* Swizzling */
912	/* constants */
913	# define R300_TX_FORMAT_X 0
914	# define R300_TX_FORMAT_Y 1
915	# define R300_TX_FORMAT_Z 2
916	# define R300_TX_FORMAT_W 3
917	# define R300_TX_FORMAT_ZERO 4
918	# define R300_TX_FORMAT_ONE 5
919	/* 2.0*Z, everything above 1.0 is set to 0.0 */
920	# define R300_TX_FORMAT_CUT_Z 6
921	/* 2.0*W, everything above 1.0 is set to 0.0 */
922	# define R300_TX_FORMAT_CUT_W 7
923
924	# define R300_TX_FORMAT_B_SHIFT 18
925	# define R300_TX_FORMAT_G_SHIFT 15
926	# define R300_TX_FORMAT_R_SHIFT 12
927	# define R300_TX_FORMAT_A_SHIFT 9
928	/* Convenience macro to take care of layout and swizzling */
929	# define R300_EASY_TX_FORMAT(B, G, R, A, FMT) ( \
930	((R300_TX_FORMAT_##B)<<R300_TX_FORMAT_B_SHIFT) \
931	| ((R300_TX_FORMAT_##G)<<R300_TX_FORMAT_G_SHIFT) \
932	| ((R300_TX_FORMAT_##R)<<R300_TX_FORMAT_R_SHIFT) \
933	| ((R300_TX_FORMAT_##A)<<R300_TX_FORMAT_A_SHIFT) \
934	| (R300_TX_FORMAT_##FMT) \
935	)
936	/* These can be ORed with result of R300_EASY_TX_FORMAT()
937	We don't really know what they do. Take values from a
938	constant color ? */
939	# define R300_TX_FORMAT_CONST_X (1<<5)
940	# define R300_TX_FORMAT_CONST_Y (2<<5)
941	# define R300_TX_FORMAT_CONST_Z (4<<5)
942	# define R300_TX_FORMAT_CONST_W (8<<5)
943
944	# define R300_TX_FORMAT_YUV_MODE 0x00800000
945
946	#define R300_TX_PITCH_0 0x4500 /* obvious missing in gap */
947	#define R300_TX_OFFSET_0 0x4540
948	/* BEGIN: Guess from R200 */
949	# define R300_TXO_ENDIAN_NO_SWAP (0 << 0)
950	# define R300_TXO_ENDIAN_BYTE_SWAP (1 << 0)
951	# define R300_TXO_ENDIAN_WORD_SWAP (2 << 0)
952	# define R300_TXO_ENDIAN_HALFDW_SWAP (3 << 0)
953	# define R300_TXO_MACRO_TILE (1 << 2)
954	# define R300_TXO_MICRO_TILE (1 << 3)
955	# define R300_TXO_MICRO_TILE_SQUARE (2 << 3)
956	# define R300_TXO_OFFSET_MASK 0xffffffe0
957	# define R300_TXO_OFFSET_SHIFT 5
958	/* END: Guess from R200 */
959
960	/* 32 bit chroma key */
961	#define R300_TX_CHROMA_KEY_0 0x4580
962	/* ff00ff00 == { 0, 1.0, 0, 1.0 } */
963	#define R300_TX_BORDER_COLOR_0 0x45C0
964
965	/* END: Texture specification */
966
967	/* BEGIN: Fragment program instruction set */
968
969	/* Fragment programs are written directly into register space.
970	* There are separate instruction streams for texture instructions and ALU
971	* instructions.
972	* In order to synchronize these streams, the program is divided into up
973	* to 4 nodes. Each node begins with a number of TEX operations, followed
974	* by a number of ALU operations.
975	* The first node can have zero TEX ops, all subsequent nodes must have at
976	* least
977	* one TEX ops.
978	* All nodes must have at least one ALU op.
979	*
980	* The index of the last node is stored in PFS_CNTL_0: A value of 0 means
981	* 1 node, a value of 3 means 4 nodes.
982	* The total amount of instructions is defined in PFS_CNTL_2. The offsets are
983	* offsets into the respective instruction streams, while *_END points to the
984	* last instruction relative to this offset.
985	*/
986	#define R300_PFS_CNTL_0 0x4600
987	# define R300_PFS_CNTL_LAST_NODES_SHIFT 0
988	# define R300_PFS_CNTL_LAST_NODES_MASK (3 << 0)
989	# define R300_PFS_CNTL_FIRST_NODE_HAS_TEX (1 << 3)
990	#define R300_PFS_CNTL_1 0x4604
991	/* There is an unshifted value here which has so far always been equal to the
992	* index of the highest used temporary register.
993	*/
994	#define R300_PFS_CNTL_2 0x4608
995	# define R300_PFS_CNTL_ALU_OFFSET_SHIFT 0
996	# define R300_PFS_CNTL_ALU_OFFSET_MASK (63 << 0)
997	# define R300_PFS_CNTL_ALU_END_SHIFT 6
998	# define R300_PFS_CNTL_ALU_END_MASK (63 << 6)
999	# define R300_PFS_CNTL_TEX_OFFSET_SHIFT 12
1000	# define R300_PFS_CNTL_TEX_OFFSET_MASK (31 << 12) /* GUESS */
1001	# define R300_PFS_CNTL_TEX_END_SHIFT 18
1002	# define R300_PFS_CNTL_TEX_END_MASK (31 << 18) /* GUESS */
1003
1004	/* gap */
1005
1006	/* Nodes are stored backwards. The last active node is always stored in
1007	* PFS_NODE_3.
1008	* Example: In a 2-node program, NODE_0 and NODE_1 are set to 0. The
1009	* first node is stored in NODE_2, the second node is stored in NODE_3.
1010	*
1011	* Offsets are relative to the master offset from PFS_CNTL_2.
1012	*/
1013	#define R300_PFS_NODE_0 0x4610
1014	#define R300_PFS_NODE_1 0x4614
1015	#define R300_PFS_NODE_2 0x4618
1016	#define R300_PFS_NODE_3 0x461C
1017	# define R300_PFS_NODE_ALU_OFFSET_SHIFT 0
1018	# define R300_PFS_NODE_ALU_OFFSET_MASK (63 << 0)
1019	# define R300_PFS_NODE_ALU_END_SHIFT 6
1020	# define R300_PFS_NODE_ALU_END_MASK (63 << 6)
1021	# define R300_PFS_NODE_TEX_OFFSET_SHIFT 12
1022	# define R300_PFS_NODE_TEX_OFFSET_MASK (31 << 12)
1023	# define R300_PFS_NODE_TEX_END_SHIFT 17
1024	# define R300_PFS_NODE_TEX_END_MASK (31 << 17)
1025	# define R300_PFS_NODE_OUTPUT_COLOR (1 << 22)
1026	# define R300_PFS_NODE_OUTPUT_DEPTH (1 << 23)
1027
1028	/* TEX
1029	* As far as I can tell, texture instructions cannot write into output
1030	* registers directly. A subsequent ALU instruction is always necessary,
1031	* even if it's just MAD o0, r0, 1, 0
1032	*/
1033	#define R300_PFS_TEXI_0 0x4620
1034	# define R300_FPITX_SRC_SHIFT 0
1035	# define R300_FPITX_SRC_MASK (31 << 0)
1036	/* GUESS */
1037	# define R300_FPITX_SRC_CONST (1 << 5)
1038	# define R300_FPITX_DST_SHIFT 6
1039	# define R300_FPITX_DST_MASK (31 << 6)
1040	# define R300_FPITX_IMAGE_SHIFT 11
1041	/* GUESS based on layout and native limits */
1042	# define R300_FPITX_IMAGE_MASK (15 << 11)
1043	/* Unsure if these are opcodes, or some kind of bitfield, but this is how
1044	* they were set when I checked
1045	*/
1046	# define R300_FPITX_OPCODE_SHIFT 15
1047	# define R300_FPITX_OP_TEX 1
1048	# define R300_FPITX_OP_KIL 2
1049	# define R300_FPITX_OP_TXP 3
1050	# define R300_FPITX_OP_TXB 4
1051	# define R300_FPITX_OPCODE_MASK (7 << 15)
1052
1053	/* ALU
1054	* The ALU instructions register blocks are enumerated according to the order
1055	* in which fglrx. I assume there is space for 64 instructions, since
1056	* each block has space for a maximum of 64 DWORDs, and this matches reported
1057	* native limits.
1058	*
1059	* The basic functional block seems to be one MAD for each color and alpha,
1060	* and an adder that adds all components after the MUL.
1061	* - ADD, MUL, MAD etc.: use MAD with appropriate neutral operands
1062	* - DP4: Use OUTC_DP4, OUTA_DP4
1063	* - DP3: Use OUTC_DP3, OUTA_DP4, appropriate alpha operands
1064	* - DPH: Use OUTC_DP4, OUTA_DP4, appropriate alpha operands
1065	* - CMPH: If ARG2 > 0.5, return ARG0, else return ARG1
1066	* - CMP: If ARG2 < 0, return ARG1, else return ARG0
1067	* - FLR: use FRC+MAD
1068	* - XPD: use MAD+MAD
1069	* - SGE, SLT: use MAD+CMP
1070	* - RSQ: use ABS modifier for argument
1071	* - Use OUTC_REPL_ALPHA to write results of an alpha-only operation
1072	* (e.g. RCP) into color register
1073	* - apparently, there's no quick DST operation
1074	* - fglrx set FPI2_UNKNOWN_31 on a "MAD fragment.color, tmp0, tmp1, tmp2"
1075	* - fglrx set FPI2_UNKNOWN_31 on a "MAX r2, r1, c0"
1076	* - fglrx once set FPI0_UNKNOWN_31 on a "FRC r1, r1"
1077	*
1078	* Operand selection
1079	* First stage selects three sources from the available registers and
1080	* constant parameters. This is defined in INSTR1 (color) and INSTR3 (alpha).
1081	* fglrx sorts the three source fields: Registers before constants,
1082	* lower indices before higher indices; I do not know whether this is
1083	* necessary.
1084	*
1085	* fglrx fills unused sources with "read constant 0"
1086	* According to specs, you cannot select more than two different constants.
1087	*
1088	* Second stage selects the operands from the sources. This is defined in
1089	* INSTR0 (color) and INSTR2 (alpha). You can also select the special constants
1090	* zero and one.
1091	* Swizzling and negation happens in this stage, as well.
1092	*
1093	* Important: Color and alpha seem to be mostly separate, i.e. their sources
1094	* selection appears to be fully independent (the register storage is probably
1095	* physically split into a color and an alpha section).
1096	* However (because of the apparent physical split), there is some interaction
1097	* WRT swizzling. If, for example, you want to load an R component into an
1098	* Alpha operand, this R component is taken from a *color* source, not from
1099	* an alpha source. The corresponding register doesn't even have to appear in
1100	* the alpha sources list. (I hope this all makes sense to you)
1101	*
1102	* Destination selection
1103	* The destination register index is in FPI1 (color) and FPI3 (alpha)
1104	* together with enable bits.
1105	* There are separate enable bits for writing into temporary registers
1106	* (DSTC_REG_* /DSTA_REG) and program output registers (DSTC_OUTPUT_*
1107	* /DSTA_OUTPUT). You can write to both at once, or not write at all (the
1108	* same index must be used for both).
1109	*
1110	* Note: There is a special form for LRP
1111	* - Argument order is the same as in ARB_fragment_program.
1112	* - Operation is MAD
1113	* - ARG1 is set to ARGC_SRC1C_LRP/ARGC_SRC1A_LRP
1114	* - Set FPI0/FPI2_SPECIAL_LRP
1115	* Arbitrary LRP (including support for swizzling) requires vanilla MAD+MAD
1116	*/
1117	#define R300_PFS_INSTR1_0 0x46C0
1118	# define R300_FPI1_SRC0C_SHIFT 0
1119	# define R300_FPI1_SRC0C_MASK (31 << 0)
1120	# define R300_FPI1_SRC0C_CONST (1 << 5)
1121	# define R300_FPI1_SRC1C_SHIFT 6
1122	# define R300_FPI1_SRC1C_MASK (31 << 6)
1123	# define R300_FPI1_SRC1C_CONST (1 << 11)
1124	# define R300_FPI1_SRC2C_SHIFT 12
1125	# define R300_FPI1_SRC2C_MASK (31 << 12)
1126	# define R300_FPI1_SRC2C_CONST (1 << 17)
1127	# define R300_FPI1_SRC_MASK 0x0003ffff
1128	# define R300_FPI1_DSTC_SHIFT 18
1129	# define R300_FPI1_DSTC_MASK (31 << 18)
1130	# define R300_FPI1_DSTC_REG_MASK_SHIFT 23
1131	# define R300_FPI1_DSTC_REG_X (1 << 23)
1132	# define R300_FPI1_DSTC_REG_Y (1 << 24)
1133	# define R300_FPI1_DSTC_REG_Z (1 << 25)
1134	# define R300_FPI1_DSTC_OUTPUT_MASK_SHIFT 26
1135	# define R300_FPI1_DSTC_OUTPUT_X (1 << 26)
1136	# define R300_FPI1_DSTC_OUTPUT_Y (1 << 27)
1137	# define R300_FPI1_DSTC_OUTPUT_Z (1 << 28)
1138
1139	#define R300_PFS_INSTR3_0 0x47C0
1140	# define R300_FPI3_SRC0A_SHIFT 0
1141	# define R300_FPI3_SRC0A_MASK (31 << 0)
1142	# define R300_FPI3_SRC0A_CONST (1 << 5)
1143	# define R300_FPI3_SRC1A_SHIFT 6
1144	# define R300_FPI3_SRC1A_MASK (31 << 6)
1145	# define R300_FPI3_SRC1A_CONST (1 << 11)
1146	# define R300_FPI3_SRC2A_SHIFT 12
1147	# define R300_FPI3_SRC2A_MASK (31 << 12)
1148	# define R300_FPI3_SRC2A_CONST (1 << 17)
1149	# define R300_FPI3_SRC_MASK 0x0003ffff
1150	# define R300_FPI3_DSTA_SHIFT 18
1151	# define R300_FPI3_DSTA_MASK (31 << 18)
1152	# define R300_FPI3_DSTA_REG (1 << 23)
1153	# define R300_FPI3_DSTA_OUTPUT (1 << 24)
1154	# define R300_FPI3_DSTA_DEPTH (1 << 27)
1155
1156	#define R300_PFS_INSTR0_0 0x48C0
1157	# define R300_FPI0_ARGC_SRC0C_XYZ 0
1158	# define R300_FPI0_ARGC_SRC0C_XXX 1
1159	# define R300_FPI0_ARGC_SRC0C_YYY 2
1160	# define R300_FPI0_ARGC_SRC0C_ZZZ 3
1161	# define R300_FPI0_ARGC_SRC1C_XYZ 4
1162	# define R300_FPI0_ARGC_SRC1C_XXX 5
1163	# define R300_FPI0_ARGC_SRC1C_YYY 6
1164	# define R300_FPI0_ARGC_SRC1C_ZZZ 7
1165	# define R300_FPI0_ARGC_SRC2C_XYZ 8
1166	# define R300_FPI0_ARGC_SRC2C_XXX 9
1167	# define R300_FPI0_ARGC_SRC2C_YYY 10
1168	# define R300_FPI0_ARGC_SRC2C_ZZZ 11
1169	# define R300_FPI0_ARGC_SRC0A 12
1170	# define R300_FPI0_ARGC_SRC1A 13
1171	# define R300_FPI0_ARGC_SRC2A 14
1172	# define R300_FPI0_ARGC_SRC1C_LRP 15
1173	# define R300_FPI0_ARGC_ZERO 20
1174	# define R300_FPI0_ARGC_ONE 21
1175	/* GUESS */
1176	# define R300_FPI0_ARGC_HALF 22
1177	# define R300_FPI0_ARGC_SRC0C_YZX 23
1178	# define R300_FPI0_ARGC_SRC1C_YZX 24
1179	# define R300_FPI0_ARGC_SRC2C_YZX 25
1180	# define R300_FPI0_ARGC_SRC0C_ZXY 26
1181	# define R300_FPI0_ARGC_SRC1C_ZXY 27
1182	# define R300_FPI0_ARGC_SRC2C_ZXY 28
1183	# define R300_FPI0_ARGC_SRC0CA_WZY 29
1184	# define R300_FPI0_ARGC_SRC1CA_WZY 30
1185	# define R300_FPI0_ARGC_SRC2CA_WZY 31
1186
1187	# define R300_FPI0_ARG0C_SHIFT 0
1188	# define R300_FPI0_ARG0C_MASK (31 << 0)
1189	# define R300_FPI0_ARG0C_NEG (1 << 5)
1190	# define R300_FPI0_ARG0C_ABS (1 << 6)
1191	# define R300_FPI0_ARG1C_SHIFT 7
1192	# define R300_FPI0_ARG1C_MASK (31 << 7)
1193	# define R300_FPI0_ARG1C_NEG (1 << 12)
1194	# define R300_FPI0_ARG1C_ABS (1 << 13)
1195	# define R300_FPI0_ARG2C_SHIFT 14
1196	# define R300_FPI0_ARG2C_MASK (31 << 14)
1197	# define R300_FPI0_ARG2C_NEG (1 << 19)
1198	# define R300_FPI0_ARG2C_ABS (1 << 20)
1199	# define R300_FPI0_SPECIAL_LRP (1 << 21)
1200	# define R300_FPI0_OUTC_MAD (0 << 23)
1201	# define R300_FPI0_OUTC_DP3 (1 << 23)
1202	# define R300_FPI0_OUTC_DP4 (2 << 23)
1203	# define R300_FPI0_OUTC_MIN (4 << 23)
1204	# define R300_FPI0_OUTC_MAX (5 << 23)
1205	# define R300_FPI0_OUTC_CMPH (7 << 23)
1206	# define R300_FPI0_OUTC_CMP (8 << 23)
1207	# define R300_FPI0_OUTC_FRC (9 << 23)
1208	# define R300_FPI0_OUTC_REPL_ALPHA (10 << 23)
1209	# define R300_FPI0_OUTC_SAT (1 << 30)
1210	# define R300_FPI0_INSERT_NOP (1 << 31)
1211
1212	#define R300_PFS_INSTR2_0 0x49C0
1213	# define R300_FPI2_ARGA_SRC0C_X 0
1214	# define R300_FPI2_ARGA_SRC0C_Y 1
1215	# define R300_FPI2_ARGA_SRC0C_Z 2
1216	# define R300_FPI2_ARGA_SRC1C_X 3
1217	# define R300_FPI2_ARGA_SRC1C_Y 4
1218	# define R300_FPI2_ARGA_SRC1C_Z 5
1219	# define R300_FPI2_ARGA_SRC2C_X 6
1220	# define R300_FPI2_ARGA_SRC2C_Y 7
1221	# define R300_FPI2_ARGA_SRC2C_Z 8
1222	# define R300_FPI2_ARGA_SRC0A 9
1223	# define R300_FPI2_ARGA_SRC1A 10
1224	# define R300_FPI2_ARGA_SRC2A 11
1225	# define R300_FPI2_ARGA_SRC1A_LRP 15
1226	# define R300_FPI2_ARGA_ZERO 16
1227	# define R300_FPI2_ARGA_ONE 17
1228	/* GUESS */
1229	# define R300_FPI2_ARGA_HALF 18
1230	# define R300_FPI2_ARG0A_SHIFT 0
1231	# define R300_FPI2_ARG0A_MASK (31 << 0)
1232	# define R300_FPI2_ARG0A_NEG (1 << 5)
1233	/* GUESS */
1234	# define R300_FPI2_ARG0A_ABS (1 << 6)
1235	# define R300_FPI2_ARG1A_SHIFT 7
1236	# define R300_FPI2_ARG1A_MASK (31 << 7)
1237	# define R300_FPI2_ARG1A_NEG (1 << 12)
1238	/* GUESS */
1239	# define R300_FPI2_ARG1A_ABS (1 << 13)
1240	# define R300_FPI2_ARG2A_SHIFT 14
1241	# define R300_FPI2_ARG2A_MASK (31 << 14)
1242	# define R300_FPI2_ARG2A_NEG (1 << 19)
1243	/* GUESS */
1244	# define R300_FPI2_ARG2A_ABS (1 << 20)
1245	# define R300_FPI2_SPECIAL_LRP (1 << 21)
1246	# define R300_FPI2_OUTA_MAD (0 << 23)
1247	# define R300_FPI2_OUTA_DP4 (1 << 23)
1248	# define R300_FPI2_OUTA_MIN (2 << 23)
1249	# define R300_FPI2_OUTA_MAX (3 << 23)
1250	# define R300_FPI2_OUTA_CMP (6 << 23)
1251	# define R300_FPI2_OUTA_FRC (7 << 23)
1252	# define R300_FPI2_OUTA_EX2 (8 << 23)
1253	# define R300_FPI2_OUTA_LG2 (9 << 23)
1254	# define R300_FPI2_OUTA_RCP (10 << 23)
1255	# define R300_FPI2_OUTA_RSQ (11 << 23)
1256	# define R300_FPI2_OUTA_SAT (1 << 30)
1257	# define R300_FPI2_UNKNOWN_31 (1 << 31)
1258	/* END: Fragment program instruction set */
1259
1260	/* Fog state and color */
1261	#define R300_RE_FOG_STATE 0x4BC0
1262	# define R300_FOG_ENABLE (1 << 0)
1263	# define R300_FOG_MODE_LINEAR (0 << 1)
1264	# define R300_FOG_MODE_EXP (1 << 1)
1265	# define R300_FOG_MODE_EXP2 (2 << 1)
1266	# define R300_FOG_MODE_MASK (3 << 1)
1267	#define R300_FOG_COLOR_R 0x4BC8
1268	#define R300_FOG_COLOR_G 0x4BCC
1269	#define R300_FOG_COLOR_B 0x4BD0
1270
1271	#define R300_PP_ALPHA_TEST 0x4BD4
1272	# define R300_REF_ALPHA_MASK 0x000000ff
1273	# define R300_ALPHA_TEST_FAIL (0 << 8)
1274	# define R300_ALPHA_TEST_LESS (1 << 8)
1275	# define R300_ALPHA_TEST_LEQUAL (3 << 8)
1276	# define R300_ALPHA_TEST_EQUAL (2 << 8)
1277	# define R300_ALPHA_TEST_GEQUAL (6 << 8)
1278	# define R300_ALPHA_TEST_GREATER (4 << 8)
1279	# define R300_ALPHA_TEST_NEQUAL (5 << 8)
1280	# define R300_ALPHA_TEST_PASS (7 << 8)
1281	# define R300_ALPHA_TEST_OP_MASK (7 << 8)
1282	# define R300_ALPHA_TEST_ENABLE (1 << 11)
1283
1284	/* gap */
1285
1286	/* Fragment program parameters in 7.16 floating point */
1287	#define R300_PFS_PARAM_0_X 0x4C00
1288	#define R300_PFS_PARAM_0_Y 0x4C04
1289	#define R300_PFS_PARAM_0_Z 0x4C08
1290	#define R300_PFS_PARAM_0_W 0x4C0C
1291	/* GUESS: PARAM_31 is last, based on native limits reported by fglrx */
1292	#define R300_PFS_PARAM_31_X 0x4DF0
1293	#define R300_PFS_PARAM_31_Y 0x4DF4
1294	#define R300_PFS_PARAM_31_Z 0x4DF8
1295	#define R300_PFS_PARAM_31_W 0x4DFC
1296
1297	/* Notes:
1298	* - AFAIK fglrx always sets BLEND_UNKNOWN when blending is used in
1299	* the application
1300	* - AFAIK fglrx always sets BLEND_NO_SEPARATE when CBLEND and ABLEND
1301	* are set to the same
1302	* function (both registers are always set up completely in any case)
1303	* - Most blend flags are simply copied from R200 and not tested yet
1304	*/
1305	#define R300_RB3D_CBLEND 0x4E04
1306	#define R300_RB3D_ABLEND 0x4E08
1307	/* the following only appear in CBLEND */
1308	# define R300_BLEND_ENABLE (1 << 0)
1309	# define R300_BLEND_UNKNOWN (3 << 1)
1310	# define R300_BLEND_NO_SEPARATE (1 << 3)
1311	/* the following are shared between CBLEND and ABLEND */
1312	# define R300_FCN_MASK (3 << 12)
1313	# define R300_COMB_FCN_ADD_CLAMP (0 << 12)
1314	# define R300_COMB_FCN_ADD_NOCLAMP (1 << 12)
1315	# define R300_COMB_FCN_SUB_CLAMP (2 << 12)
1316	# define R300_COMB_FCN_SUB_NOCLAMP (3 << 12)
1317	# define R300_COMB_FCN_MIN (4 << 12)
1318	# define R300_COMB_FCN_MAX (5 << 12)
1319	# define R300_COMB_FCN_RSUB_CLAMP (6 << 12)
1320	# define R300_COMB_FCN_RSUB_NOCLAMP (7 << 12)
1321	# define R300_BLEND_GL_ZERO (32)
1322	# define R300_BLEND_GL_ONE (33)
1323	# define R300_BLEND_GL_SRC_COLOR (34)
1324	# define R300_BLEND_GL_ONE_MINUS_SRC_COLOR (35)
1325	# define R300_BLEND_GL_DST_COLOR (36)
1326	# define R300_BLEND_GL_ONE_MINUS_DST_COLOR (37)
1327	# define R300_BLEND_GL_SRC_ALPHA (38)
1328	# define R300_BLEND_GL_ONE_MINUS_SRC_ALPHA (39)
1329	# define R300_BLEND_GL_DST_ALPHA (40)
1330	# define R300_BLEND_GL_ONE_MINUS_DST_ALPHA (41)
1331	# define R300_BLEND_GL_SRC_ALPHA_SATURATE (42)
1332	# define R300_BLEND_GL_CONST_COLOR (43)
1333	# define R300_BLEND_GL_ONE_MINUS_CONST_COLOR (44)
1334	# define R300_BLEND_GL_CONST_ALPHA (45)
1335	# define R300_BLEND_GL_ONE_MINUS_CONST_ALPHA (46)
1336	# define R300_BLEND_MASK (63)
1337	# define R300_SRC_BLEND_SHIFT (16)
1338	# define R300_DST_BLEND_SHIFT (24)
1339	#define R300_RB3D_BLEND_COLOR 0x4E10
1340	#define R300_RB3D_COLORMASK 0x4E0C
1341	# define R300_COLORMASK0_B (1<<0)
1342	# define R300_COLORMASK0_G (1<<1)
1343	# define R300_COLORMASK0_R (1<<2)
1344	# define R300_COLORMASK0_A (1<<3)
1345
1346	/* gap */
1347
1348	#define R300_RB3D_COLOROFFSET0 0x4E28
1349	# define R300_COLOROFFSET_MASK 0xFFFFFFF0 /* GUESS */
1350	#define R300_RB3D_COLOROFFSET1 0x4E2C /* GUESS */
1351	#define R300_RB3D_COLOROFFSET2 0x4E30 /* GUESS */
1352	#define R300_RB3D_COLOROFFSET3 0x4E34 /* GUESS */
1353
1354	/* gap */
1355
1356	/* Bit 16: Larger tiles
1357	* Bit 17: 4x2 tiles
1358	* Bit 18: Extremely weird tile like, but some pixels duplicated?
1359	*/
1360	#define R300_RB3D_COLORPITCH0 0x4E38
1361	# define R300_COLORPITCH_MASK 0x00001FF8 /* GUESS */
1362	# define R300_COLOR_TILE_ENABLE (1 << 16) /* GUESS */
1363	# define R300_COLOR_MICROTILE_ENABLE (1 << 17) /* GUESS */
1364	# define R300_COLOR_MICROTILE_SQUARE_ENABLE (2 << 17)
1365	# define R300_COLOR_ENDIAN_NO_SWAP (0 << 18) /* GUESS */
1366	# define R300_COLOR_ENDIAN_WORD_SWAP (1 << 18) /* GUESS */
1367	# define R300_COLOR_ENDIAN_DWORD_SWAP (2 << 18) /* GUESS */
1368	# define R300_COLOR_FORMAT_RGB565 (2 << 22)
1369	# define R300_COLOR_FORMAT_ARGB8888 (3 << 22)
1370	#define R300_RB3D_COLORPITCH1 0x4E3C /* GUESS */
1371	#define R300_RB3D_COLORPITCH2 0x4E40 /* GUESS */
1372	#define R300_RB3D_COLORPITCH3 0x4E44 /* GUESS */
1373
1374	#define R300_RB3D_AARESOLVE_OFFSET 0x4E80
1375	#define R300_RB3D_AARESOLVE_PITCH 0x4E84
1376	#define R300_RB3D_AARESOLVE_CTL 0x4E88
1377	/* gap */
1378
1379	/* Guess by Vladimir.
1380	* Set to 0A before 3D operations, set to 02 afterwards.
1381	*/
1382	/*#define R300_RB3D_DSTCACHE_CTLSTAT 0x4E4C*/
1383	# define R300_RB3D_DSTCACHE_UNKNOWN_02 0x00000002
1384	# define R300_RB3D_DSTCACHE_UNKNOWN_0A 0x0000000A
1385
1386	/* gap */
1387	/* There seems to be no "write only" setting, so use Z-test = ALWAYS
1388	* for this.
1389	* Bit (1<<8) is the "test" bit. so plain write is 6 - vd
1390	*/
1391	#define R300_ZB_CNTL 0x4F00
1392	# define R300_STENCIL_ENABLE (1 << 0)
1393	# define R300_Z_ENABLE (1 << 1)
1394	# define R300_Z_WRITE_ENABLE (1 << 2)
1395	# define R300_Z_SIGNED_COMPARE (1 << 3)
1396	# define R300_STENCIL_FRONT_BACK (1 << 4)
1397
1398	#define R300_ZB_ZSTENCILCNTL 0x4f04
1399	/* functions */
1400	# define R300_ZS_NEVER 0
1401	# define R300_ZS_LESS 1
1402	# define R300_ZS_LEQUAL 2
1403	# define R300_ZS_EQUAL 3
1404	# define R300_ZS_GEQUAL 4
1405	# define R300_ZS_GREATER 5
1406	# define R300_ZS_NOTEQUAL 6
1407	# define R300_ZS_ALWAYS 7
1408	# define R300_ZS_MASK 7
1409	/* operations */
1410	# define R300_ZS_KEEP 0
1411	# define R300_ZS_ZERO 1
1412	# define R300_ZS_REPLACE 2
1413	# define R300_ZS_INCR 3
1414	# define R300_ZS_DECR 4
1415	# define R300_ZS_INVERT 5
1416	# define R300_ZS_INCR_WRAP 6
1417	# define R300_ZS_DECR_WRAP 7
1418	# define R300_Z_FUNC_SHIFT 0
1419	/* front and back refer to operations done for front
1420	and back faces, i.e. separate stencil function support */
1421	# define R300_S_FRONT_FUNC_SHIFT 3
1422	# define R300_S_FRONT_SFAIL_OP_SHIFT 6
1423	# define R300_S_FRONT_ZPASS_OP_SHIFT 9
1424	# define R300_S_FRONT_ZFAIL_OP_SHIFT 12
1425	# define R300_S_BACK_FUNC_SHIFT 15
1426	# define R300_S_BACK_SFAIL_OP_SHIFT 18
1427	# define R300_S_BACK_ZPASS_OP_SHIFT 21
1428	# define R300_S_BACK_ZFAIL_OP_SHIFT 24
1429
1430	#define R300_ZB_STENCILREFMASK 0x4f08
1431	# define R300_STENCILREF_SHIFT 0
1432	# define R300_STENCILREF_MASK 0x000000ff
1433	# define R300_STENCILMASK_SHIFT 8
1434	# define R300_STENCILMASK_MASK 0x0000ff00
1435	# define R300_STENCILWRITEMASK_SHIFT 16
1436	# define R300_STENCILWRITEMASK_MASK 0x00ff0000
1437
1438	/* gap */
1439
1440	#define R300_ZB_FORMAT 0x4f10
1441	# define R300_DEPTHFORMAT_16BIT_INT_Z (0 << 0)
1442	# define R300_DEPTHFORMAT_16BIT_13E3 (1 << 0)
1443	# define R300_DEPTHFORMAT_24BIT_INT_Z_8BIT_STENCIL (2 << 0)
1444	/* reserved up to (15 << 0) */
1445	# define R300_INVERT_13E3_LEADING_ONES (0 << 4)
1446	# define R300_INVERT_13E3_LEADING_ZEROS (1 << 4)
1447
1448	#define R300_ZB_ZTOP 0x4F14
1449	# define R300_ZTOP_DISABLE (0 << 0)
1450	# define R300_ZTOP_ENABLE (1 << 0)
1451
1452	/* gap */
1453
1454	#define R300_ZB_ZCACHE_CTLSTAT 0x4f18
1455	# define R300_ZB_ZCACHE_CTLSTAT_ZC_FLUSH_NO_EFFECT (0 << 0)
1456	# define R300_ZB_ZCACHE_CTLSTAT_ZC_FLUSH_FLUSH_AND_FREE (1 << 0)
1457	# define R300_ZB_ZCACHE_CTLSTAT_ZC_FREE_NO_EFFECT (0 << 1)
1458	# define R300_ZB_ZCACHE_CTLSTAT_ZC_FREE_FREE (1 << 1)
1459	# define R300_ZB_ZCACHE_CTLSTAT_ZC_BUSY_IDLE (0 << 31)
1460	# define R300_ZB_ZCACHE_CTLSTAT_ZC_BUSY_BUSY (1 << 31)
1461
1462	#define R300_ZB_BW_CNTL 0x4f1c
1463	# define R300_HIZ_DISABLE (0 << 0)
1464	# define R300_HIZ_ENABLE (1 << 0)
1465	# define R300_HIZ_MIN (0 << 1)
1466	# define R300_HIZ_MAX (1 << 1)
1467	# define R300_FAST_FILL_DISABLE (0 << 2)
1468	# define R300_FAST_FILL_ENABLE (1 << 2)
1469	# define R300_RD_COMP_DISABLE (0 << 3)
1470	# define R300_RD_COMP_ENABLE (1 << 3)
1471	# define R300_WR_COMP_DISABLE (0 << 4)
1472	# define R300_WR_COMP_ENABLE (1 << 4)
1473	# define R300_ZB_CB_CLEAR_RMW (0 << 5)
1474	# define R300_ZB_CB_CLEAR_CACHE_LINEAR (1 << 5)
1475	# define R300_FORCE_COMPRESSED_STENCIL_VALUE_DISABLE (0 << 6)
1476	# define R300_FORCE_COMPRESSED_STENCIL_VALUE_ENABLE (1 << 6)
1477
1478	# define R500_ZEQUAL_OPTIMIZE_ENABLE (0 << 7)
1479	# define R500_ZEQUAL_OPTIMIZE_DISABLE (1 << 7)
1480	# define R500_SEQUAL_OPTIMIZE_ENABLE (0 << 8)
1481	# define R500_SEQUAL_OPTIMIZE_DISABLE (1 << 8)
1482
1483	# define R500_BMASK_ENABLE (0 << 10)
1484	# define R500_BMASK_DISABLE (1 << 10)
1485	# define R500_HIZ_EQUAL_REJECT_DISABLE (0 << 11)
1486	# define R500_HIZ_EQUAL_REJECT_ENABLE (1 << 11)
1487	# define R500_HIZ_FP_EXP_BITS_DISABLE (0 << 12)
1488	# define R500_HIZ_FP_EXP_BITS_1 (1 << 12)
1489	# define R500_HIZ_FP_EXP_BITS_2 (2 << 12)
1490	# define R500_HIZ_FP_EXP_BITS_3 (3 << 12)
1491	# define R500_HIZ_FP_EXP_BITS_4 (4 << 12)
1492	# define R500_HIZ_FP_EXP_BITS_5 (5 << 12)
1493	# define R500_HIZ_FP_INVERT_LEADING_ONES (0 << 15)
1494	# define R500_HIZ_FP_INVERT_LEADING_ZEROS (1 << 15)
1495	# define R500_TILE_OVERWRITE_RECOMPRESSION_ENABLE (0 << 16)
1496	# define R500_TILE_OVERWRITE_RECOMPRESSION_DISABLE (1 << 16)
1497	# define R500_CONTIGUOUS_6XAA_SAMPLES_ENABLE (0 << 17)
1498	# define R500_CONTIGUOUS_6XAA_SAMPLES_DISABLE (1 << 17)
1499	# define R500_PEQ_PACKING_DISABLE (0 << 18)
1500	# define R500_PEQ_PACKING_ENABLE (1 << 18)
1501	# define R500_COVERED_PTR_MASKING_DISABLE (0 << 18)
1502	# define R500_COVERED_PTR_MASKING_ENABLE (1 << 18)
1503
1504
1505	/* gap */
1506
1507	/* Z Buffer Address Offset.
1508	* Bits 31 to 5 are used for aligned Z buffer address offset for macro tiles.
1509	*/
1510	#define R300_ZB_DEPTHOFFSET 0x4f20
1511
1512	/* Z Buffer Pitch and Endian Control */
1513	#define R300_ZB_DEPTHPITCH 0x4f24
1514	# define R300_DEPTHPITCH_MASK 0x00003FFC
1515	# define R300_DEPTHMACROTILE_DISABLE (0 << 16)
1516	# define R300_DEPTHMACROTILE_ENABLE (1 << 16)
1517	# define R300_DEPTHMICROTILE_LINEAR (0 << 17)
1518	# define R300_DEPTHMICROTILE_TILED (1 << 17)
1519	# define R300_DEPTHMICROTILE_TILED_SQUARE (2 << 17)
1520	# define R300_DEPTHENDIAN_NO_SWAP (0 << 18)
1521	# define R300_DEPTHENDIAN_WORD_SWAP (1 << 18)
1522	# define R300_DEPTHENDIAN_DWORD_SWAP (2 << 18)
1523	# define R300_DEPTHENDIAN_HALF_DWORD_SWAP (3 << 18)
1524
1525	/* Z Buffer Clear Value */
1526	#define R300_ZB_DEPTHCLEARVALUE 0x4f28
1527
1528	#define R300_ZB_ZMASK_OFFSET 0x4f30
1529	#define R300_ZB_ZMASK_PITCH 0x4f34
1530	#define R300_ZB_ZMASK_WRINDEX 0x4f38
1531	#define R300_ZB_ZMASK_DWORD 0x4f3c
1532	#define R300_ZB_ZMASK_RDINDEX 0x4f40
1533
1534	/* Hierarchical Z Memory Offset */
1535	#define R300_ZB_HIZ_OFFSET 0x4f44
1536
1537	/* Hierarchical Z Write Index */
1538	#define R300_ZB_HIZ_WRINDEX 0x4f48
1539
1540	/* Hierarchical Z Data */
1541	#define R300_ZB_HIZ_DWORD 0x4f4c
1542
1543	/* Hierarchical Z Read Index */
1544	#define R300_ZB_HIZ_RDINDEX 0x4f50
1545
1546	/* Hierarchical Z Pitch */
1547	#define R300_ZB_HIZ_PITCH 0x4f54
1548
1549	/* Z Buffer Z Pass Counter Data */
1550	#define R300_ZB_ZPASS_DATA 0x4f58
1551
1552	/* Z Buffer Z Pass Counter Address */
1553	#define R300_ZB_ZPASS_ADDR 0x4f5c
1554
1555	/* Depth buffer X and Y coordinate offset */
1556	#define R300_ZB_DEPTHXY_OFFSET 0x4f60
1557	# define R300_DEPTHX_OFFSET_SHIFT 1
1558	# define R300_DEPTHX_OFFSET_MASK 0x000007FE
1559	# define R300_DEPTHY_OFFSET_SHIFT 17
1560	# define R300_DEPTHY_OFFSET_MASK 0x07FE0000
1561
1562	/* Sets the fifo sizes */
1563	#define R500_ZB_FIFO_SIZE 0x4fd0
1564	# define R500_OP_FIFO_SIZE_FULL (0 << 0)
1565	# define R500_OP_FIFO_SIZE_HALF (1 << 0)
1566	# define R500_OP_FIFO_SIZE_QUATER (2 << 0)
1567	# define R500_OP_FIFO_SIZE_EIGTHS (4 << 0)
1568
1569	/* Stencil Reference Value and Mask for backfacing quads */
1570	/* R300_ZB_STENCILREFMASK handles front face */
1571	#define R500_ZB_STENCILREFMASK_BF 0x4fd4
1572	# define R500_STENCILREF_SHIFT 0
1573	# define R500_STENCILREF_MASK 0x000000ff
1574	# define R500_STENCILMASK_SHIFT 8
1575	# define R500_STENCILMASK_MASK 0x0000ff00
1576	# define R500_STENCILWRITEMASK_SHIFT 16
1577	# define R500_STENCILWRITEMASK_MASK 0x00ff0000
1578
1579	/* BEGIN: Vertex program instruction set */
1580
1581	/* Every instruction is four dwords long:
1582	* DWORD 0: output and opcode
1583	* DWORD 1: first argument
1584	* DWORD 2: second argument
1585	* DWORD 3: third argument
1586	*
1587	* Notes:
1588	* - ABS r, a is implemented as MAX r, a, -a
1589	* - MOV is implemented as ADD to zero
1590	* - XPD is implemented as MUL + MAD
1591	* - FLR is implemented as FRC + ADD
1592	* - apparently, fglrx tries to schedule instructions so that there is at
1593	* least one instruction between the write to a temporary and the first
1594	* read from said temporary; however, violations of this scheduling are
1595	* allowed
1596	* - register indices seem to be unrelated with OpenGL aliasing to
1597	* conventional state
1598	* - only one attribute and one parameter can be loaded at a time; however,
1599	* the same attribute/parameter can be used for more than one argument
1600	* - the second software argument for POW is the third hardware argument
1601	* (no idea why)
1602	* - MAD with only temporaries as input seems to use VPI_OUT_SELECT_MAD_2
1603	*
1604	* There is some magic surrounding LIT:
1605	* The single argument is replicated across all three inputs, but swizzled:
1606	* First argument: xyzy
1607	* Second argument: xyzx
1608	* Third argument: xyzw
1609	* Whenever the result is used later in the fragment program, fglrx forces
1610	* x and w to be 1.0 in the input selection; I don't know whether this is
1611	* strictly necessary
1612	*/
1613	#define R300_VPI_OUT_OP_DOT (1 << 0)
1614	#define R300_VPI_OUT_OP_MUL (2 << 0)
1615	#define R300_VPI_OUT_OP_ADD (3 << 0)
1616	#define R300_VPI_OUT_OP_MAD (4 << 0)
1617	#define R300_VPI_OUT_OP_DST (5 << 0)
1618	#define R300_VPI_OUT_OP_FRC (6 << 0)
1619	#define R300_VPI_OUT_OP_MAX (7 << 0)
1620	#define R300_VPI_OUT_OP_MIN (8 << 0)
1621	#define R300_VPI_OUT_OP_SGE (9 << 0)
1622	#define R300_VPI_OUT_OP_SLT (10 << 0)
1623	/* Used in GL_POINT_DISTANCE_ATTENUATION_ARB, vector(scalar, vector) */
1624	#define R300_VPI_OUT_OP_UNK12 (12 << 0)
1625	#define R300_VPI_OUT_OP_ARL (13 << 0)
1626	#define R300_VPI_OUT_OP_EXP (65 << 0)
1627	#define R300_VPI_OUT_OP_LOG (66 << 0)
1628	/* Used in fog computations, scalar(scalar) */
1629	#define R300_VPI_OUT_OP_UNK67 (67 << 0)
1630	#define R300_VPI_OUT_OP_LIT (68 << 0)
1631	#define R300_VPI_OUT_OP_POW (69 << 0)
1632	#define R300_VPI_OUT_OP_RCP (70 << 0)
1633	#define R300_VPI_OUT_OP_RSQ (72 << 0)
1634	/* Used in GL_POINT_DISTANCE_ATTENUATION_ARB, scalar(scalar) */
1635	#define R300_VPI_OUT_OP_UNK73 (73 << 0)
1636	#define R300_VPI_OUT_OP_EX2 (75 << 0)
1637	#define R300_VPI_OUT_OP_LG2 (76 << 0)
1638	#define R300_VPI_OUT_OP_MAD_2 (128 << 0)
1639	/* all temps, vector(scalar, vector, vector) */
1640	#define R300_VPI_OUT_OP_UNK129 (129 << 0)
1641
1642	#define R300_VPI_OUT_REG_CLASS_TEMPORARY (0 << 8)
1643	#define R300_VPI_OUT_REG_CLASS_ADDR (1 << 8)
1644	#define R300_VPI_OUT_REG_CLASS_RESULT (2 << 8)
1645	#define R300_VPI_OUT_REG_CLASS_MASK (31 << 8)
1646
1647	#define R300_VPI_OUT_REG_INDEX_SHIFT 13
1648	/* GUESS based on fglrx native limits */
1649	#define R300_VPI_OUT_REG_INDEX_MASK (31 << 13)
1650
1651	#define R300_VPI_OUT_WRITE_X (1 << 20)
1652	#define R300_VPI_OUT_WRITE_Y (1 << 21)
1653	#define R300_VPI_OUT_WRITE_Z (1 << 22)
1654	#define R300_VPI_OUT_WRITE_W (1 << 23)
1655
1656	#define R300_VPI_IN_REG_CLASS_TEMPORARY (0 << 0)
1657	#define R300_VPI_IN_REG_CLASS_ATTRIBUTE (1 << 0)
1658	#define R300_VPI_IN_REG_CLASS_PARAMETER (2 << 0)
1659	#define R300_VPI_IN_REG_CLASS_NONE (9 << 0)
1660	#define R300_VPI_IN_REG_CLASS_MASK (31 << 0)
1661
1662	#define R300_VPI_IN_REG_INDEX_SHIFT 5
1663	/* GUESS based on fglrx native limits */
1664	#define R300_VPI_IN_REG_INDEX_MASK (255 << 5)
1665
1666	/* The R300 can select components from the input register arbitrarily.
1667	* Use the following constants, shifted by the component shift you
1668	* want to select
1669	*/
1670	#define R300_VPI_IN_SELECT_X 0
1671	#define R300_VPI_IN_SELECT_Y 1
1672	#define R300_VPI_IN_SELECT_Z 2
1673	#define R300_VPI_IN_SELECT_W 3
1674	#define R300_VPI_IN_SELECT_ZERO 4
1675	#define R300_VPI_IN_SELECT_ONE 5
1676	#define R300_VPI_IN_SELECT_MASK 7
1677
1678	#define R300_VPI_IN_X_SHIFT 13
1679	#define R300_VPI_IN_Y_SHIFT 16
1680	#define R300_VPI_IN_Z_SHIFT 19
1681	#define R300_VPI_IN_W_SHIFT 22
1682
1683	#define R300_VPI_IN_NEG_X (1 << 25)
1684	#define R300_VPI_IN_NEG_Y (1 << 26)
1685	#define R300_VPI_IN_NEG_Z (1 << 27)
1686	#define R300_VPI_IN_NEG_W (1 << 28)
1687	/* END: Vertex program instruction set */
1688
1689	/* BEGIN: Packet 3 commands */
1690
1691	/* A primitive emission dword. */
1692	#define R300_PRIM_TYPE_NONE (0 << 0)
1693	#define R300_PRIM_TYPE_POINT (1 << 0)
1694	#define R300_PRIM_TYPE_LINE (2 << 0)
1695	#define R300_PRIM_TYPE_LINE_STRIP (3 << 0)
1696	#define R300_PRIM_TYPE_TRI_LIST (4 << 0)
1697	#define R300_PRIM_TYPE_TRI_FAN (5 << 0)
1698	#define R300_PRIM_TYPE_TRI_STRIP (6 << 0)
1699	#define R300_PRIM_TYPE_TRI_TYPE2 (7 << 0)
1700	#define R300_PRIM_TYPE_RECT_LIST (8 << 0)
1701	#define R300_PRIM_TYPE_3VRT_POINT_LIST (9 << 0)
1702	#define R300_PRIM_TYPE_3VRT_LINE_LIST (10 << 0)
1703	/* GUESS (based on r200) */
1704	#define R300_PRIM_TYPE_POINT_SPRITES (11 << 0)
1705	#define R300_PRIM_TYPE_LINE_LOOP (12 << 0)
1706	#define R300_PRIM_TYPE_QUADS (13 << 0)
1707	#define R300_PRIM_TYPE_QUAD_STRIP (14 << 0)
1708	#define R300_PRIM_TYPE_POLYGON (15 << 0)
1709	#define R300_PRIM_TYPE_MASK 0xF
1710	#define R300_PRIM_WALK_IND (1 << 4)
1711	#define R300_PRIM_WALK_LIST (2 << 4)
1712	#define R300_PRIM_WALK_RING (3 << 4)
1713	#define R300_PRIM_WALK_MASK (3 << 4)
1714	/* GUESS (based on r200) */
1715	#define R300_PRIM_COLOR_ORDER_BGRA (0 << 6)
1716	#define R300_PRIM_COLOR_ORDER_RGBA (1 << 6)
1717	#define R300_PRIM_NUM_VERTICES_SHIFT 16
1718	#define R300_PRIM_NUM_VERTICES_MASK 0xffff
1719
1720	/* Draw a primitive from vertex data in arrays loaded via 3D_LOAD_VBPNTR.
1721	* Two parameter dwords:
1722	* 0. The first parameter appears to be always 0
1723	* 1. The second parameter is a standard primitive emission dword.
1724	*/
1725	#define R300_PACKET3_3D_DRAW_VBUF 0x00002800
1726
1727	/* Specify the full set of vertex arrays as (address, stride).
1728	* The first parameter is the number of vertex arrays specified.
1729	* The rest of the command is a variable length list of blocks, where
1730	* each block is three dwords long and specifies two arrays.
1731	* The first dword of a block is split into two words, the lower significant
1732	* word refers to the first array, the more significant word to the second
1733	* array in the block.
1734	* The low byte of each word contains the size of an array entry in dwords,
1735	* the high byte contains the stride of the array.
1736	* The second dword of a block contains the pointer to the first array,
1737	* the third dword of a block contains the pointer to the second array.
1738	* Note that if the total number of arrays is odd, the third dword of
1739	* the last block is omitted.
1740	*/
1741	#define R300_PACKET3_3D_LOAD_VBPNTR 0x00002F00
1742
1743	#define R300_PACKET3_INDX_BUFFER 0x00003300
1744	# define R300_EB_UNK1_SHIFT 24
1745	# define R300_EB_UNK1 (0x80<<24)
1746	# define R300_EB_UNK2 0x0810
1747	#define R300_PACKET3_3D_DRAW_VBUF_2 0x00003400
1748	#define R300_PACKET3_3D_DRAW_INDX_2 0x00003600
1749
1750	/* END: Packet 3 commands */
1751
1752
1753	/* Color formats for 2d packets
1754	*/
1755	#define R300_CP_COLOR_FORMAT_CI8 2
1756	#define R300_CP_COLOR_FORMAT_ARGB1555 3
1757	#define R300_CP_COLOR_FORMAT_RGB565 4
1758	#define R300_CP_COLOR_FORMAT_ARGB8888 6
1759	#define R300_CP_COLOR_FORMAT_RGB332 7
1760	#define R300_CP_COLOR_FORMAT_RGB8 9
1761	#define R300_CP_COLOR_FORMAT_ARGB4444 15
1762
1763	/*
1764	* CP type-3 packets
1765	*/
1766	#define R300_CP_CMD_BITBLT_MULTI 0xC0009B00
1767
1768	#define R500_VAP_INDEX_OFFSET 0x208c
1769
1770	#define R500_GA_US_VECTOR_INDEX 0x4250
1771	#define R500_GA_US_VECTOR_DATA 0x4254
1772
1773	#define R500_RS_IP_0 0x4074
1774	#define R500_RS_INST_0 0x4320
1775
1776	#define R500_US_CONFIG 0x4600
1777
1778	#define R500_US_FC_CTRL 0x4624
1779	#define R500_US_CODE_ADDR 0x4630
1780
1781	#define R500_RB3D_COLOR_CLEAR_VALUE_AR 0x46c0
1782	#define R500_RB3D_CONSTANT_COLOR_AR 0x4ef8
1783
1784	#define R300_SU_REG_DEST 0x42c8
1785	#define RV530_FG_ZBREG_DEST 0x4be8
1786	#define R300_ZB_ZPASS_DATA 0x4f58
1787	#define R300_ZB_ZPASS_ADDR 0x4f5c
1788
1789	#endif /* _R300_REG_H */
1790