2 * This program is free software; you can redistribute it and/or modify
3 * it under the terms of the GNU General Public License as published by
4 * the Free Software Foundation; either version 2 of the License, or
5 * (at your option) any later version.
7 * This program is distributed in the hope that it will be useful,
8 * but WITHOUT ANY WARRANTY; without even the implied warranty of
9 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
10 * GNU Library General Public License for more details.
12 * You should have received a copy of the GNU General Public License
13 * along with this program; if not, write to the Free Software
14 * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
18 * Someday its supposed to make use of the WT DMA engine
19 * for a Wavetable synthesizer.
23 #include "au88x0_wt.h"
25 static void vortex_fifo_setwtvalid(vortex_t
* vortex
, int fifo
, int en
);
26 static void vortex_connection_adb_mixin(vortex_t
* vortex
, int en
,
27 unsigned char channel
,
30 static void vortex_connection_mixin_mix(vortex_t
* vortex
, int en
,
32 unsigned char mix
, int a
);
33 static void vortex_fifo_wtinitialize(vortex_t
* vortex
, int fifo
, int j
);
34 static int vortex_wt_SetReg(vortex_t
* vortex
, unsigned char reg
, int wt
,
39 /* Put 2 WT channels together for one stereo interlaced channel. */
40 static void vortex_wt_setstereo(vortex_t
* vortex
, u32 wt
, u32 stereo
)
44 //temp = hwread(vortex->mmio, 0x80 + ((wt >> 0x5)<< 0xf) + (((wt & 0x1f) >> 1) << 2));
45 temp
= hwread(vortex
->mmio
, WT_STEREO(wt
));
46 temp
= (temp
& 0xfe) | (stereo
& 1);
47 //hwwrite(vortex->mmio, 0x80 + ((wt >> 0x5)<< 0xf) + (((wt & 0x1f) >> 1) << 2), temp);
48 hwwrite(vortex
->mmio
, WT_STEREO(wt
), temp
);
51 /* Join to mixdown route. */
52 static void vortex_wt_setdsout(vortex_t
* vortex
, u32 wt
, int en
)
56 /* There is one DSREG register for each bank (32 voices each). */
57 temp
= hwread(vortex
->mmio
, WT_DSREG((wt
>= 0x20) ? 1 : 0));
59 temp
|= (1 << (wt
& 0x1f));
61 temp
&= (1 << ~(wt
& 0x1f));
62 hwwrite(vortex
->mmio
, WT_DSREG((wt
>= 0x20) ? 1 : 0), temp
);
66 static int vortex_wt_allocroute(vortex_t
* vortex
, int wt
, int nr_ch
)
68 wt_voice_t
*voice
= &(vortex
->wt_voice
[wt
]);
71 //FIXME: WT audio routing.
73 vortex_fifo_wtinitialize(vortex
, wt
, 1);
74 vortex_fifo_setwtvalid(vortex
, wt
, 1);
75 vortex_wt_setstereo(vortex
, wt
, nr_ch
- 1);
77 vortex_fifo_setwtvalid(vortex
, wt
, 0);
79 /* Set mixdown mode. */
80 vortex_wt_setdsout(vortex
, wt
, 1);
81 /* Set other parameter registers. */
82 hwwrite(vortex
->mmio
, WT_SRAMP(0), 0x880000);
83 //hwwrite(vortex->mmio, WT_GMODE(0), 0xffffffff);
85 hwwrite(vortex
->mmio
, WT_SRAMP(1), 0x880000);
86 //hwwrite(vortex->mmio, WT_GMODE(1), 0xffffffff);
88 hwwrite(vortex
->mmio
, WT_PARM(wt
, 0), 0);
89 hwwrite(vortex
->mmio
, WT_PARM(wt
, 1), 0);
90 hwwrite(vortex
->mmio
, WT_PARM(wt
, 2), 0);
92 temp
= hwread(vortex
->mmio
, WT_PARM(wt
, 3));
93 printk("vortex: WT PARM3: %x\n", temp
);
94 //hwwrite(vortex->mmio, WT_PARM(wt, 3), temp);
96 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 0), 0);
97 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 1), 0);
98 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 2), 0);
99 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 3), 0);
101 printk("vortex: WT GMODE: %x\n", hwread(vortex
->mmio
, WT_GMODE(wt
)));
103 hwwrite(vortex
->mmio
, WT_PARM(wt
, 2), 0xffffffff);
104 hwwrite(vortex
->mmio
, WT_PARM(wt
, 3), 0xcff1c810);
106 voice
->parm0
= voice
->parm1
= 0xcfb23e2f;
107 hwwrite(vortex
->mmio
, WT_PARM(wt
, 0), voice
->parm0
);
108 hwwrite(vortex
->mmio
, WT_PARM(wt
, 1), voice
->parm1
);
109 printk("vortex: WT GMODE 2 : %x\n", hwread(vortex
->mmio
, WT_GMODE(wt
)));
114 static void vortex_wt_connect(vortex_t
* vortex
, int en
)
118 #define NR_WTROUTES 6
120 #define NR_WTBLOCKS 2
122 #define NR_WTBLOCKS 1
125 for (i
= 0; i
< NR_WTBLOCKS
; i
++) {
126 for (ii
= 0; ii
< NR_WTROUTES
; ii
++) {
128 vortex_adb_checkinout(vortex
,
129 vortex
->fixed_res
, en
,
130 VORTEX_RESOURCE_MIXIN
);
131 vortex
->mixwt
[(i
* NR_WTROUTES
) + ii
] = mix
;
133 vortex_route(vortex
, en
, 0x11,
134 ADB_WTOUT(i
, ii
+ 0x20), ADB_MIXIN(mix
));
136 vortex_connection_mixin_mix(vortex
, en
, mix
,
137 vortex
->mixplayb
[ii
% 2], 0);
138 if (VORTEX_IS_QUAD(vortex
))
139 vortex_connection_mixin_mix(vortex
, en
,
145 for (i
= 0; i
< NR_WT
; i
++) {
146 hwwrite(vortex
->mmio
, WT_RUN(i
), 1);
150 /* Read WT Register */
152 static int vortex_wt_GetReg(vortex_t
* vortex
, char reg
, int wt
)
157 return hwread(vortex
->mmio
, WT_PARM(wt
, 3));
160 return hwread(vortex
->mmio
, WT_GMODE(wt
));
166 /* WT hardware abstraction layer generic register interface. */
168 vortex_wt_SetReg2(vortex_t
* vortex
, unsigned char reg
, int wt
,
174 if (wt >= NR_WT) // 0x40 -> NR_WT
177 if ((reg - 0x20) > 0) {
178 if ((reg - 0x21) != 0)
180 eax = ((((b & 0xff) << 0xb) + (edx & 0xff)) << 4) + 0x208; // param 2
182 eax = ((((b & 0xff) << 0xb) + (edx & 0xff)) << 4) + 0x20a; // param 3
184 hwwrite(vortex->mmio, eax, c);
189 /*public: static void __thiscall CWTHal::SetReg(unsigned char,int,unsigned long) */
192 vortex_wt_SetReg(vortex_t
* vortex
, unsigned char reg
, int wt
,
197 if ((reg
== 5) || ((reg
>= 7) && (reg
<= 10)) || (reg
== 0xc)) {
198 if (wt
>= (NR_WT
/ NR_WT_PB
)) {
200 ("vortex: WT SetReg: bank out of range. reg=0x%x, wt=%d\n",
206 printk("vortex: WT SetReg: voice out of range\n");
214 /* Voice specific parameters */
215 case 0: /* running */
216 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_RUN(wt), (int)val);
217 hwwrite(vortex
->mmio
, WT_RUN(wt
), val
);
220 case 1: /* param 0 */
221 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_PARM(wt,0), (int)val);
222 hwwrite(vortex
->mmio
, WT_PARM(wt
, 0), val
);
225 case 2: /* param 1 */
226 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_PARM(wt,1), (int)val);
227 hwwrite(vortex
->mmio
, WT_PARM(wt
, 1), val
);
230 case 3: /* param 2 */
231 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_PARM(wt,2), (int)val);
232 hwwrite(vortex
->mmio
, WT_PARM(wt
, 2), val
);
235 case 4: /* param 3 */
236 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_PARM(wt,3), (int)val);
237 hwwrite(vortex
->mmio
, WT_PARM(wt
, 3), val
);
241 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_MUTE(wt), (int)val);
242 hwwrite(vortex
->mmio
, WT_MUTE(wt
), val
);
247 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", WT_DELAY(wt,0), (int)val);
248 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 3), val
);
249 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 2), val
);
250 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 1), val
);
251 hwwrite(vortex
->mmio
, WT_DELAY(wt
, 0), val
);
255 /* Global WT block parameters */
268 case 0xc: /* ds_reg */
275 //printk("vortex: WT SetReg(0x%x) = 0x%08x\n", ecx, (int)val);
276 hwwrite(vortex
->mmio
, ecx
, val
);
280 static void vortex_wt_init(vortex_t
* vortex
)
282 int var4
, var8
, varc
, var10
= 0, edi
;
297 /* Init Bank registers. */
298 for (edi
= 0; edi
< (NR_WT
/ NR_WT_PB
); edi
++) {
299 vortex_wt_SetReg(vortex
, 0xc, edi
, 0); /* ds_reg */
300 vortex_wt_SetReg(vortex
, 0xa, edi
, var10
); /* ctrl */
301 vortex_wt_SetReg(vortex
, 0x9, edi
, var4
); /* mramp */
302 vortex_wt_SetReg(vortex
, 0x8, edi
, varc
); /* aramp */
303 vortex_wt_SetReg(vortex
, 0x5, edi
, var8
); /* sramp */
305 /* Init Voice registers. */
306 for (edi
= 0; edi
< NR_WT
; edi
++) {
307 vortex_wt_SetReg(vortex
, 0x4, edi
, 0); /* param 3 0x20c */
308 vortex_wt_SetReg(vortex
, 0x3, edi
, 0); /* param 2 0x208 */
309 vortex_wt_SetReg(vortex
, 0x2, edi
, 0); /* param 1 0x204 */
310 vortex_wt_SetReg(vortex
, 0x1, edi
, 0); /* param 0 0x200 */
311 vortex_wt_SetReg(vortex
, 0xb, edi
, 0); /* delay 0x400 - 0x40c */
314 for (edi
= 0; edi
< (NR_WT
/ NR_WT_PB
); edi
++)
315 vortex_wt_SetReg(vortex
, 0xa, edi
, var10
); /* ctrl */
318 /* Extract of CAdbTopology::SetVolume(struct _ASPVOLUME *) */
320 static void vortex_wt_SetVolume(vortex_t
* vortex
, int wt
, int vol
[])
322 wt_voice_t
*voice
= &(vortex
->wt_voice
[wt
]);
323 int ecx
= vol
[1], eax
= vol
[0];
325 /* This is pure guess */
326 voice
->parm0
&= 0xff00ffff;
327 voice
->parm0
|= (vol
[0] & 0xff) << 0x10;
328 voice
->parm1
&= 0xff00ffff;
329 voice
->parm1
|= (vol
[1] & 0xff) << 0x10;
332 hwwrite(vortex
, WT_PARM(wt
, 0), voice
->parm0
);
333 hwwrite(vortex
, WT_PARM(wt
, 1), voice
->parm0
);
335 if (voice
->this_1D0
& 4) {
340 voice
->parm3
&= 0xFFFFC07F;
341 voice
->parm3
|= (ecx
& 0x7f) << 7;
342 voice
->parm3
&= 0xFFFFFF80;
343 voice
->parm3
|= (eax
& 0x7f);
345 voice
->parm3
&= 0xFFE03FFF;
346 voice
->parm3
|= (eax
& 0xFE00) << 5;
349 hwwrite(vortex
, WT_PARM(wt
, 3), voice
->parm3
);
352 /* Extract of CAdbTopology::SetFrequency(unsigned long arg_0) */
353 static void vortex_wt_SetFrequency(vortex_t
* vortex
, int wt
, unsigned int sr
)
355 wt_voice_t
*voice
= &(vortex
->wt_voice
[wt
]);
358 //FIXME: 64 bit operation.
359 eax
= ((sr
<< 0xf) * 0x57619F1) & 0xffffffff;
360 edx
= (((sr
<< 0xf) * 0x57619F1)) >> 0x20;
365 if (edx
& 0x0FFF80000)
370 while ((edx
& 0x80000000) == 0) {
384 voice
->parm0
&= 0xffff0001;
385 voice
->parm0
|= (eax
& 0x7fff) << 1;
386 voice
->parm1
= voice
->parm0
| 1;
388 //AuWt::WriteReg((ulong)(this_1DC<<4)+0x200, (ulong)this_1E4);
389 //AuWt::WriteReg((ulong)(this_1DC<<4)+0x204, (ulong)this_1E8);
390 hwwrite(vortex
->mmio
, WT_PARM(wt
, 0), voice
->parm0
);
391 hwwrite(vortex
->mmio
, WT_PARM(wt
, 1), voice
->parm1
);