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[/] [or1k/] [tags/] [before_ORP/] [uclinux/] [uClinux-2.0.x/] [drivers/] [net/] [soundmodem/] [smdma.h] - Blame information for rev 901

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/*****************************************************************************/
 
/*
 *      smdma.h  --  soundcard radio modem driver dma buffer routines.
 *
 *      Copyright (C) 1996  Thomas Sailer (sailer@ife.ee.ethz.ch)
 *
 *      This program is free software; you can redistribute it and/or modify
 *      it under the terms of the GNU General Public License as published by
 *      the Free Software Foundation; either version 2 of the License, or
 *      (at your option) any later version.
 *
 *      This program is distributed in the hope that it will be useful,
 *      but WITHOUT ANY WARRANTY; without even the implied warranty of
 *      MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *      GNU General Public License for more details.
 *
 *      You should have received a copy of the GNU General Public License
 *      along with this program; if not, write to the Free Software
 *      Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 *
 *  Please note that the GPL allows you to use the driver, NOT the radio.
 *  In order to use the radio, you need a license from the communications
 *  authority of your country.
 *
 */
 
#ifndef _SMDMA_H
#define _SMDMA_H
 
/* ---------------------------------------------------------------------- */
 
#include "sm.h"
 
/* ---------------------------------------------------------------------- */
 
#define DMA_MODE_AUTOINIT      0x10
#define NUM_FRAGMENTS          4
 
/*
 * NOTE: make sure that hdlcdrv_hdlcbuffer contains enough space
 * for the modulator to fill the whole DMA buffer without underrun
 * at the highest possible baud rate, otherwise the TX state machine will
 * not work correctly. That is (9k6 FSK): HDLCDRV_HDLCBUFFER > 6*NUM_FRAGMENTS
 */
 
/* --------------------------------------------------------------------- */
/*
 * ===================== DMA buffer management ===========================
 */
 
/*
 * returns the number of samples per fragment
 */
extern __inline__ unsigned int dma_setup(struct sm_state *sm, int send, unsigned int dmanr)
{
        if (send) {
                disable_dma(dmanr);
                clear_dma_ff(dmanr);
                set_dma_mode(dmanr, DMA_MODE_WRITE | DMA_MODE_AUTOINIT);
                set_dma_addr(dmanr, virt_to_bus(sm->dma.obuf));
                set_dma_count(dmanr, sm->dma.ofragsz * NUM_FRAGMENTS);
                enable_dma(dmanr);
                if (sm->dma.o16bit)
                        return sm->dma.ofragsz/2;
                return sm->dma.ofragsz;
        } else {
                disable_dma(dmanr);
                clear_dma_ff(dmanr);
                set_dma_mode(dmanr, DMA_MODE_READ | DMA_MODE_AUTOINIT);
                set_dma_addr(dmanr, virt_to_bus(sm->dma.ibuf));
                set_dma_count(dmanr, sm->dma.ifragsz * NUM_FRAGMENTS);
                enable_dma(dmanr);
                if (sm->dma.i16bit)
                        return sm->dma.ifragsz/2;
                return sm->dma.ifragsz;
        }
}
 
/* --------------------------------------------------------------------- */
 
extern __inline__ unsigned int dma_ptr(struct sm_state *sm, int send, unsigned int dmanr,
                                       unsigned int *curfrag)
{
        unsigned int dmaptr, sz, frg, offs;
 
        dmaptr = get_dma_residue(dmanr);
        if (send) {
                sz = sm->dma.ofragsz * NUM_FRAGMENTS;
                if (dmaptr == 0 || dmaptr > sz)
                        dmaptr = sz;
                dmaptr--;
                frg = dmaptr / sm->dma.ofragsz;
                offs = (dmaptr % sm->dma.ofragsz) + 1;
                *curfrag = NUM_FRAGMENTS - 1 - frg;
#ifdef SM_DEBUG
                if (!sm->debug_vals.dma_residue || offs < sm->debug_vals.dma_residue)
                        sm->debug_vals.dma_residue = offs;
#endif /* SM_DEBUG */
                if (sm->dma.o16bit)
                        return offs/2;
                return offs;
        } else {
                sz = sm->dma.ifragsz * NUM_FRAGMENTS;
                if (dmaptr == 0 || dmaptr > sz)
                        dmaptr = sz;
                dmaptr--;
                frg = dmaptr / sm->dma.ifragsz;
                offs = (dmaptr % sm->dma.ifragsz) + 1;
                *curfrag = NUM_FRAGMENTS - 1 - frg;
#ifdef SM_DEBUG
                if (!sm->debug_vals.dma_residue || offs < sm->debug_vals.dma_residue)
                        sm->debug_vals.dma_residue = offs;
#endif /* SM_DEBUG */
                if (sm->dma.i16bit)
                        return offs/2;
                return offs;
        }
}
 
/* --------------------------------------------------------------------- */
 
extern __inline__ int dma_end_transmit(struct sm_state *sm, unsigned int curfrag)
{
        unsigned int diff = (NUM_FRAGMENTS + curfrag - sm->dma.ofragptr) % NUM_FRAGMENTS;
 
        sm->dma.ofragptr = curfrag;
        if (sm->dma.ptt_cnt <= 0) {
                sm->dma.ptt_cnt = 0;
                return 0;
        }
        sm->dma.ptt_cnt -= diff;
        if (sm->dma.ptt_cnt <= 0) {
                sm->dma.ptt_cnt = 0;
                return -1;
        }
        return 0;
}
 
extern __inline__ void dma_transmit(struct sm_state *sm)
{
        void *p;
 
        while (sm->dma.ptt_cnt < NUM_FRAGMENTS && hdlcdrv_ptt(&sm->hdrv)) {
                p = (unsigned char *)sm->dma.obuf + sm->dma.ofragsz *
                        ((sm->dma.ofragptr + sm->dma.ptt_cnt) % NUM_FRAGMENTS);
                if (sm->dma.o16bit) {
                        time_exec(sm->debug_vals.mod_cyc,
                                  sm->mode_tx->modulator_s16(sm, p, sm->dma.ofragsz/2));
                } else {
                        time_exec(sm->debug_vals.mod_cyc,
                                  sm->mode_tx->modulator_u8(sm, p, sm->dma.ofragsz));
                }
                sm->dma.ptt_cnt++;
        }
}
 
extern __inline__ void dma_init_transmit(struct sm_state *sm)
{
        sm->dma.ofragptr = 0;
        sm->dma.ptt_cnt = 0;
}
 
extern __inline__ void dma_start_transmit(struct sm_state *sm)
{
        sm->dma.ofragptr = 0;
        if (sm->dma.o16bit) {
                time_exec(sm->debug_vals.mod_cyc,
                          sm->mode_tx->modulator_s16(sm, sm->dma.obuf, sm->dma.ofragsz/2));
        } else {
                time_exec(sm->debug_vals.mod_cyc,
                          sm->mode_tx->modulator_u8(sm, sm->dma.obuf, sm->dma.ofragsz));
        }
        sm->dma.ptt_cnt = 1;
}
 
extern __inline__ void dma_clear_transmit(struct sm_state *sm)
{
        sm->dma.ptt_cnt = 0;
        memset(sm->dma.obuf, (sm->dma.o16bit) ? 0 : 0x80, sm->dma.ofragsz * NUM_FRAGMENTS);
}
 
/* --------------------------------------------------------------------- */
 
extern __inline__ void dma_receive(struct sm_state *sm, unsigned int curfrag)
{
        void *p;
 
        while (sm->dma.ifragptr != curfrag) {
                if (sm->dma.ifragptr)
                        p = (unsigned char *)sm->dma.ibuf +
                                sm->dma.ifragsz * sm->dma.ifragptr;
                else {
                        p = (unsigned char *)sm->dma.ibuf + NUM_FRAGMENTS * sm->dma.ifragsz;
                        memcpy(p, sm->dma.ibuf, sm->dma.ifragsz);
                }
                if (sm->dma.o16bit) {
                        time_exec(sm->debug_vals.demod_cyc,
                                  sm->mode_rx->demodulator_s16(sm, p, sm->dma.ifragsz/2));
                } else {
                        time_exec(sm->debug_vals.demod_cyc,
                                  sm->mode_rx->demodulator_u8(sm, p, sm->dma.ifragsz));
                }
                sm->dma.ifragptr = (sm->dma.ifragptr + 1) % NUM_FRAGMENTS;
        }
}
 
extern __inline__ void dma_init_receive(struct sm_state *sm)
{
        sm->dma.ifragptr = 0;
}
 
/* --------------------------------------------------------------------- */
#endif /* _SMDMA_H */
 
 
 

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[/] [or1k/] [tags/] [before_ORP/] [uclinux/] [uClinux-2.0.x/] [drivers/] [net/] [soundmodem/] [smdma.h] - Blame information for rev 901

Line No.	Rev	Author	Line
1	199	simons	`/*****************************************************************************/`
2
3			`/*`
4			`* smdma.h -- soundcard radio modem driver dma buffer routines.`
5			`*`
6			`* Copyright (C) 1996 Thomas Sailer (sailer@ife.ee.ethz.ch)`
7			`*`
8			`* This program is free software; you can redistribute it and/or modify`
9			`* it under the terms of the GNU General Public License as published by`
10			`* the Free Software Foundation; either version 2 of the License, or`
11			`* (at your option) any later version.`
12			`*`
13			`* This program is distributed in the hope that it will be useful,`
14			`* but WITHOUT ANY WARRANTY; without even the implied warranty of`
15			`* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
16			`* GNU General Public License for more details.`
17			`*`
18			`* You should have received a copy of the GNU General Public License`
19			`* along with this program; if not, write to the Free Software`
20			`* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.`
21			`*`
22			`* Please note that the GPL allows you to use the driver, NOT the radio.`
23			`* In order to use the radio, you need a license from the communications`
24			`* authority of your country.`
25			`*`
26			`*/`
27
28			`#ifndef _SMDMA_H`
29			`#define _SMDMA_H`
30
31			`/* ---------------------------------------------------------------------- */`
32
33			`#include "sm.h"`
34
35			`/* ---------------------------------------------------------------------- */`
36
37			`#define DMA_MODE_AUTOINIT 0x10`
38			`#define NUM_FRAGMENTS 4`
39
40			`/*`
41			`* NOTE: make sure that hdlcdrv_hdlcbuffer contains enough space`
42			`* for the modulator to fill the whole DMA buffer without underrun`
43			`* at the highest possible baud rate, otherwise the TX state machine will`
44			`* not work correctly. That is (9k6 FSK): HDLCDRV_HDLCBUFFER > 6*NUM_FRAGMENTS`
45			`*/`
46
47			`/* --------------------------------------------------------------------- */`
48			`/*`
49			`* ===================== DMA buffer management ===========================`
50			`*/`
51
52			`/*`
53			`* returns the number of samples per fragment`
54			`*/`
55			`extern __inline__ unsigned int dma_setup(struct sm_state *sm, int send, unsigned int dmanr)`
56			`{`
57			`if (send) {`
58			`disable_dma(dmanr);`
59			`clear_dma_ff(dmanr);`
60			`set_dma_mode(dmanr, DMA_MODE_WRITE \| DMA_MODE_AUTOINIT);`
61			`set_dma_addr(dmanr, virt_to_bus(sm->dma.obuf));`
62			`set_dma_count(dmanr, sm->dma.ofragsz * NUM_FRAGMENTS);`
63			`enable_dma(dmanr);`
64			`if (sm->dma.o16bit)`
65			`return sm->dma.ofragsz/2;`
66			`return sm->dma.ofragsz;`
67			`} else {`
68			`disable_dma(dmanr);`
69			`clear_dma_ff(dmanr);`
70			`set_dma_mode(dmanr, DMA_MODE_READ \| DMA_MODE_AUTOINIT);`
71			`set_dma_addr(dmanr, virt_to_bus(sm->dma.ibuf));`
72			`set_dma_count(dmanr, sm->dma.ifragsz * NUM_FRAGMENTS);`
73			`enable_dma(dmanr);`
74			`if (sm->dma.i16bit)`
75			`return sm->dma.ifragsz/2;`
76			`return sm->dma.ifragsz;`
77			`}`
78			`}`
79
80			`/* --------------------------------------------------------------------- */`
81
82			`extern __inline__ unsigned int dma_ptr(struct sm_state *sm, int send, unsigned int dmanr,`
83			`unsigned int *curfrag)`
84			`{`
85			`unsigned int dmaptr, sz, frg, offs;`
86
87			`dmaptr = get_dma_residue(dmanr);`
88			`if (send) {`
89			`sz = sm->dma.ofragsz * NUM_FRAGMENTS;`
90			`if (dmaptr == 0 \|\| dmaptr > sz)`
91			`dmaptr = sz;`
92			`dmaptr--;`
93			`frg = dmaptr / sm->dma.ofragsz;`
94			`offs = (dmaptr % sm->dma.ofragsz) + 1;`
95			`*curfrag = NUM_FRAGMENTS - 1 - frg;`
96			`#ifdef SM_DEBUG`
97			`if (!sm->debug_vals.dma_residue \|\| offs < sm->debug_vals.dma_residue)`
98			`sm->debug_vals.dma_residue = offs;`
99			`#endif /* SM_DEBUG */`
100			`if (sm->dma.o16bit)`
101			`return offs/2;`
102			`return offs;`
103			`} else {`
104			`sz = sm->dma.ifragsz * NUM_FRAGMENTS;`
105			`if (dmaptr == 0 \|\| dmaptr > sz)`
106			`dmaptr = sz;`
107			`dmaptr--;`
108			`frg = dmaptr / sm->dma.ifragsz;`
109			`offs = (dmaptr % sm->dma.ifragsz) + 1;`
110			`*curfrag = NUM_FRAGMENTS - 1 - frg;`
111			`#ifdef SM_DEBUG`
112			`if (!sm->debug_vals.dma_residue \|\| offs < sm->debug_vals.dma_residue)`
113			`sm->debug_vals.dma_residue = offs;`
114			`#endif /* SM_DEBUG */`
115			`if (sm->dma.i16bit)`
116			`return offs/2;`
117			`return offs;`
118			`}`
119			`}`
120
121			`/* --------------------------------------------------------------------- */`
122
123			`extern __inline__ int dma_end_transmit(struct sm_state *sm, unsigned int curfrag)`
124			`{`
125			`unsigned int diff = (NUM_FRAGMENTS + curfrag - sm->dma.ofragptr) % NUM_FRAGMENTS;`
126
127			`sm->dma.ofragptr = curfrag;`
128			`if (sm->dma.ptt_cnt <= 0) {`
129			`sm->dma.ptt_cnt = 0;`
130			`return 0;`
131			`}`
132			`sm->dma.ptt_cnt -= diff;`
133			`if (sm->dma.ptt_cnt <= 0) {`
134			`sm->dma.ptt_cnt = 0;`
135			`return -1;`
136			`}`
137			`return 0;`
138			`}`
139
140			`extern __inline__ void dma_transmit(struct sm_state *sm)`
141			`{`
142			`void *p;`
143
144			`while (sm->dma.ptt_cnt < NUM_FRAGMENTS && hdlcdrv_ptt(&sm->hdrv)) {`
145			`p = (unsigned char )sm->dma.obuf + sm->dma.ofragsz `
146			`((sm->dma.ofragptr + sm->dma.ptt_cnt) % NUM_FRAGMENTS);`
147			`if (sm->dma.o16bit) {`
148			`time_exec(sm->debug_vals.mod_cyc,`
149			`sm->mode_tx->modulator_s16(sm, p, sm->dma.ofragsz/2));`
150			`} else {`
151			`time_exec(sm->debug_vals.mod_cyc,`
152			`sm->mode_tx->modulator_u8(sm, p, sm->dma.ofragsz));`
153			`}`
154			`sm->dma.ptt_cnt++;`
155			`}`
156			`}`
157
158			`extern __inline__ void dma_init_transmit(struct sm_state *sm)`
159			`{`
160			`sm->dma.ofragptr = 0;`
161			`sm->dma.ptt_cnt = 0;`
162			`}`
163
164			`extern __inline__ void dma_start_transmit(struct sm_state *sm)`
165			`{`
166			`sm->dma.ofragptr = 0;`
167			`if (sm->dma.o16bit) {`
168			`time_exec(sm->debug_vals.mod_cyc,`
169			`sm->mode_tx->modulator_s16(sm, sm->dma.obuf, sm->dma.ofragsz/2));`
170			`} else {`
171			`time_exec(sm->debug_vals.mod_cyc,`
172			`sm->mode_tx->modulator_u8(sm, sm->dma.obuf, sm->dma.ofragsz));`
173			`}`
174			`sm->dma.ptt_cnt = 1;`
175			`}`
176
177			`extern __inline__ void dma_clear_transmit(struct sm_state *sm)`
178			`{`
179			`sm->dma.ptt_cnt = 0;`
180			`memset(sm->dma.obuf, (sm->dma.o16bit) ? 0 : 0x80, sm->dma.ofragsz * NUM_FRAGMENTS);`
181			`}`
182
183			`/* --------------------------------------------------------------------- */`
184
185			`extern __inline__ void dma_receive(struct sm_state *sm, unsigned int curfrag)`
186			`{`
187			`void *p;`
188
189			`while (sm->dma.ifragptr != curfrag) {`
190			`if (sm->dma.ifragptr)`
191			`p = (unsigned char *)sm->dma.ibuf +`
192			`sm->dma.ifragsz * sm->dma.ifragptr;`
193			`else {`
194			`p = (unsigned char )sm->dma.ibuf + NUM_FRAGMENTS sm->dma.ifragsz;`
195			`memcpy(p, sm->dma.ibuf, sm->dma.ifragsz);`
196			`}`
197			`if (sm->dma.o16bit) {`
198			`time_exec(sm->debug_vals.demod_cyc,`
199			`sm->mode_rx->demodulator_s16(sm, p, sm->dma.ifragsz/2));`
200			`} else {`
201			`time_exec(sm->debug_vals.demod_cyc,`
202			`sm->mode_rx->demodulator_u8(sm, p, sm->dma.ifragsz));`
203			`}`
204			`sm->dma.ifragptr = (sm->dma.ifragptr + 1) % NUM_FRAGMENTS;`
205			`}`
206			`}`
207
208			`extern __inline__ void dma_init_receive(struct sm_state *sm)`
209			`{`
210			`sm->dma.ifragptr = 0;`
211			`}`
212
213			`/* --------------------------------------------------------------------- */`
214			`#endif /* _SMDMA_H */`
215
216
217