linux/sound/pci/ctxfi/ctatc.c

1754 lines
42 KiB
C
Raw Normal View History

/**
* Copyright (C) 2008, Creative Technology Ltd. All Rights Reserved.
*
* This source file is released under GPL v2 license (no other versions).
* See the COPYING file included in the main directory of this source
* distribution for the license terms and conditions.
*
* @File ctatc.c
*
* @Brief
* This file contains the implementation of the device resource management
* object.
*
* @Author Liu Chun
* @Date Mar 28 2008
*/
#include "ctatc.h"
#include "ctpcm.h"
#include "ctmixer.h"
#include "ctsrc.h"
#include "ctamixer.h"
#include "ctdaio.h"
#include "cttimer.h"
#include <linux/delay.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 16:04:11 +08:00
#include <linux/slab.h>
#include <sound/pcm.h>
#include <sound/control.h>
#include <sound/asoundef.h>
#define MONO_SUM_SCALE 0x19a8 /* 2^(-0.5) in 14-bit floating format */
#define MAX_MULTI_CHN 8
#define IEC958_DEFAULT_CON ((IEC958_AES0_NONAUDIO \
| IEC958_AES0_CON_NOT_COPYRIGHT) \
| ((IEC958_AES1_CON_MIXER \
| IEC958_AES1_CON_ORIGINAL) << 8) \
| (0x10 << 16) \
| ((IEC958_AES3_CON_FS_48000) << 24))
static struct snd_pci_quirk subsys_20k1_list[] = {
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, 0x0022, "SB055x", CTSB055X),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, 0x002f, "SB055x", CTSB055X),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, 0x0029, "SB073x", CTSB073X),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, 0x0031, "SB073x", CTSB073X),
SND_PCI_QUIRK_MASK(PCI_VENDOR_ID_CREATIVE, 0xf000, 0x6000,
"UAA", CTUAA),
{ } /* terminator */
};
static struct snd_pci_quirk subsys_20k2_list[] = {
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, PCI_SUBDEVICE_ID_CREATIVE_SB0760,
"SB0760", CTSB0760),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, PCI_SUBDEVICE_ID_CREATIVE_SB1270,
"SB1270", CTSB1270),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, PCI_SUBDEVICE_ID_CREATIVE_SB08801,
"SB0880", CTSB0880),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, PCI_SUBDEVICE_ID_CREATIVE_SB08802,
"SB0880", CTSB0880),
SND_PCI_QUIRK(PCI_VENDOR_ID_CREATIVE, PCI_SUBDEVICE_ID_CREATIVE_SB08803,
"SB0880", CTSB0880),
SND_PCI_QUIRK_MASK(PCI_VENDOR_ID_CREATIVE, 0xf000,
PCI_SUBDEVICE_ID_CREATIVE_HENDRIX, "HENDRIX",
CTHENDRIX),
{ } /* terminator */
};
static const char *ct_subsys_name[NUM_CTCARDS] = {
/* 20k1 models */
[CTSB055X] = "SB055x",
[CTSB073X] = "SB073x",
[CTUAA] = "UAA",
[CT20K1_UNKNOWN] = "Unknown",
/* 20k2 models */
[CTSB0760] = "SB076x",
[CTHENDRIX] = "Hendrix",
[CTSB0880] = "SB0880",
[CTSB1270] = "SB1270",
[CT20K2_UNKNOWN] = "Unknown",
};
static struct {
int (*create)(struct ct_atc *atc,
enum CTALSADEVS device, const char *device_name);
int (*destroy)(void *alsa_dev);
const char *public_name;
} alsa_dev_funcs[NUM_CTALSADEVS] = {
[FRONT] = { .create = ct_alsa_pcm_create,
.destroy = NULL,
.public_name = "Front/WaveIn"},
[SURROUND] = { .create = ct_alsa_pcm_create,
.destroy = NULL,
.public_name = "Surround"},
[CLFE] = { .create = ct_alsa_pcm_create,
.destroy = NULL,
.public_name = "Center/LFE"},
[SIDE] = { .create = ct_alsa_pcm_create,
.destroy = NULL,
.public_name = "Side"},
[IEC958] = { .create = ct_alsa_pcm_create,
.destroy = NULL,
.public_name = "IEC958 Non-audio"},
[MIXER] = { .create = ct_alsa_mix_create,
.destroy = NULL,
.public_name = "Mixer"}
};
typedef int (*create_t)(struct hw *, void **);
typedef int (*destroy_t)(void *);
static struct {
int (*create)(struct hw *hw, void **rmgr);
int (*destroy)(void *mgr);
} rsc_mgr_funcs[NUM_RSCTYP] = {
[SRC] = { .create = (create_t)src_mgr_create,
.destroy = (destroy_t)src_mgr_destroy },
[SRCIMP] = { .create = (create_t)srcimp_mgr_create,
.destroy = (destroy_t)srcimp_mgr_destroy },
[AMIXER] = { .create = (create_t)amixer_mgr_create,
.destroy = (destroy_t)amixer_mgr_destroy },
[SUM] = { .create = (create_t)sum_mgr_create,
.destroy = (destroy_t)sum_mgr_destroy },
[DAIO] = { .create = (create_t)daio_mgr_create,
.destroy = (destroy_t)daio_mgr_destroy }
};
static int
atc_pcm_release_resources(struct ct_atc *atc, struct ct_atc_pcm *apcm);
/* *
* Only mono and interleaved modes are supported now.
* Always allocates a contiguous channel block.
* */
static int ct_map_audio_buffer(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct snd_pcm_runtime *runtime;
struct ct_vm *vm;
if (!apcm->substream)
return 0;
runtime = apcm->substream->runtime;
vm = atc->vm;
apcm->vm_block = vm->map(vm, apcm->substream, runtime->dma_bytes);
if (!apcm->vm_block)
return -ENOENT;
return 0;
}
static void ct_unmap_audio_buffer(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct ct_vm *vm;
if (!apcm->vm_block)
return;
vm = atc->vm;
vm->unmap(vm, apcm->vm_block);
apcm->vm_block = NULL;
}
static unsigned long atc_get_ptp_phys(struct ct_atc *atc, int index)
{
return atc->vm->get_ptp_phys(atc->vm, index);
}
static unsigned int convert_format(snd_pcm_format_t snd_format,
struct snd_card *card)
{
switch (snd_format) {
case SNDRV_PCM_FORMAT_U8:
return SRC_SF_U8;
case SNDRV_PCM_FORMAT_S16_LE:
return SRC_SF_S16;
case SNDRV_PCM_FORMAT_S24_3LE:
return SRC_SF_S24;
case SNDRV_PCM_FORMAT_S32_LE:
return SRC_SF_S32;
case SNDRV_PCM_FORMAT_FLOAT_LE:
return SRC_SF_F32;
default:
dev_err(card->dev, "not recognized snd format is %d\n",
snd_format);
return SRC_SF_S16;
}
}
static unsigned int
atc_get_pitch(unsigned int input_rate, unsigned int output_rate)
{
unsigned int pitch;
int b;
/* get pitch and convert to fixed-point 8.24 format. */
pitch = (input_rate / output_rate) << 24;
input_rate %= output_rate;
input_rate /= 100;
output_rate /= 100;
for (b = 31; ((b >= 0) && !(input_rate >> b)); )
b--;
if (b >= 0) {
input_rate <<= (31 - b);
input_rate /= output_rate;
b = 24 - (31 - b);
if (b >= 0)
input_rate <<= b;
else
input_rate >>= -b;
pitch |= input_rate;
}
return pitch;
}
static int select_rom(unsigned int pitch)
{
if (pitch > 0x00428f5c && pitch < 0x01b851ec) {
/* 0.26 <= pitch <= 1.72 */
return 1;
} else if (pitch == 0x01d66666 || pitch == 0x01d66667) {
/* pitch == 1.8375 */
return 2;
} else if (pitch == 0x02000000) {
/* pitch == 2 */
return 3;
} else if (pitch <= 0x08000000) {
/* 0 <= pitch <= 8 */
return 0;
} else {
return -ENOENT;
}
}
static int atc_pcm_playback_prepare(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src_mgr *src_mgr = atc->rsc_mgrs[SRC];
struct amixer_mgr *amixer_mgr = atc->rsc_mgrs[AMIXER];
struct src_desc desc = {0};
struct amixer_desc mix_dsc = {0};
struct src *src;
struct amixer *amixer;
int err;
int n_amixer = apcm->substream->runtime->channels, i = 0;
int device = apcm->substream->pcm->device;
unsigned int pitch;
/* first release old resources */
atc_pcm_release_resources(atc, apcm);
/* Get SRC resource */
desc.multi = apcm->substream->runtime->channels;
desc.msr = atc->msr;
desc.mode = MEMRD;
err = src_mgr->get_src(src_mgr, &desc, (struct src **)&apcm->src);
if (err)
goto error1;
pitch = atc_get_pitch(apcm->substream->runtime->rate,
(atc->rsr * atc->msr));
src = apcm->src;
src->ops->set_pitch(src, pitch);
src->ops->set_rom(src, select_rom(pitch));
src->ops->set_sf(src, convert_format(apcm->substream->runtime->format,
atc->card));
src->ops->set_pm(src, (src->ops->next_interleave(src) != NULL));
/* Get AMIXER resource */
n_amixer = (n_amixer < 2) ? 2 : n_amixer;
apcm->amixers = kzalloc(sizeof(void *)*n_amixer, GFP_KERNEL);
if (!apcm->amixers) {
err = -ENOMEM;
goto error1;
}
mix_dsc.msr = atc->msr;
for (i = 0, apcm->n_amixer = 0; i < n_amixer; i++) {
err = amixer_mgr->get_amixer(amixer_mgr, &mix_dsc,
(struct amixer **)&apcm->amixers[i]);
if (err)
goto error1;
apcm->n_amixer++;
}
/* Set up device virtual mem map */
err = ct_map_audio_buffer(atc, apcm);
if (err < 0)
goto error1;
/* Connect resources */
src = apcm->src;
for (i = 0; i < n_amixer; i++) {
amixer = apcm->amixers[i];
mutex_lock(&atc->atc_mutex);
amixer->ops->setup(amixer, &src->rsc,
INIT_VOL, atc->pcm[i+device*2]);
mutex_unlock(&atc->atc_mutex);
src = src->ops->next_interleave(src);
if (!src)
src = apcm->src;
}
ct_timer_prepare(apcm->timer);
return 0;
error1:
atc_pcm_release_resources(atc, apcm);
return err;
}
static int
atc_pcm_release_resources(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src_mgr *src_mgr = atc->rsc_mgrs[SRC];
struct srcimp_mgr *srcimp_mgr = atc->rsc_mgrs[SRCIMP];
struct amixer_mgr *amixer_mgr = atc->rsc_mgrs[AMIXER];
struct sum_mgr *sum_mgr = atc->rsc_mgrs[SUM];
struct srcimp *srcimp;
int i;
if (apcm->srcimps) {
for (i = 0; i < apcm->n_srcimp; i++) {
srcimp = apcm->srcimps[i];
srcimp->ops->unmap(srcimp);
srcimp_mgr->put_srcimp(srcimp_mgr, srcimp);
apcm->srcimps[i] = NULL;
}
kfree(apcm->srcimps);
apcm->srcimps = NULL;
}
if (apcm->srccs) {
for (i = 0; i < apcm->n_srcc; i++) {
src_mgr->put_src(src_mgr, apcm->srccs[i]);
apcm->srccs[i] = NULL;
}
kfree(apcm->srccs);
apcm->srccs = NULL;
}
if (apcm->amixers) {
for (i = 0; i < apcm->n_amixer; i++) {
amixer_mgr->put_amixer(amixer_mgr, apcm->amixers[i]);
apcm->amixers[i] = NULL;
}
kfree(apcm->amixers);
apcm->amixers = NULL;
}
if (apcm->mono) {
sum_mgr->put_sum(sum_mgr, apcm->mono);
apcm->mono = NULL;
}
if (apcm->src) {
src_mgr->put_src(src_mgr, apcm->src);
apcm->src = NULL;
}
if (apcm->vm_block) {
/* Undo device virtual mem map */
ct_unmap_audio_buffer(atc, apcm);
apcm->vm_block = NULL;
}
return 0;
}
static int atc_pcm_playback_start(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
unsigned int max_cisz;
struct src *src = apcm->src;
if (apcm->started)
return 0;
apcm->started = 1;
max_cisz = src->multi * src->rsc.msr;
max_cisz = 0x80 * (max_cisz < 8 ? max_cisz : 8);
src->ops->set_sa(src, apcm->vm_block->addr);
src->ops->set_la(src, apcm->vm_block->addr + apcm->vm_block->size);
src->ops->set_ca(src, apcm->vm_block->addr + max_cisz);
src->ops->set_cisz(src, max_cisz);
src->ops->set_bm(src, 1);
src->ops->set_state(src, SRC_STATE_INIT);
src->ops->commit_write(src);
ct_timer_start(apcm->timer);
return 0;
}
static int atc_pcm_stop(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src *src;
int i;
ct_timer_stop(apcm->timer);
src = apcm->src;
src->ops->set_bm(src, 0);
src->ops->set_state(src, SRC_STATE_OFF);
src->ops->commit_write(src);
if (apcm->srccs) {
for (i = 0; i < apcm->n_srcc; i++) {
src = apcm->srccs[i];
src->ops->set_bm(src, 0);
src->ops->set_state(src, SRC_STATE_OFF);
src->ops->commit_write(src);
}
}
apcm->started = 0;
return 0;
}
static int
atc_pcm_playback_position(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src *src = apcm->src;
u32 size, max_cisz;
int position;
if (!src)
return 0;
position = src->ops->get_ca(src);
if (position < apcm->vm_block->addr) {
dev_dbg(atc->card->dev,
"bad ca - ca=0x%08x, vba=0x%08x, vbs=0x%08x\n",
position, apcm->vm_block->addr, apcm->vm_block->size);
position = apcm->vm_block->addr;
}
size = apcm->vm_block->size;
max_cisz = src->multi * src->rsc.msr;
max_cisz = 128 * (max_cisz < 8 ? max_cisz : 8);
return (position + size - max_cisz - apcm->vm_block->addr) % size;
}
struct src_node_conf_t {
unsigned int pitch;
unsigned int msr:8;
unsigned int mix_msr:8;
unsigned int imp_msr:8;
unsigned int vo:1;
};
static void setup_src_node_conf(struct ct_atc *atc, struct ct_atc_pcm *apcm,
struct src_node_conf_t *conf, int *n_srcc)
{
unsigned int pitch;
/* get pitch and convert to fixed-point 8.24 format. */
pitch = atc_get_pitch((atc->rsr * atc->msr),
apcm->substream->runtime->rate);
*n_srcc = 0;
if (1 == atc->msr) { /* FIXME: do we really need SRC here if pitch==1 */
*n_srcc = apcm->substream->runtime->channels;
conf[0].pitch = pitch;
conf[0].mix_msr = conf[0].imp_msr = conf[0].msr = 1;
conf[0].vo = 1;
} else if (2 <= atc->msr) {
if (0x8000000 < pitch) {
/* Need two-stage SRCs, SRCIMPs and
* AMIXERs for converting format */
conf[0].pitch = (atc->msr << 24);
conf[0].msr = conf[0].mix_msr = 1;
conf[0].imp_msr = atc->msr;
conf[0].vo = 0;
conf[1].pitch = atc_get_pitch(atc->rsr,
apcm->substream->runtime->rate);
conf[1].msr = conf[1].mix_msr = conf[1].imp_msr = 1;
conf[1].vo = 1;
*n_srcc = apcm->substream->runtime->channels * 2;
} else if (0x1000000 < pitch) {
/* Need one-stage SRCs, SRCIMPs and
* AMIXERs for converting format */
conf[0].pitch = pitch;
conf[0].msr = conf[0].mix_msr
= conf[0].imp_msr = atc->msr;
conf[0].vo = 1;
*n_srcc = apcm->substream->runtime->channels;
}
}
}
static int
atc_pcm_capture_get_resources(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src_mgr *src_mgr = atc->rsc_mgrs[SRC];
struct srcimp_mgr *srcimp_mgr = atc->rsc_mgrs[SRCIMP];
struct amixer_mgr *amixer_mgr = atc->rsc_mgrs[AMIXER];
struct sum_mgr *sum_mgr = atc->rsc_mgrs[SUM];
struct src_desc src_dsc = {0};
struct src *src;
struct srcimp_desc srcimp_dsc = {0};
struct srcimp *srcimp;
struct amixer_desc mix_dsc = {0};
struct sum_desc sum_dsc = {0};
unsigned int pitch;
int multi, err, i;
int n_srcimp, n_amixer, n_srcc, n_sum;
struct src_node_conf_t src_node_conf[2] = {{0} };
/* first release old resources */
atc_pcm_release_resources(atc, apcm);
/* The numbers of converting SRCs and SRCIMPs should be determined
* by pitch value. */
multi = apcm->substream->runtime->channels;
/* get pitch and convert to fixed-point 8.24 format. */
pitch = atc_get_pitch((atc->rsr * atc->msr),
apcm->substream->runtime->rate);
setup_src_node_conf(atc, apcm, src_node_conf, &n_srcc);
n_sum = (1 == multi) ? 1 : 0;
n_amixer = n_sum * 2 + n_srcc;
n_srcimp = n_srcc;
if ((multi > 1) && (0x8000000 >= pitch)) {
/* Need extra AMIXERs and SRCIMPs for special treatment
* of interleaved recording of conjugate channels */
n_amixer += multi * atc->msr;
n_srcimp += multi * atc->msr;
} else {
n_srcimp += multi;
}
if (n_srcc) {
apcm->srccs = kzalloc(sizeof(void *)*n_srcc, GFP_KERNEL);
if (!apcm->srccs)
return -ENOMEM;
}
if (n_amixer) {
apcm->amixers = kzalloc(sizeof(void *)*n_amixer, GFP_KERNEL);
if (!apcm->amixers) {
err = -ENOMEM;
goto error1;
}
}
apcm->srcimps = kzalloc(sizeof(void *)*n_srcimp, GFP_KERNEL);
if (!apcm->srcimps) {
err = -ENOMEM;
goto error1;
}
/* Allocate SRCs for sample rate conversion if needed */
src_dsc.multi = 1;
src_dsc.mode = ARCRW;
for (i = 0, apcm->n_srcc = 0; i < n_srcc; i++) {
src_dsc.msr = src_node_conf[i/multi].msr;
err = src_mgr->get_src(src_mgr, &src_dsc,
(struct src **)&apcm->srccs[i]);
if (err)
goto error1;
src = apcm->srccs[i];
pitch = src_node_conf[i/multi].pitch;
src->ops->set_pitch(src, pitch);
src->ops->set_rom(src, select_rom(pitch));
src->ops->set_vo(src, src_node_conf[i/multi].vo);
apcm->n_srcc++;
}
/* Allocate AMIXERs for routing SRCs of conversion if needed */
for (i = 0, apcm->n_amixer = 0; i < n_amixer; i++) {
if (i < (n_sum*2))
mix_dsc.msr = atc->msr;
else if (i < (n_sum*2+n_srcc))
mix_dsc.msr = src_node_conf[(i-n_sum*2)/multi].mix_msr;
else
mix_dsc.msr = 1;
err = amixer_mgr->get_amixer(amixer_mgr, &mix_dsc,
(struct amixer **)&apcm->amixers[i]);
if (err)
goto error1;
apcm->n_amixer++;
}
/* Allocate a SUM resource to mix all input channels together */
sum_dsc.msr = atc->msr;
err = sum_mgr->get_sum(sum_mgr, &sum_dsc, (struct sum **)&apcm->mono);
if (err)
goto error1;
pitch = atc_get_pitch((atc->rsr * atc->msr),
apcm->substream->runtime->rate);
/* Allocate SRCIMP resources */
for (i = 0, apcm->n_srcimp = 0; i < n_srcimp; i++) {
if (i < (n_srcc))
srcimp_dsc.msr = src_node_conf[i/multi].imp_msr;
else if (1 == multi)
srcimp_dsc.msr = (pitch <= 0x8000000) ? atc->msr : 1;
else
srcimp_dsc.msr = 1;
err = srcimp_mgr->get_srcimp(srcimp_mgr, &srcimp_dsc, &srcimp);
if (err)
goto error1;
apcm->srcimps[i] = srcimp;
apcm->n_srcimp++;
}
/* Allocate a SRC for writing data to host memory */
src_dsc.multi = apcm->substream->runtime->channels;
src_dsc.msr = 1;
src_dsc.mode = MEMWR;
err = src_mgr->get_src(src_mgr, &src_dsc, (struct src **)&apcm->src);
if (err)
goto error1;
src = apcm->src;
src->ops->set_pitch(src, pitch);
/* Set up device virtual mem map */
err = ct_map_audio_buffer(atc, apcm);
if (err < 0)
goto error1;
return 0;
error1:
atc_pcm_release_resources(atc, apcm);
return err;
}
static int atc_pcm_capture_prepare(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src *src;
struct amixer *amixer;
struct srcimp *srcimp;
struct ct_mixer *mixer = atc->mixer;
struct sum *mono;
struct rsc *out_ports[8] = {NULL};
int err, i, j, n_sum, multi;
unsigned int pitch;
int mix_base = 0, imp_base = 0;
atc_pcm_release_resources(atc, apcm);
/* Get needed resources. */
err = atc_pcm_capture_get_resources(atc, apcm);
if (err)
return err;
/* Connect resources */
mixer->get_output_ports(mixer, MIX_PCMO_FRONT,
&out_ports[0], &out_ports[1]);
multi = apcm->substream->runtime->channels;
if (1 == multi) {
mono = apcm->mono;
for (i = 0; i < 2; i++) {
amixer = apcm->amixers[i];
amixer->ops->setup(amixer, out_ports[i],
MONO_SUM_SCALE, mono);
}
out_ports[0] = &mono->rsc;
n_sum = 1;
mix_base = n_sum * 2;
}
for (i = 0; i < apcm->n_srcc; i++) {
src = apcm->srccs[i];
srcimp = apcm->srcimps[imp_base+i];
amixer = apcm->amixers[mix_base+i];
srcimp->ops->map(srcimp, src, out_ports[i%multi]);
amixer->ops->setup(amixer, &src->rsc, INIT_VOL, NULL);
out_ports[i%multi] = &amixer->rsc;
}
pitch = atc_get_pitch((atc->rsr * atc->msr),
apcm->substream->runtime->rate);
if ((multi > 1) && (pitch <= 0x8000000)) {
/* Special connection for interleaved
* recording with conjugate channels */
for (i = 0; i < multi; i++) {
out_ports[i]->ops->master(out_ports[i]);
for (j = 0; j < atc->msr; j++) {
amixer = apcm->amixers[apcm->n_srcc+j*multi+i];
amixer->ops->set_input(amixer, out_ports[i]);
amixer->ops->set_scale(amixer, INIT_VOL);
amixer->ops->set_sum(amixer, NULL);
amixer->ops->commit_raw_write(amixer);
out_ports[i]->ops->next_conj(out_ports[i]);
srcimp = apcm->srcimps[apcm->n_srcc+j*multi+i];
srcimp->ops->map(srcimp, apcm->src,
&amixer->rsc);
}
}
} else {
for (i = 0; i < multi; i++) {
srcimp = apcm->srcimps[apcm->n_srcc+i];
srcimp->ops->map(srcimp, apcm->src, out_ports[i]);
}
}
ct_timer_prepare(apcm->timer);
return 0;
}
static int atc_pcm_capture_start(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src *src;
struct src_mgr *src_mgr = atc->rsc_mgrs[SRC];
int i, multi;
if (apcm->started)
return 0;
apcm->started = 1;
multi = apcm->substream->runtime->channels;
/* Set up converting SRCs */
for (i = 0; i < apcm->n_srcc; i++) {
src = apcm->srccs[i];
src->ops->set_pm(src, ((i%multi) != (multi-1)));
src_mgr->src_disable(src_mgr, src);
}
/* Set up recording SRC */
src = apcm->src;
src->ops->set_sf(src, convert_format(apcm->substream->runtime->format,
atc->card));
src->ops->set_sa(src, apcm->vm_block->addr);
src->ops->set_la(src, apcm->vm_block->addr + apcm->vm_block->size);
src->ops->set_ca(src, apcm->vm_block->addr);
src_mgr->src_disable(src_mgr, src);
/* Disable relevant SRCs firstly */
src_mgr->commit_write(src_mgr);
/* Enable SRCs respectively */
for (i = 0; i < apcm->n_srcc; i++) {
src = apcm->srccs[i];
src->ops->set_state(src, SRC_STATE_RUN);
src->ops->commit_write(src);
src_mgr->src_enable_s(src_mgr, src);
}
src = apcm->src;
src->ops->set_bm(src, 1);
src->ops->set_state(src, SRC_STATE_RUN);
src->ops->commit_write(src);
src_mgr->src_enable_s(src_mgr, src);
/* Enable relevant SRCs synchronously */
src_mgr->commit_write(src_mgr);
ct_timer_start(apcm->timer);
return 0;
}
static int
atc_pcm_capture_position(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src *src = apcm->src;
if (!src)
return 0;
return src->ops->get_ca(src) - apcm->vm_block->addr;
}
static int spdif_passthru_playback_get_resources(struct ct_atc *atc,
struct ct_atc_pcm *apcm)
{
struct src_mgr *src_mgr = atc->rsc_mgrs[SRC];
struct amixer_mgr *amixer_mgr = atc->rsc_mgrs[AMIXER];
struct src_desc desc = {0};
struct amixer_desc mix_dsc = {0};
struct src *src;
int err;
int n_amixer = apcm->substream->runtime->channels, i;
unsigned int pitch, rsr = atc->pll_rate;
/* first release old resources */
atc_pcm_release_resources(atc, apcm);
/* Get SRC resource */
desc.multi = apcm->substream->runtime->channels;
desc.msr = 1;
while (apcm->substream->runtime->rate > (rsr * desc.msr))
desc.msr <<= 1;
desc.mode = MEMRD;
err = src_mgr->get_src(src_mgr, &desc, (struct src **)&apcm->src);
if (err)
goto error1;
pitch = atc_get_pitch(apcm->substream->runtime->rate, (rsr * desc.msr));
src = apcm->src;
src->ops->set_pitch(src, pitch);
src->ops->set_rom(src, select_rom(pitch));
src->ops->set_sf(src, convert_format(apcm->substream->runtime->format,
atc->card));
src->ops->set_pm(src, (src->ops->next_interleave(src) != NULL));
src->ops->set_bp(src, 1);
/* Get AMIXER resource */
n_amixer = (n_amixer < 2) ? 2 : n_amixer;
apcm->amixers = kzalloc(sizeof(void *)*n_amixer, GFP_KERNEL);
if (!apcm->amixers) {
err = -ENOMEM;
goto error1;
}
mix_dsc.msr = desc.msr;
for (i = 0, apcm->n_amixer = 0; i < n_amixer; i++) {
err = amixer_mgr->get_amixer(amixer_mgr, &mix_dsc,
(struct amixer **)&apcm->amixers[i]);
if (err)
goto error1;
apcm->n_amixer++;
}
/* Set up device virtual mem map */
err = ct_map_audio_buffer(atc, apcm);
if (err < 0)
goto error1;
return 0;
error1:
atc_pcm_release_resources(atc, apcm);
return err;
}
static int atc_pll_init(struct ct_atc *atc, int rate)
{
struct hw *hw = atc->hw;
int err;
err = hw->pll_init(hw, rate);
atc->pll_rate = err ? 0 : rate;
return err;
}
static int
spdif_passthru_playback_setup(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct dao *dao = container_of(atc->daios[SPDIFOO], struct dao, daio);
unsigned int rate = apcm->substream->runtime->rate;
unsigned int status;
int err = 0;
unsigned char iec958_con_fs;
switch (rate) {
case 48000:
iec958_con_fs = IEC958_AES3_CON_FS_48000;
break;
case 44100:
iec958_con_fs = IEC958_AES3_CON_FS_44100;
break;
case 32000:
iec958_con_fs = IEC958_AES3_CON_FS_32000;
break;
default:
return -ENOENT;
}
mutex_lock(&atc->atc_mutex);
dao->ops->get_spos(dao, &status);
if (((status >> 24) & IEC958_AES3_CON_FS) != iec958_con_fs) {
status &= ~(IEC958_AES3_CON_FS << 24);
status |= (iec958_con_fs << 24);
dao->ops->set_spos(dao, status);
dao->ops->commit_write(dao);
}
if ((rate != atc->pll_rate) && (32000 != rate))
err = atc_pll_init(atc, rate);
mutex_unlock(&atc->atc_mutex);
return err;
}
static int
spdif_passthru_playback_prepare(struct ct_atc *atc, struct ct_atc_pcm *apcm)
{
struct src *src;
struct amixer *amixer;
struct dao *dao;
int err;
int i;
atc_pcm_release_resources(atc, apcm);
/* Configure SPDIFOO and PLL to passthrough mode;
* determine pll_rate. */
err = spdif_passthru_playback_setup(atc, apcm);
if (err)
return err;
/* Get needed resources. */
err = spdif_passthru_playback_get_resources(atc, apcm);
if (err)
return err;
/* Connect resources */
src = apcm->src;
for (i = 0; i < apcm->n_amixer; i++) {
amixer = apcm->amixers[i];
amixer->ops->setup(amixer, &src->rsc, INIT_VOL, NULL);
src = src->ops->next_interleave(src);
if (!src)
src = apcm->src;
}
/* Connect to SPDIFOO */
mutex_lock(&atc->atc_mutex);
dao = container_of(atc->daios[SPDIFOO], struct dao, daio);
amixer = apcm->amixers[0];
dao->ops->set_left_input(dao, &amixer->rsc);
amixer = apcm->amixers[1];
dao->ops->set_right_input(dao, &amixer->rsc);
mutex_unlock(&atc->atc_mutex);
ct_timer_prepare(apcm->timer);
return 0;
}
static int atc_select_line_in(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
struct ct_mixer *mixer = atc->mixer;
struct src *src;
if (hw->is_adc_source_selected(hw, ADC_LINEIN))
return 0;
mixer->set_input_left(mixer, MIX_MIC_IN, NULL);
mixer->set_input_right(mixer, MIX_MIC_IN, NULL);
hw->select_adc_source(hw, ADC_LINEIN);
src = atc->srcs[2];
mixer->set_input_left(mixer, MIX_LINE_IN, &src->rsc);
src = atc->srcs[3];
mixer->set_input_right(mixer, MIX_LINE_IN, &src->rsc);
return 0;
}
static int atc_select_mic_in(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
struct ct_mixer *mixer = atc->mixer;
struct src *src;
if (hw->is_adc_source_selected(hw, ADC_MICIN))
return 0;
mixer->set_input_left(mixer, MIX_LINE_IN, NULL);
mixer->set_input_right(mixer, MIX_LINE_IN, NULL);
hw->select_adc_source(hw, ADC_MICIN);
src = atc->srcs[2];
mixer->set_input_left(mixer, MIX_MIC_IN, &src->rsc);
src = atc->srcs[3];
mixer->set_input_right(mixer, MIX_MIC_IN, &src->rsc);
return 0;
}
static struct capabilities atc_capabilities(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
return hw->capabilities(hw);
}
static int atc_output_switch_get(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
return hw->output_switch_get(hw);
}
static int atc_output_switch_put(struct ct_atc *atc, int position)
{
struct hw *hw = atc->hw;
return hw->output_switch_put(hw, position);
}
static int atc_mic_source_switch_get(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
return hw->mic_source_switch_get(hw);
}
static int atc_mic_source_switch_put(struct ct_atc *atc, int position)
{
struct hw *hw = atc->hw;
return hw->mic_source_switch_put(hw, position);
}
static int atc_select_digit_io(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
if (hw->is_adc_source_selected(hw, ADC_NONE))
return 0;
hw->select_adc_source(hw, ADC_NONE);
return 0;
}
static int atc_daio_unmute(struct ct_atc *atc, unsigned char state, int type)
{
struct daio_mgr *daio_mgr = atc->rsc_mgrs[DAIO];
if (state)
daio_mgr->daio_enable(daio_mgr, atc->daios[type]);
else
daio_mgr->daio_disable(daio_mgr, atc->daios[type]);
daio_mgr->commit_write(daio_mgr);
return 0;
}
static int
atc_dao_get_status(struct ct_atc *atc, unsigned int *status, int type)
{
struct dao *dao = container_of(atc->daios[type], struct dao, daio);
return dao->ops->get_spos(dao, status);
}
static int
atc_dao_set_status(struct ct_atc *atc, unsigned int status, int type)
{
struct dao *dao = container_of(atc->daios[type], struct dao, daio);
dao->ops->set_spos(dao, status);
dao->ops->commit_write(dao);
return 0;
}
static int atc_line_front_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, LINEO1);
}
static int atc_line_surround_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, LINEO2);
}
static int atc_line_clfe_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, LINEO3);
}
static int atc_line_rear_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, LINEO4);
}
static int atc_line_in_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, LINEIM);
}
static int atc_mic_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, MIC);
}
static int atc_spdif_out_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, SPDIFOO);
}
static int atc_spdif_in_unmute(struct ct_atc *atc, unsigned char state)
{
return atc_daio_unmute(atc, state, SPDIFIO);
}
static int atc_spdif_out_get_status(struct ct_atc *atc, unsigned int *status)
{
return atc_dao_get_status(atc, status, SPDIFOO);
}
static int atc_spdif_out_set_status(struct ct_atc *atc, unsigned int status)
{
return atc_dao_set_status(atc, status, SPDIFOO);
}
static int atc_spdif_out_passthru(struct ct_atc *atc, unsigned char state)
{
struct dao_desc da_dsc = {0};
struct dao *dao;
int err;
struct ct_mixer *mixer = atc->mixer;
struct rsc *rscs[2] = {NULL};
unsigned int spos = 0;
mutex_lock(&atc->atc_mutex);
dao = container_of(atc->daios[SPDIFOO], struct dao, daio);
da_dsc.msr = state ? 1 : atc->msr;
da_dsc.passthru = state ? 1 : 0;
err = dao->ops->reinit(dao, &da_dsc);
if (state) {
spos = IEC958_DEFAULT_CON;
} else {
mixer->get_output_ports(mixer, MIX_SPDIF_OUT,
&rscs[0], &rscs[1]);
dao->ops->set_left_input(dao, rscs[0]);
dao->ops->set_right_input(dao, rscs[1]);
/* Restore PLL to atc->rsr if needed. */
if (atc->pll_rate != atc->rsr)
err = atc_pll_init(atc, atc->rsr);
}
dao->ops->set_spos(dao, spos);
dao->ops->commit_write(dao);
mutex_unlock(&atc->atc_mutex);
return err;
}
static int atc_release_resources(struct ct_atc *atc)
{
int i;
struct daio_mgr *daio_mgr = NULL;
struct dao *dao = NULL;
struct daio *daio = NULL;
struct sum_mgr *sum_mgr = NULL;
struct src_mgr *src_mgr = NULL;
struct srcimp_mgr *srcimp_mgr = NULL;
struct srcimp *srcimp = NULL;
struct ct_mixer *mixer = NULL;
/* disconnect internal mixer objects */
if (atc->mixer) {
mixer = atc->mixer;
mixer->set_input_left(mixer, MIX_LINE_IN, NULL);
mixer->set_input_right(mixer, MIX_LINE_IN, NULL);
mixer->set_input_left(mixer, MIX_MIC_IN, NULL);
mixer->set_input_right(mixer, MIX_MIC_IN, NULL);
mixer->set_input_left(mixer, MIX_SPDIF_IN, NULL);
mixer->set_input_right(mixer, MIX_SPDIF_IN, NULL);
}
if (atc->daios) {
daio_mgr = (struct daio_mgr *)atc->rsc_mgrs[DAIO];
for (i = 0; i < atc->n_daio; i++) {
daio = atc->daios[i];
if (daio->type < LINEIM) {
dao = container_of(daio, struct dao, daio);
dao->ops->clear_left_input(dao);
dao->ops->clear_right_input(dao);
}
daio_mgr->put_daio(daio_mgr, daio);
}
kfree(atc->daios);
atc->daios = NULL;
}
if (atc->pcm) {
sum_mgr = atc->rsc_mgrs[SUM];
for (i = 0; i < atc->n_pcm; i++)
sum_mgr->put_sum(sum_mgr, atc->pcm[i]);
kfree(atc->pcm);
atc->pcm = NULL;
}
if (atc->srcs) {
src_mgr = atc->rsc_mgrs[SRC];
for (i = 0; i < atc->n_src; i++)
src_mgr->put_src(src_mgr, atc->srcs[i]);
kfree(atc->srcs);
atc->srcs = NULL;
}
if (atc->srcimps) {
srcimp_mgr = atc->rsc_mgrs[SRCIMP];
for (i = 0; i < atc->n_srcimp; i++) {
srcimp = atc->srcimps[i];
srcimp->ops->unmap(srcimp);
srcimp_mgr->put_srcimp(srcimp_mgr, atc->srcimps[i]);
}
kfree(atc->srcimps);
atc->srcimps = NULL;
}
return 0;
}
static int ct_atc_destroy(struct ct_atc *atc)
{
int i = 0;
if (!atc)
return 0;
if (atc->timer) {
ct_timer_free(atc->timer);
atc->timer = NULL;
}
atc_release_resources(atc);
/* Destroy internal mixer objects */
if (atc->mixer)
ct_mixer_destroy(atc->mixer);
for (i = 0; i < NUM_RSCTYP; i++) {
if (rsc_mgr_funcs[i].destroy && atc->rsc_mgrs[i])
rsc_mgr_funcs[i].destroy(atc->rsc_mgrs[i]);
}
if (atc->hw)
destroy_hw_obj(atc->hw);
/* Destroy device virtual memory manager object */
if (atc->vm) {
ct_vm_destroy(atc->vm);
atc->vm = NULL;
}
kfree(atc);
return 0;
}
static int atc_dev_free(struct snd_device *dev)
{
struct ct_atc *atc = dev->device_data;
return ct_atc_destroy(atc);
}
static int atc_identify_card(struct ct_atc *atc, unsigned int ssid)
{
const struct snd_pci_quirk *p;
const struct snd_pci_quirk *list;
u16 vendor_id, device_id;
switch (atc->chip_type) {
case ATC20K1:
atc->chip_name = "20K1";
list = subsys_20k1_list;
break;
case ATC20K2:
atc->chip_name = "20K2";
list = subsys_20k2_list;
break;
default:
return -ENOENT;
}
if (ssid) {
vendor_id = ssid >> 16;
device_id = ssid & 0xffff;
} else {
vendor_id = atc->pci->subsystem_vendor;
device_id = atc->pci->subsystem_device;
}
p = snd_pci_quirk_lookup_id(vendor_id, device_id, list);
if (p) {
if (p->value < 0) {
dev_err(atc->card->dev,
"Device %04x:%04x is black-listed\n",
vendor_id, device_id);
return -ENOENT;
}
atc->model = p->value;
} else {
if (atc->chip_type == ATC20K1)
atc->model = CT20K1_UNKNOWN;
else
atc->model = CT20K2_UNKNOWN;
}
atc->model_name = ct_subsys_name[atc->model];
dev_info(atc->card->dev, "chip %s model %s (%04x:%04x) is found\n",
atc->chip_name, atc->model_name,
vendor_id, device_id);
return 0;
}
int ct_atc_create_alsa_devs(struct ct_atc *atc)
{
enum CTALSADEVS i;
int err;
alsa_dev_funcs[MIXER].public_name = atc->chip_name;
for (i = 0; i < NUM_CTALSADEVS; i++) {
if (!alsa_dev_funcs[i].create)
continue;
err = alsa_dev_funcs[i].create(atc, i,
alsa_dev_funcs[i].public_name);
if (err) {
dev_err(atc->card->dev,
"Creating alsa device %d failed!\n", i);
return err;
}
}
return 0;
}
static int atc_create_hw_devs(struct ct_atc *atc)
{
struct hw *hw;
struct card_conf info = {0};
int i, err;
err = create_hw_obj(atc->pci, atc->chip_type, atc->model, &hw);
if (err) {
dev_err(atc->card->dev, "Failed to create hw obj!!!\n");
return err;
}
hw->card = atc->card;
atc->hw = hw;
/* Initialize card hardware. */
info.rsr = atc->rsr;
info.msr = atc->msr;
info.vm_pgt_phys = atc_get_ptp_phys(atc, 0);
err = hw->card_init(hw, &info);
if (err < 0)
return err;
for (i = 0; i < NUM_RSCTYP; i++) {
if (!rsc_mgr_funcs[i].create)
continue;
err = rsc_mgr_funcs[i].create(atc->hw, &atc->rsc_mgrs[i]);
if (err) {
dev_err(atc->card->dev,
"Failed to create rsc_mgr %d!!!\n", i);
return err;
}
}
return 0;
}
static int atc_get_resources(struct ct_atc *atc)
{
struct daio_desc da_desc = {0};
struct daio_mgr *daio_mgr;
struct src_desc src_dsc = {0};
struct src_mgr *src_mgr;
struct srcimp_desc srcimp_dsc = {0};
struct srcimp_mgr *srcimp_mgr;
struct sum_desc sum_dsc = {0};
struct sum_mgr *sum_mgr;
int err, i, num_srcs, num_daios;
num_daios = ((atc->model == CTSB1270) ? 8 : 7);
num_srcs = ((atc->model == CTSB1270) ? 6 : 4);
atc->daios = kzalloc(sizeof(void *)*num_daios, GFP_KERNEL);
if (!atc->daios)
return -ENOMEM;
atc->srcs = kzalloc(sizeof(void *)*num_srcs, GFP_KERNEL);
if (!atc->srcs)
return -ENOMEM;
atc->srcimps = kzalloc(sizeof(void *)*num_srcs, GFP_KERNEL);
if (!atc->srcimps)
return -ENOMEM;
atc->pcm = kzalloc(sizeof(void *)*(2*4), GFP_KERNEL);
if (!atc->pcm)
return -ENOMEM;
daio_mgr = (struct daio_mgr *)atc->rsc_mgrs[DAIO];
da_desc.msr = atc->msr;
for (i = 0, atc->n_daio = 0; i < num_daios; i++) {
da_desc.type = (atc->model != CTSB073X) ? i :
((i == SPDIFIO) ? SPDIFI1 : i);
err = daio_mgr->get_daio(daio_mgr, &da_desc,
(struct daio **)&atc->daios[i]);
if (err) {
dev_err(atc->card->dev,
"Failed to get DAIO resource %d!!!\n",
i);
return err;
}
atc->n_daio++;
}
src_mgr = atc->rsc_mgrs[SRC];
src_dsc.multi = 1;
src_dsc.msr = atc->msr;
src_dsc.mode = ARCRW;
for (i = 0, atc->n_src = 0; i < num_srcs; i++) {
err = src_mgr->get_src(src_mgr, &src_dsc,
(struct src **)&atc->srcs[i]);
if (err)
return err;
atc->n_src++;
}
srcimp_mgr = atc->rsc_mgrs[SRCIMP];
srcimp_dsc.msr = 8;
for (i = 0, atc->n_srcimp = 0; i < num_srcs; i++) {
err = srcimp_mgr->get_srcimp(srcimp_mgr, &srcimp_dsc,
(struct srcimp **)&atc->srcimps[i]);
if (err)
return err;
atc->n_srcimp++;
}
sum_mgr = atc->rsc_mgrs[SUM];
sum_dsc.msr = atc->msr;
for (i = 0, atc->n_pcm = 0; i < (2*4); i++) {
err = sum_mgr->get_sum(sum_mgr, &sum_dsc,
(struct sum **)&atc->pcm[i]);
if (err)
return err;
atc->n_pcm++;
}
return 0;
}
static void
atc_connect_dai(struct src_mgr *src_mgr, struct dai *dai,
struct src **srcs, struct srcimp **srcimps)
{
struct rsc *rscs[2] = {NULL};
struct src *src;
struct srcimp *srcimp;
int i = 0;
rscs[0] = &dai->daio.rscl;
rscs[1] = &dai->daio.rscr;
for (i = 0; i < 2; i++) {
src = srcs[i];
srcimp = srcimps[i];
srcimp->ops->map(srcimp, src, rscs[i]);
src_mgr->src_disable(src_mgr, src);
}
src_mgr->commit_write(src_mgr); /* Actually disable SRCs */
src = srcs[0];
src->ops->set_pm(src, 1);
for (i = 0; i < 2; i++) {
src = srcs[i];
src->ops->set_state(src, SRC_STATE_RUN);
src->ops->commit_write(src);
src_mgr->src_enable_s(src_mgr, src);
}
dai->ops->set_srt_srcl(dai, &(srcs[0]->rsc));
dai->ops->set_srt_srcr(dai, &(srcs[1]->rsc));
dai->ops->set_enb_src(dai, 1);
dai->ops->set_enb_srt(dai, 1);
dai->ops->commit_write(dai);
src_mgr->commit_write(src_mgr); /* Synchronously enable SRCs */
}
static void atc_connect_resources(struct ct_atc *atc)
{
struct dai *dai;
struct dao *dao;
struct src *src;
struct sum *sum;
struct ct_mixer *mixer;
struct rsc *rscs[2] = {NULL};
int i, j;
mixer = atc->mixer;
for (i = MIX_WAVE_FRONT, j = LINEO1; i <= MIX_SPDIF_OUT; i++, j++) {
mixer->get_output_ports(mixer, i, &rscs[0], &rscs[1]);
dao = container_of(atc->daios[j], struct dao, daio);
dao->ops->set_left_input(dao, rscs[0]);
dao->ops->set_right_input(dao, rscs[1]);
}
dai = container_of(atc->daios[LINEIM], struct dai, daio);
atc_connect_dai(atc->rsc_mgrs[SRC], dai,
(struct src **)&atc->srcs[2],
(struct srcimp **)&atc->srcimps[2]);
src = atc->srcs[2];
mixer->set_input_left(mixer, MIX_LINE_IN, &src->rsc);
src = atc->srcs[3];
mixer->set_input_right(mixer, MIX_LINE_IN, &src->rsc);
if (atc->model == CTSB1270) {
/* Titanium HD has a dedicated ADC for the Mic. */
dai = container_of(atc->daios[MIC], struct dai, daio);
atc_connect_dai(atc->rsc_mgrs[SRC], dai,
(struct src **)&atc->srcs[4],
(struct srcimp **)&atc->srcimps[4]);
src = atc->srcs[4];
mixer->set_input_left(mixer, MIX_MIC_IN, &src->rsc);
src = atc->srcs[5];
mixer->set_input_right(mixer, MIX_MIC_IN, &src->rsc);
}
dai = container_of(atc->daios[SPDIFIO], struct dai, daio);
atc_connect_dai(atc->rsc_mgrs[SRC], dai,
(struct src **)&atc->srcs[0],
(struct srcimp **)&atc->srcimps[0]);
src = atc->srcs[0];
mixer->set_input_left(mixer, MIX_SPDIF_IN, &src->rsc);
src = atc->srcs[1];
mixer->set_input_right(mixer, MIX_SPDIF_IN, &src->rsc);
for (i = MIX_PCMI_FRONT, j = 0; i <= MIX_PCMI_SURROUND; i++, j += 2) {
sum = atc->pcm[j];
mixer->set_input_left(mixer, i, &sum->rsc);
sum = atc->pcm[j+1];
mixer->set_input_right(mixer, i, &sum->rsc);
}
}
#ifdef CONFIG_PM_SLEEP
static int atc_suspend(struct ct_atc *atc)
{
int i;
struct hw *hw = atc->hw;
snd_power_change_state(atc->card, SNDRV_CTL_POWER_D3hot);
for (i = FRONT; i < NUM_PCMS; i++) {
if (!atc->pcms[i])
continue;
snd_pcm_suspend_all(atc->pcms[i]);
}
atc_release_resources(atc);
hw->suspend(hw);
return 0;
}
static int atc_hw_resume(struct ct_atc *atc)
{
struct hw *hw = atc->hw;
struct card_conf info = {0};
/* Re-initialize card hardware. */
info.rsr = atc->rsr;
info.msr = atc->msr;
info.vm_pgt_phys = atc_get_ptp_phys(atc, 0);
return hw->resume(hw, &info);
}
static int atc_resources_resume(struct ct_atc *atc)
{
struct ct_mixer *mixer;
int err = 0;
/* Get resources */
err = atc_get_resources(atc);
if (err < 0) {
atc_release_resources(atc);
return err;
}
/* Build topology */
atc_connect_resources(atc);
mixer = atc->mixer;
mixer->resume(mixer);
return 0;
}
static int atc_resume(struct ct_atc *atc)
{
int err = 0;
/* Do hardware resume. */
err = atc_hw_resume(atc);
if (err < 0) {
dev_err(atc->card->dev,
"pci_enable_device failed, disabling device\n");
snd_card_disconnect(atc->card);
return err;
}
err = atc_resources_resume(atc);
if (err < 0)
return err;
snd_power_change_state(atc->card, SNDRV_CTL_POWER_D0);
return 0;
}
#endif
static struct ct_atc atc_preset = {
.map_audio_buffer = ct_map_audio_buffer,
.unmap_audio_buffer = ct_unmap_audio_buffer,
.pcm_playback_prepare = atc_pcm_playback_prepare,
.pcm_release_resources = atc_pcm_release_resources,
.pcm_playback_start = atc_pcm_playback_start,
.pcm_playback_stop = atc_pcm_stop,
.pcm_playback_position = atc_pcm_playback_position,
.pcm_capture_prepare = atc_pcm_capture_prepare,
.pcm_capture_start = atc_pcm_capture_start,
.pcm_capture_stop = atc_pcm_stop,
.pcm_capture_position = atc_pcm_capture_position,
.spdif_passthru_playback_prepare = spdif_passthru_playback_prepare,
.get_ptp_phys = atc_get_ptp_phys,
.select_line_in = atc_select_line_in,
.select_mic_in = atc_select_mic_in,
.select_digit_io = atc_select_digit_io,
.line_front_unmute = atc_line_front_unmute,
.line_surround_unmute = atc_line_surround_unmute,
.line_clfe_unmute = atc_line_clfe_unmute,
.line_rear_unmute = atc_line_rear_unmute,
.line_in_unmute = atc_line_in_unmute,
.mic_unmute = atc_mic_unmute,
.spdif_out_unmute = atc_spdif_out_unmute,
.spdif_in_unmute = atc_spdif_in_unmute,
.spdif_out_get_status = atc_spdif_out_get_status,
.spdif_out_set_status = atc_spdif_out_set_status,
.spdif_out_passthru = atc_spdif_out_passthru,
.capabilities = atc_capabilities,
.output_switch_get = atc_output_switch_get,
.output_switch_put = atc_output_switch_put,
.mic_source_switch_get = atc_mic_source_switch_get,
.mic_source_switch_put = atc_mic_source_switch_put,
#ifdef CONFIG_PM_SLEEP
.suspend = atc_suspend,
.resume = atc_resume,
#endif
};
/**
* ct_atc_create - create and initialize a hardware manager
* @card: corresponding alsa card object
* @pci: corresponding kernel pci device object
* @ratc: return created object address in it
*
* Creates and initializes a hardware manager.
*
* Creates kmallocated ct_atc structure. Initializes hardware.
* Returns 0 if succeeds, or negative error code if fails.
*/
int ct_atc_create(struct snd_card *card, struct pci_dev *pci,
unsigned int rsr, unsigned int msr,
int chip_type, unsigned int ssid,
struct ct_atc **ratc)
{
struct ct_atc *atc;
static struct snd_device_ops ops = {
.dev_free = atc_dev_free,
};
int err;
*ratc = NULL;
atc = kzalloc(sizeof(*atc), GFP_KERNEL);
if (!atc)
return -ENOMEM;
/* Set operations */
*atc = atc_preset;
atc->card = card;
atc->pci = pci;
atc->rsr = rsr;
atc->msr = msr;
atc->chip_type = chip_type;
mutex_init(&atc->atc_mutex);
/* Find card model */
err = atc_identify_card(atc, ssid);
if (err < 0) {
dev_err(card->dev, "ctatc: Card not recognised\n");
goto error1;
}
/* Set up device virtual memory management object */
err = ct_vm_create(&atc->vm, pci);
if (err < 0)
goto error1;
/* Create all atc hw devices */
err = atc_create_hw_devs(atc);
if (err < 0)
goto error1;
err = ct_mixer_create(atc, (struct ct_mixer **)&atc->mixer);
if (err) {
dev_err(card->dev, "Failed to create mixer obj!!!\n");
goto error1;
}
/* Get resources */
err = atc_get_resources(atc);
if (err < 0)
goto error1;
/* Build topology */
atc_connect_resources(atc);
atc->timer = ct_timer_new(atc);
if (!atc->timer) {
err = -ENOMEM;
goto error1;
}
err = snd_device_new(card, SNDRV_DEV_LOWLEVEL, atc, &ops);
if (err < 0)
goto error1;
*ratc = atc;
return 0;
error1:
ct_atc_destroy(atc);
dev_err(card->dev, "Something wrong!!!\n");
return err;
}