OpenCloudOS-Kernel/sound/firewire/dice/dice.c

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// SPDX-License-Identifier: GPL-2.0-only
/*
* TC Applied Technologies Digital Interface Communications Engine driver
*
* Copyright (c) Clemens Ladisch <clemens@ladisch.de>
*/
#include "dice.h"
MODULE_DESCRIPTION("DICE driver");
MODULE_AUTHOR("Clemens Ladisch <clemens@ladisch.de>");
MODULE_LICENSE("GPL v2");
#define OUI_WEISS 0x001c6a
#define OUI_LOUD 0x000ff2
#define OUI_FOCUSRITE 0x00130e
#define OUI_TCELECTRONIC 0x000166
#define OUI_ALESIS 0x000595
#define OUI_MAUDIO 0x000d6c
#define OUI_MYTEK 0x001ee8
ALSA: dice: add support for Solid State Logic Duende Classic/Mini Duende Classic was produced by Solid State Logic in 2006, as a first model of Duende DSP series. The following model, Duende Mini was produced in 2008. They are designed to receive isochronous packets for PCM frames via IEEE 1394 bus, perform signal processing by downloaded program, then transfer isochronous packets for converted PCM frames. These two models includes the same embedded board, consists of several ICs below: - Texus Instruments Inc, TSB41AB3 for physical layer of IEEE 1394 bus - WaveFront semiconductor, DICE II STD ASIC for link/protocol layer - Altera MAX 3000A CPLD for programs - Analog devices, SHARC ADSP-21363 for signal processing (4 chips) This commit adds support for the two models to ALSA dice driver. Like support for the other devices, packet streaming is just available. Userspace applications should be developed if full features became available; e.g. program uploader and parameter controller. $ ./hinawa-config-rom-printer /dev/fw1 { 'bus-info': { 'adj': False, 'bmc': False, 'chip_ID': 349771402425, 'cmc': True, 'cyc_clk_acc': 255, 'generation': 1, 'imc': True, 'isc': True, 'link_spd': 2, 'max_ROM': 1, 'max_rec': 512, 'name': '1394', 'node_vendor_ID': 20674, 'pmc': False}, 'root-directory': [ ['VENDOR', 20674], ['DESCRIPTOR', 'Solid State Logic'], ['MODEL', 112], ['DESCRIPTOR', 'Duende board'], [ 'NODE_CAPABILITIES', { 'addressing': {'64': True, 'fix': True, 'prv': True}, 'misc': {'int': False, 'ms': False, 'spt': True}, 'state': { 'atn': False, 'ded': False, 'drq': True, 'elo': False, 'init': False, 'lst': True, 'off': False}, 'testing': {'bas': False, 'ext': False}}], [ 'UNIT', [ ['SPECIFIER_ID', 20674], ['VERSION', 1], ['MODEL', 112], ['DESCRIPTOR', 'Duende board']]]]} Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2019-01-28 19:40:58 +08:00
#define OUI_SSL 0x0050c2 // Actually ID reserved by IEEE.
ALSA: dice: add stream format parameters for PreSonus FireStudio FireStudio was launched by PreSonus 2009. This model consists of three ICs for its packet processing on IEEE 1394 bus: - Texus Instruments TSB41AB2 for physical layer of IEEE 1394 bus - WaveFront semiconductor, Dice II STD ASIC for link layer of IEEE 1394 bus and protocol layer - Xilinx Spartan XG3S500E FPGA for signal processing This model don't support TCAT extended application protocol. For such devices, ALSA dice driver needs to have hard-coded parameters for stream formats. This commit adds hard-coded table for this model. As a result, sampling transfer frequencies of 88.2/96.0 kHz are supported. I note that this patch can be backported to Linux kernel v4.18 and later. $ python2 crpp < /sys/bus/firewire/devices/fw1/config_rom ROM header and bus information block ----------------------------------------------------------------- 400 04042eda bus_info_length 4, crc_length 4, crc 11994 404 31333934 bus_name "1394" 408 e0ff8112 irmc 1, cmc 1, isc 1, bmc 0, pmc 0, cyc_clk_acc 255, max_rec 8 (512), max_rom 1, gen 1, spd 2 (S400) 40c 000a9204 company_id 000a92 | 410 023a8b7f device_id 04023a8b7f | EUI-64 000a9204023a8b7f root directory ----------------------------------------------------------------- 414 000661b6 directory_length 6, crc 25014 418 03000a92 vendor 41c 8100000a --> descriptor leaf at 444 420 17000008 model 424 8100000d --> descriptor leaf at 458 428 0c0087c0 node capabilities per IEEE 1394 42c d1000001 --> unit directory at 430 unit directory at 430 ----------------------------------------------------------------- 430 00041c75 directory_length 4, crc 7285 434 12000a92 specifier id 438 13000001 version 43c 17000008 model 440 8100000c --> descriptor leaf at 470 descriptor leaf at 444 ----------------------------------------------------------------- 444 00047c11 leaf_length 4, crc 31761 448 00000000 textual descriptor 44c 00000000 minimal ASCII 450 50726553 "PreS" 454 6f6e7573 "onus" descriptor leaf at 458 ----------------------------------------------------------------- 458 0005d7b3 leaf_length 5, crc 55219 45c 00000000 textual descriptor 460 00000000 minimal ASCII 464 46495245 "FIRE" 468 53545544 "STUD" 46c 494f0000 "IO" descriptor leaf at 470 ----------------------------------------------------------------- 470 0005d7b3 leaf_length 5, crc 55219 474 00000000 textual descriptor 478 00000000 minimal ASCII 47c 46495245 "FIRE" 480 53545544 "STUD" 484 494f0000 "IO" Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2019-05-17 10:56:22 +08:00
#define OUI_PRESONUS 0x000a92
#define DICE_CATEGORY_ID 0x04
#define WEISS_CATEGORY_ID 0x00
#define LOUD_CATEGORY_ID 0x10
#define MODEL_ALESIS_IO_BOTH 0x000001
static int check_dice_category(struct fw_unit *unit)
{
struct fw_device *device = fw_parent_device(unit);
struct fw_csr_iterator it;
int key, val, vendor = -1, model = -1;
unsigned int category;
/*
* Check that GUID and unit directory are constructed according to DICE
* rules, i.e., that the specifier ID is the GUID's OUI, and that the
* GUID chip ID consists of the 8-bit category ID, the 10-bit product
* ID, and a 22-bit serial number.
*/
fw_csr_iterator_init(&it, unit->directory);
while (fw_csr_iterator_next(&it, &key, &val)) {
switch (key) {
case CSR_SPECIFIER_ID:
vendor = val;
break;
case CSR_MODEL:
model = val;
break;
}
}
if (vendor == OUI_WEISS)
category = WEISS_CATEGORY_ID;
else if (vendor == OUI_LOUD)
category = LOUD_CATEGORY_ID;
else
category = DICE_CATEGORY_ID;
if (device->config_rom[3] != ((vendor << 8) | category) ||
device->config_rom[4] >> 22 != model)
return -ENODEV;
return 0;
}
static int check_clock_caps(struct snd_dice *dice)
{
__be32 value;
int err;
/* some very old firmwares don't tell about their clock support */
if (dice->clock_caps > 0) {
err = snd_dice_transaction_read_global(dice,
GLOBAL_CLOCK_CAPABILITIES,
&value, 4);
if (err < 0)
return err;
dice->clock_caps = be32_to_cpu(value);
} else {
/* this should be supported by any device */
dice->clock_caps = CLOCK_CAP_RATE_44100 |
CLOCK_CAP_RATE_48000 |
CLOCK_CAP_SOURCE_ARX1 |
CLOCK_CAP_SOURCE_INTERNAL;
}
return 0;
}
static void dice_card_strings(struct snd_dice *dice)
{
struct snd_card *card = dice->card;
struct fw_device *dev = fw_parent_device(dice->unit);
char vendor[32], model[32];
unsigned int i;
int err;
strcpy(card->driver, "DICE");
strcpy(card->shortname, "DICE");
BUILD_BUG_ON(NICK_NAME_SIZE < sizeof(card->shortname));
err = snd_dice_transaction_read_global(dice, GLOBAL_NICK_NAME,
card->shortname,
sizeof(card->shortname));
if (err >= 0) {
/* DICE strings are returned in "always-wrong" endianness */
BUILD_BUG_ON(sizeof(card->shortname) % 4 != 0);
for (i = 0; i < sizeof(card->shortname); i += 4)
swab32s((u32 *)&card->shortname[i]);
card->shortname[sizeof(card->shortname) - 1] = '\0';
}
strcpy(vendor, "?");
fw_csr_string(dev->config_rom + 5, CSR_VENDOR, vendor, sizeof(vendor));
strcpy(model, "?");
fw_csr_string(dice->unit->directory, CSR_MODEL, model, sizeof(model));
snprintf(card->longname, sizeof(card->longname),
"%s %s (serial %u) at %s, S%d",
vendor, model, dev->config_rom[4] & 0x3fffff,
dev_name(&dice->unit->device), 100 << dev->max_speed);
strcpy(card->mixername, "DICE");
}
static void dice_card_free(struct snd_card *card)
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
{
struct snd_dice *dice = card->private_data;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
snd_dice_stream_destroy_duplex(dice);
snd_dice_transaction_destroy(dice);
}
static void do_registration(struct work_struct *work)
{
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
struct snd_dice *dice = container_of(work, struct snd_dice, dwork.work);
int err;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
if (dice->registered)
return;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
err = snd_card_new(&dice->unit->device, -1, NULL, THIS_MODULE, 0,
&dice->card);
if (err < 0)
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
return;
dice->card->private_free = dice_card_free;
dice->card->private_data = dice;
err = snd_dice_transaction_init(dice);
if (err < 0)
goto error;
err = check_clock_caps(dice);
if (err < 0)
goto error;
dice_card_strings(dice);
err = dice->detect_formats(dice);
if (err < 0)
goto error;
err = snd_dice_stream_init_duplex(dice);
if (err < 0)
goto error;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
snd_dice_create_proc(dice);
err = snd_dice_create_pcm(dice);
if (err < 0)
goto error;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
err = snd_dice_create_midi(dice);
if (err < 0)
goto error;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
err = snd_dice_create_hwdep(dice);
if (err < 0)
goto error;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
err = snd_card_register(dice->card);
if (err < 0)
goto error;
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
dice->registered = true;
return;
error:
snd_card_free(dice->card);
dev_info(&dice->unit->device,
"Sound card registration failed: %d\n", err);
}
static int dice_probe(struct fw_unit *unit,
const struct ieee1394_device_id *entry)
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
{
struct snd_dice *dice;
int err;
ALSA: dice: add support for Solid State Logic Duende Classic/Mini Duende Classic was produced by Solid State Logic in 2006, as a first model of Duende DSP series. The following model, Duende Mini was produced in 2008. They are designed to receive isochronous packets for PCM frames via IEEE 1394 bus, perform signal processing by downloaded program, then transfer isochronous packets for converted PCM frames. These two models includes the same embedded board, consists of several ICs below: - Texus Instruments Inc, TSB41AB3 for physical layer of IEEE 1394 bus - WaveFront semiconductor, DICE II STD ASIC for link/protocol layer - Altera MAX 3000A CPLD for programs - Analog devices, SHARC ADSP-21363 for signal processing (4 chips) This commit adds support for the two models to ALSA dice driver. Like support for the other devices, packet streaming is just available. Userspace applications should be developed if full features became available; e.g. program uploader and parameter controller. $ ./hinawa-config-rom-printer /dev/fw1 { 'bus-info': { 'adj': False, 'bmc': False, 'chip_ID': 349771402425, 'cmc': True, 'cyc_clk_acc': 255, 'generation': 1, 'imc': True, 'isc': True, 'link_spd': 2, 'max_ROM': 1, 'max_rec': 512, 'name': '1394', 'node_vendor_ID': 20674, 'pmc': False}, 'root-directory': [ ['VENDOR', 20674], ['DESCRIPTOR', 'Solid State Logic'], ['MODEL', 112], ['DESCRIPTOR', 'Duende board'], [ 'NODE_CAPABILITIES', { 'addressing': {'64': True, 'fix': True, 'prv': True}, 'misc': {'int': False, 'ms': False, 'spt': True}, 'state': { 'atn': False, 'ded': False, 'drq': True, 'elo': False, 'init': False, 'lst': True, 'off': False}, 'testing': {'bas': False, 'ext': False}}], [ 'UNIT', [ ['SPECIFIER_ID', 20674], ['VERSION', 1], ['MODEL', 112], ['DESCRIPTOR', 'Duende board']]]]} Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2019-01-28 19:40:58 +08:00
if (!entry->driver_data && entry->vendor_id != OUI_SSL) {
err = check_dice_category(unit);
if (err < 0)
return -ENODEV;
}
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
/* Allocate this independent of sound card instance. */
dice = devm_kzalloc(&unit->device, sizeof(struct snd_dice), GFP_KERNEL);
if (!dice)
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
return -ENOMEM;
dice->unit = fw_unit_get(unit);
dev_set_drvdata(&unit->device, dice);
if (!entry->driver_data) {
dice->detect_formats = snd_dice_stream_detect_current_formats;
} else {
dice->detect_formats =
(snd_dice_detect_formats_t)entry->driver_data;
}
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
spin_lock_init(&dice->lock);
mutex_init(&dice->mutex);
init_completion(&dice->clock_accepted);
init_waitqueue_head(&dice->hwdep_wait);
/* Allocate and register this sound card later. */
INIT_DEFERRABLE_WORK(&dice->dwork, do_registration);
snd_fw_schedule_registration(unit, &dice->dwork);
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
return 0;
}
static void dice_remove(struct fw_unit *unit)
{
struct snd_dice *dice = dev_get_drvdata(&unit->device);
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
/*
* Confirm to stop the work for registration before the sound card is
* going to be released. The work is not scheduled again because bus
* reset handler is not called anymore.
*/
cancel_delayed_work_sync(&dice->dwork);
if (dice->registered) {
// Block till all of ALSA character devices are released.
snd_card_free(dice->card);
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
}
mutex_destroy(&dice->mutex);
fw_unit_put(dice->unit);
}
static void dice_bus_reset(struct fw_unit *unit)
{
struct snd_dice *dice = dev_get_drvdata(&unit->device);
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
/* Postpone a workqueue for deferred registration. */
if (!dice->registered)
snd_fw_schedule_registration(unit, &dice->dwork);
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
/* The handler address register becomes initialized. */
snd_dice_transaction_reinit(dice);
ALSA: dice: postpone card registration Some models based on ASIC for Dice II series (STD, CP) change their hardware configurations after appearing on IEEE 1394 bus. This is due to interactions of boot loader (RedBoot), firmwares (eCos) and vendor's configurations. This causes current ALSA dice driver to get wrong information about the hardware's capability because its probe function runs just after detecting unit of the model. As long as I investigated, it takes a bit time (less than 1 second) to load the firmware after bootstrap. Just after loaded, the driver can get information about the unit. Then the hardware is initialized according to vendor's configurations. After, the got information becomes wrong. Between bootstrap, firmware loading and post configuration, some bus resets are observed. This commit offloads most processing of probe function into workqueue and schedules the workqueue after successive bus resets. This has an effect to get correct hardware information and avoid involvement to bus reset storm. For code simplicity, this change effects all of Dice-based models, i.e. Dice II, Dice Jr., Dice Mini and Dice III. I use a loose strategy to manage a race condition between the work and the bus reset. This is due to a specification of dice transaction. When bus reset occurs, registered address for the transaction is cleared. Drivers must re-register their own address again. While, this operation is required for the work because the work includes to wait for the transaction. This commit uses no lock primitives for the race condition. Instead, checking 'registered' member of 'struct snd_dice' avoid executing the work again. If sound card is not registered, the work can be scheduled again by bus reset handler. When .remove callback is executed, the sound card is going to be released. The work should not be pending or executed in the releasing. This commit uses cancel_delayed_work_sync() in .remove callback and wait till the pending work finished. After .remove callback, .update callback is not executed, therefore no works are scheduled again. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2015-12-31 12:58:12 +08:00
/*
* After registration, userspace can start packet streaming, then this
* code block works fine.
*/
if (dice->registered) {
mutex_lock(&dice->mutex);
snd_dice_stream_update_duplex(dice);
mutex_unlock(&dice->mutex);
}
}
#define DICE_INTERFACE 0x000001
static const struct ieee1394_device_id dice_id_table[] = {
/* M-Audio Profire 2626 has a different value in version field. */
ALSA: dice: add support for M-Audio Profire 610 and perhaps 2626 M-Audio Profire 610 has an unexpected value in version field of its config ROM, thus ALSA dice driver is not assigned to the model due to a mismatch of modalias. This commit adds an entry to support the model. I expect the entry is also for Profire 2626. I note that Profire 610 uses TCD2220 (so-called Dice Jr.), and supports a part of Extended Application Protocol (EAP). $ cd linux-firewire-utils/src $ ./crpp < /sys/bus/firewire/devices/fw1/config_rom ROM header and bus information block ------------------------------------------------------------ 400 04047689 bus_info_length 4, crc_length 4, crc 30345 404 31333934 bus_name "1394" 408 e0ff8112 irmc 1, cmc 1, isc 1, bmc 0, pmc 0, cyc_clk_acc 255, max_rec 8 (512), max_rom 1, gen 1, spd 2 (S400) 40c 000d6c04 company_id 000d6c | 410 04400002 device_id 0404400002 | EUI-64 000d6c0404400002 root directory ------------------------------------------------------------ 414 000695fe directory_length 6, crc 38398 418 03000d6c vendor 41c 8100000a --> descriptor leaf at 444 420 17000011 model 424 8100000d --> descriptor leaf at 458 428 0c0087c0 node capabilities per IEEE 1394 42c d1000001 --> unit directory at 430 unit directory at 430 ------------------------------------------------------------ 430 0004fb14 directory_length 4, crc 64276 434 12000d6c specifier id 438 130100d1 version 43c 17000011 model 440 8100000c --> descriptor leaf at 470 descriptor leaf at 444 ------------------------------------------------------------ 444 0004b8e4 leaf_length 4, crc 47332 448 00000000 textual descriptor 44c 00000000 minimal ASCII 450 4d2d4175 "M-Au" 454 64696f00 "dio" descriptor leaf at 458 ------------------------------------------------------------ 458 00053128 leaf_length 5, crc 12584 45c 00000000 textual descriptor 460 00000000 minimal ASCII 464 50726f46 "ProF" 468 69726520 "ire " 46c 36313000 "610" descriptor leaf at 470 ------------------------------------------------------------ 470 00053128 leaf_length 5, crc 12584 474 00000000 textual descriptor 478 00000000 minimal ASCII 47c 50726f46 "ProF" 480 69726520 "ire " 484 36313000 "610" $ cat /proc/asound/card1/dice sections: global: offset 10, size 90 tx: offset 100, size 142 rx: offset 242, size 282 ext_sync: offset 524, size 4 unused2: offset 0, size 0 global: owner: ffc0:000100000000 notification: 00000040 nick name: FW610 clock select: internal 48000 enable: 1 status: locked 48000 ext status: 00000040 sample rate: 48000 version: 1.0.4.0 clock caps: 32000 44100 48000 88200 96000 176400 192000 aes1 aes4 aes adat tdif wc arx1 arx2 internal clock source names: SPDIF\AES34\AES56\TOS\AES_ANY\ADAT\ADAT_AUX\Word Clock\Unused\Unused\Unused\Unused\Internal\\ ... Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2016-04-30 21:06:46 +08:00
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_MAUDIO,
.model_id = 0x000010,
.driver_data = (kernel_ulong_t)snd_dice_detect_extension_formats,
},
/* M-Audio Profire 610 has a different value in version field. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_MAUDIO,
.model_id = 0x000011,
.driver_data = (kernel_ulong_t)snd_dice_detect_extension_formats,
ALSA: dice: add support for M-Audio Profire 610 and perhaps 2626 M-Audio Profire 610 has an unexpected value in version field of its config ROM, thus ALSA dice driver is not assigned to the model due to a mismatch of modalias. This commit adds an entry to support the model. I expect the entry is also for Profire 2626. I note that Profire 610 uses TCD2220 (so-called Dice Jr.), and supports a part of Extended Application Protocol (EAP). $ cd linux-firewire-utils/src $ ./crpp < /sys/bus/firewire/devices/fw1/config_rom ROM header and bus information block ------------------------------------------------------------ 400 04047689 bus_info_length 4, crc_length 4, crc 30345 404 31333934 bus_name "1394" 408 e0ff8112 irmc 1, cmc 1, isc 1, bmc 0, pmc 0, cyc_clk_acc 255, max_rec 8 (512), max_rom 1, gen 1, spd 2 (S400) 40c 000d6c04 company_id 000d6c | 410 04400002 device_id 0404400002 | EUI-64 000d6c0404400002 root directory ------------------------------------------------------------ 414 000695fe directory_length 6, crc 38398 418 03000d6c vendor 41c 8100000a --> descriptor leaf at 444 420 17000011 model 424 8100000d --> descriptor leaf at 458 428 0c0087c0 node capabilities per IEEE 1394 42c d1000001 --> unit directory at 430 unit directory at 430 ------------------------------------------------------------ 430 0004fb14 directory_length 4, crc 64276 434 12000d6c specifier id 438 130100d1 version 43c 17000011 model 440 8100000c --> descriptor leaf at 470 descriptor leaf at 444 ------------------------------------------------------------ 444 0004b8e4 leaf_length 4, crc 47332 448 00000000 textual descriptor 44c 00000000 minimal ASCII 450 4d2d4175 "M-Au" 454 64696f00 "dio" descriptor leaf at 458 ------------------------------------------------------------ 458 00053128 leaf_length 5, crc 12584 45c 00000000 textual descriptor 460 00000000 minimal ASCII 464 50726f46 "ProF" 468 69726520 "ire " 46c 36313000 "610" descriptor leaf at 470 ------------------------------------------------------------ 470 00053128 leaf_length 5, crc 12584 474 00000000 textual descriptor 478 00000000 minimal ASCII 47c 50726f46 "ProF" 480 69726520 "ire " 484 36313000 "610" $ cat /proc/asound/card1/dice sections: global: offset 10, size 90 tx: offset 100, size 142 rx: offset 242, size 282 ext_sync: offset 524, size 4 unused2: offset 0, size 0 global: owner: ffc0:000100000000 notification: 00000040 nick name: FW610 clock select: internal 48000 enable: 1 status: locked 48000 ext status: 00000040 sample rate: 48000 version: 1.0.4.0 clock caps: 32000 44100 48000 88200 96000 176400 192000 aes1 aes4 aes adat tdif wc arx1 arx2 internal clock source names: SPDIF\AES34\AES56\TOS\AES_ANY\ADAT\ADAT_AUX\Word Clock\Unused\Unused\Unused\Unused\Internal\\ ... Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2016-04-30 21:06:46 +08:00
},
/* TC Electronic Konnekt 24D. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000020,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
/* TC Electronic Konnekt 8. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000021,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
/* TC Electronic Studio Konnekt 48. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000022,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
/* TC Electronic Konnekt Live. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000023,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
/* TC Electronic Desktop Konnekt 6. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000024,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
/* TC Electronic Impact Twin. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000027,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
ALSA: dice: add stream format parameters for TC Electronic Digital Konnekt x32 TC Electronic Digital Konnekt x32 is an application of WaveFront DiceII STD and doesn't support TCAT extended application protocol. For such devices, ALSA dice driver needs to have hard-coded parameters for stream formats. This commit adds stream format parameters for this model. Unfortunately, at sampling transmission frequencies of 88.2/96.0kHz, I confirmed that current ALSA dice driver doesn't drive the device appropriately due to detecting packet discontinuities. $ journalctl kernel: snd_dice fw1.0: Detect discontinuity of CIP: 90 80 At the frequencies, the device transfers 16 data blocks per packet and 16 data channels per data block, as a result one packet includes 1032 bytes if it's not NODATA. However, as long as I checked, the device often postpone packet transmission and continue with truncated payload than metadata in isochronous packet header. Below is a sample of sequence I got. sec cycle bytes CIP1 CIP2 37 3314 1032 0x01100090 0x900449E2 37 3315 8 0x011000A0 0x9004FFFF 37 3316 1032 0x011000A0 0x900461E2 37 3317 1032 0x011000B0 0x900475E2 37 3318 1032 0x011000C0 0x900489E2 37 3319 8 0x011000D0 0x9004FFFF 37 3320 1032 0x011000D0 0x9004A1E2 37 3321 1032 0x011000E0 0x9004B5E2 37 3322 1032 0x011000F0 0x9004C9E2 37 3323 8 0x01100000 0x9004FFFF 37 3324 1032 0x01100000 0x9004E1E2 37 3325 1032 0x01100010 0x9004F5E2 37 3326 1032 0x01100020 0x900409E2 37 3327 8 0x01100030 0x9004FFFF 37 3328 1032 0x01100030 0x900421E2 37 3329 1032 0x01100040 0x900435E2 37 3330 (skip) 37 3331 (skip) 37 3332 (skip) 37 3333 (skip) 37 3334 (skip) 37 3335 (skip) 37 3336 (skip) 37 3337 (skip) 37 3338 (skip) 37 3339 (skip) 37 3340 (skip) 37 3341 (skip) 37 3342 (skip) 37 3343 (skip) 37 3344 (skip) 37 3345 (skip) 37 3346 (skip) 37 3347 (skip) 37 3348 (skip) 37 3349 (skip) 37 3350 (skip) 37 3351 (skip) 37 3352 (skip) 37 3353 (skip) 37 3354 (skip) 37 3355 (skip) 37 3356 (skip) 37 3357 (skip) 37 3358 (skip) 37 3359 (skip) 37 3360 (skip) 37 3361 (skip) 37 3362 (skip) 37 3363 (skip) 37 3364 (skip) 37 3365 (skip) 37 3366 (skip) 37 3367 1032 0x01100050 0x900461E1 37 3368 1032 0x01100060 0x900475E1 37 3369 1032 0x01100070 0x9004A1E1 37 3370 1032 0x01100080 0x9004A1E1 but content of payload is truncated. 37 3371 (skip) 37 3371 1032 0x01100080 0x9004B5E0 detect discontinuity 37 3372 1032 0x01100090 0x9004C9E0 37 3373 1032 0x011000A0 0x9004E1E0 37 3374 1032 0x011000B0 0x9004F5E0 37 3375 1032 0x011000C0 0x900409E0 37 3376 1032 0x011000D0 0x900421E0 37 3377 1032 0x011000E0 0x900435E0 37 3378 1032 0x011000F0 0x900449DF 37 3379 8 0x01100000 0x9004FFFF 37 3380 1032 0x01100000 0x900461DF 37 3381 1032 0x01100010 0x900475DF 37 3382 1032 0x01100020 0x900489DF 37 3383 8 0x01100030 0x9004FFFF 37 3384 1032 0x01100030 0x9004A1DF 37 3385 1032 0x01100040 0x9004B5DF 37 3386 1032 0x01100050 0x9004C9DF 37 3387 8 0x01100060 0x9004FFFF I cannot confirm this quirks with Windows driver. ALSA dice driver has a cause if assumed differences between these two drivers are ways of timestampling to RX packets from the drivers to the device. I've already reported timestamping quirk of Dice-based devices and this might bring this issue. [alsa-devel] Dice packet sequence quirk and ALSA firewire stack in Linux 4.6 http://mailman.alsa-project.org/pipermail/alsa-devel/2016-May/107715.html Well, nevertheless, I enable ALSA dice driver to work at the frequencies. This may brings inconvenience to users but I expect developers and users to fix it. $ cd linux-firewire-utils/src $ python2 crpp < /sys/bus/firewire/devices/fw1/config_rom ROM header and bus information block ----------------------------------------------------------------- 400 040423bb bus_info_length 4, crc_length 4, crc 9147 404 31333934 bus_name "1394" 408 e0ff8112 irmc 1, cmc 1, isc 1, bmc 0, pmc 0, cyc_clk_acc 255, max_rec 8 (512), max_rom 1, gen 1, spd 2 (S400) 40c 00016604 company_id 000166 | 410 0c232c28 device_id 040c232c28 | EUI-64 000166040c232c28 root directory ----------------------------------------------------------------- 414 0006b6cb directory_length 6, crc 46795 418 03000166 vendor 41c 8100000a --> descriptor leaf at 444 420 17000030 model 424 8100000f --> descriptor leaf at 460 428 0c0087c0 node capabilities per IEEE 1394 42c d1000001 --> unit directory at 430 unit directory at 430 ----------------------------------------------------------------- 430 000476c2 directory_length 4, crc 30402 434 12000166 specifier id 438 13000001 version 43c 17000030 model 440 81000010 --> descriptor leaf at 480 descriptor leaf at 444 ----------------------------------------------------------------- 444 0006c490 leaf_length 6, crc 50320 448 00000000 textual descriptor 44c 00000000 minimal ASCII 450 54432045 "TC E" 454 6c656374 "lect" 458 726f6e69 "roni" 45c 63000000 "c" descriptor leaf at 460 ----------------------------------------------------------------- 460 000772b4 leaf_length 7, crc 29364 464 00000000 textual descriptor 468 00000000 minimal ASCII 46c 44696769 "Digi" 470 74616c4b "talK" 474 6f6e6e65 "onne" 478 6b747833 "ktx3" 47c 32000000 "2" descriptor leaf at 480 ----------------------------------------------------------------- 480 000772b4 leaf_length 7, crc 29364 484 00000000 textual descriptor 488 00000000 minimal ASCII 48c 44696769 "Digi" 490 74616c4b "talK" 494 6f6e6e65 "onne" 498 6b747833 "ktx3" 49c 32000000 "2" Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2018-05-20 13:40:44 +08:00
/* TC Electronic Digital Konnekt x32. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_TCELECTRONIC,
.model_id = 0x000030,
.driver_data = (kernel_ulong_t)snd_dice_detect_tcelectronic_formats,
},
/* Alesis iO14/iO26. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_ALESIS,
.model_id = MODEL_ALESIS_IO_BOTH,
.driver_data = (kernel_ulong_t)snd_dice_detect_alesis_formats,
},
/* Mytek Stereo 192 DSD-DAC. */
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_MYTEK,
.model_id = 0x000002,
.driver_data = (kernel_ulong_t)snd_dice_detect_mytek_formats,
},
ALSA: dice: add support for Solid State Logic Duende Classic/Mini Duende Classic was produced by Solid State Logic in 2006, as a first model of Duende DSP series. The following model, Duende Mini was produced in 2008. They are designed to receive isochronous packets for PCM frames via IEEE 1394 bus, perform signal processing by downloaded program, then transfer isochronous packets for converted PCM frames. These two models includes the same embedded board, consists of several ICs below: - Texus Instruments Inc, TSB41AB3 for physical layer of IEEE 1394 bus - WaveFront semiconductor, DICE II STD ASIC for link/protocol layer - Altera MAX 3000A CPLD for programs - Analog devices, SHARC ADSP-21363 for signal processing (4 chips) This commit adds support for the two models to ALSA dice driver. Like support for the other devices, packet streaming is just available. Userspace applications should be developed if full features became available; e.g. program uploader and parameter controller. $ ./hinawa-config-rom-printer /dev/fw1 { 'bus-info': { 'adj': False, 'bmc': False, 'chip_ID': 349771402425, 'cmc': True, 'cyc_clk_acc': 255, 'generation': 1, 'imc': True, 'isc': True, 'link_spd': 2, 'max_ROM': 1, 'max_rec': 512, 'name': '1394', 'node_vendor_ID': 20674, 'pmc': False}, 'root-directory': [ ['VENDOR', 20674], ['DESCRIPTOR', 'Solid State Logic'], ['MODEL', 112], ['DESCRIPTOR', 'Duende board'], [ 'NODE_CAPABILITIES', { 'addressing': {'64': True, 'fix': True, 'prv': True}, 'misc': {'int': False, 'ms': False, 'spt': True}, 'state': { 'atn': False, 'ded': False, 'drq': True, 'elo': False, 'init': False, 'lst': True, 'off': False}, 'testing': {'bas': False, 'ext': False}}], [ 'UNIT', [ ['SPECIFIER_ID', 20674], ['VERSION', 1], ['MODEL', 112], ['DESCRIPTOR', 'Duende board']]]]} Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2019-01-28 19:40:58 +08:00
// Solid State Logic, Duende Classic and Mini.
// NOTE: each field of GUID in config ROM is not compliant to standard
// DICE scheme.
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_SSL,
.model_id = 0x000070,
},
ALSA: dice: add stream format parameters for PreSonus FireStudio FireStudio was launched by PreSonus 2009. This model consists of three ICs for its packet processing on IEEE 1394 bus: - Texus Instruments TSB41AB2 for physical layer of IEEE 1394 bus - WaveFront semiconductor, Dice II STD ASIC for link layer of IEEE 1394 bus and protocol layer - Xilinx Spartan XG3S500E FPGA for signal processing This model don't support TCAT extended application protocol. For such devices, ALSA dice driver needs to have hard-coded parameters for stream formats. This commit adds hard-coded table for this model. As a result, sampling transfer frequencies of 88.2/96.0 kHz are supported. I note that this patch can be backported to Linux kernel v4.18 and later. $ python2 crpp < /sys/bus/firewire/devices/fw1/config_rom ROM header and bus information block ----------------------------------------------------------------- 400 04042eda bus_info_length 4, crc_length 4, crc 11994 404 31333934 bus_name "1394" 408 e0ff8112 irmc 1, cmc 1, isc 1, bmc 0, pmc 0, cyc_clk_acc 255, max_rec 8 (512), max_rom 1, gen 1, spd 2 (S400) 40c 000a9204 company_id 000a92 | 410 023a8b7f device_id 04023a8b7f | EUI-64 000a9204023a8b7f root directory ----------------------------------------------------------------- 414 000661b6 directory_length 6, crc 25014 418 03000a92 vendor 41c 8100000a --> descriptor leaf at 444 420 17000008 model 424 8100000d --> descriptor leaf at 458 428 0c0087c0 node capabilities per IEEE 1394 42c d1000001 --> unit directory at 430 unit directory at 430 ----------------------------------------------------------------- 430 00041c75 directory_length 4, crc 7285 434 12000a92 specifier id 438 13000001 version 43c 17000008 model 440 8100000c --> descriptor leaf at 470 descriptor leaf at 444 ----------------------------------------------------------------- 444 00047c11 leaf_length 4, crc 31761 448 00000000 textual descriptor 44c 00000000 minimal ASCII 450 50726553 "PreS" 454 6f6e7573 "onus" descriptor leaf at 458 ----------------------------------------------------------------- 458 0005d7b3 leaf_length 5, crc 55219 45c 00000000 textual descriptor 460 00000000 minimal ASCII 464 46495245 "FIRE" 468 53545544 "STUD" 46c 494f0000 "IO" descriptor leaf at 470 ----------------------------------------------------------------- 470 0005d7b3 leaf_length 5, crc 55219 474 00000000 textual descriptor 478 00000000 minimal ASCII 47c 46495245 "FIRE" 480 53545544 "STUD" 484 494f0000 "IO" Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2019-05-17 10:56:22 +08:00
// Presonus FireStudio.
{
.match_flags = IEEE1394_MATCH_VENDOR_ID |
IEEE1394_MATCH_MODEL_ID,
.vendor_id = OUI_PRESONUS,
.model_id = 0x000008,
.driver_data = (kernel_ulong_t)snd_dice_detect_presonus_formats,
},
{
.match_flags = IEEE1394_MATCH_VERSION,
.version = DICE_INTERFACE,
},
{ }
};
MODULE_DEVICE_TABLE(ieee1394, dice_id_table);
static struct fw_driver dice_driver = {
.driver = {
.owner = THIS_MODULE,
.name = KBUILD_MODNAME,
.bus = &fw_bus_type,
},
.probe = dice_probe,
.update = dice_bus_reset,
.remove = dice_remove,
.id_table = dice_id_table,
};
static int __init alsa_dice_init(void)
{
return driver_register(&dice_driver.driver);
}
static void __exit alsa_dice_exit(void)
{
driver_unregister(&dice_driver.driver);
}
module_init(alsa_dice_init);
module_exit(alsa_dice_exit);