linux/sound/firewire/motu/motu.h

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/*
* motu.h - a part of driver for MOTU FireWire series
*
* Copyright (c) 2015-2017 Takashi Sakamoto <o-takashi@sakamocchi.jp>
*
* Licensed under the terms of the GNU General Public License, version 2.
*/
#ifndef SOUND_FIREWIRE_MOTU_H_INCLUDED
#define SOUND_FIREWIRE_MOTU_H_INCLUDED
#include <linux/device.h>
#include <linux/firewire.h>
#include <linux/firewire-constants.h>
#include <linux/module.h>
#include <linux/mod_devicetable.h>
#include <linux/mutex.h>
#include <linux/slab.h>
#include <linux/compat.h>
#include <linux/sched/signal.h>
#include <sound/control.h>
#include <sound/core.h>
ALSA: firewire-motu: add MOTU specific protocol layer MOTU FireWire series uses blocking transmission for AMDTP packet streaming. They transmit/receive 8,000 packets per second, to handle the same number of data blocks as current sampling transmission frequency. Thus, IEC 61883-1/6 packet streaming engine of ALSA firewire stack is available for them. However, the sequence of packet and data blocks includes some quirks. Below sample is a sequence of CIP headers of packets received by 828mk2, at 44.1kHz of sampling transmission frequency. quads CIP1 CIP2 488 0x020F04E8 0x8222FFFF 8 0x020F04F8 0x8222FFFF 488 0x020F0400 0x8222FFFF 488 0x020F0408 0x8222FFFF 8 0x020F04E8 0x8222FFFF 488 0x020F04F0 0x8222FFFF 488 0x020F04F8 0x8222FFFF The SID (source node ID), DBS (data block size), SPH (source packet header), FMT (format ID), FDF (format dependent field) and SYT (time stamp) fields are in IEC 61883-1. Especially, FMT is 0x02, FDF is 0x22 and SYT is 0xffff to define MOTU specific protocol. In an aspect of dbc field, the value represents accumulated number of data blocks included the packet. This is against IEC 61883-1, because according to the specification this value should be the number of data blocks already transferred. In ALSA IEC 61883-1/6 engine, this quirk is already supported by CIP_DBC_IS_END_EVENT flag, because Echo Audio Fireworks has. Each data block includes SPH as its first quadlet field, to represent its presentation time stamp. Actual value of SPH is compliant to IEC 61883-1; lower 25 bits of 32 bits width consists of 13 bits cycle count and 12 bits cycle offset. The rest of each data block consists of 24 bit chunks. All of PCM samples, MIDI messages, status and control messages are transferred by the chunks. This is similar to '24-bit * 4 Audio Pack' in IEC 61883-6. The position of each kind of data depends on generations of each model. The number of whole chunks in a data block is a multiple of 4, to consists of quadlet-aligned packets. This commit adds data block processing layer specific for the MOTU protocol. The remarkable point is the way to generate SPH header. Time stamps for each data blocks are generated by below calculation: * Using pre-computed table for the number of ticks per event * 44,1kHz: (557 + 123/441) * 48.0kHz: (512 + 0/441) * 88.2kHz: (278 + 282/441) * 96.0kHz: (256 + 0/441) * 176.4kHz: (139 + 141/441) * 192.0kHz: (128 + 0/441) * Accumulate the ticks and set the value to SPH for every events. * This way makes sense only for blocking transmission because this mode transfers fixed number or none of events. This calculation assumes that each data block has a PCM frame which is sampled according to event timing clock. Current packet streaming layer has the same assumption. Although this sequence works fine for MOTU FireWire series at sampling transmission frequency based on 48.0kHz, it is not enough at the frequency based on 44.1kHz. The units generate choppy noise every few seconds. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:18 +08:00
#include <sound/pcm.h>
#include <sound/info.h>
#include <sound/rawmidi.h>
#include <sound/firewire.h>
#include <sound/hwdep.h>
#include "../lib.h"
ALSA: firewire-motu: add MOTU specific protocol layer MOTU FireWire series uses blocking transmission for AMDTP packet streaming. They transmit/receive 8,000 packets per second, to handle the same number of data blocks as current sampling transmission frequency. Thus, IEC 61883-1/6 packet streaming engine of ALSA firewire stack is available for them. However, the sequence of packet and data blocks includes some quirks. Below sample is a sequence of CIP headers of packets received by 828mk2, at 44.1kHz of sampling transmission frequency. quads CIP1 CIP2 488 0x020F04E8 0x8222FFFF 8 0x020F04F8 0x8222FFFF 488 0x020F0400 0x8222FFFF 488 0x020F0408 0x8222FFFF 8 0x020F04E8 0x8222FFFF 488 0x020F04F0 0x8222FFFF 488 0x020F04F8 0x8222FFFF The SID (source node ID), DBS (data block size), SPH (source packet header), FMT (format ID), FDF (format dependent field) and SYT (time stamp) fields are in IEC 61883-1. Especially, FMT is 0x02, FDF is 0x22 and SYT is 0xffff to define MOTU specific protocol. In an aspect of dbc field, the value represents accumulated number of data blocks included the packet. This is against IEC 61883-1, because according to the specification this value should be the number of data blocks already transferred. In ALSA IEC 61883-1/6 engine, this quirk is already supported by CIP_DBC_IS_END_EVENT flag, because Echo Audio Fireworks has. Each data block includes SPH as its first quadlet field, to represent its presentation time stamp. Actual value of SPH is compliant to IEC 61883-1; lower 25 bits of 32 bits width consists of 13 bits cycle count and 12 bits cycle offset. The rest of each data block consists of 24 bit chunks. All of PCM samples, MIDI messages, status and control messages are transferred by the chunks. This is similar to '24-bit * 4 Audio Pack' in IEC 61883-6. The position of each kind of data depends on generations of each model. The number of whole chunks in a data block is a multiple of 4, to consists of quadlet-aligned packets. This commit adds data block processing layer specific for the MOTU protocol. The remarkable point is the way to generate SPH header. Time stamps for each data blocks are generated by below calculation: * Using pre-computed table for the number of ticks per event * 44,1kHz: (557 + 123/441) * 48.0kHz: (512 + 0/441) * 88.2kHz: (278 + 282/441) * 96.0kHz: (256 + 0/441) * 176.4kHz: (139 + 141/441) * 192.0kHz: (128 + 0/441) * Accumulate the ticks and set the value to SPH for every events. * This way makes sense only for blocking transmission because this mode transfers fixed number or none of events. This calculation assumes that each data block has a PCM frame which is sampled according to event timing clock. Current packet streaming layer has the same assumption. Although this sequence works fine for MOTU FireWire series at sampling transmission frequency based on 48.0kHz, it is not enough at the frequency based on 44.1kHz. The units generate choppy noise every few seconds. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:18 +08:00
#include "../amdtp-stream.h"
#include "../iso-resources.h"
ALSA: firewire-motu: add an abstraction layer for three types of protocols In an aspect of used protocols to communicate, models of MOTU FireWire units are categorized to three generations. This commit adds an abstraction layer of the protocols for features related to packet streaming functionality. This layer includes 5 operations. When configuring packet streaming functionality with sampling rate and sampling transmission frequency, .get_clock_rate and .set_clock_rate are called with proper arguments. MOTU FireWire series supports up to 192.0kHz. When checking current source of sampling clock (not clock for packetization layer), .get_clock_source is used. Enumeration is added to represent the sources supported by this series. This operation can be used to expose available sampling rate to user space applications when the unit is configured to use any input signal as source of clock instead of crystal clock. In the protocols, the path between packet processing layer and digital signal processing layer can be controlled. This looks a functionality to 'mute' the unit. For this feature, .switch_fetching_mode is added. This can be used to suppress noises every time packet streaming starts/stops. In a point of the size of data blocks at a certain sampling transmission frequency, the most units accept several modes. This is due to usage of optical interfaces. The size differs depending on which modes are configured to the interfaces; None, S/PDIF and ADAT. Additionally, format of packet is different depending on protocols. To cache current size of data blocks and its format, .cache_packet_formats is added. This is used by PCM functionality, packet streaming functionality and data block processing layer. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:14 +08:00
struct snd_motu_packet_format {
unsigned char midi_flag_offset;
unsigned char midi_byte_offset;
ALSA: firewire-motu: add an abstraction layer for three types of protocols In an aspect of used protocols to communicate, models of MOTU FireWire units are categorized to three generations. This commit adds an abstraction layer of the protocols for features related to packet streaming functionality. This layer includes 5 operations. When configuring packet streaming functionality with sampling rate and sampling transmission frequency, .get_clock_rate and .set_clock_rate are called with proper arguments. MOTU FireWire series supports up to 192.0kHz. When checking current source of sampling clock (not clock for packetization layer), .get_clock_source is used. Enumeration is added to represent the sources supported by this series. This operation can be used to expose available sampling rate to user space applications when the unit is configured to use any input signal as source of clock instead of crystal clock. In the protocols, the path between packet processing layer and digital signal processing layer can be controlled. This looks a functionality to 'mute' the unit. For this feature, .switch_fetching_mode is added. This can be used to suppress noises every time packet streaming starts/stops. In a point of the size of data blocks at a certain sampling transmission frequency, the most units accept several modes. This is due to usage of optical interfaces. The size differs depending on which modes are configured to the interfaces; None, S/PDIF and ADAT. Additionally, format of packet is different depending on protocols. To cache current size of data blocks and its format, .cache_packet_formats is added. This is used by PCM functionality, packet streaming functionality and data block processing layer. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:14 +08:00
unsigned char pcm_byte_offset;
unsigned char msg_chunks;
unsigned char fixed_part_pcm_chunks[3];
unsigned char differed_part_pcm_chunks[3];
};
struct snd_motu {
struct snd_card *card;
struct fw_unit *unit;
struct mutex mutex;
spinlock_t lock;
bool registered;
struct delayed_work dwork;
/* Model dependent information. */
const struct snd_motu_spec *spec;
ALSA: firewire-motu: add an abstraction layer for three types of protocols In an aspect of used protocols to communicate, models of MOTU FireWire units are categorized to three generations. This commit adds an abstraction layer of the protocols for features related to packet streaming functionality. This layer includes 5 operations. When configuring packet streaming functionality with sampling rate and sampling transmission frequency, .get_clock_rate and .set_clock_rate are called with proper arguments. MOTU FireWire series supports up to 192.0kHz. When checking current source of sampling clock (not clock for packetization layer), .get_clock_source is used. Enumeration is added to represent the sources supported by this series. This operation can be used to expose available sampling rate to user space applications when the unit is configured to use any input signal as source of clock instead of crystal clock. In the protocols, the path between packet processing layer and digital signal processing layer can be controlled. This looks a functionality to 'mute' the unit. For this feature, .switch_fetching_mode is added. This can be used to suppress noises every time packet streaming starts/stops. In a point of the size of data blocks at a certain sampling transmission frequency, the most units accept several modes. This is due to usage of optical interfaces. The size differs depending on which modes are configured to the interfaces; None, S/PDIF and ADAT. Additionally, format of packet is different depending on protocols. To cache current size of data blocks and its format, .cache_packet_formats is added. This is used by PCM functionality, packet streaming functionality and data block processing layer. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:14 +08:00
/* For packet streaming */
struct snd_motu_packet_format tx_packet_formats;
struct snd_motu_packet_format rx_packet_formats;
ALSA: firewire-motu: add MOTU specific protocol layer MOTU FireWire series uses blocking transmission for AMDTP packet streaming. They transmit/receive 8,000 packets per second, to handle the same number of data blocks as current sampling transmission frequency. Thus, IEC 61883-1/6 packet streaming engine of ALSA firewire stack is available for them. However, the sequence of packet and data blocks includes some quirks. Below sample is a sequence of CIP headers of packets received by 828mk2, at 44.1kHz of sampling transmission frequency. quads CIP1 CIP2 488 0x020F04E8 0x8222FFFF 8 0x020F04F8 0x8222FFFF 488 0x020F0400 0x8222FFFF 488 0x020F0408 0x8222FFFF 8 0x020F04E8 0x8222FFFF 488 0x020F04F0 0x8222FFFF 488 0x020F04F8 0x8222FFFF The SID (source node ID), DBS (data block size), SPH (source packet header), FMT (format ID), FDF (format dependent field) and SYT (time stamp) fields are in IEC 61883-1. Especially, FMT is 0x02, FDF is 0x22 and SYT is 0xffff to define MOTU specific protocol. In an aspect of dbc field, the value represents accumulated number of data blocks included the packet. This is against IEC 61883-1, because according to the specification this value should be the number of data blocks already transferred. In ALSA IEC 61883-1/6 engine, this quirk is already supported by CIP_DBC_IS_END_EVENT flag, because Echo Audio Fireworks has. Each data block includes SPH as its first quadlet field, to represent its presentation time stamp. Actual value of SPH is compliant to IEC 61883-1; lower 25 bits of 32 bits width consists of 13 bits cycle count and 12 bits cycle offset. The rest of each data block consists of 24 bit chunks. All of PCM samples, MIDI messages, status and control messages are transferred by the chunks. This is similar to '24-bit * 4 Audio Pack' in IEC 61883-6. The position of each kind of data depends on generations of each model. The number of whole chunks in a data block is a multiple of 4, to consists of quadlet-aligned packets. This commit adds data block processing layer specific for the MOTU protocol. The remarkable point is the way to generate SPH header. Time stamps for each data blocks are generated by below calculation: * Using pre-computed table for the number of ticks per event * 44,1kHz: (557 + 123/441) * 48.0kHz: (512 + 0/441) * 88.2kHz: (278 + 282/441) * 96.0kHz: (256 + 0/441) * 176.4kHz: (139 + 141/441) * 192.0kHz: (128 + 0/441) * Accumulate the ticks and set the value to SPH for every events. * This way makes sense only for blocking transmission because this mode transfers fixed number or none of events. This calculation assumes that each data block has a PCM frame which is sampled according to event timing clock. Current packet streaming layer has the same assumption. Although this sequence works fine for MOTU FireWire series at sampling transmission frequency based on 48.0kHz, it is not enough at the frequency based on 44.1kHz. The units generate choppy noise every few seconds. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:18 +08:00
struct amdtp_stream tx_stream;
struct amdtp_stream rx_stream;
struct fw_iso_resources tx_resources;
struct fw_iso_resources rx_resources;
unsigned int capture_substreams;
unsigned int playback_substreams;
/* For notification. */
struct fw_address_handler async_handler;
u32 msg;
/* For uapi */
int dev_lock_count;
bool dev_lock_changed;
wait_queue_head_t hwdep_wait;
};
enum snd_motu_spec_flags {
SND_MOTU_SPEC_SUPPORT_CLOCK_X2 = 0x0001,
SND_MOTU_SPEC_SUPPORT_CLOCK_X4 = 0x0002,
SND_MOTU_SPEC_TX_MICINST_CHUNK = 0x0004,
SND_MOTU_SPEC_TX_RETURN_CHUNK = 0x0008,
SND_MOTU_SPEC_TX_REVERB_CHUNK = 0x0010,
SND_MOTU_SPEC_TX_AESEBU_CHUNK = 0x0020,
SND_MOTU_SPEC_HAS_OPT_IFACE_A = 0x0040,
SND_MOTU_SPEC_HAS_OPT_IFACE_B = 0x0080,
SND_MOTU_SPEC_RX_MIDI_2ND_Q = 0x0100,
SND_MOTU_SPEC_RX_MIDI_3RD_Q = 0x0200,
SND_MOTU_SPEC_TX_MIDI_2ND_Q = 0x0400,
SND_MOTU_SPEC_TX_MIDI_3RD_Q = 0x0800,
};
ALSA: firewire-motu: add an abstraction layer for three types of protocols In an aspect of used protocols to communicate, models of MOTU FireWire units are categorized to three generations. This commit adds an abstraction layer of the protocols for features related to packet streaming functionality. This layer includes 5 operations. When configuring packet streaming functionality with sampling rate and sampling transmission frequency, .get_clock_rate and .set_clock_rate are called with proper arguments. MOTU FireWire series supports up to 192.0kHz. When checking current source of sampling clock (not clock for packetization layer), .get_clock_source is used. Enumeration is added to represent the sources supported by this series. This operation can be used to expose available sampling rate to user space applications when the unit is configured to use any input signal as source of clock instead of crystal clock. In the protocols, the path between packet processing layer and digital signal processing layer can be controlled. This looks a functionality to 'mute' the unit. For this feature, .switch_fetching_mode is added. This can be used to suppress noises every time packet streaming starts/stops. In a point of the size of data blocks at a certain sampling transmission frequency, the most units accept several modes. This is due to usage of optical interfaces. The size differs depending on which modes are configured to the interfaces; None, S/PDIF and ADAT. Additionally, format of packet is different depending on protocols. To cache current size of data blocks and its format, .cache_packet_formats is added. This is used by PCM functionality, packet streaming functionality and data block processing layer. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:14 +08:00
#define SND_MOTU_CLOCK_RATE_COUNT 6
extern const unsigned int snd_motu_clock_rates[SND_MOTU_CLOCK_RATE_COUNT];
enum snd_motu_clock_source {
SND_MOTU_CLOCK_SOURCE_INTERNAL,
SND_MOTU_CLOCK_SOURCE_ADAT_ON_DSUB,
SND_MOTU_CLOCK_SOURCE_ADAT_ON_OPT,
SND_MOTU_CLOCK_SOURCE_ADAT_ON_OPT_A,
SND_MOTU_CLOCK_SOURCE_ADAT_ON_OPT_B,
SND_MOTU_CLOCK_SOURCE_SPDIF_ON_OPT,
SND_MOTU_CLOCK_SOURCE_SPDIF_ON_OPT_A,
SND_MOTU_CLOCK_SOURCE_SPDIF_ON_OPT_B,
SND_MOTU_CLOCK_SOURCE_SPDIF_ON_COAX,
SND_MOTU_CLOCK_SOURCE_AESEBU_ON_XLR,
SND_MOTU_CLOCK_SOURCE_WORD_ON_BNC,
SND_MOTU_CLOCK_SOURCE_UNKNOWN,
};
struct snd_motu_protocol {
int (*get_clock_rate)(struct snd_motu *motu, unsigned int *rate);
int (*set_clock_rate)(struct snd_motu *motu, unsigned int rate);
int (*get_clock_source)(struct snd_motu *motu,
enum snd_motu_clock_source *source);
int (*switch_fetching_mode)(struct snd_motu *motu, bool enable);
int (*cache_packet_formats)(struct snd_motu *motu);
};
struct snd_motu_spec {
const char *const name;
enum snd_motu_spec_flags flags;
unsigned char analog_in_ports;
unsigned char analog_out_ports;
ALSA: firewire-motu: add an abstraction layer for three types of protocols In an aspect of used protocols to communicate, models of MOTU FireWire units are categorized to three generations. This commit adds an abstraction layer of the protocols for features related to packet streaming functionality. This layer includes 5 operations. When configuring packet streaming functionality with sampling rate and sampling transmission frequency, .get_clock_rate and .set_clock_rate are called with proper arguments. MOTU FireWire series supports up to 192.0kHz. When checking current source of sampling clock (not clock for packetization layer), .get_clock_source is used. Enumeration is added to represent the sources supported by this series. This operation can be used to expose available sampling rate to user space applications when the unit is configured to use any input signal as source of clock instead of crystal clock. In the protocols, the path between packet processing layer and digital signal processing layer can be controlled. This looks a functionality to 'mute' the unit. For this feature, .switch_fetching_mode is added. This can be used to suppress noises every time packet streaming starts/stops. In a point of the size of data blocks at a certain sampling transmission frequency, the most units accept several modes. This is due to usage of optical interfaces. The size differs depending on which modes are configured to the interfaces; None, S/PDIF and ADAT. Additionally, format of packet is different depending on protocols. To cache current size of data blocks and its format, .cache_packet_formats is added. This is used by PCM functionality, packet streaming functionality and data block processing layer. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:14 +08:00
const struct snd_motu_protocol *const protocol;
};
extern const struct snd_motu_protocol snd_motu_protocol_v2;
ALSA: firewire-motu: add support for MOTU 828mk3 (FireWire/Hybrid) as a model with protocol version 3 MOTU 828mk3 (FireWire/Hybrid) is one of third generation in MOTU FireWire series, produced in 2008/2014. This model consists of three chips for functionality on IEEE 1394 bus: * TI TSB41AB2 (Physical layer for IEEE 1394 bus) * Xilinx Spartan-3E FPGA Family (Link layer for IEEE 1394 bus, packet processing and data block processing layer) * TI TMS320C6722 (Digital signal processing) This commit adds a support for this model, with its unique protocol as version 3. This protocol has some additional features to protocol version 2. * Support several optical interfaces. * Support a data chunk for return of reverb effect. * Have a quirk of tx packets. * Support heartbeat asynchronous transaction. In this protocol, series of transferred packets has some quirks. Below fields in CIP headers of the packets are out of IEC 61883-1: - SID (source node id): always 0x0d - DBS (data block size): always 0x04 - DBC (data block counter): always 0x00 - EOH (End of header): always 0x00 Below is an actual sample of transferred packets. quads CIP1 CIP2 520 0x0D040400 0x22FFFFFF 8 0x0D040400 0x22FFFFFF 520 0x0D040400 0x22FFFFFF 520 0x0D040400 0x22FFFFFF 8 0x0D040400 0x22FFFFFF Status of clock is configured by write transactions to 0x'ffff'f000'0b14, as well as version 2, while meanings of fields are different from the former protocols. Modes of optical interfaces are configured by write transactions to 0x'ffff'f000'0c94. Drivers can register its address to receive heatbeat transactions from the unit. 0x'ffff'f000'0b0c is for the higher part and 0x'ffff'f000'0b10 is for the lower part. Nevertheless, this feature is not useless for this driver and this commit omits it. Each data block consists of two parts in a point of the number of included data chunks. In both of 'fixed' and 'differed' parts, the number of included data blocks are a multiple of 4, thus depending on models there's some empty data chunks. For example, 828mk3 includes one pair of empty data chunks in its fixed part. When optical interface is configured to S/PDIF, 828mk3 includes one pair of empty data chunks in its differed part. To reduce consumption of CPU cycles with additional conditions/loops, this commit just exposes these empty chunks to user space as PCM channels. Additionally, 828mk3 has a non-negligible overhead to change its sampling transfer frequency. When softwares send asynchronous transaction to perform it, LED on the unit starts to blink. In a worst case, it continues blink during several seconds; e.g. 10 seconds. When stopping blinking, the unit seems to be prepared for the requested sampling transfer frequency. To wait for the preparation, this commit forces the driver to call task scheduler and applications sleeps for 4 seconds. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:28 +08:00
extern const struct snd_motu_protocol snd_motu_protocol_v3;
ALSA: firewire-motu: add MOTU specific protocol layer MOTU FireWire series uses blocking transmission for AMDTP packet streaming. They transmit/receive 8,000 packets per second, to handle the same number of data blocks as current sampling transmission frequency. Thus, IEC 61883-1/6 packet streaming engine of ALSA firewire stack is available for them. However, the sequence of packet and data blocks includes some quirks. Below sample is a sequence of CIP headers of packets received by 828mk2, at 44.1kHz of sampling transmission frequency. quads CIP1 CIP2 488 0x020F04E8 0x8222FFFF 8 0x020F04F8 0x8222FFFF 488 0x020F0400 0x8222FFFF 488 0x020F0408 0x8222FFFF 8 0x020F04E8 0x8222FFFF 488 0x020F04F0 0x8222FFFF 488 0x020F04F8 0x8222FFFF The SID (source node ID), DBS (data block size), SPH (source packet header), FMT (format ID), FDF (format dependent field) and SYT (time stamp) fields are in IEC 61883-1. Especially, FMT is 0x02, FDF is 0x22 and SYT is 0xffff to define MOTU specific protocol. In an aspect of dbc field, the value represents accumulated number of data blocks included the packet. This is against IEC 61883-1, because according to the specification this value should be the number of data blocks already transferred. In ALSA IEC 61883-1/6 engine, this quirk is already supported by CIP_DBC_IS_END_EVENT flag, because Echo Audio Fireworks has. Each data block includes SPH as its first quadlet field, to represent its presentation time stamp. Actual value of SPH is compliant to IEC 61883-1; lower 25 bits of 32 bits width consists of 13 bits cycle count and 12 bits cycle offset. The rest of each data block consists of 24 bit chunks. All of PCM samples, MIDI messages, status and control messages are transferred by the chunks. This is similar to '24-bit * 4 Audio Pack' in IEC 61883-6. The position of each kind of data depends on generations of each model. The number of whole chunks in a data block is a multiple of 4, to consists of quadlet-aligned packets. This commit adds data block processing layer specific for the MOTU protocol. The remarkable point is the way to generate SPH header. Time stamps for each data blocks are generated by below calculation: * Using pre-computed table for the number of ticks per event * 44,1kHz: (557 + 123/441) * 48.0kHz: (512 + 0/441) * 88.2kHz: (278 + 282/441) * 96.0kHz: (256 + 0/441) * 176.4kHz: (139 + 141/441) * 192.0kHz: (128 + 0/441) * Accumulate the ticks and set the value to SPH for every events. * This way makes sense only for blocking transmission because this mode transfers fixed number or none of events. This calculation assumes that each data block has a PCM frame which is sampled according to event timing clock. Current packet streaming layer has the same assumption. Although this sequence works fine for MOTU FireWire series at sampling transmission frequency based on 48.0kHz, it is not enough at the frequency based on 44.1kHz. The units generate choppy noise every few seconds. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:18 +08:00
int amdtp_motu_init(struct amdtp_stream *s, struct fw_unit *unit,
enum amdtp_stream_direction dir,
const struct snd_motu_protocol *const protocol);
int amdtp_motu_set_parameters(struct amdtp_stream *s, unsigned int rate,
unsigned int midi_ports,
ALSA: firewire-motu: add MOTU specific protocol layer MOTU FireWire series uses blocking transmission for AMDTP packet streaming. They transmit/receive 8,000 packets per second, to handle the same number of data blocks as current sampling transmission frequency. Thus, IEC 61883-1/6 packet streaming engine of ALSA firewire stack is available for them. However, the sequence of packet and data blocks includes some quirks. Below sample is a sequence of CIP headers of packets received by 828mk2, at 44.1kHz of sampling transmission frequency. quads CIP1 CIP2 488 0x020F04E8 0x8222FFFF 8 0x020F04F8 0x8222FFFF 488 0x020F0400 0x8222FFFF 488 0x020F0408 0x8222FFFF 8 0x020F04E8 0x8222FFFF 488 0x020F04F0 0x8222FFFF 488 0x020F04F8 0x8222FFFF The SID (source node ID), DBS (data block size), SPH (source packet header), FMT (format ID), FDF (format dependent field) and SYT (time stamp) fields are in IEC 61883-1. Especially, FMT is 0x02, FDF is 0x22 and SYT is 0xffff to define MOTU specific protocol. In an aspect of dbc field, the value represents accumulated number of data blocks included the packet. This is against IEC 61883-1, because according to the specification this value should be the number of data blocks already transferred. In ALSA IEC 61883-1/6 engine, this quirk is already supported by CIP_DBC_IS_END_EVENT flag, because Echo Audio Fireworks has. Each data block includes SPH as its first quadlet field, to represent its presentation time stamp. Actual value of SPH is compliant to IEC 61883-1; lower 25 bits of 32 bits width consists of 13 bits cycle count and 12 bits cycle offset. The rest of each data block consists of 24 bit chunks. All of PCM samples, MIDI messages, status and control messages are transferred by the chunks. This is similar to '24-bit * 4 Audio Pack' in IEC 61883-6. The position of each kind of data depends on generations of each model. The number of whole chunks in a data block is a multiple of 4, to consists of quadlet-aligned packets. This commit adds data block processing layer specific for the MOTU protocol. The remarkable point is the way to generate SPH header. Time stamps for each data blocks are generated by below calculation: * Using pre-computed table for the number of ticks per event * 44,1kHz: (557 + 123/441) * 48.0kHz: (512 + 0/441) * 88.2kHz: (278 + 282/441) * 96.0kHz: (256 + 0/441) * 176.4kHz: (139 + 141/441) * 192.0kHz: (128 + 0/441) * Accumulate the ticks and set the value to SPH for every events. * This way makes sense only for blocking transmission because this mode transfers fixed number or none of events. This calculation assumes that each data block has a PCM frame which is sampled according to event timing clock. Current packet streaming layer has the same assumption. Although this sequence works fine for MOTU FireWire series at sampling transmission frequency based on 48.0kHz, it is not enough at the frequency based on 44.1kHz. The units generate choppy noise every few seconds. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
2017-03-22 20:30:18 +08:00
struct snd_motu_packet_format *formats);
int amdtp_motu_add_pcm_hw_constraints(struct amdtp_stream *s,
struct snd_pcm_runtime *runtime);
void amdtp_motu_midi_trigger(struct amdtp_stream *s, unsigned int port,
struct snd_rawmidi_substream *midi);
int snd_motu_transaction_read(struct snd_motu *motu, u32 offset, __be32 *reg,
size_t size);
int snd_motu_transaction_write(struct snd_motu *motu, u32 offset, __be32 *reg,
size_t size);
int snd_motu_transaction_register(struct snd_motu *motu);
int snd_motu_transaction_reregister(struct snd_motu *motu);
void snd_motu_transaction_unregister(struct snd_motu *motu);
int snd_motu_stream_init_duplex(struct snd_motu *motu);
void snd_motu_stream_destroy_duplex(struct snd_motu *motu);
int snd_motu_stream_cache_packet_formats(struct snd_motu *motu);
int snd_motu_stream_start_duplex(struct snd_motu *motu, unsigned int rate);
void snd_motu_stream_stop_duplex(struct snd_motu *motu);
int snd_motu_stream_lock_try(struct snd_motu *motu);
void snd_motu_stream_lock_release(struct snd_motu *motu);
void snd_motu_proc_init(struct snd_motu *motu);
int snd_motu_create_pcm_devices(struct snd_motu *motu);
int snd_motu_create_midi_devices(struct snd_motu *motu);
int snd_motu_create_hwdep_device(struct snd_motu *motu);
#endif