Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Takashi Sakamoto | 1958 | 99.95% | 19 | 95.00% |
Thomas Gleixner | 1 | 0.05% | 1 | 5.00% |
Total | 1959 | 20 |
// SPDX-License-Identifier: GPL-2.0-only // // motu-register-dsp-message-parser.c - a part of driver for MOTU FireWire series // // Copyright (c) 2021 Takashi Sakamoto <o-takashi@sakamocchi.jp> // Below models allow software to configure their DSP functions by asynchronous transaction // to access their internal registers. // * 828 mk2 // * 896hd // * Traveler // * 8 pre // * Ultralite // * 4 pre // * Audio Express // // Additionally, isochronous packets from the above models include messages to notify state of // DSP. The messages are two set of 3 byte data in 2nd and 3rd quadlet of data block. When user // operates hardware components such as dial and switch, corresponding messages are transferred. // The messages include Hardware metering and MIDI messages as well. #include "motu.h" #define MSG_FLAG_POS 4 #define MSG_FLAG_TYPE_MASK 0xf8 #define MSG_FLAG_MIDI_MASK 0x01 #define MSG_FLAG_MODEL_SPECIFIC_MASK 0x06 #define MSG_FLAG_8PRE 0x00 #define MSG_FLAG_ULTRALITE 0x04 #define MSG_FLAG_TRAVELER 0x04 #define MSG_FLAG_828MK2 0x04 #define MSG_FLAG_896HD 0x04 #define MSG_FLAG_4PRE 0x05 // MIDI mask is in 8th byte. #define MSG_FLAG_AUDIOEXPRESS 0x05 // MIDI mask is in 8th byte. #define MSG_FLAG_TYPE_SHIFT 3 #define MSG_VALUE_POS 5 #define MSG_MIDI_BYTE_POS 6 #define MSG_METER_IDX_POS 7 // In 4 pre and Audio express, meter index is in 6th byte. MIDI flag is in 8th byte and MIDI byte // is in 7th byte. #define MSG_METER_IDX_POS_4PRE_AE 6 #define MSG_MIDI_BYTE_POS_4PRE_AE 7 #define MSG_FLAG_MIDI_POS_4PRE_AE 8 enum register_dsp_msg_type { // Used for messages with no information. INVALID = 0x00, MIXER_SELECT = 0x01, MIXER_SRC_GAIN = 0x02, MIXER_SRC_PAN = 0x03, MIXER_SRC_FLAG = 0x04, MIXER_OUTPUT_PAIRED_VOLUME = 0x05, MIXER_OUTPUT_PAIRED_FLAG = 0x06, MAIN_OUTPUT_PAIRED_VOLUME = 0x07, HP_OUTPUT_PAIRED_VOLUME = 0x08, HP_OUTPUT_PAIRED_ASSIGNMENT = 0x09, // Transferred by all models but the purpose is still unknown. UNKNOWN_0 = 0x0a, // Specific to 828mk2, 896hd, Traveler. UNKNOWN_2 = 0x0c, // Specific to 828mk2, Traveler, and 896hd (not functional). LINE_INPUT_BOOST = 0x0d, // Specific to 828mk2, Traveler, and 896hd (not functional). LINE_INPUT_NOMINAL_LEVEL = 0x0e, // Specific to Ultralite, 4 pre, Audio express, and 8 pre (not functional). INPUT_GAIN_AND_INVERT = 0x15, // Specific to 4 pre, and Audio express. INPUT_FLAG = 0x16, // Specific to 4 pre, and Audio express. MIXER_SRC_PAIRED_BALANCE = 0x17, // Specific to 4 pre, and Audio express. MIXER_SRC_PAIRED_WIDTH = 0x18, // Transferred by all models. This type of message interposes the series of the other // messages. The message delivers signal level up to 96.0 kHz. In 828mk2, 896hd, and // Traveler, one of physical outputs is selected for the message. The selection is done // by LSB one byte in asynchronous write quadlet transaction to 0x'ffff'f000'0b2c. METER = 0x1f, }; #define EVENT_QUEUE_SIZE 16 struct msg_parser { spinlock_t lock; struct snd_firewire_motu_register_dsp_meter meter; bool meter_pos_quirk; struct snd_firewire_motu_register_dsp_parameter param; u8 prev_mixer_src_type; u8 mixer_ch; u8 mixer_src_ch; u8 input_ch; u8 prev_msg_type; u32 event_queue[EVENT_QUEUE_SIZE]; unsigned int push_pos; unsigned int pull_pos; }; int snd_motu_register_dsp_message_parser_new(struct snd_motu *motu) { struct msg_parser *parser; parser = devm_kzalloc(&motu->card->card_dev, sizeof(*parser), GFP_KERNEL); if (!parser) return -ENOMEM; spin_lock_init(&parser->lock); if (motu->spec == &snd_motu_spec_4pre || motu->spec == &snd_motu_spec_audio_express) parser->meter_pos_quirk = true; motu->message_parser = parser; return 0; } int snd_motu_register_dsp_message_parser_init(struct snd_motu *motu) { struct msg_parser *parser = motu->message_parser; parser->prev_mixer_src_type = INVALID; parser->mixer_ch = 0xff; parser->mixer_src_ch = 0xff; parser->prev_msg_type = INVALID; return 0; } // Rough implementaion of queue without overrun check. static void queue_event(struct snd_motu *motu, u8 msg_type, u8 identifier0, u8 identifier1, u8 val) { struct msg_parser *parser = motu->message_parser; unsigned int pos = parser->push_pos; u32 entry; if (!motu->hwdep || motu->hwdep->used == 0) return; entry = (msg_type << 24) | (identifier0 << 16) | (identifier1 << 8) | val; parser->event_queue[pos] = entry; ++pos; if (pos >= EVENT_QUEUE_SIZE) pos = 0; parser->push_pos = pos; } void snd_motu_register_dsp_message_parser_parse(const struct amdtp_stream *s, const struct pkt_desc *desc, unsigned int count) { struct snd_motu *motu = container_of(s, struct snd_motu, tx_stream); unsigned int data_block_quadlets = s->data_block_quadlets; struct msg_parser *parser = motu->message_parser; bool meter_pos_quirk = parser->meter_pos_quirk; unsigned int pos = parser->push_pos; unsigned long flags; int i; spin_lock_irqsave(&parser->lock, flags); for (i = 0; i < count; ++i) { __be32 *buffer = desc->ctx_payload; unsigned int data_blocks = desc->data_blocks; int j; desc = amdtp_stream_next_packet_desc(s, desc); for (j = 0; j < data_blocks; ++j) { u8 *b = (u8 *)buffer; u8 msg_type = (b[MSG_FLAG_POS] & MSG_FLAG_TYPE_MASK) >> MSG_FLAG_TYPE_SHIFT; u8 val = b[MSG_VALUE_POS]; buffer += data_block_quadlets; switch (msg_type) { case MIXER_SELECT: { u8 mixer_ch = val / 0x20; if (mixer_ch < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_MIXER_COUNT) { parser->mixer_src_ch = 0; parser->mixer_ch = mixer_ch; } break; } case MIXER_SRC_GAIN: case MIXER_SRC_PAN: case MIXER_SRC_FLAG: case MIXER_SRC_PAIRED_BALANCE: case MIXER_SRC_PAIRED_WIDTH: { struct snd_firewire_motu_register_dsp_parameter *param = &parser->param; u8 mixer_ch = parser->mixer_ch; u8 mixer_src_ch = parser->mixer_src_ch; if (msg_type != parser->prev_mixer_src_type) mixer_src_ch = 0; else ++mixer_src_ch; parser->prev_mixer_src_type = msg_type; if (mixer_ch < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_MIXER_COUNT && mixer_src_ch < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_MIXER_SRC_COUNT) { u8 mixer_ch = parser->mixer_ch; switch (msg_type) { case MIXER_SRC_GAIN: if (param->mixer.source[mixer_ch].gain[mixer_src_ch] != val) { queue_event(motu, msg_type, mixer_ch, mixer_src_ch, val); param->mixer.source[mixer_ch].gain[mixer_src_ch] = val; } break; case MIXER_SRC_PAN: if (param->mixer.source[mixer_ch].pan[mixer_src_ch] != val) { queue_event(motu, msg_type, mixer_ch, mixer_src_ch, val); param->mixer.source[mixer_ch].pan[mixer_src_ch] = val; } break; case MIXER_SRC_FLAG: if (param->mixer.source[mixer_ch].flag[mixer_src_ch] != val) { queue_event(motu, msg_type, mixer_ch, mixer_src_ch, val); param->mixer.source[mixer_ch].flag[mixer_src_ch] = val; } break; case MIXER_SRC_PAIRED_BALANCE: if (param->mixer.source[mixer_ch].paired_balance[mixer_src_ch] != val) { queue_event(motu, msg_type, mixer_ch, mixer_src_ch, val); param->mixer.source[mixer_ch].paired_balance[mixer_src_ch] = val; } break; case MIXER_SRC_PAIRED_WIDTH: if (param->mixer.source[mixer_ch].paired_width[mixer_src_ch] != val) { queue_event(motu, msg_type, mixer_ch, mixer_src_ch, val); param->mixer.source[mixer_ch].paired_width[mixer_src_ch] = val; } break; default: break; } parser->mixer_src_ch = mixer_src_ch; } break; } case MIXER_OUTPUT_PAIRED_VOLUME: case MIXER_OUTPUT_PAIRED_FLAG: { struct snd_firewire_motu_register_dsp_parameter *param = &parser->param; u8 mixer_ch = parser->mixer_ch; if (mixer_ch < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_MIXER_COUNT) { switch (msg_type) { case MIXER_OUTPUT_PAIRED_VOLUME: if (param->mixer.output.paired_volume[mixer_ch] != val) { queue_event(motu, msg_type, mixer_ch, 0, val); param->mixer.output.paired_volume[mixer_ch] = val; } break; case MIXER_OUTPUT_PAIRED_FLAG: if (param->mixer.output.paired_flag[mixer_ch] != val) { queue_event(motu, msg_type, mixer_ch, 0, val); param->mixer.output.paired_flag[mixer_ch] = val; } break; default: break; } } break; } case MAIN_OUTPUT_PAIRED_VOLUME: if (parser->param.output.main_paired_volume != val) { queue_event(motu, msg_type, 0, 0, val); parser->param.output.main_paired_volume = val; } break; case HP_OUTPUT_PAIRED_VOLUME: if (parser->param.output.hp_paired_volume != val) { queue_event(motu, msg_type, 0, 0, val); parser->param.output.hp_paired_volume = val; } break; case HP_OUTPUT_PAIRED_ASSIGNMENT: if (parser->param.output.hp_paired_assignment != val) { queue_event(motu, msg_type, 0, 0, val); parser->param.output.hp_paired_assignment = val; } break; case LINE_INPUT_BOOST: if (parser->param.line_input.boost_flag != val) { queue_event(motu, msg_type, 0, 0, val); parser->param.line_input.boost_flag = val; } break; case LINE_INPUT_NOMINAL_LEVEL: if (parser->param.line_input.nominal_level_flag != val) { queue_event(motu, msg_type, 0, 0, val); parser->param.line_input.nominal_level_flag = val; } break; case INPUT_GAIN_AND_INVERT: case INPUT_FLAG: { struct snd_firewire_motu_register_dsp_parameter *param = &parser->param; u8 input_ch = parser->input_ch; if (parser->prev_msg_type != msg_type) input_ch = 0; else ++input_ch; if (input_ch < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_INPUT_COUNT) { switch (msg_type) { case INPUT_GAIN_AND_INVERT: if (param->input.gain_and_invert[input_ch] != val) { queue_event(motu, msg_type, input_ch, 0, val); param->input.gain_and_invert[input_ch] = val; } break; case INPUT_FLAG: if (param->input.flag[input_ch] != val) { queue_event(motu, msg_type, input_ch, 0, val); param->input.flag[input_ch] = val; } break; default: break; } parser->input_ch = input_ch; } break; } case UNKNOWN_0: case UNKNOWN_2: break; case METER: { u8 pos; if (!meter_pos_quirk) pos = b[MSG_METER_IDX_POS]; else pos = b[MSG_METER_IDX_POS_4PRE_AE]; if (pos < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_METER_INPUT_COUNT) { parser->meter.data[pos] = val; } else if (pos >= 0x80) { pos -= (0x80 - SNDRV_FIREWIRE_MOTU_REGISTER_DSP_METER_INPUT_COUNT); if (pos < SNDRV_FIREWIRE_MOTU_REGISTER_DSP_METER_COUNT) parser->meter.data[pos] = val; } // The message for meter is interruptible to the series of other // types of messages. Don't cache it. fallthrough; } case INVALID: default: // Don't cache it. continue; } parser->prev_msg_type = msg_type; } } if (pos != parser->push_pos) wake_up(&motu->hwdep_wait); spin_unlock_irqrestore(&parser->lock, flags); } void snd_motu_register_dsp_message_parser_copy_meter(struct snd_motu *motu, struct snd_firewire_motu_register_dsp_meter *meter) { struct msg_parser *parser = motu->message_parser; unsigned long flags; spin_lock_irqsave(&parser->lock, flags); memcpy(meter, &parser->meter, sizeof(*meter)); spin_unlock_irqrestore(&parser->lock, flags); } void snd_motu_register_dsp_message_parser_copy_parameter(struct snd_motu *motu, struct snd_firewire_motu_register_dsp_parameter *param) { struct msg_parser *parser = motu->message_parser; unsigned long flags; spin_lock_irqsave(&parser->lock, flags); memcpy(param, &parser->param, sizeof(*param)); spin_unlock_irqrestore(&parser->lock, flags); } unsigned int snd_motu_register_dsp_message_parser_count_event(struct snd_motu *motu) { struct msg_parser *parser = motu->message_parser; if (parser->pull_pos > parser->push_pos) return EVENT_QUEUE_SIZE - parser->pull_pos + parser->push_pos; else return parser->push_pos - parser->pull_pos; } bool snd_motu_register_dsp_message_parser_copy_event(struct snd_motu *motu, u32 *event) { struct msg_parser *parser = motu->message_parser; unsigned int pos = parser->pull_pos; unsigned long flags; if (pos == parser->push_pos) return false; spin_lock_irqsave(&parser->lock, flags); *event = parser->event_queue[pos]; ++pos; if (pos >= EVENT_QUEUE_SIZE) pos = 0; parser->pull_pos = pos; spin_unlock_irqrestore(&parser->lock, flags); return true; }
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