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https://github.com/AuxXxilium/linux_dsm_epyc7002.git
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9dc5d31cdc
In Digi 002/003 protocol, MIDI messages are transferred in the last data channel of data blocks. Although this data channel has a label of 0x80, it's not fully MIDI conformant data channel especially because the Counter field always zero independently of included MIDI bytes. The 4th byte of the data channel in LSB tells the number of included MIDI bytes. This byte also includes the number of MIDI port. Therefore, the data format in this data channel is: * 1st: 0x80 as label * 2nd: MIDI bytes * 3rd: 0 or MIDI bytes * 4th: the number of MIDI byte and the number of MIDI port This commit adds support of MIDI messages in data block processing layer. Like AM824 data format, this data channel has a capability to transfer more MIDI messages than the capability of phisical MIDI bus. Therefore, a throttle for data rate is required to prevent devices' internal buffer to overflow. Signed-off-by: Takashi Sakamoto <o-takashi@sakamocchi.jp> Signed-off-by: Takashi Iwai <tiwai@suse.de>
443 lines
11 KiB
C
443 lines
11 KiB
C
/*
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* amdtp-dot.c - a part of driver for Digidesign Digi 002/003 family
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*
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* Copyright (c) 2014-2015 Takashi Sakamoto
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* Copyright (C) 2012 Robin Gareus <robin@gareus.org>
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* Copyright (C) 2012 Damien Zammit <damien@zamaudio.com>
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*
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* Licensed under the terms of the GNU General Public License, version 2.
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*/
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#include <sound/pcm.h>
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#include "digi00x.h"
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#define CIP_FMT_AM 0x10
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/* 'Clock-based rate control mode' is just supported. */
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#define AMDTP_FDF_AM824 0x00
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/*
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* Nominally 3125 bytes/second, but the MIDI port's clock might be
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* 1% too slow, and the bus clock 100 ppm too fast.
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*/
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#define MIDI_BYTES_PER_SECOND 3093
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/*
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* Several devices look only at the first eight data blocks.
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* In any case, this is more than enough for the MIDI data rate.
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*/
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#define MAX_MIDI_RX_BLOCKS 8
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/*
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* The double-oh-three algorithm was discovered by Robin Gareus and Damien
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* Zammit in 2012, with reverse-engineering for Digi 003 Rack.
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*/
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struct dot_state {
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u8 carry;
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u8 idx;
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unsigned int off;
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};
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struct amdtp_dot {
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unsigned int pcm_channels;
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struct dot_state state;
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unsigned int midi_ports;
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/* 2 = MAX(DOT_MIDI_IN_PORTS, DOT_MIDI_OUT_PORTS) */
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struct snd_rawmidi_substream *midi[2];
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int midi_fifo_used[2];
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int midi_fifo_limit;
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void (*transfer_samples)(struct amdtp_stream *s,
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struct snd_pcm_substream *pcm,
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__be32 *buffer, unsigned int frames);
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};
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/*
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* double-oh-three look up table
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*
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* @param idx index byte (audio-sample data) 0x00..0xff
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* @param off channel offset shift
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* @return salt to XOR with given data
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*/
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#define BYTE_PER_SAMPLE (4)
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#define MAGIC_DOT_BYTE (2)
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#define MAGIC_BYTE_OFF(x) (((x) * BYTE_PER_SAMPLE) + MAGIC_DOT_BYTE)
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static const u8 dot_scrt(const u8 idx, const unsigned int off)
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{
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/*
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* the length of the added pattern only depends on the lower nibble
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* of the last non-zero data
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*/
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static const u8 len[16] = {0, 1, 3, 5, 7, 9, 11, 13, 14,
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12, 10, 8, 6, 4, 2, 0};
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/*
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* the lower nibble of the salt. Interleaved sequence.
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* this is walked backwards according to len[]
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*/
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static const u8 nib[15] = {0x8, 0x7, 0x9, 0x6, 0xa, 0x5, 0xb, 0x4,
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0xc, 0x3, 0xd, 0x2, 0xe, 0x1, 0xf};
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/* circular list for the salt's hi nibble. */
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static const u8 hir[15] = {0x0, 0x6, 0xf, 0x8, 0x7, 0x5, 0x3, 0x4,
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0xc, 0xd, 0xe, 0x1, 0x2, 0xb, 0xa};
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/*
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* start offset for upper nibble mapping.
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* note: 9 is /special/. In the case where the high nibble == 0x9,
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* hir[] is not used and - coincidentally - the salt's hi nibble is
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* 0x09 regardless of the offset.
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*/
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static const u8 hio[16] = {0, 11, 12, 6, 7, 5, 1, 4,
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3, 0x00, 14, 13, 8, 9, 10, 2};
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const u8 ln = idx & 0xf;
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const u8 hn = (idx >> 4) & 0xf;
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const u8 hr = (hn == 0x9) ? 0x9 : hir[(hio[hn] + off) % 15];
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if (len[ln] < off)
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return 0x00;
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return ((nib[14 + off - len[ln]]) | (hr << 4));
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}
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static void dot_encode_step(struct dot_state *state, __be32 *const buffer)
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{
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u8 * const data = (u8 *) buffer;
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if (data[MAGIC_DOT_BYTE] != 0x00) {
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state->off = 0;
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state->idx = data[MAGIC_DOT_BYTE] ^ state->carry;
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}
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data[MAGIC_DOT_BYTE] ^= state->carry;
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state->carry = dot_scrt(state->idx, ++(state->off));
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}
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int amdtp_dot_set_parameters(struct amdtp_stream *s, unsigned int rate,
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unsigned int pcm_channels)
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{
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struct amdtp_dot *p = s->protocol;
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int err;
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if (amdtp_stream_running(s))
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return -EBUSY;
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/*
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* A first data channel is for MIDI conformant data channel, the rest is
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* Multi Bit Linear Audio data channel.
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*/
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err = amdtp_stream_set_parameters(s, rate, pcm_channels + 1);
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if (err < 0)
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return err;
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s->fdf = AMDTP_FDF_AM824 | s->sfc;
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p->pcm_channels = pcm_channels;
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if (s->direction == AMDTP_IN_STREAM)
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p->midi_ports = DOT_MIDI_IN_PORTS;
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else
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p->midi_ports = DOT_MIDI_OUT_PORTS;
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/*
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* We do not know the actual MIDI FIFO size of most devices. Just
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* assume two bytes, i.e., one byte can be received over the bus while
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* the previous one is transmitted over MIDI.
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* (The value here is adjusted for midi_ratelimit_per_packet().)
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*/
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p->midi_fifo_limit = rate - MIDI_BYTES_PER_SECOND * s->syt_interval + 1;
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return 0;
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}
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static void write_pcm_s32(struct amdtp_stream *s, struct snd_pcm_substream *pcm,
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__be32 *buffer, unsigned int frames)
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{
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struct amdtp_dot *p = s->protocol;
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struct snd_pcm_runtime *runtime = pcm->runtime;
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unsigned int channels, remaining_frames, i, c;
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const u32 *src;
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channels = p->pcm_channels;
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src = (void *)runtime->dma_area +
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frames_to_bytes(runtime, s->pcm_buffer_pointer);
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remaining_frames = runtime->buffer_size - s->pcm_buffer_pointer;
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buffer++;
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for (i = 0; i < frames; ++i) {
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for (c = 0; c < channels; ++c) {
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buffer[c] = cpu_to_be32((*src >> 8) | 0x40000000);
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dot_encode_step(&p->state, &buffer[c]);
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src++;
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}
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buffer += s->data_block_quadlets;
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if (--remaining_frames == 0)
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src = (void *)runtime->dma_area;
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}
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}
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static void write_pcm_s16(struct amdtp_stream *s, struct snd_pcm_substream *pcm,
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__be32 *buffer, unsigned int frames)
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{
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struct amdtp_dot *p = s->protocol;
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struct snd_pcm_runtime *runtime = pcm->runtime;
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unsigned int channels, remaining_frames, i, c;
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const u16 *src;
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channels = p->pcm_channels;
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src = (void *)runtime->dma_area +
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frames_to_bytes(runtime, s->pcm_buffer_pointer);
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remaining_frames = runtime->buffer_size - s->pcm_buffer_pointer;
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buffer++;
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for (i = 0; i < frames; ++i) {
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for (c = 0; c < channels; ++c) {
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buffer[c] = cpu_to_be32((*src << 8) | 0x40000000);
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dot_encode_step(&p->state, &buffer[c]);
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src++;
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}
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buffer += s->data_block_quadlets;
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if (--remaining_frames == 0)
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src = (void *)runtime->dma_area;
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}
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}
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static void read_pcm_s32(struct amdtp_stream *s, struct snd_pcm_substream *pcm,
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__be32 *buffer, unsigned int frames)
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{
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struct amdtp_dot *p = s->protocol;
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struct snd_pcm_runtime *runtime = pcm->runtime;
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unsigned int channels, remaining_frames, i, c;
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u32 *dst;
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channels = p->pcm_channels;
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dst = (void *)runtime->dma_area +
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frames_to_bytes(runtime, s->pcm_buffer_pointer);
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remaining_frames = runtime->buffer_size - s->pcm_buffer_pointer;
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buffer++;
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for (i = 0; i < frames; ++i) {
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for (c = 0; c < channels; ++c) {
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*dst = be32_to_cpu(buffer[c]) << 8;
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dst++;
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}
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buffer += s->data_block_quadlets;
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if (--remaining_frames == 0)
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dst = (void *)runtime->dma_area;
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}
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}
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static void write_pcm_silence(struct amdtp_stream *s, __be32 *buffer,
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unsigned int data_blocks)
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{
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struct amdtp_dot *p = s->protocol;
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unsigned int channels, i, c;
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channels = p->pcm_channels;
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buffer++;
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for (i = 0; i < data_blocks; ++i) {
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for (c = 0; c < channels; ++c)
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buffer[c] = cpu_to_be32(0x40000000);
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buffer += s->data_block_quadlets;
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}
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}
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static bool midi_ratelimit_per_packet(struct amdtp_stream *s, unsigned int port)
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{
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struct amdtp_dot *p = s->protocol;
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int used;
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used = p->midi_fifo_used[port];
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if (used == 0)
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return true;
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used -= MIDI_BYTES_PER_SECOND * s->syt_interval;
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used = max(used, 0);
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p->midi_fifo_used[port] = used;
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return used < p->midi_fifo_limit;
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}
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static inline void midi_use_bytes(struct amdtp_stream *s,
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unsigned int port, unsigned int count)
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{
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struct amdtp_dot *p = s->protocol;
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p->midi_fifo_used[port] += amdtp_rate_table[s->sfc] * count;
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}
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static void write_midi_messages(struct amdtp_stream *s, __be32 *buffer,
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unsigned int data_blocks)
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{
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struct amdtp_dot *p = s->protocol;
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unsigned int f, port;
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int len;
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u8 *b;
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for (f = 0; f < data_blocks; f++) {
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port = (s->data_block_counter + f) % 8;
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b = (u8 *)&buffer[0];
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len = 0;
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if (port < p->midi_ports &&
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midi_ratelimit_per_packet(s, port) &&
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p->midi[port] != NULL)
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len = snd_rawmidi_transmit(p->midi[port], b + 1, 2);
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if (len > 0) {
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b[3] = (0x10 << port) | len;
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midi_use_bytes(s, port, len);
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} else {
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b[1] = 0;
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b[2] = 0;
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b[3] = 0;
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}
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b[0] = 0x80;
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buffer += s->data_block_quadlets;
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}
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}
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static void read_midi_messages(struct amdtp_stream *s, __be32 *buffer,
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unsigned int data_blocks)
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{
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struct amdtp_dot *p = s->protocol;
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unsigned int f, port, len;
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u8 *b;
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for (f = 0; f < data_blocks; f++) {
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b = (u8 *)&buffer[0];
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port = b[3] >> 4;
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len = b[3] & 0x0f;
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if (port < p->midi_ports && p->midi[port] && len > 0)
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snd_rawmidi_receive(p->midi[port], b + 1, len);
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buffer += s->data_block_quadlets;
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}
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}
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int amdtp_dot_add_pcm_hw_constraints(struct amdtp_stream *s,
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struct snd_pcm_runtime *runtime)
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{
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int err;
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/* This protocol delivers 24 bit data in 32bit data channel. */
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err = snd_pcm_hw_constraint_msbits(runtime, 0, 32, 24);
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if (err < 0)
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return err;
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return amdtp_stream_add_pcm_hw_constraints(s, runtime);
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}
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void amdtp_dot_set_pcm_format(struct amdtp_stream *s, snd_pcm_format_t format)
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{
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struct amdtp_dot *p = s->protocol;
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if (WARN_ON(amdtp_stream_pcm_running(s)))
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return;
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switch (format) {
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default:
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WARN_ON(1);
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/* fall through */
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case SNDRV_PCM_FORMAT_S16:
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if (s->direction == AMDTP_OUT_STREAM) {
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p->transfer_samples = write_pcm_s16;
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break;
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}
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WARN_ON(1);
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/* fall through */
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case SNDRV_PCM_FORMAT_S32:
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if (s->direction == AMDTP_OUT_STREAM)
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p->transfer_samples = write_pcm_s32;
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else
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p->transfer_samples = read_pcm_s32;
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break;
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}
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}
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void amdtp_dot_midi_trigger(struct amdtp_stream *s, unsigned int port,
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struct snd_rawmidi_substream *midi)
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{
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struct amdtp_dot *p = s->protocol;
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if (port < p->midi_ports)
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ACCESS_ONCE(p->midi[port]) = midi;
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}
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static unsigned int process_tx_data_blocks(struct amdtp_stream *s,
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__be32 *buffer,
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unsigned int data_blocks,
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unsigned int *syt)
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{
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struct amdtp_dot *p = (struct amdtp_dot *)s->protocol;
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struct snd_pcm_substream *pcm;
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unsigned int pcm_frames;
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pcm = ACCESS_ONCE(s->pcm);
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if (pcm) {
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p->transfer_samples(s, pcm, buffer, data_blocks);
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pcm_frames = data_blocks;
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} else {
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pcm_frames = 0;
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}
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read_midi_messages(s, buffer, data_blocks);
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return pcm_frames;
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}
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static unsigned int process_rx_data_blocks(struct amdtp_stream *s,
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__be32 *buffer,
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unsigned int data_blocks,
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unsigned int *syt)
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{
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struct amdtp_dot *p = (struct amdtp_dot *)s->protocol;
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struct snd_pcm_substream *pcm;
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unsigned int pcm_frames;
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pcm = ACCESS_ONCE(s->pcm);
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if (pcm) {
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p->transfer_samples(s, pcm, buffer, data_blocks);
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pcm_frames = data_blocks;
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} else {
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write_pcm_silence(s, buffer, data_blocks);
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pcm_frames = 0;
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}
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write_midi_messages(s, buffer, data_blocks);
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return pcm_frames;
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}
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int amdtp_dot_init(struct amdtp_stream *s, struct fw_unit *unit,
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enum amdtp_stream_direction dir)
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{
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amdtp_stream_process_data_blocks_t process_data_blocks;
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enum cip_flags flags;
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/* Use different mode between incoming/outgoing. */
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if (dir == AMDTP_IN_STREAM) {
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flags = CIP_NONBLOCKING | CIP_SKIP_INIT_DBC_CHECK;
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process_data_blocks = process_tx_data_blocks;
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} else {
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flags = CIP_BLOCKING;
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process_data_blocks = process_rx_data_blocks;
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}
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return amdtp_stream_init(s, unit, dir, flags, CIP_FMT_AM,
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process_data_blocks, sizeof(struct amdtp_dot));
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}
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void amdtp_dot_reset(struct amdtp_stream *s)
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{
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struct amdtp_dot *p = s->protocol;
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p->state.carry = 0x00;
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p->state.idx = 0x00;
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p->state.off = 0;
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}
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