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/****************************************************************************
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   Copyright Echo Digital Audio Corporation (c) 1998 - 2004
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   All rights reserved
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   www.echoaudio.com
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   This file is part of Echo Digital Audio's generic driver library.
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   Echo Digital Audio's generic driver library is free software;
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   you can redistribute it and/or modify it under the terms of
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   the GNU General Public License as published by the Free Software
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   Foundation.
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   This program is distributed in the hope that it will be useful,
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   but WITHOUT ANY WARRANTY; without even the implied warranty of
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   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
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   GNU General Public License for more details.
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19
   You should have received a copy of the GNU General Public License
20
   along with this program; if not, write to the Free Software
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   Foundation, Inc., 59 Temple Place - Suite 330, Boston,
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   MA  02111-1307, USA.
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 ****************************************************************************
25

26
 Translation from C++ and adaptation for use in ALSA-Driver
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 were made by Giuliano Pochini <[email protected]>
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29
 ****************************************************************************
30

31

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   Here's a block diagram of how most of the cards work:
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                  +-----------+
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           record |           |<-------------------- Inputs
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          <-------|           |        |
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     PCI          | Transport |        |
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     bus          |  engine   |       \|/
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          ------->|           |    +-------+
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            play  |           |--->|monitor|-------> Outputs
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                  +-----------+    | mixer |
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                                   +-------+
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   The lines going to and from the PCI bus represent "pipes".  A pipe performs
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   audio transport - moving audio data to and from buffers on the host via
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   bus mastering.
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   The inputs and outputs on the right represent input and output "busses."
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   A bus is a physical, real connection to the outside world.  An example
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   of a bus would be the 1/4" analog connectors on the back of Layla or
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   an RCA S/PDIF connector.
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   For most cards, there is a one-to-one correspondence between outputs
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   and busses; that is, each individual pipe is hard-wired to a single bus.
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   Cards that work this way are Darla20, Gina20, Layla20, Darla24, Gina24,
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   Layla24, Mona, and Indigo.
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59

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   Mia has a feature called "virtual outputs."
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                  +-----------+
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           record |           |<----------------------------- Inputs
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          <-------|           |                  |
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     PCI          | Transport |                  |
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     bus          |  engine   |                 \|/
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          ------->|           |   +------+   +-------+
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            play  |           |-->|vmixer|-->|monitor|-------> Outputs
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                  +-----------+   +------+   | mixer |
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                                             +-------+
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   Obviously, the difference here is the box labeled "vmixer."  Vmixer is
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   short for "virtual output mixer."  For Mia, pipes are *not* hard-wired
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   to a single bus; the vmixer lets you mix any pipe to any bus in any
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   combination.
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79
   Note, however, that the left-hand side of the diagram is unchanged.
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   Transport works exactly the same way - the difference is in the mixer stage.
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   Pipes and busses are numbered starting at zero.
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   Pipe index
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   ==========
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90
   A number of calls in CEchoGals refer to a "pipe index".  A pipe index is
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   a unique number for a pipe that unambiguously refers to a playback or record
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   pipe.  Pipe indices are numbered starting with analog outputs, followed by
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   digital outputs, then analog inputs, then digital inputs.
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   Take Gina24 as an example:
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   Pipe index
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   0-7            Analog outputs (0 .. FirstDigitalBusOut-1)
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   8-15           Digital outputs (FirstDigitalBusOut .. NumBussesOut-1)
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   16-17          Analog inputs
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   18-25          Digital inputs
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   You get the pipe index by calling CEchoGals::OpenAudio; the other transport
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   functions take the pipe index as a parameter.  If you need a pipe index for
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   some other reason, use the handy Makepipe_index method.
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   Some calls take a CChannelMask parameter; CChannelMask is a handy way to
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   group pipe indices.
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   Digital mode switch
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   ===================
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118
   Some cards (right now, Gina24, Layla24, and Mona) have a Digital Mode Switch
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   or DMS.  Cards with a DMS can be set to one of three mutually exclusive
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   digital modes: S/PDIF RCA, S/PDIF optical, or ADAT optical.
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   This may create some confusion since ADAT optical is 8 channels wide and
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   S/PDIF is only two channels wide.  Gina24, Layla24, and Mona handle this
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   by acting as if they always have 8 digital outs and ins.  If you are in
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   either S/PDIF mode, the last 6 channels don't do anything - data sent
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   out these channels is thrown away and you will always record zeros.
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   Note that with Gina24, Layla24, and Mona, sample rates above 50 kHz are
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   only available if you have the card configured for S/PDIF optical or S/PDIF
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   RCA.
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   Double speed mode
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   =================
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   Some of the cards support 88.2 kHz and 96 kHz sampling (Darla24, Gina24,
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   Layla24, Mona, Mia, and Indigo).  For these cards, the driver sometimes has
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   to worry about "double speed mode"; double speed mode applies whenever the
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   sampling rate is above 50 kHz.
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   For instance, Mona and Layla24 support word clock sync.  However, they
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   actually support two different word clock modes - single speed (below
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   50 kHz) and double speed (above 50 kHz).  The hardware detects if a single
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   or double speed word clock signal is present; the generic code uses that
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   information to determine which mode to use.
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   The generic code takes care of all this for you.
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*/
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#ifndef _ECHOAUDIO_H_
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#define _ECHOAUDIO_H_
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#include "echoaudio_dsp.h"
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/***********************************************************************
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	PCI configuration space
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***********************************************************************/
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/*
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 * PCI vendor ID and device IDs for the hardware
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 */
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#define VENDOR_ID		0x1057
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#define DEVICE_ID_56301		0x1801
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#define DEVICE_ID_56361		0x3410
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#define SUBVENDOR_ID		0xECC0
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/*
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 * Valid Echo PCI subsystem card IDs
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 */
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#define DARLA20			0x0010
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#define GINA20			0x0020
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#define LAYLA20			0x0030
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#define DARLA24			0x0040
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#define GINA24			0x0050
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#define LAYLA24			0x0060
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#define MONA			0x0070
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#define MIA			0x0080
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#define INDIGO			0x0090
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#define INDIGO_IO		0x00a0
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#define INDIGO_DJ		0x00b0
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#define DC8			0x00c0
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#define INDIGO_IOX		0x00d0
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#define INDIGO_DJX		0x00e0
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#define ECHO3G			0x0100
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/************************************************************************
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	Array sizes and so forth
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***********************************************************************/
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/*
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 * Sizes
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 */
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#define ECHO_MAXAUDIOINPUTS	32	/* Max audio input channels */
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#define ECHO_MAXAUDIOOUTPUTS	32	/* Max audio output channels */
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#define ECHO_MAXAUDIOPIPES	32	/* Max number of input and output
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					 * pipes */
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#define E3G_MAX_OUTPUTS		16
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#define ECHO_MAXMIDIJACKS	1	/* Max MIDI ports */
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#define ECHO_MIDI_QUEUE_SZ 	512	/* Max MIDI input queue entries */
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#define ECHO_MTC_QUEUE_SZ	32	/* Max MIDI time code input queue
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					 * entries */
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/*
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 * MIDI activity indicator timeout
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 */
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#define MIDI_ACTIVITY_TIMEOUT_USEC	200000
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/****************************************************************************
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   Clocks
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*****************************************************************************/
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/*
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 * Clock numbers
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 */
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#define ECHO_CLOCK_INTERNAL		0
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#define ECHO_CLOCK_WORD			1
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#define ECHO_CLOCK_SUPER		2
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#define ECHO_CLOCK_SPDIF		3
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#define ECHO_CLOCK_ADAT			4
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#define ECHO_CLOCK_ESYNC		5
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#define ECHO_CLOCK_ESYNC96		6
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#define ECHO_CLOCK_MTC			7
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#define ECHO_CLOCK_NUMBER		8
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#define ECHO_CLOCKS			0xffff
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/*
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 * Clock bit numbers - used to report capabilities and whatever clocks
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 * are being detected dynamically.
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 */
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#define ECHO_CLOCK_BIT_INTERNAL		(1 << ECHO_CLOCK_INTERNAL)
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#define ECHO_CLOCK_BIT_WORD		(1 << ECHO_CLOCK_WORD)
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#define ECHO_CLOCK_BIT_SUPER		(1 << ECHO_CLOCK_SUPER)
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#define ECHO_CLOCK_BIT_SPDIF		(1 << ECHO_CLOCK_SPDIF)
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#define ECHO_CLOCK_BIT_ADAT		(1 << ECHO_CLOCK_ADAT)
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#define ECHO_CLOCK_BIT_ESYNC		(1 << ECHO_CLOCK_ESYNC)
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#define ECHO_CLOCK_BIT_ESYNC96		(1 << ECHO_CLOCK_ESYNC96)
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#define ECHO_CLOCK_BIT_MTC		(1<<ECHO_CLOCK_MTC)
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/***************************************************************************
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256
   Digital modes
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****************************************************************************/
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/*
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 * Digital modes for Mona, Layla24, and Gina24
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 */
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#define DIGITAL_MODE_NONE			0xFF
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#define DIGITAL_MODE_SPDIF_RCA			0
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#define DIGITAL_MODE_SPDIF_OPTICAL		1
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#define DIGITAL_MODE_ADAT			2
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#define DIGITAL_MODE_SPDIF_CDROM		3
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#define DIGITAL_MODES				4
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/*
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 * Digital mode capability masks
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 */
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#define ECHOCAPS_HAS_DIGITAL_MODE_SPDIF_RCA	(1 << DIGITAL_MODE_SPDIF_RCA)
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#define ECHOCAPS_HAS_DIGITAL_MODE_SPDIF_OPTICAL	(1 << DIGITAL_MODE_SPDIF_OPTICAL)
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#define ECHOCAPS_HAS_DIGITAL_MODE_ADAT		(1 << DIGITAL_MODE_ADAT)
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#define ECHOCAPS_HAS_DIGITAL_MODE_SPDIF_CDROM	(1 << DIGITAL_MODE_SPDIF_CDROM)
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#define EXT_3GBOX_NC			0x01	/* 3G box not connected */
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#define EXT_3GBOX_NOT_SET		0x02	/* 3G box not detected yet */
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#define ECHOGAIN_MUTED		(-128)	/* Minimum possible gain */
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#define ECHOGAIN_MINOUT		(-128)	/* Min output gain (dB) */
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#define ECHOGAIN_MAXOUT		(6)	/* Max output gain (dB) */
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#define ECHOGAIN_MININP		(-50)	/* Min input gain (0.5 dB) */
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#define ECHOGAIN_MAXINP		(50)	/* Max input gain (0.5 dB) */
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#define PIPE_STATE_STOPPED	0	/* Pipe has been reset */
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#define PIPE_STATE_PAUSED	1	/* Pipe has been stopped */
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#define PIPE_STATE_STARTED	2	/* Pipe has been started */
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#define PIPE_STATE_PENDING	3	/* Pipe has pending start */
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struct audiopipe {
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	volatile __le32 *dma_counter;	/* Commpage register that contains
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					 * the current dma position
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					 * (lower 32 bits only)
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					 */
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	u32 last_period;                /* Counter position last time a
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					 * period elapsed
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					 */
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	u32 last_counter;		/* Used exclusively by pcm_pointer
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					 * under PCM core locks.
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					 * The last position, which is used
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					 * to compute...
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					 */
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	u32 position;			/* ...the number of bytes tranferred
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					 * by the DMA engine, modulo the
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					 * buffer size
312
					 */
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	short index;			/* Index of the first channel or <0
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					 * if hw is not configured yet
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					 */
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	short interleave;
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	struct snd_dma_buffer sgpage;	/* Room for the scatter-gather list */
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	struct snd_pcm_hardware hw;
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	struct snd_pcm_hw_constraint_list constr;
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	short sglist_head;
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	char state;			/* pipe state */
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};
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struct audioformat {
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	u8 interleave;			/* How the data is arranged in memory:
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					 * mono = 1, stereo = 2, ...
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					 */
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	u8 bits_per_sample;		/* 8, 16, 24, 32 (24 bits left aligned) */
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	char mono_to_stereo;		/* Only used if interleave is 1 and
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					 * if this is an output pipe.
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					 */
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	char data_are_bigendian;	/* 1 = big endian, 0 = little endian */
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};
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struct echoaudio {
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	spinlock_t lock;
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	struct snd_pcm_substream *substream[DSP_MAXPIPES];
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	struct mutex mode_mutex;
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	u16 num_digital_modes, digital_mode_list[6];
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	u16 num_clock_sources, clock_source_list[10];
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	unsigned int opencount;  /* protected by mode_mutex */
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	struct snd_kcontrol *clock_src_ctl;
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	struct snd_pcm *analog_pcm, *digital_pcm;
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	struct snd_card *card;
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	const char *card_name;
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	struct pci_dev *pci;
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	unsigned long dsp_registers_phys;
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	struct resource *iores;
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	struct snd_dma_buffer *commpage_dma_buf;
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	int irq;
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#ifdef ECHOCARD_HAS_MIDI
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	struct snd_rawmidi *rmidi;
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	struct snd_rawmidi_substream *midi_in, *midi_out;
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#endif
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	struct timer_list timer;
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	char tinuse;				/* Timer in use */
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	char midi_full;				/* MIDI output buffer is full */
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	char can_set_rate;                      /* protected by mode_mutex */
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	char rate_set;                          /* protected by mode_mutex */
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363
	/* This stuff is used mainly by the lowlevel code */
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	struct comm_page *comm_page;	/* Virtual address of the memory
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					 * seen by DSP
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					 */
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	u32 pipe_alloc_mask;		/* Bitmask of allocated pipes */
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	u32 pipe_cyclic_mask;		/* Bitmask of pipes with cyclic
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					 * buffers
370
					 */
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	u32 sample_rate;		/* Card sample rate in Hz */
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	u8 digital_mode;		/* Current digital mode
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					 * (see DIGITAL_MODE_*)
374
					 */
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	u8 spdif_status;		/* Gina20, Darla20, Darla24 - only */
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	u8 clock_state;			/* Gina20, Darla20, Darla24 - only */
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	u8 input_clock;			/* Currently selected sample clock
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					 * source
379
					 */
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	u8 output_clock;		/* Layla20 only */
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	char meters_enabled;		/* VU-meters status */
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	char asic_loaded;		/* Set true when ASIC loaded */
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	char bad_board;			/* Set true if DSP won't load */
384
	char professional_spdif;	/* 0 = consumer; 1 = professional */
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	char non_audio_spdif;		/* 3G - only */
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	char digital_in_automute;	/* Gina24, Layla24, Mona - only */
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	char has_phantom_power;
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	char hasnt_input_nominal_level;	/* Gina3G */
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	char phantom_power;		/* Gina3G - only */
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	char has_midi;
391
	char midi_input_enabled;
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393
#ifdef ECHOCARD_ECHO3G
394
	/* External module -dependent pipe and bus indexes */
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	char px_digital_out, px_analog_in, px_digital_in, px_num;
396
	char bx_digital_out, bx_analog_in, bx_digital_in, bx_num;
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#endif
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	char nominal_level[ECHO_MAXAUDIOPIPES];	/* True == -10dBV
400
						 * False == +4dBu */
401
	s8 input_gain[ECHO_MAXAUDIOINPUTS];	/* Input level -50..+50
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						 * unit is 0.5dB */
403
	s8 output_gain[ECHO_MAXAUDIOOUTPUTS];	/* Output level -128..+6 dB
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						 * (-128=muted) */
405
	s8 monitor_gain[ECHO_MAXAUDIOOUTPUTS][ECHO_MAXAUDIOINPUTS];
406
		/* -128..+6 dB */
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	s8 vmixer_gain[ECHO_MAXAUDIOOUTPUTS][ECHO_MAXAUDIOOUTPUTS];
408
		/* -128..+6 dB */
409

410
	u16 digital_modes;		/* Bitmask of supported modes
411
					 * (see ECHOCAPS_HAS_DIGITAL_MODE_*) */
412
	u16 input_clock_types;		/* Suppoted input clock types */
413
	u16 output_clock_types;		/* Suppoted output clock types -
414
					 * Layla20 only */
415
	u16 device_id, subdevice_id;
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	u16 *dsp_code;			/* Current DSP code loaded,
417
					 * NULL if nothing loaded */
418
	short dsp_code_to_load;		/* DSP code to load */
419
	short asic_code;		/* Current ASIC code */
420
	u32 comm_page_phys;			/* Physical address of the
421
						 * memory seen by DSP */
422
	u32 __iomem *dsp_registers;		/* DSP's register base */
423
	u32 active_mask;			/* Chs. active mask or
424
						 * punks out */
425
	const struct firmware *fw_cache[8];	/* Cached firmwares */
426

427
#ifdef ECHOCARD_HAS_MIDI
428
	u16 mtc_state;				/* State for MIDI input parsing state machine */
429
	u8 midi_buffer[MIDI_IN_BUFFER_SIZE];
430
#endif
431
};
432

433

434
static int init_dsp_comm_page(struct echoaudio *chip);
435
static int init_line_levels(struct echoaudio *chip);
436
static int free_pipes(struct echoaudio *chip, struct audiopipe *pipe);
437
static int load_firmware(struct echoaudio *chip);
438
static int wait_handshake(struct echoaudio *chip);
439
static int send_vector(struct echoaudio *chip, u32 command);
440
static int get_firmware(const struct firmware **fw_entry,
441
			struct echoaudio *chip, const short fw_index);
442
static void free_firmware(const struct firmware *fw_entry,
443
			  struct echoaudio *chip);
444

445
#ifdef ECHOCARD_HAS_MIDI
446
static int enable_midi_input(struct echoaudio *chip, char enable);
447
static void snd_echo_midi_output_trigger(
448
			struct snd_rawmidi_substream *substream, int up);
449
static int midi_service_irq(struct echoaudio *chip);
450
static int snd_echo_midi_create(struct snd_card *card,
451
				struct echoaudio *chip);
452
#endif
453

454

455
static inline void clear_handshake(struct echoaudio *chip)
456
{
457
	chip->comm_page->handshake = 0;
458
}
459

460
static inline u32 get_dsp_register(struct echoaudio *chip, u32 index)
461
{
462
	return readl(&chip->dsp_registers[index]);
463
}
464

465
static inline void set_dsp_register(struct echoaudio *chip, u32 index,
466
				    u32 value)
467
{
468
	writel(value, &chip->dsp_registers[index]);
469
}
470

471

472
/* Pipe and bus indexes. PX_* and BX_* are defined as chip->px_* and chip->bx_*
473
for 3G cards because they depend on the external box. They are integer
474
constants for all other cards.
475
Never use those defines directly, use the following functions instead. */
476

477
static inline int px_digital_out(const struct echoaudio *chip)
478
{
479
	return PX_DIGITAL_OUT;
480
}
481

482
static inline int px_analog_in(const struct echoaudio *chip)
483
{
484
	return PX_ANALOG_IN;
485
}
486

487
static inline int px_digital_in(const struct echoaudio *chip)
488
{
489
	return PX_DIGITAL_IN;
490
}
491

492
static inline int px_num(const struct echoaudio *chip)
493
{
494
	return PX_NUM;
495
}
496

497
static inline int bx_digital_out(const struct echoaudio *chip)
498
{
499
	return BX_DIGITAL_OUT;
500
}
501

502
static inline int bx_analog_in(const struct echoaudio *chip)
503
{
504
	return BX_ANALOG_IN;
505
}
506

507
static inline int bx_digital_in(const struct echoaudio *chip)
508
{
509
	return BX_DIGITAL_IN;
510
}
511

512
static inline int bx_num(const struct echoaudio *chip)
513
{
514
	return BX_NUM;
515
}
516

517
static inline int num_pipes_out(const struct echoaudio *chip)
518
{
519
	return px_analog_in(chip);
520
}
521

522
static inline int num_pipes_in(const struct echoaudio *chip)
523
{
524
	return px_num(chip) - px_analog_in(chip);
525
}
526

527
static inline int num_busses_out(const struct echoaudio *chip)
528
{
529
	return bx_analog_in(chip);
530
}
531

532
static inline int num_busses_in(const struct echoaudio *chip)
533
{
534
	return bx_num(chip) - bx_analog_in(chip);
535
}
536

537
static inline int num_analog_busses_out(const struct echoaudio *chip)
538
{
539
	return bx_digital_out(chip);
540
}
541

542
static inline int num_analog_busses_in(const struct echoaudio *chip)
543
{
544
	return bx_digital_in(chip) - bx_analog_in(chip);
545
}
546

547
static inline int num_digital_busses_out(const struct echoaudio *chip)
548
{
549
	return num_busses_out(chip) - num_analog_busses_out(chip);
550
}
551

552
static inline int num_digital_busses_in(const struct echoaudio *chip)
553
{
554
	return num_busses_in(chip) - num_analog_busses_in(chip);
555
}
556

557
/* The monitor array is a one-dimensional array; compute the offset
558
 * into the array */
559
static inline int monitor_index(const struct echoaudio *chip, int out, int in)
560
{
561
	return out * num_busses_in(chip) + in;
562
}
563

564
#endif /* _ECHOAUDIO_H_ */
565

566