sound/pci/cs46xx/imgs/cwcdma.asp - kernel/mindspeed - Git at Google

 //
 //  Copyright(c) by Benny Sjostrand (benny@hostmobility.com)
 //
 //  This program is free software; you can redistribute it and/or modify
 //  it under the terms of the GNU General Public License as published by
 //  the Free Software Foundation; either version 2 of the License, or
 //  (at your option) any later version.
 //
 //  This program is distributed in the hope that it will be useful,
 //  but WITHOUT ANY WARRANTY; without even the implied warranty of
 //  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 //  GNU General Public License for more details.
 //
 //  You should have received a copy of the GNU General Public License
 //  along with this program; if not, write to the Free Software
 //  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307 USA
 //


 //
 // This code runs inside the DSP (cs4610, cs4612, cs4624, or cs4630),
 // to compile it you need a tool named SPASM 3.0 and DSP code owned by
 // Cirrus Logic(R). The SPASM program will generate a object file (cwcdma.osp),
 // the "ospparser"  tool will genereate the cwcdma.h file it's included from
 // the cs46xx_lib.c file.
 //
 //
 // The purpose of this code is very simple: make it possible to tranfser
 // the samples 'as they are' with no alteration from a PCMreader
 // SCB (DMA from host) to any other SCB. This is useful for AC3 through SPDIF.
 // SRC (source rate converters) task always alters the samples in somehow,
 // however it's from 48khz -> 48khz.
 // The alterations are not audible, but AC3 wont work.
 //
 //        ...
 //         |
 // +---------------+
 // | AsynchFGTxSCB |
 // +---------------+
 //        |
 //    subListPtr
 //        |
 // +--------------+
 // |   DMAReader  |
 // +--------------+
 //        |
 //    subListPtr
 //        |
 // +-------------+
 // | PCMReader   |
 // +-------------+
 // (DMA from host)
 //

 struct dmaSCB
   {
     long  dma_reserved1[3];

     short dma_reserved2:dma_outBufPtr;

     short dma_unused1:dma_unused2;

     long  dma_reserved3[4];

     short dma_subListPtr:dma_nextSCB;
     short dma_SPBptr:dma_entryPoint;

     long  dma_strmRsConfig;
     long  dma_strmBufPtr;

     long  dma_reserved4;

     VolumeControl s2m_volume;
   };

 #export DMAReader
 void DMAReader()
 {
   execChild();
   r2 = r0->dma_subListPtr;
   r1 = r0->nextSCB;

   rsConfig01 = r2->strmRsConfig;
   // Load rsConfig for input buffer

   rsDMA01 = r2->basicReq.daw,       ,                   tb = Z(0 - rf);
   // Load rsDMA in case input buffer is a DMA buffer    Test to see if there is any data to transfer

   if (tb) goto execSibling_2ind1 after {
       r5 = rf + (-1);
       r6 = r1->dma_entryPoint;           // r6 = entry point of sibling task
       r1 = r1->dma_SPBptr,               // r1 = pointer to sibling task's SPB
           ,   ind = r6;                  // Load entry point of sibling task
   }

   rsConfig23 = r0->dma_strmRsConfig;
   // Load rsConfig for output buffer (never a DMA buffer)

   r4 = r0->dma_outBufPtr;

   rsa0 = r2->strmBufPtr;
   // rsa0 = input buffer pointer

   for (i = r5; i >= 0; --i)
     after {
       rsa2 = r4;
       // rsa2 = output buffer pointer

       nop;
       nop;
     }
   //*****************************
   // TODO: cycles to this point *
   //*****************************
     {
       acc0 =  (rsd0 = *rsa0++1);
       // get sample

       nop;  // Those "nop"'s are really uggly, but there's
       nop;  // something with DSP's pipelines which I don't
       nop;  // understand, resulting this code to fail without
             // having those "nop"'s (Benny)

       rsa0?reqDMA = r2;
       // Trigger DMA transfer on input stream,
       // if needed to replenish input buffer

       nop;
       // Yet another magic "nop" to make stuff work

       ,,r98 = acc0 $+>> 0;
       // store sample in ALU

       nop;
       // latency on load register.
       // (this one is understandable)

       *rsa2++1 = r98;
       // store sample in output buffer

       nop; // The same story
       nop; // as above again ...
       nop;
     }
   // TODO: cycles per loop iteration

   r2->strmBufPtr = rsa0,,   ;
   // Update the modified buffer pointers

   r4 = rsa2;
   // Load output pointer position into r4

   r2 = r0->nextSCB;
   // Sibling task

   goto execSibling_2ind1 // takes 6 cycles
     after {
       r98 = r2->thisSPB:entryPoint;
       // Load child routine entry and data address

       r1 = r9;
       // r9 is r2->thisSPB

       r0->dma_outBufPtr = r4,,
       // Store updated output buffer pointer

       ind = r8;
       // r8 is r2->entryPoint
     }
 }
	//
	// Copyright(c) by Benny Sjostrand (benny@hostmobility.com)
	//
	// This program is free software; you can redistribute it and/or modify
	// it under the terms of the GNU General Public License as published by
	// the Free Software Foundation; either version 2 of the License, or
	// (at your option) any later version.
	//
	// This program is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU General Public License for more details.
	//
	// You should have received a copy of the GNU General Public License
	// along with this program; if not, write to the Free Software
	// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
	//


	//
	// This code runs inside the DSP (cs4610, cs4612, cs4624, or cs4630),
	// to compile it you need a tool named SPASM 3.0 and DSP code owned by
	// Cirrus Logic(R). The SPASM program will generate a object file (cwcdma.osp),
	// the "ospparser" tool will genereate the cwcdma.h file it's included from
	// the cs46xx_lib.c file.
	//
	//
	// The purpose of this code is very simple: make it possible to tranfser
	// the samples 'as they are' with no alteration from a PCMreader
	// SCB (DMA from host) to any other SCB. This is useful for AC3 through SPDIF.
	// SRC (source rate converters) task always alters the samples in somehow,
	// however it's from 48khz -> 48khz.
	// The alterations are not audible, but AC3 wont work.
	//
	// ...
	// \|
	// +---------------+
	// \| AsynchFGTxSCB \|
	// +---------------+
	// \|
	// subListPtr
	// \|
	// +--------------+
	// \| DMAReader \|
	// +--------------+
	// \|
	// subListPtr
	// \|
	// +-------------+
	// \| PCMReader \|
	// +-------------+
	// (DMA from host)
	//

	struct dmaSCB
	{
	long dma_reserved1[3];

	short dma_reserved2:dma_outBufPtr;

	short dma_unused1:dma_unused2;

	long dma_reserved3[4];

	short dma_subListPtr:dma_nextSCB;
	short dma_SPBptr:dma_entryPoint;

	long dma_strmRsConfig;
	long dma_strmBufPtr;

	long dma_reserved4;

	VolumeControl s2m_volume;
	};

	#export DMAReader
	void DMAReader()
	{
	execChild();
	r2 = r0->dma_subListPtr;
	r1 = r0->nextSCB;

	rsConfig01 = r2->strmRsConfig;
	// Load rsConfig for input buffer

	rsDMA01 = r2->basicReq.daw, , tb = Z(0 - rf);
	// Load rsDMA in case input buffer is a DMA buffer Test to see if there is any data to transfer

	if (tb) goto execSibling_2ind1 after {
	r5 = rf + (-1);
	r6 = r1->dma_entryPoint; // r6 = entry point of sibling task
	r1 = r1->dma_SPBptr, // r1 = pointer to sibling task's SPB
	, ind = r6; // Load entry point of sibling task
	}

	rsConfig23 = r0->dma_strmRsConfig;
	// Load rsConfig for output buffer (never a DMA buffer)

	r4 = r0->dma_outBufPtr;

	rsa0 = r2->strmBufPtr;
	// rsa0 = input buffer pointer

	for (i = r5; i >= 0; --i)
	after {
	rsa2 = r4;
	// rsa2 = output buffer pointer

	nop;
	nop;
	}
	//*****************************
	// TODO: cycles to this point *
	//*****************************
	{
	acc0 = (rsd0 = *rsa0++1);
	// get sample

	nop; // Those "nop"'s are really uggly, but there's
	nop; // something with DSP's pipelines which I don't
	nop; // understand, resulting this code to fail without
	// having those "nop"'s (Benny)

	rsa0?reqDMA = r2;
	// Trigger DMA transfer on input stream,
	// if needed to replenish input buffer

	nop;
	// Yet another magic "nop" to make stuff work

	,,r98 = acc0 $+>> 0;
	// store sample in ALU

	nop;
	// latency on load register.
	// (this one is understandable)

	*rsa2++1 = r98;
	// store sample in output buffer

	nop; // The same story
	nop; // as above again ...
	nop;
	}
	// TODO: cycles per loop iteration

	r2->strmBufPtr = rsa0,, ;
	// Update the modified buffer pointers

	r4 = rsa2;
	// Load output pointer position into r4

	r2 = r0->nextSCB;
	// Sibling task

	goto execSibling_2ind1 // takes 6 cycles
	after {
	r98 = r2->thisSPB:entryPoint;
	// Load child routine entry and data address

	r1 = r9;
	// r9 is r2->thisSPB

	r0->dma_outBufPtr = r4,,
	// Store updated output buffer pointer

	ind = r8;
	// r8 is r2->entryPoint
	}
	}