FreeRTOS-Plus/Source/FreeRTOS-Plus-FAT-SL/media-drv/ram/ramdrv_f.c - nest-detect/1.1/freertos - Git at Google

 /*
  * FreeRTOS+FAT SL V1.0.1 (C) 2014 HCC Embedded
  *
  * The FreeRTOS+FAT SL license terms are different to the FreeRTOS license
  * terms.
  *
  * FreeRTOS+FAT SL uses a dual license model that allows the software to be used
  * under a standard GPL open source license, or a commercial license.  The
  * standard GPL license (unlike the modified GPL license under which FreeRTOS
  * itself is distributed) requires that all software statically linked with
  * FreeRTOS+FAT SL is also distributed under the same GPL V2 license terms.
  * Details of both license options follow:
  *
  * - Open source licensing -
  * FreeRTOS+FAT SL is a free download and may be used, modified, evaluated and
  * distributed without charge provided the user adheres to version two of the
  * GNU General Public License (GPL) and does not remove the copyright notice or
  * this text.  The GPL V2 text is available on the gnu.org web site, and on the
  * following URL: http://www.FreeRTOS.org/gpl-2.0.txt.
  *
  * - Commercial licensing -
  * Businesses and individuals who for commercial or other reasons cannot comply
  * with the terms of the GPL V2 license must obtain a commercial license before
  * incorporating FreeRTOS+FAT SL into proprietary software for distribution in
  * any form.  Commercial licenses can be purchased from
  * http://shop.freertos.org/fat_sl and do not require any source files to be
  * changed.
  *
  * FreeRTOS+FAT SL is distributed in the hope that it will be useful.  You
  * cannot use FreeRTOS+FAT SL unless you agree that you use the software 'as
  * is'.  FreeRTOS+FAT SL is provided WITHOUT ANY WARRANTY; without even the
  * implied warranties of NON-INFRINGEMENT, MERCHANTABILITY or FITNESS FOR A
  * PARTICULAR PURPOSE. Real Time Engineers Ltd. and HCC Embedded disclaims all
  * conditions and terms, be they implied, expressed, or statutory.
  *
  * http://www.FreeRTOS.org
  * http://www.FreeRTOS.org/FreeRTOS-Plus
  *
  */

 #include "../../api/api_mdriver_ram.h"
 #include "config_mdriver_ram.h"
 #include "../../psp/include/psp_string.h"

 #include "../../version/ver_mdriver_ram.h"
 #if VER_MDRIVER_RAM_MAJOR != 1 || VER_MDRIVER_RAM_MINOR != 2
  #error Incompatible MDRIVER_RAM version number!
 #endif


 char  ramdrv0[MDRIVER_RAM_VOLUME0_SIZE];

 typedef struct
 {
   char         * ramdrv;
   unsigned long  maxsector;
   int            use;
   F_DRIVER     * driver;
 } t_RamDrv;

 static F_DRIVER  t_drivers[1];

 static t_RamDrv  RamDrv[1] =
 {
   { ramdrv0, ( MDRIVER_RAM_VOLUME0_SIZE / MDRIVER_RAM_SECTOR_SIZE ), 0, &t_drivers[0] }
 };


 /****************************************************************************
  * Read one sector
  ***************************************************************************/
 static int ram_readsector ( F_DRIVER * driver, void * data, unsigned long sector )
 {
   long       len;
   char     * d = (char *)data;
   char     * s;
   t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

   if ( sector >= p->maxsector )
   {
     return MDRIVER_RAM_ERR_SECTOR;
   }

   s = p->ramdrv;
   s += sector * MDRIVER_RAM_SECTOR_SIZE;
   len = MDRIVER_RAM_SECTOR_SIZE;

 #if MDRIVER_MEM_LONG_ACCESS
   if ( ( !( len & 3 ) ) && ( !( ( (long)d ) & 3 ) ) && ( !( ( (long)s ) & 3 ) ) )
   {
     long * dd = (long *)d;
     long * ss = (long *)s;
     len >>= 2;
     while ( len-- )
     {
       *dd++ = *ss++;
     }

     return MDRIVER_RAM_NO_ERROR;
   }

 #endif /* if MDRIVER_MEM_LONG_ACCESS */

   while ( len-- )
   {
     *d++ = *s++;
   }

   return MDRIVER_RAM_NO_ERROR;
 }

 /****************************************************************************
  * Write one sector
  ***************************************************************************/
 static int ram_writesector ( F_DRIVER * driver, void * data, unsigned long sector )
 {
   long       len;
   char     * s = (char *)data;
   char     * d;
   t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

   if ( sector >= p->maxsector )
   {
     return MDRIVER_RAM_ERR_SECTOR;
   }

   d = p->ramdrv;
   d += sector * MDRIVER_RAM_SECTOR_SIZE;
   len = MDRIVER_RAM_SECTOR_SIZE;

 #if MDRIVER_MEM_LONG_ACCESS
   if ( ( !( len & 3 ) ) && ( !( ( (long)d ) & 3 ) ) && ( !( ( (long)s ) & 3 ) ) )
   {
     long * dd = (long *)d;
     long * ss = (long *)s;
     len >>= 2;
     while ( len-- )
     {
       *dd++ = *ss++;
     }

     return MDRIVER_RAM_NO_ERROR;
   }

 #endif /* if MDRIVER_MEM_LONG_ACCESS */

   while ( len-- )
   {
     *d++ = *s++;
   }

   return MDRIVER_RAM_NO_ERROR;
 }


 /****************************************************************************
  *
  * ram_getphy
  *
  * determinate ramdrive physicals
  *
  * INPUTS
  *
  * driver - driver structure
  * phy - this structure has to be filled with physical information
  *
  * RETURNS
  *
  * error code or zero if successful
  *
  ***************************************************************************/
 static int ram_getphy ( F_DRIVER * driver, F_PHY * phy )
 {
   t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

   phy->number_of_sectors = p->maxsector;
   phy->bytes_per_sector = MDRIVER_RAM_SECTOR_SIZE;

   return MDRIVER_RAM_NO_ERROR;
 }


 /****************************************************************************
  *
  * ram_release
  *
  * Releases a drive
  *
  * INPUTS
  *
  * driver_param - driver parameter
  *
  ***************************************************************************/
 static void ram_release ( F_DRIVER * driver )
 {
   t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

   if ( p == RamDrv )
   {
     p->use = 0;
   }
 }


 /****************************************************************************
  *
  * ram_initfunc
  *
  * this init function has to be passed for highlevel to initiate the
  * driver functions
  *
  * INPUTS
  *
  * driver_param - driver parameter
  *
  * RETURNS
  *
  * driver structure pointer
  *
  ***************************************************************************/
 F_DRIVER * ram_initfunc ( unsigned long driver_param )
 {
   t_RamDrv    * p;

   p = RamDrv + driver_param;

   if ( p != RamDrv )
   {
     return 0;
   }

   if ( p->use )
   {
     return 0;
   }

   (void)psp_memset( p->driver, 0, sizeof( F_DRIVER ) );

   p->driver->readsector = ram_readsector;
   p->driver->writesector = ram_writesector;
   p->driver->getphy = ram_getphy;
   p->driver->release = ram_release;
   p->driver->user_ptr = p;

   p->use = 1;

   return p->driver;
 } /* ram_initfunc */
	/*
	* FreeRTOS+FAT SL V1.0.1 (C) 2014 HCC Embedded
	*
	* The FreeRTOS+FAT SL license terms are different to the FreeRTOS license
	* terms.
	*
	* FreeRTOS+FAT SL uses a dual license model that allows the software to be used
	* under a standard GPL open source license, or a commercial license. The
	* standard GPL license (unlike the modified GPL license under which FreeRTOS
	* itself is distributed) requires that all software statically linked with
	* FreeRTOS+FAT SL is also distributed under the same GPL V2 license terms.
	* Details of both license options follow:
	*
	* - Open source licensing -
	* FreeRTOS+FAT SL is a free download and may be used, modified, evaluated and
	* distributed without charge provided the user adheres to version two of the
	* GNU General Public License (GPL) and does not remove the copyright notice or
	* this text. The GPL V2 text is available on the gnu.org web site, and on the
	* following URL: http://www.FreeRTOS.org/gpl-2.0.txt.
	*
	* - Commercial licensing -
	* Businesses and individuals who for commercial or other reasons cannot comply
	* with the terms of the GPL V2 license must obtain a commercial license before
	* incorporating FreeRTOS+FAT SL into proprietary software for distribution in
	* any form. Commercial licenses can be purchased from
	* http://shop.freertos.org/fat_sl and do not require any source files to be
	* changed.
	*
	* FreeRTOS+FAT SL is distributed in the hope that it will be useful. You
	* cannot use FreeRTOS+FAT SL unless you agree that you use the software 'as
	* is'. FreeRTOS+FAT SL is provided WITHOUT ANY WARRANTY; without even the
	* implied warranties of NON-INFRINGEMENT, MERCHANTABILITY or FITNESS FOR A
	* PARTICULAR PURPOSE. Real Time Engineers Ltd. and HCC Embedded disclaims all
	* conditions and terms, be they implied, expressed, or statutory.
	*
	* http://www.FreeRTOS.org
	* http://www.FreeRTOS.org/FreeRTOS-Plus
	*
	*/

	#include "../../api/api_mdriver_ram.h"
	#include "config_mdriver_ram.h"
	#include "../../psp/include/psp_string.h"

	#include "../../version/ver_mdriver_ram.h"
	#if VER_MDRIVER_RAM_MAJOR != 1 \|\| VER_MDRIVER_RAM_MINOR != 2
	#error Incompatible MDRIVER_RAM version number!
	#endif


	char ramdrv0[MDRIVER_RAM_VOLUME0_SIZE];

	typedef struct
	{
	char * ramdrv;
	unsigned long maxsector;
	int use;
	F_DRIVER * driver;
	} t_RamDrv;

	static F_DRIVER t_drivers[1];

	static t_RamDrv RamDrv[1] =
	{
	{ ramdrv0, ( MDRIVER_RAM_VOLUME0_SIZE / MDRIVER_RAM_SECTOR_SIZE ), 0, &t_drivers[0] }
	};


	/****************************************************************************
	* Read one sector
	***************************************************************************/
	static int ram_readsector ( F_DRIVER * driver, void * data, unsigned long sector )
	{
	long len;
	char * d = (char *)data;
	char * s;
	t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

	if ( sector >= p->maxsector )
	{
	return MDRIVER_RAM_ERR_SECTOR;
	}

	s = p->ramdrv;
	s += sector * MDRIVER_RAM_SECTOR_SIZE;
	len = MDRIVER_RAM_SECTOR_SIZE;

	#if MDRIVER_MEM_LONG_ACCESS
	if ( ( !( len & 3 ) ) && ( !( ( (long)d ) & 3 ) ) && ( !( ( (long)s ) & 3 ) ) )
	{
	long * dd = (long *)d;
	long * ss = (long *)s;
	len >>= 2;
	while ( len-- )
	{
	dd++ = ss++;
	}

	return MDRIVER_RAM_NO_ERROR;
	}

	#endif /* if MDRIVER_MEM_LONG_ACCESS */

	while ( len-- )
	{
	d++ = s++;
	}

	return MDRIVER_RAM_NO_ERROR;
	}

	/****************************************************************************
	* Write one sector
	***************************************************************************/
	static int ram_writesector ( F_DRIVER * driver, void * data, unsigned long sector )
	{
	long len;
	char * s = (char *)data;
	char * d;
	t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

	if ( sector >= p->maxsector )
	{
	return MDRIVER_RAM_ERR_SECTOR;
	}

	d = p->ramdrv;
	d += sector * MDRIVER_RAM_SECTOR_SIZE;
	len = MDRIVER_RAM_SECTOR_SIZE;

	#if MDRIVER_MEM_LONG_ACCESS
	if ( ( !( len & 3 ) ) && ( !( ( (long)d ) & 3 ) ) && ( !( ( (long)s ) & 3 ) ) )
	{
	long * dd = (long *)d;
	long * ss = (long *)s;
	len >>= 2;
	while ( len-- )
	{
	dd++ = ss++;
	}

	return MDRIVER_RAM_NO_ERROR;
	}

	#endif /* if MDRIVER_MEM_LONG_ACCESS */

	while ( len-- )
	{
	d++ = s++;
	}

	return MDRIVER_RAM_NO_ERROR;
	}


	/****************************************************************************
	*
	* ram_getphy
	*
	* determinate ramdrive physicals
	*
	* INPUTS
	*
	* driver - driver structure
	* phy - this structure has to be filled with physical information
	*
	* RETURNS
	*
	* error code or zero if successful
	*
	***************************************************************************/
	static int ram_getphy ( F_DRIVER * driver, F_PHY * phy )
	{
	t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

	phy->number_of_sectors = p->maxsector;
	phy->bytes_per_sector = MDRIVER_RAM_SECTOR_SIZE;

	return MDRIVER_RAM_NO_ERROR;
	}


	/****************************************************************************
	*
	* ram_release
	*
	* Releases a drive
	*
	* INPUTS
	*
	* driver_param - driver parameter
	*
	***************************************************************************/
	static void ram_release ( F_DRIVER * driver )
	{
	t_RamDrv * p = (t_RamDrv *)( driver->user_ptr );

	if ( p == RamDrv )
	{
	p->use = 0;
	}
	}


	/****************************************************************************
	*
	* ram_initfunc
	*
	* this init function has to be passed for highlevel to initiate the
	* driver functions
	*
	* INPUTS
	*
	* driver_param - driver parameter
	*
	* RETURNS
	*
	* driver structure pointer
	*
	***************************************************************************/
	F_DRIVER * ram_initfunc ( unsigned long driver_param )
	{
	t_RamDrv * p;

	p = RamDrv + driver_param;

	if ( p != RamDrv )
	{
	return 0;
	}

	if ( p->use )
	{
	return 0;
	}

	(void)psp_memset( p->driver, 0, sizeof( F_DRIVER ) );

	p->driver->readsector = ram_readsector;
	p->driver->writesector = ram_writesector;
	p->driver->getphy = ram_getphy;
	p->driver->release = ram_release;
	p->driver->user_ptr = p;

	p->use = 1;

	return p->driver;
	} /* ram_initfunc */