osd-contiki/cpu/avr/dev/usb/storage/ctrl_access.c
2008-10-14 20:16:36 +00:00

974 lines
24 KiB
C
Raw Blame History

/* This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file ctrl_access.c *********************************************************************
*
* \brief
* This file contains the interface :
* - between USB <-> MEMORY
* OR
* - between USB <- Access Memory Ctrl -> Memory
*
* This interface may be controled by a "Access Memory Control" for :
* - include a management of write protect global or specific
* - include a management of access password
*
* \addtogroup usbstick
*
* \author
* Atmel Corporation: http://www.atmel.com \n
* Support email: avr@atmel.com
******************************************************************************/
/*
Copyright (c) 2004 ATMEL Corporation
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in
the documentation and/or other materials provided with the
distribution.
* Neither the name of the copyright holders nor the names of
contributors may be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
*/
/**
\addtogroup usbstorage
@{
*/
//_____ I N C L U D E S ____________________________________________________
#include "config.h"
#include "storage/ctrl_access.h"
//_____ D E F I N I T I O N S ______________________________________________
#if (ACCESS_MEM_TO_MEM == ENABLED)
#include "modules/file_system/fat.h"
U8 buf_sector[FS_SIZE_OF_SECTOR];
#endif
//! Computed the maximum of static lun (don't add the lun of Mass Storage in mode USB Host)
// FYC: Memory = Logical Unit
// CHECK FOR LUN DEFINE
#ifndef LUN_0
# error LUN_0 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_1
# error LUN_1 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_2
# error LUN_2 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_3
# error LUN_3 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_4
# error LUN_4 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_5
# error LUN_5 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_6
# error LUN_6 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_7
# error LUN_7 must be defined with ENABLE or DISABLE in conf_access.h
#endif
#ifndef LUN_USB
# error LUN_USB must be defined with ENABLE or DISABLE in conf_access.h
#endif
#if (LUN_0 == ENABLE)
#define LUN_0_EN 1
U8 FLASH lun0_name[]=LUN_0_NAME;
#else
#define LUN_0_EN 0
#endif
#if (LUN_1 == ENABLE)
#define LUN_1_EN 1
U8 FLASH lun1_name[]=LUN_1_NAME;
#else
#define LUN_1_EN 0
#endif
#if (LUN_2 == ENABLE)
#define LUN_2_EN 1
U8 FLASH lun2_name[]=LUN_2_NAME;
#else
#define LUN_2_EN 0
#endif
#if (LUN_3 == ENABLE)
#define LUN_3_EN 1
U8 FLASH lun3_name[]=LUN_3_NAME;
#else
#define LUN_3_EN 0
#endif
#if (LUN_4 == ENABLE)
#define LUN_4_EN 1
U8 FLASH lun4_name[]=LUN_4_NAME;
#else
#define LUN_4_EN 0
#endif
#if (LUN_5 == ENABLE)
#define LUN_5_EN 1
U8 FLASH lun5_name[]=LUN_5_NAME;
#else
#define LUN_5_EN 0
#endif
#if (LUN_6 == ENABLE)
#define LUN_6_EN 1
U8 FLASH lun6_name[]=LUN_6_NAME;
#else
#define LUN_6_EN 0
#endif
#if (LUN_7 == ENABLE)
#define LUN_7_EN 1
U8 FLASH lun7_name[]=LUN_7_NAME;
#else
#define LUN_7_EN 0
#endif
#if (LUN_USB == ENABLE)
#define LUN_USB_EN 1
U8 FLASH lunusb_name[]=LUN_USB_NAME;
#else
#define LUN_USB_EN 0
#endif
#define LUN_ID_0 (0)
#define LUN_ID_1 (LUN_0_EN)
#define LUN_ID_2 (LUN_0_EN+LUN_1_EN)
#define LUN_ID_3 (LUN_0_EN+LUN_1_EN+LUN_2_EN)
#define LUN_ID_4 (LUN_0_EN+LUN_1_EN+LUN_2_EN+LUN_3_EN)
#define LUN_ID_5 (LUN_0_EN+LUN_1_EN+LUN_2_EN+LUN_3_EN+LUN_4_EN)
#define LUN_ID_6 (LUN_0_EN+LUN_1_EN+LUN_2_EN+LUN_3_EN+LUN_4_EN+LUN_5_EN)
#define LUN_ID_7 (LUN_0_EN+LUN_1_EN+LUN_2_EN+LUN_3_EN+LUN_4_EN+LUN_5_EN+LUN_6_EN)
#define MAX_LUN (LUN_0_EN+LUN_1_EN+LUN_2_EN+LUN_3_EN+LUN_4_EN+LUN_5_EN+LUN_6_EN+LUN_7_EN)
#define LUN_ID_USB (MAX_LUN)
// Check configuration
#if (MAX_LUN == 0)
#error No memory is active in conf_access.h
#endif
// Write protect variable
#if (GLOBAL_WR_PROTECT == ENABLED)
static U8 g_u8_wr_protect;
#endif
//_____ D E F I N I T I O N S __ F O N C T I O N S _________________________
//! This fonction return the number of logical unit
//!
//! @return U8 number of logical unit in the system
//!
U8 get_nb_lun()
{
#if (MEM_USB == ENABLED)
return (MAX_LUN + Host_getlun());
#else
return MAX_LUN;
#endif
}
//! This fonction return the current logical unit
//!
//! @return U8 number of logical unit in the system
//!
U8 get_cur_lun()
{
return 0; //TODO
}
//! This fonction test the state of memory, and start the initialisation of the memory
//!
//! MORE (see SPC-3 <20>5.2.4) : The TEST UNIT READY command allows an application client
//! to poll a logical unit until it is ready without the need to allocate space for returned data.
//! The TEST UNIT READY command may be used to check the media status of logical units with removable media.
//!
//! @param lun Logical unit number
//!
//! @return Ctrl_status
//! It is ready -> CTRL_GOOD
//! Memory unplug -> CTRL_NO_PRESENT
//! Not initialize -> CTRL_BUSY
//!
Ctrl_status mem_test_unit_ready( U8 lun )
{
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
return Lun_0_test_unit_ready();
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
return Lun_1_test_unit_ready();
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
return Lun_2_test_unit_ready();
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
return Lun_3_test_unit_ready();
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
return Lun_4_test_unit_ready();
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
return Lun_5_test_unit_ready();
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
return Lun_6_test_unit_ready();
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
return Lun_7_test_unit_ready();
break;
# endif
# if (LUN_USB == ENABLE)
default:
return Lun_usb_test_unit_ready(lun - LUN_ID_USB);
break;
# endif
}
return CTRL_FAIL;
}
//! This fonction return the capacity of the memory
//!
//! @param lun Logical unit number
//! @param u32_nb_sector The sector to query
//!
//! @return *u16_nb_sector number of sector (sector = 512B)
//! @return Ctrl_status
//! It is ready -> CTRL_GOOD
//! Memory unplug -> CTRL_NO_PRESENT
//!
Ctrl_status mem_read_capacity( U8 lun , U32 _MEM_TYPE_SLOW_ *u32_nb_sector )
{
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
return Lun_0_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
return Lun_1_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
return Lun_2_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
return Lun_3_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
return Lun_4_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
return Lun_5_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
return Lun_6_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
return Lun_7_read_capacity( u32_nb_sector );
break;
# endif
# if (LUN_USB == ENABLE)
default:
return Lun_usb_read_capacity( lun - LUN_ID_USB,u32_nb_sector );
break;
# endif
}
return CTRL_FAIL;
}
//! This fonction return is the write protected mode
//!
//! @param lun Logical unit number
//!
//! Only used by memory removal with a HARDWARE SPECIFIC write protected detection
//! !!! The customer must be unplug the card for change this write protected mode.
//!
//! @return TRUE -> the memory is protected
//!
Bool mem_wr_protect( U8 lun )
{
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
return Lun_0_wr_protect();
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
return Lun_1_wr_protect();
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
return Lun_2_wr_protect();
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
return Lun_3_wr_protect();
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
return Lun_4_wr_protect();
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
return Lun_5_wr_protect();
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
return Lun_6_wr_protect();
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
return Lun_7_wr_protect();
break;
# endif
# if (LUN_USB == ENABLE)
default:
return Lun_usb_wr_protect(lun - LUN_ID_USB);
break;
# endif
}
return CTRL_FAIL;
}
//! This fonction inform about the memory type
//!
//! @param lun Logical unit number
//!
//! @return TRUE -> The memory is removal
//!
Bool mem_removal( U8 lun )
{
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
return Lun_0_removal();
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
return Lun_1_removal();
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
return Lun_2_removal();
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
return Lun_3_removal();
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
return Lun_4_removal();
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
return Lun_5_removal();
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
return Lun_6_removal();
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
return Lun_7_removal();
break;
# endif
# if (LUN_USB == ENABLE)
default:
return Lun_usb_removal();
break;
# endif
}
return CTRL_FAIL;
}
//! This fonction returns a pointer to the LUN name
//!
//! @param lun Logical unit number
//!
//! @return pointer to code string
//!
U8 FLASH* mem_name( U8 lun )
{
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
return (U8 FLASH*)lun0_name;
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
return (U8 FLASH*)lun1_name;
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
return (U8 FLASH*)lun2_name;
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
return (U8 FLASH*)lun3_name;
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
return (U8 FLASH*)lun4_name;
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
return (U8 FLASH*)lun5_name;
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
return (U8 FLASH*)lun6_name;
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
return (U8 FLASH*)lun7_name;
break;
# endif
# if (LUN_USB == ENABLE)
default:
return (U8 FLASH*)lunusb_name;
break;
# endif
}
return 0; // Remove compiler warning
}
//************************************************************************************
//!----------- Listing of READ/WRITE interface with MODE ACCESS REGISTER -------------
//************************************************************************************
//! This fonction tranfer a data from memory to usb
//!
//! @param lun Logical unit number
//! @param addr Sector address to start read (sector = 512B)
//! @param nb_sector Number of sectors to transfer
//!
//! @return Ctrl_status
//! It is ready -> CTRL_GOOD
//! A error occur -> CTRL_FAIL
//! Memory unplug -> CTRL_NO_PRESENT
//!
Ctrl_status memory_2_usb( U8 lun , U32 addr , U16 nb_sector )
{
Ctrl_status status;
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
status = Lun_0_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_0_usb_read();
}
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
status = Lun_1_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_1_usb_read();
}
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
status = Lun_2_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_2_usb_read();
}
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
status = Lun_3_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_3_usb_read();
}
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
status = Lun_4_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_4_usb_read();
}
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
status = Lun_5_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_5_usb_read();
}
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
status = Lun_6_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_6_usb_read();
}
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
status = Lun_7_read_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_7_usb_read();
}
break;
# endif
}
return status;
}
//! This fonction trabsfer a data from usb to memory
//!
//! @param lun Logical unit number
//! @param addr Sector address to start write (sector = 512B)
//! @param nb_sector Number of sectors to transfer
//!
//! @return Ctrl_status
//! It is ready -> CTRL_GOOD
//! A error occur -> CTRL_FAIL
//! Memory unplug -> CTRL_NO_PRESENT
//!
Ctrl_status usb_2_memory( U8 lun , U32 addr , U16 nb_sector )
{
Ctrl_status status;
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
status = Lun_0_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_0_usb_write();
}
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
status = Lun_1_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_1_usb_write();
}
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
status = Lun_2_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_2_usb_write();
}
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
status = Lun_3_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_3_usb_write();
}
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
status = Lun_4_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_4_usb_write();
}
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
status = Lun_5_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_5_usb_write();
}
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
status = Lun_6_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_6_usb_write();
}
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
status = Lun_7_write_10(addr , nb_sector);
if (CTRL_GOOD == status)
{
status = Lun_7_usb_write();
}
break;
# endif
}
return status;
}
//! Interface for RAM
#if (ACCESS_MEM_TO_RAM == ENABLED)
//! This fonction tranfer one sector data from memory to ram
//!
//! @param lun Logical unit number
//! @param addr Sector address to start read (sector = 512B)
//! @param ram Adresse of ram buffer (only xdata)
//!
//! @return TRUE -> The memory is removal
//!
Ctrl_status memory_2_ram( U8 lun , const U32 _MEM_TYPE_SLOW_ *addr , U8 _MEM_TYPE_SLOW_ *ram )
{
Ctrl_status status;
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
status = Lun_0_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_0_mem_2_ram_read();
}
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
status = Lun_1_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_1_mem_2_ram_read();
}
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
status = Lun_2_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_2_mem_2_ram_read();
}
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
status = Lun_3_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_3_mem_2_ram_read();
}
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
status = Lun_4_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_4_mem_2_ram_read();
}
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
status = Lun_5_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_5_mem_2_ram_read();
}
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
status = Lun_6_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_6_mem_2_ram_read();
}
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
status = Lun_7_mem_2_ram(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_7_mem_2_ram_read();
}
break;
# endif
# if (LUN_USB == ENABLE)
default:
return Lun_usb_mem_2_ram(*addr , ram);
# endif
}
return status;
}
#endif // ACCESS_MEM_TO_RAM == ENABLED
#if (ACCESS_MEM_TO_RAM==ENABLE)
//! This fonction trabsfer a data from ram to memory
//!
//! @param lun Logical unit number
//! @param addr Sector address to start write (sector = 512B)
//! @param ram Adresse of ram buffer (only xdata)
//!
//! @return TRUE -> The memory is removal
//!
Ctrl_status ram_2_memory( U8 lun , const U32 _MEM_TYPE_SLOW_ *addr , U8 _MEM_TYPE_SLOW_ * ram )
{
Ctrl_status status;
switch( lun )
{
# if (LUN_0 == ENABLE)
case LUN_ID_0:
status = Lun_0_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_0_ram_2_mem_write();
}
break;
# endif
# if (LUN_1 == ENABLE)
case LUN_ID_1:
status = Lun_1_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_1_ram_2_mem_write();
}
break;
# endif
# if (LUN_2 == ENABLE)
case LUN_ID_2:
status = Lun_2_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_2_ram_2_mem_write();
}
break;
# endif
# if (LUN_3 == ENABLE)
case LUN_ID_3:
status = Lun_3_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_3_ram_2_mem_write();
}
break;
# endif
# if (LUN_4 == ENABLE)
case LUN_ID_4:
status = Lun_4_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_4_ram_2_mem_write();
}
break;
# endif
# if (LUN_5 == ENABLE)
case LUN_ID_5:
status = Lun_5_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_5_ram_2_mem_write();
}
break;
# endif
# if (LUN_6 == ENABLE)
case LUN_ID_6:
status = Lun_6_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_6_ram_2_mem_write();
}
break;
# endif
# if (LUN_7 == ENABLE)
case LUN_ID_7:
status = Lun_7_ram_2_mem(*addr , ram);
if (CTRL_GOOD == status)
{
status = Lun_7_ram_2_mem_write();
}
break;
# endif
# if (LUN_USB == ENABLE)
default:
return Lun_usb_ram_2_mem(*addr , ram);
break;
# endif
}
return status;
}
#endif // ACCESS_RAM_TO_MEM == ENABLED
//! Interface for streaming interface
#if (ACCESS_STREAM == ENABLED)
// Interface for transfer MEM to MEM
# if (ACCESS_MEM_TO_MEM == ENABLED)
//! This fonction copy a data from memory to other memory
//!
//! @param src_lun The LUN of the source
//! @param src_addr The address of the source
//! @param dest_lun The LUN of the destination
//! @param dest_addr The address of the destination
//! @param nb_sector Number of sectors to transfer
//!
U8 stream_mem_to_mem( U8 src_lun , U32 src_addr , U8 dest_lun , U32 dest_addr , U16 nb_sector )
{
while(nb_sector)
{
memory_2_ram( src_lun , &src_addr , buf_sector );
ram_2_memory( dest_lun , &dest_addr , buf_sector );
src_addr++;
dest_addr++;
nb_sector--;
}
return CTRL_GOOD;
}
# endif // ACCESS_MEM_TO_MEM == ENABLED
//! Returns the state on a data transfer
//!
//! @param Id transfer id
//!
//! @return the state of the transfer
//! CTRL_GOOD It is finish
//! CTRL_BUSY It is running
//! CTRL_FAIL It is fail
//!
Ctrl_status stream_state( U8 Id )
{
return CTRL_GOOD;
}
//! Stop the data transfer
//!
//! @param Id Transfer id
//!
//! @return the number of sector remainder
//!
U16 stream_stop( U8 Id )
{
return 0;
}
#endif // ACCESS_STREAM == ENABLED
/** @} */