Staging: spectra: removes unused functions

Fix compilation warning removing unused functions.


Signed-off-by: Javier Martinez Canillas <martinez.javier@gmail.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
This commit is contained in:
Javier Martinez Canillas 2010-07-17 16:46:28 -04:00 committed by Greg Kroah-Hartman
parent fd484b86a2
commit 49b4854772
1 changed files with 0 additions and 416 deletions

View File

@ -61,7 +61,6 @@ static void FTL_Cache_Read_Page(u8 *pData, u64 dwPageAddr,
static void FTL_Cache_Write_Page(u8 *pData, u64 dwPageAddr,
u8 cache_blk, u16 flag);
static int FTL_Cache_Write(void);
static int FTL_Cache_Write_Back(u8 *pData, u64 blk_addr);
static void FTL_Calculate_LRU(void);
static u32 FTL_Get_Block_Index(u32 wBlockNum);
@ -86,8 +85,6 @@ static u32 FTL_Replace_MWBlock(void);
static int FTL_Replace_Block(u64 blk_addr);
static int FTL_Adjust_Relative_Erase_Count(u32 Index_of_MAX);
static int FTL_Flash_Error_Handle(u8 *pData, u64 old_page_addr, u64 blk_addr);
struct device_info_tag DeviceInfo;
struct flash_cache_tag Cache;
static struct spectra_l2_cache_info cache_l2;
@ -1537,79 +1534,6 @@ static int FTL_Cache_Write_All(u8 *pData, u64 blk_addr)
return wResult;
}
/*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
* Function: FTL_Cache_Update_Block
* Inputs: pointer to buffer,page address,block address
* Outputs: PASS=0 / FAIL=1
* Description: It updates the cache
*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&*/
static int FTL_Cache_Update_Block(u8 *pData,
u64 old_page_addr, u64 blk_addr)
{
int i, j;
u8 *buf = pData;
int wResult = PASS;
int wFoundInCache;
u64 page_addr;
u64 addr;
u64 old_blk_addr;
u16 page_offset;
nand_dbg_print(NAND_DBG_TRACE, "%s, Line %d, Function: %s\n",
__FILE__, __LINE__, __func__);
old_blk_addr = (u64)(old_page_addr >>
DeviceInfo.nBitsInBlockDataSize) * DeviceInfo.wBlockDataSize;
page_offset = (u16)(GLOB_u64_Remainder(old_page_addr, 2) >>
DeviceInfo.nBitsInPageDataSize);
for (i = 0; i < DeviceInfo.wPagesPerBlock; i += Cache.pages_per_item) {
page_addr = old_blk_addr + i * DeviceInfo.wPageDataSize;
if (i != page_offset) {
wFoundInCache = FAIL;
for (j = 0; j < CACHE_ITEM_NUM; j++) {
addr = Cache.array[j].address;
addr = FTL_Get_Physical_Block_Addr(addr) +
GLOB_u64_Remainder(addr, 2);
if ((addr >= page_addr) && addr <
(page_addr + Cache.cache_item_size)) {
wFoundInCache = PASS;
buf = Cache.array[j].buf;
Cache.array[j].changed = SET;
#if CMD_DMA
#if RESTORE_CACHE_ON_CDMA_CHAIN_FAILURE
int_cache[ftl_cmd_cnt].item = j;
int_cache[ftl_cmd_cnt].cache.address =
Cache.array[j].address;
int_cache[ftl_cmd_cnt].cache.changed =
Cache.array[j].changed;
#endif
#endif
break;
}
}
if (FAIL == wFoundInCache) {
if (ERR == FTL_Cache_Read_All(g_pTempBuf,
page_addr)) {
wResult = FAIL;
break;
}
buf = g_pTempBuf;
}
} else {
buf = pData;
}
if (FAIL == FTL_Cache_Write_All(buf,
blk_addr + (page_addr - old_blk_addr))) {
wResult = FAIL;
break;
}
}
return wResult;
}
/*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
* Function: FTL_Copy_Block
* Inputs: source block address
@ -2004,87 +1928,6 @@ static int search_l2_cache(u8 *buf, u64 logical_addr)
return ret;
}
/*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
* Function: FTL_Cache_Write_Back
* Inputs: pointer to data cached in sys memory
* address of free block in flash
* Outputs: PASS=0 / FAIL=1
* Description: writes all the pages of Cache Block to flash
*
*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&*/
static int FTL_Cache_Write_Back(u8 *pData, u64 blk_addr)
{
int i, j, iErase;
u64 old_page_addr, addr, phy_addr;
u32 *pbt = (u32 *)g_pBlockTable;
u32 lba;
nand_dbg_print(NAND_DBG_TRACE, "%s, Line %d, Function: %s\n",
__FILE__, __LINE__, __func__);
old_page_addr = FTL_Get_Physical_Block_Addr(blk_addr) +
GLOB_u64_Remainder(blk_addr, 2);
iErase = (FAIL == FTL_Replace_Block(blk_addr)) ? PASS : FAIL;
pbt[BLK_FROM_ADDR(blk_addr)] &= (~SPARE_BLOCK);
#if CMD_DMA
p_BTableChangesDelta = (struct BTableChangesDelta *)g_pBTDelta_Free;
g_pBTDelta_Free += sizeof(struct BTableChangesDelta);
p_BTableChangesDelta->ftl_cmd_cnt = ftl_cmd_cnt;
p_BTableChangesDelta->BT_Index = (u32)(blk_addr >>
DeviceInfo.nBitsInBlockDataSize);
p_BTableChangesDelta->BT_Entry_Value =
pbt[(u32)(blk_addr >> DeviceInfo.nBitsInBlockDataSize)];
p_BTableChangesDelta->ValidFields = 0x0C;
#endif
if (IN_PROGRESS_BLOCK_TABLE != g_cBlockTableStatus) {
g_cBlockTableStatus = IN_PROGRESS_BLOCK_TABLE;
FTL_Write_IN_Progress_Block_Table_Page();
}
for (i = 0; i < RETRY_TIMES; i++) {
if (PASS == iErase) {
phy_addr = FTL_Get_Physical_Block_Addr(blk_addr);
if (FAIL == GLOB_FTL_Block_Erase(phy_addr)) {
lba = BLK_FROM_ADDR(blk_addr);
MARK_BLOCK_AS_BAD(pbt[lba]);
i = RETRY_TIMES;
break;
}
}
for (j = 0; j < CACHE_ITEM_NUM; j++) {
addr = Cache.array[j].address;
if ((addr <= blk_addr) &&
((addr + Cache.cache_item_size) > blk_addr))
cache_block_to_write = j;
}
phy_addr = FTL_Get_Physical_Block_Addr(blk_addr);
if (PASS == FTL_Cache_Update_Block(pData,
old_page_addr, phy_addr)) {
cache_block_to_write = UNHIT_CACHE_ITEM;
break;
} else {
iErase = PASS;
}
}
if (i >= RETRY_TIMES) {
if (ERR == FTL_Flash_Error_Handle(pData,
old_page_addr, blk_addr))
return ERR;
else
return FAIL;
}
return PASS;
}
/*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
* Function: FTL_Cache_Write_Page
* Inputs: Pointer to buffer, page address, cache block number
@ -2370,159 +2213,6 @@ static int FTL_Write_Block_Table(int wForce)
return 1;
}
/******************************************************************
* Function: GLOB_FTL_Flash_Format
* Inputs: none
* Outputs: PASS
* Description: The block table stores bad block info, including MDF+
* blocks gone bad over the ages. Therefore, if we have a
* block table in place, then use it to scan for bad blocks
* If not, then scan for MDF.
* Now, a block table will only be found if spectra was already
* being used. For a fresh flash, we'll go thru scanning for
* MDF. If spectra was being used, then there is a chance that
* the MDF has been corrupted. Spectra avoids writing to the
* first 2 bytes of the spare area to all pages in a block. This
* covers all known flash devices. However, since flash
* manufacturers have no standard of where the MDF is stored,
* this cannot guarantee that the MDF is protected for future
* devices too. The initial scanning for the block table assures
* this. It is ok even if the block table is outdated, as all
* we're looking for are bad block markers.
* Use this when mounting a file system or starting a
* new flash.
*
*********************************************************************/
static int FTL_Format_Flash(u8 valid_block_table)
{
u32 i, j;
u32 *pbt = (u32 *)g_pBlockTable;
u32 tempNode;
int ret;
#if CMD_DMA
u32 *pbtStartingCopy = (u32 *)g_pBTStartingCopy;
if (ftl_cmd_cnt)
return FAIL;
#endif
if (FAIL == FTL_Check_Block_Table(FAIL))
valid_block_table = 0;
if (valid_block_table) {
u8 switched = 1;
u32 block, k;
k = DeviceInfo.wSpectraStartBlock;
while (switched && (k < DeviceInfo.wSpectraEndBlock)) {
switched = 0;
k++;
for (j = DeviceInfo.wSpectraStartBlock, i = 0;
j <= DeviceInfo.wSpectraEndBlock;
j++, i++) {
block = (pbt[i] & ~BAD_BLOCK) -
DeviceInfo.wSpectraStartBlock;
if (block != i) {
switched = 1;
tempNode = pbt[i];
pbt[i] = pbt[block];
pbt[block] = tempNode;
}
}
}
if ((k == DeviceInfo.wSpectraEndBlock) && switched)
valid_block_table = 0;
}
if (!valid_block_table) {
memset(g_pBlockTable, 0,
DeviceInfo.wDataBlockNum * sizeof(u32));
memset(g_pWearCounter, 0,
DeviceInfo.wDataBlockNum * sizeof(u8));
if (DeviceInfo.MLCDevice)
memset(g_pReadCounter, 0,
DeviceInfo.wDataBlockNum * sizeof(u16));
#if CMD_DMA
memset(g_pBTStartingCopy, 0,
DeviceInfo.wDataBlockNum * sizeof(u32));
memset(g_pWearCounterCopy, 0,
DeviceInfo.wDataBlockNum * sizeof(u8));
if (DeviceInfo.MLCDevice)
memset(g_pReadCounterCopy, 0,
DeviceInfo.wDataBlockNum * sizeof(u16));
#endif
for (j = DeviceInfo.wSpectraStartBlock, i = 0;
j <= DeviceInfo.wSpectraEndBlock;
j++, i++) {
if (GLOB_LLD_Get_Bad_Block((u32)j))
pbt[i] = (u32)(BAD_BLOCK | j);
}
}
nand_dbg_print(NAND_DBG_WARN, "Erasing all blocks in the NAND\n");
for (j = DeviceInfo.wSpectraStartBlock, i = 0;
j <= DeviceInfo.wSpectraEndBlock;
j++, i++) {
if ((pbt[i] & BAD_BLOCK) != BAD_BLOCK) {
ret = GLOB_LLD_Erase_Block(j);
if (FAIL == ret) {
pbt[i] = (u32)(j);
MARK_BLOCK_AS_BAD(pbt[i]);
nand_dbg_print(NAND_DBG_WARN,
"NAND Program fail in %s, Line %d, "
"Function: %s, new Bad Block %d generated!\n",
__FILE__, __LINE__, __func__, (int)j);
} else {
pbt[i] = (u32)(SPARE_BLOCK | j);
}
}
#if CMD_DMA
pbtStartingCopy[i] = pbt[i];
#endif
}
g_wBlockTableOffset = 0;
for (i = 0; (i <= (DeviceInfo.wSpectraEndBlock -
DeviceInfo.wSpectraStartBlock))
&& ((pbt[i] & BAD_BLOCK) == BAD_BLOCK); i++)
;
if (i > (DeviceInfo.wSpectraEndBlock - DeviceInfo.wSpectraStartBlock)) {
printk(KERN_ERR "All blocks bad!\n");
return FAIL;
} else {
g_wBlockTableIndex = pbt[i] & ~BAD_BLOCK;
if (i != BLOCK_TABLE_INDEX) {
tempNode = pbt[i];
pbt[i] = pbt[BLOCK_TABLE_INDEX];
pbt[BLOCK_TABLE_INDEX] = tempNode;
}
}
pbt[BLOCK_TABLE_INDEX] &= (~SPARE_BLOCK);
#if CMD_DMA
pbtStartingCopy[BLOCK_TABLE_INDEX] &= (~SPARE_BLOCK);
#endif
g_cBlockTableStatus = IN_PROGRESS_BLOCK_TABLE;
memset(g_pBTBlocks, 0xFF,
(1 + LAST_BT_ID - FIRST_BT_ID) * sizeof(u32));
g_pBTBlocks[FIRST_BT_ID-FIRST_BT_ID] = g_wBlockTableIndex;
FTL_Write_Block_Table(FAIL);
for (i = 0; i < CACHE_ITEM_NUM; i++) {
Cache.array[i].address = NAND_CACHE_INIT_ADDR;
Cache.array[i].use_cnt = 0;
Cache.array[i].changed = CLEAR;
}
#if (RESTORE_CACHE_ON_CDMA_CHAIN_FAILURE && CMD_DMA)
memcpy((void *)&cache_start_copy, (void *)&Cache,
sizeof(struct flash_cache_tag));
#endif
return PASS;
}
static int force_format_nand(void)
{
u32 i;
@ -3031,112 +2721,6 @@ static int FTL_Read_Block_Table(void)
return wResult;
}
/*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
* Function: FTL_Flash_Error_Handle
* Inputs: Pointer to data
* Page address
* Block address
* Outputs: PASS=0 / FAIL=1
* Description: It handles any error occured during Spectra operation
*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&*/
static int FTL_Flash_Error_Handle(u8 *pData, u64 old_page_addr,
u64 blk_addr)
{
u32 i;
int j;
u32 tmp_node, blk_node = BLK_FROM_ADDR(blk_addr);
u64 phy_addr;
int wErase = FAIL;
int wResult = FAIL;
u32 *pbt = (u32 *)g_pBlockTable;
nand_dbg_print(NAND_DBG_TRACE, "%s, Line %d, Function: %s\n",
__FILE__, __LINE__, __func__);
if (ERR == GLOB_FTL_Garbage_Collection())
return ERR;
do {
for (i = DeviceInfo.wSpectraEndBlock -
DeviceInfo.wSpectraStartBlock;
i > 0; i--) {
if (IS_SPARE_BLOCK(i)) {
tmp_node = (u32)(BAD_BLOCK |
pbt[blk_node]);
pbt[blk_node] = (u32)(pbt[i] &
(~SPARE_BLOCK));
pbt[i] = tmp_node;
#if CMD_DMA
p_BTableChangesDelta =
(struct BTableChangesDelta *)
g_pBTDelta_Free;
g_pBTDelta_Free +=
sizeof(struct BTableChangesDelta);
p_BTableChangesDelta->ftl_cmd_cnt =
ftl_cmd_cnt;
p_BTableChangesDelta->BT_Index =
blk_node;
p_BTableChangesDelta->BT_Entry_Value =
pbt[blk_node];
p_BTableChangesDelta->ValidFields = 0x0C;
p_BTableChangesDelta =
(struct BTableChangesDelta *)
g_pBTDelta_Free;
g_pBTDelta_Free +=
sizeof(struct BTableChangesDelta);
p_BTableChangesDelta->ftl_cmd_cnt =
ftl_cmd_cnt;
p_BTableChangesDelta->BT_Index = i;
p_BTableChangesDelta->BT_Entry_Value = pbt[i];
p_BTableChangesDelta->ValidFields = 0x0C;
#endif
wResult = PASS;
break;
}
}
if (FAIL == wResult) {
if (FAIL == GLOB_FTL_Garbage_Collection())
break;
else
continue;
}
if (IN_PROGRESS_BLOCK_TABLE != g_cBlockTableStatus) {
g_cBlockTableStatus = IN_PROGRESS_BLOCK_TABLE;
FTL_Write_IN_Progress_Block_Table_Page();
}
phy_addr = FTL_Get_Physical_Block_Addr(blk_addr);
for (j = 0; j < RETRY_TIMES; j++) {
if (PASS == wErase) {
if (FAIL == GLOB_FTL_Block_Erase(phy_addr)) {
MARK_BLOCK_AS_BAD(pbt[blk_node]);
break;
}
}
if (PASS == FTL_Cache_Update_Block(pData,
old_page_addr,
phy_addr)) {
wResult = PASS;
break;
} else {
wResult = FAIL;
wErase = PASS;
}
}
} while (FAIL == wResult);
FTL_Write_Block_Table(FAIL);
return wResult;
}
/*&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
* Function: FTL_Get_Page_Num
* Inputs: Size in bytes