static UINT32 assign_new_write_vpn(UINT32 const bank)
{
UINT32 write_vpn;
UINT32 vblock;
write_vpn = get_cur_write_vpn(bank);
vblock = write_vpn / PAGES_PER_BLK;
// NOTE: if next new write page's offset is
// the last page offset of vblock (i.e. PAGES_PER_BLK - 1),
if ((write_vpn % PAGES_PER_BLK) == (PAGES_PER_BLK - 2))
{
// then, because of the flash controller limitation
// (prohibit accessing a spare area (i.e. OOB)),
// thus, we persistenly write a lpn list into last page of vblock.
mem_copy(TEMP_BUF(bank), g_misc_meta[bank].lpn_list_of_cur_vblock, sizeof(UINT32) * PAGES_PER_BLK);
// fix minor bug
misc_w++;
nand_page_ptprogram(bank, vblock, PAGES_PER_BLK - 1, 0,
((sizeof(UINT32) * PAGES_PER_BLK + BYTES_PER_SECTOR - 1 ) / BYTES_PER_SECTOR),
TEMP_BUF(bank));
mem_set_sram(g_misc_meta[bank].lpn_list_of_cur_vblock, 0x00000000, sizeof(UINT32) * PAGES_PER_BLK);
inc_full_blk_cnt(bank);
// do garbage collection if necessary
if (is_full_all_blks(bank))
{
GC:
garbage_collection(bank);
return get_cur_write_vpn(bank);
}
do
{
vblock++;
if(vblock == VBLKS_PER_BANK)
{
uart_printf(" vblock == VBLKS_PER_BANK");
goto GC;
}
}while (get_vcount(bank, vblock) == VC_MAX);
}
// write page -> next block
if (vblock != (write_vpn / PAGES_PER_BLK))
{
write_vpn = vblock * PAGES_PER_BLK;
}
else
{
write_vpn++;
}
set_new_write_vpn(bank, write_vpn);
return write_vpn;
}
static void overwriteChunkOldInOwLog(UINT32 chunkAddr)
{
//uart_print_level_1("22 ");
uart_print("overwriteChunkOldInOwLog\r\n");
UINT32 nSectsToWrite = (((sectOffset_ % SECTORS_PER_CHUNK) + remainingSects_) < SECTORS_PER_CHUNK) ? remainingSects_ :
(SECTORS_PER_CHUNK - (sectOffset_ % SECTORS_PER_CHUNK));
UINT32 bank = ChunkToBank(chunkAddr);
UINT32 lbn = ChunkToLbn(chunkAddr);
UINT32 vbn = get_log_vbn(bank, lbn);
UINT32 pageOffset = ChunkToPageOffset(chunkAddr);
if (readOwCounter(bank, lbn, pageOffset) < OwLimit)
{ // Can overwrite in place
UINT32 sectOffset = ChunkToSectOffset(chunkAddr) + (sectOffset_ % SECTORS_PER_CHUNK);
//UINT32 src = WR_BUF_PTR(g_ftl_write_buf_id) + (sectOffset_ * BYTES_PER_SECTOR) - (sectOffset * BYTES_PER_SECTOR); // startBuf + srcOffset - dstOffset
if (lastBankUsingFtlBuf1 != INVALID)
{
waitBusyBank(lastBankUsingFtlBuf1);
}
mem_copy(FTL_BUF(1)+(sectOffset_*BYTES_PER_SECTOR), WR_BUF_PTR(g_ftl_write_buf_id) + (sectOffset_*BYTES_PER_SECTOR), nSectsToWrite*BYTES_PER_SECTOR);
UINT32 src = FTL_BUF(1) + (sectOffset_ * BYTES_PER_SECTOR) - (sectOffset * BYTES_PER_SECTOR); // startBuf + srcOffset - dstOffset
lastBankUsingFtlBuf1 = bank;
nand_page_ptprogram(bank, vbn, pageOffset, sectOffset, nSectsToWrite, src, RETURN_ON_ISSUE);
increaseOwCounter(bank, lbn, pageOffset);
}
else
{ // Need a new page
if (nSectsToWrite == SECTORS_PER_CHUNK)
{ // Write chunk in ow log and decrease valid chunks in previous ow blk
decrementValidChunks(&heapDataOverwrite, bank, lbn);
overwriteCompleteChunkNew();
}
else
{ // Must read old chunk and update in ow log
decrementValidChunks(&heapDataOverwrite, bank, lbn);
overwritePartialChunkWhenOldChunkIsInExhaustedOWLog(nSectsToWrite, chunkAddr);
}
updateOwDramBufMetadata();
updateOwChunkPtr();
}
#if MeasureOwEfficiency
write_dram_32(OwEffBuf(bank_, ChunkToLbn(chunkAddr)), read_dram_32(OwEffBuf(bank_, ChunkToLbn(chunkAddr))) + nSectsToWrite);
#endif
sectOffset_ += nSectsToWrite;
remainingSects_ -= nSectsToWrite;
}
void increaseLpnColdBlk (UINT32 const bank, LogCtrlBlock * ctrlBlock)
{
uart_print("increaseLpnColdBlk\r\n");
UINT32 lpn = ctrlBlock[bank].logLpn;
if (LogPageToOffset(lpn) == UsedPagesPerLogBlk-1)
{ // current rw log block is full
UINT32 lbn = get_log_lbn(lpn);
nand_page_ptprogram(bank,
get_log_vbn(bank, lbn),
PAGES_PER_BLK - 1,
0,
(CHUNK_ADDR_BYTES * CHUNKS_PER_LOG_BLK + BYTES_PER_SECTOR - 1) / BYTES_PER_SECTOR,
ctrlBlock[bank].lpnsListAddr,
RETURN_WHEN_DONE);
mem_set_dram(ctrlBlock[bank].lpnsListAddr, INVALID, (CHUNKS_PER_BLK * CHUNK_ADDR_BYTES));
insertBlkInHeap(&heapDataCold, bank, lbn);
#if CanReuseBlksForColdData == 0
lbn = cleanListPop(&cleanListDataWrite, bank); // Now the hybrid approach can pop from the cleanList
ctrlBlock[bank].logLpn = lbn * PAGES_PER_BLK;
while(cleanListSize(&cleanListDataWrite, bank) < 2)
{
#if PrintStats
uart_print_level_1("GCCOLD\r\n");
#endif
garbageCollectLog(bank);
}
#else
findNewLpnForColdLog(bank, ctrlBlock);
#endif
}
else
{
ctrlBlock[bank].logLpn = lpn+1;
}
uart_print("increaseLpnColdBlk new lpn "); uart_print_int(ctrlBlock[bank].logLpn); uart_print("\r\n");
}
// logging misc + vcount metadata
static void logging_misc_metadata(void)
{
UINT32 misc_meta_bytes = NUM_MISC_META_SECT * BYTES_PER_SECTOR; // per bank
UINT32 vcount_addr = VCOUNT_ADDR;
UINT32 vcount_bytes = NUM_VCOUNT_SECT * BYTES_PER_SECTOR; // per bank
UINT32 vcount_boundary = VCOUNT_ADDR + VCOUNT_BYTES; // entire vcount data
UINT32 bank;
flash_finish();
for (bank = 0; bank < NUM_BANKS; bank++)
{
inc_miscblk_vpn(bank);
// note: if misc. meta block is full, just erase old block & write offset #0
if ((get_miscblk_vpn(bank) / PAGES_PER_BLK) != MISCBLK_VBN)
{
nand_block_erase(bank, MISCBLK_VBN);
set_miscblk_vpn(bank, MISCBLK_VBN * PAGES_PER_BLK); // vpn = 128
}
// copy misc. metadata to FTL buffer
mem_copy(FTL_BUF(bank), &g_misc_meta[bank], misc_meta_bytes);
// copy vcount metadata to FTL buffer
if (vcount_addr <= vcount_boundary)
{
mem_copy(FTL_BUF(bank) + misc_meta_bytes, vcount_addr, vcount_bytes);
vcount_addr += vcount_bytes;
}
}
// logging the misc. metadata to nand flash
for (bank = 0; bank < NUM_BANKS; bank++)
{
nand_page_ptprogram(bank,
get_miscblk_vpn(bank) / PAGES_PER_BLK,
get_miscblk_vpn(bank) % PAGES_PER_BLK,
0,
NUM_MISC_META_SECT + NUM_VCOUNT_SECT,
FTL_BUF(bank));
}
flash_finish();
}
void logging_misc_meta()
{
UINT32 bank;
flash_finish();
for(bank = 0; bank < NUM_BANKS; bank++)
{
g_misc_meta[bank].cur_miscblk_vpn++;
if(g_misc_meta[bank].cur_miscblk_vpn / PAGES_PER_VBLK != 1 )
{
nand_block_erase(bank,1);
g_misc_meta[bank].cur_miscblk_vpn = PAGES_PER_VBLK;
}
mem_copy(FTL_BUF_ADDR , &(g_misc_meta[bank]), sizeof(misc_metadata));
nand_page_ptprogram(bank, 1,
g_misc_meta[bank].cur_miscblk_vpn % PAGES_PER_VBLK,
0,
((sizeof(misc_metadata) + BYTES_PER_SECTOR -1 ) / BYTES_PER_SECTOR),
FTL_BUF_ADDR );
}
flash_finish();
}
void increaseLpnHotBlkFirstUsage (UINT32 const bank, LogCtrlBlock * ctrlBlock)
{
uart_print("increaseLpnHotBlkFirstUsage\r\n");
UINT32 lpn = ctrlBlock[bank].logLpn;
UINT32 pageOffset = LogPageToOffset(lpn);
if (pageOffset == 123)
{ // current rw log block is full. Write lpns list in the highest low page (125)
uart_print("Blk full\r\n");
UINT32 lbn = get_log_lbn(lpn);
nand_page_ptprogram(bank,
get_log_vbn(bank, lbn),
125,
0,
(CHUNK_ADDR_BYTES * CHUNKS_PER_LOG_BLK + BYTES_PER_SECTOR - 1) / BYTES_PER_SECTOR,
ctrlBlock[bank].lpnsListAddr,
RETURN_WHEN_DONE);
mem_set_dram(ctrlBlock[bank].lpnsListAddr, INVALID, (CHUNKS_PER_BLK * CHUNK_ADDR_BYTES));
insertBlkInHeap(&heapDataFirstUsage, bank, lbn);
findNewLpnForHotLog(bank, ctrlBlock);
}
else
{
if(pageOffset == 0)
{
ctrlBlock[bank].logLpn = lpn+1;
}
else
{
ctrlBlock[bank].logLpn = lpn+2;
}
}
}
void increaseLpnHotBlkSecondUsage (UINT32 const bank, LogCtrlBlock * ctrlBlock)
{
uart_print("increaseLpnHotBlkSecondUsage\r\n");
UINT32 lpn = ctrlBlock[bank].logLpn;
UINT32 pageOffset = LogPageToOffset(lpn);
if (pageOffset == UsedPagesPerLogBlk-1)
{
uart_print("Blk full\r\n");
UINT32 lbn = LogPageToLogBlk(lpn);
UINT32 vbn = get_log_vbn(bank, lbn);
nand_page_ptprogram(bank,
vbn,
PAGES_PER_BLK - 1,
0,
(CHUNK_ADDR_BYTES * CHUNKS_PER_LOG_BLK + BYTES_PER_SECTOR - 1) / BYTES_PER_SECTOR,
ctrlBlock[bank].lpnsListAddr,
RETURN_WHEN_DONE); // write lpns list to the last high page
mem_set_dram(ctrlBlock[bank].lpnsListAddr, INVALID, (CHUNKS_PER_BLK * CHUNK_ADDR_BYTES));
insertBlkInHeap(&heapDataSecondUsage, bank, lbn);
findNewLpnForHotLog(bank, ctrlBlock);
}
else
{
lpn++;
ctrlBlock[bank].logLpn = lpn;
pageOffset++;
//uart_print_level_1("increaseLpnHotBlkSecondUsage ");
//uart_print_level_1_int(bank);
//uart_print_level_1(" ");
//uart_print_level_1_int(pageOffset);
//uart_print_level_1("\r\n");
if (pageOffset % 2 == 1)
{ // Next page is low
if (ctrlBlock[bank].nextLowPageOffset == pageOffset)
{ // The page tested positively
// Here we don't care if the page has already been prefetched because this can be done asyncronously
ctrlBlock[bank].updateChunkPtr = updateChunkPtrRecycledPage;
ctrlBlock[bank].useRecycledPage = TRUE;
}
else
{
if (pageOffset == 1)
{ // Special case: pageOffset 1 comes immediately after another low page, so there was no time for precaching
if(canReuseLowPage(bank, pageOffset, ctrlBlock))
{
ctrlBlock[bank].updateChunkPtr = updateChunkPtrRecycledPage;
ctrlBlock[bank].useRecycledPage = TRUE;
ctrlBlock[bank].precacheDone = FALSE;
ctrlBlock[bank].nextLowPageOffset = pageOffset;
return;
}
}
// Skip this page because it tested negatively
// Set the next page to the next high page
ctrlBlock[bank].updateChunkPtr = updateChunkPtr;
ctrlBlock[bank].useRecycledPage = FALSE;
lpn++;
pageOffset++;
ctrlBlock[bank].logLpn = lpn;
// Already test the next low page
pageOffset++;
if (pageOffset < UsedPagesPerLogBlk-1)
{
if(canReuseLowPage(bank, pageOffset, ctrlBlock))
{
ctrlBlock[bank].precacheDone = FALSE;
ctrlBlock[bank].nextLowPageOffset = pageOffset;
}
else
{
ctrlBlock[bank].precacheDone = FALSE;
ctrlBlock[bank].nextLowPageOffset = INVALID;
}
}
}
}
else
{ // Next page is high
ctrlBlock[bank].updateChunkPtr = updateChunkPtr;
ctrlBlock[bank].useRecycledPage = FALSE;
// Already test the next low page
pageOffset++;
if (pageOffset < UsedPagesPerLogBlk-1)
{
if(canReuseLowPage(bank, pageOffset, ctrlBlock))
{
ctrlBlock[bank].precacheDone = FALSE;
ctrlBlock[bank].nextLowPageOffset = pageOffset;
}
else
{
ctrlBlock[bank].precacheDone = FALSE;
ctrlBlock[bank].nextLowPageOffset = INVALID;
}
}
else
{
ctrlBlock[bank].precacheDone = FALSE;
ctrlBlock[bank].nextLowPageOffset = INVALID;
}
}
}
uart_print("New logLpn "); uart_print_int(ctrlBlock[bank].logLpn);
uart_print(" offset "); uart_print_int(LogPageToOffset(ctrlBlock[bank].logLpn)); uart_print("\r\n");
}
void initLog()
{
uart_print("Initializing Write Log Space...\r\n");
uart_print("Initializing clean list...");
//testCleanList();
cleanListInit(&cleanListDataWrite, CleanList(0), LOG_BLK_PER_BANK);
uart_print("done\r\n");
//int off = __builtin_offsetof(LogCtrlBlock, increaseLpn);
for(int bank=0; bank<NUM_BANKS; bank++)
{
adaptiveStepDown[bank] = initStepDown;
adaptiveStepUp[bank] = initStepUp;
nStepUps[bank] = 0;
nStepDowns[bank] = 0;
for(int lbn=0; lbn<LOG_BLK_PER_BANK; lbn++)
{
cleanListPush(&cleanListDataWrite, bank, lbn);
}
UINT32 lbn = cleanListPop(&cleanListDataWrite, bank);
hotLogCtrl[bank] = (LogCtrlBlock)
{
.logLpn = lbn * PAGES_PER_BLK,
.lpnsListAddr = LPNS_BUF_BASE_1(bank),
.logBufferAddr = HOT_LOG_BUF(bank),
.chunkPtr = 0,
.increaseLpn=increaseLpnHotBlkFirstUsage,
.updateChunkPtr=updateChunkPtr,
.nextLowPageOffset=INVALID,
.allChunksInLogAreValid = TRUE,
.useRecycledPage=FALSE,
.precacheDone=TRUE,
};
for(int chunk=0; chunk<CHUNKS_PER_PAGE; ++chunk)
{
hotLogCtrl[bank].dataLpn[chunk] = INVALID;
hotLogCtrl[bank].chunkIdx[chunk] = INVALID;
}
lbn = cleanListPop(&cleanListDataWrite, bank);
coldLogCtrl[bank] = (LogCtrlBlock)
{
.logLpn = lbn * PAGES_PER_BLK,
.lpnsListAddr = LPNS_BUF_BASE_2(bank),
.logBufferAddr = COLD_LOG_BUF(bank),
.chunkPtr = 0,
.increaseLpn=increaseLpnColdBlk,
.updateChunkPtr=updateChunkPtr,
.nextLowPageOffset=INVALID,
.allChunksInLogAreValid = TRUE,
.useRecycledPage=FALSE,
.precacheDone=TRUE,
};
for(int chunk=0; chunk<CHUNKS_PER_PAGE; ++chunk)
{
coldLogCtrl[bank].dataLpn[chunk] = INVALID;
coldLogCtrl[bank].chunkIdx[chunk] = INVALID;
}
nValidChunksFromHeap[bank] = INVALID;
}
}
static void findNewLpnForColdLog(const UINT32 bank, LogCtrlBlock * ctrlBlock)
{
uart_print("findNewLpnForColdLog bank "); uart_print_int(bank);
if (cleanListSize(&cleanListDataWrite, bank) > 2)
{
uart_print(" use clean blk\r\n");
uart_print("cleanList size = "); uart_print_int(cleanListSize(&cleanListDataWrite, bank)); uart_print("\r\n");
UINT32 lbn = cleanListPop(&cleanListDataWrite, bank);
ctrlBlock[bank].logLpn = lbn * PAGES_PER_BLK;
ctrlBlock[bank].increaseLpn = increaseLpnColdBlk;
}
else
{
if (reuseCondition(bank))
{
#if PrintStats
uart_print_level_1("REUSECOLD\r\n");
#endif
uart_print(" second usage\r\n");
UINT32 lbn = getVictim(&heapDataFirstUsage, bank);
UINT32 nValidChunks = getVictimValidPagesNumber(&heapDataFirstUsage, bank);
resetValidChunksAndRemove(&heapDataFirstUsage, bank, lbn, CHUNKS_PER_LOG_BLK_FIRST_USAGE);
resetValidChunksAndRemove(&heapDataSecondUsage, bank, lbn, CHUNKS_PER_LOG_BLK_SECOND_USAGE);
resetValidChunksAndRemove(&heapDataCold, bank, lbn, nValidChunks);
ctrlBlock[bank].logLpn = (lbn * PAGES_PER_BLK) + 2;
ctrlBlock[bank].increaseLpn = increaseLpnColdBlkReused;
nand_page_ptread(bank,
get_log_vbn(bank, lbn),
125,
0,
(CHUNK_ADDR_BYTES * CHUNKS_PER_LOG_BLK + BYTES_PER_SECTOR - 1) / BYTES_PER_SECTOR,
ctrlBlock[bank].lpnsListAddr,
RETURN_WHEN_DONE); // Read the lpns list from the max low page (125) where it was previously written by incrementLpnHotBlkFirstUsage
}
else
{
uart_print(" get new block\r\n");
UINT32 lbn = cleanListPop(&cleanListDataWrite, bank);
ctrlBlock[bank].logLpn = lbn * PAGES_PER_BLK;
ctrlBlock[bank].increaseLpn = increaseLpnColdBlk;
while(cleanListSize(&cleanListDataWrite, bank) < 2)
{
#if PrintStats
uart_print_level_1("GCCOLD\r\n");
#endif
garbageCollectLog(bank);
}
}
}
}
void increaseLpnColdBlkReused (UINT32 const bank, LogCtrlBlock * ctrlBlock)
{
uart_print("increaseLpnColdBlkReused bank "); uart_print_int(bank); uart_print("\r\n");
UINT32 lpn = ctrlBlock[bank].logLpn;
UINT32 pageOffset = LogPageToOffset(lpn);
if (pageOffset == UsedPagesPerLogBlk-1)
{
UINT32 lbn = get_log_lbn(lpn);
nand_page_ptprogram(bank,
get_log_vbn(bank, lbn),
PAGES_PER_BLK - 1,
0,
(CHUNK_ADDR_BYTES * CHUNKS_PER_LOG_BLK + BYTES_PER_SECTOR - 1) / BYTES_PER_SECTOR,
ctrlBlock[bank].lpnsListAddr,
RETURN_WHEN_DONE);
mem_set_dram(ctrlBlock[bank].lpnsListAddr, INVALID, (CHUNKS_PER_BLK * CHUNK_ADDR_BYTES));
insertBlkInHeap(&heapDataCold, bank, lbn);
findNewLpnForColdLog(bank, ctrlBlock);
}
else
{
ctrlBlock[bank].logLpn = lpn+2;
}
uart_print("increaseLpnColdBlkReused (bank="); uart_print_int(bank); uart_print(") new lpn "); uart_print_int(ctrlBlock[bank].logLpn); uart_print("\r\n");
}
static void logging_pmap_table(void)
{
UINT32 pmap_addr = PAGE_MAP_ADDR;
UINT32 pmap_bytes = BYTES_PER_PAGE; // per bank
UINT32 mapblk_vpn;
UINT32 bank;
UINT32 pmap_boundary = PAGE_MAP_ADDR + PAGE_MAP_BYTES;
BOOL32 finished = FALSE;
for (UINT32 mapblk_lbn = 0; mapblk_lbn < MAPBLKS_PER_BANK; mapblk_lbn++)
{
flash_finish();
for (bank = 0; bank < NUM_BANKS; bank++)
{
if (finished)
{
break;
}
else if (pmap_addr >= pmap_boundary)
{
finished = TRUE;
break;
}
else if (pmap_addr + BYTES_PER_PAGE >= pmap_boundary)
{
finished = TRUE;
pmap_bytes = (pmap_boundary - pmap_addr + BYTES_PER_SECTOR - 1) / BYTES_PER_SECTOR * BYTES_PER_SECTOR ;
}
inc_mapblk_vpn(bank, mapblk_lbn);
mapblk_vpn = get_mapblk_vpn(bank, mapblk_lbn);
// note: if there is no free page, then erase old map block first.
if ((mapblk_vpn % PAGES_PER_BLK) == 0)
{
// erase full map block
nand_block_erase(bank, (mapblk_vpn - 1) / PAGES_PER_BLK);
// next vpn of mapblk is offset #0
set_mapblk_vpn(bank, mapblk_lbn, ((mapblk_vpn - 1) / PAGES_PER_BLK) * PAGES_PER_BLK);
mapblk_vpn = get_mapblk_vpn(bank, mapblk_lbn);
}
// copy the page mapping table to FTL buffer
mem_copy(FTL_BUF(bank), pmap_addr, pmap_bytes);
// logging update page mapping table into map_block
nand_page_ptprogram(bank,
mapblk_vpn / PAGES_PER_BLK,
mapblk_vpn % PAGES_PER_BLK,
0,
pmap_bytes / BYTES_PER_SECTOR,
FTL_BUF(bank));
pmap_addr += pmap_bytes;
}
if (finished)
{
break;
}
}
flash_finish();
}
