NTSTATUS HookModuleInit(PDRIVER_OBJECT DriverObject, PVOID Context)
{
NTSTATUS status = STATUS_UNSUCCESSFUL;
DEBUG_ENTER_FUNCTION("DriverObject=0x%p; Context=0x%p", DriverObject, Context);
UNREFERENCED_PARAMETER(DriverObject);
UNREFERENCED_PARAMETER(Context);
KeInitializeSpinLock(&_driverValidationTableLock);
status = HashTableCreate(httNoSynchronization, 37, _HashFunction, _DriverValidationCompareFunction, NULL, &_driverValidationTable);
if (NT_SUCCESS(status)) {
KeInitializeSpinLock(&_deviceValidationTableLock);
status = HashTableCreate(httNoSynchronization, 37, _HashFunction, _DeviceValidationCompareFunction, NULL, &_deviceValidationTable);
if (NT_SUCCESS(status)) {
KeInitializeSpinLock(&_driverTableLock);
status = HashTableCreate(httNoSynchronization, 37, _HashFunction, _DriverCompareFunction, _DriverFreeFunction, &_driverTable);
if (!NT_SUCCESS(status))
HashTableDestroy(_deviceValidationTable);
}
if (!NT_SUCCESS(status))
HashTableDestroy(_driverValidationTable);
}
DEBUG_EXIT_FUNCTION("0x%x", status);
return status;
}
/*
* Resizes a HashTable to have 'newsize' buckets.
* This is called automatically when adding or removing items so that the
* hash table keeps at a sensible scale.
*
* FIXME: Halving the size of the hash table is simply a matter of coaelescing
* every other bucket. Instead we currently rehash (which is slower).
* Doubling the size of the hash table currently requires rehashing, but this
* too could be optimised by storing the full 32-bit hash of the key along
* with the key itself. This then means that it's just a matter of seeing what
* the next significant bit is. It's a memory vs speed tradeoff though and
* re-hashing is pretty quick.
*
* Returns 0 for success
* -1 for failure
*/
int HashTableResize(HashTable *h, int newsize) {
HashTable *h2;
int i;
/* fprintf(stderr, "Resizing to %d\n", newsize); */
/* Create a new hash table and rehash everything into it */
h2 = HashTableCreate(newsize, h->options);
for (i = 0; i < h->nbuckets; i++) {
HashItem *hi, *next;
for (hi = h->bucket[i]; hi; hi = next) {
uint64_t hv = hash64(h2->options & HASH_FUNC_MASK,
(uint8_t *)hi->key, hi->key_len) & h2->mask;
next = hi->next;
hi->next = h2->bucket[hv];
h2->bucket[hv] = hi;
}
}
/* Swap the links over & free */
free(h->bucket);
h->bucket = h2->bucket;
h->nbuckets = h2->nbuckets;
h->mask = h2->mask;
free(h2);
return 0;
}
/*
* Initialise results structure
*/
chksum_results_t *chksum_init_results(HASH_TYPE hash)
{
chksum_results_t *results = malloc(sizeof(chksum_results_t));
init_digest_line(hash, &(results->all));
results->rgHash = HashTableCreate(0, HASH_DYNAMIC_SIZE | HASH_FUNC_JENKINS);
return results;
}
HashTable *load_map(char *fn) {
HashTable *h = HashTableCreate(65536, HASH_DYNAMIC_SIZE | HASH_POOL_ITEMS);
FILE *fp;
char line[8192];
if (NULL == (fp = fopen(fn, "r"))) {
perror(fn);
return NULL;
}
while(fgets(line, 8192, fp)) {
char *cp, *from, *to;
HashData hd;
for (from = cp = line; *cp && !isspace(*cp); cp++);
if (!*cp) {
fprintf(stderr, "Malformed line '%s'\n", line);
return NULL;
}
*cp++ = 0;
for (to = cp; isprint(*cp); cp++);
*cp++ = 0;
hd.p = strdup(to);
if (!HashTableAdd(h, from, strlen(from), hd, NULL))
return NULL;
}
close(fp);
return h;
}
static void createHashTables( void )
//**********************************
{
SymbolToTargetTable = HashTableCreate( SYMBOL_TO_TARGET_TABLE_SIZE, HASH_NUMBER, numberCmp );
if( !SymbolToTargetTable ) {
SysError( ERR_OUT_OF_MEM, false );
}
SymbolToExportTable = HashTableCreate( SYMBOL_TO_EXPORT_TABLE_SIZE, HASH_NUMBER, numberCmp );
if( !SymbolToExportTable ) {
SysError( ERR_OUT_OF_MEM, false );
}
SectionToSegmentTable = HashTableCreate( SECTION_TO_SEGMENT_TABLE_SIZE, HASH_NUMBER, numberCmp );
if( !SectionToSegmentTable ) {
SysError( ERR_OUT_OF_MEM, false );
}
}
NTSTATUS HandleTableCreate(EHashTableType HandleTableType, CHANDLE_TABLE_HANDLE_CREATED *HandleCreateProcedure, CHANDLE_TABLE_HANDLE_DELETED *HandleDeleteProcedure, CHANDLE_TABLE_HANDLE_TRANSLATED *HandleTranslateProcedure, PCHANDLE_TABLE *HandleTable)
{
POOL_TYPE poolType = (HandleTableType == httPassiveLevel) ? PagedPool : NonPagedPool;
PCHANDLE_TABLE tmpHandleTable = NULL;
NTSTATUS status = STATUS_UNSUCCESSFUL;
DEBUG_ENTER_FUNCTION("HandleTableType=%u; HandleCreateProcedure=0x%p; HandleDeleteProcedure=0x%p; HandleTranslateProcedure=0x%p; HandleTable=0x%p", HandleTableType, HandleCreateProcedure, HandleDeleteProcedure, HandleTranslateProcedure, HandleTable);
tmpHandleTable = (PCHANDLE_TABLE)HeapMemoryAllocNonPaged(sizeof(CHANDLE_TABLE));
if (tmpHandleTable != NULL) {
tmpHandleTable->NextFreeHandle = 1;
tmpHandleTable->HandleTableType = HandleTableType;
tmpHandleTable->PoolType = poolType;
tmpHandleTable->HandleCreateProcedure = HandleCreateProcedure;
tmpHandleTable->HandleDeleteProcedure = HandleDeleteProcedure;
tmpHandleTable->HandleTranslateProcedure = HandleTranslateProcedure;
switch (tmpHandleTable->HandleTableType) {
case httPassiveLevel:
status = ExInitializeResourceLite(&tmpHandleTable->LockP);
break;
case httDispatchLevel:
KeInitializeSpinLock(&tmpHandleTable->LockD);
tmpHandleTable->ExclusiveLocker = NULL;
status = STATUS_SUCCESS;
break;
case httNoSynchronization:
status = STATUS_SUCCESS;
break;
default:
status = STATUS_NOT_SUPPORTED;
break;
}
if (NT_SUCCESS(status)) {
status = HashTableCreate(httNoSynchronization, 37, _HashFunction, _CompareFunction, _FreeFunction, &tmpHandleTable->HashTable);
if (NT_SUCCESS(status))
*HandleTable = tmpHandleTable;
if (!NT_SUCCESS(status)) {
switch (tmpHandleTable->HandleTableType) {
case httPassiveLevel:
ExDeleteResourceLite(&tmpHandleTable->LockP);
break;
case httDispatchLevel:
break;
case httNoSynchronization:
break;
default:
break;
}
}
}
if (!NT_SUCCESS(status))
HeapMemoryFree(tmpHandleTable);
} else status = STATUS_INSUFFICIENT_RESOURCES;
DEBUG_EXIT_FUNCTION("0x%x, *HandleTable=0x%p", status, *HandleTable);
return status;
}
/*
* Removes some or all tags from some or all contigs.
* If the contig list or tag list is blank it implies all contigs or all tags.
*
* Returns 0 on success
* -1 on failure
*/
int delete_tags(GapIO *io, int ncontigs, contig_list_t *contigs,
char *tag_list, int verbose) {
HashTable *h = NULL;
int ret = 0;
/* Hash tag types */
if (tag_list && *tag_list) {
int i;
if (SetActiveTags(tag_list) == -1) {
return -1;
}
h = HashTableCreate(32, 0);
for (i = 0; i < number_of_active_tags; i++) {
HashData hd;
hd.i = 0;
HashTableAdd(h, active_tag_types[i], 4, hd, NULL);
}
}
/* Iterate over contig list or all contigs */
if (verbose)
vfuncheader("Delete Tags");
if (ncontigs) {
int i;
for (i = 0; i < ncontigs; i++) {
contig_t *c = cache_search(io, GT_Contig, contigs[i].contig);
vmessage("Scanning contig %d of %d (%s)\n",
i+1, ncontigs, c->name);
ret |= delete_tag_single_contig(io, contigs[i].contig, h, verbose);
UpdateTextOutput();
cache_flush(io);
}
} else {
int i;
tg_rec *order = ArrayBase(tg_rec, io->contig_order);
for (i = 0; i < NumContigs(io); i++) {
contig_t *c = cache_search(io, GT_Contig, order[i]);
vmessage("Scanning contig %d of %d (%s)\n",
i+1, NumContigs(io), c->name);
ret |= delete_tag_single_contig(io, order[i], h, verbose);
UpdateTextOutput();
cache_flush(io);
}
}
SetActiveTags("");
if (h)
HashTableDestroy(h, 0);
return ret;
}
static return_val createHashTables( void )
{
HandleToSectionTable = HashTableCreate( HANDLE_TO_SECTION_TABLE_SIZE, HASH_NUMBER, NumberCmp );
if( HandleToSectionTable ) {
HandleToLabelListTable = HashTableCreate( HANDLE_TO_LIST_TABLE_SIZE, HASH_NUMBER, NumberCmp );
if( HandleToLabelListTable ) {
HandleToRefListTable = HashTableCreate( HANDLE_TO_LIST_TABLE_SIZE, HASH_NUMBER, NumberCmp );
if( HandleToRefListTable ) {
SymbolToLabelTable = HashTableCreate( SYMBOL_TO_LABEL_TABLE_SIZE, HASH_NUMBER, NumberCmp );
if( SymbolToLabelTable ) {
NameRecognitionTable = HashTableCreate( RECOGNITION_TABLE_SIZE, HASH_STRING, (hash_table_comparison_func) stricmp );
if( !NameRecognitionTable ) {
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToLabelListTable );
HashTableFree( HandleToRefListTable );
HashTableFree( SymbolToLabelTable );
return( OUT_OF_MEMORY );
}
} else {
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToLabelListTable );
HashTableFree( HandleToRefListTable );
return( OUT_OF_MEMORY );
}
} else {
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToLabelListTable );
return( OUT_OF_MEMORY );
}
} else {
HashTableFree( HandleToSectionTable );
return( OUT_OF_MEMORY );
}
} else {
return( OUT_OF_MEMORY );
}
return( OKAY );
}
static return_val createHashTables( void )
{
HandleToSectionTable = HashTableCreate( HANDLE_TO_SECTION_TABLE_SIZE, HASH_HANDLE );
if( HandleToSectionTable != NULL ) {
HandleToLabelListTable = HashTableCreate( HANDLE_TO_LIST_TABLE_SIZE, HASH_HANDLE );
if( HandleToLabelListTable != NULL ) {
HandleToRefListTable = HashTableCreate( HANDLE_TO_LIST_TABLE_SIZE, HASH_HANDLE );
if( HandleToRefListTable != NULL ) {
SymbolToLabelTable = HashTableCreate( SYMBOL_TO_LABEL_TABLE_SIZE, HASH_HANDLE );
if( SymbolToLabelTable != NULL ) {
NameRecognitionTable = HashTableCreate( RECOGNITION_TABLE_SIZE, HASH_STRING_IGNORECASE );
if( NameRecognitionTable == NULL ) {
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToLabelListTable );
HashTableFree( HandleToRefListTable );
HashTableFree( SymbolToLabelTable );
return( RC_OUT_OF_MEMORY );
}
} else {
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToLabelListTable );
HashTableFree( HandleToRefListTable );
return( RC_OUT_OF_MEMORY );
}
} else {
HashTableFree( HandleToSectionTable );
HashTableFree( HandleToLabelListTable );
return( RC_OUT_OF_MEMORY );
}
} else {
HashTableFree( HandleToSectionTable );
return( RC_OUT_OF_MEMORY );
}
} else {
return( RC_OUT_OF_MEMORY );
}
return( RC_OKAY );
}
HashTable *readSnpFile(char *snp_file)
{
FILE *fp;
HashTable *snp_hash;
static const int line_size = 8192;
char line[line_size];
size_t count = 0;
char last_chrom[100] = "";
display("reading snp file %s\n", snp_file);
fp = fopen(snp_file, "rb");
if (NULL == fp) {
die("ERROR: can't open known snp file %s: %s\n", snp_file, strerror(errno));
}
if (NULL == (snp_hash = HashTableCreate(0, HASH_DYNAMIC_SIZE | HASH_FUNC_JENKINS3))) {
die("ERROR: creating snp hash table\n");
}
while (fgets(line, line_size, fp)) {
char key[100];
HashData hd;
int bin, start, end;
char chrom[100];
if (4 != sscanf(line, "%d\t%s\t%d\t%d", &bin, chrom, &start, &end)) {
die("ERROR: reading snp file\n%s\n", line);
}
/* N.B rod start is 0 based */
snprintf(key, sizeof(key), "%s:%d", chrom, start);
hd.i = 0;
if (NULL == HashTableAdd(snp_hash, key, strlen(key), hd, NULL)) {
die("ERROR: building snp hash table\n");
}
if (strcmp(chrom, last_chrom)) {
strcpy(last_chrom, chrom);
count = 0;
}
count++;
}
fclose(fp);
return snp_hash;
}
static NTSTATUS _DriverHookRecordCreate(PDRIVER_OBJECT DriverObject, PDRIVER_MONITOR_SETTINGS MonitorSettings, BOOLEAN MonitoringEnabled, PDRIVER_HOOK_RECORD *Record)
{
PDRIVER_HOOK_RECORD tmpRecord = NULL;
NTSTATUS status = STATUS_UNSUCCESSFUL;
DEBUG_ENTER_FUNCTION("DriverObject=0x%p; MonitorSettings=0x%p; MonitoringEnabled=%u; Record=0x%p", DriverObject, MonitorSettings, MonitoringEnabled, Record);
tmpRecord = (PDRIVER_HOOK_RECORD)HeapMemoryAllocNonPaged(sizeof(DRIVER_HOOK_RECORD));
if (tmpRecord != NULL) {
memset(tmpRecord, 0, sizeof(DRIVER_HOOK_RECORD));
tmpRecord->ReferenceCount = 1;
status = _GetObjectName(DriverObject, &tmpRecord->DriverName);
if (NT_SUCCESS(status)) {
tmpRecord->DriverObject = DriverObject;
tmpRecord->MonitoringEnabled = MonitoringEnabled;
tmpRecord->MonitorNewDevices = MonitorSettings->MonitorNewDevices;
tmpRecord->MonitorStartIo = MonitorSettings->MonitorStartIo;
tmpRecord->MonitorAddDevice = MonitorSettings->MonitorAddDevice;
tmpRecord->MonitorDriverUnload = MonitorSettings->MonitorUnload;
tmpRecord->MonitorIRP = MonitorSettings->MonitorIRP;
tmpRecord->MonitorIRPCompletion = MonitorSettings->MonitorIRPCompletion;
tmpRecord->MonitorFastIo = MonitorSettings->MonitorFastIo;
memcpy(tmpRecord->IRPSettings, MonitorSettings->IRPSettings, sizeof(tmpRecord->IRPSettings));
memcpy(tmpRecord->FastIoSettings, MonitorSettings->FastIoSettings, sizeof(tmpRecord->FastIoSettings));
KeInitializeSpinLock(&tmpRecord->SelectedDevicesLock);
status = HashTableCreate(httNoSynchronization, 37, _HashFunction, _DeviceCompareFunction, _DeviceFreeFunction, &tmpRecord->SelectedDevices);
if (NT_SUCCESS(status))
*Record = tmpRecord;
if (!NT_SUCCESS(status))
HeapMemoryFree(tmpRecord->DriverName.Buffer);
}
if (!NT_SUCCESS(status))
HeapMemoryFree(tmpRecord);
} else status = STATUS_INSUFFICIENT_RESOURCES;
DEBUG_EXIT_FUNCTION("0x%x, *Record=0x%p", status, *Record);
return status;
}
void cram_stats_add(cram_stats *st, int32_t val) {
st->nsamp++;
//assert(val >= 0);
if (val < MAX_STAT_VAL && val >= 0) {
st->freqs[val]++;
} else {
HashItem *hi;
if (!st->h) {
st->h = HashTableCreate(2048, HASH_DYNAMIC_SIZE|HASH_NONVOLATILE_KEYS|HASH_INT_KEYS);
}
if ((hi = HashTableSearch(st->h, (char *)(size_t)val, 4))) {
hi->data.i++;
} else {
HashData hd;
hd.i = 1;
HashTableAdd(st->h, (char *)(size_t)val, 4, hd, NULL);
}
}
}
/*
* Main method.
*/
int main(int argc, char **argv) {
int ifile, nfiles;
char *input = NULL;
int c;
int errflg = 0;
extern char *optarg;
extern int optind, optopt;
int level_mode = LEVEL_ALL;
long read_count[NREADS];
char *read_str[] = {READ_GOOD_STR, READ_BAD_STR, READ_TOTAL_STR};
long chunk_count[NCHUNKS];
uint64_t chunk_size[NCHUNKS];
uint4 chunk_type[] = {CHUNK_BASE_TYPE, CHUNK_CNF1_TYPE, CHUNK_CNF4_TYPE, CHUNK_SAMP_TYPE, CHUNK_SMP4_TYPE, CHUNK_REGN_TYPE};
long key_count[NCHUNKS][NKEYS];
char *keys_str[] = {KEY_TYPE_STR, KEY_VALTYPE_STR, KEY_GROUP_STR, KEY_OFFS_STR, KEY_SCALE_STR, KEY_COORD_STR, KEY_NAME_STR};
long type_count[NCHUNKS][NTYPES];
char *types_str[] = {TYPE_PROC_STR, TYPE_SLXI_STR, TYPE_SLXN_STR, TYPE_0FAM_STR, TYPE_1CY3_STR, TYPE_2TXR_STR, TYPE_3CY5_STR};
int iread, ichunk, ikey, itype;
while ((c = getopt(argc, argv, "l:")) != -1) {
switch (c) {
case 'l':
if (1 != sscanf(optarg, "%d", &level_mode)) {
fprintf(stderr,
"Otion -%c requires an operand\n", optopt);
errflg++;
}
break;
case ':': /* -? without operand */
fprintf(stderr,
"Option -%c requires an operand\n", optopt);
errflg++;
break;
case '?':
fprintf(stderr,
"Unrecognised option: -%c\n", optopt);
errflg++;
}
}
if (errflg) {
usage(1);
}
nfiles = (argc-optind);
if( nfiles < 1 ){
fprintf(stderr, "Please specify input archive name(s).\n");
usage(1);
}
for (ifile=0; ifile<nfiles; ifile++) {
HashTable *regn_hash;
char bases[] = "ACGTN";
uint64_t base_count[5];
char type[5];
input = argv[optind+ifile];
printf("Reading archive %s.\n", input);
for (iread=0; iread<NREADS; iread++)
read_count[iread] = 0;
for (ichunk=0; ichunk<NCHUNKS; ichunk++) {
chunk_count[ichunk] = 0;
chunk_size[ichunk] = 0;
}
for (ichunk=0; ichunk<NCHUNKS; ichunk++)
for (ikey=0; ikey<NKEYS; ikey++)
key_count[ichunk][ikey] = 0;
for (ichunk=0; ichunk<NCHUNKS; ichunk++)
for (itype=0; itype<NTYPES; itype++)
type_count[ichunk][itype] = 0;
if (NULL == (regn_hash = HashTableCreate(0, HASH_DYNAMIC_SIZE|HASH_FUNC_JENKINS3))) {
return 1;
}
memset(base_count, 0, 5 * sizeof(uint64_t));
if( 0 == srf_info(input, level_mode, read_count,
chunk_count, chunk_size,
key_count, type_count, regn_hash, base_count) ){
/* read counts */
if( level_mode & LEVEL_READ ) {
for (iread=0; iread<NREADS; iread++) {
if( read_count[iread] )
printf("Reads: %s : %ld\n", read_str[iread], read_count[iread]);
}
}
/* chunk, key and type counts */
if( level_mode & LEVEL_CHUNK ) {
for (ichunk=0; ichunk<NCHUNKS; ichunk++) {
if( chunk_count[ichunk] ) {
printf("Chunk: %s : %ld %"PRId64"\n",
ZTR_BE2STR(chunk_type[ichunk], type),
chunk_count[ichunk], chunk_size[ichunk]);
for (ikey=0; ikey<NKEYS; ikey++) {
if(key_count[ichunk][ikey]) {
printf(" Mdata key: %s : %ld\n", keys_str[ikey], key_count[ichunk][ikey]);
if (ikey == KEY_TYPE && (ichunk == CHUNK_SAMP || ichunk == CHUNK_SMP4)) {
for (itype=0; itype<NTYPES; itype++)
if(type_count[ichunk][itype])
printf(" types: %s : %ld\n", types_str[itype], type_count[ichunk][itype]);
}
if (ikey == KEY_NAME && (ichunk == CHUNK_REGN)) {
int ibucket;
for (ibucket=0; ibucket<regn_hash->nbuckets; ibucket++) {
HashItem *hi;
for (hi = regn_hash->bucket[ibucket]; hi; hi = hi->next) {
regn_t *regn = (regn_t *)hi->data.p;
printf(" %s x%d\n", hi->key, regn->count);
}
}
}
}
}
}
}
}
/* base counts */
if( level_mode & LEVEL_BASE ) {
uint64_t total = 0;
int i;
for (i=0; i<5; i++) {
if( base_count[i] ){
printf("Bases: %c: %"PRId64"\n",
bases[i], base_count[i]);
total += base_count[i];
}
}
printf("Bases: TOTAL: %"PRId64"\n", total);
}
}
}
return 0;
}
int transfer_SAM_to_position_table(char * sam_file)
{
char linebuf[max(2*MAX_READ_LENGTH+300,3000)];
int allreads=0,mapped=0;
char mate_chro[MAX_CHROMOSOME_NAME_LEN+1];
unsigned int mate_pos;
int flags_mate;
char cigar_mate[EXON_MAX_CIGAR_LEN+1];
gene_input_t input_file;
HashTable * local_reassembly_pileup_files;
HashTable * chromosome_size_table;
chromosome_size_table = HashTableCreate(100);
HashTableSetDeallocationFunctions(chromosome_size_table, NULL, NULL);
HashTableSetKeyComparisonFunction(chromosome_size_table, my_strcmp);
HashTableSetHashFunction(chromosome_size_table, HashTableStringHashFunction);
local_reassembly_pileup_files = HashTableCreate(100);
HashTableSetDeallocationFunctions(local_reassembly_pileup_files, NULL, NULL);
HashTableSetKeyComparisonFunction(local_reassembly_pileup_files, my_strcmp);
HashTableSetHashFunction(local_reassembly_pileup_files ,HashTableStringHashFunction);
geinput_open_sam(sam_file, &input_file,0);
while(1)
{
unsigned int read_pos =0xffffffff;
char read_name[MAX_READ_NAME_LEN+1];
int flags;
char chro_name[MAX_CHROMOSOME_NAME_LEN+1];
unsigned int pos, pair_dist;
char cigar[EXON_MAX_CIGAR_LEN+1];
char read_text[MAX_READ_LENGTH+1];
char qual_text[MAX_READ_LENGTH+1];
int read_len, is_repeated, mapping_quality, is_anchor_certain=1;
int pos_delta = 0;
int is_paired_end_reads = 0;
unsigned long long int file_offset = ftello(input_file.input_fp);
if(feof(input_file.input_fp))break;
read_text[0]=0;
qual_text[0]=0;
geinput_readline(&input_file, linebuf,0);
int res = parse_SAM_line(linebuf, read_name,& flags, chro_name, & pos, cigar, & mapping_quality, & pair_dist, read_text , qual_text, & read_len, & is_repeated);
int cigar_cursor = 0;
int firstM = 1,xx=0;
is_paired_end_reads = flags &1;
if(res==0)
{
for(; cigar[cigar_cursor]; cigar_cursor++)
{
char nch = cigar[cigar_cursor];
if(nch>='0'&&nch<='9')
{
xx=xx*10+(nch-'0');
}else
{
if(nch=='M') firstM=0;
else if(nch=='S')
{
if(firstM)
pos_delta = xx;
}
xx=0;
}
}
pos -= pos_delta;
}
if(res == 1) {chro_name[0]='*'; chro_name[1]=0;}
//printf("MAPPED=%d\n", res);
if(res == 0) // mapped
{
read_pos = pos - 1;
mapped++;
}
else if(res == 1 && is_paired_end_reads) // unmapped
{
is_anchor_certain=0;
if(mate_chro[0])
{
if(mate_chro[0]!='*')
{
read_pos = mate_pos ;
strcpy(chro_name, mate_chro);
}
//printf("RECOVERED 1: %u - %s ; LEN=%d ; YOU_ARE_FIRST=%d\n%s\n%s\n", read_anchor_position, read_name, read_len, flags_mate & SAM_FLAG_FIRST_READ_IN_PAIR, read_text, qual_text);
}
else
{
char read_text_null[MAX_READ_LENGTH+1];
char qual_text_null[MAX_READ_LENGTH+1];
geinput_readline_back(&input_file, linebuf);
res = parse_SAM_line(linebuf, read_name,& flags_mate, mate_chro, & mate_pos, cigar_mate, & mapping_quality, & pair_dist, read_text_null , qual_text_null, & read_len, & is_repeated);
if(res==0)
{
read_pos = mate_pos - 1;
strcpy(chro_name, mate_chro);
}
//printf("RECOVERED 2: %u - %s ; LEN=%d ; YOU_ARE_FIRST=%d\n%s\n%s\n", read_anchor_position, read_name, read_len, flags_mate & SAM_FLAG_FIRST_READ_IN_PAIR, read_text, qual_text);
}
}
if(read_pos<0xffff0000)
{
unsigned int read_span = calculate_read_span(cigar);
write_read_pos(chro_name, read_pos, read_len, flags, file_offset, cigar, read_span, local_reassembly_pileup_files);
unsigned int old_max_pos = HashTableGet(chromosome_size_table, chro_name) - NULL;
if(old_max_pos==0)
{
char * chro_name_new = malloc(strlen(chro_name)+1);
strcpy(chro_name_new , chro_name);
HashTablePut(chromosome_size_table, chro_name_new, NULL+read_pos + read_span+1);
}
else if(read_pos + read_span +1 > old_max_pos )
HashTablePutReplace(chromosome_size_table, chro_name, NULL+read_pos + read_span+1, 0);
}
if(allreads %2==1)
mate_chro[0] = 0;
else
{
strcpy(mate_chro, chro_name);
mate_pos = pos - 1;
flags_mate = flags;
}
allreads++;
}
SUBREADprintf("Processed %d reads; %d mapped.\n", allreads, mapped);
destroy_pileup_table(local_reassembly_pileup_files);
finalise_sam_index(chromosome_size_table, sam_file);
HashTableDestroy(chromosome_size_table);
return 0;
}
void WordFormInit()
{
WordFormHt = HashTableCreate(1009L); /* todo: Increase size? */
WordFormTrained = 0;
}
int main(int argc, char ** argv)
{
char * junc_table_file;
HashTable * junc_table = HashTableCreate(337);
HashTable * junc_table_l = HashTableCreate(337);
HashTable * junc_table_r = HashTableCreate(337);
HashTable * bin_table = HashTableCreate(9337);
if(argc<2)
{
printf("Usage cat my.SAM | filterJunc junc.table | featureCounts -i STDIN -a myAnnot.txt \n");
return -1;
}
junc_table_file = argv[1];
if(load_junc_table(junc_table_file, junc_table, junc_table_l, junc_table_r, bin_table))
{
printf("Junction table not found!\n");
return -1;
}
char * linebuf=malloc(5001);
char * linebuf2=malloc(5001);
while(1)
{
int support_found = 0, ii, jj, alternative_found = 0;
char * new_line = fgets(linebuf, 5000, stdin);
if(!new_line) break;
if(new_line[0]=='@')
{
fputs(new_line, stdout);
continue;
}
char * new_line2 = fgets(linebuf2, 5000, stdin);
for(ii=0;ii<2;ii++)
{
int flag=0;
char chro[20];
unsigned int pos=0;
char cigar[50];
unsigned int start_points[6];
unsigned short section_lengths[6];
parse_line(ii?new_line2:new_line, &flag, chro, &pos, cigar);
int sections = RSubread_parse_CIGAR_string(cigar, start_points, section_lengths);
for(jj=0; jj<sections-1; jj++)
{
unsigned int edge1 = start_points[jj] + pos + section_lengths[jj];
unsigned int edge2 = start_points[jj+1] + pos - 1;
unsigned long long int junc_table_key = (edge1*1LLU) <<32 | edge2;
char * junc_chro=HashTableGet(junc_table, (void *)junc_table_key);
if(junc_chro && strcmp(junc_chro, chro)==0)
{
support_found = 1;
}
else
{
char * junc_chro_l=HashTableGet(junc_table_l, NULL+edge1);
char * junc_chro_2=HashTableGet(junc_table_r, NULL+edge2);
if( (junc_chro_l && strcmp(junc_chro_l, chro)==0)
|| (junc_chro_2 && strcmp(junc_chro_2, chro)==0))
alternative_found = 1;
}
}
//if(support_found) break;
if(!support_found && !alternative_found)
for(jj=0; jj<sections; jj++)
{
unsigned int edge2 = start_points[jj] + pos + section_lengths[jj];
unsigned int edge1 = start_points[jj] + pos;
unsigned int real_edge1 = HashTableGet(bin_table, NULL+edge1/50)-NULL;
unsigned int real_edge2 = HashTableGet(bin_table, NULL+edge2/50)-NULL;
if(real_edge1)
{
long long int diff = real_edge1;
diff -= edge1;
if(abs(diff)<section_lengths[jj])
alternative_found=1;
// this section should contain the read_edge, but it does not! (it was a section as a whole)
}
if(real_edge2)
{
long long int diff = real_edge2;
diff -= edge1;
if(abs(diff)<section_lengths[jj])
alternative_found=1;
// this section should contain the read_edge, but it does not! (it was a section as a whole)
}
}
}
if(alternative_found)
//if(support_found)
{
fputs( new_line, stdout);
fputs( new_line2, stdout);
}
//printf("READ: (%d) %s,%u %s\n\n", flag2, chro2, pos2, cigar2);
}
free(linebuf);
free(linebuf2);
}
return_val Init( void )
{
return_val error;
const char * const *list;
const char *name;
hash_entry_data key_entry;
error = RC_OKAY;
OutputDest = STDOUT_FILENO;
ChangePrintDest( OutputDest );
relocSections.first = NULL;
relocSections.last = NULL;
if( !MsgInit() ) {
// MsgInit does its own error message printing
return( RC_ERROR );
}
MemOpen();
error = HandleArgs();
if( error != RC_OKAY ) {
return( error );
}
openFiles();
initGlobals();
error = initHashTables();
if( error != RC_OKAY ) {
PrintErrorMsg( error, WHERE_INIT_HASH_TABLES );
return( error );
}
error = initServicesUsed();
if( error != RC_OKAY ) {
// initServicesUsed does its own error message printing
return( error );
}
error = initSectionTables();
if( error != RC_OKAY ) {
PrintErrorMsg( error, WHERE_CREATE_SEC_TABLES );
return( error );
}
if( Options & PRINT_PUBLICS ) {
CreatePublicsArray();
}
if( IsMasmOutput() ) {
CommentString = MASM_COMMENT_STRING;
}
if( IsIntelx86() ) {
SkipRefTable = HashTableCreate( RECOGNITION_TABLE_SIZE, HASH_STRING_IGNORECASE );
if( SkipRefTable != NULL ) {
for( list = intelSkipRefList; (name = *list) != NULL; ++list ) {
key_entry.key.u.string = name;
key_entry.data.u.string = *list;
error = HashTableInsert( SkipRefTable, &key_entry );
if( error != RC_OKAY ) {
break;
}
}
}
}
if( LabelChar == 0 ) {
if( IsMasmOutput() ) {
LabelChar = 'L';
} else {
LabelChar = 'X';
}
}
return( error );
}
void Init( void )
{
char cmd_line[ CMD_LINE_LEN ];
return_val error;
char **list;
OutputDest = STDOUT_FILENO;
ChangePrintDest( OutputDest );
relocSections.first = NULL;
relocSections.last = NULL;
if( !MsgInit() ) {
// MsgInit does its own error message printing
exit( -1 );
}
MemOpen();
getcmd( cmd_line );
HandleArgs( cmd_line );
openFiles();
initGlobals();
error = initHashTables();
if( error == OKAY ) {
error = initServicesUsed();
if( error == OKAY ) {
error = initSectionTables();
if( error != OKAY ) {
// free hash tables and services
MemClose();
LeaveProgram( error, WHERE_CREATE_SEC_TABLES );
}
} else {
// free hash tables
CloseFiles();
FreeHashTables();
// initServicesUsed does its own error message printing
exit( error );
}
} else {
CloseFiles();
MemClose();
LeaveProgram( error, WHERE_INIT_HASH_TABLES );
}
if( Options & PRINT_PUBLICS ) {
CreatePublicsArray();
}
if( IsMasmOutput() ) {
CommentString = MASM_COMMENT_STRING;
}
if( IsIntelx86() ) {
SkipRefTable = HashTableCreate( RECOGNITION_TABLE_SIZE, HASH_STRING,
(hash_table_comparison_func) stricmp );
if( SkipRefTable ) {
list = intelSkipRefList;
while( *list ) {
error = HashTableInsert( SkipRefTable, (hash_value) *list,
(hash_data) *list );
if( error != OKAY ) break;
list++;
}
}
}
if( !LabelChar ) {
if( IsMasmOutput() ) {
LabelChar = 'L';
} else {
LabelChar = 'X';
}
}
}
NTSTATUS
GnttabInitialize(
IN PXENBUS_FDO Fdo,
OUT PXENBUS_GNTTAB_CONTEXT *Context
)
{
NTSTATUS status;
Trace("====>\n");
*Context = __GnttabAllocate(sizeof (XENBUS_GNTTAB_CONTEXT));
status = STATUS_NO_MEMORY;
if (*Context == NULL)
goto fail1;
status = RangeSetGetInterface(FdoGetRangeSetContext(Fdo),
XENBUS_RANGE_SET_INTERFACE_VERSION_MAX,
(PINTERFACE)&(*Context)->RangeSetInterface,
sizeof ((*Context)->RangeSetInterface));
ASSERT(NT_SUCCESS(status));
ASSERT((*Context)->RangeSetInterface.Interface.Context != NULL);
status = CacheGetInterface(FdoGetCacheContext(Fdo),
XENBUS_CACHE_INTERFACE_VERSION_MAX,
(PINTERFACE)&(*Context)->CacheInterface,
sizeof ((*Context)->CacheInterface));
ASSERT(NT_SUCCESS(status));
ASSERT((*Context)->CacheInterface.Interface.Context != NULL);
status = SuspendGetInterface(FdoGetSuspendContext(Fdo),
XENBUS_SUSPEND_INTERFACE_VERSION_MAX,
(PINTERFACE)&(*Context)->SuspendInterface,
sizeof ((*Context)->SuspendInterface));
ASSERT(NT_SUCCESS(status));
ASSERT((*Context)->SuspendInterface.Interface.Context != NULL);
status = DebugGetInterface(FdoGetDebugContext(Fdo),
XENBUS_DEBUG_INTERFACE_VERSION_MAX,
(PINTERFACE)&(*Context)->DebugInterface,
sizeof ((*Context)->DebugInterface));
ASSERT(NT_SUCCESS(status));
ASSERT((*Context)->DebugInterface.Interface.Context != NULL);
InitializeListHead(&(*Context)->List);
KeInitializeSpinLock(&(*Context)->Lock);
status = HashTableCreate(&(*Context)->MapTable);
if (!NT_SUCCESS(status))
goto fail2;
(*Context)->Fdo = Fdo;
Trace("<====\n");
return STATUS_SUCCESS;
fail2:
Error("fail2\n");
fail1:
Error("fail1 (%08x)\n", status);
return status;
}
/***********************************************************************************
Function Name : InitContext
Inputs : gc, psShareContext, psMode
Outputs : -
Returns : Success
Description : Initialises a context - may setup shared name tables from a
sharecontext. Also sets up default framebuffer
************************************************************************************/
static IMG_BOOL InitContext(GLES2Context *gc, GLES2Context *psShareContext, EGLcontextMode *psMode)
{
#if defined(GLES2_EXTENSION_VERTEX_ARRAY_OBJECT)
GLES2NameType aeNameType[GLES2_MAX_UNSHAREABLE_NAMETYPE] =
{
GLES2_NAMETYPE_VERARROBJ
};
#endif /* defined(GLES2_EXTENSION_VERTEX_ARRAY_OBJECT) */
IMG_UINT32 i, j;
GLES_ASSERT(gc);
GetApplicationHints(&gc->sAppHints, psMode);
#if defined(FIX_HW_BRN_26922)
if(!AllocateBRN26922Mem(gc))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: AllocateBRN26922Mem failed"));
goto FAILED_AllocateBRN26922Mem;
}
#endif /* defined(FIX_HW_BRN_26922) */
if(!CreateSharedState(gc, psShareContext))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: CreateSharedState failed"));
goto FAILED_CreateSharedState;
}
#if defined(GLES2_EXTENSION_VERTEX_ARRAY_OBJECT)
/* Initialize the unshareable names arrays */
for (i = 0; i < GLES2_MAX_UNSHAREABLE_NAMETYPE; i++)
{
gc->apsNamesArray[i] = CreateNamesArray(gc, aeNameType[i], (PVRSRV_MUTEX_HANDLE)0);
if(!gc->apsNamesArray[i])
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: Couldn't create unshareable names array %d", i));
DestroyNamesArray(gc, gc->apsNamesArray[i]);
return IMG_FALSE;
}
}
#endif /* defined(GLES2_EXTENSION_VERTEX_ARRAY_OBJECT) */
if(GLES2ALLOCDEVICEMEM(gc->ps3DDevData,
gc->psSysContext->hSyncInfoHeap,
PVRSRV_MEM_WRITE | PVRSRV_MEM_READ | PVRSRV_MEM_NO_SYNCOBJ | PVRSRV_MEM_CACHE_CONSISTENT,
4,
0,
&gc->sKRMTAStatusUpdate.psMemInfo) != PVRSRV_OK)
{
PVR_DPF((PVR_DBG_ERROR, "InitContext: Failed to create TA sync object"));
goto FAILED_TASync;
}
gc->sKRMTAStatusUpdate.ui32StatusValue = 1;
PVRSRVMemSet(gc->sKRMTAStatusUpdate.psMemInfo->pvLinAddr, 0, 4);
if(!HashTableCreate(gc, &gc->sProgram.sPDSFragmentVariantHashTable, STATEHASH_LOG2TABLESIZE, STATEHASH_MAXNUMENTRIES, DestroyHashedPDSVariant))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: HashTableCreate failed"));
goto FAILED_CreateHashTable;
}
if(!CreateTextureState(gc))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: CreateTextureState failed"));
goto FAILED_CreateTextureState;
}
if(!CreateProgramState(gc))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: CreateProgramState failed"));
goto FAILED_CreateProgramState;
}
if(!CreateBufObjState(gc))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: CreateBufObjState failed"));
goto FAILED_CreateBufObjState;
}
if(!CreateFrameBufferState(gc, psMode))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: CreateRenderBufferState failed"));
goto FAILED_CreateFrameBufferState;
}
if(!CreateVertexArrayObjectState(gc))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: CreateVertexArrayObjectState failed"));
goto FAILED_CreateVertexArrayObjectState;
}
/* Initialise the TA kick VAO manager */
if(!KRM_Initialize(&gc->sVAOKRM,
KRM_TYPE_TA,
IMG_FALSE,
0, /* PVRSRV_MUTEX_HANDLE */
gc->ps3DDevData,
gc->psSysContext->sHWInfo.sMiscInfo.hOSGlobalEvent,
ReclaimVAOMemKRM,
IMG_TRUE,
DestroyVAOGhostKRM))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: Couldn't initialise the TA kick VAO manager"));
goto FAILED_CreateVertexArrayObjectState;
}
if(!InitSpecialUSECodeBlocks(gc))
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: InitSpecialUSECodeBlocks failed"));
goto FAILED_InitSpecialUSECodeBlocks;
}
gc->sState.sRaster.ui32ColorMask = GLES2_COLORMASK_ALL;
gc->sState.sRaster.sClearColor.fRed = GLES2_Zero;
gc->sState.sRaster.sClearColor.fGreen = GLES2_Zero;
gc->sState.sRaster.sClearColor.fBlue = GLES2_Zero;
gc->sState.sRaster.sClearColor.fAlpha = GLES2_Zero;
gc->sState.sRaster.ui32BlendFactor = ((GLES2_BLENDFACTOR_ONE << GLES2_BLENDFACTOR_RGBSRC_SHIFT) |
(GLES2_BLENDFACTOR_ONE << GLES2_BLENDFACTOR_ALPHASRC_SHIFT) |
(GLES2_BLENDFACTOR_ZERO << GLES2_BLENDFACTOR_RGBDST_SHIFT) |
(GLES2_BLENDFACTOR_ZERO << GLES2_BLENDFACTOR_ALPHADST_SHIFT));
gc->sState.sRaster.ui32BlendEquation = (GLES2_BLENDFUNC_ADD << GLES2_BLENDFUNC_RGB_SHIFT) |
(GLES2_BLENDFUNC_ADD << GLES2_BLENDFUNC_ALPHA_SHIFT);
gc->sState.sRaster.sBlendColor.fRed = GLES2_Zero;
gc->sState.sRaster.sBlendColor.fGreen = GLES2_Zero;
gc->sState.sRaster.sBlendColor.fBlue = GLES2_Zero;
gc->sState.sRaster.sBlendColor.fAlpha = GLES2_Zero;
gc->sState.sLine.fWidth = GLES2_One;
gc->sState.sPolygon.eCullMode = GL_BACK;
gc->sState.sPolygon.eFrontFaceDirection = GL_CCW;
gc->sState.sPolygon.factor.fVal = GLES2_Zero;
gc->sState.sPolygon.fUnits = GLES2_Zero;
gc->sState.sStencil.ui32FFStencil = EURASIA_ISPC_SCMP_ALWAYS |
EURASIA_ISPC_SOP1_KEEP |
EURASIA_ISPC_SOP2_KEEP |
EURASIA_ISPC_SOP3_KEEP |
(GLES2_MAX_STENCIL_VALUE << EURASIA_ISPC_SCMPMASK_SHIFT) |
(GLES2_MAX_STENCIL_VALUE << EURASIA_ISPC_SWMASK_SHIFT);
gc->sState.sStencil.ui32BFStencil = EURASIA_ISPC_SCMP_ALWAYS |
EURASIA_ISPC_SOP1_KEEP |
EURASIA_ISPC_SOP2_KEEP |
EURASIA_ISPC_SOP3_KEEP |
(GLES2_MAX_STENCIL_VALUE << EURASIA_ISPC_SCMPMASK_SHIFT) |
(GLES2_MAX_STENCIL_VALUE << EURASIA_ISPC_SWMASK_SHIFT);
gc->sState.sStencil.ui32FFStencilRef = (0 << EURASIA_ISPA_SREF_SHIFT);
gc->sState.sStencil.ui32BFStencilRef = (0 << EURASIA_ISPA_SREF_SHIFT);
gc->sState.sStencil.ui32Clear = 0;
gc->sState.sStencil.ui32FFStencilCompareMaskIn = GLES2_MAX_STENCIL_VALUE;
gc->sState.sStencil.ui32BFStencilCompareMaskIn = GLES2_MAX_STENCIL_VALUE;
gc->sState.sStencil.ui32FFStencilWriteMaskIn = GLES2_MAX_STENCIL_VALUE;
gc->sState.sStencil.ui32BFStencilWriteMaskIn = GLES2_MAX_STENCIL_VALUE;
gc->sState.sStencil.i32FFStencilRefIn = 0;
gc->sState.sStencil.i32BFStencilRefIn = 0;
gc->sState.sStencil.ui32MaxFBOStencilVal = GLES2_MAX_STENCIL_VALUE;
gc->sState.sMultisample.bSampleCoverageInvert = IMG_FALSE;
gc->sState.sMultisample.fSampleCoverageValue = GLES2_One;
gc->sState.sDepth.ui32TestFunc = EURASIA_ISPA_DCMPMODE_LT;
gc->sState.sDepth.fClear = GLES2_One;
gc->ui32Enables = GLES2_DITHER_ENABLE;
gc->sState.sClientPixel.ui32UnpackAlignment = 4;
gc->sState.sClientPixel.ui32PackAlignment = 4;
gc->ui32DirtyState = GLES2_DIRTYFLAG_ALL;
gc->ui32EmitMask = GLES2_EMITSTATE_ALL;
/*
* Set up attrib array default values
*/
for (i=0; i < GLES2_MAX_VERTEX_ATTRIBS; ++i)
{
GLES2AttribArrayPointerState *psAPState = &(gc->sVAOMachine.sDefaultVAO.asVAOState[AP_VERTEX_ATTRIB0 + i]);
psAPState->ui32StreamTypeSize = GLES2_STREAMTYPE_FLOAT | (4 << GLES2_STREAMSIZE_SHIFT);
gc->sVAOMachine.asAttribPointer[AP_VERTEX_ATTRIB0 + i].psState = psAPState;
gc->sVAOMachine.asAttribPointer[AP_VERTEX_ATTRIB0 + i].ui32Size = 16;
gc->sVAOMachine.asAttribPointer[AP_VERTEX_ATTRIB0 + i].ui32Stride = 16;
gc->sVAOMachine.asCurrentAttrib[AP_VERTEX_ATTRIB0 + i].fX = GLES2_Zero;
gc->sVAOMachine.asCurrentAttrib[AP_VERTEX_ATTRIB0 + i].fY = GLES2_Zero;
gc->sVAOMachine.asCurrentAttrib[AP_VERTEX_ATTRIB0 + i].fZ = GLES2_Zero;
gc->sVAOMachine.asCurrentAttrib[AP_VERTEX_ATTRIB0 + i].fW = GLES2_One;
}
for(i=0; i < GLES2_HINT_NUMHINTS; i++)
{
gc->sState.sHints.eHint[i] = GL_DONT_CARE;
}
j = 0;
for(i=0; i < CBUF_NUM_TA_BUFFERS; i++)
{
IMG_UINT32 ui32Size;
IMG_HANDLE hMemHeap;
switch(i)
{
case CBUF_TYPE_PDS_VERT_BUFFER:
{
hMemHeap = gc->psSysContext->hPDSVertexHeap;
ui32Size = gc->sAppHints.ui32DefaultPDSVertBufferSize;
break;
}
case CBUF_TYPE_VERTEX_DATA_BUFFER:
{
hMemHeap = gc->psSysContext->hGeneralHeap;
ui32Size = gc->sAppHints.ui32DefaultVertexBufferSize;
break;
}
case CBUF_TYPE_INDEX_DATA_BUFFER:
{
hMemHeap = gc->psSysContext->hGeneralHeap;
ui32Size = gc->sAppHints.ui32DefaultIndexBufferSize;
break;
}
case CBUF_TYPE_VDM_CTRL_BUFFER:
{
hMemHeap = gc->psSysContext->hGeneralHeap;
ui32Size = gc->sAppHints.ui32DefaultVDMBufferSize;
break;
}
case CBUF_TYPE_PDS_VERT_SECONDARY_PREGEN_BUFFER:
{
PVR_DPF((PVR_DBG_MESSAGE,"InitContext: ignoring buffer type CBUF_TYPE_PDS_VERT_SECONDARY_PREGEN_BUFFER"));
hMemHeap = gc->psSysContext->hPDSVertexHeap;
ui32Size = 4;
break;
}
case CBUF_TYPE_MTE_COPY_PREGEN_BUFFER:
{
hMemHeap = gc->psSysContext->hPDSVertexHeap;
if(gc->sAppHints.bEnableStaticMTECopy)
{
ui32Size = ((gc->sAppHints.ui32DefaultPregenMTECopyBufferSize / GLES2_ALIGNED_MTE_COPY_PROG_SIZE) * GLES2_ALIGNED_MTE_COPY_PROG_SIZE);
}
else
{
PVR_DPF((PVR_DBG_WARNING,"InitContext: ignoring buffer type CBUF_TYPE_MTE_COPY_PREGEN_BUFFER"));
ui32Size = 4;
}
break;
}
case CBUF_TYPE_PDS_AUXILIARY_PREGEN_BUFFER:
{
/* Unused */
gc->apsBuffers[i] = IMG_NULL;
continue;
}
default:
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: Invalid buffer type"));
goto FAILED_CBUF_CreateBuffer;
}
}
gc->apsBuffers[i] = CBUF_CreateBuffer(gc->ps3DDevData, i, hMemHeap, gc->psSysContext->hSyncInfoHeap, gc->psSysContext->sHWInfo.sMiscInfo.hOSGlobalEvent, ui32Size);
if(!gc->apsBuffers[i])
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: Failed to create buffer %u",i));
goto FAILED_CBUF_CreateBuffer;
}
/* Point the TA Kick status update to the device memory reserved for status updates in the buffer */
gc->sKickTA.asTAStatusUpdate[j].hKernelMemInfo = gc->apsBuffers[i]->psStatusUpdateMemInfo->hKernelMemInfo;
gc->sKickTA.asTAStatusUpdate[j].sCtlStatus.sStatusDevAddr.uiAddr = gc->apsBuffers[i]->psStatusUpdateMemInfo->sDevVAddr.uiAddr;
/* set the read offset pointer in the buffer */
gc->apsBuffers[i]->pui32ReadOffset = (IMG_UINT32*)gc->apsBuffers[i]->psStatusUpdateMemInfo->pvLinAddr;
j++;
if(i == CBUF_TYPE_MTE_COPY_PREGEN_BUFFER)
{
if(gc->sAppHints.bEnableStaticMTECopy)
{
if(SetupMTEPregenBuffer(gc) != GLES2_NO_ERROR)
{
PVR_DPF((PVR_DBG_ERROR,"InitContext: Failed to fill pregen buffer %u",i));
goto FAILED_CBUF_CreateBuffer;
}
}
}
}
gc->sKickTA.sKickTACommon.ui32NumTAStatusVals = j;
/* Setup 3D status val sync */
gc->sKickTA.sKickTACommon.ui32Num3DStatusVals = 2;
if(BuildExtensionString(gc) != IMG_TRUE)
{
goto FAILED_BuildExtensionString;
}
#if defined(SGX_FEATURE_SW_VDM_CONTEXT_SWITCH)
gc->sSmallKickTA.ui32NumIndicesThisTA = 0;
gc->sSmallKickTA.ui32NumPrimitivesThisTA = 0;
gc->sSmallKickTA.ui32NumIndicesThisFrame = 0;
gc->sSmallKickTA.ui32NumPrimitivesThisFrame = 0;
/* Default value to ensure no TA splitting on the first frame */
gc->sSmallKickTA.ui32KickThreshold = 0xFFFFFFFF;
#endif
#if defined(DEBUG)
if(gc->sAppHints.bDumpShaderAnalysis)
{
gc->pShaderAnalysisHandle = OpenShaderAnalysisFile();
}
#endif /* defined(DEBUG) */
PDUMP_STRING_CONTINUOUS((gc, "PDump from OpenGL ES 2.0 driver, version %s. HW variant %s, %d\n",PVRVERSION_STRING, pszRenderer, SGX_CORE_REV));
return IMG_TRUE;
/* Clean up any memory */
FAILED_BuildExtensionString:
FAILED_CBUF_CreateBuffer:
for(i=0; i < CBUF_NUM_TA_BUFFERS; i++)
{
if(gc->apsBuffers[i])
{
CBUF_DestroyBuffer(gc->ps3DDevData, gc->apsBuffers[i]);
}
}
FAILED_InitSpecialUSECodeBlocks:
FreeVertexArrayObjectState(gc);
FAILED_CreateVertexArrayObjectState:
FreeFrameBufferState(gc);
FAILED_CreateFrameBufferState:
FreeBufObjState(gc);
FAILED_CreateBufObjState:
FreeProgramState(gc);
FAILED_CreateProgramState:
FreeTextureState(gc);
FAILED_CreateTextureState:
HashTableDestroy(gc, &gc->sProgram.sPDSFragmentVariantHashTable);
FAILED_CreateHashTable:
GLES2FREEDEVICEMEM(gc->ps3DDevData, gc->sKRMTAStatusUpdate.psMemInfo);
FAILED_TASync:
FreeContextSharedState(gc);
FAILED_CreateSharedState:
#if defined(FIX_HW_BRN_26922)
FreeBRN26922Mem(gc);
FAILED_AllocateBRN26922Mem:
#endif /* defined(FIX_HW_BRN_26922) */
return IMG_FALSE;
}
int transfer_SAM_to_assembly(global_context_t * global_context)
{
char linebuf[max(2*MAX_READ_LENGTH+300,3000)];
int allreads=0,mapped=0;
char mate_chro[MAX_CHROMOSOME_NAME_LEN+1];
unsigned int mate_pos;
int flags_mate;
char cigar_mate[EXON_MAX_CIGAR_LEN+1];
int is_warning_shown = 0;
HashTable * local_reassembly_pileup_files;
print_in_box(80,0,0,"Transforming the sam file into: %s", global_context->config.temp_file_prefix);
local_reassembly_pileup_files = HashTableCreate(100);
HashTableSetDeallocationFunctions(local_reassembly_pileup_files, NULL, NULL);
HashTableSetKeyComparisonFunction(local_reassembly_pileup_files, my_strcmp);
HashTableSetHashFunction(local_reassembly_pileup_files ,HashTableStringHashFunction);
while(1)
{
unsigned int read_anchor_position =0xffffffff;
char read_name[MAX_READ_NAME_LEN+1];
int flags;
char chro_name[MAX_CHROMOSOME_NAME_LEN+1];
unsigned int pos, pair_dist;
char cigar[EXON_MAX_CIGAR_LEN+1];
char read_text[MAX_READ_LENGTH+1];
char qual_text[MAX_READ_LENGTH+1];
int read_len, is_repeated, mapping_quality, is_anchor_certain=1;
int pos_delta = 0;
if(feof(global_context -> input_reads.first_read_file.input_fp))break;
read_text[0]=0;
qual_text[0]=0;
geinput_readline(&global_context -> input_reads.first_read_file, linebuf,0);
int res = parse_SAM_line(linebuf, read_name,& flags, chro_name, & pos, cigar, & mapping_quality, & pair_dist, read_text , qual_text, & read_len, & is_repeated);
int cigar_cursor = 0;
int firstM = 1,xx=0;
if(res == 0&& (flags &1) && (!global_context -> input_reads.is_paired_end_reads))
{
if(!is_warning_shown)
{
SUBREADprintf("Warning: the input seems to be paired end. You may like to specify '-p' option.\n");
is_warning_shown=1;
}
}
if(res==0)
{
for(; cigar[cigar_cursor]; cigar_cursor++)
{
char nch = cigar[cigar_cursor];
if(nch>='0'&&nch<='9')
{
xx=xx*10+(nch-'0');
}else
{
if(nch=='M') firstM=0;
else if(nch=='S')
{
if(firstM)
pos_delta = xx;
}
xx=0;
}
}
pos -= pos_delta;
}
if(res == 1) {chro_name[0]='*'; chro_name[1]=0;}
//printf("RES=%d\tMAPPED=%s,%u\n", res, chro_name, pos);
if(res == 0) // mapped
{
read_anchor_position = linear_gene_position(&global_context->chromosome_table , chro_name, pos) - 1;
//printf("MAPPED_LINEAR=%u\n", read_anchor_position);
mapped++;
}
else if(res == 1 && global_context -> input_reads.is_paired_end_reads) // unmapped
{
is_anchor_certain=0;
if(mate_chro[0])
{
if(mate_chro[0]!='*')
{
unsigned int mate_linear_pos = linear_gene_position(&global_context->chromosome_table , mate_chro, mate_pos) - 1;
read_anchor_position = mate_linear_pos + global_context -> config.expected_pair_distance * ((((flags_mate & SAM_FLAG_FIRST_READ_IN_PAIR) && (flags_mate & SAM_FLAG_REVERSE_STRAND_MATCHED))|| ((flags_mate & SAM_FLAG_SECOND_READ_IN_PAIR)&& (flags_mate & SAM_FLAG_REVERSE_STRAND_MATCHED))) ?-1:1);
}
//printf("RECOVERED 1: %u - %s ; LEN=%d ; YOU_ARE_FIRST=%d\n%s\n%s\n", read_anchor_position, read_name, read_len, flags_mate & SAM_FLAG_FIRST_READ_IN_PAIR, read_text, qual_text);
}
else
{
char read_text_null[MAX_READ_LENGTH+1];
char qual_text_null[MAX_READ_LENGTH+1];
int X_read_len=0;
geinput_readline_back(&global_context -> input_reads.first_read_file, linebuf);
res = parse_SAM_line(linebuf, read_name,& flags_mate, mate_chro, & mate_pos, cigar_mate, & mapping_quality, & pair_dist, read_text_null , qual_text_null, & X_read_len, & is_repeated);
if(res==0)
{
unsigned int mate_linear_pos = linear_gene_position(&global_context->chromosome_table , mate_chro, mate_pos) - 1;
read_anchor_position = mate_linear_pos + global_context -> config.expected_pair_distance * ((((flags_mate & SAM_FLAG_FIRST_READ_IN_PAIR) && (flags_mate & SAM_FLAG_REVERSE_STRAND_MATCHED))|| ((flags_mate & SAM_FLAG_SECOND_READ_IN_PAIR)&& (flags_mate & SAM_FLAG_REVERSE_STRAND_MATCHED))) ?-1:1);
}
//printf("RECOVERED 2: %u - %s ; LEN=%d ; YOU_ARE_FIRST=%d\n%s\n%s\n", read_anchor_position, read_name, read_len, flags_mate & SAM_FLAG_FIRST_READ_IN_PAIR, read_text, qual_text);
//read_anchor_position += (global_context -> config.expected_pair_distance/3) *((1.0*(read_anchor_position % 3751) - 3751/2) / 3751.);
}
if(read_anchor_position<0xffff0000)
{
if((flags_mate & SAM_FLAG_REVERSE_STRAND_MATCHED) == (flags & SAM_FLAG_REVERSE_STRAND_MATCHED))
{
reverse_read(read_text, read_len, global_context->config.space_type);
reverse_quality(qual_text, read_len);
}
}
}
//printf("R=%s; RL=%d; anchor=%u\n", read_name, read_len, read_anchor_position);
if(read_anchor_position<0xffff0000 && read_len >=2)
{
//if(!is_anchor_certain)printf("Uncertain Anchor at %u = %s\n", read_anchor_position, read_name);
//printf("INSERT LOCAL: %u\n", read_anchor_position);
write_local_reassembly(global_context, local_reassembly_pileup_files, read_anchor_position, read_name , read_text , qual_text , read_len, is_anchor_certain);
}
if(allreads %2==1)
mate_chro[0] = 0;
else
{
strcpy(mate_chro, chro_name);
mate_pos = pos ;
flags_mate = flags;
}
allreads++;
}
print_in_box(80,0,0,"Processed %d reads; %d mapped.\n", allreads, mapped);
destroy_pileup_table(local_reassembly_pileup_files);
return 0;
}
int handle_http_propfind(http_req * req, http_rsp * rsp)
{
int ret = OK;
HashElement * e = NULL;
int depth = -1;
HashHandle props = NULL_HANDLE;
CacheHandle cache = NULL_HANDLE;
char * propxml = NULL;
int contentlen = 0;
char * vpath = req->uri;
struct stat buf;
WEBLOG_API();
#ifdef WEBCFG_SUPPORT_AUTH
/* Authentication has a very high priority. */
if (OK != CheckAuthorization(req, rsp))
{
return handle_http_error(401, req, rsp);
}
#endif
if(OK != Webdav_CheckPath(req->uri))
{
WEBLOG_ERROR("<%s> PROPFIND is not allowed for non-webdav path [%s].\n", __FUNCTION__, req->uri);
handle_http_error(403, req, rsp);
ret = NG;
goto __error_out;
}
if(0 == strlen(vpath))
{
strcat(vpath, "/");
WEBLOG_VERBOSE("<%s> redirect to root path. [%s].\n", __FUNCTION__, vpath);
}
WEBLOG_INFO("<%s> stat the file \"%s\".\n", __FUNCTION__, vpath);
ret = stat(vpath, &buf);
/* Check if statistics are valid: */
if(ret != 0)
{
WEBLOG_ERROR("<%s> fail to stat the file \"%s\".\n", __FUNCTION__, vpath);
switch (errno)
{
case ENOENT:
WEBLOG_ERROR("<%s> File %s not found.\n", __FUNCTION__, vpath);
handle_http_error(404, req, rsp);
ret = NG;
goto __error_out;
case EINVAL: /* no break */
default:
/* Should never be reached. */
WEBLOG_ERROR("<%s> Unexpected error in _stat.\n", __FUNCTION__);
handle_http_error(500, req, rsp);
ret = NG;
goto __error_out;
}
}
props = HashTableCreate(64);
ASSERT(props != NULL_HANDLE);
/* get depth. */
e = HashLookup(req->headOptions, "Depth");
if(!e) depth = -1;
else if(e->value.data.string[0] == '0') depth = 0;
else if(e->value.data.string[0] == '1') depth = 1;
else depth = -1;
if(depth == -1 && TRUE == Webdav_isFolder(vpath))
{
WEBLOG_ERROR("<%s> PROPFIND a collection with infinite depth is not allowed.\n", __FUNCTION__);
handle_http_error(403, req, rsp);
ret = NG;
goto __error_out;
}
#ifdef WEBCFG_MINIMIZE_SERVER
#else
e = HashLookup(req->headOptions, "Content-Type");
if(e && strstr(e->value.data.string, "xml"))
{
char * xmlsockbuf = NULL;
char strbuf[128] = {0};
char *end, *p, *q;
HashValue eeee = HashString("", FALSE); // empty value!
WEBLOG_INFO("<%s> Client request props in a xml body.\n", __FUNCTION__);
e = HashLookup(req->headOptions, "Content-Length");
if(!e)
{
/* RFC2616, 14.23. */
WEBLOG_ERROR("<%s> Missing \"Content-Length\" for xml body.\n", __FUNCTION__);
handle_http_error(400, req, rsp);
ret = NG;
goto __error_out;
}
contentlen = atoi(e->value.data.string);
xmlsockbuf = (char *)webmalloc(contentlen+1);
memset(xmlsockbuf, 0, contentlen+1);
if(req->datalen > 0) // data left in head buffer.
{
memcpy(xmlsockbuf, req->sockbuf, req->datalen);
WEBLOG_VERBOSE("<%s> previous buffered %d/%d bytes consumed.\n",
__FUNCTION__, req->datalen, contentlen);
}
/* if there's more data in socket.... */
if (req->datalen < contentlen)
{
/* read rest of data from socket. */
p = xmlsockbuf + req->datalen;
req->datalen = recv(req->sock, p, contentlen-req->datalen, 0);
WEBLOG_VERBOSE("<%s> %d/%d bytes read from socket.\n",
__FUNCTION__, req->datalen, contentlen);
dumpText(xmlsockbuf, contentlen);
}
p = strstr(xmlsockbuf, "<prop>") + 6;
end = strstr(xmlsockbuf, "</prop>");
if(strstr(xmlsockbuf, "<allprop/>"))
{
WEBLOG_INFO("<%s> client request all props.\n", __FUNCTION__);
}
else
{
ASSERT(p<end);
*end = '\0'; /* good for str api. */
/* Possible Value:
WinXP: <propname/>
Cadaver: <propname xmlns="DAV:"/>
*/
do
{
p = strchr(p, '<');
if(!p) break;
else p++;
q = strstr(p, "/>");
ASSERT(q && (q-p < sizeof(strbuf)));
strncpy(strbuf, p, q-p);
p = strchr(strbuf, ' ');
if(p) *p = '\0';
p = strtrim(strbuf);
WEBLOG_INFO("<%s> client request prop: <%s>\n", __FUNCTION__, p);
HashAdd(props, p, eeee);
p = q + 2;
}
while(p<end); /* <xxx/>\r\n</prop> */
}
}
#endif
cache = CacheCreate();
Webdav_Props(props, cache, vpath, depth);
contentlen = CacheGetData(cache, &propxml);
ASSERT(propxml);
dumpText(propxml, contentlen);
WEBLOG_INFO("<%s> response xml ready. len %d.\n", __FUNCTION__, contentlen);
rsp->code = 207;
rsp->body = propxml;
http_add_rspoption(rsp, "Content-Type", "text/xml");
http_send_response(rsp);
__error_out:
if (props != NULL_HANDLE) HashTableDestroy(props);
if (cache != NULL_HANDLE) CacheDestroy(cache);
return ret;
}
/*
* Complements a scaffold; both complementing each contig within it and
* reversing the order of contigs in the scaffold.
*
* Returns 0 on success
* -1 on failure
*/
int complement_scaffold(GapIO *io, tg_rec srec) {
scaffold_t *f;
int i, j, nc = ArrayMax(io->contig_order);
scaffold_member_t *contigs;
tg_rec *crecs;
HashTable *h;
reg_order ro;
reg_buffer_start rs;
reg_buffer_end re;
if (!(f = cache_search(io, GT_Scaffold, srec)))
return -1;
if (!(f = cache_rw(io, f)))
return -1;
cache_incr(io, f);
/* Complement contigs */
contigs = ArrayBase(scaffold_member_t, f->contig);
for (i = 0; i < ArrayMax(f->contig); i++) {
complement_contig(io, contigs[i].rec);
}
/* Reverse the order of the contigs in the scaffold array */
for (i = 0, j = ArrayMax(f->contig)-1; i < j; i++, j--) {
scaffold_member_t cr1 = contigs[i];
contigs[i] = contigs[j];
contigs[j] = cr1;
}
/*
* Reverse the order of contigs in the contig_order array too.
* This is the part that really matters. It's also hard as the contigs
* in the contig order array could be in any order and not adjacent.
* For our purposes we'll just ensure the contigs in this scaffold in
* the contig order array match our freshly complemented scaffold
* ordering.
*
* We initially build a hash table of contigs in this scaffold, and
* then iterate through contig_order copying out the new contigs whenever
* one matches.
*/
h = HashTableCreate(nc, 0);
for (i = 0; i < ArrayMax(f->contig); i++) {
HashData hd;
hd.i = 0;
HashTableAdd(h, (char *)&contigs[i].rec, sizeof(tg_rec), hd, NULL);
}
/* Replace any contig matching the scaffold with the new order */
crecs = ArrayBase(tg_rec, io->contig_order);
for (i = j = 0; i < nc; i++) {
HashItem *hi;
if (!(hi = HashTableSearch(h, (char *)&crecs[i], sizeof(tg_rec))))
continue;
crecs[i] = contigs[j++].rec;
}
/* Send event messages around */
rs.job = REG_BUFFER_START;
for (i = 0; i < nc; i++) {
HashItem *hi;
if (!(hi = HashTableSearch(h, (char *)&crecs[i], sizeof(tg_rec))))
continue;
contig_notify(io, crecs[i], (reg_data *)&rs);
}
ro.job = REG_ORDER;
for (i = 0; i < nc; i++) {
HashItem *hi;
if (!(hi = HashTableSearch(h, (char *)&crecs[i], sizeof(tg_rec))))
continue;
ro.pos = i+1;
contig_notify(io, crecs[i], (reg_data *)&ro);
}
/* Notify the end of our updates */
re.job = REG_BUFFER_END;
for (i = 0; i < nc; i++) {
HashItem *hi;
if (!(hi = HashTableSearch(h, (char *)&crecs[i], sizeof(tg_rec))))
continue;
contig_notify(io, crecs[i], (reg_data *)&re);
}
HashTableDestroy(h, 0);
cache_decr(io, f);
return 0;
}
void StringQuarksCreate(void)
{
quarks = HashTableCreate(HASH_STRING, NULL);
}
