// these are useful for interpreting an INTPTR to an
// Object at runtime to retrieve the object's type
// or object id (OID)
-#define OBJPTRPTR_2_OBJTYPE( opp ) ((struct ___Object___*)*(opp))->type
-#define OBJPTRPTR_2_OBJOID( opp ) ((struct ___Object___*)*(opp))->oid
+#define OBJPTRPTR_2_OBJTYPE(opp) ((struct ___Object___*)*(opp))->type
+#define OBJPTRPTR_2_OBJOID(opp) ((struct ___Object___*)*(opp))->oid
// forwarding list elements is a linked
// a lot of items are on the list
#define FLIST_ITEMS_PER_ELEMENT 30
typedef struct ForwardingListElement_t {
- int numItems;
+ int numItems;
struct ForwardingListElement_t* nextElement;
- INTPTR items[FLIST_ITEMS_PER_ELEMENT];
+ INTPTR items[FLIST_ITEMS_PER_ELEMENT];
} ForwardingListElement;
struct MemPool_t;
// generated SESE record to this can be used, because
// the common structure is always the first item in a
// customized SESE record
-typedef struct SESEcommon_t {
+typedef struct SESEcommon_t {
// the identifier for the class of sese's that
// are instances of one particular static code block
// IMPORTANT: the class ID must be the first field of
// the task record so task dispatch works correctly!
int classID;
- volatile int unresolvedDependencies;
+ volatile int unresolvedDependencies;
// a parent waits on this semaphore when stalling on
// this child, the child gives it at its SESE exit
psemaphore* parentsStallSem;
-
+
// NOTE: first element is embedded in the task
// record, so don't free it!
//ForwardingListElement forwardList;
struct Queue forwardList;
- volatile int doneExecuting;
- volatile int numRunningChildren;
+ volatile int doneExecuting;
+ volatile int numRunningChildren;
struct SESEcommon_t* parent;
-
+
int numMemoryQueue;
int rentryIdx;
int unresolvedRentryIdx;
// the lock guards the following data SESE's
// use to coordinate with one another
pthread_mutex_t lock;
- pthread_cond_t runningChildrenCond;
+ pthread_cond_t runningChildrenCond;
} SESEcommon;
// a thread-local var refers to the currently
-typedef struct REntry_t{
- // fine read:0, fine write:1, parent read:2,
+typedef struct REntry_t {
+ // fine read:0, fine write:1, parent read:2,
// parent write:3 coarse: 4, parent coarse:5, scc: 6
int type;
#ifdef RCR
struct rcrRecord *next;
};
-typedef struct SESEstall_t {
+typedef struct SESEstall_t {
SESEcommon common;
int size;
void * next;
int total; //total non-retired
int status; //NOTREADY, READY
struct MemoryQueueItem_t *next;
-
+
} MemoryQueueItem;
typedef struct MemoryQueue_t {
MemoryQueueItem * head;
- MemoryQueueItem * tail;
+ MemoryQueueItem * tail;
REntry * binbuf[NUMBINS];
REntry * buf[NUMRENTRY];
int bufcount;
-static inline void ADD_FORWARD_ITEM( ForwardingListElement* e,
- SESEcommon* s ) {
+static inline void ADD_FORWARD_ITEM(ForwardingListElement* e,
+ SESEcommon* s) {
//atomic_inc( &(s->refCount) );
}
-// simple mechanical allocation and
+// simple mechanical allocation and
// deallocation of SESE records
-void* mlpAllocSESErecord( int size );
-void mlpFreeSESErecord( SESEcommon* seseRecord );
+void* mlpAllocSESErecord(int size);
+void mlpFreeSESErecord(SESEcommon* seseRecord);
MemoryQueue** mlpCreateMemoryQueueArray(int numMemoryQueue);
REntry* mlpCreateFineREntry(MemoryQueue *q, int type, SESEcommon* seseToIssue, void* dynID);
void resolvePointer(REntry* rentry);
#endif
-static inline void ADD_REFERENCE_TO( SESEcommon* seseRec ) {
- atomic_inc( &(seseRec->refCount) );
+static inline void ADD_REFERENCE_TO(SESEcommon* seseRec) {
+ atomic_inc(&(seseRec->refCount) );
}
-static inline int RELEASE_REFERENCE_TO( SESEcommon* seseRec ) {
- if( atomic_sub_and_test( 1, &(seseRec->refCount) ) ) {
- poolfreeinto( seseRec->parent->taskRecordMemPool, seseRec );
+static inline int RELEASE_REFERENCE_TO(SESEcommon* seseRec) {
+ if( atomic_sub_and_test(1, &(seseRec->refCount) ) ) {
+ poolfreeinto(seseRec->parent->taskRecordMemPool, seseRec);
return 1;
}
return 0;
}
-static inline int RELEASE_REFERENCES_TO( SESEcommon* seseRec, int refCount) {
- if( atomic_sub_and_test( refCount, &(seseRec->refCount) ) ) {
- poolfreeinto( seseRec->parent->taskRecordMemPool, seseRec );
+static inline int RELEASE_REFERENCES_TO(SESEcommon* seseRec, int refCount) {
+ if( atomic_sub_and_test(refCount, &(seseRec->refCount) ) ) {
+ poolfreeinto(seseRec->parent->taskRecordMemPool, seseRec);
return 1;
}
return 0;
////////////////////////////////////////////////
-//
+//
// Some available debug versions of the above
// pool allocation-related helpers. The lower
// 'x' appended to names means they are not hooked
// use them for debugging
//
////////////////////////////////////////////////
-#define ADD_REFERENCE_TOx(x) atomic_inc( &((x)->refCount) ); printf("0x%x ADD 0x%x on %d\n",(INTPTR)runningSESE,(INTPTR)(x),__LINE__);
+#define ADD_REFERENCE_TOx(x) atomic_inc(&((x)->refCount) ); printf("0x%x ADD 0x%x on %d\n",(INTPTR)runningSESE,(INTPTR)(x),__LINE__);
-#define RELEASE_REFERENCE_TOx(x) if (atomic_sub_and_test(1, &((x)->refCount))) {poolfreeinto(x->parent->taskRecordMemPool, x);printf("0x%x REL 0x%x on %d\n",(INTPTR)runningSESE,(INTPTR)(x),__LINE__);}
+#define RELEASE_REFERENCE_TOx(x) if (atomic_sub_and_test(1, &((x)->refCount))) {poolfreeinto(x->parent->taskRecordMemPool, x); printf("0x%x REL 0x%x on %d\n",(INTPTR)runningSESE,(INTPTR)(x),__LINE__); }
#define CHECK_RECORDx(x) { \
if( ((SESEcommon*)(x))->refCount < 0 || \
((SESEcommon*)(x))->refCount < 0 ) { \
- printf( "Acquired 0x%x from poolalloc, with refCount=%d\n", (INTPTR)(x), ((SESEcommon*)(x))->refCount ); } \
- }
+ printf("Acquired 0x%x from poolalloc, with refCount=%d\n", (INTPTR)(x), ((SESEcommon*)(x))->refCount); } \
+}
// pass this into the poolcreate so it will run your
// custom init code ONLY for fresh records, reused records
// can be returned as is
-void freshTaskRecordInitializer( void* seseRecord );
-
+void freshTaskRecordInitializer(void* seseRecord);
+
#endif /* __MLP_RUNTIME__ */