libcm/cmTaskMgr.c

1065 lines
27 KiB
C

#include "cmGlobal.h"
#include "cmRpt.h"
#include "cmErr.h"
#include "cmCtx.h"
#include "cmMem.h"
#include "cmMallocDebug.h"
#include "cmThread.h"
#include "cmTime.h"
#include "cmTaskMgr.h"
cmTaskMgrH_t cmTaskMgrNullHandle = cmSTATIC_NULL_HANDLE;
struct cmTmInst_str;
typedef struct cmTmTask_str
{
unsigned taskId;
cmChar_t* label;
cmTaskMgrFunc_t func;
struct cmTmTask_str* link;
} cmTmTask_t;
typedef struct cmTmInst_str
{
unsigned instId;
struct cmTmTask_str* task;
void* funcArg;
unsigned progCnt;
cmStatusTmId_t status;
void* result;
unsigned resultByteCnt;
cmTaskMgrCtlId_t ctlId; // ctlId must only be written from the client thread
bool deleteOnCompleteFl; // delete this instance when its status indicates that it is killed or complete
struct cmTmInst_str* link;
} cmTmInst_t;
struct cmTm_str* p;
typedef struct cmTmThread_str
{
struct cmTm_str* p; //
cmThreadH_t thH; //
cmTmInst_t* inst; // Ptr to the task instance this thread is executing.
double durSecs;
cmTimeSpec_t t0;
bool deactivateFl;
struct cmTmThread_str* link;
} cmTmThread_t;
typedef struct cmTm_str
{
cmErr_t err;
cmThreadH_t mstrThH; //
cmTmThread_t* threads; //
unsigned maxActiveThreadCnt; //
unsigned threadRecdCnt;
cmTaskMgrStatusCb_t statusCb; //
void* statusCbArg; //
unsigned pauseSleepMs; //
cmTs1p1cH_t inQueH; // client->mgr
cmTsMp1cH_t outQueH; // mgr->client
cmTmTask_t* tasks; //
cmTmInst_t* insts; //
unsigned nextInstId;
} cmTm_t;
void _cmTaskMgrStatusArgSetup(
cmTaskMgrStatusArg_t* s,
void* arg,
unsigned instId,
cmSelTmId_t selId,
cmStatusTmId_t statusId,
unsigned prog,
const cmChar_t* msg,
void* result,
unsigned resultByteCnt )
{
s->arg = arg;
s->instId = instId;
s->selId = selId;
s->statusId = statusId;
s->prog = prog;
s->msg = msg;
s->result = result;
s->resultByteCnt = resultByteCnt;
}
// WARNING: THIS FUNCTION IS CALLED BY BOTH THE WORKER AND THE MASTER THREAD.
cmTmRC_t _cmTmEnqueueStatusMsg0( cmTm_t* p, const cmTaskMgrStatusArg_t* s )
{
enum { arrayCnt = 3 };
const void* msgPtrArray[arrayCnt];
unsigned msgSizeArray[arrayCnt];
msgPtrArray[0] = s;
msgPtrArray[1] = s->msg==NULL ? "" : s->msg;
msgPtrArray[2] = s->result;
msgSizeArray[0] = sizeof(cmTaskMgrStatusArg_t);
msgSizeArray[1] = s->msg==NULL ? 1 : strlen(s->msg)+1;
msgSizeArray[2] = s->resultByteCnt;
if( cmTsMp1cEnqueueSegMsg(p->outQueH, msgPtrArray, msgSizeArray, arrayCnt ) != kOkThRC )
return kQueueFailTmRC;
return kOkTmRC;
}
// This function is called by the worker thread wrapper _cmTmWorkerStatusCb()
// function to enqueue messages being sent back to the client.
cmTmRC_t _cmTmEnqueueStatusMsg1(
cmTm_t* p,
unsigned instId,
cmSelTmId_t selId,
cmStatusTmId_t statusId,
unsigned prog,
const cmChar_t* msg,
void* result,
unsigned resultByteCnt )
{
cmTaskMgrStatusArg_t s;
_cmTaskMgrStatusArgSetup(&s,p->statusCbArg,instId,selId,statusId,prog,msg,result,resultByteCnt);
return _cmTmEnqueueStatusMsg0(p,&s);
}
// Worker threads call this function to enqueue status messages
// for delivery to the task mgr client.
void _cmTmWorkerStatusCb( const cmTaskMgrStatusArg_t* status )
{
cmTmThread_t* trp = (cmTmThread_t*)status->arg;
if( _cmTmEnqueueStatusMsg0( trp->p, status ) != kOkTmRC )
{
/// ??????? HOW DO WE HANDLE ERRORS IN THE WORKER THREAD
/// (set an error code in trp and let the master thread notice it.)
assert(0);
}
}
// This is the wrapper for all worker threads.
bool _cmTmWorkerThreadFunc(void* arg)
{
cmTmThread_t* trp = (cmTmThread_t*)arg;
cmTaskMgrFuncArg_t r;
r.reserved = trp;
r.arg = trp->inst->funcArg;
r.instId = trp->inst->instId;
r.statusCb = _cmTmWorkerStatusCb;
r.statusCbArg = trp;
r.progCnt = trp->inst->progCnt;
r.pauseSleepMs= trp->p->pauseSleepMs;
// if the task was paused or killed while it was queued then
// cmTaskMgrHandleCommand() will do the right thing
if( cmTaskMgrWorkerHandleCommand(&r) != kKillTmId )
{
trp->inst->status = kStartedTmId;
// Notify the client that the instance has started.
_cmTmEnqueueStatusMsg1(trp->p,trp->inst->instId,kStatusTmId,trp->inst->status,0,NULL,NULL,0);
// Execute the client provided task function.
trp->inst->task->func(&r);
}
// Notify the client that the instance has completed or been killed
if( trp->inst->ctlId == kKillTmId )
trp->inst->status = kKilledTmId;
else
trp->inst->status = kCompletedTmId;
_cmTmEnqueueStatusMsg1(trp->p,trp->inst->instId,kStatusTmId,trp->inst->status,0,NULL,NULL,0);
// Force the thread to go into the 'pause' state when it
// returns to it's internal loop. The master thread recognizes paused
// threads as available for reuse.
cmThreadPause(trp->thH,kPauseThFl);
return true;
}
void _cmTmMasterRptError( cmTm_t* p, unsigned rc, const cmChar_t* msg )
{
assert(0);
}
int _cmTmSortThreadByDur( const void* t0, const void* t1 )
{
double d = ((cmTmThread_t*)t0)->durSecs - ((cmTmThread_t*)t1)->durSecs;
return d== 0 ? 0 : (d<0 ? -1 : 1);
}
// This is the master thread function.
bool _cmTmMasterThreadFunc(void* arg)
{
cmTm_t* p = (cmTm_t*)arg;
unsigned activeCnt = 0;
cmTmThread_t* trp = p->threads;
if( p->threadRecdCnt > 0 )
{
cmTmThread_t* thArray[p->threadRecdCnt];
unsigned deactivatedCnt = 0;
// for each thread record
for(trp=p->threads; trp!=NULL; trp=trp->link)
{
cmThStateId_t thState;
// if this thread is active ...
if( (thState = cmThreadState(trp->thH)) != kPausedThId )
{
// update the task lifetime duration
cmTimeSpec_t t1;
cmTimeGet(&t1);
trp->durSecs += (double)cmTimeElapsedMicros(&trp->t0,&t1) / 1000000.0;
trp->t0 = t1;
assert(trp->inst!=NULL);
// if the task assoc'd with this thread is running
if( trp->inst->status == kStartedTmId )
{
thArray[activeCnt] = trp;
++activeCnt;
}
// count the number of deactivated threads
if( trp->deactivateFl )
++deactivatedCnt;
}
}
// The first 'activeCnt' elements of thArray[] now point to
// cmTmThread_t records of the active tasks.
// if more tasks are active than should be - then deactive the youngest
if( activeCnt > p->maxActiveThreadCnt )
{
// sort the active tasks in increasing order of lifetime
qsort(&thArray[0],activeCnt,sizeof(thArray[0]),_cmTmSortThreadByDur);
// determine the number of threads that need to be paused
int n = activeCnt - p->maxActiveThreadCnt;
int i;
// pause the active threads with the lowest lifetime
for(i=0; i<n ; ++i)
if( thArray[i]->deactivateFl == false )
{
thArray[i]->deactivateFl = true;
++deactivatedCnt;
}
}
// if there are deactivated tasks and the max thread count has not been reached
// then re-activate some of the deactivated tasks.
if( activeCnt < p->maxActiveThreadCnt && deactivatedCnt > 0 )
{
// sort the active tasks in increasing order of lifetime
qsort(&thArray[0],activeCnt,sizeof(thArray[0]),_cmTmSortThreadByDur);
int n = cmMin(p->maxActiveThreadCnt - activeCnt, deactivatedCnt );
int i;
// re-activate the oldest deactivated tasks
for(i=activeCnt-1; i>=0 && n>0; --i)
if( thArray[i]->deactivateFl )
{
thArray[i]->deactivateFl = false;
--n;
++activeCnt;
}
}
}
// if a queued task exists
while( cmTs1p1cMsgWaiting(p->inQueH) )
{
cmTmInst_t* ip = NULL;
cmTmThread_t* atrp = NULL;
activeCnt = 0;
// Find a worker thread that is in the 'paused' state.
// This is the definitive indication that the thread
// does not have an assigned instance
for(trp=p->threads; trp!=NULL; trp=trp->link)
{
if( cmThreadState(trp->thH) == kPausedThId )
atrp = trp;
else
++activeCnt;
}
// If the maximum number of active threads already exists then we cannot start a new task
if( activeCnt >= p->maxActiveThreadCnt )
break;
// If all the existing worker threads are busy
// but the maximum number of threads has not yet been allocated ...
if( atrp==NULL && p->threadRecdCnt < p->maxActiveThreadCnt)
{
// ... then create a new worker thread recd
atrp = cmMemAllocZ(cmTmThread_t,1);
// ... create the new worker thread
if( cmThreadCreate(&atrp->thH,_cmTmWorkerThreadFunc,atrp,p->err.rpt) != kOkThRC )
{
cmMemFree(atrp);
atrp = NULL;
_cmTmMasterRptError(p,kThreadFailTmRC,"Worker thread create failed.");
break;
}
else
{
// ... setup the new thread record
atrp->p = p;
atrp->link = p->threads;
p->threads = atrp;
p->threadRecdCnt += 1;
}
}
// if there are no available threads then give up
if( atrp == NULL )
break;
// dequeue a pending task instance pointer from the input queue
if(cmTs1p1cDequeueMsg(p->inQueH,&ip,sizeof(ip)) != kOkThRC )
{
_cmTmMasterRptError(p,kQueueFailTmRC,"Dequeue failed on incoming task instance queue.");
break;
}
// setup the thread record associated with the new task
atrp->inst = ip;
atrp->durSecs = 0;
atrp->deactivateFl = false;
// start the worker thread
if( cmThreadPause(atrp->thH,0) != kOkThRC )
_cmTmMasterRptError(p,kThreadFailTmRC,"Worker thread start failed.");
}
cmSleepMs(p->pauseSleepMs);
return true;
}
cmTm_t* _cmTmHandleToPtr( cmTaskMgrH_t h )
{
cmTm_t* p = (cmTm_t*)h.h;
assert( p != NULL );
return p;
}
cmTmTask_t* _cmTmTaskFromId( cmTm_t* p, unsigned taskId )
{
cmTmTask_t* tp;
for(tp=p->tasks; tp!=NULL; tp=tp->link)
if( tp->taskId == taskId )
return tp;
return NULL;
}
cmTmInst_t* _cmTmInstFromId( cmTm_t* p, unsigned instId )
{
cmTmInst_t* ip;
for(ip=p->insts; ip!=NULL; ip=ip->link)
if( ip->instId == instId )
return ip;
return NULL;
}
cmTmRC_t _cmTmInstFree( cmTm_t* p, unsigned instId )
{
cmTmInst_t* ip = p->insts;
cmTmInst_t* pp = NULL;
for(; ip!=NULL; ip=ip->link)
{
if( ip->instId == instId )
{
if( pp == NULL )
p->insts = ip->link;
else
pp->link = ip->link;
cmMemFree(ip->result);
cmMemFree(ip);
return kOkTmRC;
}
pp = ip;
}
return cmErrMsg(&p->err,kAssertFailTmRC,"The instance %i could not be found to be deleted.",instId);
}
cmTmRC_t _cmTmDestroy( cmTm_t* p )
{
cmTmRC_t rc = kOkTmRC;
unsigned i;
// stop and destroy the master thread
if( cmThreadDestroy(&p->mstrThH) != kOkThRC )
{
rc = cmErrMsg(&p->err,kThreadFailTmRC,"Master thread destroy failed.");
goto errLabel;
}
// stop and destroy all the worker threads
for(i=0; p->threads != NULL; ++i )
{
if( cmThreadDestroy(&p->threads->thH) != kOkThRC )
{
rc = cmErrMsg(&p->err,kThreadFailTmRC,"Thread destruction failed for the worker thread at index %i.",i);
goto errLabel;
}
cmTmThread_t* trp = p->threads;
p->threads = p->threads->link;
cmMemFree(trp);
}
// release the input queue
if( cmTs1p1cDestroy(&p->inQueH) != kOkThRC )
{
rc = cmErrMsg(&p->err,kQueueFailTmRC,"The input queue destroy failed.");
goto errLabel;
}
// draining the output queue
while( cmTsMp1cMsgWaiting(p->outQueH) )
if(cmTsMp1cDequeueMsg(p->outQueH,NULL,0) != kOkThRC )
cmErrMsg(&p->err,kQueueFailTmRC,"The output queue failed while draingin.");
// release the output queue
if( cmTsMp1cDestroy(&p->outQueH) != kOkThRC )
{
rc = cmErrMsg(&p->err,kQueueFailTmRC,"The input queue destroy failed.");
goto errLabel;
}
// release instance list
while( p->insts != NULL )
_cmTmInstFree(p,p->insts->instId);
// release the task list
cmTmTask_t* tp = p->tasks;
while( tp != NULL )
{
cmTmTask_t* np = tp->link;
cmMemFree(tp->label);
cmMemFree(tp);
tp = np;
}
cmMemFree(p);
errLabel:
return rc;
}
cmRC_t _cmTmMasterOutQueueCb(void* arg, unsigned msgByteCnt, const void* msgDataPtr );
cmTmRC_t cmTaskMgrCreate(
cmCtx_t* ctx,
cmTaskMgrH_t* hp,
cmTaskMgrStatusCb_t statusCb,
void* statusCbArg,
unsigned maxActiveThreadCnt,
unsigned queueByteCnt,
unsigned pauseSleepMs)
{
cmTmRC_t rc = kOkTmRC;
if((rc = cmTaskMgrDestroy(hp)) != kOkTmRC )
return rc;
cmTm_t* p = cmMemAllocZ(cmTm_t,1);
cmErrSetup(&p->err,&ctx->rpt,"Task Mgr.");
p->maxActiveThreadCnt = maxActiveThreadCnt;
p->statusCb = statusCb;
p->statusCbArg = statusCbArg;
p->pauseSleepMs = pauseSleepMs;
// create the master thread
if( cmThreadCreate(&p->mstrThH, _cmTmMasterThreadFunc,p,&ctx->rpt) != kOkThRC )
{
rc = cmErrMsg(&p->err,kThreadFailTmRC,"Thread index %i create failed.");
goto errLabel;
}
// create the input queue
if(cmTs1p1cCreate( &p->inQueH, queueByteCnt, NULL, NULL, p->err.rpt ) != kOkThRC )
{
rc = cmErrMsg(&p->err,kQueueFailTmRC,"The input queue creation failed.");
goto errLabel;
}
// create the output queue
if( cmTsMp1cCreate( &p->outQueH, queueByteCnt, _cmTmMasterOutQueueCb, p, p->err.rpt ) != kOkThRC )
{
rc = cmErrMsg(&p->err,kQueueFailTmRC,"The output queue creation failed.");
goto errLabel;
}
hp->h = p;
errLabel:
return rc;
}
cmTmRC_t cmTaskMgrDestroy( cmTaskMgrH_t* hp )
{
cmTmRC_t rc = kOkTmRC;
if( hp==NULL || cmTaskMgrIsValid(*hp)==false )
return rc;
cmTm_t* p = _cmTmHandleToPtr(*hp);
if((rc = _cmTmDestroy(p)) != kOkTmRC )
return rc;
hp->h = NULL;
return rc;
}
bool cmTaskMgrIsValid( cmTaskMgrH_t h )
{ return h.h != NULL; }
// This function is called by cmTaskMgrIdle() to dispatch
// status updates to the client.
cmRC_t _cmTmMasterOutQueueCb(void* arg, unsigned msgByteCnt, const void* msgDataPtr )
{
cmTm_t* p = (cmTm_t*)arg;
cmTaskMgrStatusArg_t s;
// This is probably not nesessary since changing the memory
// pointed to by msgDataPtr should be safe even though it is marked as const.
memcpy(&s,msgDataPtr,sizeof(s));
// The 'msg' and 'result' data have been serialized after the status record.
// The 'msg' is guaranteed to at least contain a terminating zero.
s.msg = ((char*)msgDataPtr) + sizeof(s);
// if the 'resultByteCnt' > 0 then there is a result record
if( s.resultByteCnt > 0 )
s.result = ((char*)msgDataPtr) + sizeof(s) + strlen(s.msg) + 1;
else
s.result = NULL;
s.arg = p->statusCbArg;
p->statusCb( &s );
return cmOkRC;
}
cmTmRC_t cmTaskMgrOnIdle( cmTaskMgrH_t h )
{
cmTmRC_t rc = kOkTmRC;
cmTm_t* p = _cmTmHandleToPtr(h);
// Transmit any msgs waiting to be sent to the client.
while( cmTsMp1cMsgWaiting(p->outQueH) )
{
// calling this function calls: _cmTmMasterOutQueueCb()
if(cmTsMp1cDequeueMsg(p->outQueH,NULL,0) != kOkThRC )
{
rc = cmErrMsg(&p->err,kQueueFailTmRC,"The output queue failed during a dequeue.");
goto errLabel;
}
}
// Step through the instance list and delete instances that are
// completed and also marked for deletion.
cmTmInst_t* ip = p->insts;
while( ip != NULL )
{
cmTmInst_t* np = ip->link;
if( (ip->status==kCompletedTmId || ip->status==kKilledTmId) && ip->deleteOnCompleteFl )
_cmTmInstFree(p,ip->instId);
ip = np;
}
errLabel:
return rc;
}
bool cmTaskMgrIsEnabled( cmTaskMgrH_t h )
{
cmTm_t* p = _cmTmHandleToPtr(h);
return cmThreadState(p->mstrThH) != kPausedThId;
}
cmTmRC_t cmTaskMgrEnable( cmTaskMgrH_t h, bool enableFl )
{
cmTmRC_t rc = kOkTmRC;
cmTm_t* p = _cmTmHandleToPtr(h);
unsigned flags = (enableFl ? 0 : kPauseThFl) | kWaitThFl;
if( cmThreadPause(p->mstrThH, flags ) != kOkThRC )
rc = cmErrMsg(&p->err,kThreadFailTmRC,"The master thread failed to %s.",enableFl ? "enable" : "disable" );
return rc;
}
cmTmRC_t cmTaskMgrInstall( cmTaskMgrH_t h, unsigned taskId, const cmChar_t* label, cmTaskMgrFunc_t func )
{
cmTmRC_t rc = kOkTmRC;
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmTask_t* tp = cmMemAllocZ(cmTmTask_t,1);
if( _cmTmTaskFromId(p,taskId) != NULL )
{
rc = cmErrMsg(&p->err,kInvalidArgTmRC,"The task id %i is already in use.",taskId);
goto errLabel;
}
tp->taskId = taskId;
tp->func = func;
tp->label = cmMemAllocStr(label);
tp->link = p->tasks;
p->tasks = tp;
errLabel:
return rc;
}
cmTmRC_t cmTaskMgrCall(
cmTaskMgrH_t h,
unsigned taskId,
void* funcArg,
unsigned progCnt,
unsigned* retInstIdPtr )
{
cmTmRC_t rc = kOkTmRC;
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmTask_t* tp = NULL;
cmTmInst_t* ip = NULL;
if( retInstIdPtr != NULL )
*retInstIdPtr = cmInvalidId;
// locate the task for this instance
if((tp = _cmTmTaskFromId(p,taskId)) == NULL )
{
rc = cmErrMsg(&p->err,kInvalidArgTmRC,"Task not found for task id=%i.",taskId);
goto errLabel;
}
// allocate a new instance record
ip = cmMemAllocZ(cmTmInst_t,1);
// setupt the instance record
ip->instId = p->nextInstId++;
ip->task = tp;
ip->funcArg = funcArg;
ip->progCnt = progCnt;
ip->status = kQueuedTmId;
// insert the new instance at the end of the instance list
if( p->insts == NULL )
p->insts = ip;
else
{
cmTmInst_t* pp = p->insts;
for(; pp != NULL; pp=pp->link )
if( pp->link == NULL )
{
pp->link = ip;
break;
}
}
// enque the instance ptr in the input queue
if( cmTs1p1cEnqueueMsg(p->inQueH,&ip,sizeof(ip)) != kOkThRC )
{
rc = cmErrMsg(&p->err,kQueueFailTmRC,"New task instance command enqueue failed.");
goto errLabel;
}
// set the returned instance id
if( retInstIdPtr != NULL )
*retInstIdPtr = ip->instId;
// notify the client that the instance was enqueued
cmTaskMgrStatusArg_t s;
_cmTaskMgrStatusArgSetup(&s,p->statusCbArg,ip->instId,kStatusTmId,kQueuedTmId,0,NULL,NULL,0);
p->statusCb( &s );
errLabel:
return rc;
}
cmTmRC_t cmTaskMgrTaskCtl( cmTaskMgrH_t h, unsigned instId, cmTaskMgrCtlId_t ctlId )
{
cmTmRC_t rc = kOkTmRC;
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmInst_t* ip = NULL;
if((ip = _cmTmInstFromId(p,instId)) == NULL )
{
cmErrMsg(&p->err,kInvalidArgTmRC,"The task instance associated with id %i could not be found.",instId);
goto errLabel;
}
// Once an instance ctlId is set to kKillTmId don't allow it to change.
if( ip->ctlId == kKillTmId )
return rc;
switch(ctlId )
{
case kNoneTmId:
break;
case kStartTmId:
// Acting on a 'start' cmd only makes sense if the previous command was 'pause'
if( ip->ctlId == kPauseTmId )
ip->ctlId = kStartTmId;
break;
case kPauseTmId:
// Acting on a 'pause' command only makes sense if this is the first command
// or the previous command was a 'start'
if( ip->ctlId == kNoneTmId || ip->ctlId == kStartTmId )
ip->ctlId = kPauseTmId;
break;
case kKillTmId:
ip->ctlId = kKillTmId;
break;
}
errLabel:
return rc;
}
cmStatusTmId_t cmTaskMgrStatus( cmTaskMgrH_t h, unsigned instId )
{
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmInst_t* ip = NULL;
cmStatusTmId_t status = kInvalidTmId;
if((ip = _cmTmInstFromId(p,instId)) == NULL )
{
cmErrMsg(&p->err,kInvalidArgTmRC,"The task instance associated with id %i could not be found.",instId);
goto errLabel;
}
status = ip->status;
errLabel:
return status;
}
const void* cmTaskMgrResult( cmTaskMgrH_t h, unsigned instId )
{
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmInst_t* ip = NULL;
if((ip = _cmTmInstFromId(p,instId)) == NULL )
{
cmErrMsg(&p->err,kInvalidArgTmRC,"The task instance associated with id %i could not be found.",instId);
return NULL;
}
return ip->result;
}
unsigned cmTaskMgrResultByteCount( cmTaskMgrH_t h, unsigned instId )
{
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmInst_t* ip = NULL;
if((ip = _cmTmInstFromId(p,instId)) == NULL )
{
cmErrMsg(&p->err,kInvalidArgTmRC,"The task instance associated with id %i could not be found.",instId);
return 0;
}
return ip->resultByteCnt;
}
cmTmRC_t cmTaskMgrInstDelete( cmTaskMgrH_t h, unsigned instId )
{
cmTmRC_t rc = kOkTmRC;
cmTm_t* p = _cmTmHandleToPtr(h);
cmTmInst_t* ip = NULL;
if((ip = _cmTmInstFromId(p,instId)) == NULL )
{
cmErrMsg(&p->err,kInvalidArgTmRC,"The task instance associated with id %i could not be found.",instId);
return 0;
}
ip->deleteOnCompleteFl = true;
return rc;
}
cmTaskMgrCtlId_t _cmTaskMgrWorkerHelper( cmTaskMgrFuncArg_t* a, unsigned prog, cmStatusTmId_t statusId )
{
cmTaskMgrStatusArg_t s;
_cmTaskMgrStatusArgSetup(
&s,
a->statusCbArg,
a->instId,
statusId == kInvalidTmId ? kProgTmId : kStatusTmId,
statusId == kInvalidTmId ? kStartedTmId : statusId,
statusId == kInvalidTmId ? prog : 0,
NULL,NULL,0);
a->statusCb(&s);
return cmTaskMgrWorkerHandleCommand(a);
}
cmTaskMgrCtlId_t cmTaskMgrWorkerHandleCommand( cmTaskMgrFuncArg_t* a )
{
cmTmThread_t* trp = a->reserved;
while( trp->inst->ctlId == kPauseTmId || trp->deactivateFl == true )
{
// change the instance status to 'paused'.
trp->inst->status = kPausedTmId;
// notify the client of the change in state
cmTaskMgrWorkerSendStatus(a,kPausedTmId);
// sleep the thread for pauseSleepMs milliseconds
cmSleepMs(a->pauseSleepMs);
// if the task was unpaused while we slept
if( trp->inst->ctlId == kStartTmId && trp->deactivateFl == false )
{
// change the instance status to 'started'.
trp->inst->status = kStartedTmId;
// notify the client of the change in state
cmTaskMgrWorkerSendStatus(a,kStartedTmId);
}
}
// if ctlId==kKillTmId then the status update will be handled
// when the task custom function returns in _cmTmWorkerThreadFunc()
return trp->inst->ctlId;
}
cmTaskMgrCtlId_t cmTaskMgrWorkerSendStatus( cmTaskMgrFuncArg_t* a, cmStatusTmId_t statusId )
{ return _cmTaskMgrWorkerHelper(a,0,statusId); }
cmTaskMgrCtlId_t cmTaskMgrWorkerSendProgress( cmTaskMgrFuncArg_t* a, unsigned prog )
{ return _cmTaskMgrWorkerHelper(a,prog,kInvalidTmId); }
//-----------------------------------------------------------------------------
enum { kMaxTestInstCnt = 3 };
typedef struct cmTmTestInst_str
{
unsigned instId;
} cmTmTestInst_t;
typedef struct cmTmTestApp_str
{
cmErr_t* err;
cmTmTestInst_t insts[kMaxTestInstCnt];
} cmTmTestApp_t;
void _cmTmTestReportStatus( cmRpt_t* rpt, const cmTaskMgrStatusArg_t* s )
{
cmRptPrintf(rpt,"inst:%i ",s->instId );
switch( s->selId )
{
case kStatusTmId:
{
const cmChar_t* label = "<none>";
switch( s->statusId )
{
case kInvalidTmId: label="<Invalid>"; break;
case kQueuedTmId: label="Queued"; break;
case kStartedTmId: label="Started"; break;
case kCompletedTmId: label="Completed"; break;
case kKilledTmId: label="Killed"; break;
default:
{ assert(0); }
}
cmRptPrintf(rpt,"status '%s'",label);
}
break;
case kProgTmId:
cmRptPrintf(rpt,"prog %i",s->prog);
break;
case kErrorTmId:
cmRptPrintf(rpt,"error %s",cmStringNullGuard(s->msg));
break;
default:
{ assert(0); }
}
cmRptPrintf(rpt,"\n");
}
// Test client status callback function.
void _cmTmTestStatusCb( const cmTaskMgrStatusArg_t* s )
{
// s.arg set from cmTaskMgrCreate( ..., statusCbArg, ...);
cmTmTestApp_t* app = (cmTmTestApp_t*)s->arg;
unsigned i;
// locate the instance record assoc'd with this callback
for(i=0; i<kMaxTestInstCnt; ++i)
if( app->insts[i].instId == s->instId )
break;
if( i==kMaxTestInstCnt )
cmRptPrintf(app->err->rpt,"instId %i not found.\n",s->instId);
_cmTmTestReportStatus(app->err->rpt,s);
}
// Test worker function.
void _cmTmTestFunc(cmTaskMgrFuncArg_t* arg )
{
if( cmTaskMgrWorkerHandleCommand(arg) == kKillTmId )
return;
unsigned prog = 0;
for(; prog<arg->progCnt; ++prog)
{
if( cmTaskMgrWorkerHandleCommand(arg) == kKillTmId )
break;
cmSleepMs(1000);
if( cmTaskMgrWorkerSendProgress(arg,prog) == kKillTmId )
break;
}
}
cmTmRC_t cmTaskMgrTest(cmCtx_t* ctx)
{
cmTmRC_t rc = kOkTmRC;
cmTaskMgrH_t tmH = cmTaskMgrNullHandle;
unsigned threadCnt = 2;
unsigned queueByteCnt = 1024;
unsigned pauseSleepMs = 50;
unsigned nextInstId = 0;
unsigned taskId = 0;
const cmChar_t* taskLabel = "Task Label";
cmTmTestApp_t app;
char c;
memset(&app,0,sizeof(app));
app.err = &ctx->err;
// create the task mgr
if( cmTaskMgrCreate( ctx,&tmH,_cmTmTestStatusCb,&app,threadCnt,queueByteCnt,pauseSleepMs) != kOkTmRC )
{
rc = cmErrMsg(&ctx->err,kTestFailTmRC,"Task mgr create failed.");
goto errLabel;
}
// install a task
if( cmTaskMgrInstall(tmH, taskId, taskLabel, _cmTmTestFunc ) != kOkTmRC )
{
rc = cmErrMsg(&ctx->err,kTestFailTmRC,"Task mgr task install failed.");
goto errLabel;
}
// go into interactive mode
printf("q=quit e=enable c=call i=idle\n");
while((c = getchar()) != 'q')
{
switch(c)
{
case 'i':
cmTaskMgrOnIdle(tmH);
cmRptPrintf(&ctx->rpt,"idled\n");
break;
case 'e':
{
// toggle the enable state of the task mgr.
bool fl = !cmTaskMgrIsEnabled(tmH);
if( cmTaskMgrEnable(tmH,fl) != kOkTmRC )
rc = cmErrMsg(&ctx->err,kTestFailTmRC,"Test enable failed.");
else
cmRptPrintf(&ctx->rpt,"%s\n", fl ? "enabled" : "disabled" );
}
break;
case 'c':
if( nextInstId < kMaxTestInstCnt )
{
void* funcArg = app.insts + nextInstId;
unsigned progCnt = 5;
if( cmTaskMgrCall( tmH, taskId, funcArg, progCnt, &app.insts[nextInstId].instId ) != kOkTmRC )
rc = cmErrMsg(&ctx->err,kTestFailTmRC,"Test call failed.");
else
{
++nextInstId;
cmRptPrintf(&ctx->rpt,"called\n");
}
}
}
}
errLabel:
// destroy the task mgr
if( cmTaskMgrDestroy(&tmH) != kOkTmRC )
rc = cmErrMsg(&ctx->err,kTestFailTmRC,"Task mgr destroy failed.");
return rc;
}