/*
* ======== NTFY_Delete ========
* Purpose:
* Free resources allocated in NTFY_Create.
*/
void NTFY_Delete(struct NTFY_OBJECT *hNtfy)
{
struct NOTIFICATION *pNotify;
DBC_Require(MEM_IsValidHandle(hNtfy, NTFY_SIGNATURE));
/* Remove any elements remaining in list */
if (hNtfy->notifyList) {
(void) SYNC_EnterCS(hNtfy->hSync);
while ((pNotify = (struct NOTIFICATION *)LST_GetHead(hNtfy->
notifyList))) {
DeleteNotify(pNotify);
}
DBC_Assert(LST_IsEmpty(hNtfy->notifyList));
kfree(hNtfy->notifyList);
(void) SYNC_LeaveCS(hNtfy->hSync);
}
if (hNtfy->hSync)
(void)SYNC_DeleteCS(hNtfy->hSync);
MEM_FreeObject(hNtfy);
}
/*
* ======== FreeChirpList ========
* Purpose:
* Free the queue of Chirps.
*/
static void FreeChirpList(struct LST_LIST *pChirpList)
{
DBC_Require(pChirpList != NULL);
while (!LST_IsEmpty(pChirpList))
kfree(LST_GetHead(pChirpList));
kfree(pChirpList);
}
/*
* ======== WMD_CHNL_CancelIO ========
* Return all I/O requests to the client which have not yet been
* transferred. The channel's I/O completion object is
* signalled, and all the I/O requests are queued as IOC's, with the
* status field set to CHNL_IOCSTATCANCEL.
* This call is typically used in abort situations, and is a prelude to
* CHNL_Close();
*/
DSP_STATUS WMD_CHNL_CancelIO(struct CHNL_OBJECT *hChnl)
{
DSP_STATUS status = DSP_SOK;
struct CHNL_OBJECT *pChnl = (struct CHNL_OBJECT *)hChnl;
u32 iChnl = -1;
short int uMode;
struct CHNL_IRP *pChirp;
struct CHNL_MGR *pChnlMgr = NULL;
/* Check args: */
if (MEM_IsValidHandle(pChnl, CHNL_SIGNATURE) && pChnl->pChnlMgr) {
iChnl = pChnl->uId;
uMode = pChnl->uMode;
pChnlMgr = pChnl->pChnlMgr;
} else {
status = DSP_EHANDLE;
}
if (DSP_FAILED(status))
goto func_end;
/* Mark this channel as cancelled, to prevent further IORequests or
* IORequests or dispatching. */
SYNC_EnterCS(pChnlMgr->hCSObj);
pChnl->dwState |= CHNL_STATECANCEL;
if (LST_IsEmpty(pChnl->pIORequests))
goto func_cont;
if (pChnl->uChnlType == CHNL_PCPY) {
/* Indicate we have no more buffers available for transfer: */
if (CHNL_IsInput(pChnl->uMode)) {
IO_CancelChnl(pChnlMgr->hIOMgr, iChnl);
} else {
/* Record that we no longer have output buffers
* available: */
pChnlMgr->dwOutputMask &= ~(1 << iChnl);
}
}
/* Move all IOR's to IOC queue: */
while (!LST_IsEmpty(pChnl->pIORequests)) {
pChirp = (struct CHNL_IRP *)LST_GetHead(pChnl->pIORequests);
if (pChirp) {
pChirp->cBytes = 0;
pChirp->status |= CHNL_IOCSTATCANCEL;
LST_PutTail(pChnl->pIOCompletions,
(struct list_head *)pChirp);
pChnl->cIOCs++;
pChnl->cIOReqs--;
DBC_Assert(pChnl->cIOReqs >= 0);
}
}
func_cont:
SYNC_LeaveCS(pChnlMgr->hCSObj);
func_end:
return status;
}
/*
* ======== DeleteMsgQueue ========
*/
static void DeleteMsgQueue(struct MSG_QUEUE *hMsgQueue, u32 uNumToDSP)
{
struct MSG_MGR *hMsgMgr;
struct MSG_FRAME *pMsg;
u32 i;
if (!MEM_IsValidHandle(hMsgQueue, MSGQ_SIGNATURE)
|| !hMsgQueue->hMsgMgr || !hMsgQueue->hMsgMgr->msgFreeList)
goto func_end;
hMsgMgr = hMsgQueue->hMsgMgr;
/* Pull off uNumToDSP message frames from Msg manager and free */
for (i = 0; i < uNumToDSP; i++) {
if (!LST_IsEmpty(hMsgMgr->msgFreeList)) {
pMsg = (struct MSG_FRAME *)LST_GetHead(hMsgMgr->
msgFreeList);
MEM_Free(pMsg);
} else {
/* Cannot free all of the message frames */
break;
}
}
if (hMsgQueue->msgFreeList) {
FreeMsgList(hMsgQueue->msgFreeList);
hMsgQueue->msgFreeList = NULL;
}
if (hMsgQueue->msgUsedList) {
FreeMsgList(hMsgQueue->msgUsedList);
hMsgQueue->msgUsedList = NULL;
}
if (hMsgQueue->hNtfy)
NTFY_Delete(hMsgQueue->hNtfy);
if (hMsgQueue->hSyncEvent)
SYNC_CloseEvent(hMsgQueue->hSyncEvent);
if (hMsgQueue->hSyncDone)
SYNC_CloseEvent(hMsgQueue->hSyncDone);
if (hMsgQueue->hSyncDoneAck)
SYNC_CloseEvent(hMsgQueue->hSyncDoneAck);
MEM_FreeObject(hMsgQueue);
func_end:
return;
}
/*
* ======== FreeMsgList ========
*/
static void FreeMsgList(struct LST_LIST *msgList)
{
struct MSG_FRAME *pMsg;
if (!msgList)
goto func_end;
while ((pMsg = (struct MSG_FRAME *)LST_GetHead(msgList)) != NULL)
MEM_Free(pMsg);
DBC_Assert(LST_IsEmpty(msgList));
LST_Delete(msgList);
func_end:
return;
}
/*
* ======== RMM_delete ========
*/
void RMM_delete(struct RMM_TargetObj *target)
{
struct RMM_OvlySect *pSect;
struct RMM_Header *hptr;
struct RMM_Header *next;
u32 i;
DBC_Require(MEM_IsValidHandle(target, RMM_TARGSIGNATURE));
GT_1trace(RMM_debugMask, GT_ENTER, "RMM_delete(0x%lx)\n", target);
if (target->segTab != NULL)
MEM_Free(target->segTab);
if (target->ovlyList) {
while ((pSect = (struct RMM_OvlySect *)LST_GetHead
(target->ovlyList))) {
MEM_Free(pSect);
}
DBC_Assert(LST_IsEmpty(target->ovlyList));
LST_Delete(target->ovlyList);
}
if (target->freeList != NULL) {
/* Free elements on freelist */
for (i = 0; i < target->numSegs; i++) {
hptr = next = target->freeList[i];
while (next) {
hptr = next;
next = hptr->next;
MEM_Free(hptr);
}
}
MEM_Free(target->freeList);
}
MEM_FreeObject(target);
}
/*
* ======== WMD_CHNL_AddIOReq ========
* Enqueue an I/O request for data transfer on a channel to the DSP.
* The direction (mode) is specified in the channel object. Note the DSP
* address is specified for channels opened in direct I/O mode.
*/
DSP_STATUS WMD_CHNL_AddIOReq(struct CHNL_OBJECT *hChnl, void *pHostBuf,
u32 cBytes, u32 cBufSize,
OPTIONAL u32 dwDspAddr, u32 dwArg)
{
DSP_STATUS status = DSP_SOK;
struct CHNL_OBJECT *pChnl = (struct CHNL_OBJECT *)hChnl;
struct CHNL_IRP *pChirp = NULL;
struct WMD_DEV_CONTEXT *dev_ctxt;
struct DEV_OBJECT *dev_obj;
u32 dwState;
bool fIsEOS;
struct CHNL_MGR *pChnlMgr = pChnl->pChnlMgr;
u8 *pHostSysBuf = NULL;
bool fSchedDPC = false;
u16 wMbVal = 0;
fIsEOS = (cBytes == 0);
/* Validate args: */
if (pHostBuf == NULL) {
status = DSP_EPOINTER;
} else if (!MEM_IsValidHandle(pChnl, CHNL_SIGNATURE)) {
status = DSP_EHANDLE;
} else if (fIsEOS && CHNL_IsInput(pChnl->uMode)) {
status = CHNL_E_NOEOS;
} else {
/* Check the channel state: only queue chirp if channel state
* allows */
dwState = pChnl->dwState;
if (dwState != CHNL_STATEREADY) {
if (dwState & CHNL_STATECANCEL)
status = CHNL_E_CANCELLED;
else if ((dwState & CHNL_STATEEOS)
&& CHNL_IsOutput(pChnl->uMode))
status = CHNL_E_EOS;
else
/* No other possible states left: */
DBC_Assert(0);
}
}
dev_obj = DEV_GetFirst();
DEV_GetWMDContext(dev_obj, &dev_ctxt);
if (!dev_ctxt)
status = DSP_EHANDLE;
if (DSP_FAILED(status))
goto func_end;
if (pChnl->uChnlType == CHNL_PCPY && pChnl->uId > 1 && pHostBuf) {
if (!(pHostBuf < (void *)USERMODE_ADDR)) {
pHostSysBuf = pHostBuf;
goto func_cont;
}
/* if addr in user mode, then copy to kernel space */
pHostSysBuf = MEM_Alloc(cBufSize, MEM_NONPAGED);
if (pHostSysBuf == NULL) {
status = DSP_EMEMORY;
goto func_end;
}
if (CHNL_IsOutput(pChnl->uMode)) {
status = copy_from_user(pHostSysBuf, pHostBuf,
cBufSize);
if (status) {
kfree(pHostSysBuf);
pHostSysBuf = NULL;
status = DSP_EPOINTER;
goto func_end;
}
}
}
func_cont:
/* Mailbox IRQ is disabled to avoid race condition with DMA/ZCPY
* channels. DPCCS is held to avoid race conditions with PCPY channels.
* If DPC is scheduled in process context (IO_Schedule) and any
* non-mailbox interrupt occurs, that DPC will run and break CS. Hence
* we disable ALL DPCs. We will try to disable ONLY IO DPC later. */
SYNC_EnterCS(pChnlMgr->hCSObj);
omap_mbox_disable_irq(dev_ctxt->mbox, IRQ_RX);
if (pChnl->uChnlType == CHNL_PCPY) {
/* This is a processor-copy channel. */
if (DSP_SUCCEEDED(status) && CHNL_IsOutput(pChnl->uMode)) {
/* Check buffer size on output channels for fit. */
if (cBytes > IO_BufSize(pChnl->pChnlMgr->hIOMgr))
status = CHNL_E_BUFSIZE;
}
}
if (DSP_SUCCEEDED(status)) {
/* Get a free chirp: */
pChirp = (struct CHNL_IRP *)LST_GetHead(pChnl->pFreeList);
if (pChirp == NULL)
status = CHNL_E_NOIORPS;
}
if (DSP_SUCCEEDED(status)) {
/* Enqueue the chirp on the chnl's IORequest queue: */
pChirp->pHostUserBuf = pChirp->pHostSysBuf = pHostBuf;
if (pChnl->uChnlType == CHNL_PCPY && pChnl->uId > 1)
pChirp->pHostSysBuf = pHostSysBuf;
/*
* Note: for dma chans dwDspAddr contains dsp address
* of SM buffer.
*/
DBC_Assert(pChnlMgr->uWordSize != 0);
/* DSP address */
pChirp->uDspAddr = dwDspAddr / pChnlMgr->uWordSize;
pChirp->cBytes = cBytes;
pChirp->cBufSize = cBufSize;
/* Only valid for output channel */
pChirp->dwArg = dwArg;
pChirp->status = (fIsEOS ? CHNL_IOCSTATEOS :
CHNL_IOCSTATCOMPLETE);
LST_PutTail(pChnl->pIORequests, (struct list_head *)pChirp);
pChnl->cIOReqs++;
DBC_Assert(pChnl->cIOReqs <= pChnl->cChirps);
/* If end of stream, update the channel state to prevent
* more IOR's: */
if (fIsEOS)
pChnl->dwState |= CHNL_STATEEOS;
/* Legacy DSM Processor-Copy */
DBC_Assert(pChnl->uChnlType == CHNL_PCPY);
/* Request IO from the DSP */
IO_RequestChnl(pChnlMgr->hIOMgr, pChnl,
(CHNL_IsInput(pChnl->uMode) ? IO_INPUT : IO_OUTPUT),
&wMbVal);
fSchedDPC = true;
}
omap_mbox_enable_irq(dev_ctxt->mbox, IRQ_RX);
SYNC_LeaveCS(pChnlMgr->hCSObj);
if (wMbVal != 0)
IO_IntrDSP2(pChnlMgr->hIOMgr, wMbVal);
/* Schedule a DPC, to do the actual data transfer: */
if (fSchedDPC)
IO_Schedule(pChnlMgr->hIOMgr);
func_end:
return status;
}
/*
* ======== WMD_CHNL_GetIOC ========
* Optionally wait for I/O completion on a channel. Dequeue an I/O
* completion record, which contains information about the completed
* I/O request.
* Note: Ensures Channel Invariant (see notes above).
*/
DSP_STATUS WMD_CHNL_GetIOC(struct CHNL_OBJECT *hChnl, u32 dwTimeOut,
OUT struct CHNL_IOC *pIOC)
{
DSP_STATUS status = DSP_SOK;
struct CHNL_OBJECT *pChnl = (struct CHNL_OBJECT *)hChnl;
struct CHNL_IRP *pChirp;
DSP_STATUS statSync;
bool fDequeueIOC = true;
struct CHNL_IOC ioc = { NULL, 0, 0, 0, 0 };
u8 *pHostSysBuf = NULL;
struct WMD_DEV_CONTEXT *dev_ctxt;
struct DEV_OBJECT *dev_obj;
/* Check args: */
if (pIOC == NULL) {
status = DSP_EPOINTER;
} else if (!MEM_IsValidHandle(pChnl, CHNL_SIGNATURE)) {
status = DSP_EHANDLE;
} else if (dwTimeOut == CHNL_IOCNOWAIT) {
if (LST_IsEmpty(pChnl->pIOCompletions))
status = CHNL_E_NOIOC;
}
dev_obj = DEV_GetFirst();
DEV_GetWMDContext(dev_obj, &dev_ctxt);
if (!dev_ctxt)
status = DSP_EHANDLE;
if (DSP_FAILED(status))
goto func_end;
ioc.status = CHNL_IOCSTATCOMPLETE;
if (dwTimeOut != CHNL_IOCNOWAIT && LST_IsEmpty(pChnl->pIOCompletions)) {
if (dwTimeOut == CHNL_IOCINFINITE)
dwTimeOut = SYNC_INFINITE;
statSync = SYNC_WaitOnEvent(pChnl->hSyncEvent, dwTimeOut);
if (statSync == DSP_ETIMEOUT) {
/* No response from DSP */
ioc.status |= CHNL_IOCSTATTIMEOUT;
fDequeueIOC = false;
} else if (statSync == DSP_EFAIL) {
/* This can occur when the user mode thread is
* aborted (^C), or when _VWIN32_WaitSingleObject()
* fails due to unkown causes. */
/* Even though Wait failed, there may be something in
* the Q: */
if (LST_IsEmpty(pChnl->pIOCompletions)) {
ioc.status |= CHNL_IOCSTATCANCEL;
fDequeueIOC = false;
}
}
}
/* See comment in AddIOReq */
SYNC_EnterCS(pChnl->pChnlMgr->hCSObj);
omap_mbox_disable_irq(dev_ctxt->mbox, IRQ_RX);
if (fDequeueIOC) {
/* Dequeue IOC and set pIOC; */
DBC_Assert(!LST_IsEmpty(pChnl->pIOCompletions));
pChirp = (struct CHNL_IRP *)LST_GetHead(pChnl->pIOCompletions);
/* Update pIOC from channel state and chirp: */
if (pChirp) {
pChnl->cIOCs--;
/* If this is a zero-copy channel, then set IOC's pBuf
* to the DSP's address. This DSP address will get
* translated to user's virtual addr later. */
{
pHostSysBuf = pChirp->pHostSysBuf;
ioc.pBuf = pChirp->pHostUserBuf;
}
ioc.cBytes = pChirp->cBytes;
ioc.cBufSize = pChirp->cBufSize;
ioc.dwArg = pChirp->dwArg;
ioc.status |= pChirp->status;
/* Place the used chirp on the free list: */
LST_PutTail(pChnl->pFreeList,
(struct list_head *)pChirp);
} else {
ioc.pBuf = NULL;
ioc.cBytes = 0;
}
} else {
ioc.pBuf = NULL;
ioc.cBytes = 0;
ioc.dwArg = 0;
ioc.cBufSize = 0;
}
/* Ensure invariant: If any IOC's are queued for this channel... */
if (!LST_IsEmpty(pChnl->pIOCompletions)) {
/* Since DSPStream_Reclaim() does not take a timeout
* parameter, we pass the stream's timeout value to
* WMD_CHNL_GetIOC. We cannot determine whether or not
* we have waited in User mode. Since the stream's timeout
* value may be non-zero, we still have to set the event.
* Therefore, this optimization is taken out.
*
* if (dwTimeOut == CHNL_IOCNOWAIT) {
* ... ensure event is set..
* SYNC_SetEvent(pChnl->hSyncEvent);
* } */
SYNC_SetEvent(pChnl->hSyncEvent);
} else {
/* else, if list is empty, ensure event is reset. */
SYNC_ResetEvent(pChnl->hSyncEvent);
}
omap_mbox_enable_irq(dev_ctxt->mbox, IRQ_RX);
SYNC_LeaveCS(pChnl->pChnlMgr->hCSObj);
if (fDequeueIOC && (pChnl->uChnlType == CHNL_PCPY && pChnl->uId > 1)) {
if (!(ioc.pBuf < (void *) USERMODE_ADDR))
goto func_cont;
/* If the addr is in user mode, then copy it */
if (!pHostSysBuf || !ioc.pBuf) {
status = DSP_EPOINTER;
goto func_cont;
}
if (!CHNL_IsInput(pChnl->uMode))
goto func_cont1;
/*pHostUserBuf */
status = copy_to_user(ioc.pBuf, pHostSysBuf, ioc.cBytes);
if (status) {
if (current->flags & PF_EXITING)
status = 0;
}
if (status)
status = DSP_EPOINTER;
func_cont1:
kfree(pHostSysBuf);
}
func_cont:
/* Update User's IOC block: */
*pIOC = ioc;
func_end:
return status;
}
/*
* ======== WMD_CHNL_GetIOC ========
* Optionally wait for I/O completion on a channel. Dequeue an I/O
* completion record, which contains information about the completed
* I/O request.
* Note: Ensures Channel Invariant (see notes above).
*/
DSP_STATUS WMD_CHNL_GetIOC(struct CHNL_OBJECT *hChnl, u32 dwTimeOut,
OUT struct CHNL_IOC *pIOC)
{
DSP_STATUS status = DSP_SOK;
struct CHNL_OBJECT *pChnl = (struct CHNL_OBJECT *)hChnl;
struct CHNL_IRP *pChirp;
DSP_STATUS statSync;
bool fDequeueIOC = true;
struct CHNL_IOC ioc = { NULL, 0, 0, 0, 0 };
u8 *pHostSysBuf = NULL;
DBG_Trace(DBG_ENTER, "> WMD_CHNL_GetIOC pChnl %p CHNL_IsOutput %x "
"uChnlType %x\n", pChnl, CHNL_IsOutput(pChnl->uMode),
pChnl->uChnlType);
/* Check args: */
if (pIOC == NULL) {
status = DSP_EPOINTER;
} else if (!MEM_IsValidHandle(pChnl, CHNL_SIGNATURE)) {
status = DSP_EHANDLE;
} else if (dwTimeOut == CHNL_IOCNOWAIT) {
if (LST_IsEmpty(pChnl->pIOCompletions))
status = CHNL_E_NOIOC;
}
if (DSP_FAILED(status))
goto func_end;
ioc.status = CHNL_IOCSTATCOMPLETE;
if (dwTimeOut != CHNL_IOCNOWAIT && LST_IsEmpty(pChnl->pIOCompletions)) {
if (dwTimeOut == CHNL_IOCINFINITE)
dwTimeOut = SYNC_INFINITE;
statSync = SYNC_WaitOnEvent(pChnl->hSyncEvent, dwTimeOut);
if (statSync == DSP_ETIMEOUT) {
/* No response from DSP */
ioc.status |= CHNL_IOCSTATTIMEOUT;
fDequeueIOC = false;
} else if (statSync == DSP_EFAIL) {
/* This can occur when the user mode thread is
* aborted (^C), or when _VWIN32_WaitSingleObject()
* fails due to unkown causes. */
/* Even though Wait failed, there may be something in
* the Q: */
if (LST_IsEmpty(pChnl->pIOCompletions)) {
ioc.status |= CHNL_IOCSTATCANCEL;
fDequeueIOC = false;
}
}
}
/* See comment in AddIOReq */
SYNC_EnterCS(pChnl->pChnlMgr->hCSObj);
disable_irq(MAILBOX_IRQ);
if (fDequeueIOC) {
/* Dequeue IOC and set pIOC; */
DBC_Assert(!LST_IsEmpty(pChnl->pIOCompletions));
pChirp = (struct CHNL_IRP *)LST_GetHead(pChnl->pIOCompletions);
/* Update pIOC from channel state and chirp: */
if (pChirp) {
pChnl->cIOCs--;
/* If this is a zero-copy channel, then set IOC's pBuf
* to the DSP's address. This DSP address will get
* translated to user's virtual addr later. */
{
pHostSysBuf = pChirp->pHostSysBuf;
ioc.pBuf = pChirp->pHostUserBuf;
}
ioc.cBytes = pChirp->cBytes;
ioc.cBufSize = pChirp->cBufSize;
ioc.dwArg = pChirp->dwArg;
ioc.status |= pChirp->status;
/* Place the used chirp on the free list: */
LST_PutTail(pChnl->pFreeList, (struct LST_ELEM *)
pChirp);
} else {
ioc.pBuf = NULL;
ioc.cBytes = 0;
}
} else {
ioc.pBuf = NULL;
ioc.cBytes = 0;
ioc.dwArg = 0;
ioc.cBufSize = 0;
}
/* Ensure invariant: If any IOC's are queued for this channel... */
if (!LST_IsEmpty(pChnl->pIOCompletions)) {
/* Since DSPStream_Reclaim() does not take a timeout
* parameter, we pass the stream's timeout value to
* WMD_CHNL_GetIOC. We cannot determine whether or not
* we have waited in User mode. Since the stream's timeout
* value may be non-zero, we still have to set the event.
* Therefore, this optimization is taken out.
*
* if (dwTimeOut == CHNL_IOCNOWAIT) {
* ... ensure event is set..
* SYNC_SetEvent(pChnl->hSyncEvent);
* } */
SYNC_SetEvent(pChnl->hSyncEvent);
} else {
/* else, if list is empty, ensure event is reset. */
SYNC_ResetEvent(pChnl->hSyncEvent);
}
enable_irq(MAILBOX_IRQ);
SYNC_LeaveCS(pChnl->pChnlMgr->hCSObj);
if (fDequeueIOC && (pChnl->uChnlType == CHNL_PCPY && pChnl->uId > 1)) {
if (!(ioc.pBuf < (void *) USERMODE_ADDR))
goto func_cont;
/* If the addr is in user mode, then copy it */
if (!pHostSysBuf || !ioc.pBuf) {
status = DSP_EPOINTER;
DBG_Trace(DBG_LEVEL7,
"System buffer NULL in IO completion.\n");
goto func_cont;
}
if (!CHNL_IsInput(pChnl->uMode))
goto func_cont1;
/*pHostUserBuf */
status = copy_to_user(ioc.pBuf, pHostSysBuf, ioc.cBytes);
#ifndef RES_CLEANUP_DISABLE
if (status) {
if (current->flags & PF_EXITING) {
DBG_Trace(DBG_LEVEL7,
"\n2current->flags == PF_EXITING, "
" current->flags;0x%x\n",
current->flags);
status = 0;
} else {
DBG_Trace(DBG_LEVEL7,
"\n2current->flags != PF_EXITING, "
" current->flags;0x%x\n",
current->flags);
}
}
#endif
if (status) {
DBG_Trace(DBG_LEVEL7,
"Error copying kernel buffer to user, %d"
" bytes remaining. in_interupt %d\n",
status, in_interrupt());
status = DSP_EPOINTER;
}
func_cont1:
MEM_Free(pHostSysBuf);
}
func_cont:
/* Update User's IOC block: */
*pIOC = ioc;
func_end:
DBG_Trace(DBG_ENTER, "< WMD_CHNL_GetIOC pChnl %p\n", pChnl);
return status;
}
/*
* ======== WMD_MSG_Put ========
* Put a message onto a MSG queue.
*/
DSP_STATUS WMD_MSG_Put(struct MSG_QUEUE *hMsgQueue,
IN CONST struct DSP_MSG *pMsg, u32 uTimeout)
{
struct MSG_FRAME *pMsgFrame;
struct MSG_MGR *hMsgMgr;
bool fPutMsg = false;
struct SYNC_OBJECT *hSyncs[2];
u32 uIndex;
DSP_STATUS status = DSP_SOK;
DBC_Require(MEM_IsValidHandle(hMsgQueue, MSGQ_SIGNATURE));
DBC_Require(pMsg != NULL);
hMsgMgr = hMsgQueue->hMsgMgr;
if (!hMsgMgr->msgFreeList) {
status = DSP_EHANDLE;
goto func_end;
}
(void) SYNC_EnterCS(hMsgMgr->hSyncCS);
/* If a message frame is available, use it */
if (!LST_IsEmpty(hMsgMgr->msgFreeList)) {
pMsgFrame = (struct MSG_FRAME *)LST_GetHead(hMsgMgr->
msgFreeList);
if (pMsgFrame != NULL) {
pMsgFrame->msgData.msg = *pMsg;
pMsgFrame->msgData.dwId = hMsgQueue->dwId;
LST_PutTail(hMsgMgr->msgUsedList, (struct LST_ELEM *)
pMsgFrame);
hMsgMgr->uMsgsPending++;
fPutMsg = true;
}
if (LST_IsEmpty(hMsgMgr->msgFreeList))
SYNC_ResetEvent(hMsgMgr->hSyncEvent);
/* Release critical section before scheduling DPC */
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
/* Schedule a DPC, to do the actual data transfer: */
IO_Schedule(hMsgMgr->hIOMgr);
} else {
if (hMsgQueue->fDone)
status = DSP_EFAIL;
else
hMsgQueue->refCount++;
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
}
if (DSP_SUCCEEDED(status) && !fPutMsg) {
/* Wait til a free message frame is available, timeout,
* or done */
hSyncs[0] = hMsgMgr->hSyncEvent;
hSyncs[1] = hMsgQueue->hSyncDone;
status = SYNC_WaitOnMultipleEvents(hSyncs, 2, uTimeout,
&uIndex);
/* Enter critical section */
(void)SYNC_EnterCS(hMsgMgr->hSyncCS);
if (hMsgQueue->fDone) {
hMsgQueue->refCount--;
/* Exit critical section */
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
/* Signal that we're not going to access hMsgQueue
* anymore, so it can be deleted. */
(void)SYNC_SetEvent(hMsgQueue->hSyncDoneAck);
status = DSP_EFAIL;
} else {
if (DSP_SUCCEEDED(status)) {
if (LST_IsEmpty(hMsgMgr->msgFreeList)) {
status = DSP_EPOINTER;
goto func_cont;
}
/* Get msg from free list */
pMsgFrame = (struct MSG_FRAME *)
LST_GetHead(hMsgMgr->msgFreeList);
/* Copy message into pMsg and put frame on the
* used list */
if (pMsgFrame != NULL) {
pMsgFrame->msgData.msg = *pMsg;
pMsgFrame->msgData.dwId =
hMsgQueue->dwId;
LST_PutTail(hMsgMgr->msgUsedList,
(struct LST_ELEM *)
pMsgFrame);
hMsgMgr->uMsgsPending++;
/* Schedule a DPC, to do the actual
* data transfer: */
IO_Schedule(hMsgMgr->hIOMgr);
}
}
hMsgQueue->refCount--;
/* Reset event if there are still frames available */
if (!LST_IsEmpty(hMsgMgr->msgFreeList))
SYNC_SetEvent(hMsgMgr->hSyncEvent);
func_cont:
/* Exit critical section */
(void) SYNC_LeaveCS(hMsgMgr->hSyncCS);
}
}
func_end:
return status;
}
/*
* ======== WMD_MSG_Get ========
* Get a message from a MSG queue.
*/
DSP_STATUS WMD_MSG_Get(struct MSG_QUEUE *hMsgQueue,
struct DSP_MSG *pMsg, u32 uTimeout)
{
struct MSG_FRAME *pMsgFrame;
struct MSG_MGR *hMsgMgr;
bool fGotMsg = false;
struct SYNC_OBJECT *hSyncs[2];
u32 uIndex;
DSP_STATUS status = DSP_SOK;
DBC_Require(MEM_IsValidHandle(hMsgQueue, MSGQ_SIGNATURE));
DBC_Require(pMsg != NULL);
hMsgMgr = hMsgQueue->hMsgMgr;
if (!hMsgQueue->msgUsedList) {
status = DSP_EHANDLE;
goto func_end;
}
/* Enter critical section */
(void)SYNC_EnterCS(hMsgMgr->hSyncCS);
/* If a message is already there, get it */
if (!LST_IsEmpty(hMsgQueue->msgUsedList)) {
pMsgFrame = (struct MSG_FRAME *)LST_GetHead(hMsgQueue->
msgUsedList);
if (pMsgFrame != NULL) {
*pMsg = pMsgFrame->msgData.msg;
LST_PutTail(hMsgQueue->msgFreeList,
(struct LST_ELEM *)pMsgFrame);
if (LST_IsEmpty(hMsgQueue->msgUsedList))
SYNC_ResetEvent(hMsgQueue->hSyncEvent);
else {
NTFY_Notify(hMsgQueue->hNtfy,
DSP_NODEMESSAGEREADY);
SYNC_SetEvent(hMsgQueue->hSyncEvent);
}
fGotMsg = true;
}
} else {
if (hMsgQueue->fDone)
status = DSP_EFAIL;
else
hMsgQueue->refCount++;
}
/* Exit critical section */
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
if (DSP_SUCCEEDED(status) && !fGotMsg) {
/* Wait til message is available, timeout, or done. We don't
* have to schedule the DPC, since the DSP will send messages
* when they are available. */
hSyncs[0] = hMsgQueue->hSyncEvent;
hSyncs[1] = hMsgQueue->hSyncDone;
status = SYNC_WaitOnMultipleEvents(hSyncs, 2, uTimeout,
&uIndex);
/* Enter critical section */
(void)SYNC_EnterCS(hMsgMgr->hSyncCS);
if (hMsgQueue->fDone) {
hMsgQueue->refCount--;
/* Exit critical section */
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
/* Signal that we're not going to access hMsgQueue
* anymore, so it can be deleted. */
(void)SYNC_SetEvent(hMsgQueue->hSyncDoneAck);
status = DSP_EFAIL;
} else {
if (DSP_SUCCEEDED(status)) {
DBC_Assert(!LST_IsEmpty(hMsgQueue->
msgUsedList));
/* Get msg from used list */
pMsgFrame = (struct MSG_FRAME *)
LST_GetHead(hMsgQueue->msgUsedList);
/* Copy message into pMsg and put frame on the
* free list */
if (pMsgFrame != NULL) {
*pMsg = pMsgFrame->msgData.msg;
LST_PutTail(hMsgQueue->msgFreeList,
(struct LST_ELEM *)pMsgFrame);
}
}
hMsgQueue->refCount--;
/* Reset the event if there are still queued messages */
if (!LST_IsEmpty(hMsgQueue->msgUsedList)) {
NTFY_Notify(hMsgQueue->hNtfy,
DSP_NODEMESSAGEREADY);
SYNC_SetEvent(hMsgQueue->hSyncEvent);
}
/* Exit critical section */
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
}
}
func_end:
return status;
}
