/*
* ======== RMM_create ========
*/
DSP_STATUS RMM_create(struct RMM_TargetObj **pTarget,
struct RMM_Segment segTab[], u32 numSegs)
{
struct RMM_Header *hptr;
struct RMM_Segment *sptr, *tmp;
struct RMM_TargetObj *target;
s32 i;
DSP_STATUS status = DSP_SOK;
DBC_Require(pTarget != NULL);
DBC_Require(numSegs == 0 || segTab != NULL);
GT_3trace(RMM_debugMask, GT_ENTER,
"RMM_create(0x%lx, 0x%lx, 0x%lx)\n",
pTarget, segTab, numSegs);
/* Allocate DBL target object */
MEM_AllocObject(target, struct RMM_TargetObj, RMM_TARGSIGNATURE);
if (target == NULL) {
GT_0trace(RMM_debugMask, GT_6CLASS,
"RMM_create: Memory allocation failed\n");
status = DSP_EMEMORY;
}
if (DSP_FAILED(status))
goto func_cont;
target->numSegs = numSegs;
if (!(numSegs > 0))
goto func_cont;
/* Allocate the memory for freelist from host's memory */
target->freeList = MEM_Calloc(numSegs * sizeof(struct RMM_Header *),
MEM_PAGED);
if (target->freeList == NULL) {
GT_0trace(RMM_debugMask, GT_6CLASS,
"RMM_create: Memory allocation failed\n");
status = DSP_EMEMORY;
} else {
/* Allocate headers for each element on the free list */
for (i = 0; i < (s32) numSegs; i++) {
target->freeList[i] =
MEM_Calloc(sizeof(struct RMM_Header),
MEM_PAGED);
if (target->freeList[i] == NULL) {
GT_0trace(RMM_debugMask, GT_6CLASS,
"RMM_create: Memory "
"allocation failed\n");
status = DSP_EMEMORY;
break;
}
}
/* Allocate memory for initial segment table */
target->segTab = MEM_Calloc(numSegs *
sizeof(struct RMM_Segment), MEM_PAGED);
if (target->segTab == NULL) {
GT_0trace(RMM_debugMask, GT_6CLASS,
"RMM_create: Memory allocation failed\n");
status = DSP_EMEMORY;
} else {
/* Initialize segment table and free list */
sptr = target->segTab;
for (i = 0, tmp = segTab; numSegs > 0; numSegs--, i++) {
*sptr = *tmp;
hptr = target->freeList[i];
hptr->addr = tmp->base;
hptr->size = tmp->length;
hptr->next = NULL;
tmp++;
sptr++;
}
}
}
func_cont:
/* Initialize overlay memory list */
if (DSP_SUCCEEDED(status)) {
target->ovlyList = LST_Create();
if (target->ovlyList == NULL) {
GT_0trace(RMM_debugMask, GT_6CLASS,
"RMM_create: Memory allocation failed\n");
status = DSP_EMEMORY;
}
}
if (DSP_SUCCEEDED(status)) {
*pTarget = target;
} else {
*pTarget = NULL;
if (target)
RMM_delete(target);
}
DBC_Ensure((DSP_SUCCEEDED(status) && MEM_IsValidHandle((*pTarget),
RMM_TARGSIGNATURE)) || (DSP_FAILED(status) && *pTarget ==
NULL));
return status;
}
/*
* ======== MGR_EnumNodeInfo ========
* Enumerate and get configuration information about nodes configured
* in the node database.
*/
DSP_STATUS MGR_EnumNodeInfo(u32 uNode, OUT struct DSP_NDBPROPS *pNDBProps,
u32 uNDBPropsSize, OUT u32 *puNumNodes)
{
DSP_STATUS status = DSP_SOK;
DSP_STATUS status1 = DSP_SOK;
struct DSP_UUID Uuid, uTempUuid;
u32 uTempIndex = 0;
u32 uNodeIndex = 0;
struct DCD_GENERICOBJ GenObj;
struct MGR_OBJECT *pMgrObject = NULL;
DBC_Require(pNDBProps != NULL);
DBC_Require(puNumNodes != NULL);
DBC_Require(uNDBPropsSize >= sizeof(struct DSP_NDBPROPS));
DBC_Require(cRefs > 0);
GT_4trace(MGR_DebugMask, GT_ENTER, "Entered Manager_EnumNodeInfo, "
"args:\n\t uNode: 0x%x\n\tpNDBProps: 0x%x\n\tuNDBPropsSize:"
"0x%x\tpuNumNodes: 0x%x\n", uNode, pNDBProps,
uNDBPropsSize, puNumNodes);
*puNumNodes = 0;
/* Get The Manager Object from the Registry */
if (DSP_FAILED(CFG_GetObject((u32 *)&pMgrObject,
REG_MGR_OBJECT))) {
GT_0trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumNodeInfo:Failed To Get"
" MGR Object from Registry\r\n");
goto func_cont;
}
DBC_Assert(MEM_IsValidHandle(pMgrObject, SIGNATURE));
/* Forever loop till we hit failed or no more items in the
* Enumeration. We will exit the loop other than DSP_SOK; */
while (status == DSP_SOK) {
status = DCD_EnumerateObject(uTempIndex++, DSP_DCDNODETYPE,
&uTempUuid);
if (status == DSP_SOK) {
uNodeIndex++;
if (uNode == (uNodeIndex - 1))
Uuid = uTempUuid;
}
}
if (DSP_SUCCEEDED(status)) {
if (uNode > (uNodeIndex - 1)) {
status = DSP_EINVALIDARG;
GT_0trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumNodeInfo: uNode"
" is Invalid \r\n");
} else {
status1 = DCD_GetObjectDef(pMgrObject->hDcdMgr,
(struct DSP_UUID *)&Uuid,
DSP_DCDNODETYPE, &GenObj);
if (DSP_SUCCEEDED(status1)) {
/* Get the Obj def */
*pNDBProps = GenObj.objData.nodeObj.ndbProps;
*puNumNodes = uNodeIndex;
status = DSP_SOK;
} else {
GT_0trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumNodeInfo: "
"Failed to Get Node Info \r\n");
status = DSP_EFAIL;
}
}
} else {
/* This could be changed during enum, EFAIL ... */
GT_0trace(MGR_DebugMask, GT_7CLASS, "Manager_EnumNodeInfo: "
"Enumeration failure\r\n");
status = DSP_EFAIL;
}
func_cont:
GT_4trace(MGR_DebugMask, GT_ENTER,
"Exiting Manager_EnumNodeInfo, args:\n\t"
"uNode: 0x%x\n\tpNDBProps: 0x%x\n\tuNDBPropsSize:"
" 0x%x\tuNumNodes: 0x%x\n", uNode, pNDBProps,
uNDBPropsSize, *puNumNodes);
DBC_Ensure((DSP_SUCCEEDED(status) && *puNumNodes > 0) ||
(DSP_FAILED(status) && *puNumNodes == 0));
return status;
}
/*
* ======== STRM_Select ========
* Purpose:
* Selects a ready stream.
*/
DSP_STATUS STRM_Select(IN struct STRM_OBJECT **aStrmTab, u32 nStrms,
OUT u32 *pMask, u32 uTimeout)
{
u32 uIndex;
struct CHNL_INFO chnlInfo;
struct WMD_DRV_INTERFACE *pIntfFxns;
struct SYNC_OBJECT **hSyncEvents = NULL;
u32 i;
DSP_STATUS status = DSP_SOK;
DBC_Require(cRefs > 0);
DBC_Require(aStrmTab != NULL);
DBC_Require(pMask != NULL);
DBC_Require(nStrms > 0);
*pMask = 0;
for (i = 0; i < nStrms; i++) {
if (!MEM_IsValidHandle(aStrmTab[i], STRM_SIGNATURE)) {
status = DSP_EHANDLE;
break;
}
}
if (DSP_FAILED(status))
goto func_end;
/* Determine which channels have IO ready */
for (i = 0; i < nStrms; i++) {
pIntfFxns = aStrmTab[i]->hStrmMgr->pIntfFxns;
status = (*pIntfFxns->pfnChnlGetInfo)(aStrmTab[i]->hChnl,
&chnlInfo);
if (DSP_FAILED(status)) {
break;
} else {
if (chnlInfo.cIOCs > 0)
*pMask |= (1 << i);
}
}
if (DSP_SUCCEEDED(status) && uTimeout > 0 && *pMask == 0) {
/* Non-zero timeout */
hSyncEvents = (struct SYNC_OBJECT **)MEM_Alloc(nStrms *
sizeof(struct SYNC_OBJECT *), MEM_PAGED);
if (hSyncEvents == NULL) {
status = DSP_EMEMORY;
} else {
for (i = 0; i < nStrms; i++) {
pIntfFxns = aStrmTab[i]->hStrmMgr->pIntfFxns;
status = (*pIntfFxns->pfnChnlGetInfo)
(aStrmTab[i]->hChnl, &chnlInfo);
if (DSP_FAILED(status))
break;
else
hSyncEvents[i] = chnlInfo.hSyncEvent;
}
}
if (DSP_SUCCEEDED(status)) {
status = SYNC_WaitOnMultipleEvents(hSyncEvents, nStrms,
uTimeout, &uIndex);
if (DSP_SUCCEEDED(status)) {
/* Since we waited on the event, we have to
* reset it */
SYNC_SetEvent(hSyncEvents[uIndex]);
*pMask = 1 << uIndex;
}
}
}
func_end:
kfree(hSyncEvents);
DBC_Ensure((DSP_SUCCEEDED(status) && (*pMask != 0 || uTimeout == 0)) ||
(DSP_FAILED(status) && *pMask == 0));
return status;
}
/*
* ======== RMM_alloc ========
*/
DSP_STATUS RMM_alloc(struct RMM_TargetObj *target, u32 segid, u32 size,
u32 align, u32 *dspAddr, bool reserve)
{
struct RMM_OvlySect *sect;
struct RMM_OvlySect *prevSect = NULL;
struct RMM_OvlySect *newSect;
u32 addr;
DSP_STATUS status = DSP_SOK;
DBC_Require(MEM_IsValidHandle(target, RMM_TARGSIGNATURE));
DBC_Require(dspAddr != NULL);
DBC_Require(size > 0);
DBC_Require(reserve || (target->numSegs > 0));
DBC_Require(cRefs > 0);
GT_6trace(RMM_debugMask, GT_ENTER,
"RMM_alloc(0x%lx, 0x%lx, 0x%lx, 0x%lx, "
"0x%lx, 0x%lx)\n", target, segid, size, align, dspAddr,
reserve);
if (!reserve) {
if (!allocBlock(target, segid, size, align, dspAddr)) {
status = DSP_EMEMORY;
} else {
/* Increment the number of allocated blocks in this
* segment */
target->segTab[segid].number++;
}
goto func_end;
}
/* An overlay section - See if block is already in use. If not,
* insert into the list in ascending address size. */
addr = *dspAddr;
sect = (struct RMM_OvlySect *)LST_First(target->ovlyList);
/* Find place to insert new list element. List is sorted from
* smallest to largest address. */
while (sect != NULL) {
if (addr <= sect->addr) {
/* Check for overlap with sect */
if ((addr + size > sect->addr) || (prevSect &&
(prevSect->addr + prevSect->size > addr))) {
status = DSP_EOVERLAYMEMORY;
}
break;
}
prevSect = sect;
sect = (struct RMM_OvlySect *)LST_Next(target->ovlyList,
(struct LST_ELEM *)sect);
}
if (DSP_SUCCEEDED(status)) {
/* No overlap - allocate list element for new section. */
newSect = MEM_Calloc(sizeof(struct RMM_OvlySect), MEM_PAGED);
if (newSect == NULL) {
status = DSP_EMEMORY;
} else {
LST_InitElem((struct LST_ELEM *)newSect);
newSect->addr = addr;
newSect->size = size;
newSect->page = segid;
if (sect == NULL) {
/* Put new section at the end of the list */
LST_PutTail(target->ovlyList,
(struct LST_ELEM *)newSect);
} else {
/* Put new section just before sect */
LST_InsertBefore(target->ovlyList,
(struct LST_ELEM *)newSect,
(struct LST_ELEM *)sect);
}
}
}
func_end:
return status;
}
/*
* ======== WMD_DEH_Notify ========
* DEH error notification function. Informs user about the error.
*/
void WMD_DEH_Notify(struct DEH_MGR *hDehMgr, u32 ulEventMask,
u32 dwErrInfo)
{
struct DEH_MGR *pDehMgr = (struct DEH_MGR *)hDehMgr;
struct WMD_DEV_CONTEXT *pDevContext;
u32 memPhysical = 0;
u32 HW_MMU_MAX_TLB_COUNT = 31;
extern u32 faultAddr;
u32 cnt = 0;
if (MEM_IsValidHandle(pDehMgr, SIGNATURE)) {
printk(KERN_INFO "WMD_DEH_Notify: ********** DEVICE EXCEPTION "
"**********\n");
pDevContext = (struct WMD_DEV_CONTEXT *)pDehMgr->hWmdContext;
switch (ulEventMask) {
case DSP_SYSERROR:
/* reset errInfo structure before use */
pDehMgr->errInfo.dwErrMask = DSP_SYSERROR;
pDehMgr->errInfo.dwVal1 = 0L;
pDehMgr->errInfo.dwVal2 = 0L;
pDehMgr->errInfo.dwVal3 = 0L;
pDehMgr->errInfo.dwVal1 = dwErrInfo;
printk(KERN_ERR "WMD_DEH_Notify: DSP_SYSERROR, errInfo "
"= 0x%x\n", dwErrInfo);
dump_dl_modules(pDevContext);
dump_dsp_stack(pDevContext);
break;
case DSP_MMUFAULT:
/* MMU fault routine should have set err info
* structure */
pDehMgr->errInfo.dwErrMask = DSP_MMUFAULT;
printk(KERN_INFO "WMD_DEH_Notify: DSP_MMUFAULT,"
"errInfo = 0x%x\n", dwErrInfo);
printk(KERN_INFO "WMD_DEH_Notify: DSP_MMUFAULT, High "
"Address = 0x%x\n",
(unsigned int)pDehMgr->errInfo.dwVal1);
printk(KERN_INFO "WMD_DEH_Notify: DSP_MMUFAULT, Low "
"Address = 0x%x\n",
(unsigned int)pDehMgr->errInfo.dwVal2);
printk(KERN_INFO "WMD_DEH_Notify: DSP_MMUFAULT, fault "
"address = 0x%x\n", (unsigned int)faultAddr);
PrintDspTraceBuffer(pDevContext);
dump_dl_modules(pDevContext);
dummyVaAddr = (u32)MEM_Calloc(sizeof(char) * 0x1000,
MEM_PAGED);
memPhysical = VirtToPhys(PG_ALIGN_LOW((u32)dummyVaAddr,
PG_SIZE_4K));
pDevContext = (struct WMD_DEV_CONTEXT *)
pDehMgr->hWmdContext;
/* Reset the dynamic mmu index to fixed count if it
* exceeds 31. So that the dynmmuindex is always
* between the range of standard/fixed entries
* and 31. */
if (pDevContext->numTLBEntries >
HW_MMU_MAX_TLB_COUNT) {
pDevContext->numTLBEntries = pDevContext->
fixedTLBEntries;
}
HW_MMU_TLBAdd(pDevContext->dwDSPMmuBase,
memPhysical, faultAddr, HW_PAGE_SIZE_4KB, 1,
&mapAttrs, HW_SET, HW_SET);
/*
* Send a GP Timer interrupt to DSP
* The DSP expects a GP timer interrupt after an
* MMU-Fault Request GPTimer
*/
if (timer) {
omap_dm_timer_enable(timer);
/* Enable overflow interrupt */
omap_dm_timer_set_int_enable(timer,
GPTIMER_IRQ_OVERFLOW);
/*
* Set counter value to overflow counter after
* one tick and start timer
*/
omap_dm_timer_set_load_start(timer, 0,
0xfffffffe);
/* Wait 80us for timer to overflow */
udelay(80);
/* Check interrupt status and */
/* wait for interrupt */
cnt = 0;
while (!(omap_dm_timer_read_status(timer) &
GPTIMER_IRQ_OVERFLOW)) {
if (cnt++ >=
GPTIMER_IRQ_WAIT_MAX_CNT) {
pr_err("%s: GPTimer interrupt"
" failed\n", __func__);
break;
}
}
}
/* Clear MMU interrupt */
HW_MMU_EventAck(pDevContext->dwDSPMmuBase,
HW_MMU_TRANSLATION_FAULT);
dump_dsp_stack(hDehMgr->hWmdContext);
if (timer)
omap_dm_timer_disable(timer);
break;
#ifdef CONFIG_BRIDGE_NTFY_PWRERR
case DSP_PWRERROR:
/* reset errInfo structure before use */
pDehMgr->errInfo.dwErrMask = DSP_PWRERROR;
pDehMgr->errInfo.dwVal1 = 0L;
pDehMgr->errInfo.dwVal2 = 0L;
pDehMgr->errInfo.dwVal3 = 0L;
pDehMgr->errInfo.dwVal1 = dwErrInfo;
printk(KERN_ERR "WMD_DEH_Notify: DSP_PWRERROR, errInfo "
"= 0x%x\n", dwErrInfo);
break;
#endif /* CONFIG_BRIDGE_NTFY_PWRERR */
#ifdef CONFIG_BRIDGE_WDT3
case DSP_WDTOVERFLOW:
pDehMgr->errInfo.dwErrMask = DSP_WDTOVERFLOW;
pDehMgr->errInfo.dwVal1 = 0L;
pDehMgr->errInfo.dwVal2 = 0L;
pDehMgr->errInfo.dwVal3 = 0L;
pr_err("WMD_DEH_Notify: DSP_WDTOVERFLOW \n ");
break;
#endif
default:
DBG_Trace(DBG_LEVEL6,
"WMD_DEH_Notify: Unknown Error, errInfo = "
"0x%x\n", dwErrInfo);
break;
}
/* Filter subsequent notifications when an error occurs */
if (pDevContext->dwBrdState != BRD_ERROR) {
NTFY_Notify(pDehMgr->hNtfy, ulEventMask);
#ifdef CONFIG_BRIDGE_RECOVERY
bridge_recover_schedule();
#endif
}
/* Set the Board state as ERROR */
pDevContext->dwBrdState = BRD_ERROR;
/* Disable all the clocks that were enabled by DSP */
(void)DSP_PeripheralClocks_Disable(pDevContext, NULL);
#ifdef CONFIG_BRIDGE_WDT3
/*
* Avoid the subsequent WDT if it happens once,
* also If MMU fault occurs
*/
dsp_wdt_enable(false);
#endif
}
}
/*
* ======== WMD_MSG_Delete ========
* Delete a MSG manager allocated in WMD_MSG_Create().
*/
void WMD_MSG_Delete(struct MSG_MGR *hMsgMgr)
{
if (MEM_IsValidHandle(hMsgMgr, MSGMGR_SIGNATURE))
DeleteMsgMgr(hMsgMgr);
}
/*
* ======== DBLL_load ========
*/
DSP_STATUS DBLL_load(struct DBLL_LibraryObj *lib, DBLL_Flags flags,
struct DBLL_Attrs *attrs, u32 *pEntry)
{
struct DBLL_LibraryObj *zlLib = (struct DBLL_LibraryObj *)lib;
struct DBLL_TarObj *dbzl;
bool gotSymbols = true;
s32 err;
DSP_STATUS status = DSP_SOK;
bool fOpenedDoff = false;
DBC_Require(cRefs > 0);
DBC_Require(MEM_IsValidHandle(zlLib, DBLL_LIBSIGNATURE));
DBC_Require(pEntry != NULL);
DBC_Require(attrs != NULL);
GT_4trace(DBLL_debugMask, GT_ENTER,
"DBLL_load: lib: 0x%x flags: 0x%x pEntry:"
" 0x%x\n", lib, flags, attrs, pEntry);
/*
* Load if not already loaded.
*/
if (zlLib->loadRef == 0 || !(flags & DBLL_DYNAMIC)) {
dbzl = zlLib->pTarget;
dbzl->attrs = *attrs;
/* Create a hash table for symbols if not already created */
if (zlLib->symTab == NULL) {
gotSymbols = false;
zlLib->symTab = GH_create(MAXBUCKETS,
sizeof(struct Symbol),
nameHash,
nameMatch, symDelete);
if (zlLib->symTab == NULL)
status = DSP_EMEMORY;
}
/*
* Set up objects needed by the dynamic loader
*/
/* Stream */
zlLib->stream.dlStream.read_buffer = readBuffer;
zlLib->stream.dlStream.set_file_posn = setFilePosn;
zlLib->stream.lib = zlLib;
/* Symbol */
zlLib->symbol.dlSymbol.Find_Matching_Symbol = findSymbol;
if (gotSymbols) {
zlLib->symbol.dlSymbol.Add_To_Symbol_Table =
findInSymbolTable;
} else {
zlLib->symbol.dlSymbol.Add_To_Symbol_Table =
addToSymbolTable;
}
zlLib->symbol.dlSymbol.Purge_Symbol_Table = purgeSymbolTable;
zlLib->symbol.dlSymbol.Allocate = allocate;
zlLib->symbol.dlSymbol.Deallocate = deallocate;
zlLib->symbol.dlSymbol.Error_Report = errorReport;
zlLib->symbol.lib = zlLib;
/* Allocate */
zlLib->allocate.dlAlloc.Allocate = rmmAlloc;
zlLib->allocate.dlAlloc.Deallocate = rmmDealloc;
zlLib->allocate.lib = zlLib;
/* Init */
zlLib->init.dlInit.connect = connect;
zlLib->init.dlInit.readmem = readMem;
zlLib->init.dlInit.writemem = writeMem;
zlLib->init.dlInit.fillmem = fillMem;
zlLib->init.dlInit.execute = execute;
zlLib->init.dlInit.release = release;
zlLib->init.lib = zlLib;
/* If COFF file is not open, we open it. */
if (zlLib->fp == NULL) {
status = dofOpen(zlLib);
if (DSP_SUCCEEDED(status))
fOpenedDoff = true;
}
if (DSP_SUCCEEDED(status)) {
zlLib->ulPos = (*(zlLib->pTarget->attrs.ftell))
(zlLib->fp);
/* Reset file cursor */
(*(zlLib->pTarget->attrs.fseek))(zlLib->fp, (long)0,
SEEK_SET);
bSymbolsReloaded = true;
/* The 5th argument, DLOAD_INITBSS, tells the DLL
* module to zero-init all BSS sections. In general,
* this is not necessary and also increases load time.
* We may want to make this configurable by the user */
err = Dynamic_Load_Module(&zlLib->stream.dlStream,
&zlLib->symbol.dlSymbol, &zlLib->allocate.dlAlloc,
&zlLib->init.dlInit, DLOAD_INITBSS,
&zlLib->mHandle);
if (err != 0) {
GT_1trace(DBLL_debugMask, GT_6CLASS,
"DBLL_load: "
"Dynamic_Load_Module failed: 0x%lx\n",
err);
status = DSP_EDYNLOAD;
} else if (bRedefinedSymbol) {
zlLib->loadRef++;
DBLL_unload(zlLib, (struct DBLL_Attrs *) attrs);
bRedefinedSymbol = false;
status = DSP_EDYNLOAD;
} else {
*pEntry = zlLib->entry;
}
}
}
if (DSP_SUCCEEDED(status))
zlLib->loadRef++;
/* Clean up DOFF resources */
if (fOpenedDoff)
dofClose(zlLib);
DBC_Ensure(DSP_FAILED(status) || zlLib->loadRef > 0);
return status;
}
/*
* ======== WMD_CHNL_Open ========
* Open a new half-duplex channel to the DSP board.
*/
DSP_STATUS WMD_CHNL_Open(OUT struct CHNL_OBJECT **phChnl,
struct CHNL_MGR *hChnlMgr, short int uMode,
u32 uChnlId, CONST IN struct CHNL_ATTRS *pAttrs)
{
DSP_STATUS status = DSP_SOK;
struct CHNL_MGR *pChnlMgr = hChnlMgr;
struct CHNL_OBJECT *pChnl = NULL;
struct SYNC_ATTRS *pSyncAttrs = NULL;
struct SYNC_OBJECT *hSyncEvent = NULL;
/* Ensure DBC requirements: */
DBC_Require(phChnl != NULL);
DBC_Require(pAttrs != NULL);
DBC_Require(hChnlMgr != NULL);
*phChnl = NULL;
/* Validate Args: */
if (pAttrs->uIOReqs == 0) {
status = DSP_EINVALIDARG;
} else {
if (!MEM_IsValidHandle(hChnlMgr, CHNL_MGRSIGNATURE)) {
status = DSP_EHANDLE;
} else {
if (uChnlId != CHNL_PICKFREE) {
if (uChnlId >= pChnlMgr->cChannels)
status = CHNL_E_BADCHANID;
else if (pChnlMgr->apChannel[uChnlId] !=
NULL)
status = CHNL_E_CHANBUSY;
} else {
/* Check for free channel */
status = SearchFreeChannel(pChnlMgr, &uChnlId);
}
}
}
if (DSP_FAILED(status))
goto func_end;
DBC_Assert(uChnlId < pChnlMgr->cChannels);
/* Create channel object: */
MEM_AllocObject(pChnl, struct CHNL_OBJECT, 0x0000);
if (!pChnl) {
status = DSP_EMEMORY;
goto func_end;
}
/* Protect queues from IO_DPC: */
pChnl->dwState = CHNL_STATECANCEL;
/* Allocate initial IOR and IOC queues: */
pChnl->pFreeList = CreateChirpList(pAttrs->uIOReqs);
pChnl->pIORequests = CreateChirpList(0);
pChnl->pIOCompletions = CreateChirpList(0);
pChnl->cChirps = pAttrs->uIOReqs;
pChnl->cIOCs = 0;
pChnl->cIOReqs = 0;
status = SYNC_OpenEvent(&hSyncEvent, pSyncAttrs);
if (DSP_SUCCEEDED(status))
status = NTFY_Create(&pChnl->hNtfy);
if (DSP_SUCCEEDED(status)) {
if (pChnl->pIOCompletions && pChnl->pIORequests &&
pChnl->pFreeList) {
/* Initialize CHNL object fields: */
pChnl->pChnlMgr = pChnlMgr;
pChnl->uId = uChnlId;
pChnl->uMode = uMode;
pChnl->hUserEvent = hSyncEvent; /* for Linux */
pChnl->hSyncEvent = hSyncEvent;
/* Get the process handle */
pChnl->hProcess = current->tgid;
pChnl->pCBArg = 0;
pChnl->cBytesMoved = 0;
/* Default to proc-copy */
pChnl->uChnlType = CHNL_PCPY;
} else {
status = DSP_EMEMORY;
}
}
if (DSP_FAILED(status)) {
/* Free memory */
if (pChnl->pIOCompletions) {
FreeChirpList(pChnl->pIOCompletions);
pChnl->pIOCompletions = NULL;
pChnl->cIOCs = 0;
}
if (pChnl->pIORequests) {
FreeChirpList(pChnl->pIORequests);
pChnl->pIORequests = NULL;
}
if (pChnl->pFreeList) {
FreeChirpList(pChnl->pFreeList);
pChnl->pFreeList = NULL;
}
if (hSyncEvent) {
SYNC_CloseEvent(hSyncEvent);
hSyncEvent = NULL;
}
if (pChnl->hNtfy) {
NTFY_Delete(pChnl->hNtfy);
pChnl->hNtfy = NULL;
}
MEM_FreeObject(pChnl);
} else {
/* Insert channel object in channel manager: */
pChnlMgr->apChannel[pChnl->uId] = pChnl;
SYNC_EnterCS(pChnlMgr->hCSObj);
pChnlMgr->cOpenChannels++;
SYNC_LeaveCS(pChnlMgr->hCSObj);
/* Return result... */
pChnl->dwSignature = CHNL_SIGNATURE;
pChnl->dwState = CHNL_STATEREADY;
*phChnl = pChnl;
}
func_end:
DBC_Ensure((DSP_SUCCEEDED(status) &&
MEM_IsValidHandle(pChnl, CHNL_SIGNATURE)) ||
(*phChnl == NULL));
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_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_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;
}
/*
* ======== WMD_MSG_Delete ========
* Delete a MSG manager allocated in WMD_MSG_Create().
*/
void WMD_MSG_Delete(struct MSG_MGR *hMsgMgr)
{
DBC_Require(MEM_IsValidHandle(hMsgMgr, MSGMGR_SIGNATURE));
DeleteMsgMgr(hMsgMgr);
}
/*
* ======== WMD_MSG_CreateQueue ========
* Create a MSG_QUEUE for sending/receiving messages to/from a node
* on the DSP.
*/
DSP_STATUS WMD_MSG_CreateQueue(struct MSG_MGR *hMsgMgr,
OUT struct MSG_QUEUE **phMsgQueue,
u32 dwId, u32 uMaxMsgs, HANDLE hArg)
{
u32 i;
u32 uNumAllocated = 0;
struct MSG_QUEUE *pMsgQ;
DSP_STATUS status = DSP_SOK;
DBC_Require(MEM_IsValidHandle(hMsgMgr, MSGMGR_SIGNATURE));
DBC_Require(phMsgQueue != NULL);
*phMsgQueue = NULL;
/* Allocate MSG_QUEUE object */
MEM_AllocObject(pMsgQ, struct MSG_QUEUE, MSGQ_SIGNATURE);
if (!pMsgQ) {
status = DSP_EMEMORY;
goto func_end;
}
LST_InitElem((struct LST_ELEM *) pMsgQ);
pMsgQ->uMaxMsgs = uMaxMsgs;
pMsgQ->hMsgMgr = hMsgMgr;
pMsgQ->hArg = hArg; /* Node handle */
pMsgQ->dwId = dwId; /* Node env (not valid yet) */
/* Queues of Message frames for messages from the DSP */
pMsgQ->msgFreeList = LST_Create();
pMsgQ->msgUsedList = LST_Create();
if (pMsgQ->msgFreeList == NULL || pMsgQ->msgUsedList == NULL)
status = DSP_EMEMORY;
/* Create event that will be signalled when a message from
* the DSP is available. */
if (DSP_SUCCEEDED(status))
status = SYNC_OpenEvent(&pMsgQ->hSyncEvent, NULL);
/* Create a notification list for message ready notification. */
if (DSP_SUCCEEDED(status))
status = NTFY_Create(&pMsgQ->hNtfy);
/* Create events that will be used to synchronize cleanup
* when the object is deleted. hSyncDone will be set to
* unblock threads in MSG_Put() or MSG_Get(). hSyncDoneAck
* will be set by the unblocked thread to signal that it
* is unblocked and will no longer reference the object. */
if (DSP_SUCCEEDED(status))
status = SYNC_OpenEvent(&pMsgQ->hSyncDone, NULL);
if (DSP_SUCCEEDED(status))
status = SYNC_OpenEvent(&pMsgQ->hSyncDoneAck, NULL);
if (DSP_SUCCEEDED(status)) {
if (!hMsgMgr->msgFreeList) {
status = DSP_EHANDLE;
goto func_end;
}
/* Enter critical section */
(void)SYNC_EnterCS(hMsgMgr->hSyncCS);
/* Initialize message frames and put in appropriate queues */
for (i = 0; i < uMaxMsgs && DSP_SUCCEEDED(status); i++) {
status = AddNewMsg(hMsgMgr->msgFreeList);
if (DSP_SUCCEEDED(status)) {
uNumAllocated++;
status = AddNewMsg(pMsgQ->msgFreeList);
}
}
if (DSP_FAILED(status)) {
/* Stay inside CS to prevent others from taking any
* of the newly allocated message frames. */
DeleteMsgQueue(pMsgQ, uNumAllocated);
} else {
LST_PutTail(hMsgMgr->queueList,
(struct LST_ELEM *)pMsgQ);
*phMsgQueue = pMsgQ;
/* Signal that free frames are now available */
if (!LST_IsEmpty(hMsgMgr->msgFreeList))
SYNC_SetEvent(hMsgMgr->hSyncEvent);
}
/* Exit critical section */
(void)SYNC_LeaveCS(hMsgMgr->hSyncCS);
} else {
DeleteMsgQueue(pMsgQ, 0);
}
func_end:
return status;
}
/*
* ======== MGR_EnumProcessorInfo ========
* Enumerate and get configuration information about available
* DSP processors.
*/
DSP_STATUS MGR_EnumProcessorInfo(u32 uProcessor,
OUT struct DSP_PROCESSORINFO *pProcessorInfo,
u32 uProcessorInfoSize, OUT u32 *puNumProcs)
{
DSP_STATUS status = DSP_SOK;
DSP_STATUS status1 = DSP_SOK;
DSP_STATUS status2 = DSP_SOK;
struct DSP_UUID uTempUuid;
u32 uTempIndex = 0;
u32 uProcIndex = 0;
struct DCD_GENERICOBJ GenObj;
struct MGR_OBJECT *pMgrObject = NULL;
struct MGR_PROCESSOREXTINFO *pExtInfo;
struct DEV_OBJECT *hDevObject;
struct DRV_OBJECT *hDrvObject;
s32 devType;
struct CFG_DEVNODE *devNode;
struct CFG_DSPRES chipResources;
bool procDetect = false;
DBC_Require(pProcessorInfo != NULL);
DBC_Require(puNumProcs != NULL);
DBC_Require(uProcessorInfoSize >= sizeof(struct DSP_PROCESSORINFO));
DBC_Require(cRefs > 0);
GT_4trace(MGR_DebugMask, GT_ENTER,
"Entered Manager_EnumProcessorInfo, "
"args:\n\tuProcessor: 0x%x\n\tpProcessorInfo: 0x%x\n\t"
"uProcessorInfoSize: 0x%x\tpuNumProcs: 0x%x\n", uProcessor,
pProcessorInfo, uProcessorInfoSize, puNumProcs);
*puNumProcs = 0;
status = CFG_GetObject((u32 *)&hDrvObject, REG_DRV_OBJECT);
if (DSP_SUCCEEDED(status)) {
status = DRV_GetDevObject(uProcessor, hDrvObject, &hDevObject);
if (DSP_SUCCEEDED(status)) {
status = DEV_GetDevType(hDevObject, (u32 *) &devType);
status = DEV_GetDevNode(hDevObject, &devNode);
if (devType == DSP_UNIT) {
status = CFG_GetDSPResources(devNode,
&chipResources);
} else {
status = DSP_EFAIL;
GT_1trace(MGR_DebugMask, GT_7CLASS,
"Unsupported dev type gotten"
"from device object %d\n", devType);
}
if (DSP_SUCCEEDED(status)) {
pProcessorInfo->uProcessorType =
chipResources.uChipType;
}
}
}
if (DSP_FAILED(status))
goto func_end;
/* Get The Manager Object from the Registry */
if (DSP_FAILED(CFG_GetObject((u32 *)&pMgrObject,
REG_MGR_OBJECT))) {
GT_0trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumProcessorInfo: "
"Failed To Get MGR Object from Registry\r\n");
goto func_end;
}
DBC_Assert(MEM_IsValidHandle(pMgrObject, SIGNATURE));
/* Forever loop till we hit no more items in the
* Enumeration. We will exit the loop other than DSP_SOK; */
while (status1 == DSP_SOK) {
status1 = DCD_EnumerateObject(uTempIndex++,
DSP_DCDPROCESSORTYPE,
&uTempUuid);
if (status1 != DSP_SOK)
break;
uProcIndex++;
/* Get the Object properties to find the Device/Processor
* Type */
if (procDetect != false)
continue;
status2 = DCD_GetObjectDef(pMgrObject->hDcdMgr,
(struct DSP_UUID *)&uTempUuid,
DSP_DCDPROCESSORTYPE,
&GenObj);
if (DSP_SUCCEEDED(status2)) {
/* Get the Obj def */
if (uProcessorInfoSize <
sizeof(struct MGR_PROCESSOREXTINFO)) {
*pProcessorInfo = GenObj.objData.procObj;
} else {
/* extended info */
pExtInfo = (struct MGR_PROCESSOREXTINFO *)
pProcessorInfo;
*pExtInfo = GenObj.objData.extProcObj;
}
GT_1trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumProcessorInfo: Got"
" Proctype from DCD %x \r\n",
pProcessorInfo->uProcessorType);
/* See if we got the needed processor */
if (devType == DSP_UNIT) {
if (pProcessorInfo->uProcessorType ==
DSPPROCTYPE_C64)
procDetect = true;
} else if (devType == IVA_UNIT) {
if (pProcessorInfo->uProcessorType ==
IVAPROCTYPE_ARM7)
procDetect = true;
}
/* User applciatiuons aonly check for chip type, so
* this clumsy overwrite */
pProcessorInfo->uProcessorType =
chipResources.uChipType;
} else {
GT_1trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumProcessorInfo: "
"Failed to Get DCD Processor Info %x \r\n",
status2);
status = DSP_EFAIL;
}
}
*puNumProcs = uProcIndex;
if (procDetect == false) {
GT_0trace(MGR_DebugMask, GT_7CLASS,
"Manager_EnumProcessorInfo: Failed"
" to get Proc info from DCD , so use CFG registry\n");
pProcessorInfo->uProcessorType = chipResources.uChipType;
}
func_end:
return status;
}
/*
* ======== DBLL_open ========
*/
DSP_STATUS DBLL_open(struct DBLL_TarObj *target, char *file, DBLL_Flags flags,
struct DBLL_LibraryObj **pLib)
{
struct DBLL_TarObj *zlTarget = (struct DBLL_TarObj *)target;
struct DBLL_LibraryObj *zlLib = NULL;
s32 err;
DSP_STATUS status = DSP_SOK;
DBC_Require(cRefs > 0);
DBC_Require(MEM_IsValidHandle(zlTarget, DBLL_TARGSIGNATURE));
DBC_Require(zlTarget->attrs.fopen != NULL);
DBC_Require(file != NULL);
DBC_Require(pLib != NULL);
GT_3trace(DBLL_debugMask, GT_ENTER,
"DBLL_open: target: 0x%x file: %s pLib:"
" 0x%x\n", target, file, pLib);
zlLib = zlTarget->head;
while (zlLib != NULL) {
if (strcmp(zlLib->fileName, file) == 0) {
/* Library is already opened */
zlLib->openRef++;
break;
}
zlLib = zlLib->next;
}
if (zlLib == NULL) {
/* Allocate DBL library object */
MEM_AllocObject(zlLib, struct DBLL_LibraryObj,
DBLL_LIBSIGNATURE);
if (zlLib == NULL) {
GT_0trace(DBLL_debugMask, GT_6CLASS,
"DBLL_open: Memory allocation failed\n");
status = DSP_EMEMORY;
} else {
zlLib->ulPos = 0;
/* Increment ref count to allow close on failure
* later on */
zlLib->openRef++;
zlLib->pTarget = zlTarget;
/* Keep a copy of the file name */
zlLib->fileName = MEM_Calloc(strlen(file) + 1,
MEM_PAGED);
if (zlLib->fileName == NULL) {
GT_0trace(DBLL_debugMask, GT_6CLASS,
"DBLL_open: Memory "
"allocation failed\n");
status = DSP_EMEMORY;
} else {
strncpy(zlLib->fileName, file,
strlen(file) + 1);
}
zlLib->symTab = NULL;
}
}
/*
* Set up objects needed by the dynamic loader
*/
if (DSP_FAILED(status))
goto func_cont;
/* Stream */
zlLib->stream.dlStream.read_buffer = readBuffer;
zlLib->stream.dlStream.set_file_posn = setFilePosn;
zlLib->stream.lib = zlLib;
/* Symbol */
zlLib->symbol.dlSymbol.Add_To_Symbol_Table = addToSymbolTable;
zlLib->symbol.dlSymbol.Find_Matching_Symbol = findSymbol;
zlLib->symbol.dlSymbol.Purge_Symbol_Table = purgeSymbolTable;
zlLib->symbol.dlSymbol.Allocate = allocate;
zlLib->symbol.dlSymbol.Deallocate = deallocate;
zlLib->symbol.dlSymbol.Error_Report = errorReport;
zlLib->symbol.lib = zlLib;
/* Allocate */
zlLib->allocate.dlAlloc.Allocate = rmmAlloc;
zlLib->allocate.dlAlloc.Deallocate = rmmDealloc;
zlLib->allocate.lib = zlLib;
/* Init */
zlLib->init.dlInit.connect = connect;
zlLib->init.dlInit.readmem = readMem;
zlLib->init.dlInit.writemem = writeMem;
zlLib->init.dlInit.fillmem = fillMem;
zlLib->init.dlInit.execute = execute;
zlLib->init.dlInit.release = release;
zlLib->init.lib = zlLib;
if (DSP_SUCCEEDED(status) && zlLib->fp == NULL)
status = dofOpen(zlLib);
zlLib->ulPos = (*(zlLib->pTarget->attrs.ftell)) (zlLib->fp);
(*(zlLib->pTarget->attrs.fseek))(zlLib->fp, (long) 0, SEEK_SET);
/* Create a hash table for symbols if flag is set */
if (zlLib->symTab != NULL || !(flags & DBLL_SYMB))
goto func_cont;
zlLib->symTab = GH_create(MAXBUCKETS, sizeof(struct Symbol), nameHash,
nameMatch, symDelete);
if (zlLib->symTab == NULL) {
status = DSP_EMEMORY;
} else {
/* Do a fake load to get symbols - set write function to NoOp */
zlLib->init.dlInit.writemem = NoOp;
err = Dynamic_Open_Module(&zlLib->stream.dlStream,
&zlLib->symbol.dlSymbol,
&zlLib->allocate.dlAlloc,
&zlLib->init.dlInit, 0,
&zlLib->mHandle);
if (err != 0) {
GT_1trace(DBLL_debugMask, GT_6CLASS, "DBLL_open: "
"Dynamic_Load_Module failed: 0x%lx\n", err);
status = DSP_EDYNLOAD;
} else {
/* Now that we have the symbol table, we can unload */
err = Dynamic_Unload_Module(zlLib->mHandle,
&zlLib->symbol.dlSymbol,
&zlLib->allocate.dlAlloc,
&zlLib->init.dlInit);
if (err != 0) {
GT_1trace(DBLL_debugMask, GT_6CLASS,
"DBLL_open: "
"Dynamic_Unload_Module failed: 0x%lx\n",
err);
status = DSP_EDYNLOAD;
}
zlLib->mHandle = NULL;
}
}
func_cont:
if (DSP_SUCCEEDED(status)) {
if (zlLib->openRef == 1) {
/* First time opened - insert in list */
if (zlTarget->head)
(zlTarget->head)->prev = zlLib;
zlLib->prev = NULL;
zlLib->next = zlTarget->head;
zlTarget->head = zlLib;
}
*pLib = (struct DBLL_LibraryObj *)zlLib;
} else {
*pLib = NULL;
if (zlLib != NULL)
DBLL_close((struct DBLL_LibraryObj *)zlLib);
}
DBC_Ensure((DSP_SUCCEEDED(status) && (zlLib->openRef > 0) &&
MEM_IsValidHandle(((struct DBLL_LibraryObj *)(*pLib)),
DBLL_LIBSIGNATURE)) || (DSP_FAILED(status) && *pLib == NULL));
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;
}
/*
* ======== DBLL_readSect ========
* Get the content of a COFF section.
*/
DSP_STATUS DBLL_readSect(struct DBLL_LibraryObj *lib, char *name,
char *pContent, u32 size)
{
struct DBLL_LibraryObj *zlLib = (struct DBLL_LibraryObj *)lib;
bool fOpenedDoff = false;
u32 uByteSize; /* size of bytes */
u32 ulSectSize; /* size of section */
const struct LDR_SECTION_INFO *sect = NULL;
DSP_STATUS status = DSP_SOK;
DBC_Require(cRefs > 0);
DBC_Require(MEM_IsValidHandle(zlLib, DBLL_LIBSIGNATURE));
DBC_Require(name != NULL);
DBC_Require(pContent != NULL);
DBC_Require(size != 0);
GT_4trace(DBLL_debugMask, GT_ENTER,
"DBLL_readSect: lib: 0x%x name: %s "
"pContent: 0x%x size: 0x%x\n", lib, name, pContent, size);
/* If DOFF file is not open, we open it. */
if (zlLib != NULL) {
if (zlLib->fp == NULL) {
status = dofOpen(zlLib);
if (DSP_SUCCEEDED(status))
fOpenedDoff = true;
} else {
(*(zlLib->pTarget->attrs.fseek))(zlLib->fp,
zlLib->ulPos, SEEK_SET);
}
} else {
status = DSP_EHANDLE;
}
if (DSP_FAILED(status))
goto func_cont;
uByteSize = 1;
if (!DLOAD_GetSectionInfo(zlLib->desc, name, §)) {
status = DSP_ENOSECT;
goto func_cont;
}
/*
* Ensure the supplied buffer size is sufficient to store
* the section content to be read.
*/
ulSectSize = sect->size * uByteSize;
/* Make sure size is even for good swap */
if (ulSectSize % 2)
ulSectSize++;
/* Align size */
ulSectSize = DOFF_ALIGN(ulSectSize);
if (ulSectSize > size) {
status = DSP_EFAIL;
} else {
if (!DLOAD_GetSection(zlLib->desc, sect, pContent))
status = DSP_EFREAD;
}
func_cont:
if (fOpenedDoff) {
dofClose(zlLib);
fOpenedDoff = false;
}
return status;
}
/*
* ======== 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;
}
/*
* ======== STRM_Open ========
* Purpose:
* Open a stream for sending/receiving data buffers to/from a task or
* XDAIS socket node on the DSP.
*/
DSP_STATUS STRM_Open(struct NODE_OBJECT *hNode, u32 uDir, u32 uIndex,
IN struct STRM_ATTR *pAttr,
OUT struct STRM_OBJECT **phStrm,
struct PROCESS_CONTEXT *pr_ctxt)
{
struct STRM_MGR *hStrmMgr;
struct WMD_DRV_INTERFACE *pIntfFxns;
u32 ulChnlId;
struct STRM_OBJECT *pStrm = NULL;
short int uMode;
struct CHNL_ATTRS chnlAttrs;
DSP_STATUS status = DSP_SOK;
struct CMM_OBJECT *hCmmMgr = NULL; /* Shared memory manager hndl */
HANDLE hSTRMRes;
DBC_Require(cRefs > 0);
DBC_Require(phStrm != NULL);
DBC_Require(pAttr != NULL);
GT_5trace(STRM_debugMask, GT_ENTER,
"STRM_Open: hNode: 0x%x\tuDir: 0x%x\t"
"uIndex: 0x%x\tpAttr: 0x%x\tphStrm: 0x%x\n",
hNode, uDir, uIndex, pAttr, phStrm);
*phStrm = NULL;
if (uDir != DSP_TONODE && uDir != DSP_FROMNODE) {
status = DSP_EDIRECTION;
} else {
/* Get the channel id from the node (set in NODE_Connect()) */
status = NODE_GetChannelId(hNode, uDir, uIndex, &ulChnlId);
}
if (DSP_SUCCEEDED(status))
status = NODE_GetStrmMgr(hNode, &hStrmMgr);
if (DSP_SUCCEEDED(status)) {
MEM_AllocObject(pStrm, struct STRM_OBJECT, STRM_SIGNATURE);
if (pStrm == NULL) {
status = DSP_EMEMORY;
} else {
pStrm->hStrmMgr = hStrmMgr;
pStrm->uDir = uDir;
pStrm->strmState = STREAM_IDLE;
pStrm->hUserEvent = pAttr->hUserEvent;
if (pAttr->pStreamAttrIn != NULL) {
pStrm->uTimeout = pAttr->pStreamAttrIn->
uTimeout;
pStrm->uNumBufs = pAttr->pStreamAttrIn->
uNumBufs;
pStrm->lMode = pAttr->pStreamAttrIn->lMode;
pStrm->uSegment = pAttr->pStreamAttrIn->
uSegment;
pStrm->uAlignment = pAttr->pStreamAttrIn->
uAlignment;
pStrm->uDMAChnlId = pAttr->pStreamAttrIn->
uDMAChnlId;
pStrm->uDMAPriority = pAttr->pStreamAttrIn->
uDMAPriority;
chnlAttrs.uIOReqs = pAttr->pStreamAttrIn->
uNumBufs;
} else {
pStrm->uTimeout = DEFAULTTIMEOUT;
pStrm->uNumBufs = DEFAULTNUMBUFS;
pStrm->lMode = STRMMODE_PROCCOPY;
pStrm->uSegment = 0; /* local memory */
pStrm->uAlignment = 0;
pStrm->uDMAChnlId = 0;
pStrm->uDMAPriority = 0;
chnlAttrs.uIOReqs = DEFAULTNUMBUFS;
}
chnlAttrs.hReserved1 = NULL;
/* DMA chnl flush timeout */
chnlAttrs.hReserved2 = pStrm->uTimeout;
chnlAttrs.hEvent = NULL;
if (pAttr->hUserEvent != NULL)
chnlAttrs.hEvent = pAttr->hUserEvent;
}
}
if (DSP_FAILED(status))
goto func_cont;
if ((pAttr->pVirtBase == NULL) || !(pAttr->ulVirtSize > 0))
goto func_cont;
DBC_Assert(pStrm->lMode != STRMMODE_LDMA); /* no System DMA */
/* Get the shared mem mgr for this streams dev object */
status = DEV_GetCmmMgr(hStrmMgr->hDev, &hCmmMgr);
if (DSP_SUCCEEDED(status)) {
/*Allocate a SM addr translator for this strm.*/
status = CMM_XlatorCreate(&pStrm->hXlator, hCmmMgr, NULL);
if (DSP_SUCCEEDED(status)) {
DBC_Assert(pStrm->uSegment > 0);
/* Set translators Virt Addr attributes */
status = CMM_XlatorInfo(pStrm->hXlator,
(u8 **)&pAttr->pVirtBase, pAttr->ulVirtSize,
pStrm->uSegment, true);
}
}
func_cont:
if (DSP_SUCCEEDED(status)) {
/* Open channel */
uMode = (uDir == DSP_TONODE) ?
CHNL_MODETODSP : CHNL_MODEFROMDSP;
pIntfFxns = hStrmMgr->pIntfFxns;
status = (*pIntfFxns->pfnChnlOpen) (&(pStrm->hChnl),
hStrmMgr->hChnlMgr, uMode, ulChnlId, &chnlAttrs);
if (DSP_FAILED(status)) {
/*
* over-ride non-returnable status codes so we return
* something documented
*/
if (status != DSP_EMEMORY && status !=
DSP_EINVALIDARG && status != DSP_EFAIL) {
/*
* We got a status that's not return-able.
* Assert that we got something we were
* expecting (DSP_EHANDLE isn't acceptable,
* hStrmMgr->hChnlMgr better be valid or we
* assert here), and then return DSP_EFAIL.
*/
DBC_Assert(status == CHNL_E_OUTOFSTREAMS ||
status == CHNL_E_BADCHANID ||
status == CHNL_E_CHANBUSY ||
status == CHNL_E_NOIORPS);
status = DSP_EFAIL;
}
}
}
if (DSP_SUCCEEDED(status)) {
*phStrm = pStrm;
DRV_ProcInsertSTRMResElement(*phStrm, &hSTRMRes, pr_ctxt);
} else {
(void)DeleteStrm(pStrm);
}
/* ensure we return a documented error code */
DBC_Ensure((DSP_SUCCEEDED(status) &&
MEM_IsValidHandle((*phStrm), STRM_SIGNATURE)) ||
(*phStrm == NULL && (status == DSP_EHANDLE ||
status == DSP_EDIRECTION || status == DSP_EVALUE ||
status == DSP_EFAIL)));
return status;
}
/*
* ======== STRM_AllocateBuffer ========
* Purpose:
* Allocates buffers for a stream.
*/
DSP_STATUS STRM_AllocateBuffer(struct STRM_OBJECT *hStrm, u32 uSize,
OUT u8 **apBuffer, u32 uNumBufs)
{
DSP_STATUS status = DSP_SOK;
u32 uAllocated = 0;
u32 i;
#ifndef RES_CLEANUP_DISABLE
DSP_STATUS res_status = DSP_SOK;
u32 hProcess;
HANDLE pCtxt = NULL;
HANDLE hDrvObject;
HANDLE hSTRMRes;
#endif
DBC_Require(cRefs > 0);
DBC_Require(apBuffer != NULL);
GT_4trace(STRM_debugMask, GT_ENTER, "STRM_AllocateBuffer: hStrm: 0x%x\t"
"uSize: 0x%x\tapBuffer: 0x%x\tuNumBufs: 0x%x\n",
hStrm, uSize, apBuffer, uNumBufs);
if (MEM_IsValidHandle(hStrm, STRM_SIGNATURE)) {
/*
* Allocate from segment specified at time of stream open.
*/
if (uSize == 0)
status = DSP_ESIZE;
}
if (DSP_FAILED(status)) {
status = DSP_EHANDLE;
goto func_end;
}
for (i = 0; i < uNumBufs; i++) {
DBC_Assert(hStrm->hXlator != NULL);
(void)CMM_XlatorAllocBuf(hStrm->hXlator, &apBuffer[i], uSize);
if (apBuffer[i] == NULL) {
GT_0trace(STRM_debugMask, GT_7CLASS,
"STRM_AllocateBuffer: "
"DSP_FAILED to alloc shared memory.\n");
status = DSP_EMEMORY;
uAllocated = i;
break;
}
}
if (DSP_FAILED(status))
STRM_FreeBuffer(hStrm, apBuffer, uAllocated);
#ifndef RES_CLEANUP_DISABLE
if (DSP_FAILED(status))
goto func_end;
/* Return PID instead of process handle */
hProcess = current->pid;
res_status = CFG_GetObject((u32 *)&hDrvObject, REG_DRV_OBJECT);
if (DSP_FAILED(res_status))
goto func_end;
DRV_GetProcContext(hProcess, (struct DRV_OBJECT *)hDrvObject,
&pCtxt, NULL, 0);
if (pCtxt != NULL) {
if (DRV_GetSTRMResElement(hStrm, &hSTRMRes, pCtxt) !=
DSP_ENOTFOUND) {
DRV_ProcUpdateSTRMRes(uNumBufs, hSTRMRes, pCtxt);
}
}
#endif
func_end:
return status;
}
/*
* ======== NTFY_Register ========
* Purpose:
* Add a notification element to the list. If the notification is already
* registered, and uEventMask != 0, the notification will get posted for
* events specified in the new event mask. If the notification is already
* registered and uEventMask == 0, the notification will be unregistered.
*/
DSP_STATUS NTFY_Register(struct NTFY_OBJECT *hNtfy,
struct DSP_NOTIFICATION *hNotification,
u32 uEventMask, u32 uNotifyType)
{
struct NOTIFICATION *pNotify;
struct SYNC_ATTRS syncAttrs;
DSP_STATUS status = DSP_SOK;
DBC_Require(MEM_IsValidHandle(hNtfy, NTFY_SIGNATURE));
if (hNotification == NULL)
status = DSP_EHANDLE;
/* Return DSP_ENOTIMPL if uNotifyType is not supported */
if (DSP_SUCCEEDED(status)) {
if (!IsValidNotifyMask(uNotifyType))
status = DSP_ENOTIMPL;
}
if (DSP_FAILED(status))
return status;
(void)SYNC_EnterCS(hNtfy->hSync);
pNotify = (struct NOTIFICATION *)LST_First(hNtfy->notifyList);
while (pNotify != NULL) {
/* If there is more than one notification type, each
* type may require its own handler code. */
if (hNotification->handle == pNotify->hSync) {
/* found */
break;
}
pNotify = (struct NOTIFICATION *)LST_Next(hNtfy->notifyList,
(struct list_head *)pNotify);
}
if (pNotify == NULL) {
/* Not registered */
if (uEventMask == 0) {
status = DSP_EVALUE;
} else {
/* Allocate NOTIFICATION object, add to list */
pNotify = MEM_Calloc(sizeof(struct NOTIFICATION),
MEM_PAGED);
if (pNotify == NULL)
status = DSP_EMEMORY;
}
if (DSP_SUCCEEDED(status)) {
LST_InitElem((struct list_head *)pNotify);
/* If there is more than one notification type, each
* type may require its own handler code. */
status = SYNC_OpenEvent(&pNotify->hSync, &syncAttrs);
hNotification->handle = pNotify->hSync;
if (DSP_SUCCEEDED(status)) {
pNotify->uEventMask = uEventMask;
pNotify->uNotifyType = uNotifyType;
LST_PutTail(hNtfy->notifyList,
(struct list_head *)pNotify);
} else {
DeleteNotify(pNotify);
}
}
} else {
/* Found in list */
if (uEventMask == 0) {
/* Remove from list and free */
LST_RemoveElem(hNtfy->notifyList,
(struct list_head *)pNotify);
DeleteNotify(pNotify);
} else {
/* Update notification mask (type shouldn't change) */
pNotify->uEventMask = uEventMask;
}
}
(void)SYNC_LeaveCS(hNtfy->hSync);
return status;
}
