xref: /freebsd/sys/dev/pms/RefTisa/sallsdk/spc/sainit.c (revision e32fecd0c2c3ee37c47ee100f169e7eb0282a873)
1 /*******************************************************************************
2 *Copyright (c) 2014 PMC-Sierra, Inc.  All rights reserved.
3 *
4 *Redistribution and use in source and binary forms, with or without modification, are permitted provided
5 *that the following conditions are met:
6 *1. Redistributions of source code must retain the above copyright notice, this list of conditions and the
7 *following disclaimer.
8 *2. Redistributions in binary form must reproduce the above copyright notice,
9 *this list of conditions and the following disclaimer in the documentation and/or other materials provided
10 *with the distribution.
11 *
12 *THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR IMPLIED
13 *WARRANTIES,INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
14 *FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
15 *FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
16 *NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
17 *BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
18 *LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
19 *SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
20 
21 ********************************************************************************/
22 /*******************************************************************************/
23 /*! \file sainit.c
24  *  \brief The file implements the functions to initialize the LL layer
25  *
26  */
27 /******************************************************************************/
28 #include <sys/cdefs.h>
29 __FBSDID("$FreeBSD$");
30 #include <dev/pms/config.h>
31 
32 #include <dev/pms/RefTisa/sallsdk/spc/saglobal.h>
33 #ifdef SA_ENABLE_TRACE_FUNCTIONS
34 #ifdef siTraceFileID
35 #undef siTraceFileID
36 #endif
37 #define siTraceFileID 'F'
38 #endif
39 
40 bit32 gLLDebugLevel         = 3;
41 
42 #if defined(SALLSDK_DEBUG)
43 bit32 gLLDebugLevelSet      = 0; // block reinitialize from updating
44 bit32 gLLLogFuncDebugLevel  = 0;
45 bit32 gLLSoftResetCounter   = 0;
46 #endif
47 
48 bit32 gPollForMissingInt;
49 
50 #ifdef FW_EVT_LOG_TST
51 void  *eventLogAddress = NULL;
52 #endif
53 
54 extern bit32 gWait_3;
55 extern bit32 gWait_2;
56 bit32 gFPGA_TEST = 0; // If set unblock fpga functions
57 
58 /******************************************************************************/
59 /*! \brief Get the memory and lock requirement from LL layer
60  *
61  *  Get the memory and lock requirement from LL layer
62  *
63  *  \param agRoot             Handles for this instance of SAS/SATA hardware
64  *  \param swConfig           Pointer to the software configuration
65  *  \param memoryRequirement  Point to the data structure that holds the different
66  *                                       chunks of memory that are required
67  *  \param usecsPerTick       micro-seconds per tick for the LL layer
68  *  \param maxNumLocks        maximum number of locks for the LL layer
69  *
70  *  \return -void-
71  *
72  */
73 /*******************************************************************************/
74 GLOBAL void saGetRequirements(
75   agsaRoot_t              *agRoot,
76   agsaSwConfig_t          *swConfig,
77   agsaMemoryRequirement_t *memoryRequirement,
78   bit32                   *usecsPerTick,
79   bit32                   *maxNumLocks
80   )
81 {
82   bit32               memoryReqCount = 0;
83   bit32               i;
84   static mpiConfig_t  mpiConfig;
85   static mpiMemReq_t  mpiMemoryRequirement;
86 
87 
88   /* sanity check */
89   SA_ASSERT((agNULL != swConfig), "");
90   SA_ASSERT((agNULL != memoryRequirement), "");
91   SA_ASSERT((agNULL != usecsPerTick), "");
92   SA_ASSERT((agNULL != maxNumLocks), "");
93 
94   si_memset(&mpiMemoryRequirement, 0, sizeof(mpiMemReq_t));
95   si_memset(&mpiConfig, 0, sizeof(mpiConfig_t));
96 
97   SA_DBG1(("saGetRequirements:agRoot %p swConfig %p memoryRequirement %p usecsPerTick %p maxNumLocks %p\n",agRoot, swConfig,memoryRequirement,usecsPerTick,maxNumLocks));
98   SA_DBG1(("saGetRequirements: usecsPerTick 0x%x (%d)\n",*usecsPerTick,*usecsPerTick));
99 
100   /* Get Resource Requirements for SPC MPI */
101   /* Set the default/specified requirements swConfig from TD layer */
102   siConfiguration(agRoot, &mpiConfig, agNULL, swConfig);
103   mpiRequirementsGet(&mpiConfig, &mpiMemoryRequirement);
104 
105   /* memory requirement for saRoot, CACHE memory */
106   memoryRequirement->agMemory[LLROOT_MEM_INDEX].singleElementLength = sizeof(agsaLLRoot_t);
107   memoryRequirement->agMemory[LLROOT_MEM_INDEX].numElements = 1;
108   memoryRequirement->agMemory[LLROOT_MEM_INDEX].totalLength = sizeof(agsaLLRoot_t);
109   memoryRequirement->agMemory[LLROOT_MEM_INDEX].alignment = sizeof(void *);
110   memoryRequirement->agMemory[LLROOT_MEM_INDEX].type = AGSA_CACHED_MEM;
111   memoryReqCount ++;
112 
113   SA_DBG1(("saGetRequirements: agMemory[LLROOT_MEM_INDEX] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
114            memoryRequirement->agMemory[LLROOT_MEM_INDEX].singleElementLength,
115            memoryRequirement->agMemory[LLROOT_MEM_INDEX].totalLength,
116            memoryRequirement->agMemory[LLROOT_MEM_INDEX].alignment,
117            memoryRequirement->agMemory[LLROOT_MEM_INDEX].type ));
118 
119   /* memory requirement for Device Links, CACHE memory */
120   memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].singleElementLength = sizeof(agsaDeviceDesc_t);
121   memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].numElements = swConfig->numDevHandles;
122   memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].totalLength = sizeof(agsaDeviceDesc_t)
123                                                                 * swConfig->numDevHandles;
124   memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].alignment = sizeof(void *);
125   memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].type = AGSA_CACHED_MEM;
126   memoryReqCount ++;
127   SA_DBG1(("saGetRequirements: agMemory[DEVICELINK_MEM_INDEX] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
128            memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].singleElementLength,
129            memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].totalLength,
130            memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].alignment,
131            memoryRequirement->agMemory[DEVICELINK_MEM_INDEX].type ));
132 
133   /* memory requirement for IORequest Links, CACHE memory */
134   memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].singleElementLength = sizeof(agsaIORequestDesc_t);
135   /*
136   Add SA_RESERVED_REQUEST_COUNT to guarantee quality of service
137   */
138   memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].numElements = swConfig->maxActiveIOs + SA_RESERVED_REQUEST_COUNT;
139   memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].totalLength = sizeof(agsaIORequestDesc_t) *
140                 memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].numElements;
141   memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].alignment = sizeof(void *);
142   memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].type = AGSA_CACHED_MEM;
143   memoryReqCount ++;
144 
145   SA_DBG1(("saGetRequirements: agMemory[IOREQLINK_MEM_INDEX] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
146            memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].singleElementLength,
147            memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].totalLength,
148            memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].alignment,
149            memoryRequirement->agMemory[IOREQLINK_MEM_INDEX].type ));
150 
151   /* memory requirement for Timer Links, CACHE memory */
152   memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].singleElementLength = sizeof(agsaTimerDesc_t);
153   memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].numElements = NUM_TIMERS;
154   memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].totalLength = sizeof(agsaTimerDesc_t) * NUM_TIMERS;
155   memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].alignment = sizeof(void *);
156   memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].type = AGSA_CACHED_MEM;
157   memoryReqCount ++;
158   SA_DBG1(("saGetRequirements: agMemory[TIMERLINK_MEM_INDEX] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
159            memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].singleElementLength,
160            memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].totalLength,
161            memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].alignment,
162            memoryRequirement->agMemory[TIMERLINK_MEM_INDEX].type ));
163 
164 #ifdef SA_ENABLE_TRACE_FUNCTIONS
165 
166   /* memory requirement for LL trace memory */
167   memoryRequirement->agMemory[LL_FUNCTION_TRACE].singleElementLength = 1;
168   memoryRequirement->agMemory[LL_FUNCTION_TRACE].numElements = swConfig->TraceBufferSize;
169   memoryRequirement->agMemory[LL_FUNCTION_TRACE].totalLength = swConfig->TraceBufferSize;
170   memoryRequirement->agMemory[LL_FUNCTION_TRACE].alignment = sizeof(void *);
171   memoryRequirement->agMemory[LL_FUNCTION_TRACE].type = AGSA_CACHED_MEM;
172   memoryReqCount ++;
173 
174   SA_DBG1(("saGetRequirements: agMemory[LL_FUNCTION_TRACE] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
175            memoryRequirement->agMemory[LL_FUNCTION_TRACE].singleElementLength,
176            memoryRequirement->agMemory[LL_FUNCTION_TRACE].totalLength,
177            memoryRequirement->agMemory[LL_FUNCTION_TRACE].alignment,
178            memoryRequirement->agMemory[LL_FUNCTION_TRACE].type ));
179 
180 #endif /* END SA_ENABLE_TRACE_FUNCTIONS */
181 
182 #ifdef FAST_IO_TEST
183   {
184   agsaMem_t *agMemory = memoryRequirement->agMemory;
185 
186   /* memory requirement for Super IO CACHE memory */
187   agMemory[LL_FAST_IO].singleElementLength = sizeof(saFastRequest_t);
188   agMemory[LL_FAST_IO].numElements = LL_FAST_IO_SIZE;
189   agMemory[LL_FAST_IO].totalLength = LL_FAST_IO_SIZE *
190                                      agMemory[LL_FAST_IO].singleElementLength;
191   agMemory[LL_FAST_IO].alignment = sizeof(void*);
192   agMemory[LL_FAST_IO].type = AGSA_CACHED_MEM;
193   memoryReqCount ++;
194 
195   SA_DBG1(("saGetRequirements: agMemory[LL_FAST_IO] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
196            memoryRequirement->agMemory[LL_FAST_IO].singleElementLength,
197            memoryRequirement->agMemory[LL_FAST_IO].totalLength,
198            memoryRequirement->agMemory[LL_FAST_IO].alignment,
199            memoryRequirement->agMemory[LL_FAST_IO].type ));
200 
201   }
202 #endif
203 
204 #ifdef SA_ENABLE_HDA_FUNCTIONS
205   {
206   agsaMem_t *agMemory = memoryRequirement->agMemory;
207 
208   /* memory requirement for HDA FW image */
209   agMemory[HDA_DMA_BUFFER].singleElementLength = (1024 * 1024); /* must be greater than size of aap1 fw image */
210   agMemory[HDA_DMA_BUFFER].numElements = 1;
211   agMemory[HDA_DMA_BUFFER].totalLength = agMemory[HDA_DMA_BUFFER].numElements *
212                                      agMemory[HDA_DMA_BUFFER].singleElementLength;
213   agMemory[HDA_DMA_BUFFER].alignment = 32;
214   agMemory[HDA_DMA_BUFFER].type = AGSA_DMA_MEM;
215   memoryReqCount ++;
216   SA_DBG1(("saGetRequirements: agMemory[HDA_DMA_BUFFER] singleElementLength = 0x%x totalLength = 0x%x align = 0x%x type %x\n",
217            memoryRequirement->agMemory[HDA_DMA_BUFFER].singleElementLength,
218            memoryRequirement->agMemory[HDA_DMA_BUFFER].totalLength,
219            memoryRequirement->agMemory[HDA_DMA_BUFFER].alignment,
220            memoryRequirement->agMemory[HDA_DMA_BUFFER].type ));
221   }
222 #endif /* SA_ENABLE_HDA_FUNCTIONS */
223 
224   /* memory requirement for MPI MSGU layer, DMA memory */
225   for ( i = 0; i < mpiMemoryRequirement.count; i ++ )
226   {
227     memoryRequirement->agMemory[memoryReqCount].singleElementLength = mpiMemoryRequirement.region[i].elementSize;
228     memoryRequirement->agMemory[memoryReqCount].numElements         = mpiMemoryRequirement.region[i].numElements;
229     memoryRequirement->agMemory[memoryReqCount].totalLength         = mpiMemoryRequirement.region[i].totalLength;
230     memoryRequirement->agMemory[memoryReqCount].alignment           = mpiMemoryRequirement.region[i].alignment;
231     memoryRequirement->agMemory[memoryReqCount].type                = mpiMemoryRequirement.region[i].type;
232     SA_DBG1(("saGetRequirements:MPI agMemory[%d] singleElementLength = 0x%x  totalLength = 0x%x align = 0x%x type %x\n",
233           memoryReqCount,
234           memoryRequirement->agMemory[memoryReqCount].singleElementLength,
235           memoryRequirement->agMemory[memoryReqCount].totalLength,
236           memoryRequirement->agMemory[memoryReqCount].alignment,
237           memoryRequirement->agMemory[memoryReqCount].type ));
238     memoryReqCount ++;
239   }
240 
241 
242   /* requirement for locks */
243   if (swConfig->param3 == agNULL)
244   {
245     *maxNumLocks = (LL_IOREQ_IBQ_LOCK + AGSA_MAX_INBOUND_Q );
246     SA_DBG1(("saGetRequirements: param3 == agNULL maxNumLocks   %d\n", *maxNumLocks ));
247   }
248   else
249   {
250     agsaQueueConfig_t *queueConfig;
251     queueConfig = (agsaQueueConfig_t *)swConfig->param3;
252     *maxNumLocks = (LL_IOREQ_IBQ_LOCK_PARM + queueConfig->numInboundQueues );
253     SA_DBG1(("saGetRequirements: maxNumLocks   %d\n", *maxNumLocks ));
254   }
255 
256 
257   /* setup the time tick */
258   *usecsPerTick = SA_USECS_PER_TICK;
259 
260   SA_ASSERT(memoryReqCount < AGSA_NUM_MEM_CHUNKS, "saGetRequirements: Exceed max number of memory place holder");
261 
262   /* set up memory requirement count */
263   memoryRequirement->count = memoryReqCount;
264 
265   swConfig->legacyInt_X = 1;
266   swConfig->max_MSI_InterruptVectors = 32;
267   swConfig->max_MSIX_InterruptVectors = 64;//16;
268 
269   SA_DBG1(("saGetRequirements:  swConfig->stallUsec  %d\n",swConfig->stallUsec  ));
270 
271 #ifdef SA_CONFIG_MDFD_REGISTRY
272   SA_DBG1(("saGetRequirements:  swConfig->disableMDF %d\n",swConfig->disableMDF));
273 #endif /*SA_CONFIG_MDFD_REGISTRY*/
274   /*SA_DBG1(("saGetRequirements:  swConfig->enableDIF  %d\n",swConfig->enableDIF  ));*/
275   /*SA_DBG1(("saGetRequirements:  swConfig->enableEncryption  %d\n",swConfig->enableEncryption  ));*/
276 #ifdef SA_ENABLE_HDA_FUNCTIONS
277   swConfig->hostDirectAccessSupport = 1;
278   swConfig->hostDirectAccessMode = 0;
279 #else
280   swConfig->hostDirectAccessSupport = 0;
281   swConfig->hostDirectAccessMode = 0;
282 #endif
283 
284 }
285 
286 /******************************************************************************/
287 /*! \brief Initialize the Hardware
288  *
289  *  Initialize the Hardware
290  *
291  *  \param agRoot             Handles for this instance of SAS/SATA hardware
292  *  \param memoryAllocated    Point to the data structure that holds the different
293                                         chunks of memory that are required
294  *  \param hwConfig           Pointer to the hardware configuration
295  *  \param swConfig           Pointer to the software configuration
296  *  \param usecsPerTick       micro-seconds per tick for the LL layer
297  *
298  *  \return If initialization is successful
299  *          - \e AGSA_RC_SUCCESS initialization is successful
300  *          - \e AGSA_RC_FAILURE initialization is not successful
301  */
302 /*******************************************************************************/
303 GLOBAL bit32 saInitialize(
304   agsaRoot_t              *agRoot,
305   agsaMemoryRequirement_t *memoryAllocated,
306   agsaHwConfig_t          *hwConfig,
307   agsaSwConfig_t          *swConfig,
308   bit32                   usecsPerTick
309   )
310 {
311   agsaLLRoot_t          *saRoot;
312   agsaDeviceDesc_t      *pDeviceDesc;
313   agsaIORequestDesc_t   *pRequestDesc;
314   agsaTimerDesc_t       *pTimerDesc;
315   agsaPort_t            *pPort;
316   agsaPortMap_t         *pPortMap;
317   agsaDeviceMap_t       *pDeviceMap;
318   agsaIOMap_t           *pIOMap;
319   bit32                 maxNumIODevices;
320   bit32                 i, j;
321   static mpiMemReq_t    mpiMemoryAllocated;
322   bit32                 Tried_NO_HDA = agFALSE;
323   bit32                 Double_Reset_HDA = agFALSE;
324   bit32                 ret = AGSA_RC_SUCCESS;
325 #ifdef FAST_IO_TEST
326   void   *fr; /* saFastRequest_t */
327   bit32  size;
328   bit32  alignment;
329 #endif
330 
331   /* sanity check */
332   SA_ASSERT((agNULL != agRoot), "");
333   SA_ASSERT((agNULL != memoryAllocated), "");
334   SA_ASSERT((agNULL != hwConfig), "");
335   SA_ASSERT((agNULL != swConfig), "");
336   SA_ASSERT((LLROOT_MEM_INDEX < memoryAllocated->count), "");
337   SA_ASSERT((DEVICELINK_MEM_INDEX < memoryAllocated->count), "");
338   SA_ASSERT((IOREQLINK_MEM_INDEX < memoryAllocated->count), "");
339   SA_ASSERT((TIMERLINK_MEM_INDEX < memoryAllocated->count), "");
340 
341   si_memset(&mpiMemoryAllocated, 0, sizeof(mpiMemReq_t));
342 
343   si_macro_check(agRoot);
344 
345   SA_DBG1(("saInitialize: WAIT_INCREMENT %d\n", WAIT_INCREMENT ));
346   SA_DBG1(("saInitialize: usecsPerTick %d\n", usecsPerTick ));
347   if(! smIS_SPC(agRoot))
348   {
349     if(! smIS_SPCV(agRoot))
350     {
351       SA_DBG1(("saInitialize: ossaHwRegReadConfig32 ID  reads as %08X\n", ossaHwRegReadConfig32(agRoot,0 ) ));
352       SA_DBG1(("saInitialize: expect %08X or %08X or\n",  VEN_DEV_SPCV, VEN_DEV_SPCVE));
353       SA_DBG1(("saInitialize: expect %08X or %08X or\n",  VEN_DEV_SPCVP, VEN_DEV_SPCVEP));
354       SA_DBG1(("saInitialize: expect %08X or %08X\n",     VEN_DEV_ADAPVEP, VEN_DEV_ADAPVP));
355       return AGSA_RC_FAILURE;
356     }
357   }
358 
359   if(  smIS_SPC(agRoot) && smIS_SPCV(agRoot))
360   {
361       SA_DBG1(("saInitialize: Macro error !smIS_SPC %d smIS_SPCv %d smIS_SFC %d\n",smIS_SPC(agRoot),smIS_SPCV(agRoot), smIS_SFC(agRoot) ));
362       return AGSA_RC_FAILURE;
363   }
364 
365   /* Check the memory allocated */
366   for ( i = 0; i < memoryAllocated->count; i ++ )
367   {
368     /* If memory allocation failed  */
369     if (memoryAllocated->agMemory[i].singleElementLength &&
370         memoryAllocated->agMemory[i].numElements)
371     {
372       if ( (0 != memoryAllocated->agMemory[i].numElements)
373           && (0 == memoryAllocated->agMemory[i].totalLength) )
374       {
375         /* return failure */
376         SA_DBG1(("saInitialize:AGSA_RC_FAILURE Memory[%d]  singleElementLength = 0x%x  numElements = 0x%x NOT allocated\n",
377           i,
378           memoryAllocated->agMemory[i].singleElementLength,
379           memoryAllocated->agMemory[i].numElements));
380         ret = AGSA_RC_FAILURE;
381         return ret;
382       }
383       else
384       {
385         SA_DBG1(("saInitialize: Memory[%d] singleElementLength = 0x%x  numElements = 0x%x allocated %p\n",
386           i,
387           memoryAllocated->agMemory[i].singleElementLength,
388           memoryAllocated->agMemory[i].numElements,
389           memoryAllocated->agMemory[i].virtPtr));
390       }
391     }
392   }
393 
394   /* Get the saRoot memory address */
395   saRoot = (agsaLLRoot_t *) (memoryAllocated->agMemory[LLROOT_MEM_INDEX].virtPtr);
396   SA_ASSERT((agNULL != saRoot), "saRoot");
397   if(agNULL == saRoot)
398   {
399     SA_DBG1(("saInitialize:AGSA_RC_FAILURE saRoot\n"));
400     return AGSA_RC_FAILURE;
401   }
402 
403   agRoot->sdkData = (void *) saRoot;
404 
405   SA_DBG1(("saInitialize: saRoot %p\n",saRoot));
406 
407   if ( (memoryAllocated != &saRoot->memoryAllocated) ||
408        (hwConfig != &saRoot->hwConfig) ||
409        (swConfig != &saRoot->swConfig) )
410   {
411     agsaMemoryRequirement_t *memA = &saRoot->memoryAllocated;
412     agsaHwConfig_t          *hwC  = &saRoot->hwConfig;
413     agsaSwConfig_t          *swC  = &saRoot->swConfig;
414 
415     /* Copy data here */
416 
417     *memA   = *memoryAllocated;
418     *hwC    = *hwConfig;
419     *swC    = *swConfig;
420   }
421 
422 
423 #if defined(SALLSDK_DEBUG)
424   if(gLLDebugLevelSet == 0)
425   {
426     gLLDebugLevelSet = 1;
427     gLLDebugLevel = swConfig->sallDebugLevel & 0xF;
428     SA_DBG1(("saInitialize:  gLLDebugLevel  %x\n",gLLDebugLevel));
429   }
430 #endif /* SALLSDK_DEBUG */
431 
432 #ifdef SA_ENABLE_TRACE_FUNCTIONS
433 
434   saRoot->TraceBufferLength = memoryAllocated->agMemory[LL_FUNCTION_TRACE].totalLength;
435   saRoot->TraceBuffer = memoryAllocated->agMemory[LL_FUNCTION_TRACE].virtPtr;
436 
437   siEnableTracing ( agRoot );
438 /*
439 */
440 
441 #endif /* SA_ENABLE_TRACE_FUNCTIONS */
442 
443 #ifdef FAST_IO_TEST
444   {
445   agsaMem_t *agMemory = memoryAllocated->agMemory;
446 
447   /* memory requirement for Super IO CACHE memory */
448   size = sizeof(saRoot->freeFastReq) / sizeof(saRoot->freeFastReq[0]);
449 
450   SA_ASSERT(size == agMemory[LL_FAST_IO].numElements, "");
451   SA_ASSERT(agMemory[LL_FAST_IO].virtPtr, "");
452   SA_ASSERT((agMemory[LL_FAST_IO].singleElementLength ==
453     sizeof(saFastRequest_t)) &&
454     (agMemory[LL_FAST_IO].numElements == LL_FAST_IO_SIZE) &&
455     (agMemory[LL_FAST_IO].totalLength == agMemory[LL_FAST_IO].numElements *
456                                  agMemory[LL_FAST_IO].singleElementLength), "");
457 
458   for (i = 0, alignment = agMemory[LL_FAST_IO].alignment,
459        fr = agMemory[LL_FAST_IO].virtPtr;
460        i < size; i++,
461        fr = (void*)((bitptr)fr + (bitptr)(((bit32)sizeof(saFastRequest_t) +
462                     alignment - 1) & ~(alignment - 1))))
463   {
464     saRoot->freeFastReq[i] = fr;
465   }
466   saRoot->freeFastIdx = size;
467   }
468 #endif /* FAST_IO_TEST*/
469 
470   smTraceFuncEnter(hpDBG_VERY_LOUD, "m1");
471 
472   SA_DBG1(("saInitialize: swConfig->PortRecoveryResetTimer    %x\n",swConfig->PortRecoveryResetTimer ));
473 
474   SA_DBG1(("saInitialize: hwDEVICE_ID_VENDID            0x%08x\n", ossaHwRegReadConfig32(agRoot,0)));
475   SA_DBG1(("saInitialize: CFGSTAT CFGCMD                0x%08x\n", ossaHwRegReadConfig32(agRoot,4)));
476   SA_DBG1(("saInitialize: CLSCODE REVID                 0x%08x\n", ossaHwRegReadConfig32(agRoot,8)));
477   SA_DBG1(("saInitialize: BIST DT HDRTYPE LATTIM CLSIZE 0x%08x\n", ossaHwRegReadConfig32(agRoot,12)));
478   SA_DBG1(("saInitialize: hwSVID                        0x%08x\n", ossaHwRegReadConfig32(agRoot,44)));
479 
480 
481 #ifdef SA_ENABLE_PCI_TRIGGER
482 
483    SA_DBG1(("saInitialize: SA_ENABLE_PCI_TRIGGER  a       0x%08x %p\n", saRoot->swConfig.PCI_trigger,&saRoot->swConfig.PCI_trigger));
484 
485   if( saRoot->swConfig.PCI_trigger & PCI_TRIGGER_INIT_TEST )
486   {
487     SA_DBG1(("saInitialize: SA_ENABLE_PCI_TRIGGER         0x%08x %p\n", saRoot->swConfig.PCI_trigger,&saRoot->swConfig.PCI_trigger));
488     saRoot->swConfig.PCI_trigger &= ~PCI_TRIGGER_INIT_TEST;
489     siPCITriger(agRoot);
490   }
491 #endif /* SA_ENABLE_PCI_TRIGGER */
492 
493 
494   saRoot->ChipId = (ossaHwRegReadConfig32(agRoot,0) & 0xFFFF0000);
495 
496   SA_DBG1(("saInitialize: saRoot->ChipId                0x%08x\n", saRoot->ChipId));
497   siUpdateBarOffsetTable(agRoot,saRoot->ChipId);
498 
499   if(saRoot->ChipId == VEN_DEV_SPC)
500   {
501     if(!  smIS_SPC(agRoot))
502     {
503       SA_DBG1(("saInitialize: smIS_SPC macro fail !!!!\n" ));
504       smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m1");
505       return AGSA_RC_FAILURE;
506     }
507 
508     SA_DBG1(("saInitialize:  SPC \n" ));
509   }
510   else if(saRoot->ChipId == VEN_DEV_HIL )
511   {
512     SA_DBG1(("saInitialize:  SPC HIL\n" ));
513     if(!  smIS_SPC(agRoot))
514     {
515       SA_DBG1(("saInitialize: smIS_SPC macro fail !!!!\n" ));
516       smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "m1");
517       return AGSA_RC_FAILURE;
518     }
519   }
520   else if(saRoot->ChipId == VEN_DEV_SPCV)
521   {
522     SA_DBG1(("saInitialize:  SPC V\n" ));
523     if(!  smIS_SPCV(agRoot))
524     {
525       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
526       smTraceFuncExit(hpDBG_VERY_LOUD, 'c', "m1");
527       return AGSA_RC_FAILURE;
528     }
529   }
530   else if(saRoot->ChipId == VEN_DEV_SPCVE)
531   {
532     SA_DBG1(("saInitialize:  SPC VE\n" ));
533     if(!  smIS_SPCV(agRoot))
534     {
535       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
536       smTraceFuncExit(hpDBG_VERY_LOUD, 'd', "m1");
537       return AGSA_RC_FAILURE;
538     }
539   }
540   else if(saRoot->ChipId == VEN_DEV_SPCVP)
541   {
542     SA_DBG1(("saInitialize:  SPC VP\n" ));
543     if(!  smIS_SPCV(agRoot))
544     {
545       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
546       smTraceFuncExit(hpDBG_VERY_LOUD, 'e', "m1");
547       return AGSA_RC_FAILURE;
548     }
549   }
550   else if(saRoot->ChipId == VEN_DEV_SPCVEP)
551   {
552     SA_DBG1(("saInitialize:  SPC VEP\n" ));
553     if(!  smIS_SPCV(agRoot))
554     {
555       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
556       smTraceFuncExit(hpDBG_VERY_LOUD, 'f', "m1");
557       return AGSA_RC_FAILURE;
558     }
559   }
560   else if(saRoot->ChipId == VEN_DEV_ADAPVP)
561   {
562     SA_DBG1(("saInitialize: Adaptec 8088\n" ));
563   }
564   else if(saRoot->ChipId == VEN_DEV_ADAPVEP)
565   {
566     SA_DBG1(("saInitialize: Adaptec 8089\n" ));
567   }
568   else if(saRoot->ChipId == VEN_DEV_SPC12V)
569   {
570     SA_DBG1(("saInitialize:  SPC 12V\n" ));
571     if(!  smIS_SPCV(agRoot))
572     {
573       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
574       smTraceFuncExit(hpDBG_VERY_LOUD, 'g', "m1");
575       return AGSA_RC_FAILURE;
576     }
577   }
578   else if(saRoot->ChipId == VEN_DEV_SPC12VE)
579   {
580     SA_DBG1(("saInitialize:  SPC 12VE\n" ));
581     if(!  smIS_SPCV(agRoot))
582     {
583       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
584       smTraceFuncExit(hpDBG_VERY_LOUD, 'h', "m1");
585       return AGSA_RC_FAILURE;
586     }
587   }
588   else if(saRoot->ChipId == VEN_DEV_SPC12VP)
589   {
590     SA_DBG1(("saInitialize:  SPC 12VP\n" ));
591     if(!  smIS_SPCV(agRoot))
592     {
593       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
594       smTraceFuncExit(hpDBG_VERY_LOUD, 'i', "m1");
595       return AGSA_RC_FAILURE;
596     }
597   }
598   else if(saRoot->ChipId == VEN_DEV_SPC12VEP)
599   {
600     SA_DBG1(("saInitialize:  SPC 12VEP\n" ));
601     if(!  smIS_SPCV(agRoot))
602     {
603       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
604       smTraceFuncExit(hpDBG_VERY_LOUD, 'j', "m1");
605       return AGSA_RC_FAILURE;
606     }
607   }
608   else if(saRoot->ChipId == VEN_DEV_SPC12ADP)
609   {
610     SA_DBG1(("saInitialize:  SPC 12ADP\n" ));
611     if(!  smIS_SPCV(agRoot))
612     {
613       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
614       smTraceFuncExit(hpDBG_VERY_LOUD, 'k', "m1");
615       return AGSA_RC_FAILURE;
616     }
617   }
618   else if(saRoot->ChipId == VEN_DEV_SPC12ADPE)
619   {
620     SA_DBG1(("saInitialize:  SPC 12ADPE\n" ));
621     if(!  smIS_SPCV(agRoot))
622     {
623       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
624       smTraceFuncExit(hpDBG_VERY_LOUD, 'l', "m1");
625       return AGSA_RC_FAILURE;
626     }
627   }
628   else if(saRoot->ChipId == VEN_DEV_SPC12ADPP)
629   {
630     SA_DBG1(("saInitialize:  SPC 12ADPP\n" ));
631     if(!  smIS_SPCV(agRoot))
632     {
633       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
634       smTraceFuncExit(hpDBG_VERY_LOUD, 'm', "m1");
635       return AGSA_RC_FAILURE;
636     }
637   }
638   else if(saRoot->ChipId == VEN_DEV_SPC12ADPEP)
639   {
640     SA_DBG1(("saInitialize:  SPC 12ADPEP\n" ));
641     if(!  smIS_SPCV(agRoot))
642     {
643       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
644       smTraceFuncExit(hpDBG_VERY_LOUD, 'n', "m1");
645       return AGSA_RC_FAILURE;
646     }
647   }
648   else if(saRoot->ChipId == VEN_DEV_SPC12SATA)
649   {
650     SA_DBG1(("saInitialize:  SPC12SATA\n" ));
651     if(!  smIS_SPCV(agRoot))
652     {
653       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
654       smTraceFuncExit(hpDBG_VERY_LOUD, 'o', "m1");
655       return AGSA_RC_FAILURE;
656     }
657   }
658   else if(saRoot->ChipId ==  VEN_DEV_9015)
659   {
660     SA_DBG1(("saInitialize:  SPC 12V FPGA\n" ));
661     if(!  smIS_SPCV(agRoot))
662     {
663       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
664       smTraceFuncExit(hpDBG_VERY_LOUD, 'p', "m1");
665       return AGSA_RC_FAILURE;
666     }
667   }
668   else if(saRoot->ChipId ==  VEN_DEV_9060)
669   {
670     SA_DBG1(("saInitialize:  SPC 12V FPGA B\n" ));
671     if(!  smIS_SPCV(agRoot))
672     {
673       SA_DBG1(("saInitialize: smIS_SPCV macro fail !!!!\n" ));
674       smTraceFuncExit(hpDBG_VERY_LOUD, 'q', "m1");
675       return AGSA_RC_FAILURE;
676     }
677   }
678   else if(saRoot->ChipId == VEN_DEV_SFC)
679   {
680     SA_DBG1(("saInitialize: SFC \n" ));
681   }
682   else
683   {
684     SA_DBG1(("saInitialize saRoot->ChipId %8X expect %8X or %8X\n", saRoot->ChipId,VEN_DEV_SPC, VEN_DEV_SPCV));
685     SA_ASSERT(0, "ChipId");
686     smTraceFuncExit(hpDBG_VERY_LOUD, 'r', "m1");
687     return AGSA_RC_FAILURE;
688   }
689 
690   if( smIS_SPC(agRoot))
691   {
692     SA_DBG1(("saInitialize: Rev is A %d B %d C %d\n",smIsCfgSpcREV_A(agRoot),smIsCfgSpcREV_B(agRoot),smIsCfgSpcREV_C(agRoot)));
693   }
694   else
695   {
696     SA_DBG1(("saInitialize: Rev is A %d B %d C %d\n",smIsCfgVREV_A(agRoot),smIsCfgVREV_B(agRoot),smIsCfgVREV_C(agRoot)));
697   }
698 
699   if( smIS_SPC(agRoot))
700   {
701     SA_DBG1(("saInitialize: LINK_CTRL 0x%08x Speed 0x%X Lanes 0x%X \n", ossaHwRegReadConfig32(agRoot,128),
702       ((ossaHwRegReadConfig32(agRoot,128) & 0x000F0000) >> 16),
703       ((ossaHwRegReadConfig32(agRoot,128) & 0x0FF00000) >> 20) ));
704   }
705   else
706   {
707     SA_DBG1(("saInitialize: LINK_CTRL 0x%08x Speed 0x%X Lanes 0x%X \n", ossaHwRegReadConfig32(agRoot,208),
708       ((ossaHwRegReadConfig32(agRoot,208) & 0x000F0000) >> 16),
709       ((ossaHwRegReadConfig32(agRoot,208) & 0x0FF00000) >> 20) ));
710   }
711 
712   SA_DBG1(("saInitialize: V_SoftResetRegister  %08X\n",  ossaHwRegReadExt(agRoot, PCIBAR0, V_SoftResetRegister )));
713 
714 /*
715   SA_DBG1(("saInitialize:TOP_BOOT_STRAP STRAP_BIT %X\n",  ossaHwRegReadExt(agRoot, PCIBAR1, 0) ));
716 
717   SA_DBG1(("SPC_REG_TOP_DEVICE_ID  %8X expect %08X\n",  ossaHwRegReadExt(agRoot, PCIBAR2, SPC_REG_TOP_DEVICE_ID), SPC_TOP_DEVICE_ID));
718   SA_DBG1(("SPC_REG_TOP_DEVICE_ID  %8X expect %08X\n",  siHalRegReadExt( agRoot, GEN_SPC_REG_TOP_DEVICE_ID,SPC_REG_TOP_DEVICE_ID ) , SPC_TOP_DEVICE_ID));
719 
720   SA_DBG1(("SPC_REG_TOP_BOOT_STRAP %8X expect %08X\n",  ossaHwRegReadExt(agRoot, PCIBAR2, SPC_REG_TOP_BOOT_STRAP), SPC_TOP_BOOT_STRAP));
721 
722   SA_DBG1(("swConfig->numSASDevHandles =%d\n", swConfig->numDevHandles));
723 */
724   smTrace(hpDBG_VERY_LOUD,"29",swConfig->numDevHandles);
725   /* TP:29 swConfig->numDevHandles */
726 
727   /* Setup Device link */
728   /* Save the information of allocated device Link memory */
729   saRoot->deviceLinkMem = memoryAllocated->agMemory[DEVICELINK_MEM_INDEX];
730   if(agNULL == saRoot->deviceLinkMem.virtPtr)
731   {
732     SA_ASSERT(0, "deviceLinkMem");
733     smTraceFuncExit(hpDBG_VERY_LOUD, 'q', "m1");
734     return AGSA_RC_FAILURE;
735   }
736 
737   si_memset(saRoot->deviceLinkMem.virtPtr, 0, saRoot->deviceLinkMem.totalLength);
738   SA_DBG2(("saInitialize: [%d] saRoot->deviceLinkMem VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n",
739     DEVICELINK_MEM_INDEX,
740     saRoot->deviceLinkMem.virtPtr,
741     saRoot->deviceLinkMem.phyAddrLower,
742     saRoot->deviceLinkMem.numElements,
743     saRoot->deviceLinkMem.totalLength,
744     saRoot->deviceLinkMem.type));
745 
746   maxNumIODevices = swConfig->numDevHandles;
747   SA_DBG2(("saInitialize:  maxNumIODevices=%d, swConfig->numDevHandles=%d \n",
748     maxNumIODevices,
749     swConfig->numDevHandles));
750 
751 #ifdef SA_ENABLE_PCI_TRIGGER
752   SA_DBG1(("saInitialize:  swConfig->PCI_trigger= 0x%x\n", swConfig->PCI_trigger));
753 #endif /* SA_ENABLE_PCI_TRIGGER */
754 
755   /* Setup free IO Devices link list */
756   saLlistInitialize(&(saRoot->freeDevicesList));
757   for ( i = 0; i < (bit32) maxNumIODevices; i ++ )
758   {
759     /* get the pointer to the device descriptor */
760     pDeviceDesc = (agsaDeviceDesc_t *) AGSAMEM_ELEMENT_READ(&(saRoot->deviceLinkMem), i);
761     /* Initialize device descriptor */
762     saLlinkInitialize(&(pDeviceDesc->linkNode));
763 
764     pDeviceDesc->initiatorDevHandle.osData    = agNULL;
765     pDeviceDesc->initiatorDevHandle.sdkData   = agNULL;
766     pDeviceDesc->targetDevHandle.osData       = agNULL;
767     pDeviceDesc->targetDevHandle.sdkData      = agNULL;
768     pDeviceDesc->deviceType                   = SAS_SATA_UNKNOWN_DEVICE;
769     pDeviceDesc->pPort                        = agNULL;
770     pDeviceDesc->DeviceMapIndex               = 0;
771 
772     saLlistInitialize(&(pDeviceDesc->pendingIORequests));
773 
774     /* Add the device descriptor to the free IO device link list */
775     saLlistAdd(&(saRoot->freeDevicesList), &(pDeviceDesc->linkNode));
776   }
777 
778   /* Setup IO Request link */
779   /* Save the information of allocated IO Request Link memory */
780   saRoot->IORequestMem = memoryAllocated->agMemory[IOREQLINK_MEM_INDEX];
781   si_memset(saRoot->IORequestMem.virtPtr, 0, saRoot->IORequestMem.totalLength);
782 
783   SA_DBG2(("saInitialize: [%d] saRoot->IORequestMem  VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n",
784     IOREQLINK_MEM_INDEX,
785     saRoot->IORequestMem.virtPtr,
786     saRoot->IORequestMem.phyAddrLower,
787     saRoot->IORequestMem.numElements,
788     saRoot->IORequestMem.totalLength,
789     saRoot->IORequestMem.type));
790 
791   /* Setup free IO  Request link list */
792   saLlistIOInitialize(&(saRoot->freeIORequests));
793   saLlistIOInitialize(&(saRoot->freeReservedRequests));
794   for ( i = 0; i < swConfig->maxActiveIOs; i ++ )
795   {
796     /* get the pointer to the request descriptor */
797     pRequestDesc = (agsaIORequestDesc_t *) AGSAMEM_ELEMENT_READ(&(saRoot->IORequestMem), i);
798     /* Initialize request descriptor */
799     saLlinkInitialize(&(pRequestDesc->linkNode));
800 
801     pRequestDesc->valid             = agFALSE;
802     pRequestDesc->requestType       = AGSA_REQ_TYPE_UNKNOWN;
803     pRequestDesc->pIORequestContext = agNULL;
804     pRequestDesc->HTag              = i;
805     pRequestDesc->pDevice           = agNULL;
806     pRequestDesc->pPort             = agNULL;
807 
808     /* Add the request descriptor to the free Reserved Request link list */
809   /* SMP request must get service so reserve one request when first SMP completes */
810     if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
811     {
812       saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequestDesc->linkNode));
813     }
814     else
815     {
816     /* Add the request descriptor to the free IO Request link list */
817       saLlistIOAdd(&(saRoot->freeIORequests), &(pRequestDesc->linkNode));
818     }
819 
820   }
821 
822   /* Setup timer link */
823   /* Save the information of allocated timer Link memory */
824   saRoot->timerLinkMem = memoryAllocated->agMemory[TIMERLINK_MEM_INDEX];
825   si_memset(saRoot->timerLinkMem.virtPtr, 0, saRoot->timerLinkMem.totalLength);
826   SA_DBG2(("saInitialize: [%d] saRoot->timerLinkMem  VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n",
827     TIMERLINK_MEM_INDEX,
828     saRoot->timerLinkMem.virtPtr,
829     saRoot->timerLinkMem.phyAddrLower,
830     saRoot->timerLinkMem.numElements,
831     saRoot->timerLinkMem.totalLength,
832     saRoot->timerLinkMem.type ));
833 
834   /* Setup free timer link list */
835   saLlistInitialize(&(saRoot->freeTimers));
836   for ( i = 0; i < NUM_TIMERS; i ++ )
837   {
838     /* get the pointer to the timer descriptor */
839     pTimerDesc = (agsaTimerDesc_t *) AGSAMEM_ELEMENT_READ(&(saRoot->timerLinkMem), i);
840     /* Initialize timer descriptor */
841     saLlinkInitialize(&(pTimerDesc->linkNode));
842 
843     pTimerDesc->valid         = agFALSE;
844     pTimerDesc->timeoutTick   = 0;
845     pTimerDesc->pfnTimeout    = agNULL;
846     pTimerDesc->Event         = 0;
847     pTimerDesc->pParm         = agNULL;
848 
849     /* Add the timer descriptor to the free timer link list */
850     saLlistAdd(&(saRoot->freeTimers), &(pTimerDesc->linkNode));
851   }
852   /* Setup valid timer link list */
853   saLlistInitialize(&(saRoot->validTimers));
854 
855   /* Setup Phys */
856   /* Setup PhyCount */
857   saRoot->phyCount = (bit8) hwConfig->phyCount;
858   /* Init Phy data structure */
859   for ( i = 0; i < saRoot->phyCount; i ++ )
860   {
861     saRoot->phys[i].pPort = agNULL;
862     saRoot->phys[i].phyId = (bit8) i;
863 
864     /* setup phy status is PHY_STOPPED */
865     PHY_STATUS_SET(&(saRoot->phys[i]), PHY_STOPPED);
866   }
867 
868   /* Setup Ports */
869   /* Setup PortCount */
870   saRoot->portCount = saRoot->phyCount;
871   /* Setup free port link list */
872   saLlistInitialize(&(saRoot->freePorts));
873   for ( i = 0; i < saRoot->portCount; i ++ )
874   {
875     /* get the pointer to the port */
876     pPort = &(saRoot->ports[i]);
877     /* Initialize port */
878     saLlinkInitialize(&(pPort->linkNode));
879 
880     pPort->portContext.osData   = agNULL;
881     pPort->portContext.sdkData  = pPort;
882     pPort->portId         = 0;
883     pPort->portIdx        = (bit8) i;
884     pPort->status         = PORT_NORMAL;
885 
886     for ( j = 0; j < saRoot->phyCount; j ++ )
887     {
888       pPort->phyMap[j] = agFALSE;
889     }
890 
891     saLlistInitialize(&(pPort->listSASATADevices));
892 
893     /* Add the port to the free port link list */
894     saLlistAdd(&(saRoot->freePorts), &(pPort->linkNode));
895   }
896   /* Setup valid port link list */
897   saLlistInitialize(&(saRoot->validPorts));
898 
899   /* Init sysIntsActive - default is interrupt enable */
900   saRoot->sysIntsActive = agFALSE;
901 
902   /* setup timer tick granunarity */
903   saRoot->usecsPerTick = usecsPerTick;
904 
905   /* setup smallest timer increment for stall */
906   saRoot->minStallusecs = swConfig->stallUsec;
907 
908   SA_DBG1(("saInitialize: WAIT_INCREMENT %d\n" ,WAIT_INCREMENT ));
909   if (0 == WAIT_INCREMENT)
910   {
911     saRoot->minStallusecs = WAIT_INCREMENT_DEFAULT;
912   }
913 
914   /* initialize LL timer tick */
915   saRoot->timeTick = 0;
916 
917   /* initialize device (de)registration callback fns */
918   saRoot->DeviceRegistrationCB = agNULL;
919   saRoot->DeviceDeregistrationCB = agNULL;
920 
921   /* Initialize the PortMap for port context */
922   for ( i = 0; i < saRoot->portCount; i ++ )
923   {
924     pPortMap = &(saRoot->PortMap[i]);
925 
926     pPortMap->PortContext   = agNULL;
927     pPortMap->PortID        = PORT_MARK_OFF;
928     pPortMap->PortStatus    = PORT_NORMAL;
929     saRoot->autoDeregDeviceflag[i] = 0;
930   }
931 
932   /* Initialize the DeviceMap for device handle */
933   for ( i = 0; i < MAX_IO_DEVICE_ENTRIES; i ++ )
934   {
935     pDeviceMap = &(saRoot->DeviceMap[i]);
936 
937     pDeviceMap->DeviceHandle  = agNULL;
938     pDeviceMap->DeviceIdFromFW   =  i;
939   }
940 
941   /* Initialize the IOMap for IOrequest */
942   for ( i = 0; i < MAX_ACTIVE_IO_REQUESTS; i ++ )
943   {
944     pIOMap = &(saRoot->IOMap[i]);
945 
946     pIOMap->IORequest   = agNULL;
947     pIOMap->Tag         = MARK_OFF;
948   }
949 
950   /* setup mpi configuration */
951   if (!swConfig->param3)
952   {
953     /* default configuration */
954     siConfiguration(agRoot, &saRoot->mpiConfig, hwConfig, swConfig);
955   }
956   else
957   {
958     /* get from TD layer and save it */
959     agsaQueueConfig_t *dCFG = &saRoot->QueueConfig;
960     agsaQueueConfig_t *sCFG = (agsaQueueConfig_t *)swConfig->param3;
961 
962     if (dCFG != sCFG)
963     {
964       *dCFG = *sCFG;
965 
966       if ((hwConfig->hwInterruptCoalescingTimer) || (hwConfig->hwInterruptCoalescingControl))
967       {
968         for ( i = 0; i < sCFG->numOutboundQueues; i ++ )
969         {
970           /* disable FW assisted coalescing */
971           sCFG->outboundQueues[i].interruptDelay = 0;
972           sCFG->outboundQueues[i].interruptCount = 0;
973         }
974 
975         if(smIS_SPC(agRoot))
976         {
977           if (hwConfig->hwInterruptCoalescingTimer == 0)
978           {
979             hwConfig->hwInterruptCoalescingTimer = 1;
980             SA_DBG1(("saInitialize:InterruptCoalescingTimer should not be zero. Force to 1\n"));
981           }
982         }
983       }
984       ret = siConfiguration(agRoot, &saRoot->mpiConfig, hwConfig, swConfig);
985       if (AGSA_RC_FAILURE == ret)
986       {
987         SA_DBG1(("saInitialize failure queue number=%d\n", saRoot->QueueConfig.numInboundQueues));
988         agRoot->sdkData = agNULL;
989         smTraceFuncExit(hpDBG_VERY_LOUD, 'r', "m1");
990         return ret;
991       }
992     }
993   }
994 
995 
996   saRoot->swConfig.param3 = &saRoot->QueueConfig;
997 
998   mpiMemoryAllocated.count = memoryAllocated->count - MPI_MEM_INDEX;
999   for ( i = 0; i < mpiMemoryAllocated.count; i ++ )
1000   {
1001     mpiMemoryAllocated.region[i].virtPtr        = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].virtPtr;
1002     mpiMemoryAllocated.region[i].appHandle      = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].osHandle;
1003     mpiMemoryAllocated.region[i].physAddrUpper  = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].phyAddrUpper;
1004     mpiMemoryAllocated.region[i].physAddrLower  = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].phyAddrLower;
1005     mpiMemoryAllocated.region[i].totalLength    = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].totalLength;
1006     mpiMemoryAllocated.region[i].numElements    = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].numElements;
1007     mpiMemoryAllocated.region[i].elementSize    = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].singleElementLength;
1008     mpiMemoryAllocated.region[i].alignment      = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].alignment;
1009     mpiMemoryAllocated.region[i].type           = memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].type;
1010     SA_DBG2(("saInitialize: memoryAllocated->agMemory[%d] VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n",
1011       (MPI_IBQ_OBQ_INDEX + i),
1012       memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].virtPtr,
1013       memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].phyAddrLower,
1014       memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].numElements,
1015       memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].totalLength,
1016       memoryAllocated->agMemory[MPI_IBQ_OBQ_INDEX + i].type));
1017 
1018     /* set to zeros */
1019     SA_DBG1(("saInitialize: Zero memory region %d virt %p allocated %d\n",
1020             i,mpiMemoryAllocated.region[i].virtPtr,    mpiMemoryAllocated.region[i].totalLength));
1021     si_memset(mpiMemoryAllocated.region[i].virtPtr , 0,mpiMemoryAllocated.region[i].totalLength);
1022 
1023   }
1024 
1025   if ((!swConfig->max_MSI_InterruptVectors) &&
1026       (!swConfig->max_MSIX_InterruptVectors) &&
1027       (!swConfig->legacyInt_X))
1028   {
1029     /* polling mode */
1030     SA_DBG1(("saInitialize: configured as polling mode\n"));
1031   }
1032   else
1033   {
1034 
1035     SA_DBG1(("saInitialize: swConfig->max_MSI_InterruptVectors %d\n",swConfig->max_MSI_InterruptVectors));
1036     SA_DBG1(("saInitialize: swConfig->max_MSIX_InterruptVectors %d\n",swConfig->max_MSIX_InterruptVectors));
1037 
1038     if ((swConfig->legacyInt_X > 1) || (swConfig->max_MSI_InterruptVectors > 32) ||
1039       (swConfig->max_MSIX_InterruptVectors > 64))
1040     {
1041       /* error */
1042       agRoot->sdkData = agNULL;
1043       SA_DBG1(("saInitialize:AGSA_RC_FAILURE InterruptVectors A\n"));
1044       smTraceFuncExit(hpDBG_VERY_LOUD, 's', "m1");
1045       return AGSA_RC_FAILURE;
1046     }
1047     if ((swConfig->legacyInt_X) && (swConfig->max_MSI_InterruptVectors))
1048     {
1049       /* error */
1050       agRoot->sdkData = agNULL;
1051       SA_DBG1(("saInitialize:AGSA_RC_FAILURE InterruptVectors B\n"));
1052       smTraceFuncExit(hpDBG_VERY_LOUD, 't', "m1");
1053       return AGSA_RC_FAILURE;
1054     }
1055     else if ((swConfig->legacyInt_X) && (swConfig->max_MSIX_InterruptVectors))
1056     {
1057       /* error */
1058       agRoot->sdkData = agNULL;
1059       SA_DBG1(("saInitialize:AGSA_RC_FAILURE InterruptVectors C\n"));
1060       smTraceFuncExit(hpDBG_VERY_LOUD, 'u', "m1");
1061       return AGSA_RC_FAILURE;
1062     }
1063     else if ((swConfig->max_MSI_InterruptVectors) && (swConfig->max_MSIX_InterruptVectors))
1064     {
1065       /* error */
1066       agRoot->sdkData = agNULL;
1067       SA_DBG1(("saInitialize:AGSA_RC_FAILURE InterruptVectors D\n"));
1068       smTraceFuncExit(hpDBG_VERY_LOUD, 'v', "m1");
1069       return AGSA_RC_FAILURE;
1070     }
1071   }
1072 
1073   /* This section sets common interrupt for Legacy(IRQ) and MSI and MSIX types */
1074   if(smIS_SPC(agRoot))
1075   {
1076     SA_DBG1(("saInitialize:  SPC  interrupts\n" ));
1077 
1078     if (swConfig->legacyInt_X)
1079     {
1080       saRoot->OurInterrupt       = siOurLegacyInterrupt;      /* Called in ISR*/
1081       saRoot->DisableInterrupts  = siDisableLegacyInterrupts; /* Called in ISR*/
1082       saRoot->ReEnableInterrupts = siReenableLegacyInterrupts;/* Called in Delayed Int handler*/
1083     }
1084     else if (swConfig->max_MSIX_InterruptVectors)
1085     {
1086       saRoot->OurInterrupt       = siOurMSIXInterrupt;
1087       saRoot->DisableInterrupts  = siDisableMSIXInterrupts;
1088       saRoot->ReEnableInterrupts = siReenableMSIXInterrupts;
1089     }
1090     else if (swConfig->max_MSI_InterruptVectors)
1091     {
1092       saRoot->OurInterrupt       = siOurMSIInterrupt;
1093       saRoot->DisableInterrupts  = siDisableMSIInterrupts;
1094       saRoot->ReEnableInterrupts = siReenableMSIInterrupts;
1095     }
1096     else
1097     {
1098       /* polling mode */
1099       saRoot->OurInterrupt       = siOurLegacyInterrupt;      /* Called in ISR*/
1100       saRoot->DisableInterrupts  = siDisableLegacyInterrupts; /* Called in ISR*/
1101       saRoot->ReEnableInterrupts = siReenableLegacyInterrupts;/* Called in Delayed Int handler*/
1102     }
1103   }
1104   else
1105   {
1106     SA_DBG1(("saInitialize:  SPC V interrupts\n" ));
1107     if (swConfig->legacyInt_X )
1108     {
1109       SA_DBG1(("saInitialize:  SPC V legacyInt_X\n" ));
1110       saRoot->OurInterrupt       = siOurLegacy_V_Interrupt;      /* Called in ISR*/
1111       saRoot->DisableInterrupts  = siDisableLegacy_V_Interrupts; /* Called in ISR*/
1112       saRoot->ReEnableInterrupts = siReenableLegacy_V_Interrupts;/* Called in Delayed Int handler*/
1113     }
1114     else if (swConfig->max_MSIX_InterruptVectors)
1115     {
1116       SA_DBG1(("saInitialize:  SPC V max_MSIX_InterruptVectors %X\n", swConfig->max_MSIX_InterruptVectors));
1117       saRoot->OurInterrupt       = siOurMSIX_V_Interrupt;       /* */
1118       saRoot->DisableInterrupts  = siDisableMSIX_V_Interrupts;
1119       saRoot->ReEnableInterrupts = siReenableMSIX_V_Interrupts;
1120     }
1121     else if (swConfig->max_MSI_InterruptVectors)
1122     {
1123       SA_DBG1(("saInitialize:  SPC V max_MSI_InterruptVectors\n" ));
1124       saRoot->OurInterrupt       = siOurMSIX_V_Interrupt;        /* */
1125       saRoot->DisableInterrupts  = siDisableMSIX_V_Interrupts;
1126       saRoot->ReEnableInterrupts = siReenableMSIX_V_Interrupts;
1127     }
1128     else
1129     {
1130       /* polling mode */
1131       SA_DBG1(("saInitialize:  SPC V polling mode\n" ));
1132       saRoot->OurInterrupt       = siOurLegacy_V_Interrupt;      /* Called in ISR*/
1133       saRoot->DisableInterrupts  = siDisableLegacy_V_Interrupts; /* Called in ISR*/
1134       saRoot->ReEnableInterrupts = siReenableLegacy_V_Interrupts;/* Called in Delayed Int handler*/
1135     }
1136     SA_DBG1(("saInitialize:  SPC V\n" ));
1137   }
1138 
1139   saRoot->Use64bit =  (saRoot->QueueConfig.numOutboundQueues > 32 ) ? 1 : 0;
1140   if( smIS64bInt(agRoot))
1141   {
1142     SA_DBG1(("saInitialize: Use 64 bits for interrupts %d %d\n" ,saRoot->Use64bit, saRoot->QueueConfig.numOutboundQueues ));
1143   }
1144   else
1145   {
1146     SA_DBG1(("saInitialize: Use 32 bits for interrupts %d %d\n",saRoot->Use64bit , saRoot->QueueConfig.numOutboundQueues  ));
1147   }
1148 
1149 #ifdef SA_LL_IBQ_PROTECT
1150   SA_DBG1(("saInitialize: Inbound locking defined since LL_IOREQ_IBQ0_LOCK %d\n",LL_IOREQ_IBQ0_LOCK));
1151 #endif /* SA_LL_IBQ_PROTECT */
1152 
1153   /* Disable interrupt */
1154   saRoot->DisableInterrupts(agRoot, 0);
1155   SA_DBG1(("saInitialize: DisableInterrupts sysIntsActive %X\n" ,saRoot->sysIntsActive));
1156 
1157 #ifdef SA_FW_TEST_BUNCH_STARTS
1158   saRoot->BunchStarts_Enable        = FALSE;
1159   saRoot->BunchStarts_Threshold     = 5;
1160   saRoot->BunchStarts_Pending       = 0;
1161   saRoot->BunchStarts_TimeoutTicks  = 10;  // N x 100 ms
1162 #endif /* SA_FW_TEST_BUNCH_STARTS */
1163 
1164   /* clear the interrupt vector bitmap */
1165   for ( i = 0; i < MAX_NUM_VECTOR; i ++ )
1166   {
1167     saRoot->interruptVecIndexBitMap[i] = 0;
1168     saRoot->interruptVecIndexBitMap1[i] = 0;
1169   }
1170 
1171 #if defined(SALLSDK_DEBUG)
1172   smTrace(hpDBG_VERY_LOUD,"2Y",0);
1173   /* TP:2Y SCRATCH_PAD */
1174 
1175   SA_DBG1(("saInitialize: SCRATCH_PAD0 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_0)));
1176   SA_DBG1(("saInitialize: SCRATCH_PAD1 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1)));
1177   SA_DBG1(("saInitialize: SCRATCH_PAD2 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_2)));
1178   SA_DBG1(("saInitialize: SCRATCH_PAD3 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_3)));
1179 #endif /* SALLSDK_DEBUG */
1180 
1181   if(smIS_SPCV(agRoot))
1182   {
1183     bit32 ScratchPad1 =0;
1184     bit32 ScratchPad3 =0;
1185 
1186     ScratchPad1 = ossaHwRegRead(agRoot,V_Scratchpad_1_Register);
1187     ScratchPad3 = ossaHwRegRead(agRoot,V_Scratchpad_3_Register);
1188     if((ScratchPad1 & SCRATCH_PAD1_V_RAAE_MASK) ==  SCRATCH_PAD1_V_RAAE_MASK)
1189     {
1190       if(((ScratchPad3 & SCRATCH_PAD3_V_ENC_MASK ) == SCRATCH_PAD3_V_ENC_DIS_ERR ) ||
1191          ((ScratchPad3 & SCRATCH_PAD3_V_ENC_MASK ) == SCRATCH_PAD3_V_ENC_ENA_ERR )    )
1192       {
1193         SA_DBG1(("saInitialize:Warning Encryption Issue SCRATCH_PAD3 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_3)));
1194       }
1195     }
1196   }
1197 
1198   if( smIS_SPC(agRoot))
1199   {
1200 #ifdef SA_ENABLE_HDA_FUNCTIONS
1201     TryWithHDA_ON:
1202     Double_Reset_HDA = TRUE;
1203 
1204     if (swConfig->hostDirectAccessSupport)
1205     {
1206       if (AGSA_RC_FAILURE == siHDAMode(agRoot, swConfig->hostDirectAccessMode, (agsaFwImg_t *)swConfig->param4))
1207       {
1208         SA_DBG1(("saInitialize:AGSA_RC_FAILURE siHDAMode\n"));
1209         agRoot->sdkData = agNULL;
1210         smTraceFuncExit(hpDBG_VERY_LOUD, 'w', "m1");
1211         return AGSA_RC_FAILURE;
1212       }
1213       else
1214       {
1215         SA_DBG1(("saInitialize:1 Going to HDA mode HDA 0x%X \n",ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET)));
1216         if(Double_Reset_HDA == agFALSE)
1217         {
1218           siSpcSoftReset(agRoot, SPC_HDASOFT_RESET_SIGNATURE);
1219           SA_DBG1(("saInitialize: Double_Reset_HDA HDA 0x%X \n",ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET)));
1220           Double_Reset_HDA = TRUE;
1221           goto TryWithHDA_ON;
1222         }
1223       }
1224     }
1225     else
1226     {
1227       /* check FW is running */
1228       if (BOOTTLOADERHDA_IDLE == (ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET) & HDA_STATUS_BITS))
1229       {
1230         /* HDA mode */
1231         SA_DBG1(("saInitialize: No HDA mode enable and FW is not running.\n"));
1232         if(Tried_NO_HDA != agTRUE )
1233         {
1234 
1235           Tried_NO_HDA = TRUE;
1236           swConfig->hostDirectAccessSupport = 1;
1237           swConfig->hostDirectAccessMode = 1;
1238           siSpcSoftReset(agRoot, SPC_HDASOFT_RESET_SIGNATURE);
1239           SA_DBG1(("saInitialize: 2 Going to HDA mode HDA %X \n",ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET)));
1240           goto TryWithHDA_ON;
1241         }
1242         else
1243         {
1244           SA_DBG1(("saInitialize: could not start HDA mode HDA %X \n",ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET)));
1245           smTraceFuncExit(hpDBG_VERY_LOUD, 'x', "m1");
1246 
1247           return AGSA_RC_FAILURE;
1248         }
1249         smTraceFuncExit(hpDBG_VERY_LOUD, 'y', "m1");
1250         return AGSA_RC_FAILURE;
1251       }
1252     }
1253 #else /* SA_ENABLE_HDA_FUNCTIONS */
1254     /* check FW is running */
1255     if (BOOTTLOADERHDA_IDLE == (ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET) & HDA_STATUS_BITS) )
1256     {
1257       /* HDA mode */
1258       SA_DBG1(("saInitialize: No HDA mode enable and FW is not running.\n"));
1259       smTraceFuncExit(hpDBG_VERY_LOUD, 'z', "m1");
1260       return AGSA_RC_FAILURE;
1261     }
1262 #endif /* SA_ENABLE_HDA_FUNCTIONS */
1263   }
1264   else
1265   {
1266     SA_DBG1(("saInitialize: SPCv swConfig->hostDirectAccessMode %d swConfig->hostDirectAccessSupport %d\n",swConfig->hostDirectAccessMode,swConfig->hostDirectAccessSupport));
1267     if (swConfig->hostDirectAccessSupport)
1268     {
1269       bit32 hda_status;
1270       bit32 soft_reset_status = AGSA_RC_SUCCESS;
1271 
1272       SA_DBG1(("saInitialize: SPCv load HDA\n"));
1273 
1274       hda_status = (ossaHwRegReadExt(agRoot, PCIBAR0, SPC_V_HDA_RESPONSE_OFFSET+28));
1275 
1276       SA_DBG1(("saInitialize: hda_status 0x%x\n",hda_status));
1277 
1278       siScratchDump(agRoot);
1279 
1280       if( swConfig->hostDirectAccessMode == 0)
1281       {
1282         soft_reset_status = siSoftReset(agRoot, SPC_HDASOFT_RESET_SIGNATURE);
1283         if(soft_reset_status !=  AGSA_RC_SUCCESS)
1284         {
1285           agRoot->sdkData = agNULL;
1286           SA_DBG1(("saInitialize:AGSA_RC_FAILURE soft_reset_status\n"));
1287 
1288           smTraceFuncExit(hpDBG_VERY_LOUD, 'A', "m1");
1289           return AGSA_RC_FAILURE;
1290         }
1291       }
1292 
1293       if((hda_status  & SPC_V_HDAR_RSPCODE_MASK)  != SPC_V_HDAR_IDLE)
1294       {
1295         SA_DBG1(("saInitialize: hda_status not SPC_V_HDAR_IDLE 0x%08x\n", hda_status));
1296         soft_reset_status = siSoftReset(agRoot, SPC_HDASOFT_RESET_SIGNATURE);
1297         hda_status = (ossaHwRegReadExt(agRoot, PCIBAR0, SPC_V_HDA_RESPONSE_OFFSET+28));
1298         if((hda_status  & SPC_V_HDAR_RSPCODE_MASK)  != SPC_V_HDAR_IDLE)
1299         {
1300           SA_DBG1(("saInitialize: 2 reset hda_status not SPC_V_HDAR_IDLE 0x%08x\n", hda_status));
1301         }
1302       }
1303       if(soft_reset_status !=  AGSA_RC_SUCCESS)
1304       {
1305         agRoot->sdkData = agNULL;
1306         SA_DBG1(("saInitialize:AGSA_RC_FAILURE soft_reset_status A\n"));
1307         smTraceFuncExit(hpDBG_VERY_LOUD, 'B', "m1");
1308         return AGSA_RC_FAILURE;
1309       }
1310 
1311 #ifdef SA_ENABLE_HDA_FUNCTIONS
1312       if (AGSA_RC_FAILURE == siHDAMode_V(agRoot, swConfig->hostDirectAccessMode, (agsaFwImg_t *)swConfig->param4))
1313       {
1314         SA_DBG1(("saInitialize:AGSA_RC_FAILURE siHDAMode_V\n"));
1315 
1316         siChipResetV(agRoot, SPC_HDASOFT_RESET_SIGNATURE);
1317         agRoot->sdkData = agNULL;
1318         smTraceFuncExit(hpDBG_VERY_LOUD, 'C', "m1");
1319         return AGSA_RC_FAILURE;
1320       }
1321 #endif /* SA_ENABLE_HDA_FUNCTIONS */
1322 
1323     }
1324     else
1325     {
1326       SA_DBG1(("saInitialize: SPCv normal\n"));
1327     }
1328 
1329   }
1330 
1331   /* copy the table to the LL layer */
1332   si_memcpy(&saRoot->mpiConfig.phyAnalogConfig, &hwConfig->phyAnalogConfig, sizeof(agsaPhyAnalogSetupTable_t));
1333 
1334 #ifdef SALL_API_TEST
1335   /* Initialize the LL IO counter */
1336   si_memset(&saRoot->LLCounters, 0, sizeof(agsaIOCountInfo_t));
1337 #endif
1338 
1339   si_memset(&saRoot->IoErrorCount, 0, sizeof(agsaIOErrorEventStats_t));
1340   si_memset(&saRoot->IoEventCount, 0, sizeof(agsaIOErrorEventStats_t));
1341   if(smIS_SPC(agRoot))
1342   {
1343 	  if( smIS_spc8081(agRoot))
1344 	  {
1345 		if (AGSA_RC_FAILURE == siBar4Shift(agRoot, MBIC_GSM_SM_BASE))
1346 		{
1347 		  SA_DBG1(("saInitialize: siBar4Shift FAILED ******************************************\n"));
1348 		}
1349 	  }
1350 	siSpcSoftReset(agRoot, SPC_SOFT_RESET_SIGNATURE);
1351   }
1352   if(smIS_SPCV(agRoot))
1353   {
1354 	SA_DBG1(("saInitialize: saRoot->ChipId == VEN_DEV_SPCV\n"));
1355 	siChipResetV(agRoot, SPC_SOFT_RESET_SIGNATURE);
1356   }
1357 
1358   /* MPI Initialization */
1359   ret = mpiInitialize(agRoot, &mpiMemoryAllocated, &saRoot->mpiConfig);
1360   SA_DBG1(("saInitialize: MaxOutstandingIO 0x%x swConfig->maxActiveIOs 0x%x\n", saRoot->ControllerInfo.maxPendingIO,saRoot->swConfig.maxActiveIOs ));
1361 
1362 #ifdef SA_ENABLE_HDA_FUNCTIONS
1363   if( ret  == AGSA_RC_FAILURE && Tried_NO_HDA == agFALSE && smIS_SPC(agRoot))
1364   { /* FW not flashed  */
1365     Tried_NO_HDA=agTRUE;
1366     swConfig->hostDirectAccessSupport = 1;
1367     swConfig->hostDirectAccessMode = 1;
1368     siSoftReset(agRoot, SPC_SOFT_RESET_SIGNATURE);
1369     SA_DBG1(("saInitialize: 3 Going to HDA mode HDA %X \n",ossaHwRegReadExt(agRoot, PCIBAR3, HDA_RSP_OFFSET1MB+HDA_CMD_CODE_OFFSET)));
1370     goto TryWithHDA_ON;
1371   }
1372 
1373 #endif /* SA_ENABLE_HDA_FUNCTIONS */
1374 
1375   if( ret  == AGSA_RC_FAILURE)
1376   {
1377     SA_DBG1(("saInitialize:  AGSA_RC_FAILURE mpiInitialize\n"));
1378     SA_DBG1(("saInitialize: SCRATCH_PAD0 value = 0x%x\n", ossaHwRegRead(agRoot, V_Scratchpad_0_Register)));
1379     SA_DBG1(("saInitialize: SCRATCH_PAD1 value = 0x%x\n", ossaHwRegRead(agRoot, V_Scratchpad_1_Register)));
1380     SA_DBG1(("saInitialize: SCRATCH_PAD2 value = 0x%x\n", ossaHwRegRead(agRoot, V_Scratchpad_2_Register)));
1381     SA_DBG1(("saInitialize: SCRATCH_PAD3 value = 0x%x\n", ossaHwRegRead(agRoot, V_Scratchpad_3_Register)));
1382 
1383     if(saRoot->swConfig.fatalErrorInterruptEnable)
1384     {
1385       ossaDisableInterrupts(agRoot,saRoot->swConfig.fatalErrorInterruptVector );
1386     }
1387 
1388     agRoot->sdkData = agNULL;
1389     smTraceFuncExit(hpDBG_VERY_LOUD, 'D', "m1");
1390     return ret;
1391   }
1392 
1393   /* setup hardware interrupt coalescing control and timer registers */
1394   if(smIS_SPCV(agRoot))
1395   {
1396       SA_DBG1(("saInitialize: SPC_V Not set hwInterruptCoalescingTimer\n" ));
1397       SA_DBG1(("saInitialize: SPC_V Not set hwInterruptCoalescingControl\n" ));
1398   }
1399   else
1400   {
1401       ossaHwRegWriteExt(agRoot, PCIBAR1, SPC_ICTIMER,hwConfig->hwInterruptCoalescingTimer );
1402       ossaHwRegWriteExt(agRoot, PCIBAR1, SPC_ICCONTROL, hwConfig->hwInterruptCoalescingControl);
1403   }
1404 
1405 
1406   SA_DBG1(("saInitialize: swConfig->fatalErrorInterruptEnable  %X\n",swConfig->fatalErrorInterruptEnable));
1407 
1408   SA_DBG1(("saInitialize: saRoot->swConfig.fatalErrorInterruptVector  %X\n",saRoot->swConfig.fatalErrorInterruptVector));
1409   SA_DBG1(("saInitialize: swConfig->max_MSI_InterruptVectors   %X\n",swConfig->max_MSI_InterruptVectors));
1410   SA_DBG1(("saInitialize: swConfig->max_MSIX_InterruptVectors  %X\n",swConfig->max_MSIX_InterruptVectors));
1411   SA_DBG1(("saInitialize: swConfig->legacyInt_X                %X\n",swConfig->legacyInt_X));
1412   SA_DBG1(("saInitialize: swConfig->hostDirectAccessSupport    %X\n",swConfig->hostDirectAccessSupport));
1413   SA_DBG1(("saInitialize: swConfig->hostDirectAccessMode       %X\n",swConfig->hostDirectAccessMode));
1414 
1415 #ifdef SA_CONFIG_MDFD_REGISTRY
1416   SA_DBG1(("saInitialize: swConfig->disableMDF                 %X\n",swConfig->disableMDF));
1417 #endif /*SA_CONFIG_MDFD_REGISTRY*/
1418   /*SA_DBG1(("saInitialize: swConfig->enableDIF                  %X\n",swConfig->enableDIF));*/
1419   /*SA_DBG1(("saInitialize: swConfig->enableEncryption           %X\n",swConfig->enableEncryption));*/
1420 
1421 
1422   /* log message if failure */
1423   if (AGSA_RC_FAILURE == ret)
1424   {
1425     SA_DBG1(("saInitialize:AGSA_RC_FAILURE mpiInitialize\n"));
1426     /* Assign chip status */
1427     saRoot->chipStatus = CHIP_FATAL_ERROR;
1428   }
1429   else
1430   {
1431     /* Assign chip status */
1432     saRoot->chipStatus = CHIP_NORMAL;
1433 #ifdef SA_FW_TIMER_READS_STATUS
1434     siTimerAdd(agRoot,SA_FW_TIMER_READS_STATUS_INTERVAL, siReadControllerStatus,0,agNULL  );
1435 #endif /* SA_FW_TIMER_READS_STATUS */
1436   }
1437 
1438 
1439   if( ret == AGSA_RC_SUCCESS || ret == AGSA_RC_VERSION_UNTESTED)
1440   {
1441     if(gPollForMissingInt)
1442     {
1443       mpiOCQueue_t         *circularQ;
1444       SA_DBG1(("saInitialize:  saRoot->sysIntsActive %X\n",saRoot->sysIntsActive));
1445 
1446       circularQ = &saRoot->outboundQueue[0];
1447       OSSA_READ_LE_32(circularQ->agRoot, &circularQ->producerIdx, circularQ->piPointer, 0);
1448       SA_DBG1(("saInitialize: PI 0x%03x CI 0x%03x\n",circularQ->producerIdx, circularQ->consumerIdx));
1449     }
1450   }
1451 
1452   /* If fatal error interrupt enable we need checking it during the interrupt */
1453   SA_DBG1(("saInitialize: swConfig.fatalErrorInterruptEnable %d\n",saRoot->swConfig.fatalErrorInterruptEnable));
1454   SA_DBG1(("saInitialize: swConfig.fatalErrorInterruptVector %d\n",saRoot->swConfig.fatalErrorInterruptVector));
1455   SA_DBG1(("saInitialize: swConfig->max_MSIX_InterruptVectors  %X\n",swConfig->max_MSIX_InterruptVectors));
1456 
1457   if(saRoot->swConfig.fatalErrorInterruptEnable)
1458   {
1459 
1460     SA_DBG1(("saInitialize: Doorbell_Set  %08X U %08X\n",
1461                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
1462                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
1463     SA_DBG1(("saInitialize: Doorbell_Mask %08X U %08X\n",
1464                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register ),
1465                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU )));
1466 
1467     ossaReenableInterrupts(agRoot,saRoot->swConfig.fatalErrorInterruptVector );
1468 
1469     SA_DBG1(("saInitialize: Doorbell_Set  %08X U %08X\n",
1470                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
1471                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
1472     SA_DBG1(("saInitialize: Doorbell_Mask %08X U %08X\n",
1473                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register ),
1474                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU )));
1475   }
1476 
1477 
1478   SA_DBG1(("saInitialize: siDumpActiveIORequests\n"));
1479   siDumpActiveIORequests(agRoot, saRoot->swConfig.maxActiveIOs);
1480 
1481   smTraceFuncExit(hpDBG_VERY_LOUD, 'E', "m1");
1482   /* return */
1483   return ret;
1484 }
1485 
1486 
1487 
1488 #ifdef SA_FW_TIMER_READS_STATUS
1489 
1490 bit32 siReadControllerStatus(
1491                                   agsaRoot_t      *agRoot,
1492                                   bit32           Event,
1493                                   void *          pParm
1494                                   )
1495 {
1496   bit32 to_ret =0;
1497   agsaLLRoot_t *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1498   mpiReadGSTable(agRoot,  &saRoot->mpiGSTable);
1499 
1500   if(smIS_SPCV_2_IOP(agRoot))
1501   {
1502     if(saRoot->Iop1Tcnt_last  == saRoot->mpiGSTable.Iop1Tcnt )
1503     SA_DBG2(("siReadControllerStatus: Iop1 %d STUCK\n", saRoot->mpiGSTable.Iop1Tcnt));
1504   }
1505 
1506   if( saRoot->MsguTcnt_last == saRoot->mpiGSTable.MsguTcnt || saRoot->IopTcnt_last  == saRoot->mpiGSTable.IopTcnt )
1507   {
1508     SA_DBG1(("siReadControllerStatus: Msgu %d Iop %d\n",saRoot->mpiGSTable.MsguTcnt, saRoot->mpiGSTable.IopTcnt));
1509     saFatalInterruptHandler(agRoot,  saRoot->swConfig.fatalErrorInterruptVector  );
1510   }
1511   SA_DBG2(("siReadControllerStatus: Msgu %d Iop %d\n",saRoot->mpiGSTable.MsguTcnt, saRoot->mpiGSTable.IopTcnt));
1512 
1513   saRoot->MsguTcnt_last = saRoot->mpiGSTable.MsguTcnt;
1514   saRoot->IopTcnt_last  = saRoot->mpiGSTable.IopTcnt;
1515   saRoot->Iop1Tcnt_last = saRoot->mpiGSTable.Iop1Tcnt;
1516 
1517 
1518   if(gPollForMissingInt)
1519   {
1520     mpiOCQueue_t         *circularQ;
1521     SA_DBG4(("siReadControllerStatus:  saRoot->sysIntsActive %X\n",saRoot->sysIntsActive));
1522 
1523     circularQ = &saRoot->outboundQueue[0];
1524     OSSA_READ_LE_32(circularQ->agRoot, &circularQ->producerIdx, circularQ->piPointer, 0);
1525     if(circularQ->producerIdx != circularQ->consumerIdx)
1526     {
1527       SA_DBG1(("siReadControllerStatus:  saRoot->sysIntsActive %X\n",saRoot->sysIntsActive));
1528       SA_DBG1(("siReadControllerStatus: PI 0x%03x CI 0x%03x\n",circularQ->producerIdx, circularQ->consumerIdx));
1529 
1530       SA_DBG1(("siReadControllerStatus:IN MSGU_READ_ODMR %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODMR, V_Outbound_Doorbell_Mask_Set_Register )));
1531       SA_DBG1(("siReadControllerStatus:MSGU_READ_ODR  %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODR, V_Outbound_Doorbell_Set_Register)));
1532       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Clear_Register, 0xFFFFFFFF );
1533 
1534     }
1535   }
1536 
1537   siTimerAdd(agRoot,SA_FW_TIMER_READS_STATUS_INTERVAL, siReadControllerStatus,Event,pParm  );
1538 
1539   return(to_ret);
1540 }
1541 
1542 #endif /* SA_FW_TIMER_READS_STATUS */
1543 
1544 /******************************************************************************/
1545 /*! \brief Routine to do SPC configuration with default or specified values
1546  *
1547  *  Set up configuration table in LL Layer
1548  *
1549  *  \param agRoot    handles for this instance of SAS/SATA hardware
1550  *  \param mpiConfig MPI Configuration
1551  *  \param swConfig  Pointer to the software configuration
1552  *
1553  *  \return -void-
1554  */
1555 /*******************************************************************************/
1556 GLOBAL bit32 siConfiguration(
1557   agsaRoot_t      *agRoot,
1558   mpiConfig_t     *mpiConfig,
1559   agsaHwConfig_t  *hwConfig,
1560   agsaSwConfig_t  *swConfig
1561   )
1562 {
1563   agsaQueueConfig_t *queueConfig;
1564   bit32             intOption, enable64 = 0;
1565   bit8              i;
1566 
1567 
1568   /* sanity check */
1569   SA_ASSERT( (agNULL != agRoot), "");
1570 
1571   smTraceFuncEnter(hpDBG_VERY_LOUD,"m2");
1572 
1573   si_memset(mpiConfig, 0, sizeof(mpiConfig_t));
1574   SA_DBG1(("siConfiguration: si_memset mpiConfig\n"));
1575 
1576 #if defined(SALLSDK_DEBUG)
1577   sidump_swConfig(swConfig);
1578 #endif
1579   mpiConfig->mainConfig.custset                      = swConfig->FWConfig;
1580 
1581   SA_DBG1(("siConfiguration:custset              %8X  %8X\n",mpiConfig->mainConfig.custset,swConfig->FWConfig));
1582 
1583   if (swConfig->param3 == agNULL)
1584   {
1585     SA_DBG1(("siConfiguration: swConfig->param3 == agNULL\n"));
1586     /* initialize the mpiConfig */
1587     /* We configure the Host main part of configuration table */
1588     mpiConfig->mainConfig.iQNPPD_HPPD_GEvent          = 0;
1589     mpiConfig->mainConfig.outboundHWEventPID0_3       = 0;
1590     mpiConfig->mainConfig.outboundHWEventPID4_7       = 0;
1591     mpiConfig->mainConfig.outboundNCQEventPID0_3      = 0;
1592     mpiConfig->mainConfig.outboundNCQEventPID4_7      = 0;
1593     mpiConfig->mainConfig.outboundTargetITNexusEventPID0_3 = 0;
1594     mpiConfig->mainConfig.outboundTargetITNexusEventPID4_7 = 0;
1595     mpiConfig->mainConfig.outboundTargetSSPEventPID0_3 = 0;
1596     mpiConfig->mainConfig.outboundTargetSSPEventPID4_7 = 0;
1597 
1598     mpiConfig->mainConfig.ioAbortDelay                    = 0;
1599 
1600     mpiConfig->mainConfig.upperEventLogAddress        = 0;
1601     mpiConfig->mainConfig.lowerEventLogAddress        = 0;
1602     mpiConfig->mainConfig.eventLogSize                = MPI_LOGSIZE;
1603     mpiConfig->mainConfig.eventLogOption              = 0;
1604     mpiConfig->mainConfig.upperIOPeventLogAddress     = 0;
1605     mpiConfig->mainConfig.lowerIOPeventLogAddress     = 0;
1606     mpiConfig->mainConfig.IOPeventLogSize             = MPI_LOGSIZE;
1607     mpiConfig->mainConfig.IOPeventLogOption           = 0;
1608     mpiConfig->mainConfig.FatalErrorInterrupt         = 0;
1609 
1610     /* save the default value */
1611     mpiConfig->numInboundQueues = AGSA_MAX_INBOUND_Q;
1612     mpiConfig->numOutboundQueues = AGSA_MAX_OUTBOUND_Q;
1613     mpiConfig->maxNumInboundQueues = AGSA_MAX_INBOUND_Q;
1614     mpiConfig->maxNumOutboundQueues = AGSA_MAX_OUTBOUND_Q;
1615 
1616     /* configure inbound queues */
1617     for ( i = 0; i < AGSA_MAX_INBOUND_Q; i ++ )
1618     {
1619       mpiConfig->inboundQueues[i].numElements   = INBOUND_DEPTH_SIZE;
1620       mpiConfig->inboundQueues[i].elementSize   = IOMB_SIZE64;
1621       mpiConfig->inboundQueues[i].priority      = MPI_QUEUE_NORMAL;
1622     }
1623 
1624     /* configure outbound queues */
1625     for ( i = 0; i < AGSA_MAX_OUTBOUND_Q; i ++ )
1626     {
1627       mpiConfig->outboundQueues[i].numElements        = OUTBOUND_DEPTH_SIZE;
1628       mpiConfig->outboundQueues[i].elementSize        = IOMB_SIZE64;
1629       mpiConfig->outboundQueues[i].interruptVector    = 0;
1630       mpiConfig->outboundQueues[i].interruptDelay     = 0;
1631       mpiConfig->outboundQueues[i].interruptThreshold = 0;
1632       /* always enable OQ interrupt */
1633       mpiConfig->outboundQueues[i].interruptEnable    = 1;
1634     }
1635   }
1636   else
1637   { /* Parm3 is not null  */
1638     queueConfig = (agsaQueueConfig_t *)swConfig->param3;
1639 
1640 #if defined(SALLSDK_DEBUG)
1641     sidump_Q_config( queueConfig );
1642 #endif
1643 
1644     SA_DBG1(("siConfiguration: swConfig->param3 == %p\n",queueConfig));
1645 
1646     if ((queueConfig->numInboundQueues > AGSA_MAX_INBOUND_Q) ||
1647       (queueConfig->numOutboundQueues > AGSA_MAX_OUTBOUND_Q))
1648     {
1649       smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m2");
1650       SA_DBG1(("siConfiguration:AGSA_RC_FAILURE MAX_Q\n"));
1651 
1652       return AGSA_RC_FAILURE;
1653     }
1654 
1655     if ((queueConfig->numInboundQueues  == 0 ||
1656          queueConfig->numOutboundQueues == 0    ))
1657     {
1658       smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "m2");
1659       SA_DBG1(("siConfiguration:AGSA_RC_FAILURE NO_Q\n"));
1660       return AGSA_RC_FAILURE;
1661     }
1662     mpiConfig->mainConfig.eventLogSize = swConfig->sizefEventLog1 * KBYTES;
1663     mpiConfig->mainConfig.eventLogOption  = swConfig->eventLog1Option;
1664     mpiConfig->mainConfig.IOPeventLogSize = swConfig->sizefEventLog2 * KBYTES;
1665     mpiConfig->mainConfig.IOPeventLogOption = swConfig->eventLog2Option;
1666 
1667     if ((queueConfig->numInboundQueues > IQ_NUM_32) || (queueConfig->numOutboundQueues > OQ_NUM_32))
1668     {
1669       enable64 = 1;
1670     }
1671 
1672     if (agNULL == hwConfig)
1673     {
1674       intOption = 0;
1675     }
1676     else
1677     {
1678 
1679 #if defined(SALLSDK_DEBUG)
1680       sidump_hwConfig(hwConfig);
1681 #endif
1682 
1683 
1684       if(smIS_SPCV(agRoot))
1685       {
1686         intOption = 0;
1687       }
1688       else
1689       {
1690         intOption = hwConfig->intReassertionOption & INT_OPTION;
1691       }
1692 
1693     }
1694 
1695     /* Enable SGPIO */
1696     swConfig->sgpioSupportEnable = 1;
1697 
1698     /* set bit for normal priority or high priority path */
1699     /* set fatal error interrupt enable and vector */
1700     /* set Interrupt Reassertion enable and 64 IQ/OQ enable */
1701     mpiConfig->mainConfig.FatalErrorInterrupt =
1702                                  (swConfig->fatalErrorInterruptEnable)                       /* bit 0*/     |
1703          (hwConfig == agNULL ? 0: (hwConfig->hwOption & HW_CFG_PICI_EFFECTIVE_ADDRESS ? (0x1 << SHIFT1): 0))|
1704                                      (swConfig->sgpioSupportEnable                    ? (0x1 << SHIFT2): 0) |
1705     /* compile option SA_ENABLE_POISION_TLP */(SA_PTNFE_POISION_TLP                          << SHIFT3)     |
1706 #ifdef SA_CONFIG_MDFD_REGISTRY
1707                                             (swConfig->disableMDF                     ? (0x1 << SHIFT4): 0) |
1708 #else
1709     /* compile option SA_DISABLE_MDFD       */   (SA_MDFD_MULTI_DATA_FETCH                      << SHIFT4)  |
1710 #endif /*SA_CONFIG_MDFD_REGISTRY*/
1711     /* compile option SA_DISABLE_OB_COAL    */(SA_OUTBOUND_COALESCE                          << SHIFT5)     |
1712     /* compile option SA_ENABLE_ARBTE       */(SA_ARBTE                                      << SHIFT6)     |
1713                                ((swConfig->fatalErrorInterruptVector & FATAL_ERROR_INT_BITS) << SHIFT8)     |
1714                                               (enable64                                      << SHIFT16)    |
1715                                               (intOption                                     << SHIFT17);
1716 
1717 
1718     SA_DBG1(("siConfiguration: swConfig->fatalErrorInterruptEnable  %X\n",swConfig->fatalErrorInterruptEnable));
1719     SA_DBG1(("siConfiguration: swConfig->fatalErrorInterruptVector  %X\n",swConfig->fatalErrorInterruptVector));
1720 
1721 
1722 
1723     /* initialize the mpiConfig */
1724     /* We configure the Host main part of configuration table */
1725     mpiConfig->mainConfig.outboundTargetITNexusEventPID0_3 = 0;
1726     mpiConfig->mainConfig.outboundTargetITNexusEventPID4_7 = 0;
1727     mpiConfig->mainConfig.outboundTargetSSPEventPID0_3 = 0;
1728     mpiConfig->mainConfig.outboundTargetSSPEventPID4_7 = 0;
1729     mpiConfig->mainConfig.ioAbortDelay = 0;
1730     mpiConfig->mainConfig.PortRecoveryTimerPortResetTimer = swConfig->PortRecoveryResetTimer;
1731 
1732     /* get parameter from queueConfig */
1733     mpiConfig->mainConfig.iQNPPD_HPPD_GEvent          = queueConfig->iqNormalPriorityProcessingDepth |
1734                                                         (queueConfig->iqHighPriorityProcessingDepth << SHIFT8) |
1735                                                         (queueConfig->generalEventQueue << SHIFT16) |
1736                                                         (queueConfig->tgtDeviceRemovedEventQueue << SHIFT24);
1737 
1738     mpiConfig->mainConfig.outboundHWEventPID0_3       = queueConfig->sasHwEventQueue[0] |
1739                                                         (queueConfig->sasHwEventQueue[1] << SHIFT8)  |
1740                                                         (queueConfig->sasHwEventQueue[2] << SHIFT16) |
1741                                                         (queueConfig->sasHwEventQueue[3] << SHIFT24);
1742     mpiConfig->mainConfig.outboundHWEventPID4_7       = queueConfig->sasHwEventQueue[4] |
1743                                                         (queueConfig->sasHwEventQueue[5] << SHIFT8)  |
1744                                                         (queueConfig->sasHwEventQueue[6] << SHIFT16) |
1745                                                         (queueConfig->sasHwEventQueue[7] << SHIFT24);
1746     mpiConfig->mainConfig.outboundNCQEventPID0_3      = queueConfig->sataNCQErrorEventQueue[0] |
1747                                                         (queueConfig->sataNCQErrorEventQueue[1] << SHIFT8)  |
1748                                                         (queueConfig->sataNCQErrorEventQueue[2] << SHIFT16) |
1749                                                         (queueConfig->sataNCQErrorEventQueue[3] << SHIFT24);
1750     mpiConfig->mainConfig.outboundNCQEventPID4_7      = queueConfig->sataNCQErrorEventQueue[4] |
1751                                                         (queueConfig->sataNCQErrorEventQueue[5] << SHIFT8)  |
1752                                                         (queueConfig->sataNCQErrorEventQueue[6] << SHIFT16) |
1753                                                         (queueConfig->sataNCQErrorEventQueue[7] << SHIFT24);
1754     /* save it */
1755     mpiConfig->numInboundQueues = queueConfig->numInboundQueues;
1756     mpiConfig->numOutboundQueues = queueConfig->numOutboundQueues;
1757     mpiConfig->queueOption = queueConfig->queueOption;
1758 
1759     SA_DBG2(("siConfiguration: numInboundQueues=%d numOutboundQueues=%d\n",
1760     queueConfig->numInboundQueues,
1761     queueConfig->numOutboundQueues));
1762 
1763     /* configure inbound queues */
1764     /* We configure the size of queue based on swConfig */
1765     for( i = 0; i < queueConfig->numInboundQueues; i ++ )
1766     {
1767       mpiConfig->inboundQueues[i].numElements   = (bit16)queueConfig->inboundQueues[i].elementCount;
1768       mpiConfig->inboundQueues[i].elementSize   = (bit16)queueConfig->inboundQueues[i].elementSize;
1769       mpiConfig->inboundQueues[i].priority      = queueConfig->inboundQueues[i].priority;
1770 
1771       SA_DBG2(("siConfiguration: IBQ%d:elementCount=%d elementSize=%d priority=%d Total Size 0x%X\n",
1772       i,
1773       queueConfig->inboundQueues[i].elementCount,
1774       queueConfig->inboundQueues[i].elementSize,
1775       queueConfig->inboundQueues[i].priority,
1776       queueConfig->inboundQueues[i].elementCount * queueConfig->inboundQueues[i].elementSize ));
1777     }
1778 
1779     /* configura outbound queues */
1780     /* We configure the size of queue based on swConfig */
1781     for( i = 0; i < queueConfig->numOutboundQueues; i ++ )
1782     {
1783       mpiConfig->outboundQueues[i].numElements        = (bit16)queueConfig->outboundQueues[i].elementCount;
1784       mpiConfig->outboundQueues[i].elementSize        = (bit16)queueConfig->outboundQueues[i].elementSize;
1785       mpiConfig->outboundQueues[i].interruptVector    = (bit8)queueConfig->outboundQueues[i].interruptVectorIndex;
1786       mpiConfig->outboundQueues[i].interruptDelay     = (bit16)queueConfig->outboundQueues[i].interruptDelay;
1787       mpiConfig->outboundQueues[i].interruptThreshold = (bit8)queueConfig->outboundQueues[i].interruptCount;
1788       mpiConfig->outboundQueues[i].interruptEnable    = (bit32)queueConfig->outboundQueues[i].interruptEnable;
1789 
1790       SA_DBG2(("siConfiguration: OBQ%d:elementCount=%d elementSize=%d interruptCount=%d interruptEnable=%d\n",
1791       i,
1792       queueConfig->outboundQueues[i].elementCount,
1793       queueConfig->outboundQueues[i].elementSize,
1794       queueConfig->outboundQueues[i].interruptCount,
1795       queueConfig->outboundQueues[i].interruptEnable));
1796     }
1797   }
1798 
1799   SA_DBG1(("siConfiguration:mpiConfig->mainConfig.FatalErrorInterrupt 0x%X\n",mpiConfig->mainConfig.FatalErrorInterrupt));
1800   SA_DBG1(("siConfiguration:swConfig->fatalErrorInterruptVector       0x%X\n",swConfig->fatalErrorInterruptVector));
1801   SA_DBG1(("siConfiguration:enable64                                  0x%X\n",enable64));
1802   SA_DBG1(("siConfiguration:PortRecoveryResetTimer                    0x%X\n",swConfig->PortRecoveryResetTimer));
1803 
1804   smTraceFuncExit(hpDBG_VERY_LOUD, 'c', "m2");
1805 
1806   /* return */
1807   return AGSA_RC_SUCCESS;
1808 }
1809 
1810 #ifdef FW_EVT_LOG_TST
1811 void saLogDump(agsaRoot_t *agRoot,
1812                U32    *eventLogSize,
1813                U32   **eventLogAddress_)
1814 {
1815   agsaLLRoot_t *saRoot =  (agsaLLRoot_t *)(agRoot->sdkData);
1816   //mpiConfig_t  *mpiConfig = &saRoot->mpiConfig;
1817   mpiHostLLConfigDescriptor_t *mpiConfig = &saRoot->mainConfigTable;
1818 
1819   *eventLogAddress_ = (U32*)eventLogAddress;
1820   *eventLogSize = (U32)mpiConfig->eventLogSize;
1821 }
1822 #endif
1823 
1824 /*******************************************************************************/
1825 /** \fn mpiInitialize(agsaRoot *agRoot, mpiMemReq_t* memoryAllocated, mpiConfig_t* config)
1826  *  \brief Initializes the MPI Message Unit
1827  *  \param agRoot           Pointer to a data structure containing LL layer context handles
1828  *  \param memoryAllocated  Data structure that holds the different chunks of memory that are allocated
1829  *  \param config           MPI configuration
1830  *
1831  * This function is called to initialize SPC_HOST_MPI internal data structures and the SPC hardware.
1832  * This function is competed synch->ronously (there is no callback)
1833  *
1834  * Return:
1835  *         AGSA_RC_SUCCESS if initialization succeeded.
1836  *         AGSA_RC_FAILURE if initialization failed.
1837  */
1838 /*******************************************************************************/
1839 GLOBAL bit32 mpiInitialize(agsaRoot_t *agRoot,
1840                            mpiMemReq_t* memoryAllocated,
1841                            mpiConfig_t* config)
1842 {
1843   static spc_configMainDescriptor_t mainCfg;              /* main part of MPI configuration */
1844   static spc_inboundQueueDescriptor_t inQueueCfg;         /* Inbound queue HW configuration structure */
1845   static spc_outboundQueueDescriptor_t outQueueCfg;       /* Outbound queue HW configuration structure */
1846   bit16 qIdx, i, indexoffset;                      /* Queue index */
1847   bit16 mIdx = 0;                                  /* Memory region index */
1848   bit32 MSGUCfgTblDWIdx, GSTLenMPIS;
1849   bit32 MSGUCfgTblBase, ret = AGSA_RC_SUCCESS;
1850   bit32 value, togglevalue;
1851   bit32 saveOffset;
1852   bit32 inboundoffset, outboundoffset;
1853   bit8  pcibar;
1854   bit16 maxinbound = AGSA_MAX_INBOUND_Q;
1855   bit16 maxoutbound = AGSA_MAX_OUTBOUND_Q;
1856   bit32 OB_CIPCIBar;
1857   bit32 IB_PIPCIBar;
1858   bit32 max_wait_time;
1859   bit32 max_wait_count;
1860   bit32 memOffset;
1861   agsaLLRoot_t *saRoot;
1862   mpiICQueue_t *circularIQ = agNULL;
1863   mpiOCQueue_t *circularOQ;
1864 
1865   bit32 mpiUnInitFailed = 0;
1866   bit32 mpiStartToggleFailed = 0;
1867 
1868 
1869 #if defined(SALLSDK_DEBUG)
1870  bit8 phycount = AGSA_MAX_VALID_PHYS;
1871 #endif /* SALLSDK_DEBUG */
1872 
1873   SA_DBG1(("mpiInitialize: Entering\n"));
1874   SA_ASSERT(NULL != agRoot, "agRoot argument cannot be null");
1875   SA_ASSERT(NULL != memoryAllocated, "memoryAllocated argument cannot be null");
1876   SA_ASSERT(NULL != config, "config argument cannot be null");
1877   SA_ASSERT(0 == (sizeof(spc_inboundQueueDescriptor_t) % 4), "spc_inboundQueueDescriptor_t type size has to be divisible by 4");
1878 
1879   saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1880 
1881   si_memset(&mainCfg,0,sizeof(spc_configMainDescriptor_t));
1882   si_memset(&inQueueCfg,0,sizeof(spc_inboundQueueDescriptor_t));
1883   si_memset(&outQueueCfg,0,sizeof(spc_outboundQueueDescriptor_t));
1884 
1885   SA_ASSERT((agNULL !=saRoot ), "");
1886   if(saRoot == agNULL)
1887   {
1888     SA_DBG1(("mpiInitialize: saRoot == agNULL\n"));
1889     return(AGSA_RC_FAILURE);
1890   }
1891   smTraceFuncEnter(hpDBG_VERY_LOUD,"m3");
1892 
1893   /*Shift BAR 4 for SPC HAILEAH*/
1894   if(smIS_SPC(agRoot))
1895   {
1896     if( smIS_HIL(agRoot))
1897     {
1898       if (AGSA_RC_FAILURE == siBar4Shift(agRoot, MBIC_GSM_SM_BASE))
1899       {
1900         SA_DBG1(("mpiInitialize: siBar4Shift FAILED ******************************************\n"));
1901         return AGSA_RC_FAILURE;
1902       }
1903     }
1904   }
1905 
1906   /* Wait for the SPC Configuration Table to be ready */
1907   ret = mpiWaitForConfigTable(agRoot, &mainCfg);
1908   if (AGSA_RC_FAILURE == ret)
1909   {
1910     /* return error if MPI Configuration Table not ready */
1911     SA_DBG1(("mpiInitialize: mpiWaitForConfigTable FAILED ******************************************\n"));
1912     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m3");
1913     return ret;
1914   }
1915 
1916   /* read scratch pad0 to get PCI BAR and offset of configuration table */
1917   MSGUCfgTblBase = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
1918   /* get PCI BAR */
1919   MSGUCfgTblBase = (MSGUCfgTblBase & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
1920   /* get pci Bar index */
1921   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, MSGUCfgTblBase);
1922 
1923   SA_DBG1(("mpiInitialize: MSGUCfgTblBase = 0x%x\n", MSGUCfgTblBase));
1924 #if defined(SALLSDK_DEBUG)
1925   /* get Phy count from configuration table */
1926   phycount = (bit8)((mainCfg.ContrlCapFlag & PHY_COUNT_BITS) >> SHIFT19);
1927 
1928   SA_DBG1(("mpiInitialize: Number of PHYs = 0x%x\n", phycount));
1929 
1930   smTrace(hpDBG_VERY_LOUD,"70",phycount);
1931   /* TP:70 phycount */
1932 #endif /* SALLSDK_DEBUG */
1933 
1934   /* get High Priority IQ support flag */
1935   if (mainCfg.ContrlCapFlag & HP_SUPPORT_BIT)
1936   {
1937     SA_DBG1(("mpiInitialize: High Priority IQ support from SPC\n"));
1938   }
1939   /* get Interrupt Coalescing Support flag */
1940   if (mainCfg.ContrlCapFlag & INT_COL_BIT)
1941   {
1942     SA_DBG1(("mpiInitialize: Interrupt Coalescing support from SPC\n"));
1943   }
1944 
1945   /* get configured the number of inbound/outbound queues */
1946   if (memoryAllocated->count == TOTAL_MPI_MEM_CHUNKS)
1947   {
1948     config->maxNumInboundQueues  = AGSA_MAX_INBOUND_Q;
1949     config->maxNumOutboundQueues = AGSA_MAX_OUTBOUND_Q;
1950   }
1951   else
1952   {
1953     config->maxNumInboundQueues  = config->numInboundQueues;
1954     config->maxNumOutboundQueues = config->numOutboundQueues;
1955     maxinbound  = config->numInboundQueues;
1956     maxoutbound = config->numOutboundQueues;
1957   }
1958 
1959   SA_DBG1(("mpiInitialize: Number of IQ %d\n", maxinbound));
1960   SA_DBG1(("mpiInitialize: Number of OQ %d\n", maxoutbound));
1961 
1962   /* get inbound queue offset */
1963   inboundoffset = mainCfg.inboundQueueOffset;
1964   /* get outbound queue offset */
1965   outboundoffset = mainCfg.outboundQueueOffset;
1966 
1967   if(smIS_SPCV(agRoot))
1968   {
1969     SA_DBG2(("mpiInitialize: Offset of IQ %d\n", (inboundoffset & 0xFF000000) >> 24));
1970     SA_DBG2(("mpiInitialize: Offset of OQ %d\n", (outboundoffset & 0xFF000000) >> 24));
1971     inboundoffset &= 0x00FFFFFF;
1972     outboundoffset &= 0x00FFFFFF;
1973   }
1974   /* get offset of the configuration table */
1975   MSGUCfgTblDWIdx = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
1976   MSGUCfgTblDWIdx = MSGUCfgTblDWIdx & SCRATCH_PAD0_OFFSET_MASK;
1977 
1978   saveOffset = MSGUCfgTblDWIdx;
1979 
1980   /* Checks if the configuration memory region size is the same as the mpiConfigMain */
1981   if(memoryAllocated->region[mIdx].totalLength != sizeof(bit8) * config->mainConfig.eventLogSize)
1982   {
1983     SA_DBG1(("ERROR: The memory region [%d] 0x%X != 0x%X does not have the size of the MSGU event log ******************************************\n",
1984       mIdx,memoryAllocated->region[mIdx].totalLength,config->mainConfig.eventLogSize));
1985     smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "m3");
1986     return AGSA_RC_FAILURE;
1987   }
1988 
1989   mainCfg.iQNPPD_HPPD_GEvent               = config->mainConfig.iQNPPD_HPPD_GEvent;
1990 
1991   if(smIS_SPCV(agRoot))
1992   {
1993     mainCfg.outboundHWEventPID0_3            = 0;
1994     mainCfg.outboundHWEventPID4_7            = 0;
1995     mainCfg.outboundNCQEventPID0_3           = 0;
1996     mainCfg.outboundNCQEventPID4_7           = 0;
1997     mainCfg.outboundTargetITNexusEventPID0_3 = 0;
1998     mainCfg.outboundTargetITNexusEventPID4_7 = 0;
1999     mainCfg.outboundTargetSSPEventPID0_3     = 0;
2000     mainCfg.outboundTargetSSPEventPID4_7     = 0;
2001     mainCfg.ioAbortDelay                     = 0;  /* SPCV reserved */
2002     mainCfg.custset                          = 0;
2003     mainCfg.portRecoveryResetTimer           = config->mainConfig.PortRecoveryTimerPortResetTimer;
2004     SA_DBG1(("mpiInitialize:custset V                %8X\n",mainCfg.custset));
2005     SA_DBG1(("mpiInitialize:portRecoveryResetTimer V %8X\n",mainCfg.portRecoveryResetTimer));
2006 
2007     mainCfg.interruptReassertionDelay        = saRoot->hwConfig.intReassertionOption;
2008     SA_DBG1(("mpiInitialize:interruptReassertionDelay V %8X\n", mainCfg.interruptReassertionDelay));
2009 
2010 
2011   }
2012   else
2013   {
2014     mainCfg.outboundHWEventPID0_3            = config->mainConfig.outboundHWEventPID0_3;
2015     mainCfg.outboundHWEventPID4_7            = config->mainConfig.outboundHWEventPID4_7;
2016     mainCfg.outboundNCQEventPID0_3           = config->mainConfig.outboundNCQEventPID0_3;
2017     mainCfg.outboundNCQEventPID4_7           = config->mainConfig.outboundNCQEventPID4_7;
2018     mainCfg.outboundTargetITNexusEventPID0_3 = config->mainConfig.outboundTargetITNexusEventPID0_3;
2019     mainCfg.outboundTargetITNexusEventPID4_7 = config->mainConfig.outboundTargetITNexusEventPID4_7;
2020     mainCfg.outboundTargetSSPEventPID0_3     = config->mainConfig.outboundTargetSSPEventPID0_3;
2021     mainCfg.outboundTargetSSPEventPID4_7     = config->mainConfig.outboundTargetSSPEventPID4_7;
2022     mainCfg.ioAbortDelay                     = config->mainConfig.ioAbortDelay;
2023     mainCfg.custset                          = config->mainConfig.custset;
2024 
2025     SA_DBG1(("mpiInitialize:custset spc     %8X\n",mainCfg.custset));
2026 
2027   }
2028 #ifdef FW_EVT_LOG_TST
2029   eventLogAddress = memoryAllocated->region[mIdx].virtPtr;
2030 #endif
2031   mainCfg.upperEventLogAddress             = memoryAllocated->region[mIdx].physAddrUpper;
2032   mainCfg.lowerEventLogAddress             = memoryAllocated->region[mIdx].physAddrLower;
2033   mainCfg.eventLogSize                     = config->mainConfig.eventLogSize;
2034   mainCfg.eventLogOption                   = config->mainConfig.eventLogOption;
2035 
2036   mIdx++;
2037 
2038   /* Checks if the configuration memory region size is the same as the mpiConfigMain */
2039   if(memoryAllocated->region[mIdx].totalLength != sizeof(bit8) * config->mainConfig.IOPeventLogSize)
2040   {
2041     SA_DBG1(("ERROR: The memory region does not have the size of the IOP event log\n"));
2042     smTraceFuncExit(hpDBG_VERY_LOUD, 'c', "m3");
2043     return AGSA_RC_FAILURE;
2044   }
2045 
2046   mainCfg.upperIOPeventLogAddress     = memoryAllocated->region[mIdx].physAddrUpper;
2047   mainCfg.lowerIOPeventLogAddress     = memoryAllocated->region[mIdx].physAddrLower;
2048   mainCfg.IOPeventLogSize             = config->mainConfig.IOPeventLogSize;
2049   mainCfg.IOPeventLogOption           = config->mainConfig.IOPeventLogOption;
2050   mainCfg.FatalErrorInterrupt         = config->mainConfig.FatalErrorInterrupt;
2051 
2052   SA_DBG1(("mpiInitialize: iQNPPD_HPPD_GEvent 0x%x\n", mainCfg.iQNPPD_HPPD_GEvent));
2053   if(smIS_SPCV(agRoot))
2054   {
2055   }
2056   else
2057   {
2058     SA_DBG3(("mpiInitialize: outboundHWEventPID0_3 0x%x\n", mainCfg.outboundHWEventPID0_3));
2059     SA_DBG3(("mpiInitialize: outboundHWEventPID4_7 0x%x\n", mainCfg.outboundHWEventPID4_7));
2060     SA_DBG3(("mpiInitialize: outboundNCQEventPID0_3 0x%x\n", mainCfg.outboundNCQEventPID0_3));
2061     SA_DBG3(("mpiInitialize: outboundNCQEventPID4_7 0x%x\n", mainCfg.outboundNCQEventPID4_7));
2062     SA_DBG3(("mpiInitialize: outboundTargetITNexusEventPID0_3 0x%x\n", mainCfg.outboundTargetITNexusEventPID0_3));
2063     SA_DBG3(("mpiInitialize: outboundTargetITNexusEventPID4_7 0x%x\n", mainCfg.outboundTargetITNexusEventPID4_7));
2064     SA_DBG3(("mpiInitialize: outboundTargetSSPEventPID0_3 0x%x\n", mainCfg.outboundTargetSSPEventPID0_3));
2065     SA_DBG3(("mpiInitialize: outboundTargetSSPEventPID4_7 0x%x\n", mainCfg.outboundTargetSSPEventPID4_7));
2066   }
2067 
2068   SA_DBG3(("mpiInitialize: upperEventLogAddress 0x%x\n", mainCfg.upperEventLogAddress));
2069   SA_DBG3(("mpiInitialize: lowerEventLogAddress 0x%x\n", mainCfg.lowerEventLogAddress));
2070   SA_DBG3(("mpiInitialize: eventLogSize 0x%x\n", mainCfg.eventLogSize));
2071   SA_DBG3(("mpiInitialize: eventLogOption 0x%x\n", mainCfg.eventLogOption));
2072 #ifdef FW_EVT_LOG_TST
2073   SA_DBG3(("mpiInitialize: eventLogAddress 0x%p\n", eventLogAddress));
2074 #endif
2075   SA_DBG3(("mpiInitialize: upperIOPLogAddress 0x%x\n", mainCfg.upperIOPeventLogAddress));
2076   SA_DBG3(("mpiInitialize: lowerIOPLogAddress 0x%x\n", mainCfg.lowerIOPeventLogAddress));
2077   SA_DBG3(("mpiInitialize: IOPeventLogSize 0x%x\n", mainCfg.IOPeventLogSize));
2078   SA_DBG3(("mpiInitialize: IOPeventLogOption 0x%x\n", mainCfg.IOPeventLogOption));
2079   SA_DBG3(("mpiInitialize: FatalErrorInterrupt 0x%x\n", mainCfg.FatalErrorInterrupt));
2080   SA_DBG3(("mpiInitialize: HDAModeFlags 0x%x\n", mainCfg.HDAModeFlags));
2081   SA_DBG3(("mpiInitialize: analogSetupTblOffset 0x%08x\n", mainCfg.analogSetupTblOffset));
2082 
2083   saRoot->mainConfigTable.iQNPPD_HPPD_GEvent               = mainCfg.iQNPPD_HPPD_GEvent;
2084 
2085   if(smIS_SPCV(agRoot))
2086   {
2087   /* SPCV - reserved fields */
2088     saRoot->mainConfigTable.outboundHWEventPID0_3            = 0;
2089     saRoot->mainConfigTable.outboundHWEventPID4_7            = 0;
2090     saRoot->mainConfigTable.outboundNCQEventPID0_3           = 0;
2091     saRoot->mainConfigTable.outboundNCQEventPID4_7           = 0;
2092     saRoot->mainConfigTable.outboundTargetITNexusEventPID0_3 = 0;
2093     saRoot->mainConfigTable.outboundTargetITNexusEventPID4_7 = 0;
2094     saRoot->mainConfigTable.outboundTargetSSPEventPID0_3     = 0;
2095     saRoot->mainConfigTable.outboundTargetSSPEventPID4_7     = 0;
2096     saRoot->mainConfigTable.ioAbortDelay                     = 0;
2097     saRoot->mainConfigTable.custset                          = 0;
2098 
2099   }
2100   else
2101   {
2102     saRoot->mainConfigTable.outboundHWEventPID0_3            = mainCfg.outboundHWEventPID0_3;
2103     saRoot->mainConfigTable.outboundHWEventPID4_7            = mainCfg.outboundHWEventPID4_7;
2104     saRoot->mainConfigTable.outboundNCQEventPID0_3           = mainCfg.outboundNCQEventPID0_3;
2105     saRoot->mainConfigTable.outboundNCQEventPID4_7           = mainCfg.outboundNCQEventPID4_7;
2106     saRoot->mainConfigTable.outboundTargetITNexusEventPID0_3 = mainCfg.outboundTargetITNexusEventPID0_3;
2107     saRoot->mainConfigTable.outboundTargetITNexusEventPID4_7 = mainCfg.outboundTargetITNexusEventPID4_7;
2108     saRoot->mainConfigTable.outboundTargetSSPEventPID0_3     = mainCfg.outboundTargetSSPEventPID0_3;
2109     saRoot->mainConfigTable.outboundTargetSSPEventPID4_7     = mainCfg.outboundTargetSSPEventPID4_7;
2110     saRoot->mainConfigTable.ioAbortDelay                     = mainCfg.ioAbortDelay;
2111     saRoot->mainConfigTable.custset                          = mainCfg.custset;
2112 
2113   }
2114 
2115   saRoot->mainConfigTable.upperEventLogAddress             = mainCfg.upperEventLogAddress;
2116   saRoot->mainConfigTable.lowerEventLogAddress             = mainCfg.lowerEventLogAddress;
2117   saRoot->mainConfigTable.eventLogSize                     = mainCfg.eventLogSize;
2118   saRoot->mainConfigTable.eventLogOption                   = mainCfg.eventLogOption;
2119   saRoot->mainConfigTable.upperIOPeventLogAddress          = mainCfg.upperIOPeventLogAddress;
2120   saRoot->mainConfigTable.lowerIOPeventLogAddress          = mainCfg.lowerIOPeventLogAddress;
2121   saRoot->mainConfigTable.IOPeventLogSize                  = mainCfg.IOPeventLogSize;
2122   saRoot->mainConfigTable.IOPeventLogOption                = mainCfg.IOPeventLogOption;
2123   saRoot->mainConfigTable.FatalErrorInterrupt              = mainCfg.FatalErrorInterrupt;
2124 
2125 
2126   if(smIS_SPCV(agRoot))
2127   {
2128     ;/* SPCV - reserved fields */
2129   }
2130   else
2131   {
2132     saRoot->mainConfigTable.HDAModeFlags                     = mainCfg.HDAModeFlags;
2133   }
2134 
2135   saRoot->mainConfigTable.analogSetupTblOffset             = mainCfg.analogSetupTblOffset;
2136 
2137   smTrace(hpDBG_VERY_LOUD,"71",mIdx);
2138   /* TP:71 71 mIdx  */
2139 
2140 
2141 
2142   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IQNPPD_HPPD_OFFSET),
2143                      mainCfg.iQNPPD_HPPD_GEvent);
2144 
2145   SA_DBG3(("mpiInitialize: Offset 0x%08x mainCfg.iQNPPD_HPPD_GEvent 0x%x\n", (bit32)(MSGUCfgTblDWIdx + MAIN_IQNPPD_HPPD_OFFSET), mainCfg.iQNPPD_HPPD_GEvent));
2146 
2147   if(smIS_SPC6V(agRoot))
2148   {
2149     if(smIsCfgVREV_B(agRoot))
2150     {
2151       ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IO_ABORT_DELAY),
2152                      MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE);
2153 
2154       SA_DBG1(("mpiInitialize:SPCV - MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE\n" ));
2155     }
2156     if(smIsCfgVREV_C(agRoot))
2157     {
2158       SA_DBG1(("mpiInitialize:SPCV - END_TO_END_CRC On\n" ));
2159     }
2160     SA_DBG3(("mpiInitialize:SPCV - rest reserved field  \n" ));
2161     ;/* SPCV - reserved field */
2162   }
2163   else if(smIS_SPC(agRoot))
2164   {
2165     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_OB_HW_EVENT_PID03_OFFSET),
2166                        mainCfg.outboundHWEventPID0_3);
2167     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_OB_HW_EVENT_PID47_OFFSET),
2168                        mainCfg.outboundHWEventPID4_7);
2169     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_OB_NCQ_EVENT_PID03_OFFSET),
2170                        mainCfg.outboundNCQEventPID0_3);
2171     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_OB_NCQ_EVENT_PID47_OFFSET),
2172                        mainCfg.outboundNCQEventPID4_7);
2173     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_TITNX_EVENT_PID03_OFFSET),
2174                        mainCfg.outboundTargetITNexusEventPID0_3);
2175     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_TITNX_EVENT_PID47_OFFSET),
2176                        mainCfg.outboundTargetITNexusEventPID4_7);
2177     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_OB_SSP_EVENT_PID03_OFFSET),
2178                        mainCfg.outboundTargetSSPEventPID0_3);
2179     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_OB_SSP_EVENT_PID47_OFFSET),
2180                        mainCfg.outboundTargetSSPEventPID4_7);
2181     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_CUSTOMER_SETTING),
2182                        mainCfg.custset);
2183   }else
2184   {
2185     if(smIsCfgVREV_A(agRoot))
2186     {
2187        ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IO_ABORT_DELAY),
2188                      MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE);  /* */
2189        SA_DBG1(("mpiInitialize:SPCV12G - offset MAIN_IO_ABORT_DELAY 0x%x value MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE 0x%x\n",MAIN_IO_ABORT_DELAY ,MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE));
2190        SA_DBG1(("mpiInitialize:SPCV12G - END_TO_END_CRC OFF for rev A %d\n",smIsCfgVREV_A(agRoot) ));
2191     }
2192     else if(smIsCfgVREV_B(agRoot))
2193     {
2194        SA_DBG1(("mpiInitialize:SPCV12G - END_TO_END_CRC ON rev B %d ****************************\n",smIsCfgVREV_B(agRoot) ));
2195        /*ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IO_ABORT_DELAY),
2196                      MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE);
2197        */
2198     }
2199     else if(smIsCfgVREV_C(agRoot))
2200     {
2201        SA_DBG1(("mpiInitialize:SPCV12G - END_TO_END_CRC on rev C %d\n",smIsCfgVREV_C(agRoot) ));
2202     }
2203     else
2204     {
2205        ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IO_ABORT_DELAY),
2206                      MAIN_IO_ABORT_DELAY_END_TO_END_CRC_DISABLE);
2207        SA_DBG1(("mpiInitialize:SPCV12G - END_TO_END_CRC Off unknown rev 0x%x\n", ossaHwRegReadConfig32((agRoot), 8 )));
2208     }
2209   }
2210 
2211   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_ADDR_HI),       mainCfg.upperEventLogAddress);
2212   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_ADDR_LO),       mainCfg.lowerEventLogAddress);
2213   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_BUFF_SIZE),     mainCfg.eventLogSize);
2214   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_OPTION),        mainCfg.eventLogOption);
2215   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_ADDR_HI),   mainCfg.upperIOPeventLogAddress);
2216   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_ADDR_LO),   mainCfg.lowerIOPeventLogAddress);
2217   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_BUFF_SIZE), mainCfg.IOPeventLogSize);
2218   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_OPTION),    mainCfg.IOPeventLogOption);
2219   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_INTERRUPT),   mainCfg.FatalErrorInterrupt);
2220   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_PRECTD_PRESETD),          mainCfg.portRecoveryResetTimer);
2221 
2222   SA_DBG3(("mpiInitialize: Offset 0x%08x upperEventLogAddress    0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_ADDR_HI), mainCfg.upperEventLogAddress ));
2223   SA_DBG3(("mpiInitialize: Offset 0x%08x lowerEventLogAddress    0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_ADDR_LO), mainCfg.lowerEventLogAddress ));
2224   SA_DBG3(("mpiInitialize: Offset 0x%08x eventLogSize            0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_BUFF_SIZE), mainCfg.eventLogSize ));
2225   SA_DBG3(("mpiInitialize: Offset 0x%08x eventLogOption          0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_OPTION), mainCfg.eventLogOption ));
2226   SA_DBG3(("mpiInitialize: Offset 0x%08x upperIOPeventLogAddress 0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_ADDR_HI), mainCfg.upperIOPeventLogAddress ));
2227   SA_DBG3(("mpiInitialize: Offset 0x%08x lowerIOPeventLogAddress 0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_ADDR_LO), mainCfg.lowerIOPeventLogAddress ));
2228   SA_DBG3(("mpiInitialize: Offset 0x%08x IOPeventLogSize         0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_BUFF_SIZE), mainCfg.IOPeventLogSize ));
2229   SA_DBG3(("mpiInitialize: Offset 0x%08x IOPeventLogOption       0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_OPTION), mainCfg.IOPeventLogOption ));
2230   SA_DBG3(("mpiInitialize: Offset 0x%08x FatalErrorInterrupt     0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_INTERRUPT), mainCfg.FatalErrorInterrupt ));
2231   SA_DBG3(("mpiInitialize: Offset 0x%08x PortRecoveryResetTimer  0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_PRECTD_PRESETD), mainCfg.portRecoveryResetTimer ));
2232 
2233   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IRAD_RESERVED),           mainCfg.interruptReassertionDelay);
2234   SA_DBG3(("mpiInitialize: Offset 0x%08x InterruptReassertionDelay 0x%x\n",(bit32)(MSGUCfgTblDWIdx + MAIN_IRAD_RESERVED), mainCfg.interruptReassertionDelay ));
2235 
2236   mIdx++;
2237 
2238   /* skip the ci and pi memory region */
2239   mIdx++;
2240   mIdx++;
2241 
2242   smTrace(hpDBG_VERY_LOUD,"72",mIdx);
2243   /* TP:72 mIdx  */
2244   smTrace(hpDBG_VERY_LOUD,"Bc",maxinbound);
2245   /* TP:Bc  maxinbound  */
2246   smTrace(hpDBG_VERY_LOUD,"Bd",pcibar);
2247   /* TP:Bd pcibar   */
2248 
2249   /* index offset */
2250   indexoffset = 0;
2251   memOffset   = 0;
2252 
2253   /* Memory regions for the inbound queues */
2254   for(qIdx = 0; qIdx < maxinbound; qIdx++)
2255   {
2256     /* point back to the begin then plus offset to next queue */
2257     smTrace(hpDBG_VERY_LOUD,"Bd",pcibar);
2258     /* TP:Bd pcibar   */
2259     MSGUCfgTblDWIdx = saveOffset;
2260     MSGUCfgTblDWIdx += inboundoffset;
2261     MSGUCfgTblDWIdx += (sizeof(spc_inboundQueueDescriptor_t) * qIdx);
2262     SA_DBG1(("mpiInitialize: A saveOffset 0x%x MSGUCfgTblDWIdx 0x%x\n",saveOffset ,MSGUCfgTblDWIdx));
2263 
2264     /* if the MPI configuration says that this queue is disabled ... */
2265     if(0 == config->inboundQueues[qIdx].numElements)
2266     {
2267       /* ... Clears the configuration table for this queue */
2268 
2269       inQueueCfg.elementPriSizeCount= 0;
2270       inQueueCfg.upperBaseAddress = 0;
2271       inQueueCfg.lowerBaseAddress = 0;
2272       inQueueCfg.ciUpperBaseAddress = 0;
2273       inQueueCfg.ciLowerBaseAddress = 0;
2274       /* skip inQueueCfg.PIPCIBar (PM8000 write access) */
2275       /* skip inQueueCfg.PIOffset (PM8000 write access) */
2276 
2277       /* Update the inbound configuration table in SPC GSM */
2278       mpiUpdateIBQueueCfgTable(agRoot, &inQueueCfg, MSGUCfgTblDWIdx, pcibar);
2279     }
2280 
2281     /* If the queue is enabled, then ... */
2282     else
2283     {
2284       bit32 memSize = config->inboundQueues[qIdx].numElements * config->inboundQueues[qIdx].elementSize;
2285       bit32 remainder = memSize & 127;
2286 
2287       /* Calculate the size of this queue padded to 128 bytes */
2288       if (remainder > 0)
2289       {
2290         memSize += (128 - remainder);
2291       }
2292 
2293       /* ... first checks that the memory region has the right size */
2294       if( (memoryAllocated->region[mIdx].totalLength - memOffset < memSize) ||
2295           (NULL == memoryAllocated->region[mIdx].virtPtr) ||
2296           (0 == memoryAllocated->region[mIdx].totalLength))
2297       {
2298         SA_DBG1(("mpiInitialize: ERROR The memory region does not have the right size for this inbound queue"));
2299         smTraceFuncExit(hpDBG_VERY_LOUD, 'd', "m3");
2300         return AGSA_RC_FAILURE;
2301       }
2302       else
2303       {
2304         /* Then, using the MPI configuration argument, initializes the corresponding element on the saRoot */
2305         saRoot->inboundQueue[qIdx].numElements  = config->inboundQueues[qIdx].numElements;
2306         saRoot->inboundQueue[qIdx].elementSize  = config->inboundQueues[qIdx].elementSize;
2307         saRoot->inboundQueue[qIdx].priority     = config->inboundQueues[qIdx].priority;
2308         si_memcpy(&saRoot->inboundQueue[qIdx].memoryRegion, &memoryAllocated->region[mIdx], sizeof(mpiMem_t));
2309         saRoot->inboundQueue[qIdx].memoryRegion.virtPtr =
2310           (bit8 *)saRoot->inboundQueue[qIdx].memoryRegion.virtPtr + memOffset;
2311         saRoot->inboundQueue[qIdx].memoryRegion.physAddrLower += memOffset;
2312         saRoot->inboundQueue[qIdx].memoryRegion.elementSize = memSize;
2313         saRoot->inboundQueue[qIdx].memoryRegion.totalLength = memSize;
2314         saRoot->inboundQueue[qIdx].memoryRegion.numElements = 1;
2315 
2316         /* Initialize the local copy of PIs, CIs */
2317         SA_DBG1(("mpiInitialize: queue %d PI CI zero\n",qIdx));
2318         saRoot->inboundQueue[qIdx].producerIdx = 0;
2319         saRoot->inboundQueue[qIdx].consumerIdx = 0;
2320         saRoot->inboundQueue[qIdx].agRoot = agRoot;
2321 
2322         /* MPI memory region for inbound CIs are 2 */
2323         saRoot->inboundQueue[qIdx].ciPointer = (((bit8 *)(memoryAllocated->region[MPI_CI_INDEX].virtPtr)) + qIdx * 4);
2324         /* ... and in the local structure we will use to copy to the HW configuration table */
2325 
2326         /* CI base address */
2327         inQueueCfg.elementPriSizeCount= config->inboundQueues[qIdx].numElements |
2328                                         (config->inboundQueues[qIdx].elementSize << SHIFT16) |
2329                                         (config->inboundQueues[qIdx].priority << SHIFT30);
2330         inQueueCfg.upperBaseAddress   = saRoot->inboundQueue[qIdx].memoryRegion.physAddrUpper;
2331         inQueueCfg.lowerBaseAddress   = saRoot->inboundQueue[qIdx].memoryRegion.physAddrLower;
2332         inQueueCfg.ciUpperBaseAddress = memoryAllocated->region[MPI_CI_INDEX].physAddrUpper;
2333         inQueueCfg.ciLowerBaseAddress = memoryAllocated->region[MPI_CI_INDEX].physAddrLower + qIdx * 4;
2334 
2335         /* write the configured data of inbound queue to SPC GSM */
2336         mpiUpdateIBQueueCfgTable(agRoot, &inQueueCfg, MSGUCfgTblDWIdx, pcibar);
2337         /* get inbound PI PCI Bar and Offset */
2338         /* get the PI PCI Bar offset and convert it to logical BAR */
2339         IB_PIPCIBar = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + IB_PIPCI_BAR));
2340         saRoot->inboundQueue[qIdx].PIPCIBar     = mpiGetPCIBarIndex(agRoot, IB_PIPCIBar);
2341         saRoot->inboundQueue[qIdx].PIPCIOffset  = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + IB_PIPCI_BAR_OFFSET));
2342         saRoot->inboundQueue[qIdx].qNumber      = qIdx;
2343 
2344         memOffset += memSize;
2345 
2346         if ((0 == ((qIdx + 1) % MAX_QUEUE_EACH_MEM)) ||
2347             (qIdx == (maxinbound - 1)))
2348         {
2349           mIdx++;
2350           indexoffset += MAX_QUEUE_EACH_MEM;
2351           memOffset = 0;
2352         }
2353 
2354       } /* else for memeory ok */
2355     } /* queue enable */
2356   } /* loop for inbound queue */
2357 
2358   smTrace(hpDBG_VERY_LOUD,"73",0);
2359   /* TP:73  outbound queues  */
2360 
2361   /* index offset */
2362   indexoffset = 0;
2363   memOffset = 0;
2364   /* Let's process the memory regions for the outbound queues */
2365   for(qIdx = 0; qIdx < maxoutbound; qIdx++)
2366   {
2367     /* point back to the begin then plus offset to next queue */
2368     MSGUCfgTblDWIdx  = saveOffset;
2369     MSGUCfgTblDWIdx += outboundoffset;
2370     MSGUCfgTblDWIdx += (sizeof(spc_outboundQueueDescriptor_t) * qIdx);
2371 
2372     /* if the MPI configuration says that this queue is disabled ... */
2373     if(0 == config->outboundQueues[qIdx].numElements)
2374     {
2375       /* ... Clears the configuration table for this queue */
2376       outQueueCfg.upperBaseAddress   = 0;
2377       outQueueCfg.lowerBaseAddress   = 0;
2378       outQueueCfg.piUpperBaseAddress = 0;
2379       outQueueCfg.piLowerBaseAddress = 0;
2380       /* skip outQueueCfg.CIPCIBar = 0; read access only */
2381       /* skip outQueueCfg.CIOffset = 0; read access only */
2382       outQueueCfg.elementSizeCount     = 0;
2383       outQueueCfg.interruptVecCntDelay = 0;
2384 
2385       /* Updated the configuration table in SPC GSM */
2386       mpiUpdateOBQueueCfgTable(agRoot, &outQueueCfg, MSGUCfgTblDWIdx, pcibar);
2387     }
2388 
2389     /* If the outbound queue is enabled, then ... */
2390     else
2391     {
2392       bit32 memSize = config->outboundQueues[qIdx].numElements * config->outboundQueues[qIdx].elementSize;
2393       bit32 remainder = memSize & 127;
2394 
2395       /* Calculate the size of this queue padded to 128 bytes */
2396       if (remainder > 0)
2397       {
2398           memSize += (128 - remainder);
2399       }
2400 
2401       /* ... first checks that the memory region has the right size */
2402       if((memoryAllocated->region[mIdx].totalLength - memOffset < memSize) ||
2403          (NULL == memoryAllocated->region[mIdx].virtPtr) ||
2404          (0 == memoryAllocated->region[mIdx].totalLength))
2405       {
2406         SA_DBG1(("ERROR: The memory region does not have the right size for this outbound queue"));
2407         smTraceFuncExit(hpDBG_VERY_LOUD, 'e', "m3");
2408         return AGSA_RC_FAILURE;
2409       }
2410       else
2411       {
2412         /* Then, using the MPI configuration argument, initializes the corresponding element on the MPI context ... */
2413         saRoot->outboundQueue[qIdx].numElements  = config->outboundQueues[qIdx].numElements;
2414         saRoot->outboundQueue[qIdx].elementSize  = config->outboundQueues[qIdx].elementSize;
2415         si_memcpy(&saRoot->outboundQueue[qIdx].memoryRegion, &memoryAllocated->region[mIdx], sizeof(mpiMem_t));
2416         saRoot->outboundQueue[qIdx].memoryRegion.virtPtr =
2417             (bit8 *)saRoot->outboundQueue[qIdx].memoryRegion.virtPtr + memOffset;
2418         saRoot->outboundQueue[qIdx].memoryRegion.physAddrLower += memOffset;
2419         saRoot->outboundQueue[qIdx].memoryRegion.elementSize = memSize;
2420         saRoot->outboundQueue[qIdx].memoryRegion.totalLength = memSize;
2421         saRoot->outboundQueue[qIdx].memoryRegion.numElements = 1;
2422         saRoot->outboundQueue[qIdx].producerIdx = 0;
2423         saRoot->outboundQueue[qIdx].consumerIdx = 0;
2424         saRoot->outboundQueue[qIdx].agRoot = agRoot;
2425 
2426         /* MPI memory region for outbound PIs are 3 */
2427         saRoot->outboundQueue[qIdx].piPointer = (((bit8 *)(memoryAllocated->region[MPI_CI_INDEX + 1].virtPtr))+ qIdx * 4);
2428         /* ... and in the local structure we will use to copy to the HW configuration table */
2429         outQueueCfg.upperBaseAddress = saRoot->outboundQueue[qIdx].memoryRegion.physAddrUpper;
2430         outQueueCfg.lowerBaseAddress = saRoot->outboundQueue[qIdx].memoryRegion.physAddrLower;
2431 
2432         /* PI base address */
2433         outQueueCfg.piUpperBaseAddress = memoryAllocated->region[MPI_CI_INDEX + 1].physAddrUpper;
2434         outQueueCfg.piLowerBaseAddress = memoryAllocated->region[MPI_CI_INDEX + 1].physAddrLower + qIdx * 4;
2435         outQueueCfg.elementSizeCount = config->outboundQueues[qIdx].numElements |
2436                                        (config->outboundQueues[qIdx].elementSize << SHIFT16);
2437 
2438         /* enable/disable interrupt - use saSystemInterruptsActive() API */
2439         /* instead of ossaHwRegWrite(agRoot, MSGU_ODMR, 0); */
2440         /* Outbound Doorbell Auto disable */
2441         /* LL does not use ossaHwRegWriteExt(agRoot, PCIBAR1, SPC_ODAR, 0xffffffff); */
2442         if (config->outboundQueues[qIdx].interruptEnable)
2443         {
2444           /* enable interrupt flag bit30 of outbound table */
2445           outQueueCfg.elementSizeCount |= OB_PROPERTY_INT_ENABLE;
2446         }
2447         if(smIS_SPCV(agRoot))
2448         {
2449           outQueueCfg.interruptVecCntDelay = ((config->outboundQueues[qIdx].interruptVector    & INT_VEC_BITS  ) << SHIFT24);
2450         }
2451         else
2452         {
2453           outQueueCfg.interruptVecCntDelay =  (config->outboundQueues[qIdx].interruptDelay     & INT_DELAY_BITS)             |
2454                                              ((config->outboundQueues[qIdx].interruptThreshold & INT_THR_BITS  ) << SHIFT16) |
2455                                              ((config->outboundQueues[qIdx].interruptVector    & INT_VEC_BITS  ) << SHIFT24);
2456         }
2457 
2458         /* create a VectorIndex Bit Map */
2459         if (qIdx < OQ_NUM_32)
2460         {
2461           saRoot->interruptVecIndexBitMap[config->outboundQueues[qIdx].interruptVector] |= (1 << qIdx);
2462           SA_DBG2(("mpiInitialize:below 32 saRoot->interruptVecIndexBitMap[config->outboundQueues[qIdx].interruptVector] 0x%08x\n",saRoot->interruptVecIndexBitMap[config->outboundQueues[qIdx].interruptVector]));
2463         }
2464         else
2465         {
2466           saRoot->interruptVecIndexBitMap1[config->outboundQueues[qIdx].interruptVector] |= (1 << (qIdx - OQ_NUM_32));
2467           SA_DBG2(("mpiInitialize:Above 32 saRoot->interruptVecIndexBitMap1[config->outboundQueues[qIdx].interruptVector] 0x%08x\n",saRoot->interruptVecIndexBitMap1[config->outboundQueues[qIdx].interruptVector]));
2468         }
2469         /* Update the outbound configuration table */
2470         mpiUpdateOBQueueCfgTable(agRoot, &outQueueCfg, MSGUCfgTblDWIdx, pcibar);
2471 
2472         /* read the CI PCIBar offset and convert it to logical bar */
2473         OB_CIPCIBar = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + OB_CIPCI_BAR));
2474         saRoot->outboundQueue[qIdx].CIPCIBar    = mpiGetPCIBarIndex(agRoot, OB_CIPCIBar);
2475         saRoot->outboundQueue[qIdx].CIPCIOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + OB_CIPCI_BAR_OFFSET));
2476         saRoot->outboundQueue[qIdx].DIntTOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + OB_DYNAMIC_COALES_OFFSET));
2477         saRoot->outboundQueue[qIdx].qNumber      = qIdx;
2478 
2479         memOffset += memSize;
2480 
2481         if ((0 == ((qIdx + 1) % MAX_QUEUE_EACH_MEM)) ||
2482             (qIdx == (maxoutbound - 1)))
2483         {
2484           mIdx++;
2485           indexoffset += MAX_QUEUE_EACH_MEM;
2486           memOffset =0;
2487         }
2488       }
2489     }
2490   }
2491 
2492   /* calculate number of vectors */
2493   saRoot->numInterruptVectors = 0;
2494   for (qIdx = 0; qIdx < MAX_NUM_VECTOR; qIdx++)
2495   {
2496     if ((saRoot->interruptVecIndexBitMap[qIdx]) || (saRoot->interruptVecIndexBitMap1[qIdx]))
2497     {
2498       (saRoot->numInterruptVectors)++;
2499     }
2500   }
2501 
2502   SA_DBG2(("mpiInitialize:(saRoot->numInterruptVectors) 0x%x\n",(saRoot->numInterruptVectors)));
2503 
2504   if(smIS_SPCV(agRoot))
2505   {
2506     /* setup interrupt vector table  */
2507     mpiWrIntVecTable(agRoot,config);
2508   }
2509 
2510   if(smIS_SPCV(agRoot))
2511   {
2512     mpiWrAnalogSetupTable(agRoot,config);
2513   }
2514 
2515   /* setup phy analog registers */
2516   mpiWriteCALAll(agRoot, &config->phyAnalogConfig);
2517 
2518   {
2519     bit32 pcibar = 0;
2520     bit32 TableOffset;
2521     pcibar = siGetPciBar(agRoot);
2522     TableOffset = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
2523     TableOffset &= SCRATCH_PAD0_OFFSET_MASK;
2524     SA_DBG1(("mpiInitialize: mpiContextTable TableOffset 0x%08X contains 0x%08X\n",TableOffset,ossaHwRegReadExt(agRoot, pcibar, TableOffset )));
2525 
2526     SA_ASSERT( (ossaHwRegReadExt(agRoot, pcibar, TableOffset ) == 0x53434D50), "Config table signiture");
2527 
2528     SA_DBG1(("mpiInitialize: AGSA_MPI_MAIN_CONFIGURATION_TABLE           0x%08X\n", 0));
2529     SA_DBG1(("mpiInitialize: AGSA_MPI_GENERAL_STATUS_TABLE               0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_GST_OFFSET) & 0xFFFF )));
2530     SA_DBG1(("mpiInitialize: AGSA_MPI_INBOUND_QUEUE_CONFIGURATION_TABLE  0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_IBQ_OFFSET)  & 0xFFFF)));
2531     SA_DBG1(("mpiInitialize: AGSA_MPI_OUTBOUND_QUEUE_CONFIGURATION_TABLE 0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_OBQ_OFFSET)  & 0xFFFF)));
2532     SA_DBG1(("mpiInitialize: AGSA_MPI_SAS_PHY_ANALOG_SETUP_TABLE         0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_ANALOG_SETUP_OFFSET) & 0xFFFF )));
2533     SA_DBG1(("mpiInitialize: AGSA_MPI_INTERRUPT_VECTOR_TABLE             0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_INT_VEC_TABLE_OFFSET) & 0xFFFF)));
2534     SA_DBG1(("mpiInitialize: AGSA_MPI_PER_SAS_PHY_ATTRIBUTE_TABLE        0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_PHY_ATTRIBUTE_OFFSET) & 0xFFFF)));
2535     SA_DBG1(("mpiInitialize: AGSA_MPI_OUTBOUND_QUEUE_FAILOVER_TABLE      0x%08X\n", (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_MOQFOT_MOQFOES) & 0xFFFF)));
2536 
2537   }
2538 
2539   if(agNULL !=  saRoot->swConfig.mpiContextTable )
2540   {
2541     agsaMPIContext_t * context = (agsaMPIContext_t * )saRoot->swConfig.mpiContextTable;
2542     bit32 length = saRoot->swConfig.mpiContextTablelen;
2543     bit32 pcibar = 0;
2544     bit32 TableOffset;
2545     pcibar = siGetPciBar(agRoot);
2546     TableOffset = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
2547     TableOffset &= SCRATCH_PAD0_OFFSET_MASK;
2548     SA_DBG1(("mpiInitialize: mpiContextTable TableOffset 0x%08X contains 0x%08X\n",TableOffset,ossaHwRegReadExt(agRoot, pcibar, TableOffset )));
2549 
2550     SA_ASSERT( (ossaHwRegReadExt(agRoot, pcibar, TableOffset ) == 0x53434D50), "Config table signiture");
2551     if ( (ossaHwRegReadExt(agRoot, pcibar, TableOffset ) != 0x53434D50))
2552     {
2553       SA_DBG1(("mpiInitialize: TableOffset 0x%x reads 0x%x expect 0x%x \n",TableOffset,ossaHwRegReadExt(agRoot, pcibar, TableOffset ),0x53434D50));
2554     }
2555 
2556     if(context )
2557     {
2558       SA_DBG1(("mpiInitialize: MPITableType 0x%x context->offset 0x%x context->value 0x%x\n",context->MPITableType,context->offset,context->value));
2559       while( length != 0)
2560       {
2561         switch(context->MPITableType)
2562         {
2563 
2564         bit32 OffsetInMain;
2565         case AGSA_MPI_MAIN_CONFIGURATION_TABLE:
2566           SA_DBG1(("mpiInitialize:  AGSA_MPI_MAIN_CONFIGURATION_TABLE %d 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset, context->offset, context->value));
2567           OffsetInMain = TableOffset;
2568           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4) , context->value);
2569           break;
2570         case AGSA_MPI_GENERAL_STATUS_TABLE:
2571           SA_DBG1(("mpiInitialize: AGSA_MPI_GENERAL_STATUS_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType ,TableOffset+MAIN_GST_OFFSET, context->offset, context->value  ));
2572           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_GST_OFFSET ) & 0xFFFF) + TableOffset;
2573           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2574           break;
2575         case AGSA_MPI_INBOUND_QUEUE_CONFIGURATION_TABLE:
2576           SA_DBG1(("mpiInitialize: AGSA_MPI_INBOUND_QUEUE_CONFIGURATION_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset+MAIN_IBQ_OFFSET, context->offset, context->value));
2577           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_IBQ_OFFSET ) & 0xFFFF)  + TableOffset;
2578           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2579           break;
2580         case AGSA_MPI_OUTBOUND_QUEUE_CONFIGURATION_TABLE:
2581           SA_DBG1(("mpiInitialize: AGSA_MPI_OUTBOUND_QUEUE_CONFIGURATION_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset+MAIN_OBQ_OFFSET, context->offset, context->value));
2582           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_OBQ_OFFSET ) & 0xFFFF)  + TableOffset;
2583           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2584           break;
2585         case AGSA_MPI_SAS_PHY_ANALOG_SETUP_TABLE:
2586           SA_DBG1(("mpiInitialize: AGSA_MPI_SAS_PHY_ANALOG_SETUP_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset+MAIN_ANALOG_SETUP_OFFSET, context->offset, context->value));
2587           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+ MAIN_ANALOG_SETUP_OFFSET) & 0xFFFF)  + TableOffset;
2588           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2589           break;
2590         case AGSA_MPI_INTERRUPT_VECTOR_TABLE:
2591           SA_DBG1(("mpiInitialize: AGSA_MPI_INTERRUPT_VECTOR_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset+MAIN_INT_VEC_TABLE_OFFSET, context->offset, context->value));
2592           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+ MAIN_INT_VEC_TABLE_OFFSET) & 0xFFFF)  + TableOffset;
2593           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2594           break;
2595         case AGSA_MPI_PER_SAS_PHY_ATTRIBUTE_TABLE:
2596           SA_DBG1(("mpiInitialize: AGSA_MPI_PER_SAS_PHY_ATTRIBUTE_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset+MAIN_PHY_ATTRIBUTE_OFFSET, context->offset, context->value));
2597           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_PHY_ATTRIBUTE_OFFSET ) & 0xFFFF)  + TableOffset;
2598           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2599           break;
2600         case AGSA_MPI_OUTBOUND_QUEUE_FAILOVER_TABLE:
2601           SA_DBG1(("mpiInitialize: AGSA_MPI_OUTBOUND_QUEUE_FAILOVER_TABLE %d offset 0x%x + 0x%x = 0x%x\n",context->MPITableType,TableOffset+MAIN_MOQFOT_MOQFOES, context->offset, context->value));
2602           OffsetInMain = (ossaHwRegReadExt(agRoot, pcibar, TableOffset+MAIN_MOQFOT_MOQFOES ) & 0xFFFF)  + TableOffset;
2603           ossaHwRegWriteExt(agRoot, pcibar, OffsetInMain + (context->offset * 4), context->value);
2604           break;
2605         default:
2606           SA_DBG1(("mpiInitialize: error MPITableType unknown %d offset 0x%x value 0x%x\n",context->MPITableType, context->offset, context->value));
2607           break;
2608         }
2609         if(smIS_SPC12V(agRoot))
2610         {
2611           if (saRoot->ControllerInfo.fwInterfaceRev > 0x301 )
2612           {
2613             SA_DBG1(("mpiInitialize: MAIN_AWT_MIDRANGE 0x%08X\n",
2614                     ossaHwRegReadExt(agRoot, pcibar, TableOffset + MAIN_AWT_MIDRANGE)
2615                      ));
2616           }
2617         }
2618         if(length >= sizeof(agsaMPIContext_t))
2619         {
2620           length -= sizeof(agsaMPIContext_t);
2621           context++;
2622 
2623         }
2624         else
2625         {
2626           length = 0;
2627         }
2628       }
2629 
2630     }
2631 
2632     SA_DBG1(("mpiInitialize:  context %p saRoot->swConfig.mpiContextTable %p %d\n",context,saRoot->swConfig.mpiContextTable,context == saRoot->swConfig.mpiContextTable ? 1 : 0));
2633 
2634     if ( (ossaHwRegReadExt(agRoot, pcibar, TableOffset ) != 0x53434D50))
2635     {
2636       SA_DBG1(("mpiInitialize:TableOffset 0x%x reads 0x%x expect 0x%x \n",TableOffset,ossaHwRegReadExt(agRoot, pcibar, TableOffset ),0x53434D50));
2637     }
2638 
2639     SA_ASSERT( (ossaHwRegReadExt(agRoot, pcibar, TableOffset ) == 0x53434D50), "Config table signiture After");
2640   }
2641   /* At this point the Message Unit configuration table is set up. Now we need to ring the doorbell */
2642   togglevalue = 0;
2643 
2644   smTrace(hpDBG_VERY_LOUD,"74",  siHalRegReadExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET ));
2645   /* TP:74 Doorbell */
2646 
2647   /* Write bit0=1 to Inbound DoorBell Register to tell the SPC FW the table is updated */
2648   siHalRegWriteExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET, SPC_MSGU_CFG_TABLE_UPDATE);
2649 
2650   if(siHalRegReadExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET ) & SPC_MSGU_CFG_TABLE_UPDATE)
2651   {
2652     SA_DBG1(("mpiInitialize: SPC_MSGU_CFG_TABLE_UPDATE (0x%X) \n",  siHalRegReadExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET)));
2653   }
2654   else
2655   {
2656     SA_DBG1(("mpiInitialize: SPC_MSGU_CFG_TABLE_UPDATE not set (0x%X)\n",  siHalRegReadExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET)));
2657     ossaStallThread(agRoot, WAIT_INCREMENT);
2658   }
2659 
2660   smTrace(hpDBG_VERY_LOUD,"A5",  siHalRegReadExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET ));
2661   /* TP:A5 Doorbell */
2662 
2663 /*
2664 //  ossaHwRegWrite(agRoot, MSGU_IBDB_SET, SPC_MSGU_CFG_TABLE_UPDATE);
2665   MSGU_WRITE_IDR(SPC_MSGU_CFG_TABLE_UPDATE);
2666 */
2667 
2668 
2669   /* wait until Inbound DoorBell Clear Register toggled */
2670 WaitLonger:
2671   max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec */
2672   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
2673   do
2674   {
2675     ossaStallThread(agRoot, WAIT_INCREMENT);
2676     value = MSGU_READ_IDR;
2677     value &= SPC_MSGU_CFG_TABLE_UPDATE;
2678   } while ((value != togglevalue) && (max_wait_count -= WAIT_INCREMENT));
2679 
2680   smTrace(hpDBG_VERY_LOUD,"80", max_wait_count);
2681   /* TP:80 TP max_wait_count */
2682   if (!max_wait_count &&  mpiStartToggleFailed < 5 )
2683   {
2684      SA_DBG1(("mpiInitialize: mpiStartToggleFailed  count %d\n", mpiStartToggleFailed));
2685      mpiStartToggleFailed++;
2686     goto WaitLonger;
2687   }
2688 
2689   if (!max_wait_count )
2690   {
2691 
2692     SA_DBG1(("mpiInitialize: TIMEOUT:IBDB value/toggle = 0x%x 0x%x\n", value, togglevalue));
2693     MSGUCfgTblDWIdx = saveOffset;
2694     GSTLenMPIS = ossaHwRegReadExt(agRoot, pcibar, (bit32)MSGUCfgTblDWIdx + (bit32)(mainCfg.GSTOffset + GST_GSTLEN_MPIS_OFFSET));
2695     SA_DBG1(("mpiInitialize: MPI State = 0x%x\n", GSTLenMPIS));
2696     smTraceFuncExit(hpDBG_VERY_LOUD, 'f', "m3");
2697     return AGSA_RC_FAILURE;
2698   }
2699   smTrace(hpDBG_VERY_LOUD,"81", mpiStartToggleFailed );
2700   /* TP:81 TP */
2701 
2702   /* check the MPI-State for initialization */
2703   MSGUCfgTblDWIdx = saveOffset;
2704   GSTLenMPIS = ossaHwRegReadExt(agRoot, pcibar, (bit32)MSGUCfgTblDWIdx + (bit32)(mainCfg.GSTOffset + GST_GSTLEN_MPIS_OFFSET));
2705   if ( (GST_MPI_STATE_UNINIT == (GSTLenMPIS & GST_MPI_STATE_MASK)) && ( mpiUnInitFailed < 5 ) )
2706   {
2707     SA_DBG1(("mpiInitialize: MPI State = 0x%x mpiUnInitFailed count %d\n", GSTLenMPIS & GST_MPI_STATE_MASK,mpiUnInitFailed));
2708     ossaStallThread(agRoot, (20 * 1000));
2709 
2710     mpiUnInitFailed++;
2711     goto WaitLonger;
2712   }
2713 
2714   if (GST_MPI_STATE_INIT != (GSTLenMPIS & GST_MPI_STATE_MASK))
2715   {
2716     SA_DBG1(("mpiInitialize: Error Not GST_MPI_STATE_INIT MPI State = 0x%x\n", GSTLenMPIS & GST_MPI_STATE_MASK));
2717     smTraceFuncExit(hpDBG_VERY_LOUD, 'g', "m3");
2718     return AGSA_RC_FAILURE;
2719   }
2720   smTrace(hpDBG_VERY_LOUD,"82", 0);
2721   /* TP:82 TP */
2722 
2723   /* check MPI Initialization error */
2724   GSTLenMPIS = GSTLenMPIS >> SHIFT16;
2725   if (0x0000 != GSTLenMPIS)
2726   {
2727     SA_DBG1(("mpiInitialize: MPI Error = 0x%x\n", GSTLenMPIS));
2728     smTraceFuncExit(hpDBG_VERY_LOUD, 'h', "m3");
2729     return AGSA_RC_FAILURE;
2730   }
2731   smTrace(hpDBG_VERY_LOUD,"83", 0);
2732   /* TP:83 TP */
2733 
2734   /* reread IQ PI offset from SPC if IQ/OQ > 32 */
2735   if ((maxinbound > IQ_NUM_32) || (maxoutbound > OQ_NUM_32))
2736   {
2737     for(qIdx = 0; qIdx < maxinbound; qIdx++)
2738     {
2739       /* point back to the begin then plus offset to next queue */
2740       MSGUCfgTblDWIdx = saveOffset;
2741       MSGUCfgTblDWIdx += inboundoffset;
2742       MSGUCfgTblDWIdx += (sizeof(spc_inboundQueueDescriptor_t) * qIdx);
2743       saRoot->inboundQueue[qIdx].PIPCIOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + IB_PIPCI_BAR_OFFSET));
2744     }
2745   }
2746   smTrace(hpDBG_VERY_LOUD,"84", 0);
2747   /* TP:84 TP */
2748 
2749   /* at least one inbound queue and one outbound queue enabled */
2750   if ((0 == config->inboundQueues[0].numElements) || (0 == config->outboundQueues[0].numElements))
2751   {
2752     SA_DBG1(("mpiInitialize: Error,IQ0 or OQ0 have to enable\n"));
2753     smTraceFuncExit(hpDBG_VERY_LOUD, 'i', "m3");
2754     return AGSA_RC_FAILURE;
2755   }
2756   smTrace(hpDBG_VERY_LOUD,"85", 0);
2757   /* TP:85 TP */
2758 
2759   /* clean the inbound queues */
2760   for (i = 0; i < config->numInboundQueues; i ++)
2761   {
2762     if(0 != config->inboundQueues[i].numElements)
2763     {
2764       circularIQ = &saRoot->inboundQueue[i];
2765       si_memset(circularIQ->memoryRegion.virtPtr, 0, circularIQ->memoryRegion.totalLength);
2766       si_memset(saRoot->inboundQueue[i].ciPointer, 0, sizeof(bit32));
2767 
2768       if(smIS_SPCV(agRoot))
2769       {
2770         ossaHwRegWriteExt(circularIQ->agRoot, circularIQ->PIPCIBar, circularIQ->PIPCIOffset, 0);
2771         SA_DBG1(("mpiInitialize:  SPC V writes IQ %2d offset 0x%x\n",i ,circularIQ->PIPCIOffset));
2772       }
2773     }
2774   }
2775   smTrace(hpDBG_VERY_LOUD,"86", 0);
2776   /* TP:86 TP */
2777 
2778   /* clean the outbound queues */
2779   for (i = 0; i < config->numOutboundQueues; i ++)
2780   {
2781     if(0 != config->outboundQueues[i].numElements)
2782     {
2783       circularOQ = &saRoot->outboundQueue[i];
2784       si_memset(circularOQ->memoryRegion.virtPtr, 0, circularOQ->memoryRegion.totalLength);
2785       si_memset(saRoot->outboundQueue[i].piPointer, 0, sizeof(bit32));
2786       if(smIS_SPCV(agRoot))
2787       {
2788         ossaHwRegWriteExt(circularOQ->agRoot, circularOQ->CIPCIBar, circularOQ->CIPCIOffset, 0);
2789         SA_DBG2(("mpiInitialize:  SPC V writes OQ %2d offset 0x%x\n",i ,circularOQ->CIPCIOffset));
2790       }
2791 
2792     }
2793   }
2794 
2795 
2796   smTrace(hpDBG_VERY_LOUD,"75",0);
2797   /* TP:75 AAP1 IOP */
2798 
2799   /* read back AAP1 and IOP event log address and size */
2800   MSGUCfgTblDWIdx = saveOffset;
2801   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_ADDR_HI));
2802   saRoot->mainConfigTable.upperEventLogAddress = value;
2803   SA_DBG1(("mpiInitialize: upperEventLogAddress 0x%x\n", value));
2804   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_ADDR_LO));
2805   saRoot->mainConfigTable.lowerEventLogAddress = value;
2806   SA_DBG1(("mpiInitialize: lowerEventLogAddress 0x%x\n", value));
2807   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_BUFF_SIZE));
2808   saRoot->mainConfigTable.eventLogSize = value;
2809   SA_DBG1(("mpiInitialize: eventLogSize 0x%x\n", value));
2810   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_EVENT_LOG_OPTION));
2811   saRoot->mainConfigTable.eventLogOption = value;
2812   SA_DBG1(("mpiInitialize: eventLogOption 0x%x\n", value));
2813   SA_DBG1(("mpiInitialize: EventLog dd /p %08X`%08X L %x\n",saRoot->mainConfigTable.upperEventLogAddress,saRoot->mainConfigTable.lowerEventLogAddress,saRoot->mainConfigTable.eventLogSize/4 ));
2814 
2815   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_ADDR_HI));
2816   saRoot->mainConfigTable.upperIOPeventLogAddress = value;
2817   SA_DBG1(("mpiInitialize: upperIOPLogAddress 0x%x\n", value));
2818   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_ADDR_LO));
2819   saRoot->mainConfigTable.lowerIOPeventLogAddress = value;
2820   SA_DBG1(("mpiInitialize: lowerIOPLogAddress 0x%x\n", value));
2821   SA_DBG1(("mpiInitialize: IOPLog   dd /p %08X`%08X L %x\n",saRoot->mainConfigTable.upperIOPeventLogAddress,saRoot->mainConfigTable.lowerIOPeventLogAddress,saRoot->mainConfigTable.IOPeventLogSize/4 ));
2822   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_BUFF_SIZE));
2823   saRoot->mainConfigTable.IOPeventLogSize = value;
2824   SA_DBG1(("mpiInitialize: IOPeventLogSize 0x%x\n", value));
2825   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IOP_EVENT_LOG_OPTION));
2826   saRoot->mainConfigTable.IOPeventLogOption = value;
2827   SA_DBG1(("mpiInitialize: IOPeventLogOption 0x%x\n", value));
2828   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_INTERRUPT));
2829 
2830 #ifdef SA_PRINTOUT_IN_WINDBG
2831 #ifndef DBG
2832   DbgPrint("mpiInitialize: EventLog (%d) dd /p %08X`%08X L %x\n",
2833           saRoot->mainConfigTable.eventLogOption,
2834           saRoot->mainConfigTable.upperEventLogAddress,
2835           saRoot->mainConfigTable.lowerEventLogAddress,
2836           saRoot->mainConfigTable.eventLogSize/4 );
2837   DbgPrint("mpiInitialize: IOPLog   (%d) dd /p %08X`%08X L %x\n",
2838           saRoot->mainConfigTable.IOPeventLogOption,
2839           saRoot->mainConfigTable.upperIOPeventLogAddress,
2840           saRoot->mainConfigTable.lowerIOPeventLogAddress,
2841           saRoot->mainConfigTable.IOPeventLogSize/4 );
2842 #endif /* DBG  */
2843 #endif /* SA_PRINTOUT_IN_WINDBG  */
2844 
2845   saRoot->mainConfigTable.FatalErrorInterrupt = value;
2846   smTrace(hpDBG_VERY_LOUD,"76",value);
2847   /* TP:76 FatalErrorInterrupt */
2848 
2849   SA_DBG1(("mpiInitialize: hwConfig->hwOption %X\n", saRoot->hwConfig.hwOption  ));
2850 
2851   SA_DBG1(("mpiInitialize: FatalErrorInterrupt 0x%x\n", value));
2852 
2853   /* read back Register Dump offset and length */
2854   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP0_OFFSET));
2855   saRoot->mainConfigTable.FatalErrorDumpOffset0 = value;
2856   SA_DBG1(("mpiInitialize: FatalErrorDumpOffset0 0x%x\n", value));
2857   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP0_LENGTH));
2858   saRoot->mainConfigTable.FatalErrorDumpLength0 = value;
2859   SA_DBG1(("mpiInitialize: FatalErrorDumpLength0 0x%x\n", value));
2860   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP1_OFFSET));
2861   saRoot->mainConfigTable.FatalErrorDumpOffset1 = value;
2862   SA_DBG1(("mpiInitialize: FatalErrorDumpOffset1 0x%x\n", value));
2863   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP1_LENGTH));
2864   saRoot->mainConfigTable.FatalErrorDumpLength1 = value;
2865   SA_DBG1(("mpiInitialize: FatalErrorDumpLength1 0x%x\n", value));
2866 
2867   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_PRECTD_PRESETD));
2868   saRoot->mainConfigTable.PortRecoveryTimerPortResetTimer = value;
2869 
2870   SA_DBG1(("mpiInitialize: PortRecoveryTimerPortResetTimer 0x%x\n", value));
2871   value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(MSGUCfgTblDWIdx + MAIN_IRAD_RESERVED));
2872   saRoot->mainConfigTable.InterruptReassertionDelay = value;
2873 
2874   SA_DBG1(("mpiInitialize: InterruptReassertionDelay 0x%x\n", value));
2875 
2876 
2877   if(smIS_SPCV(agRoot))
2878   {
2879     bit32 sp1;
2880     sp1= ossaHwRegRead(agRoot,V_Scratchpad_1_Register );
2881     if(SCRATCH_PAD1_V_ERROR_STATE(sp1))
2882     {
2883       SA_DBG1(("mpiInitialize: SCRATCH_PAD1_V_ERROR_STAT 0x%x\n",sp1 ));
2884       ret = AGSA_RC_FAILURE;
2885     }
2886 
2887   }
2888 
2889   smTraceFuncExit(hpDBG_VERY_LOUD, 'j', "m3");
2890   return ret;
2891 }
2892 
2893 /*******************************************************************************/
2894 /** \fn mpiWaitForConfigTable(agsaRoot_t *agRoot, spc_configMainDescriptor_t *config)
2895  *  \brief Reading and Writing the Configuration Table
2896  *  \param agsaRoot Pointer to a data structure containing LL layer context handles
2897  *  \param config   Pointer to Configuration Table
2898  *
2899  * Return:
2900  *         AGSA_RC_SUCCESS if read the configuration table from SPC sucessful
2901  *         AGSA_RC_FAILURE if read the configuration table from SPC failed
2902  */
2903 /*******************************************************************************/
2904 GLOBAL bit32 mpiWaitForConfigTable(agsaRoot_t                 *agRoot,
2905                                    spc_configMainDescriptor_t *config)
2906 {
2907   agsaLLRoot_t  *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
2908   bit32    MSGUCfgTblBase, ret = AGSA_RC_SUCCESS;
2909   bit32    CfgTblDWIdx;
2910   bit32    value, value1;
2911   bit32    max_wait_time;
2912   bit32    max_wait_count;
2913   bit32    Signature, ExpSignature;
2914   bit8     pcibar;
2915 
2916   SA_DBG2(("mpiWaitForConfigTable: Entering\n"));
2917   SA_ASSERT(NULL != agRoot, "agRoot argument cannot be null");
2918 
2919   smTraceFuncEnter(hpDBG_VERY_LOUD,"m4");
2920 
2921 
2922   /* check error state */
2923   value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1,MSGU_SCRATCH_PAD_1);
2924   value1 = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2,MSGU_SCRATCH_PAD_2);
2925 
2926   if( smIS_SPC(agRoot) )
2927   {
2928     SA_DBG1(("mpiWaitForConfigTable: Waiting for SPC FW becoming ready.P1 0x%X P2 0x%X\n",value,value1));
2929 
2930   /* check AAP error */
2931   if (SCRATCH_PAD1_ERR == (value & SCRATCH_PAD_STATE_MASK))
2932   {
2933     /* error state */
2934     SA_DBG1(("mpiWaitForConfigTable: AAP error state and code 0x%x, ScratchPad2=0x%x\n", value, value1));
2935 #if defined(SALLSDK_DEBUG)
2936     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD0 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0)));
2937     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD3 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3,MSGU_SCRATCH_PAD_3)));
2938 #endif
2939     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m4");
2940     return AGSA_RC_FAILURE;
2941   }
2942 
2943   /* check IOP error */
2944   if (SCRATCH_PAD2_ERR == (value1 & SCRATCH_PAD_STATE_MASK))
2945   {
2946     /* error state */
2947     SA_DBG1(("mpiWaitForConfigTable: IOP error state and code 0x%x, ScratchPad1=0x%x\n", value1, value));
2948 #if defined(SALLSDK_DEBUG)
2949     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD0 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0)));
2950     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD3 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3,MSGU_SCRATCH_PAD_3)));
2951 #endif
2952     smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "m4");
2953     return AGSA_RC_FAILURE;
2954   }
2955 
2956   /* bit 4-31 of scratch pad1 should be zeros if it is not in error state */
2957 #ifdef DONT_DO /*                                                                        */
2958   if (value & SCRATCH_PAD1_STATE_MASK)
2959   {
2960     /* error case */
2961     SA_DBG1(("mpiWaitForConfigTable: wrong state failure, scratchPad1 0x%x\n", value));
2962     SA_DBG1(("mpiWaitForConfigTable: ScratchPad0 AAP error code 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0)));
2963 #if defined(SALLSDK_DEBUG)
2964     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD2 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2,MSGU_SCRATCH_PAD_0)));
2965     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD3 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3,MSGU_SCRATCH_PAD_3)));
2966 #endif
2967     smTraceFuncExit(hpDBG_VERY_LOUD, 'c', "m4");
2968     return AGSA_RC_FAILURE;
2969   }
2970 
2971   /* bit 4-31 of scratch pad2 should be zeros if it is not in error state */
2972   if (value1 & SCRATCH_PAD2_STATE_MASK)
2973   {
2974     /* error case */
2975     SA_DBG1(("mpiWaitForConfigTable: wrong state failure, scratchPad2 0x%x\n", value1));
2976     SA_DBG1(("mpiWaitForConfigTable: ScratchPad3 IOP error code 0x%x\n",siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3,MSGU_SCRATCH_PAD_3) ));
2977 #if defined(SALLSDK_DEBUG)
2978     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD0 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0)));
2979     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD1 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1,MSGU_SCRATCH_PAD_1)));
2980 #endif
2981     smTraceFuncExit(hpDBG_VERY_LOUD, 'd', "m4");
2982 
2983     return AGSA_RC_FAILURE;
2984   }
2985 #endif /* DONT_DO */
2986 
2987   /* checking the fw and IOP in ready state */
2988   max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec timeout */
2989   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
2990   /* wait until scratch pad 1 and 2 registers in ready state  */
2991   do
2992   {
2993     ossaStallThread(agRoot, WAIT_INCREMENT);
2994     value =siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1,MSGU_SCRATCH_PAD_1) & SCRATCH_PAD1_RDY;
2995     value1 =siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2,MSGU_SCRATCH_PAD_2)  & SCRATCH_PAD2_RDY;
2996     if(smIS_SPCV(agRoot))
2997     {
2998       SA_DBG1(("mpiWaitForConfigTable:VEN_DEV_SPCV force  SCRATCH_PAD2 RDY 1 %08X 2 %08X\n" ,value,value1));
2999       value1 =3;
3000     }
3001 
3002     if ((max_wait_count -= WAIT_INCREMENT) == 0)
3003     {
3004       SA_DBG1(("mpiWaitForConfigTable: Timeout!! SCRATCH_PAD1/2 value = 0x%x 0x%x\n", value, value1));
3005       break;
3006     }
3007   } while ((value != SCRATCH_PAD1_RDY) || (value1 != SCRATCH_PAD2_RDY));
3008 
3009   if (!max_wait_count)
3010   {
3011     SA_DBG1(("mpiWaitForConfigTable: timeout failure\n"));
3012 #if defined(SALLSDK_DEBUG)
3013     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD0 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0)));
3014     SA_DBG1(("mpiWaitForConfigTable: SCRATCH_PAD3 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3,MSGU_SCRATCH_PAD_3)));
3015 #endif
3016     smTraceFuncExit(hpDBG_VERY_LOUD, 'e', "m4");
3017     return AGSA_RC_FAILURE;
3018   }
3019 
3020   }else
3021   {
3022 
3023     if(((value & SCRATCH_PAD1_V_BOOTSTATE_HDA_SEEPROM ) == SCRATCH_PAD1_V_BOOTSTATE_HDA_SEEPROM))
3024     {
3025       SA_DBG1(("mpiWaitForConfigTable: HDA mode set in SEEPROM SP1 0x%X\n",value));
3026     }
3027     if(((value & SCRATCH_PAD1_V_READY) != SCRATCH_PAD1_V_READY) ||
3028        (value == 0xffffffff))
3029     {
3030       SA_DBG1(("mpiWaitForConfigTable: Waiting for _V_ FW becoming ready.P1 0x%X P2 0x%X\n",value,value1));
3031 
3032       /* checking the fw and IOP in ready state */
3033       max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec timeout */
3034       max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
3035       /* wait until scratch pad 1 and 2 registers in ready state  */
3036       do
3037       {
3038         ossaStallThread(agRoot, WAIT_INCREMENT);
3039         value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1,MSGU_SCRATCH_PAD_1);
3040         value1 = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2,MSGU_SCRATCH_PAD_2);
3041 
3042         if ((max_wait_count -= WAIT_INCREMENT) == 0)
3043         {
3044           SA_DBG1(("mpiWaitForConfigTable: Timeout!! SCRATCH_PAD1/2 value = 0x%x 0x%x\n", value, value1));
3045           return AGSA_RC_FAILURE;
3046         }
3047       } while (((value & SCRATCH_PAD1_V_READY) != SCRATCH_PAD1_V_READY) ||
3048                (value == 0xffffffff));
3049     }
3050   }
3051 
3052 
3053   SA_DBG1(("mpiWaitForConfigTable: FW Ready, SCRATCH_PAD1/2 value = 0x%x 0x%x\n", value, value1));
3054 
3055   /* read scratch pad0 to get PCI BAR and offset of configuration table */
3056   MSGUCfgTblBase = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
3057   /* get offset */
3058   CfgTblDWIdx = MSGUCfgTblBase & SCRATCH_PAD0_OFFSET_MASK;
3059   /* get PCI BAR */
3060   MSGUCfgTblBase = (MSGUCfgTblBase & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
3061 
3062   if(smIS_SPC(agRoot))
3063   {
3064     if( smIS_spc8081(agRoot))
3065     {
3066       if (BAR4 != MSGUCfgTblBase)
3067       {
3068         SA_DBG1(("mpiWaitForConfigTable: smIS_spc8081 PCI BAR is not BAR4, bar=0x%x - failure\n", MSGUCfgTblBase));
3069         smTraceFuncExit(hpDBG_VERY_LOUD, 'f', "m4");
3070         return AGSA_RC_FAILURE;
3071       }
3072     }
3073     else
3074     {
3075       if (BAR5 != MSGUCfgTblBase)
3076       {
3077         SA_DBG1(("mpiWaitForConfigTable: PCI BAR is not BAR5, bar=0x%x - failure\n", MSGUCfgTblBase));
3078         smTraceFuncExit(hpDBG_VERY_LOUD, 'g', "m4");
3079         return AGSA_RC_FAILURE;
3080       }
3081     }
3082   }
3083 
3084   /* convert the PCI BAR to logical bar number */
3085   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, MSGUCfgTblBase);
3086 
3087   /* read signature from the configuration table */
3088   Signature = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx);
3089 
3090   /* Error return if the signature is not "PMCS" */
3091   ExpSignature = ('P') | ('M' << SHIFT8) | ('C' << SHIFT16) | ('S' << SHIFT24);
3092 
3093   if (Signature != ExpSignature)
3094   {
3095     SA_DBG1(("mpiWaitForConfigTable: Signature value = 0x%x\n", Signature));
3096     smTraceFuncExit(hpDBG_VERY_LOUD, 'h', "m4");
3097     return AGSA_RC_FAILURE;
3098   }
3099 
3100   /* save Signature */
3101   si_memcpy(&config->Signature, &Signature, sizeof(Signature));
3102 
3103   /* read Interface Revsion from the configuration table */
3104   config->InterfaceRev = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_INTERFACE_REVISION);
3105 
3106   /* read FW Revsion from the configuration table */
3107   config->FWRevision = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_FW_REVISION);
3108 
3109   /* read Max Outstanding IO from the configuration table */
3110   config->MaxOutstandingIO = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_MAX_OUTSTANDING_IO_OFFSET);
3111 
3112   /* read Max SGL and Max Devices from the configuration table */
3113   config->MDevMaxSGL = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_MAX_SGL_OFFSET);
3114 
3115   /* read Controller Cap Flags from the configuration table */
3116   config->ContrlCapFlag = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_CNTRL_CAP_OFFSET);
3117 
3118   /* read GST Table Offset from the configuration table */
3119   config->GSTOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_GST_OFFSET);
3120 
3121   /* read Inbound Queue Offset from the configuration table */
3122   config->inboundQueueOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_IBQ_OFFSET);
3123 
3124   /* read Outbound Queue Offset from the configuration table */
3125   config->outboundQueueOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_OBQ_OFFSET);
3126 
3127 
3128   if(smIS_SPCV(agRoot))
3129   {
3130     ;/* SPCV - reserved field */
3131   }
3132   else
3133   {
3134     /* read HDA Flags from the configuration table */
3135     config->HDAModeFlags = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_HDA_FLAGS_OFFSET);
3136   }
3137 
3138   /* read analog Setting offset from the configuration table */
3139   config->analogSetupTblOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_ANALOG_SETUP_OFFSET);
3140 
3141   if(smIS_SPCV(agRoot))
3142   {
3143     ;/* SPCV - reserved field */
3144     /* read interrupt vector table offset */
3145     config->InterruptVecTblOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_INT_VEC_TABLE_OFFSET);
3146     /* read phy attribute table offset */
3147     config->phyAttributeTblOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_PHY_ATTRIBUTE_OFFSET);
3148     SA_DBG1(("mpiWaitForConfigTable: INT Vector Tble Offset = 0x%x\n", config->InterruptVecTblOffset));
3149     SA_DBG1(("mpiWaitForConfigTable: Phy Attribute Tble Offset = 0x%x\n", config->phyAttributeTblOffset));
3150   }
3151   else
3152   {
3153     ;/* SPC - Not used */
3154   }
3155 
3156   /* read Error Dump Offset and Length */
3157   config->FatalErrorDumpOffset0 = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP0_OFFSET);
3158   config->FatalErrorDumpLength0 = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP0_LENGTH);
3159   config->FatalErrorDumpOffset1 = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP1_OFFSET);
3160   config->FatalErrorDumpLength1 = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_FATAL_ERROR_RDUMP1_LENGTH);
3161 
3162   SA_DBG1(("mpiWaitForConfigTable: Interface Revision value = 0x%08x\n", config->InterfaceRev));
3163   SA_DBG1(("mpiWaitForConfigTable: FW Revision value = 0x%08x\n", config->FWRevision));
3164 
3165   if(smIS_SPC(agRoot))
3166   {
3167     SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%08x\n", STSDK_LL_SPC_VERSION));
3168   }
3169   if(smIS_SPC6V(agRoot))
3170   {
3171     SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%08x\n",STSDK_LL_VERSION ));
3172   }
3173   if(smIS_SPC12V(agRoot))
3174   {
3175     SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%08x\n",STSDK_LL_12G_VERSION ));
3176   }
3177 
3178   SA_DBG1(("mpiWaitForConfigTable: MaxOutstandingIO value = 0x%08x\n", config->MaxOutstandingIO));
3179   SA_DBG1(("mpiWaitForConfigTable: MDevMaxSGL value = 0x%08x\n", config->MDevMaxSGL));
3180   SA_DBG1(("mpiWaitForConfigTable: ContrlCapFlag value = 0x%08x\n", config->ContrlCapFlag));
3181   SA_DBG1(("mpiWaitForConfigTable: GSTOffset value = 0x%08x\n", config->GSTOffset));
3182   SA_DBG1(("mpiWaitForConfigTable: inboundQueueOffset value = 0x%08x\n", config->inboundQueueOffset));
3183   SA_DBG1(("mpiWaitForConfigTable: outboundQueueOffset value = 0x%08x\n", config->outboundQueueOffset));
3184   SA_DBG1(("mpiWaitForConfigTable: FatalErrorDumpOffset0 value = 0x%08x\n", config->FatalErrorDumpOffset0));
3185   SA_DBG1(("mpiWaitForConfigTable: FatalErrorDumpLength0 value = 0x%08x\n", config->FatalErrorDumpLength0));
3186   SA_DBG1(("mpiWaitForConfigTable: FatalErrorDumpOffset1 value = 0x%08x\n", config->FatalErrorDumpOffset1));
3187   SA_DBG1(("mpiWaitForConfigTable: FatalErrorDumpLength1 value = 0x%08x\n", config->FatalErrorDumpLength1));
3188 
3189 
3190   SA_DBG1(("mpiWaitForConfigTable: HDAModeFlags value = 0x%08x\n", config->HDAModeFlags));
3191   SA_DBG1(("mpiWaitForConfigTable: analogSetupTblOffset value = 0x%08x\n", config->analogSetupTblOffset));
3192 
3193   /* check interface version */
3194 
3195   if(smIS_SPC6V(agRoot))
3196   {
3197     if (config->InterfaceRev != STSDK_LL_INTERFACE_VERSION)
3198     {
3199       SA_DBG1(("mpiWaitForConfigTable: V sTSDK interface ver. 0x%x does not match InterfaceRev 0x%x warning!\n", STSDK_LL_INTERFACE_VERSION, config->InterfaceRev));
3200       ret = AGSA_RC_VERSION_UNTESTED;
3201       if ((config->InterfaceRev & STSDK_LL_INTERFACE_VERSION_IGNORE_MASK) != (STSDK_LL_INTERFACE_VERSION & STSDK_LL_INTERFACE_VERSION_IGNORE_MASK))
3202       {
3203         SA_DBG1(("mpiWaitForConfigTable: V sTSDK interface ver. 0x%x incompatible with InterfaceRev 0x%x warning!\n", STSDK_LL_INTERFACE_VERSION, config->InterfaceRev));
3204         ret = AGSA_RC_VERSION_INCOMPATIBLE;
3205         smTraceFuncExit(hpDBG_VERY_LOUD, 'i', "m4");
3206         return ret;
3207       }
3208     }
3209   }
3210   else if(smIS_SPC12V(agRoot))
3211   {
3212     if (config->InterfaceRev != STSDK_LL_12G_INTERFACE_VERSION)
3213     {
3214       SA_DBG1(("mpiWaitForConfigTable: 12g V sTSDK interface ver. 0x%x does not match InterfaceRev 0x%x warning!\n", STSDK_LL_12G_INTERFACE_VERSION, config->InterfaceRev));
3215       ret = AGSA_RC_VERSION_UNTESTED;
3216       if ((config->InterfaceRev & STSDK_LL_INTERFACE_VERSION_IGNORE_MASK) != (STSDK_LL_12G_INTERFACE_VERSION & STSDK_LL_INTERFACE_VERSION_IGNORE_MASK))
3217       {
3218         SA_DBG1(("mpiWaitForConfigTable: V sTSDK interface ver. 0x%x incompatible with InterfaceRev 0x%x warning!\n", STSDK_LL_12G_INTERFACE_VERSION, config->InterfaceRev));
3219         ret = AGSA_RC_VERSION_INCOMPATIBLE;
3220         ret = AGSA_RC_VERSION_UNTESTED;
3221         smTraceFuncExit(hpDBG_VERY_LOUD, 'j', "m4");
3222         return ret;
3223       }
3224     }
3225   }
3226   else
3227   {
3228     if (config->InterfaceRev != STSDK_LL_OLD_INTERFACE_VERSION)
3229     {
3230       SA_DBG1(("mpiWaitForConfigTable: SPC sTSDK interface ver. 0x%08x not compatible with InterfaceRev 0x%x warning!\n", STSDK_LL_INTERFACE_VERSION, config->InterfaceRev));
3231       ret = AGSA_RC_VERSION_INCOMPATIBLE;
3232       smTraceFuncExit(hpDBG_VERY_LOUD, 'k', "m4");
3233       return ret;
3234     }
3235 
3236   }
3237 
3238 
3239   /* Check FW versions */
3240   if(smIS_SPC6V(agRoot))
3241   {
3242     SA_DBG1(("mpiWaitForConfigTable:6 sTSDK ver. sa.h 0x%08x config 0x%08x\n", STSDK_LL_VERSION, config->FWRevision));
3243     /* check FW and LL sTSDK version */
3244     if (config->FWRevision !=  MATCHING_V_FW_VERSION )
3245     {
3246       if (config->FWRevision >  MATCHING_V_FW_VERSION)
3247       {
3248         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x hadn't tested with FW ver. 0x%08x warning!\n", STSDK_LL_VERSION, config->FWRevision));
3249         ret = AGSA_RC_VERSION_UNTESTED;
3250       }
3251 
3252       else if (config->FWRevision <  MIN_FW_SPCVE_VERSION_SUPPORTED)
3253       {
3254         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x not compatible with FW ver. 0x%08x warning!\n", STSDK_LL_VERSION, config->FWRevision));
3255         ret = AGSA_RC_VERSION_INCOMPATIBLE;
3256         smTraceFuncExit(hpDBG_VERY_LOUD, 'l', "m4");
3257         return ret;
3258       }
3259       else
3260       {
3261         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x mismatch with FW ver. 0x%08x warning!\n",STSDK_LL_VERSION , config->FWRevision));
3262         ret = AGSA_RC_VERSION_UNTESTED;
3263       }
3264     }
3265   }else if(smIS_SPC12V(agRoot))
3266   {
3267     SA_DBG1(("mpiWaitForConfigTable:12 sTSDK ver. sa.h 0x%08x config 0x%08x\n", STSDK_LL_12G_VERSION, config->FWRevision));
3268     /* check FW and LL sTSDK version */
3269     if (config->FWRevision !=  MATCHING_12G_V_FW_VERSION )
3270     {
3271       if (config->FWRevision >  MATCHING_12G_V_FW_VERSION)
3272       {
3273         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x hadn't tested with FW ver. 0x%08x warning!\n", STSDK_LL_12G_VERSION, config->FWRevision));
3274         ret = AGSA_RC_VERSION_UNTESTED;
3275       }
3276 
3277       else if (config->FWRevision <  MIN_FW_12G_SPCVE_VERSION_SUPPORTED)
3278       {
3279         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x not compatible with FW ver. 0x%08x warning!\n", STSDK_LL_12G_VERSION, config->FWRevision));
3280         ret = AGSA_RC_VERSION_INCOMPATIBLE;
3281         smTraceFuncExit(hpDBG_VERY_LOUD, 'm', "m4");
3282         return ret;
3283       }
3284       else
3285       {
3286         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x mismatch with FW ver. 0x%08x warning!\n",STSDK_LL_12G_VERSION , config->FWRevision));
3287         ret = AGSA_RC_VERSION_UNTESTED;
3288       }
3289     }
3290   }
3291   else
3292   {
3293     if (config->FWRevision != MATCHING_SPC_FW_VERSION )
3294     {
3295       if (config->FWRevision >  MATCHING_SPC_FW_VERSION)
3296       {
3297         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x hadn't tested with FW ver. 0x%08x warning!\n", STSDK_LL_SPC_VERSION, config->FWRevision));
3298         ret = AGSA_RC_VERSION_UNTESTED;
3299       }
3300       else if (config->FWRevision <  MIN_FW_SPC_VERSION_SUPPORTED)
3301       {
3302         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x not compatible with FW ver. 0x%08x warning!\n", STSDK_LL_SPC_VERSION, config->FWRevision));
3303         ret = AGSA_RC_VERSION_INCOMPATIBLE;
3304         smTraceFuncExit(hpDBG_VERY_LOUD, 'n', "m4");
3305         return ret;
3306       }
3307       else
3308       {
3309         SA_DBG1(("mpiWaitForConfigTable: sTSDK ver. 0x%x mismatch with FW ver. 0x%08x warning!\n",STSDK_LL_SPC_VERSION , config->FWRevision));
3310         ret = AGSA_RC_VERSION_UNTESTED;
3311       }
3312     }
3313   }
3314   SA_DBG1(("mpiWaitForConfigTable: ILA version 0x%08X\n",  ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_ILAT_ILAV_ILASMRN_ILAMRN_ILAMJN) ));
3315 
3316 
3317   if(smIS_SPC12V(agRoot))
3318   {
3319     if (config->InterfaceRev > 0x301 )
3320     {
3321       SA_DBG1(("mpiWaitForConfigTable: MAIN_INACTIVE_ILA_REVSION 0x%08X\n",  ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_INACTIVE_ILA_REVSION) ));
3322       SA_DBG1(("mpiWaitForConfigTable: MAIN_SEEPROM_REVSION 0x%08X\n",  ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_SEEPROM_REVSION) ));
3323     }
3324   }
3325 
3326   if(smIS_SPC12V(agRoot))
3327   {
3328     if (config->InterfaceRev > 0x301 )
3329     {
3330       SA_DBG1(("mpiWaitForConfigTable: MAIN_AWT_MIDRANGE 0x%08X\n",  ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_AWT_MIDRANGE) ));
3331     }
3332   }
3333 
3334 
3335   if(smIS_SFC(agRoot))
3336   {
3337     /* always success for SFC*/
3338     ret = AGSA_RC_SUCCESS;
3339   }
3340 
3341   if (agNULL != saRoot)
3342   {
3343     /* save the information */
3344     saRoot->ControllerInfo.signature = Signature;
3345     saRoot->ControllerInfo.fwInterfaceRev = config->InterfaceRev;
3346 
3347     if(smIS_SPCV(agRoot))
3348     {
3349       saRoot->ControllerInfo.hwRevision = (ossaHwRegReadConfig32(agRoot,8) & 0xFF);
3350       SA_DBG1(("mpiWaitForConfigTable: hwRevision 0x%x\n",saRoot->ControllerInfo.hwRevision  ));
3351     }
3352     else
3353     {
3354       saRoot->ControllerInfo.hwRevision = SPC_READ_DEV_REV;
3355     }
3356 
3357     saRoot->ControllerInfo.fwRevision = config->FWRevision;
3358     saRoot->ControllerInfo.ilaRevision  = config->ilaRevision;
3359     saRoot->ControllerInfo.maxPendingIO = config->MaxOutstandingIO;
3360     saRoot->ControllerInfo.maxSgElements = config->MDevMaxSGL & 0xFFFF;
3361     saRoot->ControllerInfo.maxDevices = (config->MDevMaxSGL & MAX_DEV_BITS) >> SHIFT16;
3362     saRoot->ControllerInfo.queueSupport = config->ContrlCapFlag & Q_SUPPORT_BITS;
3363     saRoot->ControllerInfo.phyCount = (bit8)((config->ContrlCapFlag & PHY_COUNT_BITS) >> SHIFT19);
3364     saRoot->ControllerInfo.sasSpecsSupport = (config->ContrlCapFlag & SAS_SPEC_BITS) >> SHIFT25;
3365     SA_DBG1(("mpiWaitForConfigTable: MaxOutstandingIO 0x%x swConfig->maxActiveIOs 0x%x\n", config->MaxOutstandingIO,saRoot->swConfig.maxActiveIOs ));
3366 
3367     if(smIS_SPCV(agRoot))
3368     {
3369       ;/* SPCV - reserved field */
3370     }
3371     else
3372     {
3373       saRoot->ControllerInfo.controllerSetting = (bit8)config->HDAModeFlags;
3374     }
3375 
3376     saRoot->ControllerInfo.sdkInterfaceRev = STSDK_LL_INTERFACE_VERSION;
3377     saRoot->ControllerInfo.sdkRevision = STSDK_LL_VERSION;
3378     saRoot->mainConfigTable.regDumpPCIBAR = pcibar;
3379     saRoot->mainConfigTable.FatalErrorDumpOffset0 = config->FatalErrorDumpOffset0;
3380     saRoot->mainConfigTable.FatalErrorDumpLength0 = config->FatalErrorDumpLength0;
3381     saRoot->mainConfigTable.FatalErrorDumpOffset1 = config->FatalErrorDumpOffset1;
3382     saRoot->mainConfigTable.FatalErrorDumpLength1 = config->FatalErrorDumpLength1;
3383 
3384     if(smIS_SPCV(agRoot))
3385     {
3386       ;/* SPCV - reserved field */
3387     }
3388     else
3389     {
3390       saRoot->mainConfigTable.HDAModeFlags = config->HDAModeFlags;
3391     }
3392 
3393     saRoot->mainConfigTable.analogSetupTblOffset = config->analogSetupTblOffset;
3394 
3395     if(smIS_SPCV(agRoot))
3396     {
3397       saRoot->mainConfigTable.InterruptVecTblOffset = config->InterruptVecTblOffset;
3398       saRoot->mainConfigTable.phyAttributeTblOffset = config->phyAttributeTblOffset;
3399       saRoot->mainConfigTable.PortRecoveryTimerPortResetTimer = config->portRecoveryResetTimer;
3400     }
3401 
3402     SA_DBG1(("mpiWaitForConfigTable: Signature = 0x%x\n", Signature));
3403     SA_DBG1(("mpiWaitForConfigTable: hwRevision = 0x%x\n", saRoot->ControllerInfo.hwRevision));
3404     SA_DBG1(("mpiWaitForConfigTable: FW Revision = 0x%x\n", config->FWRevision));
3405     SA_DBG1(("mpiWaitForConfigTable: Max Sgl = 0x%x\n", saRoot->ControllerInfo.maxSgElements));
3406     SA_DBG1(("mpiWaitForConfigTable: Max Device = 0x%x\n", saRoot->ControllerInfo.maxDevices));
3407     SA_DBG1(("mpiWaitForConfigTable: Queue Support = 0x%x\n", saRoot->ControllerInfo.queueSupport));
3408     SA_DBG1(("mpiWaitForConfigTable: Phy Count = 0x%x\n", saRoot->ControllerInfo.phyCount));
3409     SA_DBG1(("mpiWaitForConfigTable: sas Specs Support = 0x%x\n", saRoot->ControllerInfo.sasSpecsSupport));
3410 
3411   }
3412 
3413 
3414   if(ret != AGSA_RC_SUCCESS )
3415   {
3416     SA_DBG1(("mpiWaitForConfigTable: return 0x%x not AGSA_RC_SUCCESS warning!\n", ret));
3417   }
3418 
3419 
3420   smTraceFuncExit(hpDBG_VERY_LOUD, 'o', "m4");
3421   return ret;
3422 }
3423 
3424 /*******************************************************************************/
3425 /** \fn mpiUnInitConfigTable(agsaRoot_t *agRoot, spc_configMainDescriptor_t *config)
3426  *  \brief UnInitialization Configuration Table
3427  *  \param agsaRoot Pointer to a data structure containing LL layer context handles
3428  *
3429  * Return:
3430  *         AGSA_RC_SUCCESS if Un-initialize the configuration table sucessful
3431  *         AGSA_RC_FAILURE if Un-initialize the configuration table failed
3432  */
3433 /*******************************************************************************/
3434 GLOBAL bit32 mpiUnInitConfigTable(agsaRoot_t *agRoot)
3435 {
3436   bit32    MSGUCfgTblBase;
3437   bit32    CfgTblDWIdx, GSTOffset, GSTLenMPIS;
3438   bit32    value, togglevalue;
3439   bit32    max_wait_time;
3440   bit32    max_wait_count;
3441   bit8     pcibar;
3442 
3443   smTraceFuncEnter(hpDBG_VERY_LOUD,"m7");
3444   SA_DBG1(("mpiUnInitConfigTable: agRoot %p\n",agRoot));
3445   SA_ASSERT(NULL != agRoot, "agRoot argument cannot be null");
3446 
3447   togglevalue = 0;
3448 
3449   /* read scratch pad0 to get PCI BAR and offset of configuration table */
3450   MSGUCfgTblBase =siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
3451 
3452   if(MSGUCfgTblBase == 0xFFFFFFFF)
3453   {
3454     SA_DBG1(("mpiUnInitConfigTable: MSGUCfgTblBase = 0x%x AGSA_RC_FAILURE\n",MSGUCfgTblBase));
3455     return AGSA_RC_FAILURE;
3456   }
3457 
3458   /* get offset */
3459   CfgTblDWIdx = MSGUCfgTblBase & SCRATCH_PAD0_OFFSET_MASK;
3460   /* get PCI BAR */
3461   MSGUCfgTblBase = (MSGUCfgTblBase & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
3462 
3463   /* convert the PCI BAR to logical bar number */
3464   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, MSGUCfgTblBase);
3465 
3466   /* Write bit 1 to Inbound DoorBell Register */
3467   siHalRegWriteExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET, SPC_MSGU_CFG_TABLE_RESET);
3468 
3469   /* wait until Inbound DoorBell Clear Register toggled */
3470   max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec */
3471   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
3472   do
3473   {
3474     ossaStallThread(agRoot, WAIT_INCREMENT);
3475     value = MSGU_READ_IDR;
3476     value &= SPC_MSGU_CFG_TABLE_RESET;
3477   } while ((value != togglevalue) && (max_wait_count -= WAIT_INCREMENT));
3478 
3479   if (!max_wait_count)
3480   {
3481     SA_DBG1(("mpiUnInitConfigTable: TIMEOUT:IBDB value/toggle = 0x%x 0x%x\n", value, togglevalue));
3482     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m7");
3483 
3484     if(smIS_SPC(agRoot) )
3485     {
3486       return AGSA_RC_FAILURE;
3487     }
3488 
3489   }
3490 
3491   /* check the MPI-State for termination in progress */
3492   /* wait until Inbound DoorBell Clear Register toggled */
3493   max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec */
3494   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
3495   GSTOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + MAIN_GST_OFFSET);
3496   do
3497   {
3498     ossaStallThread(agRoot, WAIT_INCREMENT);
3499 
3500     if(GSTOffset == 0xFFFFFFFF)
3501     {
3502       SA_DBG1(("mpiUnInitConfigTable:AGSA_RC_FAILURE GSTOffset = 0x%x\n",GSTOffset));
3503       return AGSA_RC_FAILURE;
3504     }
3505 
3506     GSTLenMPIS = ossaHwRegReadExt(agRoot, pcibar, (bit32)CfgTblDWIdx + (bit32)(GSTOffset + GST_GSTLEN_MPIS_OFFSET));
3507     if (GST_MPI_STATE_UNINIT == (GSTLenMPIS & GST_MPI_STATE_MASK))
3508     {
3509       break;
3510     }
3511   } while (max_wait_count -= WAIT_INCREMENT);
3512 
3513   if (!max_wait_count)
3514   {
3515     SA_DBG1(("mpiUnInitConfigTable: TIMEOUT, MPI State = 0x%x\n", GSTLenMPIS & GST_MPI_STATE_MASK));
3516 #if defined(SALLSDK_DEBUG)
3517 
3518     SA_DBG1(("mpiUnInitConfigTable: SCRATCH_PAD0 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_0)));
3519     SA_DBG1(("mpiUnInitConfigTable: SCRATCH_PAD1 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1)));
3520     SA_DBG1(("mpiUnInitConfigTable: SCRATCH_PAD2 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_2)));
3521     SA_DBG1(("mpiUnInitConfigTable: SCRATCH_PAD3 value = 0x%x\n", ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_3)));
3522 #endif
3523 
3524     smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "m7");
3525     return AGSA_RC_FAILURE;
3526   }
3527 
3528   smTraceFuncExit(hpDBG_VERY_LOUD, 'c', "m7");
3529   return AGSA_RC_SUCCESS;
3530 }
3531 
3532 /*******************************************************************************/
3533 /** \fn void mpiUpdateIBQueueCfgTable(agsaRoot_t *agRoot, spc_inboundQueueDescriptor_t *outQueueCfg,
3534  *                               bit32 QueueTableOffset,bit8 pcibar)
3535  *  \brief Writing to the inbound queue of the Configuration Table
3536  *  \param agsaRoot Pointer to a data structure containing both application and LL layer context handles
3537  *  \param outQueueCfg      Pointer to inbuond configuration area
3538  *  \param QueueTableOffset Queue configuration table offset
3539  *  \param pcibar           PCI BAR
3540  *
3541  * Return:
3542  *         None
3543  */
3544 /*******************************************************************************/
3545 GLOBAL void mpiUpdateIBQueueCfgTable(agsaRoot_t             *agRoot,
3546                               spc_inboundQueueDescriptor_t  *inQueueCfg,
3547                               bit32                         QueueTableOffset,
3548                               bit8                          pcibar)
3549 {
3550   smTraceFuncEnter(hpDBG_VERY_LOUD,"m5");
3551 
3552   smTrace(hpDBG_VERY_LOUD,"Ba",QueueTableOffset);
3553   /* TP:Ba QueueTableOffset */
3554   smTrace(hpDBG_VERY_LOUD,"Bb",pcibar);
3555   /* TP:Bb pcibar */
3556 
3557   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + IB_PROPERITY_OFFSET), inQueueCfg->elementPriSizeCount);
3558   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + IB_BASE_ADDR_HI_OFFSET), inQueueCfg->upperBaseAddress);
3559   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + IB_BASE_ADDR_LO_OFFSET), inQueueCfg->lowerBaseAddress);
3560   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + IB_CI_BASE_ADDR_HI_OFFSET), inQueueCfg->ciUpperBaseAddress);
3561   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + IB_CI_BASE_ADDR_LO_OFFSET), inQueueCfg->ciLowerBaseAddress);
3562 
3563 
3564   SA_DBG3(("mpiUpdateIBQueueCfgTable: Offset 0x%08x elementPriSizeCount 0x%x\n",(bit32)(QueueTableOffset + IB_PROPERITY_OFFSET), inQueueCfg->elementPriSizeCount));
3565   SA_DBG3(("mpiUpdateIBQueueCfgTable: Offset 0x%08x upperBaseAddress    0x%x\n",(bit32)(QueueTableOffset + IB_BASE_ADDR_HI_OFFSET), inQueueCfg->upperBaseAddress));
3566   SA_DBG3(("mpiUpdateIBQueueCfgTable: Offset 0x%08x lowerBaseAddress    0x%x\n",(bit32)(QueueTableOffset + IB_BASE_ADDR_LO_OFFSET), inQueueCfg->lowerBaseAddress));
3567   SA_DBG3(("mpiUpdateIBQueueCfgTable: Offset 0x%08x ciUpperBaseAddress  0x%x\n",(bit32)(QueueTableOffset + IB_CI_BASE_ADDR_HI_OFFSET), inQueueCfg->ciUpperBaseAddress));
3568   SA_DBG3(("mpiUpdateIBQueueCfgTable: Offset 0x%08x ciLowerBaseAddress  0x%x\n",(bit32)(QueueTableOffset + IB_CI_BASE_ADDR_LO_OFFSET), inQueueCfg->ciLowerBaseAddress));
3569 
3570   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m5");
3571 }
3572 
3573 /*******************************************************************************/
3574 /** \fn void mpiUpdateOBQueueCfgTable(agsaRoot_t *agRoot, spc_outboundQueueDescriptor_t *outQueueCfg,
3575  *                               bit32 QueueTableOffset,bit8 pcibar)
3576  *  \brief Writing to the inbound queue of the Configuration Table
3577  *  \param agsaRoot         Pointer to a data structure containing both application
3578  *                          and LL layer context handles
3579  *  \param outQueueCfg      Pointer to outbuond configuration area
3580  *  \param QueueTableOffset Queue configuration table offset
3581  *  \param pcibar           PCI BAR
3582  *
3583  * Return:
3584  *         None
3585  */
3586 /*******************************************************************************/
3587 GLOBAL void mpiUpdateOBQueueCfgTable(agsaRoot_t             *agRoot,
3588                               spc_outboundQueueDescriptor_t *outQueueCfg,
3589                               bit32                         QueueTableOffset,
3590                               bit8                          pcibar)
3591 {
3592 
3593   smTraceFuncEnter(hpDBG_VERY_LOUD,"m8");
3594 
3595   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + OB_PROPERITY_OFFSET), outQueueCfg->elementSizeCount);
3596   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + OB_BASE_ADDR_HI_OFFSET), outQueueCfg->upperBaseAddress);
3597   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + OB_BASE_ADDR_LO_OFFSET), outQueueCfg->lowerBaseAddress);
3598   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + OB_PI_BASE_ADDR_HI_OFFSET), outQueueCfg->piUpperBaseAddress);
3599   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + OB_PI_BASE_ADDR_LO_OFFSET), outQueueCfg->piLowerBaseAddress);
3600   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(QueueTableOffset + OB_INTERRUPT_COALES_OFFSET), outQueueCfg->interruptVecCntDelay);
3601 
3602   SA_DBG3(("mpiUpdateOBQueueCfgTable: Offset 0x%08x elementSizeCount     0x%x\n",(bit32)(QueueTableOffset + OB_PROPERITY_OFFSET), outQueueCfg->elementSizeCount));
3603   SA_DBG3(("mpiUpdateOBQueueCfgTable: Offset 0x%08x upperBaseAddress     0x%x\n",(bit32)(QueueTableOffset + OB_BASE_ADDR_HI_OFFSET), outQueueCfg->upperBaseAddress));
3604   SA_DBG3(("mpiUpdateOBQueueCfgTable: Offset 0x%08x lowerBaseAddress     0x%x\n",(bit32)(QueueTableOffset + OB_BASE_ADDR_LO_OFFSET), outQueueCfg->lowerBaseAddress));
3605   SA_DBG3(("mpiUpdateOBQueueCfgTable: Offset 0x%08x piUpperBaseAddress   0x%x\n",(bit32)(QueueTableOffset + OB_PI_BASE_ADDR_HI_OFFSET), outQueueCfg->piUpperBaseAddress));
3606   SA_DBG3(("mpiUpdateOBQueueCfgTable: Offset 0x%08x piLowerBaseAddress   0x%x\n",(bit32)(QueueTableOffset + OB_PI_BASE_ADDR_LO_OFFSET), outQueueCfg->piLowerBaseAddress));
3607   SA_DBG3(("mpiUpdateOBQueueCfgTable: Offset 0x%08x interruptVecCntDelay 0x%x\n",(bit32)(QueueTableOffset + OB_INTERRUPT_COALES_OFFSET), outQueueCfg->interruptVecCntDelay));
3608   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m8");
3609 }
3610 
3611 
3612 
3613 /*******************************************************************************/
3614 /** \fn void mpiUpdateOBQueueCfgTable(agsaRoot_t *agRoot, spc_outboundQueueDescriptor_t *outQueueCfg,
3615  *                               bit32 QueueTableOffset,bit8 pcibar)
3616  *  \brief Writing to the inbound queue of the Configuration Table
3617  *  \param agsaRoot         Pointer to a data structure containing both application
3618  *                          and LL layer context handles
3619  *  \param outQueueCfg      Pointer to outbuond configuration area
3620  *  \param QueueTableOffset Queue configuration table offset
3621  *  \param pcibar           PCI BAR
3622  *
3623  * Return:
3624  *         None
3625  */
3626 /*******************************************************************************/
3627 GLOBAL void mpiUpdateFatalErrorTable(agsaRoot_t             *agRoot,
3628                               bit32                         FerrTableOffset,
3629                               bit32                         lowerBaseAddress,
3630                               bit32                         upperBaseAddress,
3631                               bit32                         length,
3632                               bit8                          pcibar)
3633 {
3634 
3635   smTraceFuncEnter(hpDBG_VERY_LOUD,"2U");
3636 
3637   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(FerrTableOffset + MPI_FATAL_EDUMP_TABLE_LO_OFFSET), lowerBaseAddress);
3638   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(FerrTableOffset + MPI_FATAL_EDUMP_TABLE_HI_OFFSET), upperBaseAddress);
3639   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(FerrTableOffset + MPI_FATAL_EDUMP_TABLE_LENGTH), length);
3640   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(FerrTableOffset + MPI_FATAL_EDUMP_TABLE_HANDSHAKE), 0);
3641   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(FerrTableOffset + MPI_FATAL_EDUMP_TABLE_STATUS), 0);
3642 
3643 
3644   SA_DBG3(("mpiUpdateFatalErrorTable: Offset 0x%08x  MPI_FATAL_EDUMP_TABLE_LO_OFFSET 0x%x\n",FerrTableOffset + MPI_FATAL_EDUMP_TABLE_LO_OFFSET, lowerBaseAddress));
3645   SA_DBG3(("mpiUpdateFatalErrorTable: Offset 0x%08x  MPI_FATAL_EDUMP_TABLE_HI_OFFSET 0x%x\n",FerrTableOffset + MPI_FATAL_EDUMP_TABLE_HI_OFFSET,upperBaseAddress ));
3646   SA_DBG3(("mpiUpdateFatalErrorTable: Offset 0x%08x  MPI_FATAL_EDUMP_TABLE_LENGTH    0x%x\n",FerrTableOffset + MPI_FATAL_EDUMP_TABLE_LENGTH, length));
3647   SA_DBG3(("mpiUpdateFatalErrorTable: Offset 0x%08x  MPI_FATAL_EDUMP_TABLE_HANDSHAKE 0x%x\n",FerrTableOffset + MPI_FATAL_EDUMP_TABLE_HANDSHAKE,0 ));
3648   SA_DBG3(("mpiUpdateFatalErrorTable: Offset 0x%08x  MPI_FATAL_EDUMP_TABLE_STATUS    0x%x\n",FerrTableOffset + MPI_FATAL_EDUMP_TABLE_STATUS,0 ));
3649   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "2U");
3650 }
3651 
3652 
3653 /*******************************************************************************/
3654 /** \fn bit32 mpiGetPCIBarIndex(agsaRoot_t *agRoot, pciBar)
3655  *  \brief Get PCI BAR Index from PCI BAR
3656  *  \param agsaRoot Pointer to a data structure containing both application and LL layer context handles
3657  *  \param pciBar - PCI BAR
3658  *
3659  * Return:
3660  *         PCI BAR Index
3661  */
3662 /*******************************************************************************/
3663 GLOBAL bit32 mpiGetPCIBarIndex(agsaRoot_t *agRoot, bit32 pciBar)
3664 {
3665   switch(pciBar)
3666   {
3667   case BAR0:
3668   case BAR1:
3669       pciBar = PCIBAR0;
3670       break;
3671   case BAR2:
3672   case BAR3:
3673       pciBar = PCIBAR1;
3674       break;
3675   case BAR4:
3676       pciBar = PCIBAR2;
3677       break;
3678   case BAR5:
3679       pciBar = PCIBAR3;
3680       break;
3681   default:
3682       pciBar = PCIBAR0;
3683       break;
3684   }
3685 
3686   return pciBar;
3687 }
3688 
3689 /*******************************************************************************/
3690 /** \fn void mpiReadGSTTable(agsaRoot_t *agRoot, spc_GSTableDescriptor_t *mpiGSTable)
3691  *  \brief Reading the General Status Table
3692  *
3693  *  \param agsaRoot         Handles for this instance of SAS/SATA LLL
3694  *  \param mpiGSTable       Pointer of General Status Table
3695  *
3696  * Return:
3697  *         None
3698  */
3699 /*******************************************************************************/
3700 GLOBAL void mpiReadGSTable(agsaRoot_t             *agRoot,
3701                          spc_GSTableDescriptor_t  *mpiGSTable)
3702 {
3703   bit32 CFGTableOffset, TableOffset;
3704   bit32 GSTableOffset;
3705   bit8  i, pcibar;
3706 
3707   smTraceFuncEnter(hpDBG_VERY_LOUD,"m9");
3708 
3709   /* get offset of the configuration table */
3710   TableOffset = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
3711 
3712   if(0xFFFFFFFF ==  TableOffset)
3713   {
3714     SA_ASSERT(0xFFFFFFFF ==  TableOffset, "Chip PCI dead");
3715 
3716     SA_DBG1(("mpiReadGSTable: Chip PCI dead  TableOffset 0x%x\n", TableOffset));
3717     return;
3718   }
3719 
3720 //  SA_DBG1(("mpiReadGSTable: TableOffset 0x%x\n", TableOffset));
3721   CFGTableOffset = TableOffset & SCRATCH_PAD0_OFFSET_MASK;
3722 
3723   /* get PCI BAR */
3724   TableOffset = (TableOffset & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
3725   /* convert the PCI BAR to logical bar number */
3726   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, TableOffset);
3727 
3728   /* read GST Table Offset from the configuration table */
3729   GSTableOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CFGTableOffset + MAIN_GST_OFFSET);
3730 //  SA_DBG1(("mpiReadGSTable: GSTableOffset 0x%x\n",GSTableOffset ));
3731 
3732   GSTableOffset = CFGTableOffset + GSTableOffset;
3733 
3734   mpiGSTable->GSTLenMPIS = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_GSTLEN_MPIS_OFFSET));
3735   mpiGSTable->IQFreezeState0 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_IQ_FREEZE_STATE0_OFFSET));
3736   mpiGSTable->IQFreezeState1 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_IQ_FREEZE_STATE1_OFFSET));
3737   mpiGSTable->MsguTcnt       = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_MSGUTCNT_OFFSET));
3738   mpiGSTable->IopTcnt        = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_IOPTCNT_OFFSET));
3739   mpiGSTable->Iop1Tcnt       = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_IOP1TCNT_OFFSET));
3740 
3741   SA_DBG4(("mpiReadGSTable: GSTLenMPIS     0x%x\n", mpiGSTable->GSTLenMPIS));
3742   SA_DBG4(("mpiReadGSTable: GSTLen         0x%x\n", (mpiGSTable->GSTLenMPIS & 0xfff8) >> SHIFT3));
3743   SA_DBG4(("mpiReadGSTable: IQFreezeState0 0x%x\n", mpiGSTable->IQFreezeState0));
3744   SA_DBG4(("mpiReadGSTable: IQFreezeState1 0x%x\n", mpiGSTable->IQFreezeState1));
3745   SA_DBG4(("mpiReadGSTable: MsguTcnt       0x%x\n", mpiGSTable->MsguTcnt));
3746   SA_DBG4(("mpiReadGSTable: IopTcnt        0x%x\n", mpiGSTable->IopTcnt));
3747   SA_DBG4(("mpiReadGSTable: Iop1Tcnt       0x%x\n", mpiGSTable->Iop1Tcnt));
3748 
3749 
3750   if(smIS_SPCV(agRoot))
3751   {
3752     /***** read Phy State from SAS Phy Attribute Table */
3753     TableOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CFGTableOffset + MAIN_PHY_ATTRIBUTE_OFFSET);
3754     TableOffset &= 0x00FFFFFF;
3755     TableOffset = TableOffset + CFGTableOffset;
3756     for (i = 0; i < 8; i++)
3757     {
3758       mpiGSTable->PhyState[i] = ossaHwRegReadExt(agRoot, pcibar, (bit32)(TableOffset + i * sizeof(phyAttrb_t)));
3759       SA_DBG4(("mpiReadGSTable: PhyState[0x%x] 0x%x\n", i, mpiGSTable->PhyState[i]));
3760     }
3761   }
3762   else
3763   {
3764     for (i = 0; i < 8; i++)
3765     {
3766       mpiGSTable->PhyState[i] = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_PHYSTATE_OFFSET + i * 4));
3767       SA_DBG4(("mpiReadGSTable: PhyState[0x%x] 0x%x\n", i, mpiGSTable->PhyState[i]));
3768     }
3769   }
3770 
3771   mpiGSTable->GPIOpins = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_GPIO_PINS_OFFSET));
3772   SA_DBG4(("mpiReadGSTable: GPIOpins 0x%x\n", mpiGSTable->GPIOpins));
3773 
3774   for (i = 0; i < 8; i++)
3775   {
3776     mpiGSTable->recoverErrInfo[i] = ossaHwRegReadExt(agRoot, pcibar, (bit32)(GSTableOffset + GST_RERRINFO_OFFSET));
3777     SA_DBG4(("mpiReadGSTable: recoverErrInfo[0x%x] 0x%x\n", i, mpiGSTable->recoverErrInfo[i]));
3778   }
3779 
3780   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m9");
3781 
3782 }
3783 
3784 /*******************************************************************************/
3785 /** \fn void siInitResources(agsaRoot_t *agRoot)
3786  *  Initialization of LL resources
3787  *
3788  *  \param agsaRoot         Handles for this instance of SAS/SATA LLL
3789  *  \param memoryAllocated  Point to the data structure that holds the different
3790  *                          chunks of memory that are required
3791  *
3792  * Return:
3793  *         None
3794  */
3795 /*******************************************************************************/
3796 GLOBAL void siInitResources(agsaRoot_t              *agRoot,
3797                             agsaMemoryRequirement_t *memoryAllocated,
3798                             agsaHwConfig_t          *hwConfig,
3799                             agsaSwConfig_t          *swConfig,
3800                             bit32                   usecsPerTick)
3801 {
3802   agsaLLRoot_t          *saRoot;
3803   agsaDeviceDesc_t      *pDeviceDesc;
3804   agsaIORequestDesc_t   *pRequestDesc;
3805   agsaTimerDesc_t       *pTimerDesc;
3806   agsaPort_t            *pPort;
3807   agsaPortMap_t         *pPortMap;
3808   agsaDeviceMap_t       *pDeviceMap;
3809   agsaIOMap_t           *pIOMap;
3810   bit32                 maxNumIODevices;
3811   bit32                 i, j;
3812   mpiICQueue_t          *circularIQ;
3813   mpiOCQueue_t          *circularOQ;
3814 
3815   if (agNULL == agRoot)
3816   {
3817     return;
3818   }
3819 
3820   /* Get the saRoot memory address */
3821   saRoot = (agsaLLRoot_t *) (memoryAllocated->agMemory[LLROOT_MEM_INDEX].virtPtr);
3822   agRoot->sdkData = (void *) saRoot;
3823 
3824   /* Setup Device link */
3825   /* Save the information of allocated device Link memory */
3826   saRoot->deviceLinkMem = memoryAllocated->agMemory[DEVICELINK_MEM_INDEX];
3827   si_memset(saRoot->deviceLinkMem.virtPtr, 0, saRoot->deviceLinkMem.totalLength);
3828   SA_DBG2(("siInitResources: [%d] saRoot->deviceLinkMem VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n" ,
3829     DEVICELINK_MEM_INDEX,
3830     saRoot->deviceLinkMem.virtPtr,
3831     saRoot->deviceLinkMem.phyAddrLower,
3832     saRoot->deviceLinkMem.numElements,
3833     saRoot->deviceLinkMem.totalLength,
3834     saRoot->deviceLinkMem.type));
3835 
3836   maxNumIODevices = swConfig->numDevHandles;
3837   SA_DBG2(("siInitResources:  maxNumIODevices=%d, swConfig->numDevHandles=%d \n",
3838     maxNumIODevices,
3839     swConfig->numDevHandles));
3840 
3841   /* Setup free IO Devices link list */
3842   saLlistInitialize(&(saRoot->freeDevicesList));
3843   for ( i = 0; i < (bit32) maxNumIODevices; i ++ )
3844   {
3845     /* get the pointer to the device descriptor */
3846     pDeviceDesc = (agsaDeviceDesc_t *) AGSAMEM_ELEMENT_READ(&(saRoot->deviceLinkMem), i);
3847     /* Initialize device descriptor */
3848     saLlinkInitialize(&(pDeviceDesc->linkNode));
3849 
3850     pDeviceDesc->initiatorDevHandle.osData    = agNULL;
3851     pDeviceDesc->initiatorDevHandle.sdkData   = agNULL;
3852     pDeviceDesc->targetDevHandle.osData       = agNULL;
3853     pDeviceDesc->targetDevHandle.sdkData      = agNULL;
3854     pDeviceDesc->deviceType                   = SAS_SATA_UNKNOWN_DEVICE;
3855     pDeviceDesc->pPort                        = agNULL;
3856     pDeviceDesc->DeviceMapIndex               = 0;
3857 
3858     saLlistInitialize(&(pDeviceDesc->pendingIORequests));
3859 
3860     /* Add the device descriptor to the free IO device link list */
3861     saLlistAdd(&(saRoot->freeDevicesList), &(pDeviceDesc->linkNode));
3862   }
3863 
3864   /* Setup IO Request link */
3865   /* Save the information of allocated IO Request Link memory */
3866   saRoot->IORequestMem = memoryAllocated->agMemory[IOREQLINK_MEM_INDEX];
3867   si_memset(saRoot->IORequestMem.virtPtr, 0, saRoot->IORequestMem.totalLength);
3868 
3869   SA_DBG2(("siInitResources: [%d] saRoot->IORequestMem  VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n",
3870     IOREQLINK_MEM_INDEX,
3871     saRoot->IORequestMem.virtPtr,
3872     saRoot->IORequestMem.phyAddrLower,
3873     saRoot->IORequestMem.numElements,
3874     saRoot->IORequestMem.totalLength,
3875     saRoot->IORequestMem.type));
3876 
3877   /* Setup free IO  Request link list */
3878   saLlistIOInitialize(&(saRoot->freeIORequests));
3879   saLlistIOInitialize(&(saRoot->freeReservedRequests));
3880   for ( i = 0; i < swConfig->maxActiveIOs; i ++ )
3881   {
3882     /* get the pointer to the request descriptor */
3883     pRequestDesc = (agsaIORequestDesc_t *) AGSAMEM_ELEMENT_READ(&(saRoot->IORequestMem), i);
3884     /* Initialize request descriptor */
3885     saLlinkIOInitialize(&(pRequestDesc->linkNode));
3886 
3887     pRequestDesc->valid             = agFALSE;
3888     pRequestDesc->requestType       = AGSA_REQ_TYPE_UNKNOWN;
3889     pRequestDesc->pIORequestContext = agNULL;
3890     pRequestDesc->HTag              = i;
3891     pRequestDesc->pDevice           = agNULL;
3892     pRequestDesc->pPort             = agNULL;
3893 
3894     /* Add the request descriptor to the free IO Request link list */
3895     /* Add the request descriptor to the free Reserved Request link list */
3896   /* SMP request must get service so reserve one request when first SMP completes */
3897     if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
3898     {
3899       saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequestDesc->linkNode));
3900     }
3901     else
3902     {
3903       saLlistIOAdd(&(saRoot->freeIORequests), &(pRequestDesc->linkNode));
3904     }
3905   }
3906 
3907 
3908   /* Setup timer link */
3909   /* Save the information of allocated timer Link memory */
3910   saRoot->timerLinkMem = memoryAllocated->agMemory[TIMERLINK_MEM_INDEX];
3911   si_memset(saRoot->timerLinkMem.virtPtr, 0, saRoot->timerLinkMem.totalLength);
3912   SA_DBG2(("siInitResources: [%d] saRoot->timerLinkMem  VirtPtr=%p PhysicalLo=%x Count=%x Total=%x type %x\n",
3913     TIMERLINK_MEM_INDEX,
3914     saRoot->timerLinkMem.virtPtr,
3915     saRoot->timerLinkMem.phyAddrLower,
3916     saRoot->timerLinkMem.numElements,
3917     saRoot->timerLinkMem.totalLength,
3918     saRoot->timerLinkMem.type));
3919 
3920   /* Setup free timer link list */
3921   saLlistInitialize(&(saRoot->freeTimers));
3922   for ( i = 0; i < NUM_TIMERS; i ++ )
3923   {
3924     /* get the pointer to the timer descriptor */
3925     pTimerDesc = (agsaTimerDesc_t *) AGSAMEM_ELEMENT_READ(&(saRoot->timerLinkMem), i);
3926     /* Initialize timer descriptor */
3927     saLlinkInitialize(&(pTimerDesc->linkNode));
3928 
3929     pTimerDesc->valid         = agFALSE;
3930     pTimerDesc->timeoutTick   = 0;
3931     pTimerDesc->pfnTimeout    = agNULL;
3932     pTimerDesc->Event         = 0;
3933     pTimerDesc->pParm         = agNULL;
3934 
3935     /* Add the timer descriptor to the free timer link list */
3936     saLlistAdd(&(saRoot->freeTimers), &(pTimerDesc->linkNode));
3937   }
3938   /* Setup valid timer link list */
3939   saLlistInitialize(&(saRoot->validTimers));
3940 
3941   /* Setup Phys */
3942   /* Setup PhyCount */
3943   saRoot->phyCount = (bit8) hwConfig->phyCount;
3944   /* Init Phy data structure */
3945   for ( i = 0; i < saRoot->phyCount; i ++ )
3946   {
3947     saRoot->phys[i].pPort = agNULL;
3948     saRoot->phys[i].phyId = (bit8) i;
3949 
3950     /* setup phy status is PHY_STOPPED */
3951     PHY_STATUS_SET(&(saRoot->phys[i]), PHY_STOPPED);
3952   }
3953 
3954   /* Setup Ports */
3955   /* Setup PortCount */
3956   saRoot->portCount = saRoot->phyCount;
3957   /* Setup free port link list */
3958   saLlistInitialize(&(saRoot->freePorts));
3959   for ( i = 0; i < saRoot->portCount; i ++ )
3960   {
3961     /* get the pointer to the port */
3962     pPort = &(saRoot->ports[i]);
3963     /* Initialize port */
3964     saLlinkInitialize(&(pPort->linkNode));
3965 
3966     pPort->portContext.osData   = agNULL;
3967     pPort->portContext.sdkData  = pPort;
3968     pPort->portId         = 0;
3969     pPort->portIdx        = (bit8) i;
3970     pPort->status         = PORT_NORMAL;
3971 
3972     for ( j = 0; j < saRoot->phyCount; j ++ )
3973     {
3974       pPort->phyMap[j] = agFALSE;
3975     }
3976 
3977     saLlistInitialize(&(pPort->listSASATADevices));
3978 
3979     /* Add the port to the free port link list */
3980     saLlistAdd(&(saRoot->freePorts), &(pPort->linkNode));
3981   }
3982   /* Setup valid port link list */
3983   saLlistInitialize(&(saRoot->validPorts));
3984 
3985   /* Init sysIntsActive */
3986   saRoot->sysIntsActive = agFALSE;
3987 
3988   /* setup timer tick granunarity */
3989   saRoot->usecsPerTick = usecsPerTick;
3990 
3991   /* initialize LL timer tick */
3992   saRoot->timeTick = 0;
3993 
3994   /* initialize device (de)registration callback fns */
3995   saRoot->DeviceRegistrationCB = agNULL;
3996   saRoot->DeviceDeregistrationCB = agNULL;
3997 
3998   /* Initialize the PortMap for port context */
3999   for ( i = 0; i < saRoot->portCount; i ++ )
4000   {
4001     pPortMap = &(saRoot->PortMap[i]);
4002 
4003     pPortMap->PortContext   = agNULL;
4004     pPortMap->PortID        = PORT_MARK_OFF;
4005     pPortMap->PortStatus    = PORT_NORMAL;
4006     saRoot->autoDeregDeviceflag[i] = 0;
4007   }
4008 
4009   /* Initialize the DeviceMap for device handle */
4010   for ( i = 0; i < MAX_IO_DEVICE_ENTRIES; i ++ )
4011   {
4012     pDeviceMap = &(saRoot->DeviceMap[i]);
4013 
4014     pDeviceMap->DeviceHandle  = agNULL;
4015     pDeviceMap->DeviceIdFromFW   =  i;
4016   }
4017 
4018   /* Initialize the IOMap for IOrequest */
4019   for ( i = 0; i < MAX_ACTIVE_IO_REQUESTS; i ++ )
4020   {
4021     pIOMap = &(saRoot->IOMap[i]);
4022 
4023     pIOMap->IORequest   = agNULL;
4024     pIOMap->Tag         = MARK_OFF;
4025   }
4026 
4027   /* clean the inbound queues */
4028   for (i = 0; i < saRoot->QueueConfig.numInboundQueues; i ++)
4029   {
4030     if(0 != saRoot->inboundQueue[i].numElements)
4031     {
4032       circularIQ = &saRoot->inboundQueue[i];
4033       si_memset(circularIQ->memoryRegion.virtPtr, 0, circularIQ->memoryRegion.totalLength);
4034       si_memset(saRoot->inboundQueue[i].ciPointer, 0, sizeof(bit32));
4035     }
4036   }
4037   /* clean the outbound queues */
4038   for (i = 0; i < saRoot->QueueConfig.numOutboundQueues; i ++)
4039   {
4040     if(0 != saRoot->outboundQueue[i].numElements)
4041     {
4042       circularOQ = &saRoot->outboundQueue[i];
4043       si_memset(circularOQ->memoryRegion.virtPtr, 0, circularOQ->memoryRegion.totalLength);
4044       si_memset(saRoot->outboundQueue[i].piPointer, 0, sizeof(bit32));
4045       circularOQ->producerIdx = 0;
4046       circularOQ->consumerIdx = 0;
4047       SA_DBG3(("siInitResource: Q %d  Clean PI 0x%03x CI 0x%03x\n", i,circularOQ->producerIdx, circularOQ->consumerIdx));
4048     }
4049   }
4050 
4051   return;
4052 }
4053 
4054 /*******************************************************************************/
4055 /** \fn void mpiReadCALTable(agsaRoot_t *agRoot,
4056  *                           spc_SPASTable_t *mpiCALTable, bit32 index)
4057  *  \brief Reading the Phy Analog Setup Register Table
4058  *  \param agsaRoot    Handles for this instance of SAS/SATA LLL
4059  *  \param mpiCALTable Pointer of Phy Calibration Table
4060  *
4061  * Return:
4062  *         None
4063  */
4064 /*******************************************************************************/
4065 GLOBAL void mpiReadCALTable(agsaRoot_t      *agRoot,
4066                             spc_SPASTable_t *mpiCALTable,
4067                             bit32           index)
4068 {
4069   bit32 CFGTableOffset, TableOffset;
4070   bit32 CALTableOffset;
4071   bit8  pcibar;
4072 
4073   /* get offset of the configuration table */
4074   TableOffset = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
4075 
4076   CFGTableOffset = TableOffset & SCRATCH_PAD0_OFFSET_MASK;
4077 
4078   /* get PCI BAR */
4079   TableOffset = (TableOffset & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
4080   /* convert the PCI BAR to logical bar number */
4081   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, TableOffset);
4082 
4083   /* read Calibration Table Offset from the configuration table */
4084   CALTableOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CFGTableOffset + MAIN_ANALOG_SETUP_OFFSET);
4085   if(smIS_SPCV(agRoot))
4086   {
4087     CALTableOffset &= 0x00FFFFFF;
4088   }
4089   CALTableOffset = CFGTableOffset + CALTableOffset + (index * ANALOG_SETUP_ENTRY_SIZE * 4);
4090 
4091   mpiCALTable->spaReg0 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_PORT_CFG1_OFFSET));
4092   mpiCALTable->spaReg1 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_PORT_CFG2_OFFSET));
4093   mpiCALTable->spaReg2 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_PORT_CFG3_OFFSET));
4094   mpiCALTable->spaReg3 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_CFG_OFFSET));
4095   mpiCALTable->spaReg4 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_PORT_CFG1_OFFSET));
4096   mpiCALTable->spaReg5 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_PORT_CFG2_OFFSET));
4097   mpiCALTable->spaReg6 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_CFG1_OFFSET));
4098   mpiCALTable->spaReg7 = ossaHwRegReadExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_CFG2_OFFSET));
4099 
4100   SA_DBG3(("mpiReadCALTable: spaReg0 0x%x\n", mpiCALTable->spaReg0));
4101   SA_DBG3(("mpiReadCALTable: spaReg1 0x%x\n", mpiCALTable->spaReg1));
4102   SA_DBG3(("mpiReadCALTable: spaReg2 0x%x\n", mpiCALTable->spaReg2));
4103   SA_DBG3(("mpiReadCALTable: spaReg3 0x%x\n", mpiCALTable->spaReg3));
4104   SA_DBG3(("mpiReadCALTable: spaReg4 0x%x\n", mpiCALTable->spaReg4));
4105   SA_DBG3(("mpiReadCALTable: spaReg5 0x%x\n", mpiCALTable->spaReg5));
4106   SA_DBG3(("mpiReadCALTable: spaReg6 0x%x\n", mpiCALTable->spaReg6));
4107   SA_DBG3(("mpiReadCALTable: spaReg7 0x%x\n", mpiCALTable->spaReg7));
4108 }
4109 
4110 /*******************************************************************************/
4111 /** \fn void mpiWriteCALTable(agsaRoot_t *agRoot,
4112  *                            spc_SPASTable_t *mpiCALTable, index)
4113  *  \brief Writing the Phy Analog Setup Register Table
4114  *  \param agsaRoot    Handles for this instance of SAS/SATA LLL
4115  *  \param mpiCALTable Pointer of Phy Calibration Table
4116  *
4117  * Return:
4118  *         None
4119  */
4120 /*******************************************************************************/
4121 GLOBAL void mpiWriteCALTable(agsaRoot_t     *agRoot,
4122                             spc_SPASTable_t *mpiCALTable,
4123                             bit32           index)
4124 {
4125   bit32 CFGTableOffset, TableOffset;
4126   bit32 CALTableOffset;
4127   bit8  pcibar;
4128 
4129   smTraceFuncEnter(hpDBG_VERY_LOUD,"m6");
4130 
4131   /* get offset of the configuration table */
4132   TableOffset = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
4133 
4134   CFGTableOffset = TableOffset & SCRATCH_PAD0_OFFSET_MASK;
4135 
4136   /* get PCI BAR */
4137   TableOffset = (TableOffset & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
4138   /* convert the PCI BAR to logical bar number */
4139   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, TableOffset);
4140 
4141   /* read Calibration Table Offset from the configuration table */
4142   CALTableOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CFGTableOffset + MAIN_ANALOG_SETUP_OFFSET);
4143   if(smIS_SPCV(agRoot))
4144   {
4145     CALTableOffset &= 0x00FFFFFF;
4146   }
4147   CALTableOffset = CFGTableOffset + CALTableOffset + (index * ANALOG_SETUP_ENTRY_SIZE * 4);
4148 
4149   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_PORT_CFG1_OFFSET), mpiCALTable->spaReg0);
4150   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_PORT_CFG2_OFFSET), mpiCALTable->spaReg1);
4151   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_PORT_CFG3_OFFSET), mpiCALTable->spaReg2);
4152   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + TX_CFG_OFFSET),       mpiCALTable->spaReg3);
4153   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_PORT_CFG1_OFFSET), mpiCALTable->spaReg4);
4154   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_PORT_CFG2_OFFSET), mpiCALTable->spaReg5);
4155   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_CFG1_OFFSET),      mpiCALTable->spaReg6);
4156   ossaHwRegWriteExt(agRoot, pcibar, (bit32)(CALTableOffset + RV_CFG2_OFFSET),      mpiCALTable->spaReg7);
4157 
4158   SA_DBG4(("mpiWriteCALTable: Offset 0x%08x  spaReg0 0x%x 0x%x 0x%x 0x%x\n",(bit32)(CALTableOffset + TX_PORT_CFG1_OFFSET), mpiCALTable->spaReg0, mpiCALTable->spaReg1, mpiCALTable->spaReg2, mpiCALTable->spaReg3));
4159   SA_DBG4(("mpiWriteCALTable: Offset 0x%08x  spaReg4 0x%x 0x%x 0x%x 0x%x\n",(bit32)(CALTableOffset + RV_PORT_CFG1_OFFSET), mpiCALTable->spaReg4, mpiCALTable->spaReg5, mpiCALTable->spaReg6, mpiCALTable->spaReg7));
4160 
4161   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "m6");
4162 }
4163 
4164 /*******************************************************************************/
4165 /** \fn void mpiWriteCALAll(agsaRoot_t *agRoot,
4166  *                          agsaPhyAnalogSetupTable_t *mpiCALTable)
4167  *  \brief Writing the Phy Analog Setup Register Table
4168  *  \param agsaRoot    Handles for this instance of SAS/SATA LLL
4169  *  \param mpiCALTable Pointer of Phy Calibration Table
4170  *
4171  * Return:
4172  *         None
4173  */
4174 /*******************************************************************************/
4175 GLOBAL void mpiWriteCALAll(agsaRoot_t     *agRoot,
4176                            agsaPhyAnalogSetupTable_t *mpiCALTable)
4177 {
4178   bit8 i;
4179   smTraceFuncEnter(hpDBG_VERY_LOUD,"mz");
4180 
4181   if(smIS_SPCV(agRoot))
4182   {
4183     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "mz");
4184     return;
4185   }
4186 
4187   for (i = 0; i < MAX_INDEX; i++)
4188   {
4189     mpiWriteCALTable(agRoot, (spc_SPASTable_t *)&mpiCALTable->phyAnalogSetupRegisters[i], i);
4190   }
4191   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "mz");
4192 }
4193 
4194 GLOBAL void mpiWrAnalogSetupTable(agsaRoot_t *agRoot,
4195                                    mpiConfig_t      *config
4196                                  )
4197 {
4198 
4199   bit32 AnalogTableBase,CFGTableOffset, value,phy;
4200   bit32 AnalogtableSize;
4201   bit8  pcibar;
4202   value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
4203   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, value);
4204 
4205   CFGTableOffset = value & SCRATCH_PAD0_OFFSET_MASK;
4206   AnalogtableSize  = AnalogTableBase = ossaHwRegReadExt(agRoot,pcibar , (bit32)CFGTableOffset + MAIN_ANALOG_SETUP_OFFSET);
4207   AnalogtableSize &= 0xFF000000;
4208   AnalogtableSize >>= SHIFT24;
4209   AnalogTableBase &= 0x00FFFFFF;
4210 
4211   AnalogTableBase = CFGTableOffset + AnalogTableBase;
4212 
4213 //   config->phyAnalogConfig.phyAnalogSetupRegisters[0].spaRegister0 = 0;
4214   SA_DBG1(("mpiWrAnalogSetupTable:Analogtable Base Offset %08X pcibar %d\n",AnalogTableBase, pcibar ));
4215 
4216   SA_DBG1(("mpiWrAnalogSetupTable:%d %d\n",(int)sizeof(agsaPhyAnalogSetupRegisters_t), AnalogtableSize));
4217 
4218   for(phy = 0; phy < 10; phy++) /* upto 10 phys See PM*/
4219   {
4220       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 0 ),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister0 );
4221       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 4 ),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister1 );
4222       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 8 ),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister2 );
4223       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 12),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister3 );
4224       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 16),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister4 );
4225       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 20),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister5 );
4226       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 24),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister6 );
4227       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 28),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister7 );
4228       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 32),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister8 );
4229       ossaHwRegWriteExt(agRoot, pcibar,(AnalogTableBase + ( AnalogtableSize * phy)+ 36),config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister9 );
4230 
4231       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister0 0x%x 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) + 0,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister0 ,ossaHwRegReadExt(agRoot, pcibar,AnalogTableBase + ( AnalogtableSize * phy)+ 0 )));
4232       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister1 0x%x 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) + 4,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister1 ,ossaHwRegReadExt(agRoot, pcibar,AnalogTableBase + ( AnalogtableSize * phy)+ 4 )));
4233       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister2 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) + 8,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister2 ));
4234       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister3 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +12,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister3 ));
4235       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister4 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +16,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister4 ));
4236       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister5 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +20,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister5 ));
4237       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister6 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +24,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister6 ));
4238       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister7 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +28,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister7 ));
4239       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister8 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +32,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister8 ));
4240       SA_DBG4(("mpiWrAnalogSetupTable:phy %d Offset 0x%08x spaRegister9 0x%x\n",phy, (bit32) AnalogTableBase+ (AnalogtableSize * phy) +36,config->phyAnalogConfig.phyAnalogSetupRegisters[phy].spaRegister9 ));
4241   }
4242 
4243 }
4244 
4245 
4246 GLOBAL void mpiWrIntVecTable(agsaRoot_t *agRoot,
4247                             mpiConfig_t* config
4248                             )
4249 {
4250   bit32 CFGTableOffset, value;
4251   bit32 INTVTableOffset;
4252   bit32 ValuetoWrite;
4253   bit8  pcibar, i,obq;
4254 
4255   /* get offset of the configuration table */
4256   value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
4257 
4258   CFGTableOffset = value & SCRATCH_PAD0_OFFSET_MASK;
4259 
4260   /* get PCI BAR */
4261   value = (value & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
4262   /* convert the PCI BAR to logical bar number */
4263   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, value);
4264 
4265   /* read Interrupt Table Offset from the main configuration table */
4266   INTVTableOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CFGTableOffset + MAIN_INT_VEC_TABLE_OFFSET);
4267   INTVTableOffset &= 0x00FFFFFF;
4268   INTVTableOffset = CFGTableOffset + INTVTableOffset;
4269   SA_DBG1(("mpiWrIntVecTable: Base Offset %08X\n",(bit32)(INTVTableOffset + INT_VT_Coal_CNT_TO ) ));
4270 
4271   for (i = 0; i < MAX_NUM_VECTOR; i ++)
4272   {
4273     bit32 found=0;
4274     for (obq = 0; obq < MAX_NUM_VECTOR; obq++)
4275     { /* find OBQ for  vector i */
4276       if( config->outboundQueues[obq].interruptVector == i )
4277       {
4278         found=1;
4279         break;
4280       }
4281     }
4282 
4283     if(!found )
4284     {
4285       continue;
4286     }
4287 
4288     ValuetoWrite = (( config->outboundQueues[obq].interruptDelay << SHIFT15) | config->outboundQueues[obq].interruptThreshold  );
4289 
4290     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(INTVTableOffset + INT_VT_Coal_CNT_TO + i * sizeof(InterruptVT_t)), ValuetoWrite );
4291 
4292     SA_DBG3(("mpiWrIntVecTable: Q %d interruptDelay 0x%X interruptThreshold 0x%X \n",i,
4293              config->outboundQueues[i].interruptDelay,  config->outboundQueues[i].interruptThreshold ));
4294 
4295     SA_DBG3(("mpiWrIntVecTable: %d INT_VT_Coal_CNT_TO Bar %d Offset %3X Writing 0x%08x\n",i,
4296             pcibar,
4297             (bit32)(INTVTableOffset + INT_VT_Coal_CNT_TO + i * sizeof(InterruptVT_t)),
4298             ValuetoWrite));
4299 
4300   }
4301 
4302   for (i = 0; i < MAX_NUM_VECTOR; i++)
4303   {
4304     /* read interrupt colescing control and timer  */
4305     value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(INTVTableOffset + INT_VT_Coal_CNT_TO + i * sizeof(InterruptVT_t)));
4306     SA_DBG4(("mpiWrIntVecTable: Offset 0x%08x Interrupt Colescing iccict[%02d] 0x%x\n", (bit32)(INTVTableOffset + INT_VT_Coal_CNT_TO + i * sizeof(InterruptVT_t)), i, value));
4307   }
4308 }
4309 
4310 GLOBAL void mpiWrPhyAttrbTable(agsaRoot_t *agRoot, sasPhyAttribute_t *phyAttrib)
4311 {
4312   bit32 CFGTableOffset, value;
4313   bit32 PHYTableOffset;
4314   bit8  pcibar, i;
4315 
4316   /* get offset of the configuration table */
4317   value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0);
4318 
4319   CFGTableOffset = value & SCRATCH_PAD0_OFFSET_MASK;
4320 
4321   /* get PCI BAR */
4322   value = (value & SCRATCH_PAD0_BAR_MASK) >> SHIFT26;
4323   /* convert the PCI BAR to logical bar number */
4324   pcibar = (bit8)mpiGetPCIBarIndex(agRoot, value);
4325 
4326   /* read Phy Attribute Table Offset from the configuration table */
4327   PHYTableOffset = ossaHwRegReadExt(agRoot, pcibar, (bit32)CFGTableOffset + MAIN_PHY_ATTRIBUTE_OFFSET);
4328 
4329   PHYTableOffset &=0x00FFFFFF;
4330 
4331   PHYTableOffset = CFGTableOffset + PHYTableOffset + PHY_EVENT_OQ;
4332 
4333   SA_DBG1(("mpiWrPhyAttrbTable: PHYTableOffset 0x%08x\n", PHYTableOffset));
4334 
4335   /* write OQ event per phy */
4336   for (i = 0; i < MAX_VALID_PHYS; i ++)
4337   {
4338     ossaHwRegWriteExt(agRoot, pcibar, (bit32)(PHYTableOffset + i * sizeof(phyAttrb_t)), phyAttrib->phyAttribute[i].phyEventOQ);
4339 
4340   SA_DBG3(("mpiWrPhyAttrbTable:%d Offset 0x%08x phyAttribute 0x%x\n",i,(bit32)(PHYTableOffset + i * sizeof(phyAttrb_t)), phyAttrib->phyAttribute[i].phyEventOQ ));
4341 
4342 
4343   }
4344 
4345   for (i = 0; i < MAX_VALID_PHYS; i ++)
4346   {
4347     value = ossaHwRegReadExt(agRoot, pcibar, (bit32)(PHYTableOffset + i * sizeof(phyAttrb_t)));
4348   SA_DBG1(("mpiWrPhyAttrbTable: OQ Event per phy[%x] 0x%x\n", i, value));
4349   }
4350 }
4351 
4352 
4353 #ifdef TEST /******************************************************************/
4354 /*******************************************************************************/
4355 /** \fn mpiFreezeInboundQueue(agsaRoot_t *agRoot)
4356  *  \brief Freeze the inbound queue
4357  *
4358  *  \param agRoot             Handles for this instance of SAS/SATA hardware
4359  *  \param bitMapQueueNum0    bit map for inbound queue number 0 - 31 to freeze
4360  *  \param bitMapQueueNum1    bit map for inbound queue number 32 - 63 to freeze
4361  *
4362  * Return:
4363  *         AGSA_RC_SUCCESS if Un-initialize the configuration table sucessful
4364  *         AGSA_RC_FAILURE if Un-initialize the configuration table failed
4365  */
4366 /*******************************************************************************/
4367 GLOBAL bit32 mpiFreezeInboundQueue(agsaRoot_t *agRoot, bit32 bitMapQueueNum0, bit32 bitMapQueueNum1)
4368 {
4369   bit32    value, togglevalue;
4370   bit32    max_wait_time;
4371   bit32    max_wait_count;
4372 
4373   SA_DBG2(("Entering function:mpiFreezeInboundQueue\n"));
4374   SA_ASSERT(NULL != agRoot, "agRoot argument cannot be null");
4375 
4376   togglevalue = 0;
4377 
4378   if (bitMapQueueNum0)
4379   {
4380     /* update the inbound queue number to HOST_SCRATCH_PAD1 register for queue 0 to 31 */
4381     SA_DBG1(("mpiFreezeInboundQueue: SCRATCH_PAD0 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_0)));
4382     SA_DBG1(("mpiFreezeInboundQueue: SCRATCH_PAD3 value = 0x%x\n", siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3,MSGU_SCRATCH_PAD_3)));
4383 
4384     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0,MSGU_SCRATCH_PAD_1);
4385     value |= bitMapQueueNum0;
4386     siHalRegWriteExt(agRoot, GEN_MSGU_HOST_SCRATCH_PAD_1, MSGU_HOST_SCRATCH_PAD_1, value);
4387   }
4388 
4389   if (bitMapQueueNum1)
4390   {
4391     /* update the inbound queue number to HOST_SCRATCH_PAD2 register for queue 32 to 63 */
4392     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2,MSGU_SCRATCH_PAD_2);
4393     value |= bitMapQueueNum1;
4394     siHalRegWriteExt(agRoot, GEN_MSGU_HOST_SCRATCH_PAD_2, MSGU_HOST_SCRATCH_PAD_2, value);
4395   }
4396 
4397   /* Write bit 2 to Inbound DoorBell Register */
4398   siHalRegWriteExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET, IBDB_IBQ_FREEZE);
4399 
4400   /* wait until Inbound DoorBell Clear Register toggled */
4401   max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec */
4402   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
4403   do
4404   {
4405     ossaStallThread(agRoot, WAIT_INCREMENT);
4406     /* Read Inbound DoorBell Register - for RevB */
4407 //    value = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_IBDB_SET);
4408     value = MSGU_READ_IDR;
4409     value &= IBDB_IBQ_FREEZE;
4410   } while ((value != togglevalue) && (max_wait_count -= WAIT_INCREMENT));
4411 
4412   if (!max_wait_count)
4413   {
4414     SA_DBG1(("mpiFreezeInboundQueue: IBDB value/toggle = 0x%x 0x%x\n", value, togglevalue));
4415     return AGSA_RC_FAILURE;
4416   }
4417 
4418   return AGSA_RC_SUCCESS;
4419 }
4420 
4421 /******************************************************************************/
4422 /** \fn mpiUnFreezeInboundQueue(agsaRoot_t *agRoot)
4423  *  \brief Freeze the inbound queue
4424  *
4425  *  \param agRoot             Handles for this instance of SAS/SATA hardware
4426  *  \param bitMapQueueNum0    bit map for inbound queue number 0 - 31 to freeze
4427  *  \param bitMapQueueNum1    bit map for inbound queue number 32 - 63 to freeze
4428  *
4429  * Return:
4430  *         AGSA_RC_SUCCESS if Un-initialize the configuration table sucessful
4431  *         AGSA_RC_FAILURE if Un-initialize the configuration table failed
4432  */
4433 /******************************************************************************/
4434 GLOBAL bit32 mpiUnFreezeInboundQueue(agsaRoot_t *agRoot, bit32 bitMapQueueNum0, bit32 bitMapQueueNum1)
4435 {
4436   bit32    value, togglevalue;
4437   bit32    max_wait_time;
4438   bit32    max_wait_count;
4439 
4440   SA_DBG2(("Entering function:mpiUnFreezeInboundQueue\n"));
4441   SA_ASSERT(NULL != agRoot, "agRoot argument cannot be null");
4442 
4443   togglevalue = 0;
4444 
4445   if (bitMapQueueNum0)
4446   {
4447     /* update the inbound queue number to HOST_SCRATCH_PAD1 register - for queue 0 to 31 */
4448     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1,MSGU_SCRATCH_PAD_1);
4449     value |= bitMapQueueNum0;
4450     siHalRegWriteExt(agRoot, GEN_MSGU_HOST_SCRATCH_PAD_1, MSGU_HOST_SCRATCH_PAD_1, value);
4451   }
4452 
4453   if (bitMapQueueNum1)
4454   {
4455     /* update the inbound queue number to HOST_SCRATCH_PAD2 register - for queue 32 to 63 */
4456     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2,MSGU_SCRATCH_PAD_2);
4457     value |= bitMapQueueNum1;
4458     siHalRegWriteExt(agRoot, GEN_MSGU_HOST_SCRATCH_PAD_2, MSGU_HOST_SCRATCH_PAD_2, value);
4459   }
4460 
4461   /* Write bit 2 to Inbound DoorBell Register */
4462   siHalRegWriteExt(agRoot, GEN_MSGU_IBDB_SET, MSGU_IBDB_SET, IBDB_IBQ_UNFREEZE);
4463 
4464   /* wait until Inbound DoorBell Clear Register toggled */
4465   max_wait_time = WAIT_SECONDS(gWait_2);  /* 2 sec */
4466   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
4467   do
4468   {
4469     ossaStallThread(agRoot, WAIT_INCREMENT);
4470     /* Read Inbound DoorBell Register - for RevB */
4471     value = MSGU_READ_IDR;
4472     value &= IBDB_IBQ_UNFREEZE;
4473   } while ((value != togglevalue) && (max_wait_count -= WAIT_INCREMENT));
4474 
4475   if (!max_wait_count)
4476   {
4477     SA_DBG1(("mpiUnFreezeInboundQueue: IBDB value/toggle = 0x%x 0x%x\n", value, togglevalue));
4478     return AGSA_RC_FAILURE;
4479   }
4480 
4481   return AGSA_RC_SUCCESS;
4482 }
4483 
4484 #endif /* TEST ****************************************************************/
4485 
4486 GLOBAL bit32 si_check_V_HDA(agsaRoot_t *agRoot)
4487 {
4488   bit32 ret = AGSA_RC_SUCCESS;
4489   bit32 hda_status = 0;
4490 
4491   hda_status = (ossaHwRegReadExt(agRoot, PCIBAR0, SPC_V_HDA_RESPONSE_OFFSET+28));
4492 
4493   SA_DBG1(("si_check_V_HDA: hda_status 0x%08X\n",hda_status ));
4494 
4495   if((hda_status  & SPC_V_HDAR_RSPCODE_MASK)  == SPC_V_HDAR_IDLE)
4496   {
4497     /* HDA mode */
4498     SA_DBG1(("si_check_V_HDA: HDA mode, value = 0x%x\n", hda_status));
4499     ret = AGSA_RC_HDA_NO_FW_RUNNING;
4500   }
4501 
4502 
4503   return(ret);
4504 }
4505 GLOBAL bit32  si_check_V_Ready(agsaRoot_t *agRoot)
4506 {
4507   bit32 ret = AGSA_RC_SUCCESS;
4508   bit32    SCRATCH_PAD1;
4509   bit32    max_wait_time;
4510   bit32    max_wait_count;
4511 /* ILA */
4512   max_wait_time = (200 * 1000); /* wait 200 milliseconds */
4513   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
4514   do
4515   {
4516     ossaStallThread(agRoot, WAIT_INCREMENT);
4517     SCRATCH_PAD1 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1);
4518   } while (((SCRATCH_PAD1 & SCRATCH_PAD1_V_ILA_MASK) != SCRATCH_PAD1_V_ILA_MASK) && (max_wait_count -= WAIT_INCREMENT));
4519 
4520   if (!max_wait_count)
4521   {
4522     SA_DBG1(("si_check_V_Ready: SCRATCH_PAD1_V_ILA_MASK (0x%x)  not set SCRATCH_PAD1 = 0x%x\n",SCRATCH_PAD1_V_ILA_MASK, SCRATCH_PAD1));
4523     return( AGSA_RC_FAILURE);
4524   }
4525   /* RAAE */
4526   max_wait_time = (200 * 1000); /* wait 200 milliseconds */
4527   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
4528   do
4529   {
4530     ossaStallThread(agRoot, WAIT_INCREMENT);
4531     SCRATCH_PAD1 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1);
4532   } while (((SCRATCH_PAD1 & SCRATCH_PAD1_V_RAAE_MASK) != SCRATCH_PAD1_V_RAAE_MASK) && (max_wait_count -= WAIT_INCREMENT));
4533 
4534   if (!max_wait_count)
4535   {
4536     SA_DBG1(("si_check_V_Ready: SCRATCH_PAD1_V_RAAE_MASK (0x%x) not set SCRATCH_PAD1 = 0x%x\n",SCRATCH_PAD1_V_RAAE_MASK, SCRATCH_PAD1));
4537     return( AGSA_RC_FAILURE);
4538 
4539   }
4540   /* IOP0 */
4541   max_wait_time = (200 * 1000); /* wait 200 milliseconds */
4542   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
4543   do
4544   {
4545     ossaStallThread(agRoot, WAIT_INCREMENT);
4546     SCRATCH_PAD1 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1);
4547   } while (((SCRATCH_PAD1 & SCRATCH_PAD1_V_IOP0_MASK) != SCRATCH_PAD1_V_IOP0_MASK) && (max_wait_count -= WAIT_INCREMENT));
4548 
4549   if (!max_wait_count)
4550   {
4551     SA_DBG1(("si_check_V_Ready: SCRATCH_PAD1_V_IOP0_MASK (0x%x) not set SCRATCH_PAD1 = 0x%x\n",SCRATCH_PAD1_V_IOP0_MASK ,SCRATCH_PAD1));
4552     return( AGSA_RC_FAILURE);
4553 
4554   }
4555 
4556   /* IOP1 */
4557   max_wait_time = (200 * 1000); /* wait 200 milliseconds */
4558   max_wait_count = MAKE_MODULO(max_wait_time,WAIT_INCREMENT);
4559   do
4560   {
4561     ossaStallThread(agRoot, WAIT_INCREMENT);
4562     SCRATCH_PAD1 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1);
4563   } while (((SCRATCH_PAD1 & SCRATCH_PAD1_V_IOP1_MASK) != SCRATCH_PAD1_V_IOP1_MASK) && (max_wait_count -= WAIT_INCREMENT));
4564 
4565   if (!max_wait_count)
4566   {
4567     SA_DBG1(("si_check_V_Ready: SCRATCH_PAD1_V_IOP1_MASK (0x%x) not set SCRATCH_PAD1 = 0x%x\n",SCRATCH_PAD1_V_IOP1_MASK, SCRATCH_PAD1));
4568     // return( AGSA_RC_FAILURE);
4569   }
4570 
4571   return(ret);
4572 }
4573 
4574 GLOBAL bit32 siScratchDump(agsaRoot_t *agRoot)
4575 {
4576   bit32 SCRATCH_PAD1;
4577   bit32 ret =0;
4578 #ifdef SALLSDK_DEBUG
4579   bit32 SCRATCH_PAD2;
4580   bit32 SCRATCH_PAD3;
4581   bit32 SCRATCH_PAD0;
4582 
4583   SCRATCH_PAD0 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_0);
4584   SCRATCH_PAD2 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_2);
4585   SCRATCH_PAD3 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_3);
4586 #endif  /* SALLSDK_DEBUG */
4587   SCRATCH_PAD1 = ossaHwRegReadExt(agRoot, PCIBAR0, MSGU_SCRATCH_PAD_1);
4588   SA_DBG1(("siScratchDump: SCRATCH_PAD 0 0x%08x 1 0x%08x 2 0x%08x 3 0x%08x\n",SCRATCH_PAD0,SCRATCH_PAD1,SCRATCH_PAD2,SCRATCH_PAD3 ));
4589 
4590   if((SCRATCH_PAD1 & SCRATCH_PAD1_V_RESERVED) == SCRATCH_PAD1_V_RESERVED  )
4591   {
4592     SA_DBG1(("siScratchDump: SCRATCH_PAD1 SCRATCH_PAD1_V_RESERVED 0x%08x\n", SCRATCH_PAD1_V_RESERVED));
4593   }
4594   else
4595   {
4596     if((SCRATCH_PAD1 & SCRATCH_PAD1_V_RAAE_MASK) == SCRATCH_PAD1_V_RAAE_MASK  )
4597     {
4598       SA_DBG1(("siScratchDump: SCRATCH_PAD1 valid 0x%08x\n",SCRATCH_PAD0 ));
4599       SA_DBG1(("siScratchDump: RAAE ready 0x%08x\n",SCRATCH_PAD1 & SCRATCH_PAD1_V_RAAE_MASK));
4600     }
4601     if((SCRATCH_PAD1 & SCRATCH_PAD1_V_ILA_MASK) == SCRATCH_PAD1_V_ILA_MASK)
4602     {
4603       SA_DBG1(("siScratchDump: ILA  ready 0x%08x\n", SCRATCH_PAD1 & SCRATCH_PAD1_V_ILA_MASK));
4604     }
4605 
4606     if(SCRATCH_PAD1 & SCRATCH_PAD1_V_BOOTSTATE_MASK)
4607     {
4608       SA_DBG1(("siScratchDump: BOOTSTATE not success 0x%08x\n",SCRATCH_PAD1 & SCRATCH_PAD1_V_BOOTSTATE_MASK));
4609     }
4610 
4611     if((SCRATCH_PAD1 & SCRATCH_PAD1_V_IOP0_MASK) == SCRATCH_PAD1_V_IOP0_MASK)
4612     {
4613       SA_DBG1(("siScratchDump: IOP0 ready 0x%08x\n",SCRATCH_PAD1 & SCRATCH_PAD1_V_IOP0_MASK));
4614     }
4615     if((SCRATCH_PAD1 & SCRATCH_PAD1_V_IOP1_MASK) == SCRATCH_PAD1_V_IOP1_MASK)
4616     {
4617       SA_DBG1(("siScratchDump: IOP1 ready 0x%08x\n",SCRATCH_PAD1 & SCRATCH_PAD1_V_IOP1_MASK ));
4618     }
4619     if((SCRATCH_PAD1 & SCRATCH_PAD1_V_READY) == SCRATCH_PAD1_V_READY)
4620     {
4621       SA_DBG1(("siScratchDump: SCRATCH_PAD1_V_READY  0x%08x\n",SCRATCH_PAD1 & SCRATCH_PAD1_V_READY ));
4622     }
4623     if((SCRATCH_PAD1 & SCRATCH_PAD1_V_BOOTSTATE_MASK) == SCRATCH_PAD1_V_BOOTSTATE_MASK)
4624     {
4625       SA_DBG1(("siScratchDump: SCRATCH_PAD1_V_BOOTSTATE_MASK  0x%08x\n",SCRATCH_PAD1 & SCRATCH_PAD1_V_BOOTSTATE_MASK ));
4626     }
4627   }
4628   return(ret);
4629 
4630 }
4631 
4632 
4633 void si_macro_check(agsaRoot_t *agRoot)
4634 {
4635 
4636   SA_DBG1(("si_macro_check:smIS_SPC      %d\n",smIS_SPC(agRoot)  ));
4637   SA_DBG1(("si_macro_check:smIS_HIL      %d\n",smIS_HIL(agRoot)  ));
4638   SA_DBG1(("si_macro_check:smIS_SFC      %d\n",smIS_SFC(agRoot)  ));
4639 
4640   SA_DBG1(("si_macro_check:smIS_spc8001  %d\n",smIS_spc8001(agRoot)  ));
4641   SA_DBG1(("si_macro_check:smIS_spc8081  %d\n",smIS_spc8081(agRoot)  ));
4642 
4643   SA_DBG1(("si_macro_check:smIS_SPCV8008 %d\n",smIS_SPCV8008(agRoot)  ));
4644   SA_DBG1(("si_macro_check:smIS_SPCV8009 %d\n",smIS_SPCV8009(agRoot)  ));
4645   SA_DBG1(("si_macro_check:smIS_SPCV8018 %d\n",smIS_SPCV8018(agRoot)  ));
4646   SA_DBG1(("si_macro_check:smIS_SPCV8019 %d\n",smIS_SPCV8019(agRoot)  ));
4647   SA_DBG1(("si_macro_check:smIS_ADAP8088 %d\n",smIS_ADAP8088(agRoot)  ));
4648   SA_DBG1(("si_macro_check:smIS_ADAP8089 %d\n",smIS_ADAP8089(agRoot)  ));
4649   SA_DBG1(("si_macro_check:smIS_SPCV8070 %d\n",smIS_SPCV8070(agRoot)  ));
4650   SA_DBG1(("si_macro_check:smIS_SPCV8071 %d\n",smIS_SPCV8071(agRoot)  ));
4651   SA_DBG1(("si_macro_check:smIS_SPCV8072 %d\n",smIS_SPCV8072(agRoot)  ));
4652   SA_DBG1(("si_macro_check:smIS_SPCV8073 %d\n",smIS_SPCV8073(agRoot)  ));
4653   SA_DBG1(("si_macro_check:smIS_SPCV8074 %d\n",smIS_SPCV8074(agRoot)  ));
4654   SA_DBG1(("si_macro_check:smIS_SPCV8075 %d\n",smIS_SPCV8075(agRoot)  ));
4655   SA_DBG1(("si_macro_check:smIS_SPCV8076 %d\n",smIS_SPCV8076(agRoot)  ));
4656   SA_DBG1(("si_macro_check:smIS_SPCV8077 %d\n",smIS_SPCV8077(agRoot)  ));
4657   SA_DBG1(("si_macro_check:smIS_SPCV9015 %d\n",smIS_SPCV9015(agRoot)  ));
4658   SA_DBG1(("si_macro_check:smIS_SPCV9060 %d\n",smIS_SPCV9060(agRoot)  ));
4659   SA_DBG1(("si_macro_check:smIS_SPCV     %d\n",smIS_SPCV(agRoot)      ));
4660 
4661   SA_DBG1(("si_macro_check:smIS64bInt    %d\n", smIS64bInt(agRoot)    ));
4662 
4663 }
4664 
4665