xref: /freebsd/sys/dev/pms/RefTisa/sallsdk/spc/saint.c (revision c66ec88fed842fbaad62c30d510644ceb7bd2d71)
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 saint.c
24  *  \brief The file implements the functions to handle/enable/disable interrupt
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 #define SA_CLEAR_ODCR_IN_INTERRUPT
34 
35 //#define SA_TEST_FW_SPURIOUS_INT
36 
37 #ifdef SA_TEST_FW_SPURIOUS_INT
38 bit32 gOurIntCount = 0;
39 bit32 gSpuriousIntCount = 0;
40 bit32 gSpuriousInt[64]=
41 {
42 0,0,0,0,0,0,0,0,
43 0,0,0,0,0,0,0,0,
44 0,0,0,0,0,0,0,0,
45 0,0,0,0,0,0,0,0,
46 0,0,0,0,0,0,0,0,
47 0,0,0,0,0,0,0,0,
48 0,0,0,0,0,0,0,0,
49 0,0,0,0,0,0,0,0
50 };
51 bit32 gSpuriousInt1[64]=
52 {
53 0,0,0,0,0,0,0,0,
54 0,0,0,0,0,0,0,0,
55 0,0,0,0,0,0,0,0,
56 0,0,0,0,0,0,0,0,
57 0,0,0,0,0,0,0,0,
58 0,0,0,0,0,0,0,0,
59 0,0,0,0,0,0,0,0,
60 0,0,0,0,0,0,0,0
61 };
62 #endif /* SA_TEST_FW_SPURIOUS_INT */
63 
64 #ifdef SA_ENABLE_TRACE_FUNCTIONS
65 #ifdef siTraceFileID
66 #undef siTraceFileID
67 #endif /* siTraceFileID */
68 #define siTraceFileID 'G'
69 #endif /* SA_ENABLE_TRACE_FUNCTIONS */
70 
71 LOCAL FORCEINLINE bit32 siProcessOBMsg(
72                            agsaRoot_t  *agRoot,
73                            bit32        count,
74                            bit32        queueNum
75                            );
76 
77 LOCAL bit32 siFatalInterruptHandler(
78   agsaRoot_t  *agRoot,
79   bit32       interruptVectorIndex
80   )
81 {
82   agsaLLRoot_t         *saRoot = agNULL;
83   agsaFatalErrorInfo_t fatal_error;
84   bit32                value;
85   bit32                ret = AGSA_RC_FAILURE;
86   bit32                Sendfatal = agTRUE;
87 
88   SA_ASSERT((agNULL != agRoot), "");
89   if (agRoot == agNULL)
90   {
91     SA_DBG1(("siFatalInterruptHandler: agRoot == agNULL\n"));
92     return AGSA_RC_FAILURE;
93   }
94   saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
95   SA_ASSERT((agNULL != saRoot), "");
96   if (saRoot == agNULL)
97   {
98     SA_DBG1(("siFatalInterruptHandler: saRoot == agNULL\n"));
99     return AGSA_RC_FAILURE;
100   }
101 
102   value  = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1, MSGU_SCRATCH_PAD_1);
103   if (saRoot->ResetFailed)
104   {
105     SA_DBG1(("siFatalInterruptHandler: ResetFailed\n"));
106     ossaDisableInterrupts(agRoot, interruptVectorIndex);
107     return AGSA_RC_FAILURE;
108   }
109 
110   if(SCRATCH_PAD1_V_ERROR_STATE( value ) )
111   {
112     si_memset(&fatal_error, 0, sizeof(agsaFatalErrorInfo_t));
113     /* read detail fatal errors */
114     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0, MSGU_SCRATCH_PAD_0);
115     fatal_error.errorInfo0 = value;
116     SA_DBG1(("siFatalInterruptHandler: ScratchPad0 AAP error 0x%x code 0x%x\n",SCRATCH_PAD1_V_ERROR_STATE( value ), value));
117 
118     value  = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1, MSGU_SCRATCH_PAD_1);
119     fatal_error.errorInfo1 = value;
120     /* AAP error state */
121     SA_DBG1(("siFatalInterruptHandler: AAP error state and error code 0x%x\n", value));
122     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2, MSGU_SCRATCH_PAD_2);
123     fatal_error.errorInfo2 = value;
124     SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2 0x%08x\n", fatal_error.errorInfo2 ));
125 
126 #if defined(SALLSDK_DEBUG)
127     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_ILA_ERR)
128     {
129       SA_DBG1(("siFatalInterruptHandler:SCRATCH_PAD1_V_ERROR_STATE SCRATCH_PAD2_FW_ILA_ERR 0x%08x\n", SCRATCH_PAD2_FW_ILA_ERR));
130     }
131     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_FLM_ERR)
132     {
133       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_FLM_ERR 0x%08x\n", SCRATCH_PAD2_FW_FLM_ERR));
134     }
135     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_FW_ASRT_ERR)
136     {
137       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_FW_ASRT_ERR 0x%08x\n", SCRATCH_PAD2_FW_FW_ASRT_ERR));
138     }
139     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_WDG_ERR)
140     {
141       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_HW_WDG_ERR 0x%08x\n", SCRATCH_PAD2_FW_HW_WDG_ERR));
142     }
143     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_GEN_EXCEPTION_ERR)
144     {
145       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_GEN_EXCEPTION_ERR 0x%08x\n", SCRATCH_PAD2_FW_GEN_EXCEPTION_ERR));
146     }
147     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_UNDTMN_ERR)
148     {
149       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_UNDTMN_ERR 0x%08x\n",SCRATCH_PAD2_FW_UNDTMN_ERR ));
150     }
151     if(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_FATAL_ERR)
152     {
153       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_HW_FATAL_ERR 0x%08x\n", SCRATCH_PAD2_FW_HW_FATAL_ERR));
154     }
155     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_PCS_ERR )
156     {
157       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_PCS_ERR 0x%08x\n", value));
158     }
159     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_GSM_ERR )
160     {
161       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_GSM_ERR 0x%08x\n", value));
162     }
163     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP0_ERR )
164     {
165       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP0_ERR 0x%08x\n", value));
166     }
167     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) ==SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP1_ERR  )
168     {
169       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP1_ERR 0x%08x\n", value));
170     }
171     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP2_ERR )
172     {
173       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP2_ERR 0x%08x\n", value));
174     }
175     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_ERAAE_ERR )
176     {
177       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_ERAAE_ERR 0x%08x\n", value));
178     }
179     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_SDS_ERR )
180     {
181       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_SDS_ERR 0x%08x\n", value));
182     }
183     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_PCIE_CORE_ERR )
184     {
185       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_PCIE_CORE_ERR 0x%08x\n", value));
186     }
187     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_PCIE_AL_ERR )
188     {
189       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_PCIE_AL_ERR 0x%08x\n", value));
190     }
191     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_MSGU_ERR )
192     {
193       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_MSGU_ERR 0x%08x\n", value));
194     }
195     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_SPBC_ERR )
196     {
197       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_SPBC_ERR 0x%08x\n", value));
198     }
199     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_BDMA_ERR )
200     {
201       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_BDMA_ERR 0x%08x\n", value));
202     }
203     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) ==  SCRATCH_PAD2_HW_ERROR_INT_INDX_MCPSL2B_ERR)
204     {
205       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_MCPSL2B_ERR 0x%08x\n", value));
206     }
207     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_MCPSDC_ERR )
208     {
209       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_MCPSDC_ERR 0x%08x\n", value));
210     }
211     if((fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_MASK) == SCRATCH_PAD2_HW_ERROR_INT_INDX_UNDETERMINED_ERROR_OCCURRED )
212     {
213       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_HW_ERROR_INT_INDX_UNDETERMINED_ERROR_OCCURRED 0x%08x\n", value));
214     }
215 #endif /* SALLSDK_DEBUG */
216 
217     if( fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_NON_FATAL_ERR   &&
218       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_ILA_ERR)           &&
219       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_FLM_ERR)           &&
220       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_FW_ASRT_ERR)       &&
221       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_WDG_ERR)        &&
222       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_GEN_EXCEPTION_ERR) &&
223       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_UNDTMN_ERR)        &&
224       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_PCS_ERR)       &&
225       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_GSM_ERR)       &&
226       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP0_ERR)     &&
227       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_OSSP2_ERR)     &&
228       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_ERAAE_ERR)     &&
229       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_SDS_ERR)       &&
230       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_PCIE_CORE_ERR) &&
231       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_PCIE_AL_ERR)   &&
232       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_MSGU_ERR)      &&
233       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_SPBC_ERR)      &&
234       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_BDMA_ERR)      &&
235       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_MCPSL2B_ERR)   &&
236       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_MCPSDC_ERR)    &&
237       !(fatal_error.errorInfo2 & SCRATCH_PAD2_HW_ERROR_INT_INDX_UNDETERMINED_ERROR_OCCURRED) &&
238       !(fatal_error.errorInfo2 & SCRATCH_PAD2_FW_HW_FATAL_ERR) )
239     {
240       SA_DBG1(("siFatalInterruptHandler: SCRATCH_PAD2_FW_HW_NON_FATAL_ERR 0x%08x\n", value));
241       Sendfatal = agFALSE;
242     }
243 
244     value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3, MSGU_SCRATCH_PAD_3);
245     SA_DBG1(("siFatalInterruptHandler: ScratchPad3 IOP error code 0x%08x\n", value));
246     fatal_error.errorInfo3 = value;
247 
248     if (agNULL != saRoot)
249     {
250       fatal_error.regDumpBusBaseNum0 = saRoot->mainConfigTable.regDumpPCIBAR;
251       fatal_error.regDumpOffset0 = saRoot->mainConfigTable.FatalErrorDumpOffset0;
252       fatal_error.regDumpLen0 = saRoot->mainConfigTable.FatalErrorDumpLength0;
253       fatal_error.regDumpBusBaseNum1 = saRoot->mainConfigTable.regDumpPCIBAR;
254       fatal_error.regDumpOffset1 = saRoot->mainConfigTable.FatalErrorDumpOffset1;
255       fatal_error.regDumpLen1 = saRoot->mainConfigTable.FatalErrorDumpLength1;
256     }
257     else
258     {
259       fatal_error.regDumpBusBaseNum0 = 0;
260       fatal_error.regDumpOffset0 = 0;
261       fatal_error.regDumpLen0 = 0;
262       fatal_error.regDumpBusBaseNum1 = 0;
263       fatal_error.regDumpOffset1 = 0;
264       fatal_error.regDumpLen1 = 0;
265     }
266     /* Call Back with error */
267     SA_DBG1(("siFatalInterruptHandler: Sendfatal %x HostR0 0x%x\n",Sendfatal ,ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_Rsvd_0_Register ) ));
268     SA_DBG1(("siFatalInterruptHandler:  ScratchPad2 0x%x ScratchPad3 0x%x\n",
269                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Host_Scratchpad_2_Register),
270                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Host_Scratchpad_3_Register) ));
271 
272     ossaHwCB(agRoot, agNULL, OSSA_HW_EVENT_MALFUNCTION, Sendfatal, (void *)&fatal_error, agNULL);
273     ret = AGSA_RC_SUCCESS;
274   }
275   else
276   {
277     bit32 host_reg0;
278     host_reg0 = ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_Rsvd_0_Register );
279     if( host_reg0 == 0x2)
280     {
281       Sendfatal = agFALSE;
282 
283       SA_DBG1(("siFatalInterruptHandler: Non fatal ScratchPad1 0x%x HostR0 0x%x\n", value,host_reg0));
284       SA_DBG1(("siFatalInterruptHandler:  ScratchPad0 0x%x ScratchPad1 0x%x\n",
285                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_0_Register),
286                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_1_Register) ));
287       SA_DBG1(("siFatalInterruptHandler:  ScratchPad2 0x%x ScratchPad3 0x%x\n",
288                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_2_Register),
289                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_3_Register) ));
290 
291       ossaHwCB(agRoot, agNULL, OSSA_HW_EVENT_MALFUNCTION, Sendfatal, (void *)&fatal_error, agNULL);
292       ret = AGSA_RC_SUCCESS;
293     }
294     else if( host_reg0 == HDA_AES_DIF_FUNC)
295     {
296       SA_DBG1(("siFatalInterruptHandler: HDA_AES_DIF_FUNC 0x%x\n",
297                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_Rsvd_0_Register)));
298       Sendfatal = agFALSE;
299       ret = AGSA_RC_SUCCESS;
300     }
301     else
302     {
303       SA_DBG1(("siFatalInterruptHandler: No error detected ScratchPad1 0x%x HostR0 0x%x\n", value,host_reg0));
304       SA_DBG1(("siFatalInterruptHandler:  ScratchPad0 0x%x ScratchPad1 0x%x\n",
305                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_0_Register),
306                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_1_Register) ));
307       SA_DBG1(("siFatalInterruptHandler:  ScratchPad2 0x%x ScratchPad3 0x%x\n",
308                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_2_Register),
309                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_3_Register) ));
310 
311       SA_DBG1(("siFatalInterruptHandler: Doorbell_Set  %08X U %08X\n",
312                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
313                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
314       SA_DBG1(("siFatalInterruptHandler: Doorbell_Mask %08X U %08X\n",
315                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register ),
316                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU )));
317 
318       ret = AGSA_RC_FAILURE;
319     }
320   }
321   return ret;
322 
323 }
324 
325 GLOBAL bit32 saFatalInterruptHandler(
326   agsaRoot_t  *agRoot,
327   bit32       interruptVectorIndex
328   )
329 {
330   agsaLLRoot_t         *saRoot = agNULL;
331   bit32                ret = AGSA_RC_FAILURE;
332 
333   /* sanity check */
334   SA_ASSERT((agNULL != agRoot), "");
335   saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
336   SA_ASSERT((agNULL != saRoot), "");
337 
338   if (saRoot->ResetFailed)
339   {
340     SA_DBG1(("saFatalInterruptHandler: ResetFailed\n"));
341     ossaDisableInterrupts(agRoot, interruptVectorIndex);
342     return AGSA_RC_FAILURE;
343   }
344   if (saRoot->swConfig.fatalErrorInterruptEnable != 1)
345   {
346     SA_DBG1(("saFatalInterruptHandler: fatalErrorInterrtupt is NOT enabled\n"));
347     ossaDisableInterrupts(agRoot, interruptVectorIndex);
348     return AGSA_RC_FAILURE;
349   }
350 
351   if (saRoot->swConfig.fatalErrorInterruptVector != interruptVectorIndex)
352   {
353     SA_DBG1(("saFatalInterruptHandler: interruptVectorIndex does not match 0x%x 0x%x\n",
354              saRoot->swConfig.fatalErrorInterruptVector, interruptVectorIndex));
355     SA_DBG1(("saFatalInterruptHandler:  ScratchPad0 0x%x ScratchPad1 0x%x\n",
356                               ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_0_Register),
357                               ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_1_Register) ));
358     SA_DBG1(("saFatalInterruptHandler:  ScratchPad2 0x%x ScratchPad3 0x%x\n",
359                               ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_2_Register),
360                               ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_3_Register) ));
361     ossaDisableInterrupts(agRoot, interruptVectorIndex);
362     return AGSA_RC_FAILURE;
363   }
364 
365   ret = siFatalInterruptHandler(agRoot,interruptVectorIndex);
366 
367 
368   ossaDisableInterrupts(agRoot, interruptVectorIndex);
369 
370   return ret;
371 }
372 /******************************************************************************/
373 /*! \brief Function to process the interrupts
374  *
375  *  The saInterruptHandler() function is called after an interrupts has
376  *  been received
377  *  This function disables interrupts
378  *
379  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
380  *                instance of SAS/SATA hardware
381  *  \param interruptVectorIndex message that caused MSI message
382  *
383  *  \return TRUE if we caused interrupt
384  *
385  */
386 /*******************************************************************************/
387 FORCEINLINE bit32
388 saInterruptHandler(
389   agsaRoot_t  *agRoot,
390   bit32       interruptVectorIndex
391   )
392 {
393   agsaLLRoot_t *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
394   bit32 ToBeProcessedCount = 0;
395   bit32 our_int = 0;
396 #ifdef SA_TEST_FW_SPURIOUS_INT
397   bit8         i;
398 #endif/* SA_TEST_FW_SPURIOUS_INT */
399 
400   if( agNULL == saRoot )
401   {
402     /* Can be called before initialize is completed in a shared
403        interrupt environment like windows 2003
404     */
405     return(ToBeProcessedCount);
406   }
407 
408   if( (our_int = saRoot->OurInterrupt(agRoot,interruptVectorIndex)) == FALSE )
409   {
410 #ifdef SA_TEST_FW_SPURIOUS_INT
411     gSpuriousIntCount++;
412     smTrace(hpDBG_REGISTERS,"S1",gSpuriousIntCount);
413     /* TP:S1 gSpuriousIntCount */
414 #endif /* SA_TEST_FW_SPURIOUS_INT */
415     return(ToBeProcessedCount);
416   }
417 
418   smTraceFuncEnter(hpDBG_TICK_INT, "5q");
419 
420   smTrace(hpDBG_TICK_INT,"VI",interruptVectorIndex);
421   /* TP:Vi interrupt VectorIndex */
422 
423   if ( agFALSE == saRoot->sysIntsActive )
424   {
425     // SA_ASSERT(0, "saInterruptHandler sysIntsActive not set");
426 
427 #ifdef SA_PRINTOUT_IN_WINDBG
428 #ifndef DBG
429         DbgPrint("saInterruptHandler: sysIntsActive not set Doorbell_Mask_Set  %08X U %08X\n",
430                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register),
431                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU) );
432 #endif /* DBG  */
433 #endif /* SA_PRINTOUT_IN_WINDBG  */
434 
435 
436     SA_DBG1(("saInterruptHandler: Doorbell_Mask_Set  %08X U %08X\n",
437                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register),
438                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU)));
439     ossaDisableInterrupts(agRoot, interruptVectorIndex);
440     return(ToBeProcessedCount);
441 
442   }
443 
444   /* Allow replacement of disable interrupt */
445   ossaDisableInterrupts(agRoot, interruptVectorIndex);
446 
447 
448 #ifdef SA_TEST_FW_SPURIOUS_INT
449 
450   /* count for my interrupt */
451   gOurIntCount++;
452 
453   smTrace(hpDBG_REGISTERS,"S4",gOurIntCount);
454   /* TP:S4 gOurIntCount */
455 #endif /* SA_TEST_FW_SPURIOUS_INT */
456 
457   smTraceFuncExit(hpDBG_TICK_INT, 'a', "5q");
458   return(TRUE);
459 
460 }
461 
462 /******************************************************************************/
463 /*! \brief Function to disable MSIX interrupts
464  *
465  *  siDisableMSIXInterrupts disables interrupts
466  *  called thru macro ossaDisableInterrupts
467  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
468  *                instance of SAS/SATA hardware
469  *  \param interruptVectorIndex - vector index for message
470  *
471  */
472 /*******************************************************************************/
473 GLOBAL void siDisableMSIXInterrupts(
474   agsaRoot_t *agRoot,
475   bit32 interruptVectorIndex
476   )
477 {
478   bit32 msi_index;
479 #ifndef SA_CLEAR_ODCR_IN_INTERRUPT
480   bit32 value;
481 #endif /* SA_CLEAR_ODCR_IN_INTERRUPT */
482   msi_index = interruptVectorIndex * MSIX_TABLE_ELEMENT_SIZE;
483   msi_index += MSIX_TABLE_BASE;
484   ossaHwRegWrite(agRoot,msi_index , MSIX_INTERRUPT_DISABLE);
485   ossaHwRegRead(agRoot, msi_index); /* Dummy read */
486 #ifndef SA_CLEAR_ODCR_IN_INTERRUPT
487   value  = (1 << interruptVectorIndex);
488   ossaHwRegWrite(agRoot, MSGU_ODCR, value);
489 #endif /* SA_CLEAR_ODCR_IN_INTERRUPT */
490 }
491 
492 /******************************************************************************/
493 /*! \brief Function to disable MSIX V interrupts
494  *
495  *  siDisableMSIXInterrupts disables interrupts
496  *  called thru macro ossaDisableInterrupts
497  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
498  *                instance of SAS/SATA hardware
499  *  \param interruptVectorIndex - vector index for message
500  *
501  */
502 /*******************************************************************************/
503 void siDisableMSIX_V_Interrupts(
504   agsaRoot_t *agRoot,
505   bit32 interruptVectorIndex
506   )
507 {
508   bit64 mask;
509   agsabit32bit64 u64;
510   mask =( (bit64)1 << interruptVectorIndex);
511   u64.B64 = mask;
512   if(smIS64bInt(agRoot))
513   {
514     SA_DBG4(("siDisableMSIX_V_Interrupts: VI %d U 0x%08X L 0x%08X\n",interruptVectorIndex,u64.S32[1],u64.S32[0]));
515     ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_RegisterU,u64.S32[1]);
516   }
517   ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_Register, u64.S32[0]);
518 
519 }
520 /******************************************************************************/
521 /*! \brief Function to disable MSI interrupts
522  *
523  *  siDisableMSIInterrupts disables interrupts
524  *  called thru macro ossaDisableInterrupts
525  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
526  *                instance of SAS/SATA hardware
527  *  \param interruptVectorIndex - vector index for message
528  *
529  */
530 /*******************************************************************************/
531 GLOBAL void siDisableMSIInterrupts(
532   agsaRoot_t *agRoot,
533   bit32 interruptVectorIndex
534   )
535 {
536   bit32 ODMRValue;
537   bit32 mask;
538   mask = 1 << interruptVectorIndex;
539 
540   /*Must be protected for interuption */
541   ODMRValue = ossaHwRegRead(agRoot, MSGU_ODMR);
542   ODMRValue |= mask;
543 
544   ossaHwRegWrite(agRoot, MSGU_ODMR, ODMRValue);
545   ossaHwRegWrite(agRoot, MSGU_ODCR, mask);
546 }
547 
548 /******************************************************************************/
549 /*! \brief Function to disable MSI V interrupts
550  *
551  *  siDisableMSIInterrupts disables interrupts
552  *  called thru macro ossaDisableInterrupts
553  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
554  *                instance of SAS/SATA hardware
555  *  \param interruptVectorIndex - vector index for message
556  *
557  */
558 /*******************************************************************************/
559 GLOBAL void siDisableMSI_V_Interrupts(
560   agsaRoot_t *agRoot,
561   bit32 interruptVectorIndex
562   )
563 {
564   SA_ASSERT(0, "Should not be called");
565   SA_DBG4(("siDisableMSI_V_Interrupts:\n"));
566 }
567 
568 /******************************************************************************/
569 /*! \brief Function to process Legacy interrupts
570  *
571  *  siDisableLegacyInterrupts disables interrupts
572  *  called thru macro ossaDisableInterrupts
573  *
574  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
575  *                instance of SAS/SATA hardware
576  *  \param interruptVectorIndex not used in legacy case
577  *
578  */
579 /*******************************************************************************/
580 GLOBAL void siDisableLegacyInterrupts(
581   agsaRoot_t *agRoot,
582   bit32 interruptVectorIndex
583   )
584 {
585   ossaHwRegWrite(agRoot, MSGU_ODMR, ODMR_MASK_ALL);
586 #ifndef SA_CLEAR_ODCR_IN_INTERRUPT
587   ossaHwRegWrite(agRoot, MSGU_ODCR, ODCR_CLEAR_ALL);
588 #endif /* SA_CLEAR_ODCR_IN_INTERRUPT */
589 }
590 
591 /******************************************************************************/
592 /*! \brief Function to process Legacy V interrupts
593  *
594  *  siDisableLegacyInterrupts disables interrupts
595  *  called thru macro ossaDisableInterrupts
596  *
597  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
598  *                instance of SAS/SATA hardware
599  *  \param interruptVectorIndex not used in legacy case
600  *
601  */
602 /*******************************************************************************/
603 GLOBAL void siDisableLegacy_V_Interrupts(
604   agsaRoot_t *agRoot,
605   bit32 interruptVectorIndex
606   )
607 {
608 
609   bit64 mask;
610   agsabit32bit64 u64;
611   mask =( (bit64)1 << interruptVectorIndex);
612   u64.B64 = mask;
613 
614   SA_DBG4(("siDisableLegacy_V_Interrupts:IN MSGU_READ_ODR  %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODR,  V_Outbound_Doorbell_Set_Register)));
615   SA_DBG4(("siDisableLegacy_V_Interrupts:IN MSGU_READ_ODMR %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODMR, V_Outbound_Doorbell_Mask_Set_Register )));
616   if(smIS64bInt(agRoot))
617   {
618     SA_DBG4(("siDisableLegacy_V_Interrupts: VI %d U 0x%08X L 0x%08X\n",interruptVectorIndex,u64.S32[1],u64.S32[0]));
619     ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_Register,u64.S32[1] );
620   }
621   ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_RegisterU,u64.S32[0]);
622 
623 }
624 /******************************************************************************/
625 /*! \brief Function to process MSIX interrupts
626  *
627  *  siOurMSIXInterrupt checks if we generated interrupt
628  *  called thru function pointer saRoot->OurInterrupt
629  *
630  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
631  *                instance of SAS/SATA hardware
632  *  \return always true
633  */
634 /*******************************************************************************/
635 GLOBAL bit32 siOurMSIXInterrupt(
636   agsaRoot_t *agRoot,
637   bit32 interruptVectorIndex
638   )
639 {
640   return(TRUE);
641 }
642 
643 /******************************************************************************/
644 /*! \brief Function to process MSIX V interrupts
645  *
646  *  siOurMSIXInterrupt checks if we generated interrupt
647  *  called thru function pointer saRoot->OurInterrupt
648  *
649  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
650  *                instance of SAS/SATA hardware
651  *  \return always true
652  */
653 /*******************************************************************************/
654 GLOBAL bit32 siOurMSIX_V_Interrupt(
655   agsaRoot_t *agRoot,
656   bit32 interruptVectorIndex
657   )
658 {
659   return(TRUE);
660 }
661 /******************************************************************************/
662 /*! \brief Function to process MSI interrupts
663  *
664  *  siOurMSIInterrupt checks if we generated interrupt
665  *  called thru function pointer saRoot->OurInterrupt
666  *
667  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
668  *                instance of SAS/SATA hardware
669  *  \return always true
670  */
671 /*******************************************************************************/
672 bit32 siOurMSIInterrupt(
673   agsaRoot_t *agRoot,
674   bit32 interruptVectorIndex
675   )
676 {
677   return(TRUE);
678 }
679 
680 /******************************************************************************/
681 /*! \brief Function to process MSI V interrupts
682  *
683  *  siOurMSIInterrupt checks if we generated interrupt
684  *  called thru function pointer saRoot->OurInterrupt
685  *
686  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
687  *                instance of SAS/SATA hardware
688  *  \return always true
689  */
690 /*******************************************************************************/
691 bit32 siOurMSI_V_Interrupt(
692   agsaRoot_t *agRoot,
693   bit32 interruptVectorIndex
694   )
695 {
696   SA_DBG4((":siOurMSI_V_Interrupt\n"));
697   return(TRUE);
698 }
699 
700 /******************************************************************************/
701 /*! \brief Function to process Legacy interrupts
702  *
703  *  siOurLegacyInterrupt checks if we generated interrupt
704  *  called thru function pointer saRoot->OurInterrupt
705  *
706  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
707  *                instance of SAS/SATA hardware
708  *  \return true if we claim interrupt
709  */
710 /*******************************************************************************/
711 bit32 siOurLegacyInterrupt(
712   agsaRoot_t *agRoot,
713   bit32 interruptVectorIndex
714   )
715 {
716   bit32 Int_masked;
717   bit32 Int_active;
718   Int_masked = MSGU_READ_ODMR;
719   Int_active = MSGU_READ_ODR;
720 
721   if(Int_masked & 1 )
722   {
723     return(FALSE);
724   }
725   if(Int_active & 1 )
726   {
727 
728     return(TRUE);
729   }
730   return(FALSE);
731 }
732 
733 /******************************************************************************/
734 /*! \brief Function to process Legacy V interrupts
735  *
736  *  siOurLegacyInterrupt checks if we generated interrupt
737  *  called thru function pointer saRoot->OurInterrupt
738  *
739  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
740  *                instance of SAS/SATA hardware
741  *  \return true if we claim interrupt
742  */
743 /*******************************************************************************/
744 bit32 siOurLegacy_V_Interrupt(
745   agsaRoot_t *agRoot,
746   bit32 interruptVectorIndex
747   )
748 {
749   bit32 Int_active;
750   Int_active = siHalRegReadExt(agRoot, GEN_MSGU_ODR, V_Outbound_Doorbell_Set_Register  );
751 
752   return(Int_active ? TRUE : FALSE);
753 }
754 
755 
756 /******************************************************************************/
757 /*! \brief Function to process the cause of interrupt
758  *
759  *  The saDelayedInterruptHandler() function is called after an interrupt messages has
760  *  been received it may be called by a deferred procedure call
761  *
762  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
763  *                instance of SAS/SATA hardware
764  *  \param interruptVectorIndex  - vector index for message
765  *  \param count Number of completion queue entries to consume
766  *
767  *  \return number of messages processed
768  *
769  */
770 /*******************************************************************************/
771 FORCEINLINE bit32
772 saDelayedInterruptHandler(
773   agsaRoot_t  *agRoot,
774   bit32       interruptVectorIndex,
775   bit32       count
776   )
777 {
778   agsaLLRoot_t *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
779   bit32         processedMsgCount = 0;
780   bit32         pad1 = 0;
781   bit32         host_reg0 = 0;
782 #if defined(SALLSDK_DEBUG)
783   bit32 host_reg1 = 0;
784 #endif
785   bit8         i = 0;
786 
787   OSSA_OUT_ENTER(agRoot);
788 
789   smTraceFuncEnter(hpDBG_VERY_LOUD,"5p");
790 
791   smTrace(hpDBG_VERY_LOUD,"Vd",interruptVectorIndex);
792   /* TP:Vd delayed VectorIndex */
793   smTrace(hpDBG_VERY_LOUD,"Vc",count);
794   /* TP:Vc IOMB count*/
795 
796   if( saRoot->swConfig.fatalErrorInterruptEnable &&
797       saRoot->swConfig.fatalErrorInterruptVector == interruptVectorIndex )
798   {
799     pad1 = siHalRegReadExt(agRoot,GEN_MSGU_SCRATCH_PAD_1,  MSGU_SCRATCH_PAD_1);
800     host_reg0 = ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_Rsvd_0_Register );
801 
802 
803     if(saRoot->swConfig.hostDirectAccessMode & 2 )
804     {
805       if( host_reg0 == HDA_AES_DIF_FUNC)
806       {
807         host_reg0 = 0;
808       }
809     }
810 
811 
812 #if defined(SALLSDK_DEBUG)
813     host_reg1 = ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_Rsvd_1_Register );
814 #endif
815     if( (SCRATCH_PAD1_V_ERROR_STATE( pad1 ) != 0 ) && host_reg0 )
816     {
817 
818       SA_DBG1(("saDelayedInterruptHandler: vi %d  Error %08X\n",interruptVectorIndex,  SCRATCH_PAD1_V_ERROR_STATE( pad1 )));
819       SA_DBG1(("saDelayedInterruptHandler: Sp 1 %08X Hr0 %08X Hr1 %08X\n",pad1,host_reg0,host_reg1 ));
820       SA_DBG1(("saDelayedInterruptHandler: SCRATCH_PAD1_V_ERROR_STATE      %08X\n", SCRATCH_PAD1_V_ERROR_STATE( pad1 )));
821       SA_DBG1(("saDelayedInterruptHandler: SCRATCH_PAD1_V_ILA_ERROR_STATE  %08X\n", SCRATCH_PAD1_V_ILA_ERROR_STATE( pad1 )));
822       SA_DBG1(("saDelayedInterruptHandler: SCRATCH_PAD1_V_RAAE_ERROR_STATE %08X\n", SCRATCH_PAD1_V_RAAE_ERROR_STATE( pad1 )));
823       SA_DBG1(("saDelayedInterruptHandler: SCRATCH_PAD1_V_IOP0_ERROR_STATE %08X\n", SCRATCH_PAD1_V_IOP0_ERROR_STATE( pad1 )));
824       SA_DBG1(("saDelayedInterruptHandler: SCRATCH_PAD1_V_IOP1_ERROR_STATE %08X\n", SCRATCH_PAD1_V_IOP1_ERROR_STATE( pad1 )));
825 
826       siFatalInterruptHandler( agRoot, interruptVectorIndex  );
827       ossaDisableInterrupts(agRoot, interruptVectorIndex);
828 
829     }
830     else
831     {
832       SA_DBG2(("saDelayedInterruptHandler: Fatal Check VI %d SCRATCH_PAD1 %08X host_reg0 %08X host_reg1 %08X\n",interruptVectorIndex, pad1,host_reg0,host_reg1));
833       SA_DBG2(("saDelayedInterruptHandler:  ScratchPad0 0x%x ScratchPad1 0x%x\n",
834                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_0_Register),
835                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_1_Register) ));
836       SA_DBG2(("saDelayedInterruptHandler:  ScratchPad2 0x%x ScratchPad3 0x%x\n",
837                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_2_Register),
838                                 ossaHwRegReadExt(agRoot, PCIBAR0,V_Scratchpad_3_Register) ));
839 
840       SA_DBG2(("saDelayedInterruptHandler: Doorbell_Set  %08X U %08X\n",
841                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
842                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
843       SA_DBG2(("saDelayedInterruptHandler: Doorbell_Mask %08X U %08X\n",
844                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register ),
845                                ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU )));
846     }
847 
848   }
849 
850 
851 #ifdef SA_LNX_PERF_MODE
852   return siProcessOBMsg(agRoot, count, interruptVectorIndex);
853 #endif
854 
855   /* check all the configuration outbound queues within a vector bitmap */
856   SA_ASSERT((saRoot->QueueConfig.numOutboundQueues < 65), "numOutboundQueue");
857 
858   for ( i = 0; i < saRoot->QueueConfig.numOutboundQueues; i++ )
859   {
860     /* process IOMB in the outbound queue 0 to 31 if bit set in the vector bitmap */
861     if (i < OQ_NUM_32)
862     {
863       if (saRoot->interruptVecIndexBitMap[interruptVectorIndex] & (1 << i))
864       {
865         processedMsgCount += siProcessOBMsg(agRoot, count, i);
866       }
867       else if (saRoot->QueueConfig.outboundQueues[i].interruptEnable == 0)
868       {
869         /* polling mode - interruptVectorIndex = 0 only and no bit set */
870         processedMsgCount += siProcessOBMsg(agRoot, count, i);
871       }
872 #ifdef SA_FW_TEST_INTERRUPT_REASSERT
873       else if (saRoot->CheckAll)
874       {
875         /* polling mode - interruptVectorIndex = 0 only and no bit set */
876         processedMsgCount += siProcessOBMsg(agRoot, count, i);
877       }
878 #endif /* SA_FW_TEST_INTERRUPT_REASSERT */
879 
880     }
881     else
882     {
883       /* process IOMB in the outbound queue 32 to 63 if bit set in the vector bitmap */
884       if (saRoot->interruptVecIndexBitMap1[interruptVectorIndex] & (1 << (i - OQ_NUM_32)))
885       {
886         processedMsgCount += siProcessOBMsg(agRoot, count, i);
887       }
888       /* check interruptEnable bit for polling mode of OQ */
889       /* the following code can be removed, we do not care about the bit */
890       else if (saRoot->QueueConfig.outboundQueues[i].interruptEnable == 0)
891       {
892         /* polling mode - interruptVectorIndex = 0 only and no bit set */
893         processedMsgCount += siProcessOBMsg(agRoot, count, i);
894       }
895 #ifdef SA_FW_TEST_INTERRUPT_REASSERT
896       else if (saRoot->CheckAll)
897       {
898         /* polling mode - interruptVectorIndex = 0 only and no bit set */
899         processedMsgCount += siProcessOBMsg(agRoot, count, i);
900       }
901 #endif /* SA_FW_TEST_INTERRUPT_REASSERT */
902     }
903   }
904 
905 #ifdef SA_FW_TEST_INTERRUPT_REASSERT
906   saRoot->CheckAll = 0;
907 #endif /* SA_FW_TEST_INTERRUPT_REASSERT */
908 
909 #ifndef SA_RENABLE_IN_OSLAYER
910   if ( agTRUE == saRoot->sysIntsActive )
911   {
912     /* Allow replacement of enable interrupt */
913     ossaReenableInterrupts(agRoot, interruptVectorIndex);
914   }
915 #endif /* SA_RENABLE_IN_OSLAYER */
916 
917   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5p");
918 
919   OSSA_OUT_LEAVE(agRoot);
920   return processedMsgCount;
921 }
922 
923 /******************************************************************************/
924 /*! \brief Function to reenable MSIX interrupts
925  *
926  *  siReenableMSIXInterrupts  reenableinterrupts
927  *  called thru macro ossaReenableInterrupts
928  *
929  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
930  *                instance of SAS/SATA hardware
931  *  \param interruptVectorIndex  - vector index for message
932  *
933  */
934 /*******************************************************************************/
935 void siReenableMSIXInterrupts(
936    agsaRoot_t *agRoot,
937    bit32 interruptVectorIndex
938   )
939 {
940   bit32 msi_index;
941 #ifdef SA_CLEAR_ODCR_IN_INTERRUPT
942   bit32 value;
943 #endif /* SA_CLEAR_ODCR_IN_INTERRUPT */
944   msi_index = interruptVectorIndex * MSIX_TABLE_ELEMENT_SIZE;
945   msi_index += MSIX_TABLE_BASE;
946   ossaHwRegWriteExt(agRoot, PCIBAR0,msi_index, MSIX_INTERRUPT_ENABLE);
947 
948   SA_DBG4(("siReenableMSIXInterrupts:interruptVectorIndex %d\n",interruptVectorIndex));
949 
950 #ifdef SA_CLEAR_ODCR_IN_INTERRUPT
951   value  = (1 << interruptVectorIndex);
952   siHalRegWriteExt(agRoot, GEN_MSGU_ODCR, MSGU_ODCR, value);
953 #endif /* SA_CLEAR_ODCR_IN_INTERRUPT */
954 }
955 /******************************************************************************/
956 /*! \brief Function to reenable MSIX interrupts
957  *
958  *  siReenableMSIXInterrupts  reenableinterrupts
959  *  called thru macro ossaReenableInterrupts
960  *
961  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
962  *                instance of SAS/SATA hardware
963  *  \param interruptVectorIndex  - vector index for message
964  *
965  */
966 /*******************************************************************************/
967 void siReenableMSIX_V_Interrupts(
968     agsaRoot_t *agRoot,
969     bit32 interruptVectorIndex
970     )
971 {
972   agsaLLRoot_t         *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
973   bit64 mask;
974   agsabit32bit64 u64;
975   mask =( (bit64)1 << interruptVectorIndex);
976   u64.B64 = mask;
977 
978   SA_DBG4(("siReenableMSIX_V_Interrupts:\n"));
979 
980   if(saRoot->sysIntsActive)
981   {
982     if(smIS64bInt(agRoot))
983     {
984       SA_DBG4(("siReenableMSIX_V_Interrupts: VI %d U 0x%08X L 0x%08X\n",interruptVectorIndex,u64.S32[1],u64.S32[0]));
985       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Clear_RegisterU,u64.S32[1] );
986     }
987     ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Clear_Register,u64.S32[0]);
988   }
989   else
990   {
991       SA_DBG1(("siReenableMSIX_V_Interrupts: VI %d sysIntsActive off\n",interruptVectorIndex));
992   }
993 
994 }
995 
996 /******************************************************************************/
997 /*! \brief Function to reenable MSI interrupts
998  *
999  *  siReenableMSIXInterrupts  reenableinterrupts
1000  *  called thru macro ossaReenableInterrupts
1001  *
1002  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
1003  *                instance of SAS/SATA hardware
1004  *  \param interruptVectorIndex  - vector index for message
1005  *
1006  */
1007 /*******************************************************************************/
1008 GLOBAL void siReenableMSIInterrupts(
1009   agsaRoot_t *agRoot,
1010   bit32 interruptVectorIndex
1011   )
1012 {
1013   bit32 ODMRValue;
1014 
1015   ODMRValue = siHalRegReadExt(agRoot, GEN_MSGU_ODMR, MSGU_ODMR);
1016   ODMRValue &= ~(1 << interruptVectorIndex);
1017 
1018   siHalRegWriteExt(agRoot, GEN_MSGU_ODMR, MSGU_ODMR, ODMRValue);
1019 }
1020 
1021 /******************************************************************************/
1022 /*! \brief Function to reenable MSI V interrupts
1023  *
1024  *  siReenableMSIXInterrupts  reenableinterrupts
1025  *  called thru macro ossaReenableInterrupts
1026  *
1027  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
1028  *                instance of SAS/SATA hardware
1029  *  \param interruptVectorIndex  - vector index for message
1030  *
1031  */
1032 /*******************************************************************************/
1033 GLOBAL void siReenableMSI_V_Interrupts(
1034    agsaRoot_t *agRoot,
1035    bit32 interruptVectorIndex
1036    )
1037 {
1038   SA_ASSERT(0, "Should not be called");
1039 
1040   SA_DBG4(("siReenableMSI_V_Interrupts:\n"));
1041 
1042 }
1043 /******************************************************************************/
1044 /*! \brief Function to reenable Legacy interrupts
1045  *
1046  *  siReenableLegacyInterrupts reenableinterrupts
1047  *  called thru macro ossaReenableInterrupts
1048  *
1049  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
1050  *                instance of SAS/SATA hardware
1051  *  \param interruptVectorIndex always zero
1052  *
1053  */
1054 /*******************************************************************************/
1055 GLOBAL void siReenableLegacyInterrupts(
1056   agsaRoot_t *agRoot,
1057   bit32 interruptVectorIndex
1058   )
1059 {
1060   siHalRegWriteExt(agRoot, GEN_MSGU_ODMR, MSGU_ODMR, ODMR_CLEAR_ALL);
1061 
1062 #ifdef SA_CLEAR_ODCR_IN_INTERRUPT
1063   siHalRegWriteExt(agRoot, GEN_MSGU_ODCR, MSGU_ODCR, ODCR_CLEAR_ALL);
1064 #endif /* SA_CLEAR_ODCR_IN_INTERRUPT */
1065 }
1066 
1067 /******************************************************************************/
1068 /*! \brief Function to reenable Legacy V interrupts
1069  *
1070  *  siReenableLegacyInterrupts reenableinterrupts
1071  *  called thru macro ossaReenableInterrupts
1072  *
1073  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
1074  *                instance of SAS/SATA hardware
1075  *  \param interruptVectorIndex always zero
1076  *
1077  */
1078 /*******************************************************************************/
1079 GLOBAL void siReenableLegacy_V_Interrupts(
1080   agsaRoot_t *agRoot,
1081   bit32 interruptVectorIndex
1082   )
1083 {
1084 
1085   bit32 mask;
1086   mask = 1 << interruptVectorIndex;
1087 
1088   SA_DBG5(("siReenableLegacy_V_Interrupts:IN MSGU_READ_ODR  %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODR, V_Outbound_Doorbell_Set_Register)));
1089   SA_DBG5(("siReenableLegacy_V_Interrupts:IN MSGU_READ_ODMR %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODMR, V_Outbound_Doorbell_Mask_Set_Register )));
1090 
1091   ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Clear_Register, mask);
1092   ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Clear_Register, mask );
1093 
1094 
1095   SA_DBG5(("siReenableLegacy_V_Interrupts:OUT MSGU_READ_ODMR %08X\n",siHalRegReadExt(agRoot, GEN_MSGU_ODMR, V_Outbound_Doorbell_Mask_Set_Register )));
1096 
1097 }
1098 
1099 /******************************************************************************/
1100 /*! \brief Function to enable a single interrupt vector
1101  *
1102  *
1103  *
1104  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
1105  *                instance of SAS/SATA hardware
1106  *  \param interruptVectorIndex Interrupt vector to enable
1107  *
1108  */
1109 /*******************************************************************************/
1110 /******************************************************************************/
1111 /*! \brief  saSystemInterruptsEnable
1112  *   Function to enable a single interrupt vector
1113  *
1114  *  \param agRoot OS Layer-specific and LL Layer-specific context handles for this
1115  *                instance of SAS/SATA hardware
1116  *  \param interruptVectorIndex Interrupt vector to enable
1117  *
1118  */
1119 /*******************************************************************************/
1120 GLOBAL FORCEINLINE
1121 void saSystemInterruptsEnable(
1122                               agsaRoot_t  *agRoot,
1123                               bit32       interruptVectorIndex
1124                               )
1125 {
1126   ossaReenableInterrupts(agRoot, interruptVectorIndex);
1127 }
1128 /******************************************************************************/
1129 /*! \brief Routine to handle Outbound Message
1130  *
1131  *  The handle for outbound message
1132  *
1133  *  \param agRoot   handles for this instance of SAS/SATA hardware
1134  *  \param count    interrupt message count
1135  *  \param queueNum outbound queue
1136  *
1137  *  \return
1138  */
1139 /*******************************************************************************/
1140 LOCAL FORCEINLINE bit32
1141 siProcessOBMsg(
1142   agsaRoot_t  *agRoot,
1143   bit32       count,
1144   bit32       queueNum
1145   )
1146 {
1147   agsaLLRoot_t         *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1148   mpiOCQueue_t         *circularQ = agNULL;
1149   void                 *pMsg1     = agNULL;
1150   bit32                ret, processedMsgCount = 0;
1151   bit32                ParseOBIombStatus = 0;
1152 #ifdef SA_ENABLE_TRACE_FUNCTIONS
1153   bit32                i = 0;
1154 #endif
1155   bit16                opcode  = 0;
1156   mpiMsgCategory_t     category;
1157   bit8                 bc      = 0;
1158 
1159   smTraceFuncEnter(hpDBG_VERY_LOUD,"5r");
1160 
1161 
1162   SA_DBG3(("siProcessOBMsg: queueNum 0x%x\n", queueNum));
1163 
1164   ossaSingleThreadedEnter(agRoot, LL_IOREQ_OBQ_LOCK + queueNum);
1165 
1166   circularQ = &saRoot->outboundQueue[queueNum];
1167   OSSA_READ_LE_32(circularQ->agRoot, &circularQ->producerIdx, circularQ->piPointer, 0);
1168 
1169   if (circularQ->producerIdx == circularQ->consumerIdx)
1170   {
1171     ossaSingleThreadedLeave(agRoot, LL_IOREQ_OBQ_LOCK + queueNum);
1172     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5r");
1173     return processedMsgCount;
1174   }
1175 
1176   ossaSingleThreadedLeave(agRoot, LL_IOREQ_OBQ_LOCK + queueNum);
1177 
1178   do
1179   {
1180     /* ossaSingleThreadedEnter(agRoot, LL_IOREQ_OBQ_LOCK + queueNum); */
1181     ret = mpiMsgConsume(circularQ, &pMsg1, &category, &opcode, &bc);
1182     /* ossaSingleThreadedLeave(agRoot, LL_IOREQ_OBQ_LOCK + queueNum); */
1183 
1184     if (AGSA_RC_SUCCESS == ret)
1185     {
1186       smTrace(hpDBG_IOMB,"M0",queueNum);
1187       /* TP:M0 queueNum */
1188       smTrace(hpDBG_VERY_LOUD,"MA",opcode);
1189       /* TP:MA opcode */
1190       smTrace(hpDBG_IOMB,"MB",category);
1191       /* TP:MB category */
1192 
1193 #ifdef SA_ENABLE_TRACE_FUNCTIONS
1194       for (i=0; i<((bit32)bc*(circularQ->elementSize/4)); i++)
1195       {
1196           /* The -sizeof(mpiMsgHeader_t) is to account for mpiMsgConsume incrementing the pointer past the header*/
1197           smTrace(hpDBG_IOMB,"MC",*( ((bit32*)((bit8 *)pMsg1 - sizeof(mpiMsgHeader_t))) + i));
1198           /* TP:MC Outbound IOMB Dword */
1199       }
1200 #endif
1201 
1202       MPI_DEBUG_TRACE( circularQ->qNumber,((circularQ->producerIdx << 16 ) | circularQ->consumerIdx),MPI_DEBUG_TRACE_OBQ, (void *)(((bit8*)pMsg1) - sizeof(mpiMsgHeader_t)), circularQ->elementSize);
1203 
1204       ossaLogIomb(circularQ->agRoot,
1205                   circularQ->qNumber,
1206                   FALSE,
1207                   (void *)(((bit8*)pMsg1) - sizeof(mpiMsgHeader_t)),
1208                   bc*circularQ->elementSize);
1209 
1210       ossaQueueProcessed(agRoot, queueNum, circularQ->producerIdx, circularQ->consumerIdx);
1211       /* process the outbound message */
1212       ParseOBIombStatus = mpiParseOBIomb(agRoot, (bit32 *)pMsg1, category, opcode);
1213       if (ParseOBIombStatus == AGSA_RC_FAILURE)
1214       {
1215         SA_DBG1(("siProcessOBMsg, Failed Q %2d PI 0x%03x CI 0x%03x\n", queueNum, circularQ->producerIdx, circularQ->consumerIdx));
1216 #if defined(SALLSDK_DEBUG)
1217         /* free the message for debug: this is a hang! */
1218 
1219         mpiMsgFreeSet(circularQ, pMsg1, bc);
1220         processedMsgCount ++;
1221 #endif /**/
1222         break;
1223       }
1224 
1225       /* free the message from the outbound circular buffer */
1226       mpiMsgFreeSet(circularQ, pMsg1, bc);
1227       processedMsgCount ++;
1228     }
1229     else
1230     //if (AGSA_RC_BUSY == ret) // always (circularQ->producerIdx == circularQ->consumerIdx)
1231     // || (AGSA_RC_FAILURE == ret)
1232     {
1233         break;
1234     }
1235   }
1236   /* end of message processing if hit the count */
1237   while(count > processedMsgCount);
1238 
1239 /* #define SALLSDK_FATAL_ERROR_DETECT 1 */
1240 /*
1241    this comments are to be removed
1242    fill in 0x1D 0x1e 0x1f 0x20 in MPI table for
1243   bit32   regDumpBusBaseNum0;
1244   bit32   regDumpOffset0;
1245   bit32   regDumpLen0;
1246   bit32   regDumpBusBaseNum1;
1247   bit32   regDumpOffset1;
1248   bit32   regDumpLen1;
1249   in agsaFatalErrorInfo_t
1250 
1251   ??? regDumpBusBaseNum0 and regDumpBusBaseNum1
1252     saRoot->mainConfigTable.regDumpPCIBAR = pcibar;
1253     saRoot->mainConfigTable.FatalErrorDumpOffset0 = config->FatalErrorDumpOffset0;
1254     saRoot->mainConfigTable.FatalErrorDumpLength0 = config->FatalErrorDumpLength0;
1255     saRoot->mainConfigTable.FatalErrorDumpOffset1 = config->FatalErrorDumpOffset1;
1256     saRoot->mainConfigTable.FatalErrorDumpLength1 = config->FatalErrorDumpLength1;
1257 
1258 
1259 
1260 */
1261 #if defined(SALLSDK_FATAL_ERROR_DETECT)
1262 
1263   if( smIS_SPC(agRoot) ) /* SPC only */
1264   {
1265 
1266   /* any fatal error happened */
1267   /* executing this code impacts performance by 1% when no error is detected */
1268   {
1269     agsaFatalErrorInfo_t fatal_error;
1270     bit32                value;
1271     bit32                value1;
1272 
1273     value  = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1, MSGU_SCRATCH_PAD_1);
1274     value1 = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2, MSGU_SCRATCH_PAD_2);
1275 
1276     if( (value & SA_FATAL_ERROR_SP1_AAP1_ERR_MASK) == SA_FATAL_ERROR_FATAL_ERROR ||
1277         (value1 & SA_FATAL_ERROR_SP2_IOP_ERR_MASK) == SA_FATAL_ERROR_FATAL_ERROR    )
1278     {
1279       si_memset(&fatal_error, 0, sizeof(agsaFatalErrorInfo_t));
1280       /* read detail fatal errors */
1281       value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_0, MSGU_SCRATCH_PAD_0);
1282       fatal_error.errorInfo0 = value;
1283       SA_DBG1(("siProcessOBMsg: ScratchPad0 AAP error code 0x%x\n", value));
1284 
1285       value  = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_1, MSGU_SCRATCH_PAD_1);
1286       fatal_error.errorInfo1 = value;
1287       /* AAP error state */
1288       SA_DBG1(("siProcessOBMsg: AAP error state and error code 0x%x\n", value));
1289       value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_2, MSGU_SCRATCH_PAD_2);
1290       fatal_error.errorInfo2 = value;
1291       /* IOP error state */
1292       SA_DBG1(("siProcessOBMsg: IOP error state and error code 0x%x\n", value));
1293       value = siHalRegReadExt(agRoot, GEN_MSGU_SCRATCH_PAD_3, MSGU_SCRATCH_PAD_3);
1294       SA_DBG1(("siProcessOBMsg: ScratchPad3 IOP error code 0x%x\n", value));
1295       fatal_error.errorInfo3 = value;
1296 
1297       if (agNULL != saRoot)
1298       {
1299         fatal_error.regDumpBusBaseNum0 = saRoot->mainConfigTable.regDumpPCIBAR;
1300         fatal_error.regDumpOffset0 = saRoot->mainConfigTable.FatalErrorDumpOffset0;
1301         fatal_error.regDumpLen0 = saRoot->mainConfigTable.FatalErrorDumpLength0;
1302         fatal_error.regDumpBusBaseNum1 = saRoot->mainConfigTable.regDumpPCIBAR;
1303         fatal_error.regDumpOffset1 = saRoot->mainConfigTable.FatalErrorDumpOffset1;
1304         fatal_error.regDumpLen1 = saRoot->mainConfigTable.FatalErrorDumpLength1;
1305       }
1306       else
1307       {
1308         fatal_error.regDumpBusBaseNum0 = 0;
1309         fatal_error.regDumpOffset0 = 0;
1310         fatal_error.regDumpLen0 = 0;
1311         fatal_error.regDumpBusBaseNum1 = 0;
1312         fatal_error.regDumpOffset1 = 0;
1313         fatal_error.regDumpLen1 = 0;
1314       }
1315       /* Call Back with error */
1316       SA_DBG1(("siProcessOBMsg: SALLSDK_FATAL_ERROR_DETECT \n"));
1317       ossaHwCB(agRoot, agNULL, OSSA_HW_EVENT_MALFUNCTION, 0, (void *)&fatal_error, agNULL);
1318     }
1319   }
1320   }
1321 #endif /* SALLSDK_FATAL_ERROR_DETECT */
1322   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "5r");
1323   return processedMsgCount;
1324 }
1325 
1326 /******************************************************************************/
1327 /*! \brief Function to enable/disable interrupts
1328  *
1329  *  The saSystemInterruptsActive() function is called to indicate to the LL Layer
1330  *  whether interrupts are available. The parameter sysIntsActive indicates whether
1331  *  interrupts are available at this time.
1332  *
1333  *  \param agRoot handles for this instance of SAS/SATA hardware
1334  *  \param sysIntsActive flag for enable/disable interrupt
1335  *
1336  *  \return -void-
1337  *
1338  */
1339 /*******************************************************************************/
1340 GLOBAL void saSystemInterruptsActive(
1341   agsaRoot_t  *agRoot,
1342   agBOOLEAN   sysIntsActive
1343   )
1344 {
1345   bit32 x;
1346   agsaLLRoot_t  *saRoot;
1347 
1348   SA_ASSERT((agNULL != agRoot), "");
1349   if (agRoot == agNULL)
1350   {
1351     SA_DBG1(("saSystemInterruptsActive: agRoot == agNULL\n"));
1352     return;
1353   }
1354   saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1355   SA_ASSERT((agNULL != saRoot), "");
1356   if (saRoot == agNULL)
1357   {
1358     SA_DBG1(("saSystemInterruptsActive: saRoot == agNULL\n"));
1359     return;
1360   }
1361 
1362   smTraceFuncEnter(hpDBG_TICK_INT,"5s");
1363   SA_DBG1(("saSystemInterruptsActive: now 0x%X new 0x%x\n",saRoot->sysIntsActive,sysIntsActive));
1364   SA_DBG3(("saSystemInterruptsActive: Doorbell_Set  %08X U %08X\n",
1365                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
1366                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
1367   SA_DBG3(("saSystemInterruptsActive: Doorbell_Mask %08X U %08X\n",
1368                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register ),
1369                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU )));
1370 
1371   if( saRoot->sysIntsActive && sysIntsActive )
1372   {
1373     SA_DBG1(("saSystemInterruptsActive: Already active 0x%X new 0x%x\n",saRoot->sysIntsActive,sysIntsActive));
1374     smTraceFuncExit(hpDBG_TICK_INT, 'a', "5s");
1375     return;
1376   }
1377 
1378   if( !saRoot->sysIntsActive && !sysIntsActive )
1379   {
1380     if(smIS_SPC(agRoot))
1381     {
1382       siHalRegWriteExt(agRoot, GEN_MSGU_ODMR, MSGU_ODMR,AGSA_INTERRUPT_HANDLE_ALL_CHANNELS );
1383     }
1384     else
1385     {
1386       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_Register, AGSA_INTERRUPT_HANDLE_ALL_CHANNELS);
1387       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_RegisterU, AGSA_INTERRUPT_HANDLE_ALL_CHANNELS);
1388     }
1389     SA_DBG1(("saSystemInterruptsActive: Already disabled 0x%X new 0x%x\n",saRoot->sysIntsActive,sysIntsActive));
1390     smTraceFuncExit(hpDBG_TICK_INT, 'b', "5s");
1391     return;
1392   }
1393 
1394   /* Set the flag is sdkData */
1395   saRoot->sysIntsActive = (bit8)sysIntsActive;
1396 
1397 
1398   smTrace(hpDBG_TICK_INT,"Vq",sysIntsActive);
1399   /* TP:Vq sysIntsActive */
1400   /* If sysIntsActive is true */
1401   if ( agTRUE == sysIntsActive )
1402   {
1403 
1404     SA_DBG1(("saSystemInterruptsActive: Doorbell_Set  %08X U %08X\n",
1405                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
1406                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
1407     SA_DBG1(("saSystemInterruptsActive: Doorbell_Mask_Set  %08X U %08X\n",
1408                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register),
1409                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU)));
1410     if(smIS_SPCV(agRoot))
1411     {
1412       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Clear_Register, 0xFFFFFFFF);
1413       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Clear_RegisterU, 0xFFFFFFFF);
1414     }
1415     /* enable interrupt */
1416     for(x=0; x < saRoot->numInterruptVectors; x++)
1417     {
1418       ossaReenableInterrupts(agRoot,x );
1419     }
1420 
1421     if(saRoot->swConfig.fatalErrorInterruptEnable)
1422     {
1423       ossaReenableInterrupts(agRoot,saRoot->swConfig.fatalErrorInterruptVector );
1424     }
1425 
1426     siHalRegWriteExt(agRoot, GEN_MSGU_ODMR, MSGU_ODMR, 0);
1427   }
1428   /* If sysIntsActive is false */
1429   else
1430   {
1431     /* disable interrupt */
1432     if(smIS_SPC(agRoot))
1433     {
1434       siHalRegWriteExt(agRoot, GEN_MSGU_ODMR, MSGU_ODMR,AGSA_INTERRUPT_HANDLE_ALL_CHANNELS );
1435     }
1436     else
1437     {
1438       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_Register, AGSA_INTERRUPT_HANDLE_ALL_CHANNELS);
1439       ossaHwRegWriteExt(agRoot, PCIBAR0,V_Outbound_Doorbell_Mask_Set_RegisterU, AGSA_INTERRUPT_HANDLE_ALL_CHANNELS);
1440     }
1441   }
1442 
1443   SA_DBG3(("saSystemInterruptsActive: Doorbell_Set  %08X U %08X\n",
1444                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_Register),
1445                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Set_RegisterU)));
1446   SA_DBG3(("saSystemInterruptsActive: Doorbell_Mask %08X U %08X\n",
1447                            ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_Register ),
1448                              ossaHwRegReadExt(agRoot, PCIBAR0, V_Outbound_Doorbell_Mask_Set_RegisterU )));
1449 
1450 
1451   smTraceFuncExit(hpDBG_TICK_INT, 'c', "5s");
1452 }
1453 
1454 /******************************************************************************/
1455 /*! \brief Routine to handle for received SAS with data payload event
1456  *
1457  *  The handle for received SAS with data payload event
1458  *
1459  *  \param agRoot   handles for this instance of SAS/SATA hardware
1460  *  \param pRequest handles for the IOrequest
1461  *  \param pRespIU  the pointer to the Response IU
1462  *  \param param    Payload Length
1463  *
1464  *  \return -void-
1465  */
1466 /*******************************************************************************/
1467 GLOBAL void siEventSSPResponseWtDataRcvd(
1468   agsaRoot_t                *agRoot,
1469   agsaIORequestDesc_t       *pRequest,
1470   agsaSSPResponseInfoUnit_t *pRespIU,
1471   bit32                     param,
1472   bit32                     sspTag
1473   )
1474 {
1475   agsaLLRoot_t  *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1476   agsaDeviceDesc_t        *pDevice;
1477   bit32                   count = 0;
1478   bit32                   padCount;
1479 
1480   smTraceFuncEnter(hpDBG_VERY_LOUD,"5g");
1481 
1482   /* get frame handle */
1483 
1484   /* If the request is still valid */
1485   if ( agTRUE == pRequest->valid )
1486   {
1487     /* get device */
1488     pDevice = pRequest->pDevice;
1489 
1490     /* Delete the request from the pendingIORequests */
1491     ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1492     saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1493     ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1494 
1495     if (sspTag & SSP_RESCV_BIT)
1496     {
1497         /* get the pad count, bit 17 and 18 of sspTag */
1498       padCount = (sspTag >> SSP_RESCV_PAD_SHIFT) & 0x3;
1499       /* get Residual Count */
1500       count = *(bit32 *)((bit8 *)pRespIU + param + padCount);
1501     }
1502 
1503     (*(ossaSSPCompletedCB_t)(pRequest->completionCB))(agRoot,
1504                              pRequest->pIORequestContext,
1505                              OSSA_IO_SUCCESS,
1506                              param,
1507                              (void *)pRespIU,
1508                              (bit16)(sspTag & SSPTAG_BITS),
1509                              count);
1510 
1511     ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1512     pRequest->valid = agFALSE;
1513     /* return the request to free pool */
1514     if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
1515     {
1516       SA_DBG1(("siEventSSPResponseWtDataRcvd: saving pRequest (%p) for later use\n", pRequest));
1517       saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
1518     }
1519     else
1520     {
1521       /* return the request to free pool */
1522       saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1523     }
1524     ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1525 
1526   }
1527   else
1528   {
1529     SA_DBG1(("siEventSSPResponseWtDataRcvd: pRequest->Valid not TRUE\n"));
1530   }
1531 
1532   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5g");
1533 
1534   return;
1535 }
1536 
1537 /******************************************************************************/
1538 /*! \brief Routine to handle successfully completed IO event
1539  *
1540  *  Handle successfully completed IO
1541  *
1542  *  \param agRoot   handles for this instance of SAS/SATA hardware
1543  *  \param pRequest Pointer of IO request of the IO
1544  *  \param status   status of the IO
1545  *
1546  *  \return -void-
1547  */
1548 /*******************************************************************************/
1549 GLOBAL FORCEINLINE void siIODone(
1550   agsaRoot_t                *agRoot,
1551   agsaIORequestDesc_t       *pRequest,
1552   bit32                     status,
1553   bit32                     sspTag
1554   )
1555 {
1556   agsaLLRoot_t     *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1557   agsaDeviceDesc_t *pDevice = agNULL;
1558 
1559   smTraceFuncEnter(hpDBG_VERY_LOUD,"5h");
1560 
1561   SA_ASSERT(NULL != pRequest, "pRequest cannot be null");
1562 
1563   /* If the request is still valid */
1564   if ( agTRUE == pRequest->valid )
1565   {
1566     /* get device */
1567     pDevice = pRequest->pDevice;
1568 
1569     /* process different request type */
1570     switch (pRequest->requestType & AGSA_REQTYPE_MASK)
1571     {
1572       case AGSA_SSP_REQTYPE:
1573       {
1574         SA_ASSERT(pRequest->valid, "pRequest not valid");
1575         pRequest->completionCB(agRoot,
1576                                pRequest->pIORequestContext,
1577                                OSSA_IO_SUCCESS,
1578                                0,
1579                                agNULL,
1580                                (bit16)(sspTag & SSPTAG_BITS),
1581                                0);
1582         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1583         /* Delete the request from the pendingIORequests */
1584         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1585         /* return the request to free pool */
1586         pRequest->valid = agFALSE;
1587         saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1588         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1589 
1590 
1591         break;
1592       }
1593       case AGSA_SATA_REQTYPE:
1594       {
1595         SA_DBG5(("siIODone: SATA complete\n"));
1596 
1597         if ( agNULL != pRequest->pIORequestContext )
1598         {
1599           SA_DBG5(("siIODone: Complete Request\n"));
1600 
1601           (*(ossaSATACompletedCB_t)(pRequest->completionCB))(agRoot,
1602                                                              pRequest->pIORequestContext,
1603                                                              OSSA_IO_SUCCESS,
1604                                                              agNULL,
1605                                                              0,
1606                                                              agNULL);
1607         }
1608         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1609         /* Delete the request from the pendingIORequests */
1610         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1611         /* return the request to free pool */
1612         saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1613         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1614 
1615         pRequest->valid = agFALSE;
1616 
1617         break;
1618       }
1619       case AGSA_SMP_REQTYPE:
1620       {
1621         if ( agNULL != pRequest->pIORequestContext )
1622         {
1623           (*(ossaSMPCompletedCB_t)(pRequest->completionCB))(agRoot,
1624                                                             pRequest->pIORequestContext,
1625                                                             OSSA_IO_SUCCESS,
1626                                                             0,
1627                                                             agNULL);
1628         }
1629 
1630         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1631         /* Delete the request from the pendingSMPRequests */
1632         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1633         /* return the request to free pool */
1634         if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
1635         {
1636           SA_DBG1(("siIODone: saving pRequest (%p) for later use\n", pRequest));
1637           saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
1638         }
1639         else
1640         {
1641           saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1642         }
1643         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1644 
1645         pRequest->valid = agFALSE;
1646 
1647         break;
1648       }
1649       default:
1650       {
1651         SA_DBG1(("siIODone: unknown request type (%x) is completed. HTag=0x%x\n", pRequest->requestType, pRequest->HTag));
1652         break;
1653       }
1654     }
1655   }
1656   else
1657   {
1658     SA_DBG1(("siIODone: The request is not valid any more. HTag=0x%x requestType=0x%x\n", pRequest->HTag, pRequest->requestType));
1659   }
1660 
1661   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5h");
1662 
1663 }
1664 
1665 /******************************************************************************/
1666 /*! \brief Routine to handle abnormal completed IO/SMP event
1667  *
1668  *  Handle abnormal completed IO/SMP
1669  *
1670  *  \param agRoot   handles for this instance of SAS/SATA hardware
1671  *  \param pRequest Pointer of IO request of the IO
1672  *  \param status   status of the IO
1673  *  \param param    Length
1674  *
1675  *  \return -void-
1676  */
1677 /*******************************************************************************/
1678 GLOBAL void siAbnormal(
1679   agsaRoot_t                *agRoot,
1680   agsaIORequestDesc_t       *pRequest,
1681   bit32                     status,
1682   bit32                     param,
1683   bit32                     sspTag
1684   )
1685 {
1686   agsaLLRoot_t     *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1687   agsaDeviceDesc_t *pDevice;
1688 
1689   smTraceFuncEnter(hpDBG_VERY_LOUD,"5i");
1690 
1691   if (agNULL == pRequest)
1692   {
1693     SA_DBG1(("siAbnormal: pRequest is NULL.\n"));
1694     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5i");
1695     return;
1696   }
1697 
1698   /* If the request is still valid */
1699   if ( agTRUE == pRequest->valid )
1700   {
1701     /* get device */
1702 
1703     SA_ASSERT((pRequest->pIORequestContext->osData != pRequest->pIORequestContext->sdkData), "pIORequestContext");
1704 
1705     pDevice = pRequest->pDevice;
1706 
1707     /* remove the IO request from IOMap */
1708     saRoot->IOMap[pRequest->HTag].Tag = MARK_OFF;
1709     saRoot->IOMap[pRequest->HTag].IORequest = agNULL;
1710     saRoot->IOMap[pRequest->HTag].agContext = agNULL;
1711 
1712     smTrace(hpDBG_VERY_LOUD,"P6",status );
1713      /* TP:P6 siAbnormal status */
1714     smTrace(hpDBG_VERY_LOUD,"P7",param );
1715      /* TP:P7 siAbnormal param */
1716     /* process different request type */
1717     switch (pRequest->requestType & AGSA_REQTYPE_MASK)
1718     {
1719       case AGSA_SSP_REQTYPE:
1720       {
1721         (*(ossaSSPCompletedCB_t)(pRequest->completionCB))(agRoot,
1722                                                           pRequest->pIORequestContext,
1723                                                           status,
1724                                                           param,
1725                                                           agNULL,
1726                                                           (bit16)(sspTag & SSPTAG_BITS),
1727                                                           ((sspTag & SSP_AGR_S_BIT)? (1 << 0) : 0));
1728 
1729         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1730         /* Delete the request from the pendingIORequests */
1731         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1732         pRequest->valid = agFALSE;
1733         /* return the request to free pool */
1734         if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
1735         {
1736           SA_DBG1(("siAbnormal: saving pRequest (%p) for later use\n", pRequest));
1737           saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
1738         }
1739         else
1740         {
1741           /* return the request to free pool */
1742           saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1743         }
1744         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1745 
1746         break;
1747       }
1748       case AGSA_SATA_REQTYPE:
1749       {
1750         SA_DBG5(("siAbnormal: SATA \n"));
1751 
1752         if ( agNULL != pRequest->pIORequestContext )
1753         {
1754           SA_DBG5(("siAbnormal: Calling SATACompletedCB\n"));
1755 
1756           (*(ossaSATACompletedCB_t)(pRequest->completionCB))(agRoot,
1757                                                              pRequest->pIORequestContext,
1758                                                              status,
1759                                                              agNULL,
1760                                                              param,
1761                                                              agNULL);
1762         }
1763 
1764         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1765         /* Delete the request from the pendingIORequests */
1766         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1767         /* return the request to free pool */
1768         pRequest->valid = agFALSE;
1769         if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
1770         {
1771           SA_DBG1(("siAbnormal: saving pRequest (%p) for later use\n", pRequest));
1772           saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
1773         }
1774         else
1775         {
1776           /* return the request to free pool */
1777           saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1778         }
1779         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1780 
1781         break;
1782       }
1783       case AGSA_SMP_REQTYPE:
1784       {
1785         if ( agNULL != pRequest->pIORequestContext )
1786         {
1787           (*(ossaSMPCompletedCB_t)(pRequest->completionCB))(agRoot,
1788                                                             pRequest->pIORequestContext,
1789                                                             status,
1790                                                             param,
1791                                                             agNULL);
1792         }
1793 
1794         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1795         /* Delete the request from the pendingSMPRequests */
1796         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1797         /* return the request to free pool */
1798         pRequest->valid = agFALSE;
1799         if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
1800         {
1801           SA_DBG1(("siAbnormal: saving pRequest (%p) for later use\n", pRequest));
1802           saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
1803         }
1804         else
1805         {
1806           /* return the request to free pool */
1807           saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1808         }
1809         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1810 
1811         break;
1812       }
1813       default:
1814       {
1815         SA_DBG1(("siAbnormal: unknown request type (%x) is completed. Tag=0x%x\n", pRequest->requestType, pRequest->HTag));
1816         break;
1817       }
1818     }
1819 
1820   }
1821   else
1822   {
1823     SA_DBG1(("siAbnormal: The request is not valid any more. Tag=0x%x\n", pRequest->HTag));
1824   }
1825 
1826   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "5i");
1827 
1828   return;
1829 }
1830 
1831 
1832 /******************************************************************************/
1833 /*! \brief Routine to handle abnormal DIF completed IO/SMP event
1834  *
1835  *  Handle abnormal completed IO/SMP
1836  *
1837  *  \param agRoot   handles for this instance of SAS/SATA hardware
1838  *  \param pRequest Pointer of IO request of the IO
1839  *  \param status   status of the IO
1840  *  \param param    Length
1841  *
1842  *  \return -void-
1843  */
1844 /*******************************************************************************/
1845 GLOBAL void siDifAbnormal(
1846   agsaRoot_t          *agRoot,
1847   agsaIORequestDesc_t *pRequest,
1848   bit32               status,
1849   bit32               param,
1850   bit32               sspTag,
1851   bit32               *pMsg1
1852   )
1853 {
1854   agsaLLRoot_t     *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1855   agsaDeviceDesc_t *pDevice;
1856 
1857   smTraceFuncEnter(hpDBG_VERY_LOUD,"2S");
1858 
1859   if (agNULL == pRequest)
1860   {
1861     SA_DBG1(("siDifAbnormal: pRequest is NULL.\n"));
1862     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "2S");
1863     return;
1864   }
1865 
1866   /* If the request is still valid */
1867   if ( agTRUE == pRequest->valid )
1868   {
1869     /* get device */
1870     pDevice = pRequest->pDevice;
1871 
1872     /* remove the IO request from IOMap */
1873     saRoot->IOMap[pRequest->HTag].Tag = MARK_OFF;
1874     saRoot->IOMap[pRequest->HTag].IORequest = agNULL;
1875     saRoot->IOMap[pRequest->HTag].agContext = agNULL;
1876 
1877     smTrace(hpDBG_VERY_LOUD,"P6",status );
1878      /* TP:P6 siDifAbnormal status */
1879     /* process different request type */
1880     switch (pRequest->requestType & AGSA_REQTYPE_MASK)
1881     {
1882       case AGSA_SSP_REQTYPE:
1883       {
1884         agsaDifDetails_t          agDifDetails;
1885         agsaSSPCompletionDifRsp_t    *pIomb;
1886         pIomb = (agsaSSPCompletionDifRsp_t *)pMsg1;
1887         si_memset(&agDifDetails, 0, sizeof(agDifDetails));
1888 
1889         OSSA_READ_LE_32(agRoot, &agDifDetails.UpperLBA,           pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,UpperLBA ));
1890         OSSA_READ_LE_32(agRoot, &agDifDetails.LowerLBA,           pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,LowerLBA ));
1891         OSSA_READ_LE_32(agRoot, &agDifDetails.sasAddressHi,       pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,sasAddressHi ));
1892         OSSA_READ_LE_32(agRoot, &agDifDetails.sasAddressLo,       pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,sasAddressLo));
1893         OSSA_READ_LE_32(agRoot, &agDifDetails.ExpectedCRCUDT01,   pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,ExpectedCRCUDT01 ));
1894         OSSA_READ_LE_32(agRoot, &agDifDetails.ExpectedUDT2345,    pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,ExpectedUDT2345));
1895         OSSA_READ_LE_32(agRoot, &agDifDetails.ActualCRCUDT01,     pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,ActualCRCUDT01 ));
1896         OSSA_READ_LE_32(agRoot, &agDifDetails.ActualUDT2345,      pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,ActualUDT2345));
1897         OSSA_READ_LE_32(agRoot, &agDifDetails.DIFErrDevID,        pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,DIFErrDevID ));
1898         OSSA_READ_LE_32(agRoot, &agDifDetails.ErrBoffsetEDataLen, pIomb, OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t,ErrBoffsetEDataLen ));
1899         agDifDetails.frame = (void *)(bit8*)(pIomb+ OSSA_OFFSET_OF(agsaSSPCompletionDifRsp_t, EDATA_FRM));
1900 
1901         (*(ossaSSPCompletedCB_t)(pRequest->completionCB))(agRoot,
1902                                                           pRequest->pIORequestContext,
1903                                                           status,
1904                                                           param,
1905                                                           &agDifDetails,
1906                                                           (bit16)(sspTag & SSPTAG_BITS),
1907                     ((sspTag & SSP_AGR_S_BIT)? (1 << 0) : 0));
1908 
1909         ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1910         pRequest->valid = agFALSE;
1911         /* Delete the request from the pendingIORequests */
1912         saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
1913 
1914         /* return the request to free pool */
1915         if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
1916         {
1917           SA_DBG1(("siDifAbnormal: saving pRequest (%p) for later use\n", pRequest));
1918           saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
1919         }
1920         else
1921         {
1922           /* return the request to free pool */
1923           saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
1924         }
1925         ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
1926 
1927         break;
1928       }
1929       default:
1930       {
1931         SA_DBG1(("siDifAbnormal: unknown request type (%x) is completed. Tag=0x%x\n", pRequest->requestType, pRequest->HTag));
1932         break;
1933       }
1934     }
1935 
1936   }
1937   else
1938   {
1939     SA_DBG1(("siDifAbnormal: The request is not valid any more. Tag=0x%x\n", pRequest->HTag));
1940   }
1941 
1942   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "2S");
1943 
1944   return;
1945 }
1946 
1947 
1948 /******************************************************************************/
1949 /*! \brief Routine to handle for received SMP response event
1950  *
1951  *  The handle for received SMP response event
1952  *
1953  *  \param agRoot      handles for this instance of SAS/SATA hardware
1954  *  \param pIomb       Pointer of payload of IOMB
1955  *  \param payloadSize size of the payload
1956  *  \param tag         the tag of the request SMP
1957  *
1958  *  \return -void-
1959  */
1960 /*******************************************************************************/
1961 GLOBAL void siSMPRespRcvd(
1962   agsaRoot_t              *agRoot,
1963   agsaSMPCompletionRsp_t  *pIomb,
1964   bit32                   payloadSize,
1965   bit32                   tag
1966   )
1967 {
1968   agsaLLRoot_t            *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
1969   agsaFrameHandle_t       frameHandle;
1970   agsaIORequestDesc_t     *pRequest;
1971   agsaDeviceDesc_t        *pDevice;
1972   agsaPort_t              *pPort;
1973 
1974   smTraceFuncEnter(hpDBG_VERY_LOUD,"5j");
1975 
1976   /* get the request */
1977   pRequest = (agsaIORequestDesc_t*)saRoot->IOMap[tag].IORequest;
1978   SA_ASSERT(pRequest, "pRequest");
1979 
1980   /* get the port */
1981   pPort = pRequest->pPort;
1982   SA_ASSERT(pPort, "pPort");
1983 
1984   if (pRequest->IRmode == 0)
1985   {
1986     /* get frame handle - direct response mode */
1987     frameHandle = (agsaFrameHandle_t)(&(pIomb->SMPrsp[0]));
1988 #if defined(SALLSDK_DEBUG)
1989     SA_DBG3(("saSMPRespRcvd(direct): smpRspPtr=0x%p - len=0x%x\n",
1990         frameHandle,
1991         payloadSize
1992         ));
1993 #endif /* SALLSDK_DEBUG */
1994   }
1995   else
1996   {
1997     /* indirect response mode */
1998     frameHandle = agNULL;
1999   }
2000 
2001   /* If the request is still valid */
2002   if ( agTRUE == pRequest->valid )
2003   {
2004     /* get device */
2005     pDevice = pRequest->pDevice;
2006     SA_ASSERT(pDevice, "pDevice");
2007 
2008     /* Delete the request from the pendingSMPRequests */
2009     ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
2010     saLlistIORemove(&(pDevice->pendingIORequests), &(pRequest->linkNode));
2011     ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
2012 
2013     /* If the request is from OS layer */
2014     if ( agNULL != pRequest->pIORequestContext )
2015     {
2016       if (agNULL == frameHandle)
2017       {
2018         /* indirect mode */
2019         /* call back with success */
2020         (*(ossaSMPCompletedCB_t)(pRequest->completionCB))(agRoot, pRequest->pIORequestContext, OSSA_IO_SUCCESS, payloadSize, frameHandle);
2021       }
2022       else
2023       {
2024         /* direct mode */
2025         /* call back with success */
2026         (*(ossaSMPCompletedCB_t)(pRequest->completionCB))(agRoot, pRequest->pIORequestContext, OSSA_IO_SUCCESS, payloadSize, frameHandle);
2027       }
2028     }
2029 
2030     /* remove the IO request from IOMap */
2031     saRoot->IOMap[tag].Tag = MARK_OFF;
2032     saRoot->IOMap[tag].IORequest = agNULL;
2033     saRoot->IOMap[tag].agContext = agNULL;
2034     ossaSingleThreadedEnter(agRoot, LL_IOREQ_LOCKEQ_LOCK);
2035     pRequest->valid = agFALSE;
2036     if(saLlistIOGetCount(&(saRoot->freeReservedRequests)) < SA_RESERVED_REQUEST_COUNT)
2037     {
2038       SA_DBG1(("siSMPRespRcvd: saving pRequest (%p) for later use\n", pRequest));
2039       saLlistIOAdd(&(saRoot->freeReservedRequests), &(pRequest->linkNode));
2040     }
2041     else
2042     {
2043       /* return the request to free pool */
2044       saLlistIOAdd(&(saRoot->freeIORequests), &(pRequest->linkNode));
2045     }
2046     ossaSingleThreadedLeave(agRoot, LL_IOREQ_LOCKEQ_LOCK);
2047   }
2048 
2049   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5j");
2050 
2051   return;
2052 }
2053 
2054 /******************************************************************************/
2055 /*! \brief Routine to handle for received Phy Up event
2056  *
2057  *  The handle for received Phy Up event
2058  *
2059  *  \param agRoot handles for this instance of SAS/SATA hardware
2060  *  \param phyId for the Phy Up event happened
2061  *  \param agSASIdentify is the remote phy Identify
2062  *  \param portId is the port context index of the phy up event
2063  *  \param deviceId is the device context index
2064  *  \param linkRate link up rate from SPC
2065  *
2066  *  \return -void-
2067  */
2068 /*******************************************************************************/
2069 GLOBAL void siEventPhyUpRcvd(
2070   agsaRoot_t        *agRoot,
2071   bit32             phyId,
2072   agsaSASIdentify_t *agSASIdentify,
2073   bit32             portId,
2074   bit32             npipps,
2075   bit8              linkRate
2076   )
2077 {
2078   agsaLLRoot_t      *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
2079   agsaPhy_t         *pPhy = &(saRoot->phys[phyId]);
2080   agsaPort_t        *pPort;
2081   agsaSASIdentify_t remoteIdentify;
2082   agsaPortContext_t *agPortContext;
2083 
2084   smTraceFuncEnter(hpDBG_VERY_LOUD,"5k");
2085 
2086   /* Read remote SAS Identify from response message and save it */
2087   remoteIdentify = *agSASIdentify;
2088 
2089   /* get port context from portMap */
2090   SA_DBG2(("siEventPhyUpRcvd:PortID 0x%x PortStatus 0x%x PortContext %p\n",saRoot->PortMap[portId & PORTID_MASK].PortID,saRoot->PortMap[portId & PORTID_MASK].PortStatus,saRoot->PortMap[portId & PORTID_MASK].PortContext));
2091   agPortContext = (agsaPortContext_t *)saRoot->PortMap[portId].PortContext;
2092 
2093   SA_DBG2(("siEventPhyUpRcvd: portID %d PortContext %p linkRate 0x%X\n", portId, agPortContext,linkRate));
2094   if (smIS_SPCV8006(agRoot))
2095   {
2096     SA_DBG1(("siEventPhyUpRcvd: SAS_PHY_UP received for SATA Controller\n"));
2097     return;
2098   }
2099 
2100   if (agNULL != agPortContext)
2101   {
2102     /* existing port */
2103     pPort = (agsaPort_t *) (agPortContext->sdkData);
2104     pPort->portId = portId;
2105 
2106     /* include the phy to the port */
2107     pPort->phyMap[phyId] = agTRUE;
2108     /* Set the port for the phy */
2109     saRoot->phys[phyId].pPort = pPort;
2110 
2111     /* Update port state */
2112     if (OSSA_PORT_VALID == (npipps & PORT_STATE_MASK))
2113     {
2114       pPort->status &= ~PORT_INVALIDATING;
2115       saRoot->PortMap[portId].PortStatus  &= ~PORT_INVALIDATING;
2116       SA_DBG1(("siEventPhyUpRcvd: portID %d PortContext %p, hitting workaround\n", portId, agPortContext));
2117     }
2118   }
2119   else
2120   {
2121     ossaSingleThreadedEnter(agRoot, LL_PORT_LOCK);
2122     /* new port */
2123     /* Allocate a free port */
2124     pPort = (agsaPort_t *) saLlistGetHead(&(saRoot->freePorts));
2125     if (agNULL != pPort)
2126     {
2127       /* Acquire port list lock */
2128       saLlistRemove(&(saRoot->freePorts), &(pPort->linkNode));
2129 
2130       /* setup the port data structure */
2131       pPort->portContext.osData = agNULL;
2132       pPort->portContext.sdkData = pPort;
2133 
2134       /* Add to valid port list */
2135       saLlistAdd(&(saRoot->validPorts), &(pPort->linkNode));
2136       /* Release port list lock */
2137       ossaSingleThreadedLeave(agRoot, LL_PORT_LOCK);
2138 
2139       /* include the phy to the port */
2140       pPort->phyMap[phyId] = agTRUE;
2141       /* Set the port for the phy */
2142       saRoot->phys[phyId].pPort = pPort;
2143 
2144       /* Setup portMap based on portId */
2145       saRoot->PortMap[portId].PortID = portId;
2146       saRoot->PortMap[portId].PortContext = &(pPort->portContext);
2147       pPort->portId = portId;
2148 
2149       SA_DBG3(("siEventPhyUpRcvd: NewPort portID %d PortContext %p\n", portId, saRoot->PortMap[portId].PortContext));
2150     }
2151     else
2152     {
2153       ossaSingleThreadedLeave(agRoot, LL_PORT_LOCK);
2154       /* pPort is agNULL*/
2155       smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5k");
2156       return;
2157     }
2158 
2159     if (OSSA_PORT_VALID == (npipps & PORT_STATE_MASK))
2160     {
2161       pPort->status &= ~PORT_INVALIDATING;
2162       saRoot->PortMap[portId].PortStatus  &= ~PORT_INVALIDATING;
2163     }
2164     else
2165     {
2166       SA_DBG1(("siEventPhyUpRcvd: PortInvalid portID %d PortContext %p\n", portId, saRoot->PortMap[portId].PortContext));
2167     }
2168   }
2169 
2170   /* adjust the bit fields before callback */
2171   phyId = (linkRate << SHIFT8) | phyId;
2172   /* report PhyId, NPIP, PortState */
2173   phyId |= (npipps & PHY_IN_PORT_MASK) | ((npipps & PORT_STATE_MASK) << SHIFT16);
2174   ossaHwCB(agRoot, &(pPort->portContext), OSSA_HW_EVENT_SAS_PHY_UP, phyId, agNULL, &remoteIdentify);
2175 
2176   /* set PHY_UP status */
2177   PHY_STATUS_SET(pPhy, PHY_UP);
2178 
2179   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "5k");
2180 
2181   /* return */
2182   return;
2183 }
2184 
2185 /******************************************************************************/
2186 /*! \brief Routine to handle for received SATA signature event
2187  *
2188  *  The handle for received SATA signature event
2189  *
2190  *  \param agRoot   handles for this instance of SAS/SATA hardware
2191  *  \param phyId    the phy id of the phy received the frame
2192  *  \param pMsg     the pointer to the message payload
2193  *  \param portId   the port context index of the phy up event
2194  *  \param deviceId the device context index
2195  *  \param linkRate link up rate from SPC
2196  *
2197  *  \return -void-
2198  */
2199 /*******************************************************************************/
2200 GLOBAL void siEventSATASignatureRcvd(
2201   agsaRoot_t    *agRoot,
2202   bit32         phyId,
2203   void          *pMsg,
2204   bit32         portId,
2205   bit32         npipps,
2206   bit8          linkRate
2207   )
2208 {
2209   agsaLLRoot_t                *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
2210   agsaPhy_t                   *pPhy = &(saRoot->phys[phyId]);
2211   agsaPort_t                  *pPort = agNULL;
2212   agsaPortContext_t           *agPortContext;
2213 #if defined(SALLSDK_DEBUG)
2214   agsaFisRegDeviceToHost_t    *fisD2H;
2215   /* Read the D2H FIS */
2216   fisD2H = (agsaFisRegDeviceToHost_t *)pMsg;
2217 #endif  /* SALLSDK_DEBUG */
2218 
2219   smTraceFuncEnter(hpDBG_VERY_LOUD,"5m");
2220 
2221   SA_DBG5(("siEventSATASignatureRcvd: About to read the signatureFIS data\n"));
2222 
2223 
2224   SA_DBG5(("agsaFisRegDeviceToHost_t:\n"));
2225   SA_DBG5(("  fisType         = %x\n", fisD2H->h.fisType));
2226   SA_DBG5(("  i_pmPort        = %x\n", fisD2H->h.i_pmPort));
2227   SA_DBG5(("  status          = %x\n", fisD2H->h.status));
2228   SA_DBG5(("  error           = %x\n", fisD2H->h.error));
2229 
2230   SA_DBG5(("  lbaLow          = %x\n", fisD2H->d.lbaLow));
2231   SA_DBG5(("  lbaMid          = %x\n", fisD2H->d.lbaMid));
2232   SA_DBG5(("  lbaHigh         = %x\n", fisD2H->d.lbaHigh));
2233   SA_DBG5(("  device          = %x\n", fisD2H->d.device));
2234 
2235   SA_DBG5(("  lbaLowExp       = %x\n", fisD2H->d.lbaLowExp));
2236   SA_DBG5(("  lbaMidExp       = %x\n", fisD2H->d.lbaMidExp));
2237   SA_DBG5(("  lbaHighExp      = %x\n", fisD2H->d.lbaHighExp));
2238   SA_DBG5(("  reserved4       = %x\n", fisD2H->d.reserved4));
2239 
2240   SA_DBG5(("  sectorCount     = %x\n", fisD2H->d.sectorCount));
2241   SA_DBG5(("  sectorCountExp  = %x\n", fisD2H->d.sectorCountExp));
2242   SA_DBG5(("  reserved5       = %x\n", fisD2H->d.reserved5));
2243   SA_DBG5(("  reserved6       = %x\n", fisD2H->d.reserved6));
2244 
2245   SA_DBG5(("  reserved7 (32)  = %08X\n", fisD2H->d.reserved7));
2246 
2247   SA_DBG5(("siEventSATASignatureRcvd: GOOD signatureFIS data\n"));
2248 
2249 #if defined(SALLSDK_DEBUG)
2250   /* read signature */
2251   pPhy->remoteSignature[0] = (bit8) fisD2H->d.sectorCount;
2252   pPhy->remoteSignature[1] = (bit8) fisD2H->d.lbaLow;
2253   pPhy->remoteSignature[2] = (bit8) fisD2H->d.lbaMid;
2254   pPhy->remoteSignature[3] = (bit8) fisD2H->d.lbaHigh;
2255   pPhy->remoteSignature[4] = (bit8) fisD2H->d.device;
2256 #endif
2257 
2258   /* get port context from portMap */
2259   SA_DBG2(("siEventSATASignatureRcvd:PortID 0x%x PortStatus 0x%x PortContext %p\n",saRoot->PortMap[portId & PORTID_MASK].PortID,saRoot->PortMap[portId & PORTID_MASK].PortStatus,saRoot->PortMap[portId & PORTID_MASK].PortContext));
2260   agPortContext = (agsaPortContext_t *)saRoot->PortMap[portId].PortContext;
2261 
2262   SA_DBG2(("siEventSATASignatureRcvd: portID %d PortContext %p\n", portId, agPortContext));
2263 
2264   if (agNULL != agPortContext)
2265   {
2266     /* exist port */
2267     pPort = (agsaPort_t *) (agPortContext->sdkData);
2268     pPort->portId = portId;
2269 
2270     /* include the phy to the port */
2271     pPort->phyMap[phyId] = agTRUE;
2272     /* Set the port for the phy */
2273     saRoot->phys[phyId].pPort = pPort;
2274   }
2275   else
2276   {
2277     ossaSingleThreadedEnter(agRoot, LL_PORT_LOCK);
2278     /* new port */
2279     /* Allocate a free port */
2280     pPort = (agsaPort_t *) saLlistGetHead(&(saRoot->freePorts));
2281     if (agNULL != pPort)
2282     {
2283       /* Acquire port list lock */
2284       saLlistRemove(&(saRoot->freePorts), &(pPort->linkNode));
2285 
2286       /* setup the port data structure */
2287       pPort->portContext.osData = agNULL;
2288       pPort->portContext.sdkData = pPort;
2289 
2290       /* Add to valid port list */
2291       saLlistAdd(&(saRoot->validPorts), &(pPort->linkNode));
2292       /* Release port list lock */
2293       ossaSingleThreadedLeave(agRoot, LL_PORT_LOCK);
2294 
2295       /* include the phy to the port */
2296       pPort->phyMap[phyId] = agTRUE;
2297       /* Set the port for the phy */
2298       saRoot->phys[phyId].pPort = pPort;
2299 
2300       /* Setup portMap based on portId */
2301       saRoot->PortMap[portId].PortID = portId;
2302       saRoot->PortMap[portId].PortContext = &(pPort->portContext);
2303       pPort->portId = portId;
2304       SA_DBG3(("siEventSATASignatureRcvd: NewPort portID %d portContect %p\n", portId, saRoot->PortMap[portId].PortContext));
2305     }
2306     else
2307     {
2308       ossaSingleThreadedLeave(agRoot, LL_PORT_LOCK);
2309       /* pPort is agNULL*/
2310       smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5m");
2311       return;
2312     }
2313 
2314     if (OSSA_PORT_VALID == (npipps & PORT_STATE_MASK))
2315     {
2316       pPort->status &= ~PORT_INVALIDATING;
2317       saRoot->PortMap[portId].PortStatus  &= ~PORT_INVALIDATING;
2318     }
2319     else
2320     {
2321       SA_DBG1(("siEventSATASignatureRcvd: PortInvalid portID %d PortContext %p\n", portId, saRoot->PortMap[portId].PortContext));
2322     }
2323   }
2324 
2325   /* adjust the bit fields before callback */
2326   phyId = (linkRate << SHIFT8) | phyId;
2327   /* report PhyId, NPIP, PortState */
2328   phyId |= (npipps & PHY_IN_PORT_MASK) | ((npipps & PORT_STATE_MASK) << SHIFT16);
2329   ossaHwCB(agRoot, &(pPort->portContext), OSSA_HW_EVENT_SATA_PHY_UP, phyId, agNULL, pMsg);
2330 
2331   /* set PHY_UP status */
2332   PHY_STATUS_SET(pPhy, PHY_UP);
2333 
2334   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "5m");
2335 
2336   /* return */
2337   return;
2338 }
2339 
2340 
2341 /******************************************************************************/
2342 /*! \brief Process Outbound IOMB Message
2343  *
2344  *  Process Outbound IOMB from SPC
2345  *
2346  *  \param agRoot       Handles for this instance of SAS/SATA LL Layer
2347  *  \param pMsg1        Pointer of Response IOMB message 1
2348  *  \param category     category of outbpond IOMB header
2349  *  \param opcode       Opcode of Outbound IOMB header
2350  *  \param bc           buffer count of IOMB header
2351  *
2352  *  \return success or fail
2353  *
2354  */
2355 /*******************************************************************************/
2356 GLOBAL bit32 mpiParseOBIomb(
2357   agsaRoot_t        *agRoot,
2358   bit32             *pMsg1,
2359   mpiMsgCategory_t  category,
2360   bit16             opcode
2361   )
2362 {
2363   agsaLLRoot_t      *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
2364   bit32              ret = AGSA_RC_SUCCESS;
2365   bit32              parserStatus = AGSA_RC_SUCCESS;
2366 
2367   smTraceFuncEnter(hpDBG_VERY_LOUD, "2f");
2368 
2369   switch (opcode)
2370   {
2371     case OPC_OUB_COMBINED_SSP_COMP:
2372     {
2373       agsaSSPCoalescedCompletionRsp_t  *pIomb = (agsaSSPCoalescedCompletionRsp_t *)pMsg1;
2374       agsaIORequestDesc_t              *pRequest = agNULL;
2375       bit32  tag     = 0;
2376       bit32  sspTag  = 0;
2377       bit32  count   = 0;
2378 
2379 #ifdef SALL_API_TEST
2380       saRoot->LLCounters.IOCounter.numSSPCompleted++;
2381       SA_DBG3(("mpiParseOBIomb, SSP_COMP Response received IOMB=%p %d\n",
2382          pMsg1, saRoot->LLCounters.IOCounter.numSSPCompleted));
2383 #else
2384       SA_DBG3(("mpiParseOBIomb, OPC_OUB_COMBINED_SSP_COMP Response received IOMB=%p\n", pMsg1));
2385 #endif
2386       /* get Tag */
2387       for (count = 0; count < pIomb->coalescedCount; count++)
2388       {
2389         tag = pIomb->sspComplCxt[count].tag;
2390         sspTag = pIomb->sspComplCxt[count].SSPTag;
2391         pRequest = (agsaIORequestDesc_t *)saRoot->IOMap[tag].IORequest;
2392         SA_ASSERT((pRequest), "pRequest");
2393 
2394         if(pRequest == agNULL)
2395         {
2396           SA_DBG1(("mpiParseOBIomb,OPC_OUB_COMBINED_SSP_COMP Resp IOMB tag=0x%x, status=0x%x, param=0x%x, SSPTag=0x%x\n", tag, OSSA_IO_SUCCESS, 0, sspTag));
2397 #ifdef SA_ENABLE_PCI_TRIGGER
2398           if( saRoot->swConfig.PCI_trigger & PCI_TRIGGER_COAL_IOMB_ERROR )
2399           {
2400             siPCITriger(agRoot);
2401           }
2402 #endif /* SA_ENABLE_PCI_TRIGGER */
2403           return(AGSA_RC_FAILURE);
2404         }
2405         SA_ASSERT((pRequest->valid), "pRequest->valid");
2406 
2407 #ifdef SA_ENABLE_PCI_TRIGGER
2408         if(!pRequest->valid)
2409         {
2410           if( saRoot->swConfig.PCI_trigger & PCI_TRIGGER_COAL_INVALID )
2411           {
2412             siPCITriger(agRoot);
2413           }
2414         }
2415 #endif /* SA_ENABLE_PCI_TRIGGER */
2416 
2417 
2418         SA_DBG3(("mpiParseOBIomb, OPC_OUB_COMBINED_SSP_COMP IOMB tag=0x%x, status=0x%x, param=0x%x, SSPTag=0x%x\n", tag, OSSA_IO_SUCCESS, 0, sspTag));
2419 
2420         /* Completion of SSP without Response Data */
2421         siIODone( agRoot, pRequest, OSSA_IO_SUCCESS, sspTag);
2422       }
2423     }
2424     break;
2425 
2426     case OPC_OUB_SSP_COMP:
2427     {
2428 #ifdef SALL_API_TEST
2429       saRoot->LLCounters.IOCounter.numSSPCompleted++;
2430       SA_DBG3(("mpiParseOBIomb, SSP_COMP Response received IOMB=%p %d\n",
2431          pMsg1, saRoot->LLCounters.IOCounter.numSSPCompleted));
2432 #else
2433       SA_DBG3(("mpiParseOBIomb, SSP_COMP Response received IOMB=%p\n", pMsg1));
2434 #endif
2435       /* process the SSP IO Completed response message */
2436       mpiSSPCompletion(agRoot, pMsg1);
2437       break;
2438     }
2439     case OPC_OUB_COMBINED_SATA_COMP:
2440     {
2441       agsaSATACoalescedCompletionRsp_t    *pIomb;
2442       agsaIORequestDesc_t       *pRequest;
2443       bit32                     tag;
2444       bit32                     count;
2445 
2446     #ifdef SALL_API_TEST
2447       saRoot->LLCounters.IOCounter.numSSPCompleted++;
2448       SA_DBG3(("mpiParseOBIomb, OPC_OUB_COMBINED_SATA_COMP Response received IOMB=%p %d\n",
2449          pMsg1, saRoot->LLCounters.IOCounter.numSSPCompleted));
2450     #else
2451       SA_DBG3(("mpiParseOBIomb, OPC_OUB_COMBINED_SATA_COMP Response received IOMB=%p\n", pMsg1));
2452     #endif
2453 
2454       pIomb = (agsaSATACoalescedCompletionRsp_t *)pMsg1;
2455       /* get Tag */
2456       for (count = 0; count < pIomb->coalescedCount; count++)
2457       {
2458         tag = pIomb->stpComplCxt[count].tag;
2459         pRequest = (agsaIORequestDesc_t *)saRoot->IOMap[tag].IORequest;
2460         SA_ASSERT((pRequest), "pRequest");
2461 
2462         if(pRequest == agNULL)
2463         {
2464           SA_DBG1(("mpiParseOBIomb,OPC_OUB_COMBINED_SATA_COMP Resp IOMB tag=0x%x, status=0x%x, param=0x%x\n", tag, OSSA_IO_SUCCESS, 0));
2465           return(AGSA_RC_FAILURE);
2466         }
2467         SA_ASSERT((pRequest->valid), "pRequest->valid");
2468 
2469         SA_DBG3(("mpiParseOBIomb, OPC_OUB_COMBINED_SATA_COMP IOMB tag=0x%x, status=0x%x, param=0x%x\n", tag, OSSA_IO_SUCCESS, 0));
2470 
2471         /* Completion of SATA without Response Data */
2472         siIODone( agRoot, pRequest, OSSA_IO_SUCCESS, 0);
2473       }
2474       break;
2475     }
2476     case OPC_OUB_SATA_COMP:
2477     {
2478 #ifdef SALL_API_TEST
2479       saRoot->LLCounters.IOCounter.numSataCompleted++;
2480       SA_DBG3(("mpiParseOBIomb, SATA_COMP Response received IOMB=%p %d\n",
2481              pMsg1, saRoot->LLCounters.IOCounter.numSataCompleted));
2482 #else
2483       SA_DBG3(("mpiParseOBIomb, SATA_COMP Response received IOMB=%p\n", pMsg1));
2484 #endif
2485       /* process the response message */
2486       mpiSATACompletion(agRoot, pMsg1);
2487       break;
2488     }
2489     case OPC_OUB_SSP_ABORT_RSP:
2490     {
2491 #ifdef SALL_API_TEST
2492       saRoot->LLCounters.IOCounter.numSSPAbortedCB++;
2493 #else
2494       SA_DBG3(("mpiParseOBIomb, SSP_ABORT Response received IOMB=%p\n", pMsg1));
2495 #endif
2496       /* process the response message */
2497       parserStatus = mpiSSPAbortRsp(agRoot, (agsaSSPAbortRsp_t *)pMsg1);
2498       if(parserStatus !=  AGSA_RC_SUCCESS)
2499       {
2500          SA_DBG3(("mpiParseOBIomb, mpiSSPAbortRsp FAIL IOMB=%p\n", pMsg1));
2501       }
2502 
2503       break;
2504     }
2505     case OPC_OUB_SATA_ABORT_RSP:
2506     {
2507 #ifdef SALL_API_TEST
2508       saRoot->LLCounters.IOCounter.numSataAbortedCB++;
2509 #else
2510       SA_DBG3(("mpiParseOBIomb, SATA_ABORT Response received IOMB=%p\n", pMsg1));
2511 #endif
2512       /* process the response message */
2513       mpiSATAAbortRsp(agRoot, (agsaSATAAbortRsp_t *)pMsg1);
2514       break;
2515     }
2516     case OPC_OUB_SATA_EVENT:
2517     {
2518       SA_DBG3(("mpiParseOBIomb, SATA_EVENT Response received IOMB=%p\n", pMsg1));
2519       /* process the response message */
2520       mpiSATAEvent(agRoot, (agsaSATAEventRsp_t *)pMsg1);
2521       break;
2522     }
2523     case OPC_OUB_SSP_EVENT:
2524     {
2525       SA_DBG3(("mpiParseOBIomb, SSP_EVENT Response received IOMB=%p\n", pMsg1));
2526       /* process the response message */
2527       mpiSSPEvent(agRoot, (agsaSSPEventRsp_t *)pMsg1);
2528       break;
2529     }
2530     case OPC_OUB_SMP_COMP:
2531     {
2532 #ifdef SALL_API_TEST
2533       saRoot->LLCounters.IOCounter.numSMPCompleted++;
2534       SA_DBG3(("mpiParseOBIomb, SMP_COMP Response received IOMB=%p, %d\n",
2535              pMsg1, saRoot->LLCounters.IOCounter.numSMPCompleted));
2536 #else
2537       SA_DBG3(("mpiParseOBIomb, SMP_COMP Response received IOMB=%p\n", pMsg1));
2538 #endif
2539       /* process the response message */
2540       mpiSMPCompletion(agRoot, (agsaSMPCompletionRsp_t *)pMsg1);
2541       break;
2542     }
2543     case OPC_OUB_ECHO:
2544     {
2545 #ifdef SALL_API_TEST
2546       saRoot->LLCounters.IOCounter.numEchoCB++;
2547       SA_DBG3(("mpiParseOBIomb, ECHO Response received %d\n", saRoot->LLCounters.IOCounter.numEchoCB));
2548 #else
2549       SA_DBG3(("mpiParseOBIomb, ECHO Response received\n"));
2550 #endif
2551       /* process the response message */
2552       mpiEchoRsp(agRoot, (agsaEchoRsp_t *)pMsg1);
2553       break;
2554     }
2555     case OPC_OUB_GET_NVMD_DATA:
2556     {
2557       SA_DBG3(("mpiParseOBIomb, OPC_OUB_GET_NVMD_DATA received IOMB=%p\n", pMsg1));
2558       /* process the response message */
2559       mpiGetNVMDataRsp(agRoot, (agsaGetNVMDataRsp_t *)pMsg1);
2560       break;
2561     }
2562     case OPC_OUB_SPC_HW_EVENT:
2563     {
2564       SA_ASSERT((smIS_SPC(agRoot)), "smIS_SPC");
2565       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SPC_HW_EVENT Response received IOMB=%p\n", pMsg1));
2566       /* process the response message */
2567       mpiHWevent(agRoot, (agsaHWEvent_SPC_OUB_t *)pMsg1);
2568       break;
2569     }
2570     case OPC_OUB_HW_EVENT:
2571     {
2572       SA_DBG3(("mpiParseOBIomb, HW_EVENT Response received IOMB=%p\n", pMsg1));
2573       /* process the response message */
2574       mpiHWevent(agRoot, (agsaHWEvent_SPC_OUB_t *)pMsg1);
2575       break;
2576     }
2577     case OPC_OUB_PHY_START_RESPONSE:
2578     {
2579       SA_DBG1(("mpiParseOBIomb, OPC_OUB_PHY_START_RESPONSE Response received IOMB=%p\n", pMsg1));
2580       /* process the response message */
2581       mpiPhyStartEvent( agRoot, (agsaHWEvent_Phy_OUB_t  *)pMsg1  );
2582 
2583       break;
2584     }
2585     case OPC_OUB_PHY_STOP_RESPONSE:
2586     {
2587       SA_DBG1(("mpiParseOBIomb, OPC_OUB_PHY_STOP_RESPONSE Response received IOMB=%p\n", pMsg1));
2588       /* process the response message */
2589       mpiPhyStopEvent( agRoot, (agsaHWEvent_Phy_OUB_t  *)pMsg1  );
2590       break;
2591     }
2592 
2593     case OPC_OUB_LOCAL_PHY_CNTRL:
2594     {
2595       SA_DBG3(("mpiParseOBIomb, PHY CONTROL Response received IOMB=%p\n", pMsg1));
2596       /* process the response message */
2597       mpiPhyCntrlRsp(agRoot, (agsaLocalPhyCntrlRsp_t *)pMsg1);
2598       break;
2599     }
2600     case OPC_OUB_SPC_DEV_REGIST:
2601     {
2602       SA_ASSERT((smIS_SPC(agRoot)), "smIS_SPC");
2603       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SPC_DEV_REGIST Response received IOMB=%p\n", pMsg1));
2604       /* process the response message */
2605       mpiDeviceRegRsp(agRoot, (agsaDeviceRegistrationRsp_t *)pMsg1);
2606       break;
2607     }
2608     case OPC_OUB_DEV_REGIST:
2609     {
2610       SA_DBG2(("mpiParseOBIomb, DEV_REGISTRATION Response received IOMB=%p\n", pMsg1));
2611       /* process the response message */
2612       mpiDeviceRegRsp(agRoot, (agsaDeviceRegistrationRsp_t *)pMsg1);
2613       break;
2614     }
2615     case OPC_OUB_DEREG_DEV:
2616     {
2617       SA_DBG3(("mpiParseOBIomb, DEREGISTRATION DEVICE Response received IOMB=%p\n", pMsg1));
2618       /* process the response message */
2619       mpiDeregDevHandleRsp(agRoot, (agsaDeregDevHandleRsp_t *)pMsg1);
2620       break;
2621     }
2622     case OPC_OUB_GET_DEV_HANDLE:
2623     {
2624       SA_DBG3(("mpiParseOBIomb, GET_DEV_HANDLE Response received IOMB=%p\n", pMsg1));
2625       /* process the response message */
2626       mpiGetDevHandleRsp(agRoot, (agsaGetDevHandleRsp_t *)pMsg1);
2627       break;
2628     }
2629     case OPC_OUB_SPC_DEV_HANDLE_ARRIV:
2630     {
2631       SA_DBG3(("mpiParseOBIomb, SPC_DEV_HANDLE_ARRIV Response received IOMB=%p\n", pMsg1));
2632       /* process the response message */
2633       mpiDeviceHandleArrived(agRoot, (agsaDeviceHandleArrivedNotify_t *)pMsg1);
2634       break;
2635     }
2636     case OPC_OUB_DEV_HANDLE_ARRIV:
2637     {
2638       SA_DBG3(("mpiParseOBIomb, DEV_HANDLE_ARRIV Response received IOMB=%p\n", pMsg1));
2639       /* process the response message */
2640       mpiDeviceHandleArrived(agRoot, (agsaDeviceHandleArrivedNotify_t *)pMsg1);
2641       break;
2642     }
2643     case OPC_OUB_SSP_RECV_EVENT:
2644     {
2645       SA_DBG3(("mpiParseOBIomb, SSP_RECV_EVENT Response received IOMB=%p\n", pMsg1));
2646       /* process the response message */
2647       mpiSSPReqReceivedNotify(agRoot, (agsaSSPReqReceivedNotify_t *)pMsg1);
2648       break;
2649     }
2650     case OPC_OUB_DEV_INFO:
2651     {
2652       SA_ASSERT((smIS_SPCV(agRoot)), "smIS_SPCV");
2653       SA_DBG3(("mpiParseOBIomb, DEV_INFO Response received IOMB=%p\n", pMsg1));
2654       /* process the response message */
2655       mpiGetDevInfoRsp(agRoot, (agsaGetDevInfoRspV_t *)pMsg1);
2656       break;
2657     }
2658     case OPC_OUB_GET_PHY_PROFILE_RSP:
2659     {
2660       SA_ASSERT((smIS_SPCV(agRoot)), "smIS_SPCV");
2661       SA_DBG2(("mpiParseOBIomb, OPC_OUB_GET_PHY_PROFILE_RSP Response received IOMB=%p\n", pMsg1));
2662       /* process the response message */
2663       mpiGetPhyProfileRsp(agRoot, (agsaGetPhyProfileRspV_t *)pMsg1);
2664       break;
2665     }
2666     case OPC_OUB_SET_PHY_PROFILE_RSP:
2667     {
2668       SA_ASSERT((smIS_SPCV(agRoot)), "smIS_SPCV");
2669       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_PHY_PROFILE_RSP Response received IOMB=%p\n", pMsg1));
2670       /* process the response message */
2671       mpiSetPhyProfileRsp(agRoot, (agsaSetPhyProfileRspV_t *)pMsg1);
2672       break;
2673     }
2674     case OPC_OUB_SPC_DEV_INFO:
2675     {
2676       SA_ASSERT((smIS_SPC(agRoot)), "smIS_SPC");
2677       SA_DBG3(("mpiParseOBIomb, DEV_INFO Response received IOMB=%p\n", pMsg1));
2678       /* process the response message */
2679       mpiGetDevInfoRspSpc(agRoot, (agsaGetDevInfoRsp_t *)pMsg1);
2680       break;
2681     }
2682     case OPC_OUB_FW_FLASH_UPDATE:
2683     {
2684       SA_DBG3(("mpiParseOBIomb, OPC_OUB_FW_FLASH_UPDATE Response received IOMB=%p\n", pMsg1));
2685       /* process the response message */
2686       mpiFwFlashUpdateRsp(agRoot, (agsaFwFlashUpdateRsp_t *)pMsg1);
2687       break;
2688     }
2689     case OPC_OUB_FLASH_OP_EXT_RSP:
2690     {
2691       SA_DBG3(("mpiParseOBIomb, OPC_OUB_FLASH_OP_EXT_RSP Response received IOMB=%p\n", pMsg1));
2692       /* process the response message */
2693       mpiFwExtFlashUpdateRsp(agRoot, (agsaFwFlashOpExtRsp_t *)pMsg1);
2694       break;
2695     }
2696 #ifdef SPC_ENABLE_PROFILE
2697     case OPC_OUB_FW_PROFILE:
2698     {
2699       SA_DBG3(("mpiParseOBIomb, OPC_OUB_FW_PROFILE Response received IOMB=%p\n", pMsg1));
2700       /* process the response message */
2701       mpiFwProfileRsp(agRoot, (agsaFwProfileRsp_t *)pMsg1);
2702       break;
2703     }
2704 #endif
2705     case OPC_OUB_SET_NVMD_DATA:
2706     {
2707       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_NVMD_DATA received IOMB=%p\n", pMsg1));
2708       /* process the response message */
2709       mpiSetNVMDataRsp(agRoot, (agsaSetNVMDataRsp_t *)pMsg1);
2710       break;
2711     }
2712     case OPC_OUB_GPIO_RESPONSE:
2713     {
2714       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_GPIO_RESPONSE Response received IOMB=%p\n", pMsg1));
2715       /* process the response message */
2716       mpiGPIORsp(agRoot, (agsaGPIORsp_t *)pMsg1);
2717       break;
2718     }
2719     case OPC_OUB_GPIO_EVENT:
2720     {
2721       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_GPIO_RESPONSE Response received IOMB=%p\n", pMsg1));
2722       /* process the response message */
2723       mpiGPIOEventRsp(agRoot, (agsaGPIOEvent_t *)pMsg1);
2724       break;
2725     }
2726     case OPC_OUB_GENERAL_EVENT:
2727     {
2728       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_GENERAL_EVENT Response received IOMB=%p\n", pMsg1));
2729       /* process the response message */
2730       mpiGeneralEventRsp(agRoot, (agsaGeneralEventRsp_t *)pMsg1);
2731       break;
2732     }
2733     case OPC_OUB_SAS_DIAG_MODE_START_END:
2734     {
2735       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SAS_DIAG_MODE_START_END Response received IOMB=%p\n", pMsg1));
2736       /* process the response message */
2737       mpiSASDiagStartEndRsp(agRoot, (agsaSASDiagStartEndRsp_t *)pMsg1);
2738       break;
2739     }
2740     case OPC_OUB_SAS_DIAG_EXECUTE:
2741     {
2742       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SAS_DIAG_EXECUTE_RSP Response received IOMB=%p\n", pMsg1));
2743       /* process the response message */
2744       mpiSASDiagExecuteRsp(agRoot, (agsaSASDiagExecuteRsp_t *)pMsg1);
2745       break;
2746     }
2747     case OPC_OUB_GET_TIME_STAMP:
2748     {
2749       SA_DBG3(("mpiParseOBIomb, OPC_OUB_GET_TIME_STAMP Response received IOMB=%p\n", pMsg1));
2750       /* process the response message */
2751       mpiGetTimeStampRsp(agRoot, (agsaGetTimeStampRsp_t *)pMsg1);
2752       break;
2753     }
2754 
2755     case OPC_OUB_SPC_SAS_HW_EVENT_ACK:
2756     {
2757       SA_ASSERT((smIS_SPC(agRoot)), "smIS_SPC");
2758       SA_DBG3(("mpiParseOBIomb,OPC_OUB_SPC_SAS_HW_EVENT_ACK  Response received IOMB=%p\n", pMsg1));
2759       /* process the response message */
2760       mpiSASHwEventAckRsp(agRoot, (agsaSASHwEventAckRsp_t *)pMsg1);
2761       break;
2762     }
2763 
2764     case OPC_OUB_SAS_HW_EVENT_ACK:
2765     {
2766       SA_ASSERT((smIS_SPCV(agRoot)), "smIS_SPCV");
2767       SA_DBG1(("mpiParseOBIomb, OPC_OUB_SAS_HW_EVENT_ACK Response received IOMB=%p\n", pMsg1));
2768       /* process the response message */
2769       mpiSASHwEventAckRsp(agRoot, (agsaSASHwEventAckRsp_t *)pMsg1);
2770       break;
2771     }
2772     case OPC_OUB_PORT_CONTROL:
2773     {
2774       SA_DBG1(("mpiParseOBIomb, OPC_OUB_PORT_CONTROL Response received IOMB=%p\n", pMsg1));
2775       /* process the response message */
2776       mpiPortControlRsp(agRoot, (agsaPortControlRsp_t *)pMsg1);
2777       break;
2778     }
2779     case OPC_OUB_SMP_ABORT_RSP:
2780     {
2781 #ifdef SALL_API_TEST
2782       saRoot->LLCounters.IOCounter.numSMPAbortedCB++;
2783       SA_DBG3(("mpiParseOBIomb, SMP_ABORT Response received IOMB=%p, %d\n",
2784              pMsg1, saRoot->LLCounters.IOCounter.numSMPAbortedCB));
2785 #else
2786       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SMP_ABORT_RSP Response received IOMB=%p\n", pMsg1));
2787 #endif
2788       /* process the response message */
2789       mpiSMPAbortRsp(agRoot, (agsaSMPAbortRsp_t *)pMsg1);
2790       break;
2791     }
2792     case OPC_OUB_DEVICE_HANDLE_REMOVAL:
2793     {
2794       SA_DBG3(("mpiParseOBIomb, OPC_OUB_DEVICE_HANDLE_REMOVAL received IOMB=%p\n", pMsg1));
2795       /* process the response message */
2796       mpiDeviceHandleRemoval(agRoot, (agsaDeviceHandleRemoval_t *)pMsg1);
2797       break;
2798     }
2799     case OPC_OUB_SET_DEVICE_STATE:
2800     {
2801       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_DEVICE_STATE received IOMB=%p\n", pMsg1));
2802       /* process the response message */
2803       mpiSetDeviceStateRsp(agRoot, (agsaSetDeviceStateRsp_t *)pMsg1);
2804       break;
2805     }
2806     case OPC_OUB_GET_DEVICE_STATE:
2807     {
2808       SA_DBG3(("mpiParseOBIomb, OPC_OUB_GET_DEVICE_STATE received IOMB=%p\n", pMsg1));
2809       /* process the response message */
2810       mpiGetDeviceStateRsp(agRoot, (agsaGetDeviceStateRsp_t *)pMsg1);
2811       break;
2812     }
2813     case OPC_OUB_SET_DEV_INFO:
2814     {
2815       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_DEV_INFO received IOMB=%p\n", pMsg1));
2816       /* process the response message */
2817       mpiSetDevInfoRsp(agRoot, (agsaSetDeviceInfoRsp_t *)pMsg1);
2818       break;
2819     }
2820     case OPC_OUB_SAS_RE_INITIALIZE:
2821     {
2822       SA_ASSERT((smIS_SPC(agRoot)), "smIS_SPC");
2823       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SAS_RE_INITIALIZE received IOMB=%p\n", pMsg1));
2824       /* process the response message */
2825       mpiSasReInitializeRsp(agRoot, (agsaSasReInitializeRsp_t *)pMsg1);
2826       break;
2827     }
2828 
2829     case OPC_OUB_SGPIO_RESPONSE:
2830     {
2831       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SGPIO_RESPONSE Response received IOMB=%p\n", pMsg1));
2832       /* process the response message */
2833       mpiSGpioRsp(agRoot, (agsaSGpioRsp_t *)pMsg1);
2834       break;
2835     }
2836 
2837     case OPC_OUB_PCIE_DIAG_EXECUTE:
2838     {
2839       SA_DBG3(("mpiParseOBIomb, OPC_OUB_PCIE_DIAG_EXECUTE Response received IOMB=%p\n", pMsg1));
2840       /* process the response message */
2841       mpiPCIeDiagExecuteRsp(agRoot, (agsaPCIeDiagExecuteRsp_t *)pMsg1);
2842       break;
2843     }
2844 
2845     case OPC_OUB_GET_VIST_CAP_RSP:
2846     {
2847       SA_DBG3(("mpiParseOBIomb, OPC_INB_GET_VIST_CAP Response received IOMB=%p\n", pMsg1));
2848       /* process the response message */
2849       mpiGetVHistRsp(agRoot, (agsaGetVHistCapRsp_t *)pMsg1);
2850       break;
2851     }
2852     case 2104:
2853     {
2854       if(smIS_SPC6V(agRoot))
2855       {
2856         SA_DBG3(("mpiParseOBIomb, OPC_OUB_GET_DFE_DATA_RSP Response received IOMB=%p\n", pMsg1));
2857         /* process the response message */
2858         mpiGetDFEDataRsp(agRoot, (agsaGetDDEFDataRsp_t *)pMsg1);
2859       }
2860       if(smIS_SPC12V(agRoot))
2861       {
2862         SA_DBG3(("mpiParseOBIomb, OPC_INB_GET_VIST_CAP Response received IOMB=%p\n", pMsg1));
2863         /* process the response message */
2864         mpiGetVHistRsp(agRoot, (agsaGetVHistCapRsp_t *)pMsg1);
2865       }
2866       else
2867       {
2868         SA_DBG1(("mpiParseOBIomb, 2104  Response received IOMB=%p\n", pMsg1));
2869         /* process the response message */
2870       }
2871       break;
2872     }
2873     case OPC_OUB_SET_CONTROLLER_CONFIG:
2874     {
2875       SA_DBG3(("mpiParseOBIomb, OPC_OUB_SET_CONTROLLER_CONFIG Response received IOMB=%p\n", pMsg1));
2876       mpiSetControllerConfigRsp(agRoot, (agsaSetControllerConfigRsp_t *)pMsg1);
2877       break;
2878     }
2879     case OPC_OUB_GET_CONTROLLER_CONFIG:
2880     {
2881       SA_DBG3(("mpiParseOBIomb, OPC_OUB_GET_CONTROLLER_CONFIG Response received IOMB=%p\n", pMsg1));
2882       mpiGetControllerConfigRsp(agRoot, (agsaGetControllerConfigRsp_t *)pMsg1);
2883       break;
2884     }
2885     case OPC_OUB_KEK_MANAGEMENT:
2886     {
2887       SA_DBG3(("mpiParseOBIomb, OPC_OUB_KEK_MANAGEMENT Response received IOMB=%p\n", pMsg1));
2888       mpiKekManagementRsp(agRoot, (agsaKekManagementRsp_t *)pMsg1);
2889       break;
2890     }
2891     case OPC_OUB_DEK_MANAGEMENT:
2892     {
2893       SA_DBG3(("mpiParseOBIomb, OPC_OUB_DEK_MANAGEMENT Response received IOMB=%p\n", pMsg1));
2894       mpiDekManagementRsp(agRoot, (agsaDekManagementRsp_t *)pMsg1);
2895       break;
2896     }
2897     case OPC_OUB_OPR_MGMT:
2898     {
2899       SA_DBG1(("mpiParseOBIomb, OPC_OUB_OPR_MGMT Response received IOMB=%p\n", pMsg1));
2900       mpiOperatorManagementRsp(agRoot, (agsaOperatorMangmenRsp_t *)pMsg1);
2901       break;
2902     }
2903     case OPC_OUB_ENC_TEST_EXECUTE:
2904     {
2905       SA_DBG1(("mpiParseOBIomb, OPC_OUB_ENC_TEST_EXECUTE Response received IOMB=%p\n", pMsg1));
2906       mpiBistRsp(agRoot, (agsaEncryptBistRsp_t *)pMsg1);
2907       break;
2908     }
2909     case OPC_OUB_SET_OPERATOR:
2910     {
2911       SA_DBG1(("mpiParseOBIomb, OPC_OUB_SET_OPERATOR Response received IOMB=%p\n", pMsg1));
2912       mpiSetOperatorRsp(agRoot, (agsaSetOperatorRsp_t *)pMsg1);
2913       break;
2914     }
2915     case OPC_OUB_GET_OPERATOR:
2916     {
2917       SA_DBG1(("mpiParseOBIomb, OPC_OUB_GET_OPERATOR Response received IOMB=%p\n", pMsg1));
2918       mpiGetOperatorRsp(agRoot, (agsaGetOperatorRsp_t *)pMsg1);
2919       break;
2920     }
2921     case OPC_OUB_DIF_ENC_OFFLOAD_RSP:
2922     {
2923       SA_ASSERT((smIS_SPCV(agRoot)), "smIS_SPCV");
2924       SA_DBG1(("mpiParseOBIomb, OPC_OUB_DIF_ENC_OFFLOAD_RSP Response received IOMB=%p\n", pMsg1));
2925       /* process the response message */
2926       mpiDifEncOffloadRsp(agRoot, (agsaDifEncOffloadRspV_t *)pMsg1);
2927       break;
2928     }
2929     default:
2930     {
2931 #ifdef SALL_API_TEST
2932       saRoot->LLCounters.IOCounter.numUNKNWRespIOMB++;
2933       SA_DBG1(("mpiParseOBIomb, UnKnown Response received IOMB=%p, %d\n",
2934              pMsg1, saRoot->LLCounters.IOCounter.numUNKNWRespIOMB));
2935 #else
2936       SA_DBG1(("mpiParseOBIomb, Unknown IOMB Response received opcode 0x%X IOMB=%p\n",opcode, pMsg1));
2937 #endif
2938       break;
2939     }
2940   } /* switch */
2941 
2942   smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "2f");
2943 
2944   return ret;
2945 
2946 }
2947 
2948 
2949 /******************************************************************************/
2950 /*! \brief SPC MPI SATA Completion
2951  *
2952  *  This function handles the SATA completion.
2953  *
2954  *  \param agRoot       Handles for this instance of SAS/SATA LLL
2955  *  \param pIomb1       Pointer of Message1
2956  *  \param bc           buffer count
2957  *
2958  *  \return The read value
2959  *
2960  */
2961 /*******************************************************************************/
2962 GLOBAL FORCEINLINE
2963 bit32 mpiSATACompletion(
2964   agsaRoot_t    *agRoot,
2965   bit32         *pIomb1
2966   )
2967 {
2968   bit32                     ret = AGSA_RC_SUCCESS;
2969   agsaLLRoot_t              *saRoot = (agsaLLRoot_t *)(agRoot->sdkData);
2970   bit32                     status;
2971   bit32                     tag;
2972   bit32                     param;
2973   agsaIORequestDesc_t       *pRequest;
2974   bit32                     *agFirstDword;
2975   bit32                     *pResp;
2976 
2977   smTraceFuncEnter(hpDBG_VERY_LOUD,"2s");
2978 
2979   OSSA_READ_LE_32(AGROOT, &tag, pIomb1, OSSA_OFFSET_OF(agsaSATACompletionRsp_t, tag)) ;
2980   OSSA_READ_LE_32(AGROOT, &status, pIomb1, OSSA_OFFSET_OF(agsaSATACompletionRsp_t, status)) ;
2981   OSSA_READ_LE_32(AGROOT, &param, pIomb1, OSSA_OFFSET_OF(agsaSATACompletionRsp_t, param)) ;
2982 
2983   SA_DBG3(("mpiSATACompletion: start, HTAG=0x%x\n", tag));
2984 
2985   /* get IOrequest from IOMap */
2986   pRequest  = (agsaIORequestDesc_t*)saRoot->IOMap[tag].IORequest;
2987   SA_ASSERT((pRequest), "pRequest");
2988 
2989   if(agNULL == pRequest)
2990   {
2991     SA_DBG1(("mpiSATACompletion: agNULL == pRequest tag 0x%X status 0x%X\n",tag, status ));
2992     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "2s");
2993     return AGSA_RC_FAILURE;
2994   }
2995 
2996   SA_ASSERT((pRequest->valid), "pRequest->valid");
2997   if(!pRequest->valid)
2998   {
2999     SA_DBG1(("mpiSATACompletion: not valid IOMB tag=0x%x status=0x%x param=0x%x Device =0x%x\n", tag, status, param,
3000     pRequest->pDevice ? pRequest->pDevice->DeviceMapIndex : -1));
3001   }
3002 
3003   switch (status)
3004   {
3005     case OSSA_IO_SUCCESS:
3006     {
3007       SA_DBG3(("mpiSATACompletion: OSSA_IO_SUCCESS, param=0x%x\n", param));
3008       if (!param)
3009       {
3010         /* SATA request completion */
3011         siIODone( agRoot, pRequest, OSSA_IO_SUCCESS, 0);
3012       }
3013       else
3014       {
3015         /* param number bytes of SATA Rsp */
3016         agFirstDword  = &pIomb1[3];
3017         pResp         = &pIomb1[4];
3018 
3019         /* CB function to the up layer */
3020         /* Response Length not include firstDW */
3021         saRoot->IoErrorCount.agOSSA_IO_COMPLETED_ERROR_SCSI_STATUS++;
3022         SA_DBG2(("mpiSATACompletion: param 0x%x agFirstDwordResp 0x%x Resp 0x%x tag 0x%x\n",param,*agFirstDword,*pResp ,tag));
3023         siEventSATAResponseWtDataRcvd(agRoot, pRequest, agFirstDword, pResp, (param - 4));
3024       }
3025 
3026       break;
3027     }
3028     case OSSA_IO_ABORTED:
3029     {
3030       SA_DBG2(("mpiSATACompletion: OSSA_IO_ABORTED tag 0x%X\n", tag));
3031       saRoot->IoErrorCount.agOSSA_IO_ABORTED++;
3032       siAbnormal(agRoot, pRequest, status, param, 0);
3033       break;
3034     }
3035     case OSSA_IO_UNDERFLOW:
3036     {
3037       /* SATA Completion with error */
3038       SA_DBG1(("mpiSATACompletion, OSSA_IO_UNDERFLOW tag 0x%X\n", tag));
3039       /*underflow means underrun, treat it as success*/
3040       saRoot->IoErrorCount.agOSSA_IO_UNDERFLOW++;
3041       siAbnormal(agRoot, pRequest, status, param, 0);
3042       break;
3043     }
3044     case OSSA_IO_NO_DEVICE:
3045     {
3046       SA_DBG1(("mpiSATACompletion, OSSA_IO_NO_DEVICE tag 0x%X\n", tag));
3047       saRoot->IoErrorCount.agOSSA_IO_NO_DEVICE++;
3048       siAbnormal(agRoot, pRequest, status, 0, 0);
3049       break;
3050     }
3051     case OSSA_IO_XFER_ERROR_BREAK:
3052     {
3053       SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_ERROR_BREAK SPC tag 0x%X\n", tag));
3054       saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_BREAK++;
3055       siAbnormal(agRoot, pRequest, status, 0, 0);
3056       break;
3057     }
3058     case OSSA_IO_XFER_ERROR_PHY_NOT_READY:
3059     {
3060       SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_ERROR_PHY_NOT_READY tag 0x%X\n", tag));
3061       saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_PHY_NOT_READY++;
3062       siAbnormal(agRoot, pRequest, status, 0, 0);
3063       break;
3064     }
3065     case OSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED:
3066     {
3067       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED tag 0x%X\n", tag));
3068       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED++;
3069       siAbnormal(agRoot, pRequest, status, 0, 0);
3070       break;
3071     }
3072     case OSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION:
3073     {
3074       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION tag 0x%X\n", tag));
3075       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION++;
3076       siAbnormal(agRoot, pRequest, status, 0, 0);
3077       break;
3078     }
3079     case OSSA_IO_OPEN_CNX_ERROR_BREAK:
3080     {
3081       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_BREAK SPC tag 0x%X\n", tag));
3082       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_BREAK++;
3083       siAbnormal(agRoot, pRequest, status, 0, 0);
3084       break;
3085     }
3086     case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS:
3087     {
3088       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS tag 0x%X\n", tag));
3089       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS++;
3090       siAbnormal(agRoot, pRequest, status, 0, 0);
3091       break;
3092     }
3093     case OSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION:
3094     {
3095       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION tag 0x%X\n", tag));
3096       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION++;
3097       siAbnormal(agRoot, pRequest, status, 0, 0);
3098       break;
3099     }
3100     case OSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED:
3101     {
3102       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED tag 0x%X\n", tag));
3103       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED++;
3104       siAbnormal(agRoot, pRequest, status, 0, 0);
3105       break;
3106     }
3107     case OSSA_IO_OPEN_CNX_ERROR_STP_RESOURCES_BUSY:
3108     {
3109       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_STP_RESOURCES_BUSY tag 0x%X\n", tag));
3110       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_STP_RESOURCES_BUSY++;
3111       siAbnormal(agRoot, pRequest, status, 0, 0);
3112       break;
3113     }
3114     case OSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION:
3115     {
3116       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION tag 0x%X\n", tag));
3117       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION++;
3118       siAbnormal(agRoot, pRequest, status, 0, 0);
3119       break;
3120     }
3121     case OSSA_IO_XFER_ERROR_NAK_RECEIVED:
3122     {
3123       SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_ERROR_NAK_RECEIVED tag 0x%X\n", tag));
3124       saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_NAK_RECEIVED++;
3125       siAbnormal(agRoot, pRequest, status, 0, 0);
3126       break;
3127     }
3128     case OSSA_IO_XFER_ERROR_DMA:
3129     {
3130        SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_ERROR_DMA tag 0x%X\n", tag));
3131        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_DMA++;
3132        siAbnormal(agRoot, pRequest, status, 0, 0);
3133        break;
3134     }
3135     case OSSA_IO_XFER_ERROR_SATA_LINK_TIMEOUT:
3136     {
3137       SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_ERROR_SATA_LINK_TIMEOUT tag 0x%X\n", tag));
3138       saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_SATA_LINK_TIMEOUT++;
3139       siAbnormal(agRoot, pRequest, status, 0, 0);
3140       break;
3141     }
3142     case OSSA_IO_XFER_ERROR_REJECTED_NCQ_MODE:
3143     {
3144       SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_ERROR_REJECTED_NCQ_MODE tag 0x%X\n", tag));
3145       saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_REJECTED_NCQ_MODE++;
3146       siAbnormal(agRoot, pRequest, status, 0, 0);
3147       break;
3148     }
3149     case OSSA_IO_XFER_OPEN_RETRY_TIMEOUT:
3150     {
3151        SA_DBG1(("mpiSATACompletion, OSSA_IO_XFER_OPEN_RETRY_TIMEOUT tag 0x%X\n", tag));
3152        saRoot->IoErrorCount.agOSSA_IO_XFER_OPEN_RETRY_TIMEOUT++;
3153        siAbnormal(agRoot, pRequest, status, 0, 0);
3154        break;
3155     }
3156     case OSSA_IO_PORT_IN_RESET:
3157     {
3158       SA_DBG1(("mpiSATACompletion: OSSA_IO_PORT_IN_RESET tag 0x%X\n", tag));
3159       saRoot->IoErrorCount.agOSSA_IO_PORT_IN_RESET++;
3160       siAbnormal(agRoot, pRequest, status, 0, 0);
3161       break;
3162     }
3163     case OSSA_IO_DS_NON_OPERATIONAL:
3164     {
3165       SA_DBG1(("mpiSATACompletion: OSSA_IO_DS_NON_OPERATIONAL tag 0x%X\n", tag));
3166       saRoot->IoErrorCount.agOSSA_IO_DS_NON_OPERATIONAL++;
3167       siAbnormal(agRoot, pRequest, status, 0, 0);
3168       break;
3169     }
3170     case OSSA_IO_DS_IN_RECOVERY:
3171     {
3172       SA_DBG1(("mpiSATACompletion: OSSA_IO_DS_IN_RECOVERY tag 0x%X\n", tag));
3173       saRoot->IoErrorCount.agOSSA_IO_DS_IN_RECOVERY++;
3174       siAbnormal(agRoot, pRequest, status, 0, 0);
3175       break;
3176     }
3177     case OSSA_IO_DS_IN_ERROR:
3178     {
3179       SA_DBG1(("mpiSATACompletion: OSSA_IO_DS_IN_ERROR tag 0x%X\n", tag));
3180       saRoot->IoErrorCount.agOSSA_IO_DS_IN_ERROR++;
3181       siAbnormal(agRoot, pRequest, status, 0, 0);
3182       break;
3183     }
3184 
3185     case OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY:
3186     {
3187       SA_DBG1(("mpiSATACompletion: OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY tag 0x%X\n", tag));
3188       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY++;
3189       siAbnormal(agRoot, pRequest, status, 0, 0);
3190       break;
3191     }
3192     case OSSA_IO_ABORT_IN_PROGRESS:
3193     {
3194       SA_DBG1(("mpiSATACompletion: OSSA_IO_ABORT_IN_PROGRESS tag 0x%X\n", tag));
3195       saRoot->IoErrorCount.agOSSA_IO_ABORT_IN_PROGRESS++;
3196       siAbnormal(agRoot, pRequest, status, 0, 0);
3197       break;
3198     }
3199     case OSSA_IO_ABORT_DELAYED:
3200     {
3201       SA_DBG1(("mpiSATACompletion: OSSA_IO_ABORT_DELAYED tag 0x%X\n", tag));
3202       saRoot->IoErrorCount.agOSSA_IO_ABORT_DELAYED++;
3203       siAbnormal(agRoot, pRequest, status, 0, 0);
3204       break;
3205     }
3206     case OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT:
3207     {
3208       SA_DBG1(("mpiSATACompletion: OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT tag 0x%X\n", tag));
3209       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT++;
3210       siAbnormal(agRoot, pRequest, status, 0, 0);
3211       break;
3212     }
3213     case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED:
3214     {
3215       SA_DBG1(("mpiSATACompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED HTAG = 0x%x\n", tag));
3216       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED++;
3217       siAbnormal(agRoot, pRequest, status, 0, 0);
3218       break;
3219     }
3220     case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO:
3221     {
3222       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO tag 0x%x\n", tag));
3223       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO++;
3224       siAbnormal(agRoot, pRequest, status, 0, 0 );
3225       break;
3226     }
3227     case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST:
3228     {
3229       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST tag 0x%x\n", tag));
3230       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST++;
3231       siAbnormal(agRoot, pRequest, status, 0, 0 );
3232       break;
3233     }
3234     case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE:
3235     {
3236       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE tag 0x%x\n", tag));
3237       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE++;
3238       siAbnormal(agRoot, pRequest, status, 0, 0 );
3239       break;
3240     }
3241     case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED:
3242     {
3243       SA_DBG1(("mpiSATACompletion, OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED tag 0x%x\n", tag));
3244       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED++;
3245       siAbnormal(agRoot, pRequest, status, 0, 0 );
3246       break;
3247     }
3248     case OSSA_IO_DS_INVALID:
3249     {
3250       SA_DBG1(("mpiSATACompletion: OSSA_IO_DS_INVALID tag 0x%X\n", tag));
3251       saRoot->IoErrorCount.agOSSA_IO_DS_INVALID++;
3252       siAbnormal(agRoot, pRequest, status, 0, 0);
3253       break;
3254     }
3255     case OSSA_IO_XFER_ERR_LAST_PIO_DATAIN_CRC_ERR:
3256     {
3257       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFER_ERR_LAST_PIO_DATAIN_CRC_ERR tag 0x%X\n", tag));
3258       saRoot->IoErrorCount.agOSSA_IO_XFER_ERR_LAST_PIO_DATAIN_CRC_ERR++;
3259       siAbnormal(agRoot, pRequest, status, 0, 0);
3260       break;
3261     }
3262     case OSSA_MPI_IO_RQE_BUSY_FULL:
3263     {
3264       SA_DBG1(("mpiSATACompletion: OSSA_MPI_IO_RQE_BUSY_FULL tag 0x%X\n", tag));
3265       saRoot->IoErrorCount.agOSSA_MPI_IO_RQE_BUSY_FULL++;
3266       siAbnormal(agRoot, pRequest, status, 0, 0);
3267       break;
3268     }
3269 #ifdef REMOVED
3270     case OSSA_IO_XFER_ERR_EOB_DATA_OVERRUN:
3271     {
3272       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFER_ERR_EOB_DATA_OVERRUN tag 0x%x\n", tag));
3273       saRoot->IoErrorCount.agOSSA_IO_XFER_ERR_EOB_DATA_OVERRUN++;
3274       siAbnormal(agRoot, pRequest, status, 0, 0);
3275       break;
3276     }
3277 #endif
3278     case OSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE:
3279     {
3280       SA_DBG1(("mpiSATACompletion: OPC_OUB_SATA_COMP:OSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE \n"));
3281       saRoot->IoErrorCount.agOSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE++;
3282       siAbnormal(agRoot, pRequest, status, 0, 0);
3283       break;
3284     }
3285     case OSSA_MPI_ERR_ATAPI_DEVICE_BUSY:
3286     {
3287       SA_DBG1(("mpiSATACompletion: OSSA_MPI_ERR_ATAPI_DEVICE_BUSY tag 0x%X\n", tag));
3288       saRoot->IoErrorCount.agOSSA_MPI_ERR_ATAPI_DEVICE_BUSY++;
3289       siAbnormal(agRoot, pRequest, status, param, 0 );
3290       break;
3291     }
3292     case OSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS:
3293     {
3294       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS tag 0x%X\n", tag));
3295       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS++;
3296       siAbnormal(agRoot, pRequest, status, 0, 0);
3297       break;
3298     }
3299     case OSSA_IO_XFR_ERROR_CIPHER_MODE_INVALID:
3300     {
3301       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_CIPHER_MODE_INVALID tag 0x%X\n", tag));
3302       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS++;
3303       siAbnormal(agRoot, pRequest, status, 0, 0);
3304       break;
3305     }
3306     case OSSA_IO_XFR_ERROR_DEK_IV_MISMATCH:
3307     {
3308       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_DEK_IV_MISMATCH tag 0x%X\n", tag));
3309       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_IV_MISMATCH++;
3310       siAbnormal(agRoot, pRequest, status, 0, 0);
3311       break;
3312     }
3313     case OSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR:
3314     {
3315       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR tag 0x%X\n", tag));
3316       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR++;
3317       siAbnormal(agRoot, pRequest, status, 0, 0);
3318       break;
3319     }
3320     case OSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED:
3321     {
3322       SA_DBG1(("mpiSATACompletion: OSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED tag 0x%X\n", tag));
3323       saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED++;
3324       siAbnormal(agRoot, pRequest, status, 0, 0);
3325       break;
3326     }
3327 
3328     case OSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH:
3329     {
3330       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH tag 0x%X\n", tag));
3331       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH++;
3332       siAbnormal(agRoot, pRequest, status, 0, 0);
3333       break;
3334     }
3335     case OSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS:
3336     {
3337       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS tag 0x%X\n", tag));
3338       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS++;
3339       siAbnormal(agRoot, pRequest, status, 0, 0);
3340       break;
3341     }
3342     case OSSA_IO_XFR_ERROR_DEK_ILLEGAL_TABLE:
3343     {
3344       SA_DBG1(("mpiSATACompletion: OSSA_IO_XFR_ERROR_DEK_ILLEGAL_TABLE tag 0x%X\n", tag));
3345       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS++;
3346       siAbnormal(agRoot, pRequest, status, 0, 0);
3347       break;
3348     }
3349 
3350     default:
3351     {
3352       SA_DBG1(("mpiSATACompletion: Unknown status  0x%x tag 0x%x\n", status, tag));
3353       saRoot->IoErrorCount.agOSSA_IO_UNKNOWN_ERROR++;
3354       siAbnormal(agRoot, pRequest, status, param, 0);
3355       break;
3356     }
3357   }
3358 
3359   /* The HTag should equal to the IOMB tag */
3360   if (pRequest->HTag != tag)
3361   {
3362     SA_DBG1(("mpiSATACompletion: Error Htag %d not equal IOMBtag %d\n", pRequest->HTag, tag));
3363   }
3364 
3365   smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "2s");
3366   return ret;
3367 }
3368 
3369 /******************************************************************************/
3370 /*! \brief SPC MPI SSP Completion
3371  *
3372  *  This function handles the SSP completion.
3373  *
3374  *  \param agRoot       Handles for this instance of SAS/SATA LLL
3375  *  \param pIomb1       Pointer of Message1
3376  *  \param bc           buffer count
3377  *
3378  *  \return The read value
3379  *
3380  */
3381 /*******************************************************************************/
3382 GLOBAL FORCEINLINE
3383 bit32 mpiSSPCompletion(
3384   agsaRoot_t    *agRoot,
3385   bit32         *pIomb1
3386   )
3387 {
3388   agsaLLRoot_t              *saRoot   = (agsaLLRoot_t *)(agRoot->sdkData);
3389   agsaSSPCompletionRsp_t    *pIomb    = (agsaSSPCompletionRsp_t *)pIomb1;
3390   agsaIORequestDesc_t       *pRequest = agNULL;
3391   agsaSSPResponseInfoUnit_t *pRespIU  = agNULL;
3392   bit32                      tag      = 0;
3393   bit32                      sspTag   = 0;
3394   bit32                      status, param = 0;
3395   bit32                      ret = AGSA_RC_SUCCESS;
3396 
3397   smTraceFuncEnter(hpDBG_VERY_LOUD, "5A");
3398 
3399   /* get Tag */
3400   OSSA_READ_LE_32(agRoot, &tag, pIomb, OSSA_OFFSET_OF(agsaSSPCompletionRsp_t, tag));
3401   OSSA_READ_LE_32(agRoot, &status, pIomb, OSSA_OFFSET_OF(agsaSSPCompletionRsp_t, status));
3402   OSSA_READ_LE_32(agRoot, &param, pIomb, OSSA_OFFSET_OF(agsaSSPCompletionRsp_t, param));
3403   OSSA_READ_LE_32(agRoot, &sspTag, pIomb, OSSA_OFFSET_OF(agsaSSPCompletionRsp_t, SSPTag));
3404   /* get SSP_START IOrequest from IOMap */
3405   pRequest = (agsaIORequestDesc_t *)saRoot->IOMap[tag].IORequest;
3406   SA_ASSERT((pRequest), "pRequest");
3407 
3408   if(pRequest == agNULL)
3409   {
3410     SA_DBG1(("mpiSSPCompletion,AGSA_RC_FAILURE SSP Resp IOMB tag=0x%x, status=0x%x, param=0x%x, SSPTag=0x%x\n", tag, status, param, sspTag));
3411     smTraceFuncExit(hpDBG_VERY_LOUD, 'a', "5A");
3412     return(AGSA_RC_FAILURE);
3413   }
3414   SA_ASSERT((pRequest->valid), "pRequest->valid");
3415 
3416   if(!pRequest->valid)
3417   {
3418     SA_DBG1(("mpiSSPCompletion, SSP Resp IOMB tag=0x%x, status=0x%x, param=0x%x, SSPTag=0x%x Device =0x%x\n", tag, status, param, sspTag,
3419     pRequest->pDevice ? pRequest->pDevice->DeviceMapIndex : -1));
3420   }
3421 
3422   switch (status)
3423   {
3424     case OSSA_IO_SUCCESS:
3425     {
3426       if (!param)
3427       {
3428         /* Completion of SSP without Response Data */
3429         siIODone( agRoot, pRequest, OSSA_IO_SUCCESS, sspTag);
3430       }
3431       else
3432       {
3433         /* Get SSP Response with Response Data */
3434         pRespIU = (agsaSSPResponseInfoUnit_t *)&(pIomb->SSPrsp);
3435         if (pRespIU->status == 0x02 || pRespIU->status == 0x18 ||
3436             pRespIU->status == 0x30 || pRespIU->status == 0x40 )
3437         {
3438           /* SCSI status is CHECK_CONDITION, RESV_CONFLICT, ACA_ACTIVE, TASK_ABORTED */
3439           saRoot->IoErrorCount.agOSSA_IO_COMPLETED_ERROR_SCSI_STATUS++;
3440           SA_DBG2(("mpiSSPCompletion: pRespIU->status 0x%x tag 0x%x\n", pRespIU->status,tag));
3441         }
3442         siEventSSPResponseWtDataRcvd(agRoot, pRequest, pRespIU, param, sspTag);
3443       }
3444 
3445       break;
3446     }
3447 
3448     case OSSA_IO_XFR_ERROR_INVALID_SSP_RSP_FRAME:
3449     {
3450       SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_INVALID_SSP_RSP_FRAME tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3451       saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_INVALID_SSP_RSP_FRAME++;
3452       /* Get SSP Response with Response Data */
3453       pRespIU = (agsaSSPResponseInfoUnit_t *)&(pIomb->SSPrsp);
3454       if (pRespIU->status == 0x02 || pRespIU->status == 0x18 ||
3455           pRespIU->status == 0x30 || pRespIU->status == 0x40 )
3456       {
3457         /* SCSI status is CHECK_CONDITION, RESV_CONFLICT, ACA_ACTIVE, TASK_ABORTED */
3458         saRoot->IoErrorCount.agOSSA_IO_COMPLETED_ERROR_SCSI_STATUS++;
3459         SA_DBG2(("mpiSSPCompletion: pRespIU->status 0x%x tag 0x%x\n", pRespIU->status,tag));
3460       }
3461       siEventSSPResponseWtDataRcvd(agRoot, pRequest, pRespIU, param, sspTag);
3462 
3463       break;
3464      }
3465 
3466      case OSSA_IO_ABORTED:
3467      {
3468 #ifdef SALL_API_TEST
3469        saRoot->LLCounters.IOCounter.numSSPAborted++;
3470        SA_DBG3(("mpiSSPCompletion, OSSA_IO_ABORTED Response received IOMB=%p %d\n",
3471               pIomb1, saRoot->LLCounters.IOCounter.numSSPAborted));
3472 #endif
3473        SA_DBG2(("mpiSSPCompletion, OSSA_IO_ABORTED IOMB tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3474        saRoot->IoErrorCount.agOSSA_IO_ABORTED++;
3475        /* SSP Abort CB */
3476        siAbnormal(agRoot, pRequest, status, param, sspTag);
3477        break;
3478      }
3479      case OSSA_IO_UNDERFLOW:
3480      {
3481        /* SSP Completion with error */
3482        SA_DBG2(("mpiSSPCompletion, OSSA_IO_UNDERFLOW tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3483        /*saRoot->IoErrorCount.agOSSA_IO_UNDERFLOW++;*/
3484        siAbnormal(agRoot, pRequest, status, param, sspTag);
3485        break;
3486      }
3487      case OSSA_IO_NO_DEVICE:
3488      {
3489        SA_DBG1(("mpiSSPCompletion: OSSA_IO_NO_DEVICE tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3490        saRoot->IoErrorCount.agOSSA_IO_NO_DEVICE++;
3491        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3492        break;
3493      }
3494      case OSSA_IO_XFER_ERROR_BREAK:
3495      {
3496        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_BREAK tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3497        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_BREAK++;
3498        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3499        break;
3500      }
3501      case OSSA_IO_XFER_ERROR_PHY_NOT_READY:
3502      {
3503        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_PHY_NOT_READY tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3504        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_PHY_NOT_READY++;
3505        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3506        break;
3507      }
3508      case OSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED:
3509      {
3510        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3511        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED++;
3512        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3513        break;
3514      }
3515      case OSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION:
3516      {
3517        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION++;
3518        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3519        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3520        break;
3521      }
3522      case OSSA_IO_OPEN_CNX_ERROR_BREAK:
3523      {
3524        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_BREAK tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3525        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_BREAK++;
3526        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3527        break;
3528      }
3529      case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS:
3530      {
3531        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3532        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS++;
3533        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3534        break;
3535      }
3536      case OSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION:
3537      {
3538        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3539        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION++;
3540        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3541        break;
3542      }
3543      case OSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED:
3544      {
3545        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3546        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED++;
3547        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3548        break;
3549      }
3550      case OSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION:
3551      {
3552        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3553        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION++;
3554        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3555        break;
3556      }
3557      case OSSA_IO_XFER_ERROR_NAK_RECEIVED:
3558      {
3559        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_NAK_RECEIVED tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3560        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_NAK_RECEIVED++;
3561        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3562        break;
3563      }
3564      case OSSA_IO_XFER_ERROR_ACK_NAK_TIMEOUT:
3565      {
3566        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_ACK_NAK_TIMEOUT tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3567        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_ACK_NAK_TIMEOUT++;
3568        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3569        break;
3570      }
3571      case OSSA_IO_XFER_ERROR_DMA:
3572      {
3573        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_DMA tag 0x%x ssptag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3574        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_DMA++;
3575        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3576        break;
3577      }
3578      case OSSA_IO_XFER_OPEN_RETRY_TIMEOUT:
3579      {
3580        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_OPEN_RETRY_TIMEOUT tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3581        saRoot->IoErrorCount.agOSSA_IO_XFER_OPEN_RETRY_TIMEOUT++;
3582        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3583        break;
3584      }
3585      case OSSA_IO_XFER_ERROR_UNEXPECTED_PHASE:
3586      {
3587        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_UNEXPECTED_PHASE tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3588        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_UNEXPECTED_PHASE++;
3589        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3590        break;
3591      }
3592      case OSSA_IO_XFER_ERROR_OFFSET_MISMATCH:
3593      {
3594        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_OFFSET_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3595        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_OFFSET_MISMATCH++;
3596        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3597        break;
3598      }
3599      case OSSA_IO_PORT_IN_RESET:
3600      {
3601        SA_DBG1(("mpiSSPCompletion: OSSA_IO_PORT_IN_RESET tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3602        saRoot->IoErrorCount.agOSSA_IO_PORT_IN_RESET++;
3603        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3604        break;
3605      }
3606      case OSSA_IO_DS_NON_OPERATIONAL:
3607      {
3608        SA_DBG1(("mpiSSPCompletion: OSSA_IO_DS_NON_OPERATIONAL tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3609        saRoot->IoErrorCount.agOSSA_IO_DS_NON_OPERATIONAL++;
3610        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3611        break;
3612      }
3613      case OSSA_IO_DS_IN_RECOVERY:
3614      {
3615        SA_DBG1(("mpiSSPCompletion: OSSA_IO_DS_IN_RECOVERY tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3616        saRoot->IoErrorCount.agOSSA_IO_DS_IN_RECOVERY++;
3617        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3618        break;
3619      }
3620      case OSSA_IO_TM_TAG_NOT_FOUND:
3621      {
3622        SA_DBG1(("mpiSSPCompletion: OSSA_IO_TM_TAG_NOT_FOUND tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3623        saRoot->IoErrorCount.agOSSA_IO_TM_TAG_NOT_FOUND++;
3624        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3625        break;
3626      }
3627      case OSSA_IO_XFER_PIO_SETUP_ERROR:
3628      {
3629        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_PIO_SETUP_ERROR tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3630        saRoot->IoErrorCount.agOSSA_IO_XFER_PIO_SETUP_ERROR++;
3631        /* not allowed case. Therefore, return failed status */
3632        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3633        break;
3634      }
3635      case OSSA_IO_SSP_EXT_IU_ZERO_LEN_ERROR:
3636      {
3637        SA_DBG1(("mpiSSPCompletion: OSSA_IO_SSP_IU_ZERO_LEN_ERROR tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3638        saRoot->IoErrorCount.agOSSA_IO_SSP_EXT_IU_ZERO_LEN_ERROR++;
3639        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3640        break;
3641      }
3642      case OSSA_IO_DS_IN_ERROR:
3643      {
3644        SA_DBG1(("mpiSSPCompletion: OSSA_IO_DS_IN_ERROR tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3645        saRoot->IoErrorCount.agOSSA_IO_DS_IN_ERROR++;
3646        /* not allowed case. Therefore, return failed status */
3647        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3648        break;
3649      }
3650      case OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY:
3651      {
3652        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3653        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY++;
3654        /* not allowed case. Therefore, return failed status */
3655        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3656        break;
3657      }
3658      case OSSA_IO_ABORT_IN_PROGRESS:
3659      {
3660        SA_DBG1(("mpiSSPCompletion: OSSA_IO_ABORT_IN_PROGRESS tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3661        saRoot->IoErrorCount.agOSSA_IO_ABORT_IN_PROGRESS++;
3662        /* not allowed case. Therefore, return failed status */
3663        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3664        break;
3665      }
3666      case OSSA_IO_ABORT_DELAYED:
3667      {
3668        SA_DBG1(("mpiSSPCompletion: OSSA_IO_ABORT_DELAYED tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3669        saRoot->IoErrorCount.agOSSA_IO_ABORT_DELAYED++;
3670        /* not allowed case. Therefore, return failed status */
3671        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3672        break;
3673      }
3674      case OSSA_IO_INVALID_LENGTH:
3675      {
3676        SA_DBG1(("mpiSSPCompletion: OSSA_IO_INVALID_LENGTH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3677        saRoot->IoErrorCount.agOSSA_IO_INVALID_LENGTH++;
3678        /* not allowed case. Therefore, return failed status */
3679        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3680        break;
3681      }
3682      case OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT:
3683      {
3684        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3685        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT++;
3686        /* not allowed case. Therefore, return failed status */
3687        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3688        break;
3689      }
3690      case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED:
3691      {
3692        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED HTAG = 0x%x ssptag = 0x%x\n", tag, sspTag));
3693        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED++;
3694        siAbnormal(agRoot, pRequest, status, 0, sspTag);
3695        break;
3696      }
3697      case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO:
3698      {
3699        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3700        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO++;
3701        siAbnormal(agRoot, pRequest, status, param, sspTag);
3702        break;
3703      }
3704      case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST:
3705      {
3706        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3707        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST++;
3708        siAbnormal(agRoot, pRequest, status, param, sspTag);
3709        break;
3710      }
3711      case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE:
3712      {
3713        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3714        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE++;
3715        siAbnormal(agRoot, pRequest, status, param, sspTag);
3716        break;
3717      }
3718      case OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED:
3719      {
3720        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3721        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED++;
3722        siAbnormal(agRoot, pRequest, status, param, sspTag);
3723        break;
3724      }
3725      case OSSA_IO_DS_INVALID:
3726      {
3727        SA_DBG1(("mpiSSPCompletion: OSSA_IO_DS_INVALID tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3728        saRoot->IoErrorCount.agOSSA_IO_DS_INVALID++;
3729        siAbnormal(agRoot, pRequest, status, param, sspTag);
3730        break;
3731      }
3732      case OSSA_MPI_IO_RQE_BUSY_FULL:
3733      {
3734        SA_DBG1(("mpiSSPCompletion: OSSA_MPI_IO_RQE_BUSY_FULL tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3735        saRoot->IoErrorCount.agOSSA_MPI_IO_RQE_BUSY_FULL++;
3736        siAbnormal(agRoot, pRequest, status, param, sspTag);
3737        break;
3738      }
3739      case OSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE:
3740      {
3741        SA_DBG1(("mpiSSPCompletion: OSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3742        saRoot->IoErrorCount.agOSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE++;
3743        siAbnormal(agRoot, pRequest, status, param, sspTag);
3744        break;
3745      }
3746      case OSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS:
3747      {
3748        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3749        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS++;
3750        siAbnormal(agRoot, pRequest, status, param, sspTag);
3751        break;
3752      }
3753      case OSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH:
3754      {
3755        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3756        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH++;
3757        siAbnormal(agRoot, pRequest, status, param, sspTag);
3758        break;
3759      }
3760      case OSSA_IO_XFR_ERROR_CIPHER_MODE_INVALID:
3761      {
3762        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_CIPHER_MODE_INVALID tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3763        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_CIPHER_MODE_INVALID++;
3764        siAbnormal(agRoot, pRequest, status, param, sspTag);
3765        break;
3766      }
3767      case OSSA_IO_XFR_ERROR_DEK_IV_MISMATCH:
3768      {
3769        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DEK_IV_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3770        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_IV_MISMATCH++;
3771        siAbnormal(agRoot, pRequest, status, param, sspTag);
3772        break;
3773      }
3774      case OSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR:
3775      {
3776        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3777        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR++;
3778        siAbnormal(agRoot, pRequest, status, param, sspTag);
3779        break;
3780      }
3781      case OSSA_IO_XFR_ERROR_INTERNAL_RAM:
3782      {
3783        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_INTERNAL_RAM tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3784        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_INTERNAL_RAM++;
3785        siAbnormal(agRoot, pRequest, status, param, sspTag);
3786        break;
3787      }
3788      case OSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS:
3789      {
3790        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3791        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS++;
3792        siAbnormal(agRoot, pRequest, status, param, sspTag);
3793        break;
3794      }
3795      case OSSA_IO_XFR_ERROR_DEK_ILLEGAL_TABLE:
3796      {
3797        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DEK_ILLEGAL_TABLE tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3798        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DEK_ILLEGAL_TABLE++;
3799        siAbnormal(agRoot, pRequest, status, param, sspTag);
3800        break;
3801      }
3802 #ifdef SA_TESTBASE_EXTRA
3803      /* TestBase */
3804      case OSSA_IO_HOST_BST_INVALID:
3805      {
3806         SA_DBG1(("mpiParseOBIomb, OPC_OUB_SSP_COMP: OSSA_IO_HOST_BST_INVALID 0x%x\n", status));
3807         siAbnormal(agRoot, pRequest, status, param, sspTag);
3808         break;
3809      }
3810 #endif /*  SA_TESTBASE_EXTRA */
3811      case OSSA_IO_XFR_ERROR_DIF_MISMATCH:
3812      {
3813         SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DIF_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3814         saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DIF_MISMATCH++;
3815         siDifAbnormal(agRoot, pRequest, status, param, sspTag, pIomb1);
3816         break;
3817      }
3818      case OSSA_IO_XFR_ERROR_DIF_APPLICATION_TAG_MISMATCH:
3819      {
3820        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DIF_APPLICATION_TAG_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3821        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DIF_APPLICATION_TAG_MISMATCH++;
3822        siDifAbnormal(agRoot, pRequest, status, param, sspTag, pIomb1);
3823        break;
3824      }
3825      case OSSA_IO_XFR_ERROR_DIF_REFERENCE_TAG_MISMATCH:
3826      {
3827        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DIF_REFERENCE_TAG_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3828        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DIF_REFERENCE_TAG_MISMATCH++;
3829        siDifAbnormal(agRoot, pRequest, status, param, sspTag, pIomb1);
3830        break;
3831      }
3832      case OSSA_IO_XFR_ERROR_DIF_CRC_MISMATCH:
3833      {
3834        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFR_ERROR_DIF_CRC_MISMATCH tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3835        saRoot->IoErrorCount.agOSSA_IO_XFR_ERROR_DIF_CRC_MISMATCH++;
3836        siDifAbnormal(agRoot, pRequest, status, param, sspTag, pIomb1);
3837        break;
3838      }
3839      case OSSA_IO_XFER_ERROR_DIF_INTERNAL_ERROR:
3840      {
3841        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERROR_DIF_INTERNAL_ERROR tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3842        saRoot->IoErrorCount.agOSSA_IO_XFER_ERROR_DIF_INTERNAL_ERROR++;
3843        siDifAbnormal(agRoot, pRequest, status, param, sspTag, pIomb1);
3844        break;
3845      }
3846      case OSSA_IO_XFER_ERR_EOB_DATA_OVERRUN:
3847      {
3848        SA_DBG1(("mpiSSPCompletion: OSSA_IO_XFER_ERR_EOB_DATA_OVERRUN tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3849        saRoot->IoErrorCount.agOSSA_IO_XFER_ERR_EOB_DATA_OVERRUN++;
3850        siAbnormal(agRoot, pRequest, status, param, sspTag);
3851        break;
3852      }
3853      case OSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED:
3854      {
3855        SA_DBG1(("mpiSSPCompletion: OSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3856        saRoot->IoErrorCount.agOSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED++;
3857        siAbnormal(agRoot, pRequest, status, param, sspTag);
3858        break;
3859      }
3860      default:
3861      {
3862        SA_DBG1(("mpiSSPCompletion: Unknown tag 0x%x sspTag 0x%x status 0x%x param 0x%x\n", tag,sspTag,status,param));
3863        /* not allowed case. Therefore, return failed status */
3864        saRoot->IoErrorCount.agOSSA_IO_UNKNOWN_ERROR++;
3865        siAbnormal(agRoot, pRequest, OSSA_IO_FAILED, param, sspTag);
3866        break;
3867      }
3868    }
3869 
3870    smTraceFuncExit(hpDBG_VERY_LOUD, 'b', "5A");
3871    return ret;
3872 }
3873