xref: /illumos-gate/usr/src/uts/sun4u/io/px/px_err.c (revision 66e150d7d3c0cb2de3c45c74612784ffd3e73de6)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 /*
22  * Copyright 2008 Sun Microsystems, Inc.  All rights reserved.
23  * Use is subject to license terms.
24  */
25 
26 #pragma ident	"%Z%%M%	%I%	%E% SMI"
27 
28 /*
29  * sun4u Fire Error Handling
30  */
31 
32 #include <sys/types.h>
33 #include <sys/ddi.h>
34 #include <sys/sunddi.h>
35 #include <sys/sunndi.h>
36 #include <sys/fm/protocol.h>
37 #include <sys/fm/util.h>
38 #include <sys/pcie.h>
39 #include <sys/pcie_impl.h>
40 #include "px_obj.h"
41 #include <px_regs.h>
42 #include <px_csr.h>
43 #include <sys/membar.h>
44 #include <sys/machcpuvar.h>
45 #include <sys/platform_module.h>
46 #include "pcie_pwr.h"
47 #include "px_lib4u.h"
48 #include "px_err.h"
49 #include "px_err_impl.h"
50 #include "oberon_regs.h"
51 
52 uint64_t px_tlu_ue_intr_mask	= PX_ERR_EN_ALL;
53 uint64_t px_tlu_ue_log_mask	= PX_ERR_EN_ALL;
54 uint64_t px_tlu_ue_count_mask	= PX_ERR_EN_ALL;
55 
56 uint64_t px_tlu_ce_intr_mask	= PX_ERR_MASK_NONE;
57 uint64_t px_tlu_ce_log_mask	= PX_ERR_MASK_NONE;
58 uint64_t px_tlu_ce_count_mask	= PX_ERR_MASK_NONE;
59 
60 /*
61  * Do not enable Link Interrupts
62  */
63 uint64_t px_tlu_oe_intr_mask	= PX_ERR_EN_ALL & ~0x80000000800;
64 uint64_t px_tlu_oe_log_mask	= PX_ERR_EN_ALL & ~0x80000000800;
65 uint64_t px_tlu_oe_count_mask	= PX_ERR_EN_ALL;
66 
67 uint64_t px_mmu_intr_mask	= PX_ERR_EN_ALL;
68 uint64_t px_mmu_log_mask	= PX_ERR_EN_ALL;
69 uint64_t px_mmu_count_mask	= PX_ERR_EN_ALL;
70 
71 uint64_t px_imu_intr_mask	= PX_ERR_EN_ALL;
72 uint64_t px_imu_log_mask	= PX_ERR_EN_ALL;
73 uint64_t px_imu_count_mask	= PX_ERR_EN_ALL;
74 
75 /*
76  * (1ull << ILU_INTERRUPT_ENABLE_IHB_PE_S) |
77  * (1ull << ILU_INTERRUPT_ENABLE_IHB_PE_P);
78  */
79 uint64_t px_ilu_intr_mask	= (((uint64_t)0x10 << 32) | 0x10);
80 uint64_t px_ilu_log_mask	= (((uint64_t)0x10 << 32) | 0x10);
81 uint64_t px_ilu_count_mask	= PX_ERR_EN_ALL;
82 
83 uint64_t px_ubc_intr_mask	= PX_ERR_EN_ALL;
84 uint64_t px_ubc_log_mask		= PX_ERR_EN_ALL;
85 uint64_t px_ubc_count_mask	= PX_ERR_EN_ALL;
86 
87 uint64_t px_jbc_intr_mask	= PX_ERR_EN_ALL;
88 uint64_t px_jbc_log_mask		= PX_ERR_EN_ALL;
89 uint64_t px_jbc_count_mask	= PX_ERR_EN_ALL;
90 
91 /*
92  * LPU Intr Registers are reverse encoding from the registers above.
93  * 1 = disable
94  * 0 = enable
95  *
96  * Log and Count are however still the same.
97  */
98 uint64_t px_lpul_intr_mask	= LPU_INTR_DISABLE;
99 uint64_t px_lpul_log_mask	= PX_ERR_EN_ALL;
100 uint64_t px_lpul_count_mask	= PX_ERR_EN_ALL;
101 
102 uint64_t px_lpup_intr_mask	= LPU_INTR_DISABLE;
103 uint64_t px_lpup_log_mask	= PX_ERR_EN_ALL;
104 uint64_t px_lpup_count_mask	= PX_ERR_EN_ALL;
105 
106 uint64_t px_lpur_intr_mask	= LPU_INTR_DISABLE;
107 uint64_t px_lpur_log_mask	= PX_ERR_EN_ALL;
108 uint64_t px_lpur_count_mask	= PX_ERR_EN_ALL;
109 
110 uint64_t px_lpux_intr_mask	= LPU_INTR_DISABLE;
111 uint64_t px_lpux_log_mask	= PX_ERR_EN_ALL;
112 uint64_t px_lpux_count_mask	= PX_ERR_EN_ALL;
113 
114 uint64_t px_lpus_intr_mask	= LPU_INTR_DISABLE;
115 uint64_t px_lpus_log_mask	= PX_ERR_EN_ALL;
116 uint64_t px_lpus_count_mask	= PX_ERR_EN_ALL;
117 
118 uint64_t px_lpug_intr_mask	= LPU_INTR_DISABLE;
119 uint64_t px_lpug_log_mask	= PX_ERR_EN_ALL;
120 uint64_t px_lpug_count_mask	= PX_ERR_EN_ALL;
121 
122 /*
123  * JBC error bit table
124  */
125 #define	JBC_BIT_DESC(bit, hdl, erpt) \
126 	JBC_INTERRUPT_STATUS_ ## bit ## _P, \
127 	0, \
128 	PX_ERR_BIT_HANDLE(hdl), \
129 	PX_ERPT_SEND(erpt), \
130 	PX_ERR_JBC_CLASS(bit) }, \
131 	{ JBC_INTERRUPT_STATUS_ ## bit ## _S, \
132 	0, \
133 	PX_ERR_BIT_HANDLE(hdl), \
134 	PX_ERPT_SEND(erpt), \
135 	PX_ERR_JBC_CLASS(bit)
136 px_err_bit_desc_t px_err_jbc_tbl[] = {
137 	/* JBC FATAL */
138 	{ JBC_BIT_DESC(MB_PEA,	hw_reset,	jbc_fatal) },
139 	{ JBC_BIT_DESC(CPE,	hw_reset,	jbc_fatal) },
140 	{ JBC_BIT_DESC(APE,	hw_reset,	jbc_fatal) },
141 	{ JBC_BIT_DESC(PIO_CPE,	hw_reset,	jbc_fatal) },
142 	{ JBC_BIT_DESC(JTCEEW,	hw_reset,	jbc_fatal) },
143 	{ JBC_BIT_DESC(JTCEEI,	hw_reset,	jbc_fatal) },
144 	{ JBC_BIT_DESC(JTCEER,	hw_reset,	jbc_fatal) },
145 
146 	/* JBC MERGE */
147 	{ JBC_BIT_DESC(MB_PER,	jbc_merge,	jbc_merge) },
148 	{ JBC_BIT_DESC(MB_PEW,	jbc_merge,	jbc_merge) },
149 
150 	/* JBC Jbusint IN */
151 	{ JBC_BIT_DESC(UE_ASYN,	panic,		jbc_in) },
152 	{ JBC_BIT_DESC(CE_ASYN,	no_error,	jbc_in) },
153 	{ JBC_BIT_DESC(JTE,	panic,		jbc_in) },
154 	{ JBC_BIT_DESC(JBE,	panic,		jbc_in) },
155 	{ JBC_BIT_DESC(JUE,	panic,		jbc_in) },
156 	{ JBC_BIT_DESC(ICISE,	panic,		jbc_in) },
157 	{ JBC_BIT_DESC(WR_DPE,	jbc_jbusint_in,	jbc_in) },
158 	{ JBC_BIT_DESC(RD_DPE,	jbc_jbusint_in,	jbc_in) },
159 	{ JBC_BIT_DESC(ILL_BMW,	panic,		jbc_in) },
160 	{ JBC_BIT_DESC(ILL_BMR,	panic,		jbc_in) },
161 	{ JBC_BIT_DESC(BJC,	panic,		jbc_in) },
162 
163 	/* JBC Jbusint Out */
164 	{ JBC_BIT_DESC(IJP,	panic,		jbc_out) },
165 
166 	/*
167 	 * JBC Dmcint ODCD
168 	 *
169 	 * Error bits which can be set via a bad PCItool access go through
170 	 * jbc_safe_acc instead.
171 	 */
172 	{ JBC_BIT_DESC(PIO_UNMAP_RD,	jbc_safe_acc,		jbc_odcd) },
173 	{ JBC_BIT_DESC(ILL_ACC_RD,	jbc_safe_acc,		jbc_odcd) },
174 	{ JBC_BIT_DESC(PIO_UNMAP,	jbc_safe_acc,		jbc_odcd) },
175 	{ JBC_BIT_DESC(PIO_DPE,		jbc_dmcint_odcd,	jbc_odcd) },
176 	{ JBC_BIT_DESC(PIO_CPE,		hw_reset,		jbc_odcd) },
177 	{ JBC_BIT_DESC(ILL_ACC,		jbc_safe_acc,		jbc_odcd) },
178 
179 	/* JBC Dmcint IDC */
180 	{ JBC_BIT_DESC(UNSOL_RD,	no_panic,	jbc_idc) },
181 	{ JBC_BIT_DESC(UNSOL_INTR,	no_panic,	jbc_idc) },
182 
183 	/* JBC CSR */
184 	{ JBC_BIT_DESC(EBUS_TO,		panic,		jbc_csr) }
185 };
186 
187 #define	px_err_jbc_keys \
188 	(sizeof (px_err_jbc_tbl)) / (sizeof (px_err_bit_desc_t))
189 
190 /*
191  * UBC error bit table
192  */
193 #define	UBC_BIT_DESC(bit, hdl, erpt) \
194 	UBC_INTERRUPT_STATUS_ ## bit ## _P, \
195 	0, \
196 	PX_ERR_BIT_HANDLE(hdl), \
197 	PX_ERPT_SEND(erpt), \
198 	PX_ERR_UBC_CLASS(bit) }, \
199 	{ UBC_INTERRUPT_STATUS_ ## bit ## _S, \
200 	0, \
201 	PX_ERR_BIT_HANDLE(hdl), \
202 	PX_ERPT_SEND(erpt), \
203 	PX_ERR_UBC_CLASS(bit)
204 px_err_bit_desc_t px_err_ubc_tbl[] = {
205 	/* UBC FATAL  */
206 	{ UBC_BIT_DESC(DMARDUEA,	no_panic,	ubc_fatal) },
207 	{ UBC_BIT_DESC(DMAWTUEA,	panic,		ubc_fatal) },
208 	{ UBC_BIT_DESC(MEMRDAXA,	panic,		ubc_fatal) },
209 	{ UBC_BIT_DESC(MEMWTAXA,	panic,		ubc_fatal) },
210 	{ UBC_BIT_DESC(DMARDUEB,	no_panic,	ubc_fatal) },
211 	{ UBC_BIT_DESC(DMAWTUEB,	panic,		ubc_fatal) },
212 	{ UBC_BIT_DESC(MEMRDAXB,	panic,		ubc_fatal) },
213 	{ UBC_BIT_DESC(MEMWTAXB,	panic,		ubc_fatal) },
214 	{ UBC_BIT_DESC(PIOWTUE,		panic,		ubc_fatal) },
215 	{ UBC_BIT_DESC(PIOWBEUE,	panic,		ubc_fatal) },
216 	{ UBC_BIT_DESC(PIORBEUE,	panic,		ubc_fatal) }
217 };
218 
219 #define	px_err_ubc_keys \
220 	(sizeof (px_err_ubc_tbl)) / (sizeof (px_err_bit_desc_t))
221 
222 
223 char *ubc_class_eid_qualifier[] = {
224 	"-mem",
225 	"-channel",
226 	"-cpu",
227 	"-path"
228 };
229 
230 
231 /*
232  * DMC error bit tables
233  */
234 #define	IMU_BIT_DESC(bit, hdl, erpt) \
235 	IMU_INTERRUPT_STATUS_ ## bit ## _P, \
236 	0, \
237 	PX_ERR_BIT_HANDLE(hdl), \
238 	PX_ERPT_SEND(erpt), \
239 	PX_ERR_DMC_CLASS(bit) }, \
240 	{ IMU_INTERRUPT_STATUS_ ## bit ## _S, \
241 	0, \
242 	PX_ERR_BIT_HANDLE(hdl), \
243 	PX_ERPT_SEND(erpt), \
244 	PX_ERR_DMC_CLASS(bit)
245 px_err_bit_desc_t px_err_imu_tbl[] = {
246 	/* DMC IMU RDS */
247 	{ IMU_BIT_DESC(MSI_MAL_ERR,		panic,		imu_rds) },
248 	{ IMU_BIT_DESC(MSI_PAR_ERR,		panic,		imu_rds) },
249 	{ IMU_BIT_DESC(PMEACK_MES_NOT_EN,	panic,		imu_rds) },
250 	{ IMU_BIT_DESC(PMPME_MES_NOT_EN,	panic,		imu_rds) },
251 	{ IMU_BIT_DESC(FATAL_MES_NOT_EN,	panic,		imu_rds) },
252 	{ IMU_BIT_DESC(NONFATAL_MES_NOT_EN,	panic,		imu_rds) },
253 	{ IMU_BIT_DESC(COR_MES_NOT_EN,		panic,		imu_rds) },
254 	{ IMU_BIT_DESC(MSI_NOT_EN,		panic,		imu_rds) },
255 
256 	/* DMC IMU SCS */
257 	{ IMU_BIT_DESC(EQ_NOT_EN,		panic,		imu_scs) },
258 
259 	/* DMC IMU */
260 	{ IMU_BIT_DESC(EQ_OVER,			imu_eq_ovfl,	imu) }
261 };
262 
263 #define	px_err_imu_keys (sizeof (px_err_imu_tbl)) / (sizeof (px_err_bit_desc_t))
264 
265 /* mmu errors */
266 #define	MMU_BIT_DESC(bit, hdl, erpt) \
267 	MMU_INTERRUPT_STATUS_ ## bit ## _P, \
268 	0, \
269 	PX_ERR_BIT_HANDLE(hdl), \
270 	PX_ERPT_SEND(erpt), \
271 	PX_ERR_DMC_CLASS(bit) }, \
272 	{ MMU_INTERRUPT_STATUS_ ## bit ## _S, \
273 	0, \
274 	PX_ERR_BIT_HANDLE(hdl), \
275 	PX_ERPT_SEND(erpt), \
276 	PX_ERR_DMC_CLASS(bit)
277 px_err_bit_desc_t px_err_mmu_tbl[] = {
278 	/* DMC MMU TFAR/TFSR */
279 	{ MMU_BIT_DESC(BYP_ERR,		mmu_rbne,	mmu_tfar_tfsr) },
280 	{ MMU_BIT_DESC(BYP_OOR,		mmu_tfa,	mmu_tfar_tfsr) },
281 	{ MMU_BIT_DESC(TRN_ERR,		panic,		mmu_tfar_tfsr) },
282 	{ MMU_BIT_DESC(TRN_OOR,		mmu_tfa,	mmu_tfar_tfsr) },
283 	{ MMU_BIT_DESC(TTE_INV,		mmu_tfa,	mmu_tfar_tfsr) },
284 	{ MMU_BIT_DESC(TTE_PRT,		mmu_tfa,	mmu_tfar_tfsr) },
285 	{ MMU_BIT_DESC(TTC_DPE,		mmu_parity,	mmu_tfar_tfsr) },
286 	{ MMU_BIT_DESC(TBW_DME,		panic,		mmu_tfar_tfsr) },
287 	{ MMU_BIT_DESC(TBW_UDE,		panic,		mmu_tfar_tfsr) },
288 	{ MMU_BIT_DESC(TBW_ERR,		panic,		mmu_tfar_tfsr) },
289 	{ MMU_BIT_DESC(TBW_DPE,		mmu_parity,	mmu_tfar_tfsr) },
290 
291 	/* DMC MMU */
292 	{ MMU_BIT_DESC(TTC_CAE,		panic,		mmu) }
293 };
294 #define	px_err_mmu_keys (sizeof (px_err_mmu_tbl)) / (sizeof (px_err_bit_desc_t))
295 
296 
297 /*
298  * PEC error bit tables
299  */
300 #define	ILU_BIT_DESC(bit, hdl, erpt) \
301 	ILU_INTERRUPT_STATUS_ ## bit ## _P, \
302 	0, \
303 	PX_ERR_BIT_HANDLE(hdl), \
304 	PX_ERPT_SEND(erpt), \
305 	PX_ERR_PEC_CLASS(bit) }, \
306 	{ ILU_INTERRUPT_STATUS_ ## bit ## _S, \
307 	0, \
308 	PX_ERR_BIT_HANDLE(hdl), \
309 	PX_ERPT_SEND(erpt), \
310 	PX_ERR_PEC_CLASS(bit)
311 px_err_bit_desc_t px_err_ilu_tbl[] = {
312 	/* PEC ILU none */
313 	{ ILU_BIT_DESC(IHB_PE,		panic,		pec_ilu) }
314 };
315 #define	px_err_ilu_keys \
316 	(sizeof (px_err_ilu_tbl)) / (sizeof (px_err_bit_desc_t))
317 
318 /*
319  * PEC UE errors implementation is incomplete pending PCIE generic
320  * fabric rules.  Must handle both PRIMARY and SECONDARY errors.
321  */
322 /* pec ue errors */
323 #define	TLU_UC_BIT_DESC(bit, hdl, erpt) \
324 	TLU_UNCORRECTABLE_ERROR_STATUS_CLEAR_ ## bit ## _P, \
325 	0, \
326 	PX_ERR_BIT_HANDLE(hdl), \
327 	PX_ERPT_SEND(erpt), \
328 	PX_ERR_PEC_CLASS(bit) }, \
329 	{ TLU_UNCORRECTABLE_ERROR_STATUS_CLEAR_ ## bit ## _S, \
330 	0, \
331 	PX_ERR_BIT_HANDLE(hdl), \
332 	PX_ERPT_SEND(erpt), \
333 	PX_ERR_PEC_CLASS(bit)
334 #define	TLU_UC_OB_BIT_DESC(bit, hdl, erpt) \
335 	TLU_UNCORRECTABLE_ERROR_STATUS_CLEAR_ ## bit ## _P, \
336 	0, \
337 	PX_ERR_BIT_HANDLE(hdl), \
338 	PX_ERPT_SEND(erpt), \
339 	PX_ERR_PEC_OB_CLASS(bit) }, \
340 	{ TLU_UNCORRECTABLE_ERROR_STATUS_CLEAR_ ## bit ## _S, \
341 	0, \
342 	PX_ERR_BIT_HANDLE(hdl), \
343 	PX_ERPT_SEND(erpt), \
344 	PX_ERR_PEC_OB_CLASS(bit)
345 px_err_bit_desc_t px_err_tlu_ue_tbl[] = {
346 	/* PCI-E Receive Uncorrectable Errors */
347 	{ TLU_UC_BIT_DESC(UR,		pciex_ue,	pciex_rx_ue) },
348 	{ TLU_UC_BIT_DESC(UC,		pciex_ue,	pciex_rx_ue) },
349 
350 	/* PCI-E Transmit Uncorrectable Errors */
351 	{ TLU_UC_OB_BIT_DESC(ECRC,	pciex_ue,	pciex_rx_ue) },
352 	{ TLU_UC_BIT_DESC(CTO,		pciex_ue,	pciex_tx_ue) },
353 	{ TLU_UC_BIT_DESC(ROF,		pciex_ue,	pciex_tx_ue) },
354 
355 	/* PCI-E Rx/Tx Uncorrectable Errors */
356 	{ TLU_UC_BIT_DESC(MFP,		pciex_ue,	pciex_rx_tx_ue) },
357 	{ TLU_UC_BIT_DESC(PP,		pciex_ue,	pciex_rx_tx_ue) },
358 
359 	/* Other PCI-E Uncorrectable Errors */
360 	{ TLU_UC_BIT_DESC(FCP,		pciex_ue,	pciex_ue) },
361 	{ TLU_UC_BIT_DESC(DLP,		pciex_ue,	pciex_ue) },
362 	{ TLU_UC_BIT_DESC(TE,		pciex_ue,	pciex_ue) },
363 
364 	/* Not used */
365 	{ TLU_UC_BIT_DESC(CA,		pciex_ue,	do_not) }
366 };
367 #define	px_err_tlu_ue_keys \
368 	(sizeof (px_err_tlu_ue_tbl)) / (sizeof (px_err_bit_desc_t))
369 
370 
371 /*
372  * PEC CE errors implementation is incomplete pending PCIE generic
373  * fabric rules.
374  */
375 /* pec ce errors */
376 #define	TLU_CE_BIT_DESC(bit, hdl, erpt) \
377 	TLU_CORRECTABLE_ERROR_STATUS_CLEAR_ ## bit ## _P, \
378 	0, \
379 	PX_ERR_BIT_HANDLE(hdl), \
380 	PX_ERPT_SEND(erpt), \
381 	PX_ERR_PEC_CLASS(bit) }, \
382 	{ TLU_CORRECTABLE_ERROR_STATUS_CLEAR_ ## bit ## _S, \
383 	0, \
384 	PX_ERR_BIT_HANDLE(hdl), \
385 	PX_ERPT_SEND(erpt), \
386 	PX_ERR_PEC_CLASS(bit)
387 px_err_bit_desc_t px_err_tlu_ce_tbl[] = {
388 	/* PCI-E Correctable Errors */
389 	{ TLU_CE_BIT_DESC(RTO,		pciex_ce,	pciex_ce) },
390 	{ TLU_CE_BIT_DESC(RNR,		pciex_ce,	pciex_ce) },
391 	{ TLU_CE_BIT_DESC(BDP,		pciex_ce,	pciex_ce) },
392 	{ TLU_CE_BIT_DESC(BTP,		pciex_ce,	pciex_ce) },
393 	{ TLU_CE_BIT_DESC(RE,		pciex_ce,	pciex_ce) }
394 };
395 #define	px_err_tlu_ce_keys \
396 	(sizeof (px_err_tlu_ce_tbl)) / (sizeof (px_err_bit_desc_t))
397 
398 
399 /* pec oe errors */
400 #define	TLU_OE_BIT_DESC(bit, hdl, erpt) \
401 	TLU_OTHER_EVENT_STATUS_CLEAR_ ## bit ## _P, \
402 	0, \
403 	PX_ERR_BIT_HANDLE(hdl), \
404 	PX_ERPT_SEND(erpt), \
405 	PX_ERR_PEC_CLASS(bit) }, \
406 	{ TLU_OTHER_EVENT_STATUS_CLEAR_ ## bit ## _S, \
407 	0, \
408 	PX_ERR_BIT_HANDLE(hdl), \
409 	PX_ERPT_SEND(erpt), \
410 	PX_ERR_PEC_CLASS(bit)
411 #define	TLU_OE_OB_BIT_DESC(bit, hdl, erpt) \
412 	TLU_OTHER_EVENT_STATUS_CLEAR_ ## bit ## _P, \
413 	0, \
414 	PX_ERR_BIT_HANDLE(hdl), \
415 	PX_ERPT_SEND(erpt), \
416 	PX_ERR_PEC_OB_CLASS(bit) }, \
417 	{ TLU_OTHER_EVENT_STATUS_CLEAR_ ## bit ## _S, \
418 	0, \
419 	PX_ERR_BIT_HANDLE(hdl), \
420 	PX_ERPT_SEND(erpt), \
421 	PX_ERR_PEC_OB_CLASS(bit)
422 px_err_bit_desc_t px_err_tlu_oe_tbl[] = {
423 	/* TLU Other Event Status (receive only) */
424 	{ TLU_OE_BIT_DESC(MRC,		hw_reset,	pciex_rx_oe) },
425 
426 	/* TLU Other Event Status (rx + tx) */
427 	{ TLU_OE_BIT_DESC(WUC,		wuc_ruc,	pciex_rx_tx_oe) },
428 	{ TLU_OE_BIT_DESC(RUC,		wuc_ruc,	pciex_rx_tx_oe) },
429 	{ TLU_OE_BIT_DESC(CRS,		no_panic,	pciex_rx_tx_oe) },
430 
431 	/* TLU Other Event */
432 	{ TLU_OE_BIT_DESC(IIP,		panic,		pciex_oe) },
433 	{ TLU_OE_BIT_DESC(EDP,		panic,		pciex_oe) },
434 	{ TLU_OE_BIT_DESC(EHP,		panic,		pciex_oe) },
435 	{ TLU_OE_OB_BIT_DESC(TLUEITMO,	panic,		pciex_oe) },
436 	{ TLU_OE_BIT_DESC(LIN,		no_panic,	pciex_oe) },
437 	{ TLU_OE_BIT_DESC(LRS,		no_panic,	pciex_oe) },
438 	{ TLU_OE_BIT_DESC(LDN,		tlu_ldn,	pciex_oe) },
439 	{ TLU_OE_BIT_DESC(LUP,		tlu_lup,	pciex_oe) },
440 	{ TLU_OE_BIT_DESC(ERU,		panic,		pciex_oe) },
441 	{ TLU_OE_BIT_DESC(ERO,		panic,		pciex_oe) },
442 	{ TLU_OE_BIT_DESC(EMP,		panic,		pciex_oe) },
443 	{ TLU_OE_BIT_DESC(EPE,		panic,		pciex_oe) },
444 	{ TLU_OE_BIT_DESC(ERP,		panic,		pciex_oe) },
445 	{ TLU_OE_BIT_DESC(EIP,		panic,		pciex_oe) }
446 };
447 
448 #define	px_err_tlu_oe_keys \
449 	(sizeof (px_err_tlu_oe_tbl)) / (sizeof (px_err_bit_desc_t))
450 
451 
452 /*
453  * All the following tables below are for LPU Interrupts.  These interrupts
454  * are *NOT* error interrupts, but event status interrupts.
455  *
456  * These events are probably of most interest to:
457  * o Hotplug
458  * o Power Management
459  * o etc...
460  *
461  * There are also a few events that would be interresting for FMA.
462  * Again none of the regiseters below state that an error has occured
463  * or that data has been lost.  If anything, they give status that an
464  * error is *about* to occur.  examples
465  * o INT_SKP_ERR - indicates clock between fire and child is too far
466  *		   off and is most unlikely able to compensate
467  * o INT_TX_PAR_ERR - A parity error occured in ONE lane.  This is
468  *		      HW recoverable, but will like end up as a future
469  *		      fabric error as well.
470  *
471  * For now, we don't care about any of these errors and should be ignore,
472  * but cleared.
473  */
474 
475 /* LPU Link Interrupt Table */
476 #define	LPUL_BIT_DESC(bit, hdl, erpt) \
477 	LPU_LINK_LAYER_INTERRUPT_AND_STATUS_INT_ ## bit, \
478 	0, \
479 	NULL, \
480 	NULL, \
481 	""
482 px_err_bit_desc_t px_err_lpul_tbl[] = {
483 	{ LPUL_BIT_DESC(LINK_ERR_ACT,	NULL,		NULL) }
484 };
485 #define	px_err_lpul_keys \
486 	(sizeof (px_err_lpul_tbl)) / (sizeof (px_err_bit_desc_t))
487 
488 /* LPU Physical Interrupt Table */
489 #define	LPUP_BIT_DESC(bit, hdl, erpt) \
490 	LPU_PHY_LAYER_INTERRUPT_AND_STATUS_INT_ ## bit, \
491 	0, \
492 	NULL, \
493 	NULL, \
494 	""
495 px_err_bit_desc_t px_err_lpup_tbl[] = {
496 	{ LPUP_BIT_DESC(PHY_LAYER_ERR,	NULL,		NULL) }
497 };
498 #define	px_err_lpup_keys \
499 	(sizeof (px_err_lpup_tbl)) / (sizeof (px_err_bit_desc_t))
500 
501 /* LPU Receive Interrupt Table */
502 #define	LPUR_BIT_DESC(bit, hdl, erpt) \
503 	LPU_RECEIVE_PHY_INTERRUPT_AND_STATUS_INT_ ## bit, \
504 	0, \
505 	NULL, \
506 	NULL, \
507 	""
508 px_err_bit_desc_t px_err_lpur_tbl[] = {
509 	{ LPUR_BIT_DESC(RCV_PHY,	NULL,		NULL) }
510 };
511 #define	px_err_lpur_keys \
512 	(sizeof (px_err_lpur_tbl)) / (sizeof (px_err_bit_desc_t))
513 
514 /* LPU Transmit Interrupt Table */
515 #define	LPUX_BIT_DESC(bit, hdl, erpt) \
516 	LPU_TRANSMIT_PHY_INTERRUPT_AND_STATUS_INT_ ## bit, \
517 	0, \
518 	NULL, \
519 	NULL, \
520 	""
521 px_err_bit_desc_t px_err_lpux_tbl[] = {
522 	{ LPUX_BIT_DESC(UNMSK,		NULL,		NULL) }
523 };
524 #define	px_err_lpux_keys \
525 	(sizeof (px_err_lpux_tbl)) / (sizeof (px_err_bit_desc_t))
526 
527 /* LPU LTSSM Interrupt Table */
528 #define	LPUS_BIT_DESC(bit, hdl, erpt) \
529 	LPU_LTSSM_INTERRUPT_AND_STATUS_INT_ ## bit, \
530 	0, \
531 	NULL, \
532 	NULL, \
533 	""
534 px_err_bit_desc_t px_err_lpus_tbl[] = {
535 	{ LPUS_BIT_DESC(ANY,		NULL,		NULL) }
536 };
537 #define	px_err_lpus_keys \
538 	(sizeof (px_err_lpus_tbl)) / (sizeof (px_err_bit_desc_t))
539 
540 /* LPU Gigablaze Glue Interrupt Table */
541 #define	LPUG_BIT_DESC(bit, hdl, erpt) \
542 	LPU_GIGABLAZE_GLUE_INTERRUPT_AND_STATUS_INT_ ## bit, \
543 	0, \
544 	NULL, \
545 	NULL, \
546 	""
547 px_err_bit_desc_t px_err_lpug_tbl[] = {
548 	{ LPUG_BIT_DESC(GLOBL_UNMSK,	NULL,		NULL) }
549 };
550 #define	px_err_lpug_keys \
551 	(sizeof (px_err_lpug_tbl)) / (sizeof (px_err_bit_desc_t))
552 
553 
554 /* Mask and Tables */
555 #define	MnT6X(pre) \
556 	&px_ ## pre ## _intr_mask, \
557 	&px_ ## pre ## _log_mask, \
558 	&px_ ## pre ## _count_mask, \
559 	px_err_ ## pre ## _tbl, \
560 	px_err_ ## pre ## _keys, \
561 	PX_REG_XBC, \
562 	0
563 
564 #define	MnT6(pre) \
565 	&px_ ## pre ## _intr_mask, \
566 	&px_ ## pre ## _log_mask, \
567 	&px_ ## pre ## _count_mask, \
568 	px_err_ ## pre ## _tbl, \
569 	px_err_ ## pre ## _keys, \
570 	PX_REG_CSR, \
571 	0
572 
573 /* LPU Registers Addresses */
574 #define	LR4(pre) \
575 	NULL, \
576 	LPU_ ## pre ## _INTERRUPT_MASK, \
577 	LPU_ ## pre ## _INTERRUPT_AND_STATUS, \
578 	LPU_ ## pre ## _INTERRUPT_AND_STATUS
579 
580 /* LPU Registers Addresses with Irregularities */
581 #define	LR4_FIXME(pre) \
582 	NULL, \
583 	LPU_ ## pre ## _INTERRUPT_MASK, \
584 	LPU_ ## pre ## _LAYER_INTERRUPT_AND_STATUS, \
585 	LPU_ ## pre ## _LAYER_INTERRUPT_AND_STATUS
586 
587 /* TLU Registers Addresses */
588 #define	TR4(pre) \
589 	TLU_ ## pre ## _LOG_ENABLE, \
590 	TLU_ ## pre ## _INTERRUPT_ENABLE, \
591 	TLU_ ## pre ## _INTERRUPT_STATUS, \
592 	TLU_ ## pre ## _STATUS_CLEAR
593 
594 /* Registers Addresses for JBC, UBC, MMU, IMU and ILU */
595 #define	R4(pre) \
596 	pre ## _ERROR_LOG_ENABLE, \
597 	pre ## _INTERRUPT_ENABLE, \
598 	pre ## _INTERRUPT_STATUS, \
599 	pre ## _ERROR_STATUS_CLEAR
600 
601 /* Bits in chip_mask, set according to type. */
602 #define	CHP_O	BITMASK(PX_CHIP_OBERON)
603 #define	CHP_F	BITMASK(PX_CHIP_FIRE)
604 #define	CHP_FO	(CHP_F | CHP_O)
605 
606 /*
607  * Register error handling tables.
608  * The ID Field (first field) is identified by an enum px_err_id_t.
609  * It is located in px_err.h
610  */
611 static const
612 px_err_reg_desc_t px_err_reg_tbl[] = {
613 	{ CHP_F,  MnT6X(jbc),	R4(JBC),		  "JBC Error"},
614 	{ CHP_O,  MnT6X(ubc),	R4(UBC),		  "UBC Error"},
615 	{ CHP_FO, MnT6(mmu),	R4(MMU),		  "MMU Error"},
616 	{ CHP_FO, MnT6(imu),	R4(IMU),		  "IMU Error"},
617 	{ CHP_FO, MnT6(tlu_ue),	TR4(UNCORRECTABLE_ERROR), "TLU UE"},
618 	{ CHP_FO, MnT6(tlu_ce),	TR4(CORRECTABLE_ERROR),	  "TLU CE"},
619 	{ CHP_FO, MnT6(tlu_oe),	TR4(OTHER_EVENT),	  "TLU OE"},
620 	{ CHP_FO, MnT6(ilu),	R4(ILU),		  "ILU Error"},
621 	{ CHP_F,  MnT6(lpul),	LR4(LINK_LAYER),	  "LPU Link Layer"},
622 	{ CHP_F,  MnT6(lpup),	LR4_FIXME(PHY),		  "LPU Phy Layer"},
623 	{ CHP_F,  MnT6(lpur),	LR4(RECEIVE_PHY),	  "LPU RX Phy Layer"},
624 	{ CHP_F,  MnT6(lpux),	LR4(TRANSMIT_PHY),	  "LPU TX Phy Layer"},
625 	{ CHP_F,  MnT6(lpus),	LR4(LTSSM),		  "LPU LTSSM"},
626 	{ CHP_F,  MnT6(lpug),	LR4(GIGABLAZE_GLUE),	  "LPU GigaBlaze Glue"},
627 };
628 
629 #define	PX_ERR_REG_KEYS	(sizeof (px_err_reg_tbl)) / (sizeof (px_err_reg_tbl[0]))
630 
631 typedef struct px_err_ss {
632 	uint64_t err_status[PX_ERR_REG_KEYS];
633 } px_err_ss_t;
634 
635 static void px_err_snapshot(px_t *px_p, px_err_ss_t *ss, int block);
636 static int  px_err_erpt_and_clr(px_t *px_p, ddi_fm_error_t *derr,
637     px_err_ss_t *ss);
638 static int  px_err_check_severity(px_t *px_p, ddi_fm_error_t *derr,
639     int err, int caller);
640 
641 /*
642  * px_err_cb_intr:
643  * Interrupt handler for the JBC/UBC block.
644  * o lock
645  * o create derr
646  * o px_err_cmn_intr
647  * o unlock
648  * o handle error: fatal? fm_panic() : return INTR_CLAIMED)
649  */
650 uint_t
651 px_err_cb_intr(caddr_t arg)
652 {
653 	px_fault_t	*px_fault_p = (px_fault_t *)arg;
654 	dev_info_t	*rpdip = px_fault_p->px_fh_dip;
655 	px_t		*px_p = DIP_TO_STATE(rpdip);
656 	int		err;
657 	ddi_fm_error_t	derr;
658 
659 	/* Create the derr */
660 	bzero(&derr, sizeof (ddi_fm_error_t));
661 	derr.fme_version = DDI_FME_VERSION;
662 	derr.fme_ena = fm_ena_generate(0, FM_ENA_FMT1);
663 	derr.fme_flag = DDI_FM_ERR_UNEXPECTED;
664 
665 	if (px_fm_enter(px_p) != DDI_SUCCESS)
666 		goto done;
667 
668 	err = px_err_cmn_intr(px_p, &derr, PX_INTR_CALL, PX_FM_BLOCK_HOST);
669 	(void) px_lib_intr_setstate(rpdip, px_fault_p->px_fh_sysino,
670 	    INTR_IDLE_STATE);
671 
672 	px_err_panic(err, PX_HB, PX_NO_ERROR, B_TRUE);
673 	px_fm_exit(px_p);
674 	px_err_panic(err, PX_HB, PX_NO_ERROR, B_FALSE);
675 
676 done:
677 	return (DDI_INTR_CLAIMED);
678 }
679 
680 /*
681  * px_err_dmc_pec_intr:
682  * Interrupt handler for the DMC/PEC block.
683  * o lock
684  * o create derr
685  * o px_err_cmn_intr(leaf, with out cb)
686  * o pcie_scan_fabric (leaf)
687  * o unlock
688  * o handle error: fatal? fm_panic() : return INTR_CLAIMED)
689  */
690 uint_t
691 px_err_dmc_pec_intr(caddr_t arg)
692 {
693 	px_fault_t	*px_fault_p = (px_fault_t *)arg;
694 	dev_info_t	*rpdip = px_fault_p->px_fh_dip;
695 	px_t		*px_p = DIP_TO_STATE(rpdip);
696 	int		rc_err, fab_err;
697 	ddi_fm_error_t	derr;
698 
699 	/* Create the derr */
700 	bzero(&derr, sizeof (ddi_fm_error_t));
701 	derr.fme_version = DDI_FME_VERSION;
702 	derr.fme_ena = fm_ena_generate(0, FM_ENA_FMT1);
703 	derr.fme_flag = DDI_FM_ERR_UNEXPECTED;
704 
705 	if (px_fm_enter(px_p) != DDI_SUCCESS)
706 		goto done;
707 
708 	/* send ereport/handle/clear fire registers */
709 	rc_err = px_err_cmn_intr(px_p, &derr, PX_INTR_CALL, PX_FM_BLOCK_PCIE);
710 
711 	/* Check all child devices for errors */
712 	fab_err = px_scan_fabric(px_p, rpdip, &derr);
713 
714 	/* Set the interrupt state to idle */
715 	(void) px_lib_intr_setstate(rpdip, px_fault_p->px_fh_sysino,
716 	    INTR_IDLE_STATE);
717 
718 	px_err_panic(rc_err, PX_RC, fab_err, B_TRUE);
719 	px_fm_exit(px_p);
720 	px_err_panic(rc_err, PX_RC, fab_err, B_FALSE);
721 
722 done:
723 	return (DDI_INTR_CLAIMED);
724 }
725 
726 /*
727  * Proper csr_base is responsibility of the caller. (Called from px_lib_dev_init
728  * via px_err_reg_setup_all for pcie error registers;  called from
729  * px_cb_add_intr for jbc/ubc from px_cb_attach.)
730  *
731  * Note: reg_id is passed in instead of reg_desc since this function is called
732  * from px_lib4u.c, which doesn't know about the structure of the table.
733  */
734 void
735 px_err_reg_enable(px_err_id_t reg_id, caddr_t csr_base)
736 {
737 	const px_err_reg_desc_t	*reg_desc_p = &px_err_reg_tbl[reg_id];
738 	uint64_t 		intr_mask = *reg_desc_p->intr_mask_p;
739 	uint64_t 		log_mask = *reg_desc_p->log_mask_p;
740 
741 	/* Enable logs if it exists */
742 	if (reg_desc_p->log_addr != NULL)
743 		CSR_XS(csr_base, reg_desc_p->log_addr, log_mask);
744 
745 	/*
746 	 * For readability you in code you set 1 to enable an interrupt.
747 	 * But in Fire it's backwards.  You set 1 to *disable* an intr.
748 	 * Reverse the user tunable intr mask field.
749 	 *
750 	 * Disable All Errors
751 	 * Clear All Errors
752 	 * Enable Errors
753 	 */
754 	CSR_XS(csr_base, reg_desc_p->enable_addr, 0);
755 	CSR_XS(csr_base, reg_desc_p->clear_addr, -1);
756 	CSR_XS(csr_base, reg_desc_p->enable_addr, intr_mask);
757 	DBG(DBG_ATTACH, NULL, "%s Mask: 0x%llx\n", reg_desc_p->msg,
758 	    CSR_XR(csr_base, reg_desc_p->enable_addr));
759 	DBG(DBG_ATTACH, NULL, "%s Status: 0x%llx\n", reg_desc_p->msg,
760 	    CSR_XR(csr_base, reg_desc_p->status_addr));
761 	DBG(DBG_ATTACH, NULL, "%s Clear: 0x%llx\n", reg_desc_p->msg,
762 	    CSR_XR(csr_base, reg_desc_p->clear_addr));
763 	if (reg_desc_p->log_addr != NULL) {
764 		DBG(DBG_ATTACH, NULL, "%s Log: 0x%llx\n", reg_desc_p->msg,
765 		    CSR_XR(csr_base, reg_desc_p->log_addr));
766 	}
767 }
768 
769 void
770 px_err_reg_disable(px_err_id_t reg_id, caddr_t csr_base)
771 {
772 	const px_err_reg_desc_t	*reg_desc_p = &px_err_reg_tbl[reg_id];
773 	uint64_t		val = (reg_id >= PX_ERR_LPU_LINK) ? -1 : 0;
774 
775 	if (reg_desc_p->log_addr != NULL)
776 		CSR_XS(csr_base, reg_desc_p->log_addr, val);
777 	CSR_XS(csr_base, reg_desc_p->enable_addr, val);
778 }
779 
780 /*
781  * Set up pcie error registers.
782  */
783 void
784 px_err_reg_setup_pcie(uint8_t chip_mask, caddr_t csr_base, boolean_t enable)
785 {
786 	px_err_id_t		reg_id;
787 	const px_err_reg_desc_t	*reg_desc_p;
788 	void (*px_err_reg_func)(px_err_id_t, caddr_t);
789 
790 	/*
791 	 * JBC or XBC are enabled during adding of common block interrupts,
792 	 * not done here.
793 	 */
794 	px_err_reg_func = (enable ? px_err_reg_enable : px_err_reg_disable);
795 	for (reg_id = 0; reg_id < PX_ERR_REG_KEYS; reg_id++) {
796 		reg_desc_p = &px_err_reg_tbl[reg_id];
797 		if ((reg_desc_p->chip_mask & chip_mask) &&
798 		    (reg_desc_p->reg_bank == PX_REG_CSR))
799 			px_err_reg_func(reg_id, csr_base);
800 	}
801 }
802 
803 /*
804  * px_err_cmn_intr:
805  * Common function called by trap, mondo and fabric intr.
806  * o Snap shot current fire registers
807  * o check for safe access
808  * o send ereport and clear snap shot registers
809  * o create and queue RC info for later use in fabric scan.
810  *   o RUC/WUC, PTLP, MMU Errors(CA), UR
811  * o check severity of snap shot registers
812  *
813  * @param px_p		leaf in which to check access
814  * @param derr		fm err data structure to be updated
815  * @param caller	PX_TRAP_CALL | PX_INTR_CALL
816  * @param block		PX_FM_BLOCK_HOST | PX_FM_BLOCK_PCIE | PX_FM_BLOCK_ALL
817  * @return err		PX_NO_PANIC | PX_PANIC | PX_HW_RESET | PX_PROTECTED
818  */
819 int
820 px_err_cmn_intr(px_t *px_p, ddi_fm_error_t *derr, int caller, int block)
821 {
822 	px_err_ss_t		ss = {0};
823 	int			err;
824 
825 	ASSERT(MUTEX_HELD(&px_p->px_fm_mutex));
826 
827 	/* check for safe access */
828 	px_err_safeacc_check(px_p, derr);
829 
830 	/* snap shot the current fire registers */
831 	px_err_snapshot(px_p, &ss, block);
832 
833 	/* send ereports/handle/clear registers */
834 	err = px_err_erpt_and_clr(px_p, derr, &ss);
835 
836 	/* check for error severity */
837 	err = px_err_check_severity(px_p, derr, err, caller);
838 
839 	/* Mark the On Trap Handle if an error occured */
840 	if (err != PX_NO_ERROR) {
841 		px_pec_t	*pec_p = px_p->px_pec_p;
842 		on_trap_data_t	*otd = pec_p->pec_ontrap_data;
843 
844 		if ((otd != NULL) && (otd->ot_prot & OT_DATA_ACCESS))
845 			otd->ot_trap |= OT_DATA_ACCESS;
846 	}
847 
848 	return (err);
849 }
850 
851 /*
852  * Static function
853  */
854 
855 /*
856  * px_err_snapshot:
857  * Take a current snap shot of all the fire error registers.  This includes
858  * JBC/UBC, DMC, and PEC depending on the block flag
859  *
860  * @param px_p		leaf in which to take the snap shot.
861  * @param ss		pre-allocated memory to store the snap shot.
862  * @param chk_cb	boolean on whether to store jbc/ubc register.
863  */
864 static void
865 px_err_snapshot(px_t *px_p, px_err_ss_t *ss_p, int block)
866 {
867 	pxu_t	*pxu_p = (pxu_t *)px_p->px_plat_p;
868 	caddr_t	xbc_csr_base = (caddr_t)pxu_p->px_address[PX_REG_XBC];
869 	caddr_t	pec_csr_base = (caddr_t)pxu_p->px_address[PX_REG_CSR];
870 	caddr_t	csr_base;
871 	uint8_t chip_mask = 1 << PX_CHIP_TYPE(pxu_p);
872 	const px_err_reg_desc_t *reg_desc_p = px_err_reg_tbl;
873 	px_err_id_t reg_id;
874 
875 	for (reg_id = 0; reg_id < PX_ERR_REG_KEYS; reg_id++, reg_desc_p++) {
876 		if (!(reg_desc_p->chip_mask & chip_mask))
877 			continue;
878 
879 		if ((block & PX_FM_BLOCK_HOST) &&
880 		    (reg_desc_p->reg_bank == PX_REG_XBC))
881 			csr_base = xbc_csr_base;
882 		else if ((block & PX_FM_BLOCK_PCIE) &&
883 		    (reg_desc_p->reg_bank == PX_REG_CSR))
884 			csr_base = pec_csr_base;
885 		else {
886 			ss_p->err_status[reg_id] = 0;
887 			continue;
888 		}
889 
890 		ss_p->err_status[reg_id] = CSR_XR(csr_base,
891 		    reg_desc_p->status_addr);
892 	}
893 }
894 
895 /*
896  * px_err_erpt_and_clr:
897  * This function does the following thing to all the fire registers based
898  * on an earlier snap shot.
899  * o Send ereport
900  * o Handle the error
901  * o Clear the error
902  *
903  * @param px_p		leaf in which to take the snap shot.
904  * @param derr		fm err in which the ereport is to be based on
905  * @param ss_p		pre-allocated memory to store the snap shot.
906  */
907 static int
908 px_err_erpt_and_clr(px_t *px_p, ddi_fm_error_t *derr, px_err_ss_t *ss_p)
909 {
910 	dev_info_t		*rpdip = px_p->px_dip;
911 	pxu_t			*pxu_p = (pxu_t *)px_p->px_plat_p;
912 	caddr_t			csr_base;
913 	const px_err_reg_desc_t	*err_reg_tbl;
914 	px_err_bit_desc_t	*err_bit_tbl;
915 	px_err_bit_desc_t	*err_bit_desc;
916 
917 	uint64_t		*count_mask;
918 	uint64_t		clear_addr;
919 	uint64_t		ss_reg;
920 
921 	int			(*err_handler)();
922 	int			(*erpt_handler)();
923 	int			reg_id, key;
924 	int			err = PX_NO_ERROR;
925 	int			biterr = 0;
926 
927 	ASSERT(MUTEX_HELD(&px_p->px_fm_mutex));
928 
929 	/* send erport/handle/clear JBC errors */
930 	for (reg_id = 0; reg_id < PX_ERR_REG_KEYS; reg_id++) {
931 		/* Get the correct register description table */
932 		err_reg_tbl = &px_err_reg_tbl[reg_id];
933 
934 		/* Only look at enabled groups. */
935 		if (!(BIT_TST(err_reg_tbl->chip_mask, PX_CHIP_TYPE(pxu_p))))
936 			continue;
937 
938 		/* Get the correct CSR BASE */
939 		csr_base = (caddr_t)pxu_p->px_address[err_reg_tbl->reg_bank];
940 
941 		/* If there are no errors in this register, continue */
942 		ss_reg = ss_p->err_status[reg_id];
943 		if (!ss_reg)
944 			continue;
945 
946 		/* Get pointers to masks and register addresses */
947 		count_mask = err_reg_tbl->count_mask_p;
948 		clear_addr = err_reg_tbl->clear_addr;
949 
950 		/* Get the register BIT description table */
951 		err_bit_tbl = err_reg_tbl->err_bit_tbl;
952 
953 		/* For each known bit in the register send erpt and handle */
954 		for (key = 0; key < err_reg_tbl->err_bit_keys; key++) {
955 			/*
956 			 * If the ss_reg is set for this bit,
957 			 * send ereport and handle
958 			 */
959 			err_bit_desc = &err_bit_tbl[key];
960 			if (!BIT_TST(ss_reg, err_bit_desc->bit))
961 				continue;
962 
963 			/* Increment the counter if necessary */
964 			if (BIT_TST(*count_mask, err_bit_desc->bit)) {
965 				err_bit_desc->counter++;
966 			}
967 
968 			/* Error Handle for this bit */
969 			err_handler = err_bit_desc->err_handler;
970 			if (err_handler) {
971 				biterr = err_handler(rpdip, csr_base, derr,
972 				    err_reg_tbl, err_bit_desc);
973 				err |= biterr;
974 			}
975 
976 			/*
977 			 * Send the ereport if it's an UNEXPECTED err.
978 			 * This is the only place where PX_EXPECTED is utilized.
979 			 */
980 			erpt_handler = err_bit_desc->erpt_handler;
981 			if ((derr->fme_flag != DDI_FM_ERR_UNEXPECTED) ||
982 			    (biterr == PX_EXPECTED))
983 				continue;
984 
985 			if (erpt_handler)
986 				(void) erpt_handler(rpdip, csr_base, ss_reg,
987 				    derr, err_bit_desc->bit,
988 				    err_bit_desc->class_name);
989 		}
990 
991 		/* Clear the register and error */
992 		CSR_XS(csr_base, clear_addr, ss_reg);
993 	}
994 
995 	return (err);
996 }
997 
998 /*
999  * px_err_check_severity:
1000  * Check the severity of the fire error based on an earlier snapshot
1001  *
1002  * @param px_p		leaf in which to take the snap shot.
1003  * @param derr		fm err in which the ereport is to be based on
1004  * @param err		fire register error status
1005  * @param caller	PX_TRAP_CALL | PX_INTR_CALL | PX_LIB_CALL
1006  */
1007 static int
1008 px_err_check_severity(px_t *px_p, ddi_fm_error_t *derr, int err, int caller)
1009 {
1010 	px_pec_t 	*pec_p = px_p->px_pec_p;
1011 	boolean_t	is_safeacc = B_FALSE;
1012 
1013 	/*
1014 	 * Nothing to do if called with no error.
1015 	 * The err could have already been set to PX_NO_PANIC, which means the
1016 	 * system doesn't need to panic, but PEEK/POKE still failed.
1017 	 */
1018 	if (err == PX_NO_ERROR)
1019 		return (err);
1020 
1021 	/* Cautious access error handling  */
1022 	switch (derr->fme_flag) {
1023 	case DDI_FM_ERR_EXPECTED:
1024 		if (caller == PX_TRAP_CALL) {
1025 			/*
1026 			 * for ddi_caut_get treat all events as nonfatal
1027 			 * The trampoline will set err_ena = 0,
1028 			 * err_status = NONFATAL.
1029 			 */
1030 			derr->fme_status = DDI_FM_NONFATAL;
1031 			is_safeacc = B_TRUE;
1032 		} else {
1033 			/*
1034 			 * For ddi_caut_put treat all events as nonfatal. Here
1035 			 * we have the handle and can call ndi_fm_acc_err_set().
1036 			 */
1037 			derr->fme_status = DDI_FM_NONFATAL;
1038 			ndi_fm_acc_err_set(pec_p->pec_acc_hdl, derr);
1039 			is_safeacc = B_TRUE;
1040 		}
1041 		break;
1042 	case DDI_FM_ERR_PEEK:
1043 	case DDI_FM_ERR_POKE:
1044 		/*
1045 		 * For ddi_peek/poke treat all events as nonfatal.
1046 		 */
1047 		is_safeacc = B_TRUE;
1048 		break;
1049 	default:
1050 		is_safeacc = B_FALSE;
1051 	}
1052 
1053 	/* re-adjust error status from safe access, forgive all errors */
1054 	if (is_safeacc)
1055 		return (PX_NO_PANIC);
1056 
1057 	return (err);
1058 }
1059 
1060 /* predefined convenience functions */
1061 /* ARGSUSED */
1062 void
1063 px_err_log_handle(dev_info_t *rpdip, px_err_reg_desc_t *err_reg_descr,
1064 	px_err_bit_desc_t *err_bit_descr, char *msg)
1065 {
1066 	DBG(DBG_ERR_INTR, rpdip,
1067 	    "Bit %d, %s, at %s(0x%x) has occured %d times with a severity "
1068 	    "of \"%s\"\n",
1069 	    err_bit_descr->bit, err_bit_descr->class_name,
1070 	    err_reg_descr->msg, err_reg_descr->status_addr,
1071 	    err_bit_descr->counter, msg);
1072 }
1073 
1074 /* ARGSUSED */
1075 int
1076 px_err_hw_reset_handle(dev_info_t *rpdip, caddr_t csr_base,
1077 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1078 	px_err_bit_desc_t *err_bit_descr)
1079 {
1080 	if (px_log & PX_HW_RESET) {
1081 		px_err_log_handle(rpdip, err_reg_descr, err_bit_descr,
1082 		    "HW RESET");
1083 	}
1084 
1085 	return (PX_HW_RESET);
1086 }
1087 
1088 /* ARGSUSED */
1089 int
1090 px_err_panic_handle(dev_info_t *rpdip, caddr_t csr_base,
1091 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1092 	px_err_bit_desc_t *err_bit_descr)
1093 {
1094 	if (px_log & PX_PANIC) {
1095 		px_err_log_handle(rpdip, err_reg_descr, err_bit_descr, "PANIC");
1096 	}
1097 
1098 	return (PX_PANIC);
1099 }
1100 
1101 /* ARGSUSED */
1102 int
1103 px_err_protected_handle(dev_info_t *rpdip, caddr_t csr_base,
1104 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1105 	px_err_bit_desc_t *err_bit_descr)
1106 {
1107 	if (px_log & PX_PROTECTED) {
1108 		px_err_log_handle(rpdip, err_reg_descr, err_bit_descr,
1109 		    "PROTECTED");
1110 	}
1111 
1112 	return (PX_PROTECTED);
1113 }
1114 
1115 /* ARGSUSED */
1116 int
1117 px_err_no_panic_handle(dev_info_t *rpdip, caddr_t csr_base,
1118 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1119 	px_err_bit_desc_t *err_bit_descr)
1120 {
1121 	if (px_log & PX_NO_PANIC) {
1122 		px_err_log_handle(rpdip, err_reg_descr, err_bit_descr,
1123 		    "NO PANIC");
1124 	}
1125 
1126 	return (PX_NO_PANIC);
1127 }
1128 
1129 /* ARGSUSED */
1130 int
1131 px_err_no_error_handle(dev_info_t *rpdip, caddr_t csr_base,
1132 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1133 	px_err_bit_desc_t *err_bit_descr)
1134 {
1135 	if (px_log & PX_NO_ERROR) {
1136 		px_err_log_handle(rpdip, err_reg_descr, err_bit_descr,
1137 		    "NO ERROR");
1138 	}
1139 
1140 	return (PX_NO_ERROR);
1141 }
1142 
1143 /* ARGSUSED */
1144 PX_ERPT_SEND_DEC(do_not)
1145 {
1146 	return (PX_NO_ERROR);
1147 }
1148 
1149 /*
1150  * Search the px_cb_list_t embedded in the px_cb_t for the
1151  * px_t of the specified Leaf (leaf_id).  Return its associated dip.
1152  */
1153 static dev_info_t *
1154 px_err_search_cb(px_cb_t *px_cb_p, uint_t leaf_id)
1155 {
1156 	int		i;
1157 	px_cb_list_t	*pxl_elemp;
1158 
1159 	for (i = px_cb_p->attachcnt, pxl_elemp = px_cb_p->pxl; i > 0;
1160 	    i--, pxl_elemp = pxl_elemp->next) {
1161 		if ((((pxu_t *)pxl_elemp->pxp->px_plat_p)->portid &
1162 		    OBERON_PORT_ID_LEAF_MASK) == leaf_id) {
1163 			return (pxl_elemp->pxp->px_dip);
1164 		}
1165 	}
1166 	return (NULL);
1167 }
1168 
1169 /* UBC FATAL - see io erpt doc, section 1.1 */
1170 /* ARGSUSED */
1171 PX_ERPT_SEND_DEC(ubc_fatal)
1172 {
1173 	char		buf[FM_MAX_CLASS];
1174 	uint64_t	memory_ue_log, marked;
1175 	char		unum[FM_MAX_CLASS];
1176 	int		unum_length;
1177 	uint64_t	device_id = 0;
1178 	uint8_t		cpu_version = 0;
1179 	nvlist_t	*resource = NULL;
1180 	uint64_t	ubc_intr_status;
1181 	px_t		*px_p;
1182 	px_cb_t		*px_cb_p;
1183 	dev_info_t	*actual_dip;
1184 
1185 	unum[0] = '\0';
1186 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1187 
1188 	memory_ue_log = CSR_XR(csr_base, UBC_MEMORY_UE_LOG);
1189 	marked = (memory_ue_log >> UBC_MEMORY_UE_LOG_MARKED) &
1190 	    UBC_MEMORY_UE_LOG_MARKED_MASK;
1191 
1192 	if ((strstr(class_name, "ubc.piowtue") != NULL) ||
1193 	    (strstr(class_name, "ubc.piowbeue") != NULL) ||
1194 	    (strstr(class_name, "ubc.piorbeue") != NULL) ||
1195 	    (strstr(class_name, "ubc.dmarduea") != NULL) ||
1196 	    (strstr(class_name, "ubc.dmardueb") != NULL)) {
1197 		int eid = (memory_ue_log >> UBC_MEMORY_UE_LOG_EID) &
1198 		    UBC_MEMORY_UE_LOG_EID_MASK;
1199 		(void) strncat(buf, ubc_class_eid_qualifier[eid],
1200 		    FM_MAX_CLASS);
1201 
1202 		if (eid == UBC_EID_MEM) {
1203 			uint64_t phys_addr = memory_ue_log &
1204 			    MMU_OBERON_PADDR_MASK;
1205 			uint64_t offset = (uint64_t)-1;
1206 
1207 			resource = fm_nvlist_create(NULL);
1208 			if (&plat_get_mem_unum) {
1209 				if ((plat_get_mem_unum(0,
1210 				    phys_addr, 0, B_TRUE, 0, unum,
1211 				    FM_MAX_CLASS, &unum_length)) != 0)
1212 					unum[0] = '\0';
1213 			}
1214 			fm_fmri_mem_set(resource, FM_MEM_SCHEME_VERSION,
1215 			    NULL, unum, NULL, offset);
1216 
1217 		} else if (eid == UBC_EID_CPU) {
1218 			int cpuid = (marked & UBC_MARKED_MAX_CPUID_MASK);
1219 			char sbuf[21]; /* sizeof (UINT64_MAX) + '\0' */
1220 
1221 			resource = fm_nvlist_create(NULL);
1222 			cpu_version = cpunodes[cpuid].version;
1223 			device_id = cpunodes[cpuid].device_id;
1224 			(void) snprintf(sbuf, sizeof (sbuf), "%lX",
1225 			    device_id);
1226 			(void) fm_fmri_cpu_set(resource,
1227 			    FM_CPU_SCHEME_VERSION, NULL, cpuid,
1228 			    &cpu_version, sbuf);
1229 		}
1230 	}
1231 
1232 	/*
1233 	 * For most of the errors represented in the UBC Interrupt Status
1234 	 * register, one can compute the dip of the actual Leaf that was
1235 	 * involved in the error.  To do this, find the px_cb_t structure
1236 	 * that is shared between a pair of Leaves (eg, LeafA and LeafB).
1237 	 *
1238 	 * If any of the error bits for LeafA are set in the hardware
1239 	 * register, search the list of px_t's rooted in the px_cb_t for
1240 	 * the one corresponding to LeafA.  If error bits for LeafB are set,
1241 	 * search the list for LeafB's px_t.  The px_t references its
1242 	 * associated dip.
1243 	 */
1244 	px_p = DIP_TO_STATE(rpdip);
1245 	px_cb_p = ((pxu_t *)px_p->px_plat_p)->px_cb_p;
1246 
1247 	/* read hardware register */
1248 	ubc_intr_status = CSR_XR(csr_base, UBC_INTERRUPT_STATUS);
1249 
1250 	if ((ubc_intr_status & UBC_INTERRUPT_STATUS_LEAFA) != 0) {
1251 		/* then Leaf A is involved in the error */
1252 		actual_dip = px_err_search_cb(px_cb_p, OBERON_PORT_ID_LEAF_A);
1253 		ASSERT(actual_dip != NULL);
1254 		rpdip = actual_dip;
1255 	} else if ((ubc_intr_status & UBC_INTERRUPT_STATUS_LEAFB) != 0) {
1256 		/* then Leaf B is involved in the error */
1257 		actual_dip = px_err_search_cb(px_cb_p, OBERON_PORT_ID_LEAF_B);
1258 		ASSERT(actual_dip != NULL);
1259 		rpdip = actual_dip;
1260 	} /* else error cannot be associated with a Leaf */
1261 
1262 	if (resource) {
1263 		ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1264 		    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1265 		    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, B_TRUE,
1266 		    OBERON_UBC_ELE, DATA_TYPE_UINT64,
1267 		    CSR_XR(csr_base, UBC_ERROR_LOG_ENABLE),
1268 		    OBERON_UBC_IE, DATA_TYPE_UINT64,
1269 		    CSR_XR(csr_base, UBC_INTERRUPT_ENABLE),
1270 		    OBERON_UBC_IS, DATA_TYPE_UINT64, ubc_intr_status,
1271 		    OBERON_UBC_ESS, DATA_TYPE_UINT64,
1272 		    CSR_XR(csr_base, UBC_ERROR_STATUS_SET),
1273 		    OBERON_UBC_MUE, DATA_TYPE_UINT64, memory_ue_log,
1274 		    OBERON_UBC_UNUM, DATA_TYPE_STRING, unum,
1275 		    OBERON_UBC_DID, DATA_TYPE_UINT64, device_id,
1276 		    OBERON_UBC_CPUV, DATA_TYPE_UINT32, cpu_version,
1277 		    OBERON_UBC_RESOURCE, DATA_TYPE_NVLIST, resource,
1278 		    NULL);
1279 		fm_nvlist_destroy(resource, FM_NVA_FREE);
1280 	} else {
1281 		ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1282 		    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1283 		    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, B_TRUE,
1284 		    OBERON_UBC_ELE, DATA_TYPE_UINT64,
1285 		    CSR_XR(csr_base, UBC_ERROR_LOG_ENABLE),
1286 		    OBERON_UBC_IE, DATA_TYPE_UINT64,
1287 		    CSR_XR(csr_base, UBC_INTERRUPT_ENABLE),
1288 		    OBERON_UBC_IS, DATA_TYPE_UINT64, ubc_intr_status,
1289 		    OBERON_UBC_ESS, DATA_TYPE_UINT64,
1290 		    CSR_XR(csr_base, UBC_ERROR_STATUS_SET),
1291 		    OBERON_UBC_MUE, DATA_TYPE_UINT64, memory_ue_log,
1292 		    OBERON_UBC_UNUM, DATA_TYPE_STRING, unum,
1293 		    OBERON_UBC_DID, DATA_TYPE_UINT64, device_id,
1294 		    OBERON_UBC_CPUV, DATA_TYPE_UINT32, cpu_version,
1295 		    NULL);
1296 	}
1297 
1298 	return (PX_NO_PANIC);
1299 }
1300 
1301 /* JBC FATAL */
1302 PX_ERPT_SEND_DEC(jbc_fatal)
1303 {
1304 	char		buf[FM_MAX_CLASS];
1305 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1306 
1307 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1308 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1309 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1310 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1311 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1312 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1313 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1314 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1315 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1316 	    ss_reg,
1317 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1318 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1319 	    FIRE_JBC_FEL1, DATA_TYPE_UINT64,
1320 	    CSR_XR(csr_base, FATAL_ERROR_LOG_1),
1321 	    FIRE_JBC_FEL2, DATA_TYPE_UINT64,
1322 	    CSR_XR(csr_base, FATAL_ERROR_LOG_2),
1323 	    NULL);
1324 
1325 	return (PX_NO_PANIC);
1326 }
1327 
1328 /* JBC MERGE */
1329 PX_ERPT_SEND_DEC(jbc_merge)
1330 {
1331 	char		buf[FM_MAX_CLASS];
1332 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1333 
1334 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1335 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1336 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1337 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1338 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1339 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1340 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1341 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1342 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1343 	    ss_reg,
1344 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1345 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1346 	    FIRE_JBC_MTEL, DATA_TYPE_UINT64,
1347 	    CSR_XR(csr_base, MERGE_TRANSACTION_ERROR_LOG),
1348 	    NULL);
1349 
1350 	return (PX_NO_PANIC);
1351 }
1352 
1353 /*
1354  * JBC Merge buffer retryable errors:
1355  *    Merge buffer parity error (rd_buf): PIO or DMA
1356  *    Merge buffer parity error (wr_buf): PIO or DMA
1357  */
1358 /* ARGSUSED */
1359 int
1360 px_err_jbc_merge_handle(dev_info_t *rpdip, caddr_t csr_base,
1361     ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1362     px_err_bit_desc_t *err_bit_descr)
1363 {
1364 	/*
1365 	 * Holder function to attempt error recovery.  When the features
1366 	 * are in place, look up the address of the transaction in:
1367 	 *
1368 	 * paddr = CSR_XR(csr_base, MERGE_TRANSACTION_ERROR_LOG);
1369 	 * paddr &= MERGE_TRANSACTION_ERROR_LOG_ADDRESS_MASK;
1370 	 *
1371 	 * If the error is a secondary error, there is no log information
1372 	 * just panic as it is unknown which address has been affected.
1373 	 *
1374 	 * Remember the address is pretranslation and might be hard to look
1375 	 * up the appropriate driver based on the PA.
1376 	 */
1377 	return (px_err_panic_handle(rpdip, csr_base, derr, err_reg_descr,
1378 	    err_bit_descr));
1379 }
1380 
1381 /* JBC Jbusint IN */
1382 PX_ERPT_SEND_DEC(jbc_in)
1383 {
1384 	char		buf[FM_MAX_CLASS];
1385 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1386 
1387 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1388 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1389 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1390 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1391 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1392 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1393 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1394 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1395 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1396 	    ss_reg,
1397 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1398 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1399 	    FIRE_JBC_JITEL1, DATA_TYPE_UINT64,
1400 	    CSR_XR(csr_base, JBCINT_IN_TRANSACTION_ERROR_LOG),
1401 	    FIRE_JBC_JITEL2, DATA_TYPE_UINT64,
1402 	    CSR_XR(csr_base, JBCINT_IN_TRANSACTION_ERROR_LOG_2),
1403 	    NULL);
1404 
1405 	return (PX_NO_PANIC);
1406 }
1407 
1408 /*
1409  * JBC Jbusint IN retryable errors
1410  * Log Reg[42:0].
1411  *    Write Data Parity Error: PIO Writes
1412  *    Read Data Parity Error: DMA Reads
1413  */
1414 int
1415 px_err_jbc_jbusint_in_handle(dev_info_t *rpdip, caddr_t csr_base,
1416 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1417 	px_err_bit_desc_t *err_bit_descr)
1418 {
1419 	/*
1420 	 * Holder function to attempt error recovery.  When the features
1421 	 * are in place, look up the address of the transaction in:
1422 	 *
1423 	 * paddr = CSR_XR(csr_base, JBCINT_IN_TRANSACTION_ERROR_LOG);
1424 	 * paddr &= JBCINT_IN_TRANSACTION_ERROR_LOG_ADDRESS_MASK;
1425 	 *
1426 	 * If the error is a secondary error, there is no log information
1427 	 * just panic as it is unknown which address has been affected.
1428 	 *
1429 	 * Remember the address is pretranslation and might be hard to look
1430 	 * up the appropriate driver based on the PA.
1431 	 */
1432 	return (px_err_panic_handle(rpdip, csr_base, derr, err_reg_descr,
1433 	    err_bit_descr));
1434 }
1435 
1436 
1437 /* JBC Jbusint Out */
1438 PX_ERPT_SEND_DEC(jbc_out)
1439 {
1440 	char		buf[FM_MAX_CLASS];
1441 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1442 
1443 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1444 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1445 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1446 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1447 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1448 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1449 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1450 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1451 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1452 	    ss_reg,
1453 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1454 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1455 	    FIRE_JBC_JOTEL1, DATA_TYPE_UINT64,
1456 	    CSR_XR(csr_base, JBCINT_OUT_TRANSACTION_ERROR_LOG),
1457 	    FIRE_JBC_JOTEL2, DATA_TYPE_UINT64,
1458 	    CSR_XR(csr_base, JBCINT_OUT_TRANSACTION_ERROR_LOG_2),
1459 	    NULL);
1460 
1461 	return (PX_NO_PANIC);
1462 }
1463 
1464 /* JBC Dmcint ODCD */
1465 PX_ERPT_SEND_DEC(jbc_odcd)
1466 {
1467 	char		buf[FM_MAX_CLASS];
1468 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1469 
1470 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1471 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1472 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1473 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1474 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1475 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1476 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1477 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1478 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1479 	    ss_reg,
1480 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1481 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1482 	    FIRE_JBC_DMC_ODCD, DATA_TYPE_UINT64,
1483 	    CSR_XR(csr_base, DMCINT_ODCD_ERROR_LOG),
1484 	    NULL);
1485 
1486 	return (PX_NO_PANIC);
1487 }
1488 
1489 /*
1490  * JBC Dmcint ODCO nonfatal errer handling -
1491  *    PIO data parity error: PIO
1492  */
1493 /* ARGSUSED */
1494 int
1495 px_err_jbc_dmcint_odcd_handle(dev_info_t *rpdip, caddr_t csr_base,
1496 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1497 	px_err_bit_desc_t *err_bit_descr)
1498 {
1499 	/*
1500 	 * Holder function to attempt error recovery.  When the features
1501 	 * are in place, look up the address of the transaction in:
1502 	 *
1503 	 * paddr = CSR_XR(csr_base, DMCINT_ODCD_ERROR_LOG);
1504 	 * paddr &= DMCINT_ODCD_ERROR_LOG_ADDRESS_MASK;
1505 	 *
1506 	 * If the error is a secondary error, there is no log information
1507 	 * just panic as it is unknown which address has been affected.
1508 	 *
1509 	 * Remember the address is pretranslation and might be hard to look
1510 	 * up the appropriate driver based on the PA.
1511 	 */
1512 	return (px_err_panic_handle(rpdip, csr_base, derr, err_reg_descr,
1513 	    err_bit_descr));
1514 }
1515 
1516 /* Does address in DMCINT error log register match address of pcitool access? */
1517 static boolean_t
1518 px_jbc_pcitool_addr_match(dev_info_t *rpdip, caddr_t csr_base)
1519 {
1520 	px_t	*px_p = DIP_TO_STATE(rpdip);
1521 	pxu_t	*pxu_p = (pxu_t *)px_p->px_plat_p;
1522 	caddr_t	pcitool_addr = pxu_p->pcitool_addr;
1523 	caddr_t errlog_addr =
1524 	    (caddr_t)CSR_FR(csr_base, DMCINT_ODCD_ERROR_LOG, ADDRESS);
1525 
1526 	return (pcitool_addr == errlog_addr);
1527 }
1528 
1529 /*
1530  * JBC Dmcint ODCD errer handling for errors which are forgivable during a safe
1531  * access.  (This will be most likely be a PCItool access.)  If not a safe
1532  * access context, treat like jbc_dmcint_odcd.
1533  *    Unmapped PIO read error: pio:read:M:nonfatal
1534  *    Unmapped PIO write error: pio:write:M:nonfatal
1535  *    Invalid PIO write to PCIe cfg/io, csr, ebus or i2c bus: pio:write:nonfatal
1536  *    Invalid PIO read to PCIe cfg/io, csr, ebus or i2c bus: pio:read:nonfatal
1537  */
1538 /* ARGSUSED */
1539 int
1540 px_err_jbc_safe_acc_handle(dev_info_t *rpdip, caddr_t csr_base,
1541 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1542 	px_err_bit_desc_t *err_bit_descr)
1543 {
1544 	boolean_t	pri = PX_ERR_IS_PRI(err_bit_descr->bit);
1545 
1546 	if (!pri)
1547 		return (px_err_panic_handle(rpdip, csr_base, derr,
1548 		    err_reg_descr, err_bit_descr));
1549 	/*
1550 	 * Got an error which is forgivable during a PCItool access.
1551 	 *
1552 	 * Don't do handler check since the error may otherwise be unfairly
1553 	 * attributed to a device.  Just return.
1554 	 *
1555 	 * Note: There is a hole here in that a legitimate error can come in
1556 	 * while a PCItool access is in play and be forgiven.  This is possible
1557 	 * though not likely.
1558 	 */
1559 	if ((derr->fme_flag != DDI_FM_ERR_UNEXPECTED) &&
1560 	    (px_jbc_pcitool_addr_match(rpdip, csr_base)))
1561 		return (px_err_protected_handle(rpdip, csr_base, derr,
1562 		    err_reg_descr, err_bit_descr));
1563 
1564 	return (px_err_jbc_dmcint_odcd_handle(rpdip, csr_base, derr,
1565 	    err_reg_descr, err_bit_descr));
1566 }
1567 
1568 /* JBC Dmcint IDC */
1569 PX_ERPT_SEND_DEC(jbc_idc)
1570 {
1571 	char		buf[FM_MAX_CLASS];
1572 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1573 
1574 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1575 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1576 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1577 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1578 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1579 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1580 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1581 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1582 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1583 	    ss_reg,
1584 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1585 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1586 	    FIRE_JBC_DMC_IDC, DATA_TYPE_UINT64,
1587 	    CSR_XR(csr_base, DMCINT_IDC_ERROR_LOG),
1588 	    NULL);
1589 
1590 	return (PX_NO_PANIC);
1591 }
1592 
1593 /* JBC CSR */
1594 PX_ERPT_SEND_DEC(jbc_csr)
1595 {
1596 	char		buf[FM_MAX_CLASS];
1597 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1598 
1599 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1600 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1601 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1602 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1603 	    FIRE_JBC_ELE, DATA_TYPE_UINT64,
1604 	    CSR_XR(csr_base, JBC_ERROR_LOG_ENABLE),
1605 	    FIRE_JBC_IE, DATA_TYPE_UINT64,
1606 	    CSR_XR(csr_base, JBC_INTERRUPT_ENABLE),
1607 	    FIRE_JBC_IS, DATA_TYPE_UINT64,
1608 	    ss_reg,
1609 	    FIRE_JBC_ESS, DATA_TYPE_UINT64,
1610 	    CSR_XR(csr_base, JBC_ERROR_STATUS_SET),
1611 	    "jbc-error-reg", DATA_TYPE_UINT64,
1612 	    CSR_XR(csr_base, CSR_ERROR_LOG),
1613 	    NULL);
1614 
1615 	return (PX_NO_PANIC);
1616 }
1617 
1618 /* DMC IMU RDS */
1619 PX_ERPT_SEND_DEC(imu_rds)
1620 {
1621 	char		buf[FM_MAX_CLASS];
1622 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1623 
1624 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1625 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1626 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1627 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1628 	    FIRE_IMU_ELE, DATA_TYPE_UINT64,
1629 	    CSR_XR(csr_base, IMU_ERROR_LOG_ENABLE),
1630 	    FIRE_IMU_IE, DATA_TYPE_UINT64,
1631 	    CSR_XR(csr_base, IMU_INTERRUPT_ENABLE),
1632 	    FIRE_IMU_IS, DATA_TYPE_UINT64,
1633 	    ss_reg,
1634 	    FIRE_IMU_ESS, DATA_TYPE_UINT64,
1635 	    CSR_XR(csr_base, IMU_ERROR_STATUS_SET),
1636 	    FIRE_IMU_RDS, DATA_TYPE_UINT64,
1637 	    CSR_XR(csr_base, IMU_RDS_ERROR_LOG),
1638 	    NULL);
1639 
1640 	return (PX_NO_PANIC);
1641 }
1642 
1643 /* handle EQ overflow */
1644 /* ARGSUSED */
1645 int
1646 px_err_imu_eq_ovfl_handle(dev_info_t *rpdip, caddr_t csr_base,
1647 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1648 	px_err_bit_desc_t *err_bit_descr)
1649 {
1650 	px_t	*px_p = DIP_TO_STATE(rpdip);
1651 	pxu_t	*pxu_p = (pxu_t *)px_p->px_plat_p;
1652 	int	err = px_err_check_eq(rpdip);
1653 
1654 	if ((err == PX_PANIC) && (pxu_p->cpr_flag == PX_NOT_CPR)) {
1655 		return (px_err_panic_handle(rpdip, csr_base, derr,
1656 		    err_reg_descr, err_bit_descr));
1657 	} else {
1658 		return (px_err_no_panic_handle(rpdip, csr_base, derr,
1659 		    err_reg_descr, err_bit_descr));
1660 	}
1661 }
1662 
1663 /* DMC IMU SCS */
1664 PX_ERPT_SEND_DEC(imu_scs)
1665 {
1666 	char		buf[FM_MAX_CLASS];
1667 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1668 
1669 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1670 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1671 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1672 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1673 	    FIRE_IMU_ELE, DATA_TYPE_UINT64,
1674 	    CSR_XR(csr_base, IMU_ERROR_LOG_ENABLE),
1675 	    FIRE_IMU_IE, DATA_TYPE_UINT64,
1676 	    CSR_XR(csr_base, IMU_INTERRUPT_ENABLE),
1677 	    FIRE_IMU_IS, DATA_TYPE_UINT64,
1678 	    ss_reg,
1679 	    FIRE_IMU_ESS, DATA_TYPE_UINT64,
1680 	    CSR_XR(csr_base, IMU_ERROR_STATUS_SET),
1681 	    FIRE_IMU_SCS, DATA_TYPE_UINT64,
1682 	    CSR_XR(csr_base, IMU_SCS_ERROR_LOG),
1683 	    NULL);
1684 
1685 	return (PX_NO_PANIC);
1686 }
1687 
1688 /* DMC IMU */
1689 PX_ERPT_SEND_DEC(imu)
1690 {
1691 	char		buf[FM_MAX_CLASS];
1692 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1693 
1694 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1695 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1696 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1697 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1698 	    FIRE_IMU_ELE, DATA_TYPE_UINT64,
1699 	    CSR_XR(csr_base, IMU_ERROR_LOG_ENABLE),
1700 	    FIRE_IMU_IE, DATA_TYPE_UINT64,
1701 	    CSR_XR(csr_base, IMU_INTERRUPT_ENABLE),
1702 	    FIRE_IMU_IS, DATA_TYPE_UINT64,
1703 	    ss_reg,
1704 	    FIRE_IMU_ESS, DATA_TYPE_UINT64,
1705 	    CSR_XR(csr_base, IMU_ERROR_STATUS_SET),
1706 	    NULL);
1707 
1708 	return (PX_NO_PANIC);
1709 }
1710 
1711 /* DMC MMU TFAR/TFSR */
1712 PX_ERPT_SEND_DEC(mmu_tfar_tfsr)
1713 {
1714 	char		buf[FM_MAX_CLASS];
1715 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1716 	px_t		*px_p = DIP_TO_STATE(rpdip);
1717 	pcie_req_id_t	fault_bdf = 0;
1718 	uint16_t	s_status = 0;
1719 
1720 	if (pri) {
1721 		fault_bdf = CSR_XR(csr_base, MMU_TRANSLATION_FAULT_STATUS)
1722 		    & (MMU_TRANSLATION_FAULT_STATUS_ID_MASK <<
1723 		    MMU_TRANSLATION_FAULT_STATUS_ID);
1724 		s_status = PCI_STAT_S_TARG_AB;
1725 
1726 		/* Only PIO Fault Addresses are valid, this is DMA */
1727 		(void) px_rp_en_q(px_p, fault_bdf, NULL, s_status);
1728 	}
1729 
1730 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1731 
1732 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1733 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1734 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1735 	    FIRE_MMU_ELE, DATA_TYPE_UINT64,
1736 	    CSR_XR(csr_base, MMU_ERROR_LOG_ENABLE),
1737 	    FIRE_MMU_IE, DATA_TYPE_UINT64,
1738 	    CSR_XR(csr_base, MMU_INTERRUPT_ENABLE),
1739 	    FIRE_MMU_IS, DATA_TYPE_UINT64,
1740 	    ss_reg,
1741 	    FIRE_MMU_ESS, DATA_TYPE_UINT64,
1742 	    CSR_XR(csr_base, MMU_ERROR_STATUS_SET),
1743 	    FIRE_MMU_TFAR, DATA_TYPE_UINT64,
1744 	    CSR_XR(csr_base, MMU_TRANSLATION_FAULT_ADDRESS),
1745 	    FIRE_MMU_TFSR, DATA_TYPE_UINT64,
1746 	    CSR_XR(csr_base, MMU_TRANSLATION_FAULT_STATUS),
1747 	    NULL);
1748 
1749 	return (PX_NO_PANIC);
1750 }
1751 
1752 /* DMC MMU */
1753 PX_ERPT_SEND_DEC(mmu)
1754 {
1755 	char		buf[FM_MAX_CLASS];
1756 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1757 
1758 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1759 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1760 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1761 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1762 	    FIRE_MMU_ELE, DATA_TYPE_UINT64,
1763 	    CSR_XR(csr_base, MMU_ERROR_LOG_ENABLE),
1764 	    FIRE_MMU_IE, DATA_TYPE_UINT64,
1765 	    CSR_XR(csr_base, MMU_INTERRUPT_ENABLE),
1766 	    FIRE_MMU_IS, DATA_TYPE_UINT64,
1767 	    ss_reg,
1768 	    FIRE_MMU_ESS, DATA_TYPE_UINT64,
1769 	    CSR_XR(csr_base, MMU_ERROR_STATUS_SET),
1770 	    NULL);
1771 
1772 	return (PX_NO_PANIC);
1773 }
1774 
1775 /*
1776  * IMU function to handle all Received but Not Enabled errors.
1777  *
1778  * These errors are due to transactions modes in which the PX driver was not
1779  * setup to be able to do.  If possible, inform the driver that their DMA has
1780  * failed by marking their DMA handle as failed, but do not panic the system.
1781  * Most likely the address is not valid, as Fire wasn't setup to handle them in
1782  * the first place.
1783  *
1784  * These errors are not retryable, unless the PX mode has changed, otherwise the
1785  * same error will occur again.
1786  */
1787 int
1788 px_err_mmu_rbne_handle(dev_info_t *rpdip, caddr_t csr_base,
1789 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1790 	px_err_bit_desc_t *err_bit_descr)
1791 {
1792 	pcie_req_id_t bdf;
1793 
1794 	if (!PX_ERR_IS_PRI(err_bit_descr->bit))
1795 		goto done;
1796 
1797 	bdf = (pcie_req_id_t)CSR_FR(csr_base, MMU_TRANSLATION_FAULT_STATUS, ID);
1798 	(void) pf_hdl_lookup(rpdip, derr->fme_ena, PF_ADDR_DMA, NULL,
1799 	    bdf);
1800 
1801 done:
1802 	return (px_err_no_panic_handle(rpdip, csr_base, derr, err_reg_descr,
1803 	    err_bit_descr));
1804 }
1805 
1806 /*
1807  * IMU function to handle all invalid address errors.
1808  *
1809  * These errors are due to transactions in which the address is not recognized.
1810  * If possible, inform the driver that all DMAs have failed by marking their DMA
1811  * handles.  Fire should not panic the system, it'll be up to the driver to
1812  * panic.  The address logged is invalid.
1813  *
1814  * These errors are not retryable since retrying the same transaction with the
1815  * same invalid address will result in the same error.
1816  */
1817 /* ARGSUSED */
1818 int
1819 px_err_mmu_tfa_handle(dev_info_t *rpdip, caddr_t csr_base,
1820 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1821 	px_err_bit_desc_t *err_bit_descr)
1822 {
1823 	pcie_req_id_t bdf;
1824 
1825 	if (!PX_ERR_IS_PRI(err_bit_descr->bit))
1826 		goto done;
1827 
1828 	bdf = (pcie_req_id_t)CSR_FR(csr_base, MMU_TRANSLATION_FAULT_STATUS, ID);
1829 	(void) pf_hdl_lookup(rpdip, derr->fme_ena, PF_ADDR_DMA, NULL,
1830 	    bdf);
1831 
1832 done:
1833 	return (px_err_no_panic_handle(rpdip, csr_base, derr, err_reg_descr,
1834 	    err_bit_descr));
1835 }
1836 
1837 /*
1838  * IMU function to handle normal transactions that encounter a parity error.
1839  *
1840  * These errors are due to transactions that enouter a parity error. If
1841  * possible, inform the driver that their DMA have failed and that they should
1842  * retry.  If Fire is unable to contact the leaf driver, panic the system.
1843  * Otherwise, it'll be up to the device to determine is this is a panicable
1844  * error.
1845  */
1846 /* ARGSUSED */
1847 int
1848 px_err_mmu_parity_handle(dev_info_t *rpdip, caddr_t csr_base,
1849 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1850 	px_err_bit_desc_t *err_bit_descr)
1851 {
1852 	uint64_t mmu_tfa;
1853 	pcie_req_id_t bdf;
1854 	int status = PF_HDL_NOTFOUND;
1855 
1856 	if (!PX_ERR_IS_PRI(err_bit_descr->bit))
1857 		goto done;
1858 
1859 	mmu_tfa = CSR_XR(csr_base, MMU_TRANSLATION_FAULT_ADDRESS);
1860 	bdf = (pcie_req_id_t)CSR_FR(csr_base, MMU_TRANSLATION_FAULT_STATUS, ID);
1861 	status = pf_hdl_lookup(rpdip, derr->fme_ena, PF_ADDR_DMA,
1862 	    (uint32_t)mmu_tfa, bdf);
1863 
1864 done:
1865 	if (status == PF_HDL_NOTFOUND)
1866 		return (px_err_panic_handle(rpdip, csr_base, derr,
1867 		    err_reg_descr, err_bit_descr));
1868 	else
1869 		return (px_err_no_panic_handle(rpdip, csr_base, derr,
1870 		    err_reg_descr, err_bit_descr));
1871 }
1872 
1873 /*
1874  * wuc/ruc event - Mark the handle of the failed PIO access.  Return "no_panic"
1875  */
1876 /* ARGSUSED */
1877 int
1878 px_err_wuc_ruc_handle(dev_info_t *rpdip, caddr_t csr_base,
1879 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1880 	px_err_bit_desc_t *err_bit_descr)
1881 {
1882 	px_t		*px_p = DIP_TO_STATE(rpdip);
1883 	pxu_t		*pxu_p = (pxu_t *)px_p->px_plat_p;
1884 	uint64_t 	data;
1885 	pf_pcie_adv_err_regs_t adv_reg;
1886 	int		sts;
1887 
1888 	if (!PX_ERR_IS_PRI(err_bit_descr->bit))
1889 		goto done;
1890 
1891 	data = CSR_XR(csr_base, TLU_TRANSMIT_OTHER_EVENT_HEADER1_LOG);
1892 	adv_reg.pcie_ue_hdr[0] = (uint32_t)(data >> 32);
1893 	adv_reg.pcie_ue_hdr[1] = (uint32_t)(data & 0xFFFFFFFF);
1894 	data = CSR_XR(csr_base, TLU_TRANSMIT_OTHER_EVENT_HEADER2_LOG);
1895 	adv_reg.pcie_ue_hdr[2] = (uint32_t)(data >> 32);
1896 	adv_reg.pcie_ue_hdr[3] = (uint32_t)(data & 0xFFFFFFFF);
1897 
1898 	pf_tlp_decode(PCIE_DIP2BUS(rpdip), &adv_reg);
1899 	sts = pf_hdl_lookup(rpdip, derr->fme_ena, adv_reg.pcie_ue_tgt_trans,
1900 	    adv_reg.pcie_ue_tgt_addr, adv_reg.pcie_ue_tgt_bdf);
1901 done:
1902 	if ((sts == PF_HDL_NOTFOUND) && (pxu_p->cpr_flag == PX_NOT_CPR))
1903 		return (px_err_protected_handle(rpdip, csr_base, derr,
1904 		    err_reg_descr, err_bit_descr));
1905 
1906 	return (px_err_no_panic_handle(rpdip, csr_base, derr,
1907 	    err_reg_descr, err_bit_descr));
1908 }
1909 
1910 /*
1911  * TLU LUP event - if caused by power management activity, then it is expected.
1912  * In all other cases, it is an error.
1913  */
1914 /* ARGSUSED */
1915 int
1916 px_err_tlu_lup_handle(dev_info_t *rpdip, caddr_t csr_base,
1917 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1918 	px_err_bit_desc_t *err_bit_descr)
1919 {
1920 	px_t	*px_p = DIP_TO_STATE(rpdip);
1921 
1922 	/*
1923 	 * power management code is currently the only segment that sets
1924 	 * px_lup_pending to indicate its expectation for a healthy LUP
1925 	 * event.  For all other occasions, LUP event should be flaged as
1926 	 * error condition.
1927 	 */
1928 	return ((atomic_cas_32(&px_p->px_lup_pending, 1, 0) == 0) ?
1929 	    PX_NO_PANIC : PX_EXPECTED);
1930 }
1931 
1932 /*
1933  * TLU LDN event - if caused by power management activity, then it is expected.
1934  * In all other cases, it is an error.
1935  */
1936 /* ARGSUSED */
1937 int
1938 px_err_tlu_ldn_handle(dev_info_t *rpdip, caddr_t csr_base,
1939 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1940 	px_err_bit_desc_t *err_bit_descr)
1941 {
1942 	px_t    *px_p = DIP_TO_STATE(rpdip);
1943 	return ((px_p->px_pm_flags & PX_LDN_EXPECTED) ? PX_EXPECTED :
1944 	    PX_NO_PANIC);
1945 }
1946 
1947 /* PEC ILU none - see io erpt doc, section 3.1 */
1948 PX_ERPT_SEND_DEC(pec_ilu)
1949 {
1950 	char		buf[FM_MAX_CLASS];
1951 	boolean_t	pri = PX_ERR_IS_PRI(bit);
1952 
1953 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
1954 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
1955 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
1956 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
1957 	    FIRE_ILU_ELE, DATA_TYPE_UINT64,
1958 	    CSR_XR(csr_base, ILU_ERROR_LOG_ENABLE),
1959 	    FIRE_ILU_IE, DATA_TYPE_UINT64,
1960 	    CSR_XR(csr_base, ILU_INTERRUPT_ENABLE),
1961 	    FIRE_ILU_IS, DATA_TYPE_UINT64,
1962 	    ss_reg,
1963 	    FIRE_ILU_ESS, DATA_TYPE_UINT64,
1964 	    CSR_XR(csr_base, ILU_ERROR_STATUS_SET),
1965 	    NULL);
1966 
1967 	return (PX_NO_PANIC);
1968 }
1969 
1970 /* PCIEX UE Errors */
1971 /* ARGSUSED */
1972 int
1973 px_err_pciex_ue_handle(dev_info_t *rpdip, caddr_t csr_base,
1974 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
1975 	px_err_bit_desc_t *err_bit_descr)
1976 {
1977 	px_err_pcie_t	regs = {0};
1978 	uint32_t	err_bit;
1979 	int		err;
1980 	uint64_t	log;
1981 
1982 	if (err_bit_descr->bit < 32) {
1983 		err_bit = (uint32_t)BITMASK(err_bit_descr->bit);
1984 		regs.ue_reg = err_bit;
1985 		regs.primary_ue = err_bit;
1986 
1987 		/*
1988 		 * Log the Received Log for PTLP, UR and UC.
1989 		 */
1990 		if ((PCIE_AER_UCE_PTLP | PCIE_AER_UCE_UR | PCIE_AER_UCE_UC) &
1991 		    err_bit) {
1992 			log = CSR_XR(csr_base,
1993 			    TLU_RECEIVE_UNCORRECTABLE_ERROR_HEADER1_LOG);
1994 			regs.rx_hdr1 = (uint32_t)(log >> 32);
1995 			regs.rx_hdr2 = (uint32_t)(log & 0xFFFFFFFF);
1996 
1997 			log = CSR_XR(csr_base,
1998 			    TLU_RECEIVE_UNCORRECTABLE_ERROR_HEADER2_LOG);
1999 			regs.rx_hdr3 = (uint32_t)(log >> 32);
2000 			regs.rx_hdr4 = (uint32_t)(log & 0xFFFFFFFF);
2001 		}
2002 	} else {
2003 		regs.ue_reg = (uint32_t)BITMASK(err_bit_descr->bit - 32);
2004 	}
2005 
2006 	err = px_err_check_pcie(rpdip, derr, &regs);
2007 
2008 	if (err & PX_PANIC) {
2009 		return (px_err_panic_handle(rpdip, csr_base, derr,
2010 		    err_reg_descr, err_bit_descr));
2011 	} else {
2012 		return (px_err_no_panic_handle(rpdip, csr_base, derr,
2013 		    err_reg_descr, err_bit_descr));
2014 	}
2015 }
2016 
2017 /* PCI-E Uncorrectable Errors */
2018 PX_ERPT_SEND_DEC(pciex_rx_ue)
2019 {
2020 	char		buf[FM_MAX_CLASS];
2021 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2022 
2023 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2024 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2025 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2026 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2027 	    FIRE_TLU_UELE, DATA_TYPE_UINT64,
2028 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_LOG_ENABLE),
2029 	    FIRE_TLU_UIE, DATA_TYPE_UINT64,
2030 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_INTERRUPT_ENABLE),
2031 	    FIRE_TLU_UIS, DATA_TYPE_UINT64,
2032 	    ss_reg,
2033 	    FIRE_TLU_UESS, DATA_TYPE_UINT64,
2034 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_STATUS_SET),
2035 	    FIRE_TLU_RUEH1L, DATA_TYPE_UINT64,
2036 	    CSR_XR(csr_base, TLU_RECEIVE_UNCORRECTABLE_ERROR_HEADER1_LOG),
2037 	    FIRE_TLU_RUEH2L, DATA_TYPE_UINT64,
2038 	    CSR_XR(csr_base, TLU_RECEIVE_UNCORRECTABLE_ERROR_HEADER2_LOG),
2039 	    NULL);
2040 
2041 	return (PX_NO_PANIC);
2042 }
2043 
2044 /* PCI-E Uncorrectable Errors */
2045 PX_ERPT_SEND_DEC(pciex_tx_ue)
2046 {
2047 	char		buf[FM_MAX_CLASS];
2048 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2049 
2050 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2051 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2052 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2053 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2054 	    FIRE_TLU_UELE, DATA_TYPE_UINT64,
2055 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_LOG_ENABLE),
2056 	    FIRE_TLU_UIE, DATA_TYPE_UINT64,
2057 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_INTERRUPT_ENABLE),
2058 	    FIRE_TLU_UIS, DATA_TYPE_UINT64,
2059 	    ss_reg,
2060 	    FIRE_TLU_UESS, DATA_TYPE_UINT64,
2061 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_STATUS_SET),
2062 	    FIRE_TLU_TUEH1L, DATA_TYPE_UINT64,
2063 	    CSR_XR(csr_base, TLU_TRANSMIT_UNCORRECTABLE_ERROR_HEADER1_LOG),
2064 	    FIRE_TLU_TUEH2L, DATA_TYPE_UINT64,
2065 	    CSR_XR(csr_base, TLU_TRANSMIT_UNCORRECTABLE_ERROR_HEADER2_LOG),
2066 	    NULL);
2067 
2068 	return (PX_NO_PANIC);
2069 }
2070 
2071 /* PCI-E Uncorrectable Errors */
2072 PX_ERPT_SEND_DEC(pciex_rx_tx_ue)
2073 {
2074 	char		buf[FM_MAX_CLASS];
2075 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2076 
2077 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2078 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2079 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2080 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2081 	    FIRE_TLU_UELE, DATA_TYPE_UINT64,
2082 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_LOG_ENABLE),
2083 	    FIRE_TLU_UIE, DATA_TYPE_UINT64,
2084 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_INTERRUPT_ENABLE),
2085 	    FIRE_TLU_UIS, DATA_TYPE_UINT64,
2086 	    ss_reg,
2087 	    FIRE_TLU_UESS, DATA_TYPE_UINT64,
2088 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_STATUS_SET),
2089 	    FIRE_TLU_RUEH1L, DATA_TYPE_UINT64,
2090 	    CSR_XR(csr_base, TLU_RECEIVE_UNCORRECTABLE_ERROR_HEADER1_LOG),
2091 	    FIRE_TLU_RUEH2L, DATA_TYPE_UINT64,
2092 	    CSR_XR(csr_base, TLU_RECEIVE_UNCORRECTABLE_ERROR_HEADER2_LOG),
2093 	    FIRE_TLU_TUEH1L, DATA_TYPE_UINT64,
2094 	    CSR_XR(csr_base, TLU_TRANSMIT_UNCORRECTABLE_ERROR_HEADER1_LOG),
2095 	    FIRE_TLU_TUEH2L, DATA_TYPE_UINT64,
2096 	    CSR_XR(csr_base, TLU_TRANSMIT_UNCORRECTABLE_ERROR_HEADER2_LOG),
2097 	    NULL);
2098 
2099 	return (PX_NO_PANIC);
2100 }
2101 
2102 /* PCI-E Uncorrectable Errors */
2103 PX_ERPT_SEND_DEC(pciex_ue)
2104 {
2105 	char		buf[FM_MAX_CLASS];
2106 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2107 
2108 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2109 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2110 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2111 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2112 	    FIRE_TLU_UELE, DATA_TYPE_UINT64,
2113 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_LOG_ENABLE),
2114 	    FIRE_TLU_UIE, DATA_TYPE_UINT64,
2115 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_INTERRUPT_ENABLE),
2116 	    FIRE_TLU_UIS, DATA_TYPE_UINT64,
2117 	    ss_reg,
2118 	    FIRE_TLU_UESS, DATA_TYPE_UINT64,
2119 	    CSR_XR(csr_base, TLU_UNCORRECTABLE_ERROR_STATUS_SET),
2120 	    NULL);
2121 
2122 	return (PX_NO_PANIC);
2123 }
2124 
2125 /* PCIEX UE Errors */
2126 /* ARGSUSED */
2127 int
2128 px_err_pciex_ce_handle(dev_info_t *rpdip, caddr_t csr_base,
2129 	ddi_fm_error_t *derr, px_err_reg_desc_t *err_reg_descr,
2130 	px_err_bit_desc_t *err_bit_descr)
2131 {
2132 	px_err_pcie_t	regs = {0};
2133 	int		err;
2134 
2135 	if (err_bit_descr->bit < 32)
2136 		regs.ce_reg = (uint32_t)BITMASK(err_bit_descr->bit);
2137 	else
2138 		regs.ce_reg = (uint32_t)BITMASK(err_bit_descr->bit - 32);
2139 
2140 	err = px_err_check_pcie(rpdip, derr, &regs);
2141 
2142 	if (err & PX_PANIC) {
2143 		return (px_err_panic_handle(rpdip, csr_base, derr,
2144 		    err_reg_descr, err_bit_descr));
2145 	} else {
2146 		return (px_err_no_panic_handle(rpdip, csr_base, derr,
2147 		    err_reg_descr, err_bit_descr));
2148 	}
2149 }
2150 
2151 /* PCI-E Correctable Errors - see io erpt doc, section 3.6 */
2152 PX_ERPT_SEND_DEC(pciex_ce)
2153 {
2154 	char		buf[FM_MAX_CLASS];
2155 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2156 
2157 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2158 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2159 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2160 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2161 	    FIRE_TLU_CELE, DATA_TYPE_UINT64,
2162 	    CSR_XR(csr_base, TLU_CORRECTABLE_ERROR_LOG_ENABLE),
2163 	    FIRE_TLU_CIE, DATA_TYPE_UINT64,
2164 	    CSR_XR(csr_base, TLU_CORRECTABLE_ERROR_INTERRUPT_ENABLE),
2165 	    FIRE_TLU_CIS, DATA_TYPE_UINT64,
2166 	    ss_reg,
2167 	    FIRE_TLU_CESS, DATA_TYPE_UINT64,
2168 	    CSR_XR(csr_base, TLU_CORRECTABLE_ERROR_STATUS_SET),
2169 	    NULL);
2170 
2171 	return (PX_NO_PANIC);
2172 }
2173 
2174 /* TLU Other Event Status (receive only) - see io erpt doc, section 3.7 */
2175 PX_ERPT_SEND_DEC(pciex_rx_oe)
2176 {
2177 	char		buf[FM_MAX_CLASS];
2178 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2179 
2180 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2181 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2182 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2183 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2184 	    FIRE_TLU_OEELE, DATA_TYPE_UINT64,
2185 	    CSR_XR(csr_base, TLU_OTHER_EVENT_LOG_ENABLE),
2186 	    FIRE_TLU_OEIE, DATA_TYPE_UINT64,
2187 	    CSR_XR(csr_base, TLU_OTHER_EVENT_INTERRUPT_ENABLE),
2188 	    FIRE_TLU_OEIS, DATA_TYPE_UINT64,
2189 	    ss_reg,
2190 	    FIRE_TLU_OEESS, DATA_TYPE_UINT64,
2191 	    CSR_XR(csr_base, TLU_OTHER_EVENT_STATUS_SET),
2192 	    FIRE_TLU_RUEH1L, DATA_TYPE_UINT64,
2193 	    CSR_XR(csr_base, TLU_RECEIVE_OTHER_EVENT_HEADER1_LOG),
2194 	    FIRE_TLU_RUEH2L, DATA_TYPE_UINT64,
2195 	    CSR_XR(csr_base, TLU_RECEIVE_OTHER_EVENT_HEADER2_LOG),
2196 	    NULL);
2197 
2198 	return (PX_NO_PANIC);
2199 }
2200 
2201 /* TLU Other Event Status (rx + tx) - see io erpt doc, section 3.8 */
2202 PX_ERPT_SEND_DEC(pciex_rx_tx_oe)
2203 {
2204 	char		buf[FM_MAX_CLASS];
2205 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2206 	px_t		*px_p = DIP_TO_STATE(rpdip);
2207 	uint64_t	rx_h1, rx_h2, tx_h1, tx_h2;
2208 	uint16_t	s_status;
2209 	int		sts;
2210 	pcie_cpl_t	*cpl;
2211 	pf_pcie_adv_err_regs_t adv_reg;
2212 
2213 	rx_h1 = CSR_XR(csr_base, TLU_RECEIVE_OTHER_EVENT_HEADER1_LOG);
2214 	rx_h2 = CSR_XR(csr_base, TLU_RECEIVE_OTHER_EVENT_HEADER2_LOG);
2215 	tx_h1 = CSR_XR(csr_base, TLU_TRANSMIT_OTHER_EVENT_HEADER1_LOG);
2216 	tx_h2 = CSR_XR(csr_base, TLU_TRANSMIT_OTHER_EVENT_HEADER2_LOG);
2217 
2218 	if ((bit == TLU_OTHER_EVENT_STATUS_SET_RUC_P) ||
2219 	    (bit == TLU_OTHER_EVENT_STATUS_SET_WUC_P)) {
2220 		adv_reg.pcie_ue_hdr[0] = (uint32_t)(rx_h1 >> 32);
2221 		adv_reg.pcie_ue_hdr[1] = (uint32_t)rx_h1;
2222 		adv_reg.pcie_ue_hdr[2] = (uint32_t)(rx_h2 >> 32);
2223 		adv_reg.pcie_ue_hdr[3] = (uint32_t)rx_h2;
2224 
2225 		/* get completer bdf (fault bdf) from rx logs */
2226 		cpl = (pcie_cpl_t *)&adv_reg.pcie_ue_hdr[1];
2227 
2228 		/* Figure out if UR/CA from rx logs */
2229 		if (cpl->status == PCIE_CPL_STS_UR)
2230 			s_status = PCI_STAT_R_MAST_AB;
2231 		else if (cpl->status == PCIE_CPL_STS_CA)
2232 			s_status = PCI_STAT_R_TARG_AB;
2233 
2234 		adv_reg.pcie_ue_hdr[0] = (uint32_t)(tx_h1 >> 32);
2235 		adv_reg.pcie_ue_hdr[1] = (uint32_t)tx_h1;
2236 		adv_reg.pcie_ue_hdr[2] = (uint32_t)(tx_h2 >> 32);
2237 		adv_reg.pcie_ue_hdr[3] = (uint32_t)tx_h2;
2238 
2239 		/* get fault addr from tx logs */
2240 		sts = pf_tlp_decode(PCIE_DIP2BUS(rpdip), &adv_reg);
2241 
2242 		if (sts == DDI_SUCCESS)
2243 			(void) px_rp_en_q(px_p, adv_reg.pcie_ue_tgt_bdf,
2244 			    adv_reg.pcie_ue_tgt_addr, s_status);
2245 	}
2246 
2247 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2248 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2249 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2250 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2251 	    FIRE_TLU_OEELE, DATA_TYPE_UINT64,
2252 	    CSR_XR(csr_base, TLU_OTHER_EVENT_LOG_ENABLE),
2253 	    FIRE_TLU_OEIE, DATA_TYPE_UINT64,
2254 	    CSR_XR(csr_base, TLU_OTHER_EVENT_INTERRUPT_ENABLE),
2255 	    FIRE_TLU_OEIS, DATA_TYPE_UINT64,
2256 	    ss_reg,
2257 	    FIRE_TLU_OEESS, DATA_TYPE_UINT64,
2258 	    CSR_XR(csr_base, TLU_OTHER_EVENT_STATUS_SET),
2259 	    FIRE_TLU_ROEEH1L, DATA_TYPE_UINT64, rx_h1,
2260 	    FIRE_TLU_ROEEH2L, DATA_TYPE_UINT64, rx_h2,
2261 	    FIRE_TLU_TOEEH1L, DATA_TYPE_UINT64, tx_h1,
2262 	    FIRE_TLU_TOEEH2L, DATA_TYPE_UINT64, tx_h2,
2263 	    NULL);
2264 
2265 	return (PX_NO_PANIC);
2266 }
2267 
2268 /* TLU Other Event - see io erpt doc, section 3.9 */
2269 PX_ERPT_SEND_DEC(pciex_oe)
2270 {
2271 	char		buf[FM_MAX_CLASS];
2272 	boolean_t	pri = PX_ERR_IS_PRI(bit);
2273 
2274 	(void) snprintf(buf, FM_MAX_CLASS, "%s", class_name);
2275 	ddi_fm_ereport_post(rpdip, buf, derr->fme_ena,
2276 	    DDI_NOSLEEP, FM_VERSION, DATA_TYPE_UINT8, 0,
2277 	    FIRE_PRIMARY, DATA_TYPE_BOOLEAN_VALUE, pri,
2278 	    FIRE_TLU_OEELE, DATA_TYPE_UINT64,
2279 	    CSR_XR(csr_base, TLU_OTHER_EVENT_LOG_ENABLE),
2280 	    FIRE_TLU_OEIE, DATA_TYPE_UINT64,
2281 	    CSR_XR(csr_base, TLU_OTHER_EVENT_INTERRUPT_ENABLE),
2282 	    FIRE_TLU_OEIS, DATA_TYPE_UINT64,
2283 	    ss_reg,
2284 	    FIRE_TLU_OEESS, DATA_TYPE_UINT64,
2285 	    CSR_XR(csr_base, TLU_OTHER_EVENT_STATUS_SET),
2286 	    NULL);
2287 
2288 	return (PX_NO_PANIC);
2289 }
2290