xref: /illumos-gate/usr/src/uts/common/io/hxge/hxge_peu_hw.h (revision 012e6ce759c490003aed29439cc47d3d73a99ad3)
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 #ifndef	_HXGE_PEU_HW_H
27 #define	_HXGE_PEU_HW_H
28 
29 #ifdef	__cplusplus
30 extern "C" {
31 #endif
32 
33 #define	PIO_LDSV_BASE_ADDR			0X800000
34 #define	PIO_BASE_ADDR				0X000000
35 #define	PIO_LDMASK_BASE_ADDR			0XA00000
36 
37 #define	DEVICE_VENDOR_ID			(PIO_BASE_ADDR + 0x0)
38 #define	STATUS_COMMAND				(PIO_BASE_ADDR + 0x4)
39 #define	CLASSCODE_REV_ID			(PIO_BASE_ADDR + 0x8)
40 #define	BIST_HDRTYP_LATTMR_CASHLSZ		(PIO_BASE_ADDR + 0xC)
41 #define	PIO_BAR0				(PIO_BASE_ADDR + 0x10)
42 #define	PIO_BAR1				(PIO_BASE_ADDR + 0x14)
43 #define	MSIX_BAR0				(PIO_BASE_ADDR + 0x18)
44 #define	MSIX_BAR1				(PIO_BASE_ADDR + 0x1C)
45 #define	VIRT_BAR0				(PIO_BASE_ADDR + 0x20)
46 #define	VIRT_BAR1				(PIO_BASE_ADDR + 0x24)
47 #define	CIS_PTR					(PIO_BASE_ADDR + 0x28)
48 #define	SUB_VENDOR_ID				(PIO_BASE_ADDR + 0x2C)
49 #define	EXP_ROM_BAR				(PIO_BASE_ADDR + 0x30)
50 #define	CAP_PTR					(PIO_BASE_ADDR + 0x34)
51 #define	INT_LINE				(PIO_BASE_ADDR + 0x3C)
52 #define	PM_CAP					(PIO_BASE_ADDR + 0x40)
53 #define	PM_CTRL_STAT				(PIO_BASE_ADDR + 0x44)
54 #define	MSI_CAP					(PIO_BASE_ADDR + 0x50)
55 #define	MSI_LO_ADDR				(PIO_BASE_ADDR + 0x54)
56 #define	MSI_HI_ADDR				(PIO_BASE_ADDR + 0x58)
57 #define	MSI_DATA				(PIO_BASE_ADDR + 0x5C)
58 #define	MSI_MASK				(PIO_BASE_ADDR + 0x60)
59 #define	MSI_PEND				(PIO_BASE_ADDR + 0x64)
60 #define	MSIX_CAP				(PIO_BASE_ADDR + 0x70)
61 #define	MSIX_TAB_OFF				(PIO_BASE_ADDR + 0x74)
62 #define	MSIX_PBA_OFF				(PIO_BASE_ADDR + 0x78)
63 #define	PCIE_CAP				(PIO_BASE_ADDR + 0x80)
64 #define	DEV_CAP					(PIO_BASE_ADDR + 0x84)
65 #define	DEV_STAT_CTRL				(PIO_BASE_ADDR + 0x88)
66 #define	LNK_CAP					(PIO_BASE_ADDR + 0x8C)
67 #define	LNK_STAT_CTRL				(PIO_BASE_ADDR + 0x90)
68 #define	VEN_CAP_HDR				(PIO_BASE_ADDR + 0x94)
69 #define	VEN_CTRL				(PIO_BASE_ADDR + 0x98)
70 #define	VEN_PRT_HDR				(PIO_BASE_ADDR + 0x9C)
71 #define	ACKLAT_REPLAY				(PIO_BASE_ADDR + 0xA0)
72 #define	OTH_MSG					(PIO_BASE_ADDR + 0xA4)
73 #define	FORCE_LINK				(PIO_BASE_ADDR + 0xA8)
74 #define	ACK_FREQ				(PIO_BASE_ADDR + 0xAC)
75 #define	LINK_CTRL				(PIO_BASE_ADDR + 0xB0)
76 #define	LANE_SKEW				(PIO_BASE_ADDR + 0xB4)
77 #define	SYMBOL_NUM				(PIO_BASE_ADDR + 0xB8)
78 #define	SYMB_TIM_RADM_FLT1			(PIO_BASE_ADDR + 0xBC)
79 #define	RADM_FLT2				(PIO_BASE_ADDR + 0xC0)
80 #define	CASCADE_DEB_REG0			(PIO_BASE_ADDR + 0xC8)
81 #define	CASCADE_DEB_REG1			(PIO_BASE_ADDR + 0xCC)
82 #define	TXP_FC_CREDIT_STAT			(PIO_BASE_ADDR + 0xD0)
83 #define	TXNP_FC_CREDIT_STAT			(PIO_BASE_ADDR + 0xD4)
84 #define	TXCPL_FC_CREDIT_STAT			(PIO_BASE_ADDR + 0xD8)
85 #define	QUEUE_STAT				(PIO_BASE_ADDR + 0xDC)
86 #define	GBT_DEBUG0				(PIO_BASE_ADDR + 0xE0)
87 #define	GBT_DEBUG1				(PIO_BASE_ADDR + 0xE4)
88 #define	GBT_DEBUG2				(PIO_BASE_ADDR + 0xE8)
89 #define	GBT_DEBUG3				(PIO_BASE_ADDR + 0xEC)
90 #define	PIPE_DEBUG0				(PIO_BASE_ADDR + 0xF0)
91 #define	PIPE_DEBUG1				(PIO_BASE_ADDR + 0xF4)
92 #define	PIPE_DEBUG2				(PIO_BASE_ADDR + 0xF8)
93 #define	PIPE_DEBUG3				(PIO_BASE_ADDR + 0xFC)
94 #define	PCIE_ENH_CAP_HDR			(PIO_BASE_ADDR + 0x100)
95 #define	UNC_ERR_STAT				(PIO_BASE_ADDR + 0x104)
96 #define	UNC_ERR_MASK				(PIO_BASE_ADDR + 0x108)
97 #define	UNC_ERR_SVRTY				(PIO_BASE_ADDR + 0x10C)
98 #define	CORR_ERR_STAT				(PIO_BASE_ADDR + 0x110)
99 #define	CORR_ERR_MASK				(PIO_BASE_ADDR + 0x114)
100 #define	ADV_CAP_CTRL				(PIO_BASE_ADDR + 0x118)
101 #define	HDR_LOG0				(PIO_BASE_ADDR + 0x11C)
102 #define	HDR_LOG1				(PIO_BASE_ADDR + 0x120)
103 #define	HDR_LOG2				(PIO_BASE_ADDR + 0x124)
104 #define	HDR_LOG3				(PIO_BASE_ADDR + 0x128)
105 #define	PIPE_RX_TX_CONTROL			(PIO_BASE_ADDR + 0x1000)
106 #define	PIPE_RX_TX_STATUS			(PIO_BASE_ADDR + 0x1004)
107 #define	PIPE_RX_TX_PWR_CNTL			(PIO_BASE_ADDR + 0x1008)
108 #define	PIPE_RX_TX_PARAM			(PIO_BASE_ADDR + 0x1010)
109 #define	PIPE_RX_TX_CLOCK			(PIO_BASE_ADDR + 0x1014)
110 #define	PIPE_GLUE_CNTL0				(PIO_BASE_ADDR + 0x1018)
111 #define	PIPE_GLUE_CNTL1				(PIO_BASE_ADDR + 0x101C)
112 #define	HCR_REG					(PIO_BASE_ADDR + 0x2000)
113 #define	BLOCK_RESET				(PIO_BASE_ADDR + 0x8000)
114 #define	TIMEOUT_CFG				(PIO_BASE_ADDR + 0x8004)
115 #define	HEART_CFG				(PIO_BASE_ADDR + 0x8008)
116 #define	HEART_TIMER				(PIO_BASE_ADDR + 0x800C)
117 #define	CIP_GP_CTRL				(PIO_BASE_ADDR + 0x8010)
118 #define	CIP_STATUS				(PIO_BASE_ADDR + 0x8014)
119 #define	CIP_LINK_STAT				(PIO_BASE_ADDR + 0x801C)
120 #define	EPC_STAT				(PIO_BASE_ADDR + 0x8020)
121 #define	EPC_DATA				(PIO_BASE_ADDR + 0x8024)
122 #define	SPC_STAT				(PIO_BASE_ADDR + 0x8030)
123 #define	HOST2SPI_INDACC_ADDR			(PIO_BASE_ADDR + 0x8050)
124 #define	HOST2SPI_INDACC_CTRL			(PIO_BASE_ADDR + 0x8054)
125 #define	HOST2SPI_INDACC_DATA			(PIO_BASE_ADDR + 0x8058)
126 #define	BT_CTRL0				(PIO_BASE_ADDR + 0x8080)
127 #define	BT_DATA0				(PIO_BASE_ADDR + 0x8084)
128 #define	BT_INTMASK0				(PIO_BASE_ADDR + 0x8088)
129 #define	BT_CTRL1				(PIO_BASE_ADDR + 0x8090)
130 #define	BT_DATA1				(PIO_BASE_ADDR + 0x8094)
131 #define	BT_INTMASK1				(PIO_BASE_ADDR + 0x8098)
132 #define	BT_CTRL2				(PIO_BASE_ADDR + 0x80A0)
133 #define	BT_DATA2				(PIO_BASE_ADDR + 0x80A4)
134 #define	BT_INTMASK2				(PIO_BASE_ADDR + 0x80A8)
135 #define	BT_CTRL3				(PIO_BASE_ADDR + 0x80B0)
136 #define	BT_DATA3				(PIO_BASE_ADDR + 0x80B4)
137 #define	BT_INTMASK3				(PIO_BASE_ADDR + 0x80B8)
138 #define	DEBUG_SEL				(PIO_BASE_ADDR + 0x80C0)
139 #define	INDACC_MEM0_CTRL			(PIO_BASE_ADDR + 0x80C4)
140 #define	INDACC_MEM0_DATA0			(PIO_BASE_ADDR + 0x80C8)
141 #define	INDACC_MEM0_DATA1			(PIO_BASE_ADDR + 0x80CC)
142 #define	INDACC_MEM0_DATA2			(PIO_BASE_ADDR + 0x80D0)
143 #define	INDACC_MEM0_DATA3			(PIO_BASE_ADDR + 0x80D4)
144 #define	INDACC_MEM0_PRTY			(PIO_BASE_ADDR + 0x80D8)
145 #define	INDACC_MEM1_CTRL			(PIO_BASE_ADDR + 0x80DC)
146 #define	INDACC_MEM1_DATA0			(PIO_BASE_ADDR + 0x80E0)
147 #define	INDACC_MEM1_DATA1			(PIO_BASE_ADDR + 0x80E4)
148 #define	INDACC_MEM1_DATA2			(PIO_BASE_ADDR + 0x80E8)
149 #define	INDACC_MEM1_DATA3			(PIO_BASE_ADDR + 0x80EC)
150 #define	INDACC_MEM1_PRTY			(PIO_BASE_ADDR + 0x80F0)
151 #define	PHY_DEBUG_TRAINING_VEC			(PIO_BASE_ADDR + 0x80F4)
152 #define	PEU_DEBUG_TRAINING_VEC			(PIO_BASE_ADDR + 0x80F8)
153 #define	PIPE_CFG0				(PIO_BASE_ADDR + 0x8120)
154 #define	PIPE_CFG1				(PIO_BASE_ADDR + 0x8124)
155 #define	CIP_BAR_MASK_CFG			(PIO_BASE_ADDR + 0x8134)
156 #define	CIP_BAR_MASK				(PIO_BASE_ADDR + 0x8138)
157 #define	CIP_LDSV0_STAT				(PIO_BASE_ADDR + 0x8140)
158 #define	CIP_LDSV1_STAT				(PIO_BASE_ADDR + 0x8144)
159 #define	PEU_INTR_STAT				(PIO_BASE_ADDR + 0x8148)
160 #define	PEU_INTR_MASK				(PIO_BASE_ADDR + 0x814C)
161 #define	PEU_INTR_STAT_MIRROR			(PIO_BASE_ADDR + 0x8150)
162 #define	CPL_HDRQ_PERR_LOC			(PIO_BASE_ADDR + 0x8154)
163 #define	CPL_DATAQ_PERR_LOC			(PIO_BASE_ADDR + 0x8158)
164 #define	RETR_PERR_LOC				(PIO_BASE_ADDR + 0x815C)
165 #define	RETR_SOT_PERR_LOC			(PIO_BASE_ADDR + 0x8160)
166 #define	P_HDRQ_PERR_LOC				(PIO_BASE_ADDR + 0x8164)
167 #define	P_DATAQ_PERR_LOC			(PIO_BASE_ADDR + 0x8168)
168 #define	NP_HDRQ_PERR_LOC			(PIO_BASE_ADDR + 0x816C)
169 #define	NP_DATAQ_PERR_LOC			(PIO_BASE_ADDR + 0x8170)
170 #define	MSIX_PERR_LOC				(PIO_BASE_ADDR + 0x8174)
171 #define	HCR_PERR_LOC				(PIO_BASE_ADDR + 0x8178)
172 #define	TDC_PIOACC_ERR_LOG			(PIO_BASE_ADDR + 0x8180)
173 #define	RDC_PIOACC_ERR_LOG			(PIO_BASE_ADDR + 0x8184)
174 #define	PFC_PIOACC_ERR_LOG			(PIO_BASE_ADDR + 0x8188)
175 #define	VMAC_PIOACC_ERR_LOG			(PIO_BASE_ADDR + 0x818C)
176 #define	LD_GRP_CTRL				(PIO_BASE_ADDR + 0x8300)
177 #define	DEV_ERR_STAT				(PIO_BASE_ADDR + 0x8380)
178 #define	DEV_ERR_MASK				(PIO_BASE_ADDR + 0x8384)
179 #define	LD_INTR_TIM_RES				(PIO_BASE_ADDR + 0x8390)
180 #define	LDSV0					(PIO_LDSV_BASE_ADDR + 0x0)
181 #define	LDSV1					(PIO_LDSV_BASE_ADDR + 0x4)
182 #define	LD_INTR_MASK				(PIO_LDMASK_BASE_ADDR + 0x0)
183 #define	LD_INTR_MGMT				(PIO_LDMASK_BASE_ADDR + 0x4)
184 #define	SID					(PIO_LDMASK_BASE_ADDR + 0x8)
185 
186 
187 /*
188  * Register: DeviceVendorId
189  * Device ID and Vendor ID
190  * Description: Device ID/Vendor ID
191  * Fields:
192  *     Device ID Register: dbi writeable
193  *     Vendor ID Register (Sun Microsystem): dbi writeable
194  */
195 typedef union {
196 	uint32_t value;
197 	struct {
198 #if defined(_BIG_ENDIAN)
199 		uint32_t	device_id:16;
200 		uint32_t	vendor_id:16;
201 #else
202 		uint32_t	vendor_id:16;
203 		uint32_t	device_id:16;
204 #endif
205 	} bits;
206 } device_vendor_id_t;
207 
208 
209 /*
210  * Register: StatusCommand
211  * Status and Command
212  * Description: Status/Command
213  * Fields:
214  *     The device detected a parity error. The device detects
215  *     Poisoned TLP received regardless of Command Register Parity
216  *     Error Enable/Response bit.
217  *     The device signaled a system error with SERR#. The device
218  *     detects a UE, is about to send a F/NF error message; and if
219  *     the Command Register SERR# enable is set.
220  *     A transaction initiated by this device was terminated due to a
221  *     Master Abort (i.e. Unsupported Request Completion Status was
222  *     received).
223  *     A transaction initiated by this device was terminated due to a
224  *     Target Abort (i.e. Completer Abort Completion Status was
225  *     received).
226  *     Set when Completer Abort Completion Status is sent back to the
227  *     RC. The request violated hydra's programming rules.
228  *     The slowest DEVSEL# timing for this target device (N/A in
229  *     PCIE)
230  *     Master Data Parity Error - set if all the following conditions
231  *     are true: received a poisoned TLP header or sending a poisoned
232  *     write request; and the parity error response bit in the
233  *     command register is set.
234  *     Fast Back-to-Back Capable (N/A in PCIE)
235  *     66 MHz Capable (N/A in PCIE)
236  *     Capabilities List - presence of extended capability item.
237  *     INTx Status
238  *     INTx Assertion Disable
239  *     Fast Back-to-Back Enable (N/A in PCIE)
240  *     This device can drive the SERR# line.
241  *     IDSEL Stepping/Wait Cycle Control (N/A in PCIE)
242  *     This device can drive the PERR# line.
243  *     VGA Palette Snoop (N/A in PCIE)
244  *     The device can issue Memory Write-and-Invalidate commands (N/A
245  *     in PCIE)
246  *     This device monitors for PCI Special Cycles (N/A in PCIE)
247  *     This device's bus master capability is enabled.
248  *     This device responds to PCI memory accesses.
249  *     This device responds to PCI IO accesses (No I/O space used in
250  *     Hydra)
251  */
252 typedef union {
253 	uint32_t value;
254 	struct {
255 #if defined(_BIG_ENDIAN)
256 		uint32_t	det_par_err:1;
257 		uint32_t	sig_serr:1;
258 		uint32_t	rcv_mstr_abrt:1;
259 		uint32_t	rcv_tgt_abrt:1;
260 		uint32_t	sig_tgt_abrt:1;
261 		uint32_t	devsel_timing:2;
262 		uint32_t	mstr_dpe:1;
263 		uint32_t	fast_b2b_cap:1;
264 		uint32_t	rsrvd:1;
265 		uint32_t	mhz_cap:1;
266 		uint32_t	cap_list:1;
267 		uint32_t	intx_stat:1;
268 		uint32_t	rsrvd1:3;
269 		uint32_t	rsrvd2:5;
270 		uint32_t	intx_dis:1;
271 		uint32_t	fast_b2b_en:1;
272 		uint32_t	serr_en:1;
273 		uint32_t	idsel_step:1;
274 		uint32_t	par_err_en:1;
275 		uint32_t	vga_snoop:1;
276 		uint32_t	mwi_en:1;
277 		uint32_t	special_cycle:1;
278 		uint32_t	bm_en:1;
279 		uint32_t	mem_sp_en:1;
280 		uint32_t	io_sp_en:1;
281 #else
282 		uint32_t	io_sp_en:1;
283 		uint32_t	mem_sp_en:1;
284 		uint32_t	bm_en:1;
285 		uint32_t	special_cycle:1;
286 		uint32_t	mwi_en:1;
287 		uint32_t	vga_snoop:1;
288 		uint32_t	par_err_en:1;
289 		uint32_t	idsel_step:1;
290 		uint32_t	serr_en:1;
291 		uint32_t	fast_b2b_en:1;
292 		uint32_t	intx_dis:1;
293 		uint32_t	rsrvd2:5;
294 		uint32_t	rsrvd1:3;
295 		uint32_t	intx_stat:1;
296 		uint32_t	cap_list:1;
297 		uint32_t	mhz_cap:1;
298 		uint32_t	rsrvd:1;
299 		uint32_t	fast_b2b_cap:1;
300 		uint32_t	mstr_dpe:1;
301 		uint32_t	devsel_timing:2;
302 		uint32_t	sig_tgt_abrt:1;
303 		uint32_t	rcv_tgt_abrt:1;
304 		uint32_t	rcv_mstr_abrt:1;
305 		uint32_t	sig_serr:1;
306 		uint32_t	det_par_err:1;
307 #endif
308 	} bits;
309 } status_command_t;
310 
311 
312 /*
313  * Register: ClasscodeRevId
314  * Class Code, and Revision ID
315  * Description: Class Code/Revision ID
316  * Fields:
317  *     Base Class (Network Controller): dbi writeable
318  *     Sub Class (Ethernet Controller): dbi writeable
319  *     Programming Interface: dbi writeable
320  *     Revision ID: dbi writeable
321  */
322 typedef union {
323 	uint32_t value;
324 	struct {
325 #if defined(_BIG_ENDIAN)
326 		uint32_t	base_class:8;
327 		uint32_t	sub_class:8;
328 		uint32_t	prog_if:8;
329 		uint32_t	rev_id:8;
330 #else
331 		uint32_t	rev_id:8;
332 		uint32_t	prog_if:8;
333 		uint32_t	sub_class:8;
334 		uint32_t	base_class:8;
335 #endif
336 	} bits;
337 } classcode_rev_id_t;
338 
339 
340 /*
341  * Register: BistHdrtypLattmrCashlsz
342  * BIST, Header Type, Latency Timer, and Cache Line Size
343  * Description: BIST, Latency Timer etc
344  * Fields:
345  *     BIST is not supported. Header Type Fields
346  *     Multi-Function Device: dbi writeable
347  *     Configuration Header Format. 0 = Type 0.
348  *     Master Latency Timer. (N/A in PCIE)
349  *     Cache line size for legacy compatibility (N/A in PCIE)
350  */
351 typedef union {
352 	uint32_t value;
353 	struct {
354 #if defined(_BIG_ENDIAN)
355 		uint32_t	value:8;
356 		uint32_t	mult_func_dev:1;
357 		uint32_t	cfg_hdr_fmt:7;
358 		uint32_t	timer:8;
359 		uint32_t	cache_line_sz:8;
360 #else
361 		uint32_t	cache_line_sz:8;
362 		uint32_t	timer:8;
363 		uint32_t	cfg_hdr_fmt:7;
364 		uint32_t	mult_func_dev:1;
365 		uint32_t	value:8;
366 #endif
367 	} bits;
368 } bist_hdrtyp_lattmr_cashlsz_t;
369 
370 
371 /*
372  * Register: PioBar0
373  * PIO BAR0
374  * Description: PIO BAR0 - For Hydra PIO space PIO BAR1 & PIO BAR0
375  * are together configured as a 64b BAR register (Synopsys core
376  * implementation dependent) where PIO BAR1 handles the upper address
377  * bits and PIO BAR0 handles the lower address bits.
378  * Fields:
379  *     Base Address Relocation : indirect dbi writeable via bar0Mask
380  *     register in EP core
381  *     Base Address for PIO (16MB space) : indirect dbi writeable via
382  *     bar0Mask register in EP core
383  *     Prefetchable if memory BAR (PIOs not prefetchable): dbi
384  *     writeable
385  *     If memory BAR, then 32 or 64 bit BAR (00 = 32 bit, 10 = 64
386  *     bit): dbi writeable
387  *     I/O or Memory space indicator (0 = memory BAR): dbi writeable
388  */
389 typedef union {
390 	uint32_t value;
391 	struct {
392 #if defined(_BIG_ENDIAN)
393 		uint32_t	base_addr_rel_lo:8;
394 		uint32_t	base_addr:20;
395 		uint32_t	pftch:1;
396 		uint32_t	type:2;
397 		uint32_t	mem_sp_ind:1;
398 #else
399 		uint32_t	mem_sp_ind:1;
400 		uint32_t	type:2;
401 		uint32_t	pftch:1;
402 		uint32_t	base_addr:20;
403 		uint32_t	base_addr_rel_lo:8;
404 #endif
405 	} bits;
406 } pio_bar0_t;
407 
408 
409 /*
410  * Register: PioBar1
411  * PIO BAR1
412  * Description: PIO BAR1
413  * Fields:
414  *     Base Address Relocation : indirect dbi writeable via bar0Mask
415  *     register in EP core
416  */
417 typedef union {
418 	uint32_t value;
419 	struct {
420 #if defined(_BIG_ENDIAN)
421 		uint32_t	base_addr_rel_hi:32;
422 #else
423 		uint32_t	base_addr_rel_hi:32;
424 #endif
425 	} bits;
426 } pio_bar1_t;
427 
428 
429 /*
430  * Register: MsixBar0
431  * MSIX BAR0
432  * Description: MSIX BAR0 - For MSI-X Tables and PBA MSIX BAR1 & MSIX
433  * BAR0 are together configured as a 64b BAR register (Synopsys core
434  * implementation dependent) where MSIX BAR1 handles the upper
435  * address bits and MSIX BAR0 handles the lower address bits.
436  * Fields:
437  *     Base Address Relocation : indirect dbi writeable via bar2Mask
438  *     register in EP core
439  *     Base Address for MSIX (16KB space) : indirect dbi writeable
440  *     via bar2Mask register in EP core
441  *     Prefetchable if memory BAR (Not prefetchable) : dbi writeable
442  *     If memory BAR, then 32 or 64 bit BAR (00 = 32 bit, 10 = 64
443  *     bit): dbi writeable
444  *     I/O or Memory space indicator (0 = memory BAR) : dbi writeable
445  */
446 typedef union {
447 	uint32_t value;
448 	struct {
449 #if defined(_BIG_ENDIAN)
450 		uint32_t	base_addr_rel_lo:18;
451 		uint32_t	base_addr:10;
452 		uint32_t	pftch:1;
453 		uint32_t	type:2;
454 		uint32_t	mem_sp_ind:1;
455 #else
456 		uint32_t	mem_sp_ind:1;
457 		uint32_t	type:2;
458 		uint32_t	pftch:1;
459 		uint32_t	base_addr:10;
460 		uint32_t	base_addr_rel_lo:18;
461 #endif
462 	} bits;
463 } msix_bar0_t;
464 
465 
466 /*
467  * Register: MsixBar1
468  * MSIX BAR1
469  * Description: MSIX BAR1
470  * Fields:
471  *     Base Address Relocation : indirect dbi writeable via bar2Mask
472  *     register in EP core
473  */
474 typedef union {
475 	uint32_t value;
476 	struct {
477 #if defined(_BIG_ENDIAN)
478 		uint32_t	base_addr_rel_hi:32;
479 #else
480 		uint32_t	base_addr_rel_hi:32;
481 #endif
482 	} bits;
483 } msix_bar1_t;
484 
485 
486 /*
487  * Register: VirtBar0
488  * Virtualization BAR0
489  * Description: Virtualization BAR0 - Previously for Hydra
490  * Virtualization space This bar is no longer enabled and is not dbi
491  * writeable. VIRT BAR1 & VIRT BAR0 could be configured as a 64b BAR
492  * register (Synopsys core implementation dependent), but this is not
493  * used in hydra.
494  * Fields:
495  *     Base Address Relocation
496  *     Base Address for Virtualization (64KB space)
497  *     Prefetchable if memory BAR (Not prefetchable)
498  *     If memory BAR, then 32 or 64 bit BAR (00 = 32 bit, 10 = 64
499  *     bit)
500  *     I/O or Memory space indicator (0 = memory BAR)
501  */
502 typedef union {
503 	uint32_t value;
504 	struct {
505 #if defined(_BIG_ENDIAN)
506 		uint32_t	base_addr_rel_lo:17;
507 		uint32_t	base_addr:11;
508 		uint32_t	pftch:1;
509 		uint32_t	type:2;
510 		uint32_t	mem_sp_ind:1;
511 #else
512 		uint32_t	mem_sp_ind:1;
513 		uint32_t	type:2;
514 		uint32_t	pftch:1;
515 		uint32_t	base_addr:11;
516 		uint32_t	base_addr_rel_lo:17;
517 #endif
518 	} bits;
519 } virt_bar0_t;
520 
521 
522 /*
523  * Register: VirtBar1
524  * Virtualization BAR1
525  * Description: Previously for Virtualization BAR1 This bar is no
526  * longer enabled and is not dbi writeable.
527  * Fields:
528  *     Base Address Relocation
529  */
530 typedef union {
531 	uint32_t value;
532 	struct {
533 #if defined(_BIG_ENDIAN)
534 		uint32_t	base_addr_rel_hi:32;
535 #else
536 		uint32_t	base_addr_rel_hi:32;
537 #endif
538 	} bits;
539 } virt_bar1_t;
540 
541 
542 /*
543  * Register: CisPtr
544  * CardBus CIS Pointer
545  * Description: CardBus CIS Pointer
546  * Fields:
547  *     CardBus CIS Pointer: dbi writeable
548  */
549 typedef union {
550 	uint32_t value;
551 	struct {
552 #if defined(_BIG_ENDIAN)
553 		uint32_t	cis_ptr:32;
554 #else
555 		uint32_t	cis_ptr:32;
556 #endif
557 	} bits;
558 } cis_ptr_t;
559 
560 
561 /*
562  * Register: SubVendorId
563  * Subsystem ID and Vendor ID
564  * Description: Subsystem ID and Vendor ID
565  * Fields:
566  *     Subsystem ID as assigned by PCI-SIG : dbi writeable
567  *     Subsystem Vendor ID as assigned by PCI-SIG : dbi writeable
568  */
569 typedef union {
570 	uint32_t value;
571 	struct {
572 #if defined(_BIG_ENDIAN)
573 		uint32_t	dev_id:16;
574 		uint32_t	vendor_id:16;
575 #else
576 		uint32_t	vendor_id:16;
577 		uint32_t	dev_id:16;
578 #endif
579 	} bits;
580 } sub_vendor_id_t;
581 
582 
583 /*
584  * Register: ExpRomBar
585  * Expansion ROM BAR
586  * Description: Expansion ROM BAR - For Hydra EEPROM space
587  * Fields:
588  *     Base Address Relocatable : indirect dbi writeable via
589  *     romBarMask register in EP core
590  *     Base Address for ROM (2MB) : indirect dbi writeable via
591  *     romBarMask register in EP core
592  *     ROM Enable: dbi writeable
593  */
594 typedef union {
595 	uint32_t value;
596 	struct {
597 #if defined(_BIG_ENDIAN)
598 		uint32_t	base_addr_rel:11;
599 		uint32_t	base_addr:10;
600 		uint32_t	rsrvd:10;
601 		uint32_t	rom_en:1;
602 #else
603 		uint32_t	rom_en:1;
604 		uint32_t	rsrvd:10;
605 		uint32_t	base_addr:10;
606 		uint32_t	base_addr_rel:11;
607 #endif
608 	} bits;
609 } exp_rom_bar_t;
610 
611 
612 /*
613  * Register: CapPtr
614  * Capabilities Pointer
615  * Description: Capabilities Pointer
616  * Fields:
617  *     Pointer to PM Capability structure : dbi writeable
618  */
619 typedef union {
620 	uint32_t value;
621 	struct {
622 #if defined(_BIG_ENDIAN)
623 		uint32_t	rsrvd:24;
624 		uint32_t	pm_ptr:8;
625 #else
626 		uint32_t	pm_ptr:8;
627 		uint32_t	rsrvd:24;
628 #endif
629 	} bits;
630 } cap_ptr_t;
631 
632 
633 /*
634  * Register: IntLine
635  * Interrupt Line
636  * Description: Interrupt Line
637  * Fields:
638  *     Max Latency (N/A in PCIE)
639  *     Minimum Grant (N/A in PCIE)
640  *     Interrupt pin: dbi writeable
641  *     Interrupt Line
642  */
643 typedef union {
644 	uint32_t value;
645 	struct {
646 #if defined(_BIG_ENDIAN)
647 		uint32_t	max_lat:8;
648 		uint32_t	min_gnt:8;
649 		uint32_t	int_pin:8;
650 		uint32_t	int_line:8;
651 #else
652 		uint32_t	int_line:8;
653 		uint32_t	int_pin:8;
654 		uint32_t	min_gnt:8;
655 		uint32_t	max_lat:8;
656 #endif
657 	} bits;
658 } int_line_t;
659 
660 
661 /*
662  * Register: PmCap
663  * Power Management Capability
664  * Description: Power Management Capability
665  * Fields:
666  *     PME Support (N/A in Hydra): dbi writeable
667  *     D2 Support (N/A in Hydra): dbi writeable
668  *     D1 Support (N/A in Hydra): dbi writeable
669  *     Aux Current (N/A in Hydra): dbi writeable
670  *     Device Specific Initialization: dbi writeable
671  *     PME Clock (N/A in PCIE)
672  *     PM Spec Version: dbi writeable
673  *     Next Capability Pointer: dbi writeable
674  *     Power Management Capability ID: dbi writeable
675  */
676 typedef union {
677 	uint32_t value;
678 	struct {
679 #if defined(_BIG_ENDIAN)
680 		uint32_t	pme_supt:5;
681 		uint32_t	d2_supt:1;
682 		uint32_t	d1_supt:1;
683 		uint32_t	aux_curr:3;
684 		uint32_t	dev_spec_init:1;
685 		uint32_t	rsrvd:1;
686 		uint32_t	pme_clk:1;
687 		uint32_t	pm_ver:3;
688 		uint32_t	nxt_cap_ptr:8;
689 		uint32_t	pm_id:8;
690 #else
691 		uint32_t	pm_id:8;
692 		uint32_t	nxt_cap_ptr:8;
693 		uint32_t	pm_ver:3;
694 		uint32_t	pme_clk:1;
695 		uint32_t	rsrvd:1;
696 		uint32_t	dev_spec_init:1;
697 		uint32_t	aux_curr:3;
698 		uint32_t	d1_supt:1;
699 		uint32_t	d2_supt:1;
700 		uint32_t	pme_supt:5;
701 #endif
702 	} bits;
703 } pm_cap_t;
704 
705 
706 /*
707  * Register: PmCtrlStat
708  * Power Management Control and Status
709  * Description: Power Management Control and Status
710  * Fields:
711  *     Data for additional info (N/A)
712  *     Bus Power and Clock Control Enable (N/A in PCIE)
713  *     B2/B3 Support (N/A in PCIE)
714  *     Indicates if PME event occured
715  *     Data Scale (N/A)
716  *     Data Select (N/A)
717  *     PME Enable (Sticky)
718  *     Power State
719  */
720 typedef union {
721 	uint32_t value;
722 	struct {
723 #if defined(_BIG_ENDIAN)
724 		uint32_t	pwr_data:8;
725 		uint32_t	pwr_clk_en:1;
726 		uint32_t	b2_b3_supt:1;
727 		uint32_t	rsrvd:6;
728 		uint32_t	pme_stat:1;
729 		uint32_t	data_scale:2;
730 		uint32_t	data_sel:4;
731 		uint32_t	pme_en:1;
732 		uint32_t	rsrvd1:6;
733 		uint32_t	pwr_st:2;
734 #else
735 		uint32_t	pwr_st:2;
736 		uint32_t	rsrvd1:6;
737 		uint32_t	pme_en:1;
738 		uint32_t	data_sel:4;
739 		uint32_t	data_scale:2;
740 		uint32_t	pme_stat:1;
741 		uint32_t	rsrvd:6;
742 		uint32_t	b2_b3_supt:1;
743 		uint32_t	pwr_clk_en:1;
744 		uint32_t	pwr_data:8;
745 #endif
746 	} bits;
747 } pm_ctrl_stat_t;
748 
749 
750 /*
751  * Register: MsiCap
752  * MSI Capability
753  * Description: MSI Capability
754  * Fields:
755  *     Mask and Pending bits available
756  *     64-bit Address Capable
757  *     Multiple Messages Enabled
758  *     Multiple Message Capable (32 messages = 0x5)
759  *     MSI Enabled (if enabled, INTx must be diabled)
760  *     Next Capability Pointer: dbi writeable
761  *     MSI Capability ID
762  */
763 typedef union {
764 	uint32_t value;
765 	struct {
766 #if defined(_BIG_ENDIAN)
767 		uint32_t	rsrvd:7;
768 		uint32_t	vect_mask:1;
769 		uint32_t	msi64_en:1;
770 		uint32_t	mult_msg_en:3;
771 		uint32_t	mult_msg_cap:3;
772 		uint32_t	msi_en:1;
773 		uint32_t	nxt_cap_ptr:8;
774 		uint32_t	msi_cap_id:8;
775 #else
776 		uint32_t	msi_cap_id:8;
777 		uint32_t	nxt_cap_ptr:8;
778 		uint32_t	msi_en:1;
779 		uint32_t	mult_msg_cap:3;
780 		uint32_t	mult_msg_en:3;
781 		uint32_t	msi64_en:1;
782 		uint32_t	vect_mask:1;
783 		uint32_t	rsrvd:7;
784 #endif
785 	} bits;
786 } msi_cap_t;
787 
788 
789 /*
790  * Register: MsiLoAddr
791  * MSI Low Address
792  * Description: MSI Low Address
793  * Fields:
794  *     Lower 32 bit Address
795  */
796 typedef union {
797 	uint32_t value;
798 	struct {
799 #if defined(_BIG_ENDIAN)
800 		uint32_t	lo_addr:30;
801 		uint32_t	rsrvd:2;
802 #else
803 		uint32_t	rsrvd:2;
804 		uint32_t	lo_addr:30;
805 #endif
806 	} bits;
807 } msi_lo_addr_t;
808 
809 
810 /*
811  * Register: MsiHiAddr
812  * MSI High Address
813  * Description: MSI High Address
814  * Fields:
815  *     Upper 32 bit Address (only if msi64En = 1)
816  */
817 typedef union {
818 	uint32_t value;
819 	struct {
820 #if defined(_BIG_ENDIAN)
821 		uint32_t	hi_addr:32;
822 #else
823 		uint32_t	hi_addr:32;
824 #endif
825 	} bits;
826 } msi_hi_addr_t;
827 
828 
829 /*
830  * Register: MsiData
831  * MSI Data
832  * Description: MSI Data
833  * Fields:
834  *     MSI Data. Depending on the value for multMsgEn in the MSI
835  *     Capability Register which determines the number of allocated
836  *     vectors, bits [4:0] may be replaced with msiVector[4:0] bits
837  *     to generate up to 32 MSI messages. # allocated vectors Actual
838  *     messageData[4:0] ------------------- ------------------------
839  *     1 DATA[4:0] (no replacement) 2 {DATA[4:1], msiVector[0]} 4
840  *     {DATA[4:2], msiVector[1:0]} 8 {DATA[4:3], msiVector[2:0]} 16
841  *     {DATA[4], msiVector[3:0]} 32 msiVector[4:0] (full replacement)
842  */
843 typedef union {
844 	uint32_t value;
845 	struct {
846 #if defined(_BIG_ENDIAN)
847 		uint32_t	rsrvd:16;
848 		uint32_t	data:16;
849 #else
850 		uint32_t	data:16;
851 		uint32_t	rsrvd:16;
852 #endif
853 	} bits;
854 } msi_data_t;
855 
856 
857 /*
858  * Register: MsiMask
859  * MSI Mask
860  * Description: MSI Mask
861  * Fields:
862  *     per vector MSI Mask bits
863  */
864 typedef union {
865 	uint32_t value;
866 	struct {
867 #if defined(_BIG_ENDIAN)
868 		uint32_t	mask:32;
869 #else
870 		uint32_t	mask:32;
871 #endif
872 	} bits;
873 } msi_mask_t;
874 
875 
876 /*
877  * Register: MsiPend
878  * MSI Pending
879  * Description: MSI Pending
880  * Fields:
881  *     per vector MSI Pending bits
882  */
883 typedef union {
884 	uint32_t value;
885 	struct {
886 #if defined(_BIG_ENDIAN)
887 		uint32_t	pend:32;
888 #else
889 		uint32_t	pend:32;
890 #endif
891 	} bits;
892 } msi_pend_t;
893 
894 
895 /*
896  * Register: MsixCap
897  * MSIX Capability
898  * Description: MSIX Capability
899  * Fields:
900  *     MSIX Enable (if enabled, MSI and INTx must be disabled)
901  *     Function Mask (1 = all vectors masked regardless of per vector
902  *     mask, 0 = each vector's mask
903  *     Table Size (0x1F = 32 entries): dbi writeable
904  *     Next Capability Pointer: dbi writeable
905  *     MSIX Capability ID
906  */
907 typedef union {
908 	uint32_t value;
909 	struct {
910 #if defined(_BIG_ENDIAN)
911 		uint32_t	msix_en:1;
912 		uint32_t	func_mask:1;
913 		uint32_t	rsrvd:3;
914 		uint32_t	tab_sz:11;
915 		uint32_t	nxt_cap_ptr:8;
916 		uint32_t	msix_cap_id:8;
917 #else
918 		uint32_t	msix_cap_id:8;
919 		uint32_t	nxt_cap_ptr:8;
920 		uint32_t	tab_sz:11;
921 		uint32_t	rsrvd:3;
922 		uint32_t	func_mask:1;
923 		uint32_t	msix_en:1;
924 #endif
925 	} bits;
926 } msix_cap_t;
927 
928 
929 /*
930  * Register: MsixTabOff
931  * MSIX Table Offset
932  * Description: MSIX Table Offset
933  * Fields:
934  *     Table Offset (Base address of MSIX Table = msixTabBir.BAR +
935  *     msixTabOff) : dbi writeable
936  *     Table BAR Indicator (0x2 = BAR2 at loc 0x18) : dbi writeable
937  */
938 typedef union {
939 	uint32_t value;
940 	struct {
941 #if defined(_BIG_ENDIAN)
942 		uint32_t	msix_tab_off:29;
943 		uint32_t	msix_tab_bir:3;
944 #else
945 		uint32_t	msix_tab_bir:3;
946 		uint32_t	msix_tab_off:29;
947 #endif
948 	} bits;
949 } msix_tab_off_t;
950 
951 
952 /*
953  * Register: MsixPbaOff
954  * MSIX PBA Offset
955  * Description: MSIX PBA Offset
956  * Fields:
957  *     Pending Bit Array (PBA) Offset (Base address of MSIX Table =
958  *     msixTabBir.BAR + msixPbaOff); msixPbaOff is quad-aligned, i.e.
959  *     starts at 0x2000 (half-way in MSI-X bar space. : dbi writeable
960  *     Pending Bit Array (PBA) BAR Indicator (0x2 = BAR2 at loc 0x18)
961  *     : dbi writeable
962  */
963 typedef union {
964 	uint32_t value;
965 	struct {
966 #if defined(_BIG_ENDIAN)
967 		uint32_t	msix_pba_off:29;
968 		uint32_t	msix_pba_bir:3;
969 #else
970 		uint32_t	msix_pba_bir:3;
971 		uint32_t	msix_pba_off:29;
972 #endif
973 	} bits;
974 } msix_pba_off_t;
975 
976 
977 /*
978  * Register: PcieCap
979  * PCIE Capability
980  * Description: PCIE Capability
981  * Fields:
982  *     Interrupt Message Number (updated by HW)
983  *     Slot Implemented (Endpoint must be 0)
984  *     PCIE Express Device Port Type (Endpoint)
985  *     PCIE Express Capability Version
986  *     Next Capability Pointer: dbi writeable
987  *     PCI Express Capability ID
988  */
989 typedef union {
990 	uint32_t value;
991 	struct {
992 #if defined(_BIG_ENDIAN)
993 		uint32_t	rsrvd:2;
994 		uint32_t	int_msg_num:5;
995 		uint32_t	pcie_slt_imp:1;
996 		uint32_t	pcie_dev_type:4;
997 		uint32_t	pcie_cap_ver:4;
998 		uint32_t	nxt_cap_ptr:8;
999 		uint32_t	pcie_cap_id:8;
1000 #else
1001 		uint32_t	pcie_cap_id:8;
1002 		uint32_t	nxt_cap_ptr:8;
1003 		uint32_t	pcie_cap_ver:4;
1004 		uint32_t	pcie_dev_type:4;
1005 		uint32_t	pcie_slt_imp:1;
1006 		uint32_t	int_msg_num:5;
1007 		uint32_t	rsrvd:2;
1008 #endif
1009 	} bits;
1010 } pcie_cap_t;
1011 
1012 
1013 /*
1014  * Register: DevCap
1015  * Device Capability
1016  * Description: Device Capability
1017  * Fields:
1018  *     Slot Power Limit Scale (Msg from RC) Hydra can capture
1019  *     Received setSlotPowerLimit message; values in this field are
1020  *     ignored as no power scaling is possible.
1021  *     Slot Power Limit Value (Msg from RC) Hydra can capture
1022  *     Received setSlotPowerLimit message; values in this field are
1023  *     ignored as no power scaling is possible.
1024  *     Introduced in PCIe 1.1 specification. : dbi writeable
1025  *     L1 Acceptable Latency (4 - 8 us) : dbi writeable
1026  *     LOs Acceptable Latency (2 - 4 us) : dbi writeable
1027  *     Extended Tag Field Support (N/A) : dbi writeable
1028  *     Phantom Function Supported (N/A) : dbi writeable
1029  *     Maximum Payload Size supported (Hydra = 1KB) : dbi writeable
1030  */
1031 typedef union {
1032 	uint32_t value;
1033 	struct {
1034 #if defined(_BIG_ENDIAN)
1035 		uint32_t	rsrvd:4;
1036 		uint32_t	slt_pwr_lmt_scle:2;
1037 		uint32_t	slt_pwr_lmt_val:8;
1038 		uint32_t	rsrvd1:2;
1039 		uint32_t	role_based_err:1;
1040 		uint32_t	rsrvd2:3;
1041 		uint32_t	l1_lat:3;
1042 		uint32_t	los_lat:3;
1043 		uint32_t	ext_tag:1;
1044 		uint32_t	phant_func:2;
1045 		uint32_t	max_mtu:3;
1046 #else
1047 		uint32_t	max_mtu:3;
1048 		uint32_t	phant_func:2;
1049 		uint32_t	ext_tag:1;
1050 		uint32_t	los_lat:3;
1051 		uint32_t	l1_lat:3;
1052 		uint32_t	rsrvd2:3;
1053 		uint32_t	role_based_err:1;
1054 		uint32_t	rsrvd1:2;
1055 		uint32_t	slt_pwr_lmt_val:8;
1056 		uint32_t	slt_pwr_lmt_scle:2;
1057 		uint32_t	rsrvd:4;
1058 #endif
1059 	} bits;
1060 } dev_cap_t;
1061 
1062 
1063 /*
1064  * Register: DevStatCtrl
1065  * Device Status and Control
1066  * Description: Device Control
1067  * Fields:
1068  *     Transaction Pending (1 if NP request not completed)
1069  *     Auxilliary Power Detected (1 if detected)
1070  *     Unsupported Request Detect
1071  *     Fatal Error Detected
1072  *     Non-Fatal Error Detected
1073  *     Correctable Error Detected ----- Control Fields
1074  *     Introduced in PCIe 1.1 specification.
1075  *     Maximum Read Request Size (default = 512B) for the device as a
1076  *     requester. 3'b000: 128 Bytes 3'b001: 256 Bytes 3'b010: 512
1077  *     Bytes 3'b011: 1K Bytes 3'b100: 2K Bytes 3'b101: 4K Bytes
1078  *     3'b110: Reserved 3'b111: Reserved
1079  *     No Snoop Enable This bit indicates the device "could", not
1080  *     that it does. Both this bit and the hydra specific peuCip
1081  *     register bit must be set for the value of this bit to impact
1082  *     the TLP header no snoop attribute. When both are set, hydra
1083  *     sets the no snoop attribute on all initiated TLPs. Software
1084  *     must guarantee the No Snoop attribute is used in the system
1085  *     correctly.
1086  *     Auxilliary Power PM Enable
1087  *     Phantom Function enable
1088  *     Extended Tag Field Enable
1089  *     Maximum Payload Size. 3-bit value has the same encodings as
1090  *     the maxRdSz field.
1091  *     Relaxed Ordering Enable This bit indicates the device "could",
1092  *     not that it does. Both this bit and the hydra specific peuCip
1093  *     register bit must be set for the value of this bit to impact
1094  *     the TLP header relaxed ordering attribute. When both are set,
1095  *     packet operations set the relaxed ordering attribute. Mailbox
1096  *     updates always set the relaxed ordering attribute to 0,
1097  *     regardless of this bit. When this bit is 0, the default
1098  *     Sun4u/Sun4v ordering model is used.
1099  *     Unsupported Request Report Enable
1100  *     Fatal Error Report Enable
1101  *     Non-Fatal Error Report Enable
1102  *     Correctable Error Report Enable
1103  */
1104 typedef union {
1105 	uint32_t value;
1106 	struct {
1107 #if defined(_BIG_ENDIAN)
1108 		uint32_t	rsrvd:10;
1109 		uint32_t	trans_pend:1;
1110 		uint32_t	aux_pwr_det:1;
1111 		uint32_t	unsup_req_det:1;
1112 		uint32_t	fat_err_det:1;
1113 		uint32_t	nf_err_det:1;
1114 		uint32_t	corr_err_det:1;
1115 		uint32_t	pcie2pcix_brdg:1;
1116 		uint32_t	max_rd_sz:3;
1117 		uint32_t	no_snoop_en:1;
1118 		uint32_t	aux_pwr_pm_en:1;
1119 		uint32_t	phant_func_en:1;
1120 		uint32_t	ext_tag_en:1;
1121 		uint32_t	max_pld_sz:3;
1122 		uint32_t	rlx_ord_en:1;
1123 		uint32_t	unsup_req_en:1;
1124 		uint32_t	fat_err_en:1;
1125 		uint32_t	nf_err_en:1;
1126 		uint32_t	corr_err_en:1;
1127 #else
1128 		uint32_t	corr_err_en:1;
1129 		uint32_t	nf_err_en:1;
1130 		uint32_t	fat_err_en:1;
1131 		uint32_t	unsup_req_en:1;
1132 		uint32_t	rlx_ord_en:1;
1133 		uint32_t	max_pld_sz:3;
1134 		uint32_t	ext_tag_en:1;
1135 		uint32_t	phant_func_en:1;
1136 		uint32_t	aux_pwr_pm_en:1;
1137 		uint32_t	no_snoop_en:1;
1138 		uint32_t	max_rd_sz:3;
1139 		uint32_t	pcie2pcix_brdg:1;
1140 		uint32_t	corr_err_det:1;
1141 		uint32_t	nf_err_det:1;
1142 		uint32_t	fat_err_det:1;
1143 		uint32_t	unsup_req_det:1;
1144 		uint32_t	aux_pwr_det:1;
1145 		uint32_t	trans_pend:1;
1146 		uint32_t	rsrvd:10;
1147 #endif
1148 	} bits;
1149 } dev_stat_ctrl_t;
1150 
1151 
1152 /*
1153  * Register: LnkCap
1154  * Link Capability
1155  * Description: Link Capability
1156  * Fields:
1157  *     Port Number : dbi writeable
1158  *     Introduced in PCIe 1.1 specification.
1159  *     Introduced in PCIe 1.1 specification.
1160  *     Default Clock Power Management (N/A) Introduced in PCIe 1.1
1161  *     specification. : dbi writeable
1162  *     Default L1 Exit Latency (32us to 64us => 0x6) : dbi writeable
1163  *     Default L0s Exit Latency (1us to 2us => 0x5) : dbi writeable
1164  *     Active Link PM Support (only L0s = 1) : dbi writeable
1165  *     Maximum Link Width (x8) : dbi writeable
1166  *     Maximum Link Speed (2.5 Gbps = 1) : dbi writeable
1167  */
1168 typedef union {
1169 	uint32_t value;
1170 	struct {
1171 #if defined(_BIG_ENDIAN)
1172 		uint32_t	prt_num:8;
1173 		uint32_t	rsrvd:3;
1174 		uint32_t	def_dll_act_rptg:1;
1175 		uint32_t	def_surpise_down:1;
1176 		uint32_t	def_clk_pm_cap:1;
1177 		uint32_t	def_l1_lat:3;
1178 		uint32_t	def_l0s_lat:3;
1179 		uint32_t	as_lnk_pm_supt:2;
1180 		uint32_t	max_lnk_wid:6;
1181 		uint32_t	max_lnk_spd:4;
1182 #else
1183 		uint32_t	max_lnk_spd:4;
1184 		uint32_t	max_lnk_wid:6;
1185 		uint32_t	as_lnk_pm_supt:2;
1186 		uint32_t	def_l0s_lat:3;
1187 		uint32_t	def_l1_lat:3;
1188 		uint32_t	def_clk_pm_cap:1;
1189 		uint32_t	def_surpise_down:1;
1190 		uint32_t	def_dll_act_rptg:1;
1191 		uint32_t	rsrvd:3;
1192 		uint32_t	prt_num:8;
1193 #endif
1194 	} bits;
1195 } lnk_cap_t;
1196 
1197 
1198 /*
1199  * Register: LnkStatCtrl
1200  * Link Status and Control
1201  * Description: Link Control
1202  * Fields:
1203  *     Slot Clock Configuration (0 = using independent clock; pg 266
1204  *     PCIe 1.1) : dbi writeable
1205  *     Link Training (N/A for EP)
1206  *     Training Error (N/A for EP)
1207  *     Negotiated Link Width (Max negotiated: x8)
1208  *     Negotiated Link Speed (Max negotiated: 1 = 2.5 Gbps) -----
1209  *     Control Fields
1210  *     Introduced in PCIe 1.1.
1211  *     Extended Synch
1212  *     Common Clock Configuration
1213  *     Retrain Link (N/A for EP)
1214  *     Link Disable (N/A for EP)
1215  *     Read Completion Boundary (128B)
1216  *     Active State Link PM Control
1217  */
1218 typedef union {
1219 	uint32_t value;
1220 	struct {
1221 #if defined(_BIG_ENDIAN)
1222 		uint32_t	rsrvd:2;
1223 		uint32_t	dll_active:1;
1224 		uint32_t	slt_clk_cfg:1;
1225 		uint32_t	lnk_train:1;
1226 		uint32_t	train_err:1;
1227 		uint32_t	lnk_wid:6;
1228 		uint32_t	lnk_spd:4;
1229 		uint32_t	rsrvd1:7;
1230 		uint32_t	en_clkpwr_mg:1;
1231 		uint32_t	ext_sync:1;
1232 		uint32_t	com_clk_cfg:1;
1233 		uint32_t	retrain_lnk:1;
1234 		uint32_t	lnk_dis:1;
1235 		uint32_t	rd_cmpl_bndy:1;
1236 		uint32_t	rsrvd2:1;
1237 		uint32_t	aspm_ctrl:2;
1238 #else
1239 		uint32_t	aspm_ctrl:2;
1240 		uint32_t	rsrvd2:1;
1241 		uint32_t	rd_cmpl_bndy:1;
1242 		uint32_t	lnk_dis:1;
1243 		uint32_t	retrain_lnk:1;
1244 		uint32_t	com_clk_cfg:1;
1245 		uint32_t	ext_sync:1;
1246 		uint32_t	en_clkpwr_mg:1;
1247 		uint32_t	rsrvd1:7;
1248 		uint32_t	lnk_spd:4;
1249 		uint32_t	lnk_wid:6;
1250 		uint32_t	train_err:1;
1251 		uint32_t	lnk_train:1;
1252 		uint32_t	slt_clk_cfg:1;
1253 		uint32_t	dll_active:1;
1254 		uint32_t	rsrvd:2;
1255 #endif
1256 	} bits;
1257 } lnk_stat_ctrl_t;
1258 
1259 
1260 /*
1261  * Register: VenCapHdr
1262  * Vendor Specific Capability Header
1263  * Description: Vendor Specific Capability Header
1264  * Fields:
1265  *     Length
1266  *     Next Capbility Pointer
1267  *     Vendor Specific Capbility ID
1268  */
1269 typedef union {
1270 	uint32_t value;
1271 	struct {
1272 #if defined(_BIG_ENDIAN)
1273 		uint32_t	rsrvd:8;
1274 		uint32_t	len:8;
1275 		uint32_t	nxt_cap_ptr:8;
1276 		uint32_t	ven_cap_id:8;
1277 #else
1278 		uint32_t	ven_cap_id:8;
1279 		uint32_t	nxt_cap_ptr:8;
1280 		uint32_t	len:8;
1281 		uint32_t	rsrvd:8;
1282 #endif
1283 	} bits;
1284 } ven_cap_hdr_t;
1285 
1286 
1287 /*
1288  * Register: VenCtrl
1289  * Vendor Specific Control
1290  * Description: Vendor Specific Control
1291  * Fields:
1292  *     PCIe spec absolute minimum is 50usec - (likely ~10ms). PCIe
1293  *     spec absolute max is 50msec. Default set for 22.2 msec via
1294  *     adding time as follows: Bit 23: 3.21 secs <---POR 0 Bit 22:
1295  *     201.3 msec <---POR 0 Bit 21: 100.8 msec <---POR 0 Bit 20: 25.2
1296  *     msec <---POR 0 Bit 19: 12.6 msec <---POR 1 Bit 18: 6.3 msec
1297  *     <---POR 1 Bit 17: 3.3 msec <---POR 1 Bit 16: if 0:
1298  *     Baseline0=50usec; else Baseline1(use for
1299  *     simulation-only)=804nsec
1300  *     Interrupt Control Mode (00 = Reserved, 01 = INTx emulation, 10
1301  *     = Reserved [Neptune INTx pins], 11 = Reserved [Neptune INTx
1302  *     emulation + pins]
1303  */
1304 typedef union {
1305 	uint32_t value;
1306 	struct {
1307 #if defined(_BIG_ENDIAN)
1308 		uint32_t	rsrvd:8;
1309 		uint32_t	eic_xtd_cpl_timout:8;
1310 		uint32_t	rsrvd1:14;
1311 		uint32_t	legacy_int_ctrl:2;
1312 #else
1313 		uint32_t	legacy_int_ctrl:2;
1314 		uint32_t	rsrvd1:14;
1315 		uint32_t	eic_xtd_cpl_timout:8;
1316 		uint32_t	rsrvd:8;
1317 #endif
1318 	} bits;
1319 } ven_ctrl_t;
1320 
1321 
1322 /*
1323  * Register: VenPrtHdr
1324  * Vendor Specific Port Logic Header
1325  * Description: Vendor Specific Port Logic Header
1326  * Fields:
1327  *     Length
1328  *     Next Capbility Pointer (END, no more)
1329  *     Vendor Specific Capbility ID
1330  */
1331 typedef union {
1332 	uint32_t value;
1333 	struct {
1334 #if defined(_BIG_ENDIAN)
1335 		uint32_t	rsrvd:8;
1336 		uint32_t	len:8;
1337 		uint32_t	nxt_cap_ptr:8;
1338 		uint32_t	ven_cap_id:8;
1339 #else
1340 		uint32_t	ven_cap_id:8;
1341 		uint32_t	nxt_cap_ptr:8;
1342 		uint32_t	len:8;
1343 		uint32_t	rsrvd:8;
1344 #endif
1345 	} bits;
1346 } ven_prt_hdr_t;
1347 
1348 
1349 /*
1350  * Register: AcklatReplay
1351  * Ack Latency and Replay Timer register
1352  * Description: Ack Latency/Replay Timer
1353  * Fields:
1354  *     Replay Time limit = 16'd12429/`cxNb where cxNb=1.
1355  *     Round Trip Latency Time limit = 9d'4143/`cxNb where cxNb=1.
1356  */
1357 typedef union {
1358 	uint32_t value;
1359 	struct {
1360 #if defined(_BIG_ENDIAN)
1361 		uint32_t	rep_tim:16;
1362 		uint32_t	ack_tim:16;
1363 #else
1364 		uint32_t	ack_tim:16;
1365 		uint32_t	rep_tim:16;
1366 #endif
1367 	} bits;
1368 } acklat_replay_t;
1369 
1370 
1371 /*
1372  * Register: OthMsg
1373  * Other Message Register
1374  * Description: Other Message Register
1375  * Fields:
1376  *     Message to send/Data to corrupt LCRC
1377  */
1378 typedef union {
1379 	uint32_t value;
1380 	struct {
1381 #if defined(_BIG_ENDIAN)
1382 		uint32_t	oth_msg:32;
1383 #else
1384 		uint32_t	oth_msg:32;
1385 #endif
1386 	} bits;
1387 } oth_msg_t;
1388 
1389 
1390 /*
1391  * Register: ForceLink
1392  * Port Force Link
1393  * Description: Other Message Register
1394  * Fields:
1395  *     LinkState that the EP core will be forced to when ForceLink
1396  *     (bit[15]) is set
1397  *     Forces Link to the specified LinkState field below. Write this
1398  *     bit to generate a pulse to the ltssm. It clears itself once
1399  *     the pulse is generated. Read will always return 0.
1400  *     Link Number - N/A for Endpoint
1401  */
1402 typedef union {
1403 	uint32_t value;
1404 	struct {
1405 #if defined(_BIG_ENDIAN)
1406 		uint32_t	rsrvd:10;
1407 		uint32_t	link_state:6;
1408 		uint32_t	force_link:1;
1409 		uint32_t	rsrvd1:7;
1410 		uint32_t	link_num:8;
1411 #else
1412 		uint32_t	link_num:8;
1413 		uint32_t	rsrvd1:7;
1414 		uint32_t	force_link:1;
1415 		uint32_t	link_state:6;
1416 		uint32_t	rsrvd:10;
1417 #endif
1418 	} bits;
1419 } force_link_t;
1420 
1421 
1422 /*
1423  * Register: AckFreq
1424  * ACK Frequency Register
1425  * Description: ACK Frequency Register
1426  * Fields:
1427  *     NFTS = 115.
1428  *     NFTS = 115.
1429  */
1430 typedef union {
1431 	uint32_t value;
1432 	struct {
1433 #if defined(_BIG_ENDIAN)
1434 		uint32_t	rsrvd:2;
1435 		uint32_t	l1_entr_latency:3;
1436 		uint32_t	los_entr_latency:3;
1437 		uint32_t	cx_comm_nfts:8;
1438 		uint32_t	nfts:8;
1439 		uint32_t	def_ack_freq:8;
1440 #else
1441 		uint32_t	def_ack_freq:8;
1442 		uint32_t	nfts:8;
1443 		uint32_t	cx_comm_nfts:8;
1444 		uint32_t	los_entr_latency:3;
1445 		uint32_t	l1_entr_latency:3;
1446 		uint32_t	rsrvd:2;
1447 #endif
1448 	} bits;
1449 } ack_freq_t;
1450 
1451 
1452 /*
1453  * Register: LinkCtrl
1454  * Port Link Control
1455  * Description: Port Link Control
1456  * Fields:
1457  *     8 lanes
1458  *     When set, this bit is only set for 1 cycle. A write of 0 has
1459  *     no effect.
1460  */
1461 typedef union {
1462 	uint32_t value;
1463 	struct {
1464 #if defined(_BIG_ENDIAN)
1465 		uint32_t	rsrvd:4;
1466 		uint32_t	rsrvd1:2;
1467 		uint32_t	corrupt_lcrc:1;
1468 		uint32_t	rsrvd2:1;
1469 		uint32_t	rsrvd3:2;
1470 		uint32_t	link_mode_en:6;
1471 		uint32_t	rsrvd4:4;
1472 		uint32_t	rsrvd5:4;
1473 		uint32_t	fast_link_mode:1;
1474 		uint32_t	rsrvd6:1;
1475 		uint32_t	dll_link_en:1;
1476 		uint32_t	rsrvd7:1;
1477 		uint32_t	reset_assert:1;
1478 		uint32_t	lpbk_en:1;
1479 		uint32_t	scram_dis:1;
1480 		uint32_t	oth_msg_req:1;
1481 #else
1482 		uint32_t	oth_msg_req:1;
1483 		uint32_t	scram_dis:1;
1484 		uint32_t	lpbk_en:1;
1485 		uint32_t	reset_assert:1;
1486 		uint32_t	rsrvd7:1;
1487 		uint32_t	dll_link_en:1;
1488 		uint32_t	rsrvd6:1;
1489 		uint32_t	fast_link_mode:1;
1490 		uint32_t	rsrvd5:4;
1491 		uint32_t	rsrvd4:4;
1492 		uint32_t	link_mode_en:6;
1493 		uint32_t	rsrvd3:2;
1494 		uint32_t	rsrvd2:1;
1495 		uint32_t	corrupt_lcrc:1;
1496 		uint32_t	rsrvd1:2;
1497 		uint32_t	rsrvd:4;
1498 #endif
1499 	} bits;
1500 } link_ctrl_t;
1501 
1502 
1503 /*
1504  * Register: LaneSkew
1505  * Lane Skew Register
1506  * Description: Lane Skew Register
1507  * Fields:
1508  *     prevents EP core from sending Ack/Nack DLLPs
1509  *     prevents EP core from sending FC DLLPs
1510  */
1511 typedef union {
1512 	uint32_t value;
1513 	struct {
1514 #if defined(_BIG_ENDIAN)
1515 		uint32_t	dis_lane_to_lane_deskew:1;
1516 		uint32_t	rsrvd:5;
1517 		uint32_t	ack_nack_dis:1;
1518 		uint32_t	flow_control_dis:1;
1519 		uint32_t	tx_lane_skew:24;
1520 #else
1521 		uint32_t	tx_lane_skew:24;
1522 		uint32_t	flow_control_dis:1;
1523 		uint32_t	ack_nack_dis:1;
1524 		uint32_t	rsrvd:5;
1525 		uint32_t	dis_lane_to_lane_deskew:1;
1526 #endif
1527 	} bits;
1528 } lane_skew_t;
1529 
1530 
1531 /*
1532  * Register: SymbolNum
1533  * Symbol Number Register
1534  * Description: Symbol Number Register
1535  * Fields:
1536  *     Timer modifier for Flow control Watch Dog timer
1537  *     Timer modifier for Ack/Nack latency timer
1538  *     Timer modifier for Replay timer
1539  *     Note: rtl uses defaultNSkipSymbols
1540  *     Note: rtl initialized using defaultNTs1Symbols
1541  */
1542 typedef union {
1543 	uint32_t value;
1544 	struct {
1545 #if defined(_BIG_ENDIAN)
1546 		uint32_t	rsrvd:3;
1547 		uint32_t	fc_wdog_tim_mod:5;
1548 		uint32_t	ack_nack_tim_mod:5;
1549 		uint32_t	rep_tim_mod:5;
1550 		uint32_t	rsrvd1:3;
1551 		uint32_t	num_skip_symb:3;
1552 		uint32_t	rsrvd2:4;
1553 		uint32_t	num_ts_symb:4;
1554 #else
1555 		uint32_t	num_ts_symb:4;
1556 		uint32_t	rsrvd2:4;
1557 		uint32_t	num_skip_symb:3;
1558 		uint32_t	rsrvd1:3;
1559 		uint32_t	rep_tim_mod:5;
1560 		uint32_t	ack_nack_tim_mod:5;
1561 		uint32_t	fc_wdog_tim_mod:5;
1562 		uint32_t	rsrvd:3;
1563 #endif
1564 	} bits;
1565 } symbol_num_t;
1566 
1567 
1568 /*
1569  * Register: SymbTimRadmFlt1
1570  * Symbol Timer Register / RADM Filter Mask Register 1
1571  * Description: Symbol Timer / RADM Filter Mask 1
1572  * Fields:
1573  *     No masking errors while filtering
1574  */
1575 typedef union {
1576 	uint32_t value;
1577 	struct {
1578 #if defined(_BIG_ENDIAN)
1579 		uint32_t	mask_radm_flt:16;
1580 		uint32_t	dis_fc_wdog:1;
1581 		uint32_t	rsrvd:4;
1582 		uint32_t	skip_interval:11;
1583 #else
1584 		uint32_t	skip_interval:11;
1585 		uint32_t	rsrvd:4;
1586 		uint32_t	dis_fc_wdog:1;
1587 		uint32_t	mask_radm_flt:16;
1588 #endif
1589 	} bits;
1590 } symb_tim_radm_flt1_t;
1591 
1592 
1593 /*
1594  * Register: RadmFlt2
1595  * RADM Filter Mask Register 2
1596  * Description: RADM Filter Mask Register 2
1597  * Fields:
1598  *     [31:2] = Reserved [1]=0=Vendor MSG Type0 dropped & treated as
1599  *     UR, [0]=0=Vendor MSG Type1 silently dropped.
1600  */
1601 typedef union {
1602 	uint32_t value;
1603 	struct {
1604 #if defined(_BIG_ENDIAN)
1605 		uint32_t	mask_radm_flt:32;
1606 #else
1607 		uint32_t	mask_radm_flt:32;
1608 #endif
1609 	} bits;
1610 } radm_flt2_t;
1611 
1612 
1613 /*
1614  * Register: CascadeDebReg0
1615  * Cascade core (EP) Debug Register 0
1616  * Description: Debug Register 0 EP Core SII Interface bus :
1617  * cxplDebugInfo[31:0]
1618  * Fields:
1619  */
1620 typedef union {
1621 	uint32_t value;
1622 	struct {
1623 #if defined(_BIG_ENDIAN)
1624 		uint32_t	rmlh_ts_link_ctrl:4;
1625 		uint32_t	rmlh_ts_lane_num_is_k237:1;
1626 		uint32_t	rmlh_ts_link_num_is_k237:1;
1627 		uint32_t	rmlh_rcvd_idle_bit0:1;
1628 		uint32_t	rmlh_rcvd_idle_bit1:1;
1629 		uint32_t	mac_phy_txdata:16;
1630 		uint32_t	mac_phy_txdatak:2;
1631 		uint32_t	rsrvd:1;
1632 		uint32_t	xmlh_ltssm_state:5;
1633 #else
1634 		uint32_t	xmlh_ltssm_state:5;
1635 		uint32_t	rsrvd:1;
1636 		uint32_t	mac_phy_txdatak:2;
1637 		uint32_t	mac_phy_txdata:16;
1638 		uint32_t	rmlh_rcvd_idle_bit1:1;
1639 		uint32_t	rmlh_rcvd_idle_bit0:1;
1640 		uint32_t	rmlh_ts_link_num_is_k237:1;
1641 		uint32_t	rmlh_ts_lane_num_is_k237:1;
1642 		uint32_t	rmlh_ts_link_ctrl:4;
1643 #endif
1644 	} bits;
1645 } cascade_deb_reg0_t;
1646 
1647 
1648 /*
1649  * Register: CascadeDebReg1
1650  * Cascade Core (EP) Debug Register 1
1651  * Description: Debug Register 1 EP Core SII Interface bus :
1652  * cxplDebugInfo[63:32]
1653  * Fields:
1654  *     PCIe Link status. 0=down, 1=up
1655  */
1656 typedef union {
1657 	uint32_t value;
1658 	struct {
1659 #if defined(_BIG_ENDIAN)
1660 		uint32_t	xmlh_scrambler_disable:1;
1661 		uint32_t	xmlh_link_disable:1;
1662 		uint32_t	xmlh_link_in_training:1;
1663 		uint32_t	xmlh_rcvr_revrs_pol_en:1;
1664 		uint32_t	xmlh_training_rst_n:1;
1665 		uint32_t	rsrvd:4;
1666 		uint32_t	mac_phy_txdetectrx_loopback:1;
1667 		uint32_t	mac_phy_txelecidle_bit0:1;
1668 		uint32_t	mac_phy_txcompliance_bit0:1;
1669 		uint32_t	app_init_rst:1;
1670 		uint32_t	rsrvd1:3;
1671 		uint32_t	rmlh_rs_link_num:8;
1672 		uint32_t	rmlh_link_mode:3;
1673 		uint32_t	xmlh_link_up:1;
1674 		uint32_t	rmlh_inskip_rcv:1;
1675 		uint32_t	rmlh_ts1_rcvd:1;
1676 		uint32_t	rmlh_ts2_rcvd:1;
1677 		uint32_t	rmlh_rcvd_lane_rev:1;
1678 #else
1679 		uint32_t	rmlh_rcvd_lane_rev:1;
1680 		uint32_t	rmlh_ts2_rcvd:1;
1681 		uint32_t	rmlh_ts1_rcvd:1;
1682 		uint32_t	rmlh_inskip_rcv:1;
1683 		uint32_t	xmlh_link_up:1;
1684 		uint32_t	rmlh_link_mode:3;
1685 		uint32_t	rmlh_rs_link_num:8;
1686 		uint32_t	rsrvd1:3;
1687 		uint32_t	app_init_rst:1;
1688 		uint32_t	mac_phy_txcompliance_bit0:1;
1689 		uint32_t	mac_phy_txelecidle_bit0:1;
1690 		uint32_t	mac_phy_txdetectrx_loopback:1;
1691 		uint32_t	rsrvd:4;
1692 		uint32_t	xmlh_training_rst_n:1;
1693 		uint32_t	xmlh_rcvr_revrs_pol_en:1;
1694 		uint32_t	xmlh_link_in_training:1;
1695 		uint32_t	xmlh_link_disable:1;
1696 		uint32_t	xmlh_scrambler_disable:1;
1697 #endif
1698 	} bits;
1699 } cascade_deb_reg1_t;
1700 
1701 
1702 /*
1703  * Register: TxpFcCreditStat
1704  * Transmit Posted FC Credit Status
1705  * Description: Transmit Posted FC Credit Status
1706  * Fields:
1707  */
1708 typedef union {
1709 	uint32_t value;
1710 	struct {
1711 #if defined(_BIG_ENDIAN)
1712 		uint32_t	rsrvd:12;
1713 		uint32_t	txp_fc_hdr_credit_stat:8;
1714 		uint32_t	txp_fc_data_credit_stat:12;
1715 #else
1716 		uint32_t	txp_fc_data_credit_stat:12;
1717 		uint32_t	txp_fc_hdr_credit_stat:8;
1718 		uint32_t	rsrvd:12;
1719 #endif
1720 	} bits;
1721 } txp_fc_credit_stat_t;
1722 
1723 
1724 /*
1725  * Register: TxnpFcCreditStat
1726  * Transmit Non-Posted FC Credit Status
1727  * Description: Transmit Non-Posted FC Credit Status
1728  * Fields:
1729  */
1730 typedef union {
1731 	uint32_t value;
1732 	struct {
1733 #if defined(_BIG_ENDIAN)
1734 		uint32_t	rsrvd:12;
1735 		uint32_t	txnp_fc_hdr_credit_stat:8;
1736 		uint32_t	txnp_fc_data_credit_stat:12;
1737 #else
1738 		uint32_t	txnp_fc_data_credit_stat:12;
1739 		uint32_t	txnp_fc_hdr_credit_stat:8;
1740 		uint32_t	rsrvd:12;
1741 #endif
1742 	} bits;
1743 } txnp_fc_credit_stat_t;
1744 
1745 
1746 /*
1747  * Register: TxcplFcCreditStat
1748  * Transmit Completion FC Credit Status
1749  * Description: Transmit Completion FC Credit Status
1750  * Fields:
1751  */
1752 typedef union {
1753 	uint32_t value;
1754 	struct {
1755 #if defined(_BIG_ENDIAN)
1756 		uint32_t	rsrvd:12;
1757 		uint32_t	txcpl_fc_hdr_credit_stat:8;
1758 		uint32_t	txcpl_fc_data_credit_stat:12;
1759 #else
1760 		uint32_t	txcpl_fc_data_credit_stat:12;
1761 		uint32_t	txcpl_fc_hdr_credit_stat:8;
1762 		uint32_t	rsrvd:12;
1763 #endif
1764 	} bits;
1765 } txcpl_fc_credit_stat_t;
1766 
1767 
1768 /*
1769  * Register: QueueStat
1770  * Queue Status
1771  * Description: Queue Status
1772  * Fields:
1773  */
1774 typedef union {
1775 	uint32_t value;
1776 	struct {
1777 #if defined(_BIG_ENDIAN)
1778 		uint32_t	rsrvd:29;
1779 		uint32_t	rx_queue_not_empty:1;
1780 		uint32_t	tx_rbuf_not_empty:1;
1781 		uint32_t	tx_fc_credit_not_ret:1;
1782 #else
1783 		uint32_t	tx_fc_credit_not_ret:1;
1784 		uint32_t	tx_rbuf_not_empty:1;
1785 		uint32_t	rx_queue_not_empty:1;
1786 		uint32_t	rsrvd:29;
1787 #endif
1788 	} bits;
1789 } queue_stat_t;
1790 
1791 
1792 /*
1793  * Register: GbtDebug0
1794  * GBT Debug, Status register
1795  * Description: This register returns bits [31:0] of the PIPE core's
1796  * gbtDebug bus
1797  * Fields:
1798  *     [6] & [22] = rxclkO will always read 1'b0 [7] & [23] =
1799  *     tbcout10O will always read 1'b0
1800  * The value specified here is the Power On Reset value as given
1801  *     in spec. except for the clock bits which are hardwired to
1802  *     1'b0.
1803  * The gbtDebug[0:15] bus is provided for each lane as an output
1804  *     from the pcieGbtopWrapper.v module. These signals are not
1805  *     required for manufacturing test and may be left unconnected.
1806  *     The cw00041130PipeParam.vh bus width is the number of lanes
1807  *     multiplied by 16. lane0 is bits[15:0], lane1 is bits[31:16],
1808  *     lane2 is bits[47:32], lane3 is bits[63:48], lane4 is
1809  *     bits[79:64], lane5 is bits[95:80], lane6 is bits[111:96],
1810  *     lane7 is bits[127:112].
1811  * Refer to section 4.2.2.4, Gigablaze Debug Signals section.
1812  *     (pgs 4.27 - 4.28) in the following document :
1813  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
1814  *     cw000411TechMan.pdf
1815  *     lane0 is bits[15:0], which is gbtDebug0[15:0] lane1 is
1816  *     bits[31:16], which is gbtDebug0[31:16]
1817  *
1818  *     -------------------------------------------------------------------------
1819  *     Signal Bit Reset Description
1820  *     -------------------------------------------------------------------------
1821  *     gbtResetRbcI [16n+15] [15] 1 Reset receiver bit clock
1822  *     gbtResetTbc20I [16n+14] [14] 1 Reset transmit 20-bit clock
1823  *     gbtResetRI [16n+13] [13] 1 Reset receiver logic gbtResetTI
1824  *     [16n+12] [12] 1 Reset transmit logic reserved [16n+11:16n+8]
1825  *     [11:8] 0 reserved gbtTbcout10 [16n+7] [7] 1 transmit clock
1826  *     10-bit gbtRxclkO [16n+6] [6] 0 receiver PLL clock gbtRxpresO
1827  *     [16n+5] [5] 0 receiver detect present gbtRxpresvalidO [16n+4]
1828  *     [4] 0 gbtRxpresO is valid gbtRxlosO [16n+3] [3] 1 raw receiver
1829  *     loss-of-signal gbtPassnO [16n+2] [2] 1 GigaBlaze BIST pass
1830  *     active low reserved [16n+1] [1] 0 reserved reserved [16n] [0]
1831  *     0 reserved
1832  *     -------------------------------------------------------------------------
1833  */
1834 typedef union {
1835 	uint32_t value;
1836 	struct {
1837 #if defined(_BIG_ENDIAN)
1838 		uint32_t	data:32;
1839 #else
1840 		uint32_t	data:32;
1841 #endif
1842 	} bits;
1843 } gbt_debug0_t;
1844 
1845 
1846 /*
1847  * Register: GbtDebug1
1848  * GBT Debug, Status register
1849  * Description: This register returns bits [63:32] of the PIPE core's
1850  * gbtDebug bus
1851  * Fields:
1852  *     [6] & [22] = rxclkO will always read 1'b0 [7] & [23] =
1853  *     tbcout10O will always read 1'b0
1854  * The value specified here is the Power On Reset value as given
1855  *     in spec. except for the clock bits which are hardwired to
1856  *     1'b0.
1857  * The gbtDebug[0:15] bus is provided for each lane as an output
1858  *     from the pcieGbtopWrapper.v module. These signals are not
1859  *     required for manufacturing test and may be left unconnected.
1860  *     The cw00041130PipeParam.vh bus width is the number of lanes
1861  *     multiplied by 16.
1862  * Refer to section 4.2.2.4, Gigablaze Debug Signals section.
1863  *     (pgs 4.27 - 4.28) in the following document :
1864  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
1865  *     cw000411TechMan.pdf
1866  *     lane2 is bits[47:32], which is gbtDebug1[15:0] lane3 is
1867  *     bits[63:48], which is gbtDebug1[31:16]
1868  *
1869  *     -------------------------------------------------------------------------
1870  *     Signal Bit Reset Description
1871  *     -------------------------------------------------------------------------
1872  *     gbtResetRbcI [16n+15] [15] 1 Reset receiver bit clock
1873  *     gbtResetTbc20I [16n+14] [14] 1 Reset transmit 20-bit clock
1874  *     gbtResetRI [16n+13] [13] 1 Reset receiver logic gbtResetTI
1875  *     [16n+12] [12] 1 Reset transmit logic reserved [16n+11:16n+8]
1876  *     [11:8] 0 reserved gbtTbcout10 [16n+7] [7] 1 transmit clock
1877  *     10-bit gbtRxclkO [16n+6] [6] 0 receiver PLL clock gbtRxpresO
1878  *     [16n+5] [5] 0 receiver detect present gbtRxpresvalidO [16n+4]
1879  *     [4] 0 gbtRxpresO is valid gbtRxlosO [16n+3] [3] 1 raw receiver
1880  *     loss-of-signal gbtPassnO [16n+2] [2] 1 GigaBlaze BIST pass
1881  *     active low reserved [16n+1] [1] 0 reserved reserved [16n] [0]
1882  *     0 reserved
1883  *     -------------------------------------------------------------------------
1884  */
1885 typedef union {
1886 	uint32_t value;
1887 	struct {
1888 #if defined(_BIG_ENDIAN)
1889 		uint32_t	data:32;
1890 #else
1891 		uint32_t	data:32;
1892 #endif
1893 	} bits;
1894 } gbt_debug1_t;
1895 
1896 
1897 /*
1898  * Register: GbtDebug2
1899  * GBT Debug, Status register
1900  * Description: This register returns bits [95:64] of the PIPE core's
1901  * gbtDebug bus
1902  * Fields:
1903  *     [6] & [22] = rxclkO will always read 1'b0 [7] & [23] =
1904  *     tbcout10O will always read 1'b0
1905  * The value specified here is the Power On Reset value as given
1906  *     in spec. except for the clock bits which are hardwired to
1907  *     1'b0.
1908  * The gbtDebug[0:15] bus is provided for each lane as an output
1909  *     from the pcieGbtopWrapper.v module. These signals are not
1910  *     required for manufacturing test and may be left unconnected.
1911  *     The cw00041130PipeParam.vh bus width is the number of lanes
1912  *     multiplied by 16.
1913  * Refer to section 4.2.2.4, Gigablaze Debug Signals section.
1914  *     (pgs 4.27 - 4.28) in the following document :
1915  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
1916  *     cw000411TechMan.pdf
1917  *     lane4 is bits[79:64], which is gbtDebug2[15:0] lane5 is
1918  *     bits[95:80], which is gbtDebug2[31:16]
1919  *
1920  *     -------------------------------------------------------------------------
1921  *     Signal Bit Reset Description
1922  *     -------------------------------------------------------------------------
1923  *     gbtResetRbcI [16n+15] [15] 1 Reset receiver bit clock
1924  *     gbtResetTbc20I [16n+14] [14] 1 Reset transmit 20-bit clock
1925  *     gbtResetRI [16n+13] [13] 1 Reset receiver logic gbtResetTI
1926  *     [16n+12] [12] 1 Reset transmit logic reserved [16n+11:16n+8]
1927  *     [11:8] 0 reserved gbtTbcout10 [16n+7] [7] 1 transmit clock
1928  *     10-bit gbtRxclkO [16n+6] [6] 0 receiver PLL clock gbtRxpresO
1929  *     [16n+5] [5] 0 receiver detect present gbtRxpresvalidO [16n+4]
1930  *     [4] 0 gbtRxpresO is valid gbtRxlosO [16n+3] [3] 1 raw receiver
1931  *     loss-of-signal gbtPassnO [16n+2] [2] 1 GigaBlaze BIST pass
1932  *     active low reserved [16n+1] [1] 0 reserved reserved [16n] [0]
1933  *     0 reserved
1934  *     -------------------------------------------------------------------------
1935  */
1936 typedef union {
1937 	uint32_t value;
1938 	struct {
1939 #if defined(_BIG_ENDIAN)
1940 		uint32_t	data:32;
1941 #else
1942 		uint32_t	data:32;
1943 #endif
1944 	} bits;
1945 } gbt_debug2_t;
1946 
1947 
1948 /*
1949  * Register: GbtDebug3
1950  * GBT Debug, Status register
1951  * Description: This register returns bits [127:96] of the PIPE
1952  * core's gbtDebug bus
1953  * Fields:
1954  *     [6] & [22] = rxclkO will always read 1'b0 [7] & [23] =
1955  *     tbcout10O will always read 1'b0
1956  * The value specified here is the Power On Reset value as given
1957  *     in spec. except for the clock bits which are hardwired to
1958  *     1'b0.
1959  * The gbtDebug[0:15] bus is provided for each lane as an output
1960  *     from the pcieGbtopWrapper.v module. These signals are not
1961  *     required for manufacturing test and may be left unconnected.
1962  *     The cw00041130PipeParam.vh bus width is the number of lanes
1963  *     multiplied by 16.
1964  * Refer to section 4.2.2.4, Gigablaze Debug Signals section.
1965  *     (pgs 4.27 - 4.28) in the following document :
1966  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
1967  *     cw000411TechMan.pdf
1968  *     lane6 is bits[111:96], which is gbtDebug3[15:0] lane7 is
1969  *     bits[127:112], which is gbtDebug3[31:16]
1970  *
1971  *     -------------------------------------------------------------------------
1972  *     Signal Bit Reset Description
1973  *     -------------------------------------------------------------------------
1974  *     gbtResetRbcI [16n+15] [15] 1 Reset receiver bit clock
1975  *     gbtResetTbc20I [16n+14] [14] 1 Reset transmit 20-bit clock
1976  *     gbtResetRI [16n+13] [13] 1 Reset receiver logic gbtResetTI
1977  *     [16n+12] [12] 1 Reset transmit logic reserved [16n+11:16n+8]
1978  *     [11:8] 0 reserved gbtTbcout10 [16n+7] [7] 1 transmit clock
1979  *     10-bit gbtRxclkO [16n+6] [6] 0 receiver PLL clock gbtRxpresO
1980  *     [16n+5] [5] 0 receiver detect present gbtRxpresvalidO [16n+4]
1981  *     [4] 0 gbtRxpresO is valid gbtRxlosO [16n+3] [3] 1 raw receiver
1982  *     loss-of-signal gbtPassnO [16n+2] [2] 1 GigaBlaze BIST pass
1983  *     active low reserved [16n+1] [1] 0 reserved reserved [16n] [0]
1984  *     0 reserved
1985  *     -------------------------------------------------------------------------
1986  */
1987 typedef union {
1988 	uint32_t value;
1989 	struct {
1990 #if defined(_BIG_ENDIAN)
1991 		uint32_t	data:32;
1992 #else
1993 		uint32_t	data:32;
1994 #endif
1995 	} bits;
1996 } gbt_debug3_t;
1997 
1998 
1999 /*
2000  * Register: PipeDebug0
2001  * PIPE Debug, status register
2002  * Description: This register returns bits [31:0] of the PIPE core's
2003  * gbtDebug bus
2004  * Fields:
2005  *     The value specified here is the Power On Reset value as given
2006  *     in spec.
2007  * This 16-bit debug bus reports operating conditions for the
2008  *     PIPE. The pipeDebug[0:15] bus is provided for each lane. lane0
2009  *     is bits[15:0], lane1 is bits[31:16], lane2 is bits[47:32],
2010  *     lane3 is bits[63:48], lane4 is bits[79:64], lane5 is
2011  *     bits[95:80], lane6 is bits[111:96], lane7 is bits[127:112].
2012  * Refer to section 4.2.1.5 Single-Lane PIPE Debug Signals in
2013  *     the following document :
2014  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
2015  *     cw000411TechMan.pdf
2016  *     lane0 is bit[15:0], which is pipeDebug0[15:0] lane1 is
2017  *     bit[31:16], which is pipeDebug0[31:16]
2018  *
2019  *     -------------------------------------------------------------------------
2020  *     pipeDebug Signal or Condition Description Reset
2021  *     -------------------------------------------------------------------------
2022  *     [15] efifoOverflow or EFIFO overflow or 0 efifoUnderflow EFIFO
2023  *     underflow occurred
2024  * [14] skipInsert or EFIFO skip inserted or 0 skipDelete
2025  *     deleted 0
2026  * [13] fifordData[12] == Skip flag read by EFIFO. 0 skipFlag
2027  *     Used with skipcharflag to verify EFIFO depth.
2028  * [12] skipcharflag Skip flag written by EFIFO 0
2029  * [11:8] efifoDepth[3:0] Indicates EFIFO depth 0000
2030  * [7] efifoEios Detected EFIFO 0 electrical-idle ordered-set
2031  *     output
2032  * [6] efifoBytesync EFIFO output byte 0 synchronization
2033  * [5] rxinvalid 8b/10b error or 0 or code violation
2034  * [4] rxinitdone Receiver bit-init done. 0 Synchronous with
2035  *     pipeClk.
2036  * [3] txinitdone Transmitter-bit init done. 0 Synchronous with
2037  *     pipeClk.
2038  * [2] filteredrxlos Filtered loss of signal used 1 to generate
2039  *     p2lRxelectidle. Synchronous with pipeClk.
2040  * [1] rxdetectInt Receiver detected 0
2041  * [0] pipeMasterDoneOut Receiver detection valid 0
2042  *
2043  */
2044 typedef union {
2045 	uint32_t value;
2046 	struct {
2047 #if defined(_BIG_ENDIAN)
2048 		uint32_t	data:32;
2049 #else
2050 		uint32_t	data:32;
2051 #endif
2052 	} bits;
2053 } pipe_debug0_t;
2054 
2055 
2056 /*
2057  * Register: PipeDebug1
2058  * PIPE Debug, status register
2059  * Description: This register returns bits [63:32] of the PIPE core's
2060  * gbtDebug bus
2061  * Fields:
2062  *     The value specified here is the Power On Reset value as given
2063  *     in spec.
2064  * This 16-bit debug bus reports operating conditions for the
2065  *     PIPE. The pipeDebug[0:15] bus is provided for each lane. lane0
2066  *     is bits[15:0], lane1 is bits[31:16], lane2 is bits[47:32],
2067  *     lane3 is bits[63:48], lane4 is bits[79:64], lane5 is
2068  *     bits[95:80], lane6 is bits[111:96], lane7 is bits[127:112].
2069  * Refer to section 4.2.1.5 Single-Lane PIPE Debug Signals in
2070  *     the following document :
2071  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
2072  *     cw000411TechMan.pdf
2073  * lane2 is bits[47:32], which is pipeDebug1[15:0] lane3 is
2074  *     bits[63:48], which is pipeDebug1[31:16]
2075  *
2076  *     -------------------------------------------------------------------------
2077  *     pipeDebug Signal or Condition Description Reset
2078  *     -------------------------------------------------------------------------
2079  *     [15] efifoOverflow or EFIFO overflow or 0 efifoUnderflow EFIFO
2080  *     underflow occurred
2081  * [14] skipInsert or EFIFO skip inserted or 0 skipDelete
2082  *     deleted 0
2083  * [13] fifordData[12] == Skip flag read by EFIFO. 0 skipFlag
2084  *     Used with skipcharflag to verify EFIFO depth.
2085  * [12] skipcharflag Skip flag written by EFIFO 0
2086  * [11:8] efifoDepth[3:0] Indicates EFIFO depth 0000
2087  * [7] efifoEios Detected EFIFO 0 electrical-idle ordered-set
2088  *     output
2089  * [6] efifoBytesync EFIFO output byte 0 synchronization
2090  * [5] rxinvalid 8b/10b error or 0 or code violation
2091  * [4] rxinitdone Receiver bit-init done. 0 Synchronous with
2092  *     pipeClk.
2093  * [3] txinitdone Transmitter-bit init done. 0 Synchronous with
2094  *     pipeClk.
2095  * [2] filteredrxlos Filtered loss of signal used 1 to generate
2096  *     p2lRxelectidle. Synchronous with pipeClk.
2097  * [1] rxdetectInt Receiver detected 0
2098  * [0] pipeMasterDoneOut Receiver detection valid 0
2099  *
2100  */
2101 typedef union {
2102 	uint32_t value;
2103 	struct {
2104 #if defined(_BIG_ENDIAN)
2105 		uint32_t	data:32;
2106 #else
2107 		uint32_t	data:32;
2108 #endif
2109 	} bits;
2110 } pipe_debug1_t;
2111 
2112 
2113 /*
2114  * Register: PipeDebug2
2115  * PIPE Debug, status register
2116  *     The value specified here is the Power On Reset value as given
2117  *     in spec.
2118  * This 16-bit debug bus reports operating conditions for the
2119  *     PIPE. The pipeDebug[0:15] bus is provided for each lane. lane0
2120  *     is bits[15:0], lane1 is bits[31:16], lane2 is bits[47:32],
2121  *     lane3 is bits[63:48], lane4 is bits[79:64], lane5 is
2122  *     bits[95:80], lane6 is bits[111:96], lane7 is bits[127:112].
2123  * Refer to section 4.2.1.5 Single-Lane PIPE Debug Signals in
2124  *     the following document :
2125  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
2126  *     cw000411TechMan.pdf
2127  * lane4 is bits[79:64], which is pipeDebug2[15:0] lane5 is
2128  *     bits[95:80], which is pipeDebug2[31:16]
2129  *
2130  *     -------------------------------------------------------------------------
2131  *     pipeDebug Signal or Condition Description Reset
2132  *     -------------------------------------------------------------------------
2133  *     [15] efifoOverflow or EFIFO overflow or 0 efifoUnderflow EFIFO
2134  *     underflow occurred
2135  * [14] skipInsert or EFIFO skip inserted or 0 skipDelete
2136  *     deleted 0
2137  * [13] fifordData[12] == Skip flag read by EFIFO. 0 skipFlag
2138  *     Used with skipcharflag to verify EFIFO depth.
2139  * [12] skipcharflag Skip flag written by EFIFO 0
2140  * [11:8] efifoDepth[3:0] Indicates EFIFO depth 0000
2141  * [7] efifoEios Detected EFIFO 0 electrical-idle ordered-set
2142  *     output
2143  * [6] efifoBytesync EFIFO output byte 0 synchronization
2144  * [5] rxinvalid 8b/10b error or 0 or code violation
2145  * [4] rxinitdone Receiver bit-init done. 0 Synchronous with
2146  *     pipeClk.
2147  * [3] txinitdone Transmitter-bit init done. 0 Synchronous with
2148  *     pipeClk.
2149  * [2] filteredrxlos Filtered loss of signal used 1 to generate
2150  *     p2lRxelectidle. Synchronous with pipeClk.
2151  * [1] rxdetectInt Receiver detected 0
2152  * [0] pipeMasterDoneOut Receiver detection valid 0
2153  *
2154  */
2155 typedef union {
2156 	uint32_t value;
2157 	struct {
2158 #if defined(_BIG_ENDIAN)
2159 		uint32_t	data:32;
2160 #else
2161 		uint32_t	data:32;
2162 #endif
2163 	} bits;
2164 } pipe_debug2_t;
2165 
2166 
2167 /*
2168  * Register: PipeDebug3
2169  * PIPE Debug, status register
2170  * Description: This register returns bits [127:96] of the PIPE
2171  * core's gbtDebug bus
2172  * Fields:
2173  *     The value specified here is the Power On Reset value as given
2174  *     in spec.
2175  * This 16-bit debug bus reports operating conditions for the
2176  *     PIPE. The pipeDebug[0:15] bus is provided for each lane. lane0
2177  *     is bits[15:0], lane1 is bits[31:16], lane2 is bits[47:32],
2178  *     lane3 is bits[63:48], lane4 is bits[79:64], lane5 is
2179  *     bits[95:80], lane6 is bits[111:96], lane7 is bits[127:112].
2180  * Refer to section 4.2.1.5 Single-Lane PIPE Debug Signals in
2181  *     the following document :
2182  *     /home/cadtools/cores/lsi/cw000411/cw00041131/prod/docs/manuals/
2183  *     cw000411TechMan.pdf
2184  * lane6 is bits[111:96], which is pipeDebug3[15:0] lane7 is
2185  *     bits[127:112], which is pipeDebug3[31:16]
2186  *
2187  *     -------------------------------------------------------------------------
2188  *     pipeDebug Signal or Condition Description Reset
2189  *     -------------------------------------------------------------------------
2190  *     [15] efifoOverflow or EFIFO overflow or 0 efifoUnderflow EFIFO
2191  *     underflow occurred
2192  * [14] skipInsert or EFIFO skip inserted or 0 skipDelete
2193  *     deleted 0
2194  * [13] fifordData[12] == Skip flag read by EFIFO. 0 skipFlag
2195  *     Used with skipcharflag to verify EFIFO depth.
2196  * [12] skipcharflag Skip flag written by EFIFO 0
2197  * [11:8] efifoDepth[3:0] Indicates EFIFO depth 0000
2198  * [7] efifoEios Detected EFIFO 0 electrical-idle ordered-set
2199  *     output
2200  * [6] efifoBytesync EFIFO output byte 0 synchronization
2201  * [5] rxinvalid 8b/10b error or 0 or code violation
2202  * [4] rxinitdone Receiver bit-init done. 0 Synchronous with
2203  *     pipeClk.
2204  * [3] txinitdone Transmitter-bit init done. 0 Synchronous with
2205  *     pipeClk.
2206  * [2] filteredrxlos Filtered loss of signal used 1 to generate
2207  *     p2lRxelectidle. Synchronous with pipeClk.
2208  * [1] rxdetectInt Receiver detected 0
2209  * [0] pipeMasterDoneOut Receiver detection valid 0
2210  *
2211  */
2212 typedef union {
2213 	uint32_t value;
2214 	struct {
2215 #if defined(_BIG_ENDIAN)
2216 		uint32_t	data:32;
2217 #else
2218 		uint32_t	data:32;
2219 #endif
2220 	} bits;
2221 } pipe_debug3_t;
2222 
2223 
2224 /*
2225  * Register: PcieEnhCapHdr
2226  * PCIE Enhanced Capability Header
2227  * Description: PCIE Enhanced Capability Header
2228  * Fields:
2229  *     Next Capability Offset (END, no more)
2230  *     Capability Version
2231  *     PCI Express Enhanced Capability ID (0x1 = Advanced Error
2232  *     Reporting)
2233  */
2234 typedef union {
2235 	uint32_t value;
2236 	struct {
2237 #if defined(_BIG_ENDIAN)
2238 		uint32_t	nxt_cap_offset:12;
2239 		uint32_t	cap_ver:4;
2240 		uint32_t	pcie_enh_cap_id:16;
2241 #else
2242 		uint32_t	pcie_enh_cap_id:16;
2243 		uint32_t	cap_ver:4;
2244 		uint32_t	nxt_cap_offset:12;
2245 #endif
2246 	} bits;
2247 } pcie_enh_cap_hdr_t;
2248 
2249 
2250 /*
2251  * Register: UncErrStat
2252  * Uncorrectable Error Status
2253  * Description: Uncorrectable Error Status
2254  * Fields:
2255  *     Unsupported Request Error
2256  *     ECRC Error
2257  *     Malformed TLP
2258  *     Reciever Overflow
2259  *     Unexpected Completion
2260  *     Completion Abort
2261  *     Completion Timeout
2262  *     Flow Control Protocol Error
2263  *     Poisoned TLP
2264  *     Introduced in PCIe 1.1 specification.
2265  *     Data Link Protocol Error
2266  */
2267 typedef union {
2268 	uint32_t value;
2269 	struct {
2270 #if defined(_BIG_ENDIAN)
2271 		uint32_t	rsrvd:11;
2272 		uint32_t	unsup_req_err:1;
2273 		uint32_t	ecrc_err:1;
2274 		uint32_t	bad_tlp:1;
2275 		uint32_t	rcv_ovfl:1;
2276 		uint32_t	unexp_cpl:1;
2277 		uint32_t	cpl_abrt:1;
2278 		uint32_t	cpl_tmout:1;
2279 		uint32_t	fc_err:1;
2280 		uint32_t	psn_tlp:1;
2281 		uint32_t	rsrvd1:6;
2282 		uint32_t	surprise_down_err:1;
2283 		uint32_t	dlp_err:1;
2284 		uint32_t	rsrvd2:4;
2285 #else
2286 		uint32_t	rsrvd2:4;
2287 		uint32_t	dlp_err:1;
2288 		uint32_t	surprise_down_err:1;
2289 		uint32_t	rsrvd1:6;
2290 		uint32_t	psn_tlp:1;
2291 		uint32_t	fc_err:1;
2292 		uint32_t	cpl_tmout:1;
2293 		uint32_t	cpl_abrt:1;
2294 		uint32_t	unexp_cpl:1;
2295 		uint32_t	rcv_ovfl:1;
2296 		uint32_t	bad_tlp:1;
2297 		uint32_t	ecrc_err:1;
2298 		uint32_t	unsup_req_err:1;
2299 		uint32_t	rsrvd:11;
2300 #endif
2301 	} bits;
2302 } unc_err_stat_t;
2303 
2304 
2305 /*
2306  * Register: UncErrMask
2307  * Uncorrectable Error Mask
2308  * Description: Uncorrectable Error Mask
2309  * Fields:
2310  *     Unsupported Request Error
2311  *     ECRC Error
2312  *     Malformed TLP
2313  *     Reciever Overflow
2314  *     Unexpected Completion
2315  *     Completion Abort
2316  *     Completion Timeout
2317  *     Flow Control Protocol Error
2318  *     Poisoned TLP
2319  *     Introduced in PCIe 1.1
2320  *     Data Link Protocol Error
2321  */
2322 typedef union {
2323 	uint32_t value;
2324 	struct {
2325 #if defined(_BIG_ENDIAN)
2326 		uint32_t	rsrvd:11;
2327 		uint32_t	unsup_req_err:1;
2328 		uint32_t	ecrc_err:1;
2329 		uint32_t	bad_tlp:1;
2330 		uint32_t	rcv_ovfl:1;
2331 		uint32_t	unexp_cpl:1;
2332 		uint32_t	cpl_abrt:1;
2333 		uint32_t	cpl_tmout:1;
2334 		uint32_t	fc_err:1;
2335 		uint32_t	psn_tlp:1;
2336 		uint32_t	rsrvd1:6;
2337 		uint32_t	surprise_down_err:1;
2338 		uint32_t	dlp_err:1;
2339 		uint32_t	rsrvd2:4;
2340 #else
2341 		uint32_t	rsrvd2:4;
2342 		uint32_t	dlp_err:1;
2343 		uint32_t	surprise_down_err:1;
2344 		uint32_t	rsrvd1:6;
2345 		uint32_t	psn_tlp:1;
2346 		uint32_t	fc_err:1;
2347 		uint32_t	cpl_tmout:1;
2348 		uint32_t	cpl_abrt:1;
2349 		uint32_t	unexp_cpl:1;
2350 		uint32_t	rcv_ovfl:1;
2351 		uint32_t	bad_tlp:1;
2352 		uint32_t	ecrc_err:1;
2353 		uint32_t	unsup_req_err:1;
2354 		uint32_t	rsrvd:11;
2355 #endif
2356 	} bits;
2357 } unc_err_mask_t;
2358 
2359 
2360 /*
2361  * Register: UncErrSvrty
2362  * Uncorrectable Error Severity
2363  * Description: Uncorrectable Error Severity
2364  * Fields:
2365  *     Unsupported Request Error
2366  *     ECRC Error
2367  *     Malformed TLP
2368  *     Reciever Overflow
2369  *     Unexpected Completion
2370  *     Completion Abort
2371  *     Completion Timeout
2372  *     Flow Control Protocol Error
2373  *     Poisoned TLP
2374  *     Introduced in PCIe 1.1 specification. Not supported; use PCIe
2375  *     default.
2376  *     Data Link Protocol Error
2377  */
2378 typedef union {
2379 	uint32_t value;
2380 	struct {
2381 #if defined(_BIG_ENDIAN)
2382 		uint32_t	rsrvd:11;
2383 		uint32_t	unsup_req_err:1;
2384 		uint32_t	ecrc_err:1;
2385 		uint32_t	bad_tlp:1;
2386 		uint32_t	rcv_ovfl:1;
2387 		uint32_t	unexp_cpl:1;
2388 		uint32_t	cpl_abrt:1;
2389 		uint32_t	cpl_tmout:1;
2390 		uint32_t	fc_err:1;
2391 		uint32_t	psn_tlp:1;
2392 		uint32_t	rsrvd1:6;
2393 		uint32_t	surprise_down_err:1;
2394 		uint32_t	dlp_err:1;
2395 		uint32_t	rsrvd2:4;
2396 #else
2397 		uint32_t	rsrvd2:4;
2398 		uint32_t	dlp_err:1;
2399 		uint32_t	surprise_down_err:1;
2400 		uint32_t	rsrvd1:6;
2401 		uint32_t	psn_tlp:1;
2402 		uint32_t	fc_err:1;
2403 		uint32_t	cpl_tmout:1;
2404 		uint32_t	cpl_abrt:1;
2405 		uint32_t	unexp_cpl:1;
2406 		uint32_t	rcv_ovfl:1;
2407 		uint32_t	bad_tlp:1;
2408 		uint32_t	ecrc_err:1;
2409 		uint32_t	unsup_req_err:1;
2410 		uint32_t	rsrvd:11;
2411 #endif
2412 	} bits;
2413 } unc_err_svrty_t;
2414 
2415 
2416 /*
2417  * Register: CorrErrStat
2418  * Correctable Error Status
2419  * Description: Correctable Error Status
2420  * Fields:
2421  *     Advisory Non-Fatal Error Introduced in PCIe 1.1 specification.
2422  *     Reply Timer Timeout
2423  *     Replay Number Rollover
2424  *     Bad DLLP
2425  *     Bad TLP
2426  *     Receive Error
2427  */
2428 typedef union {
2429 	uint32_t value;
2430 	struct {
2431 #if defined(_BIG_ENDIAN)
2432 		uint32_t	rsrvd:18;
2433 		uint32_t	adv_nf_err:1;
2434 		uint32_t	rply_tmr_tmout:1;
2435 		uint32_t	rsrvd1:3;
2436 		uint32_t	rply_rlovr:1;
2437 		uint32_t	bad_dllp:1;
2438 		uint32_t	bad_tlp:1;
2439 		uint32_t	rsrvd2:5;
2440 		uint32_t	rcv_err:1;
2441 #else
2442 		uint32_t	rcv_err:1;
2443 		uint32_t	rsrvd2:5;
2444 		uint32_t	bad_tlp:1;
2445 		uint32_t	bad_dllp:1;
2446 		uint32_t	rply_rlovr:1;
2447 		uint32_t	rsrvd1:3;
2448 		uint32_t	rply_tmr_tmout:1;
2449 		uint32_t	adv_nf_err:1;
2450 		uint32_t	rsrvd:18;
2451 #endif
2452 	} bits;
2453 } corr_err_stat_t;
2454 
2455 
2456 /*
2457  * Register: CorrErrMask
2458  * Correctable Error Mask
2459  * Description: Correctable Error Mask
2460  * Fields:
2461  *     Advisory Non Fatal Error Mask
2462  *     Reply Timer Timeout
2463  *     Replay Number Rollover
2464  *     Bad DLLP
2465  *     Bad TLP
2466  *     Receive Error
2467  */
2468 typedef union {
2469 	uint32_t value;
2470 	struct {
2471 #if defined(_BIG_ENDIAN)
2472 		uint32_t	rsrvd:18;
2473 		uint32_t	adv_nf_err_mask:1;
2474 		uint32_t	rply_tmr_tmout:1;
2475 		uint32_t	rsrvd1:3;
2476 		uint32_t	rply_rlovr:1;
2477 		uint32_t	bad_dllp:1;
2478 		uint32_t	bad_tlp:1;
2479 		uint32_t	rsrvd2:5;
2480 		uint32_t	rcv_err:1;
2481 #else
2482 		uint32_t	rcv_err:1;
2483 		uint32_t	rsrvd2:5;
2484 		uint32_t	bad_tlp:1;
2485 		uint32_t	bad_dllp:1;
2486 		uint32_t	rply_rlovr:1;
2487 		uint32_t	rsrvd1:3;
2488 		uint32_t	rply_tmr_tmout:1;
2489 		uint32_t	adv_nf_err_mask:1;
2490 		uint32_t	rsrvd:18;
2491 #endif
2492 	} bits;
2493 } corr_err_mask_t;
2494 
2495 
2496 /*
2497  * Register: AdvCapCtrl
2498  * Advanced Capability and Control
2499  * Description: Advanced Capability and Control
2500  * Fields:
2501  *     ECRC Check Enable
2502  *     ECRC Check Capable
2503  *     ECRC Generation Enable
2504  *     ECRC Generation Capability
2505  *     First Error Pointer
2506  */
2507 typedef union {
2508 	uint32_t value;
2509 	struct {
2510 #if defined(_BIG_ENDIAN)
2511 		uint32_t	rsrvd:23;
2512 		uint32_t	ecrc_chk_en:1;
2513 		uint32_t	ecrc_chk_cap:1;
2514 		uint32_t	ecrc_gen_en:1;
2515 		uint32_t	ecrc_gen_cap:1;
2516 		uint32_t	st_err_ptr:5;
2517 #else
2518 		uint32_t	st_err_ptr:5;
2519 		uint32_t	ecrc_gen_cap:1;
2520 		uint32_t	ecrc_gen_en:1;
2521 		uint32_t	ecrc_chk_cap:1;
2522 		uint32_t	ecrc_chk_en:1;
2523 		uint32_t	rsrvd:23;
2524 #endif
2525 	} bits;
2526 } adv_cap_ctrl_t;
2527 
2528 
2529 /*
2530  * Register: HdrLog0
2531  * Header Log0
2532  * Description: Header Log0
2533  * Fields:
2534  *     First DW of TLP header with error
2535  */
2536 typedef union {
2537 	uint32_t value;
2538 	struct {
2539 #if defined(_BIG_ENDIAN)
2540 		uint32_t	data:32;
2541 #else
2542 		uint32_t	data:32;
2543 #endif
2544 	} bits;
2545 } hdr_log0_t;
2546 
2547 
2548 /*
2549  * Register: HdrLog1
2550  * Header Log1
2551  * Description: Header Log1
2552  * Fields:
2553  *     Second DW of TLP header with error
2554  */
2555 typedef union {
2556 	uint32_t value;
2557 	struct {
2558 #if defined(_BIG_ENDIAN)
2559 		uint32_t	data:32;
2560 #else
2561 		uint32_t	data:32;
2562 #endif
2563 	} bits;
2564 } hdr_log1_t;
2565 
2566 
2567 /*
2568  * Register: HdrLog2
2569  * Header Log2
2570  * Description: Header Log2
2571  * Fields:
2572  *     Third DW of TLP header with error
2573  */
2574 typedef union {
2575 	uint32_t value;
2576 	struct {
2577 #if defined(_BIG_ENDIAN)
2578 		uint32_t	data:32;
2579 #else
2580 		uint32_t	data:32;
2581 #endif
2582 	} bits;
2583 } hdr_log2_t;
2584 
2585 
2586 /*
2587  * Register: HdrLog3
2588  * Header Log3
2589  * Description: Header Log3
2590  * Fields:
2591  *     Fourth DW of TLP header with error
2592  */
2593 typedef union {
2594 	uint32_t value;
2595 	struct {
2596 #if defined(_BIG_ENDIAN)
2597 		uint32_t	data:32;
2598 #else
2599 		uint32_t	data:32;
2600 #endif
2601 	} bits;
2602 } hdr_log3_t;
2603 
2604 
2605 /*
2606  * Register: PipeRxTxControl
2607  * Pipe Rx/Tx Control
2608  *     00 : ewrap : Enable wrapback test mode 01 : padLoopback :
2609  *     Enable Pad Serial Loopback test mode 10 : revLoopback : Enable
2610  *     Reverse Loopback test mode 11 : efifoLoopback : Enable PCI
2611  *     Express Slave loop back
2612  *     100 : Clock generator test x10 : Vil/Vih test x01 : Vih/Vil
2613  *     test x11 : No-error test. A full test of the transceiver 111 :
2614  *     Forced-error test. A full test of the transceiver with forced
2615  *     errors
2616  *     1 : selects 20-bit mode 0 : selects 10-bit mode
2617  *     1 : selects Tx 20-bit fifo mode
2618  *     00 : 52 us (470 cycles) 01 : 53 us (720 cycles) 10 : 54 us
2619  *     (970 cycles) 11 : 55 us (1220 cycles)
2620  *     1 : selects 20-bit mode 0 : selects 10-bit mode
2621  *     1 : Enable receiver reference clocks
2622  */
2623 typedef union {
2624 	uint32_t value;
2625 	struct {
2626 #if defined(_BIG_ENDIAN)
2627 		uint32_t	rsrvd:1;
2628 		uint32_t	loopback:1;
2629 		uint32_t	loopback_mode_sel:2;
2630 		uint32_t	rsrvd1:1;
2631 		uint32_t	en_bist:3;
2632 		uint32_t	tdws20:1;
2633 		uint32_t	tdenfifo:1;
2634 		uint32_t	rxpreswin:2;
2635 		uint32_t	rdws20:1;
2636 		uint32_t	enstretch:1;
2637 		uint32_t	rsrvd2:18;
2638 #else
2639 		uint32_t	rsrvd2:18;
2640 		uint32_t	enstretch:1;
2641 		uint32_t	rdws20:1;
2642 		uint32_t	rxpreswin:2;
2643 		uint32_t	tdenfifo:1;
2644 		uint32_t	tdws20:1;
2645 		uint32_t	en_bist:3;
2646 		uint32_t	rsrvd1:1;
2647 		uint32_t	loopback_mode_sel:2;
2648 		uint32_t	loopback:1;
2649 		uint32_t	rsrvd:1;
2650 #endif
2651 	} bits;
2652 } pipe_rx_tx_control_t;
2653 
2654 
2655 /*
2656  * Register: PipeRxTxStatus
2657  * Pipe Rx/Tx Status
2658  */
2659 typedef union {
2660 	uint32_t value;
2661 	struct {
2662 #if defined(_BIG_ENDIAN)
2663 		uint32_t	rsrvd:32;
2664 #else
2665 		uint32_t	rsrvd:32;
2666 #endif
2667 	} bits;
2668 } pipe_rx_tx_status_t;
2669 
2670 
2671 /*
2672  * Register: PipeRxTxPwrCntl
2673  * Pipe Rx/Tx Power Control
2674  *     1 : power down termination trimming circuit 0 : normal
2675  *     operation
2676  *     Power down PECL Clock buffer 1 : when a bit is 1, power down
2677  *     associated clock buffer cell 0 : normal operation
2678  *     Power down Transmit PLL 1 : when a bit is 1, power down
2679  *     associated Tx PLL circuit 0 : normal operation
2680  *     Power down Differential O/P Clock buffer 1 : when a bit is 1,
2681  *     power down associated differntial clock buffer that drives
2682  *     gbtClkoutN/p 0 : normal operation
2683  *     Power down Transmitter Analog section 1 : when a bit is 1,
2684  *     power down analog section of the associated Transmitter and
2685  *     the Tx buffer 0 : normal operation
2686  *     Power down RxLOS 1 : when a bit is 1, it powers down the Rx
2687  *     LOS circuitry for the associated serdes lanes 0 : normal
2688  *     operation
2689  *     Power down Receiver Analog section 1 : when a bit is 1, power
2690  *     down analog section of the associated Receiver and the Tx
2691  *     buffer 0 : normal operation
2692  */
2693 typedef union {
2694 	uint32_t value;
2695 	struct {
2696 #if defined(_BIG_ENDIAN)
2697 		uint32_t	rsrvd:1;
2698 		uint32_t	pdrtrim:1;
2699 		uint32_t	pdownpecl:2;
2700 		uint32_t	pdownpll:2;
2701 		uint32_t	pdclkout:2;
2702 		uint32_t	pdownt:8;
2703 		uint32_t	pdrxlos:8;
2704 		uint32_t	pdownr:8;
2705 #else
2706 		uint32_t	pdownr:8;
2707 		uint32_t	pdrxlos:8;
2708 		uint32_t	pdownt:8;
2709 		uint32_t	pdclkout:2;
2710 		uint32_t	pdownpll:2;
2711 		uint32_t	pdownpecl:2;
2712 		uint32_t	pdrtrim:1;
2713 		uint32_t	rsrvd:1;
2714 #endif
2715 	} bits;
2716 } pipe_rx_tx_pwr_cntl_t;
2717 
2718 
2719 /*
2720  * Register: PipeRxTxParam
2721  * Pipe Rx/Tx Parameter
2722  *     Tx Driver Emphasis
2723  *     Serial output Slew Rate Control
2724  *     Tx Voltage Mux control
2725  *     Tx Voltage Pulse control
2726  *     Output Swing setting
2727  *     Transmitter Clock generator pole adjust
2728  *     Transmitter Clock generator zero adjust
2729  *     Receiver Clock generator pole adjust
2730  *     Receiver Clock generator zero adjust
2731  *     Bias Control for factory testing and debugging
2732  *     Receiver LOS Threshold adjustment. This value is determined by
2733  *     LSI.
2734  *     Receiver Input Equalizer control
2735  */
2736 typedef union {
2737 	uint32_t value;
2738 	struct {
2739 #if defined(_BIG_ENDIAN)
2740 		uint32_t	rsrvd:1;
2741 		uint32_t	emph:3;
2742 		uint32_t	rsrvd1:1;
2743 		uint32_t	risefall:3;
2744 		uint32_t	vmuxlo:2;
2745 		uint32_t	vpulselo:2;
2746 		uint32_t	vtxlo:4;
2747 		uint32_t	tp:2;
2748 		uint32_t	tz:2;
2749 		uint32_t	rp:2;
2750 		uint32_t	rz:2;
2751 		uint32_t	biascntl:1;
2752 		uint32_t	losadj:3;
2753 		uint32_t	rxeq:4;
2754 #else
2755 		uint32_t	rxeq:4;
2756 		uint32_t	losadj:3;
2757 		uint32_t	biascntl:1;
2758 		uint32_t	rz:2;
2759 		uint32_t	rp:2;
2760 		uint32_t	tz:2;
2761 		uint32_t	tp:2;
2762 		uint32_t	vtxlo:4;
2763 		uint32_t	vpulselo:2;
2764 		uint32_t	vmuxlo:2;
2765 		uint32_t	risefall:3;
2766 		uint32_t	rsrvd1:1;
2767 		uint32_t	emph:3;
2768 		uint32_t	rsrvd:1;
2769 #endif
2770 	} bits;
2771 } pipe_rx_tx_param_t;
2772 
2773 
2774 /*
2775  * Register: PipeRxTxClock
2776  * Pipe Rx/Tx Clock
2777  *     Reverse Loopback clock select 00 : gbtRbcAO 01 : gbtRbcBO 10 :
2778  *     gbtRbcCO 11 : gbtRbcDO
2779  *     Select Master Clock 100 : All lanes 000 : Lane A 001 : Lane B
2780  *     010 : Lane C 011 : Lane D
2781  *     Transmit PLL Divider control
2782  *     Transmit Data rate control
2783  *     Receiver PLL Frequency control
2784  *     Bit rate control to enable bit doubling feature
2785  *     Reset Transmitter lane
2786  *     Reset Receiver lane
2787  */
2788 typedef union {
2789 	uint32_t value;
2790 	struct {
2791 #if defined(_BIG_ENDIAN)
2792 		uint32_t	rsrvd:2;
2793 		uint32_t	revlbrefsel:2;
2794 		uint32_t	rsrvd1:1;
2795 		uint32_t	tdmaster:3;
2796 		uint32_t	fbdivt:3;
2797 		uint32_t	half_ratet:1;
2798 		uint32_t	fbdivr:3;
2799 		uint32_t	half_rater:1;
2800 		uint32_t	txreset:8;
2801 		uint32_t	rxreset:8;
2802 #else
2803 		uint32_t	rxreset:8;
2804 		uint32_t	txreset:8;
2805 		uint32_t	half_rater:1;
2806 		uint32_t	fbdivr:3;
2807 		uint32_t	half_ratet:1;
2808 		uint32_t	fbdivt:3;
2809 		uint32_t	tdmaster:3;
2810 		uint32_t	rsrvd1:1;
2811 		uint32_t	revlbrefsel:2;
2812 		uint32_t	rsrvd:2;
2813 #endif
2814 	} bits;
2815 } pipe_rx_tx_clock_t;
2816 
2817 
2818 /*
2819  * Register: PipeGlueCntl0
2820  * Pipe Glue Control 0
2821  *     Lock to Bitstream Initialization Time
2822  *     RXLOS Test bit
2823  *     Electrical Idle Ordered set enable
2824  *     Enable RxLOS
2825  *     Enable Fast resync
2826  *     RxLOS Sample Interval
2827  *     RxLOS threshold
2828  */
2829 typedef union {
2830 	uint32_t value;
2831 	struct {
2832 #if defined(_BIG_ENDIAN)
2833 		uint32_t	bitlocktime:16;
2834 		uint32_t	rxlos_test:1;
2835 		uint32_t	eiosenable:1;
2836 		uint32_t	rxlosenable:1;
2837 		uint32_t	fastresync:1;
2838 		uint32_t	samplerate:4;
2839 		uint32_t	thresholdcount:8;
2840 #else
2841 		uint32_t	thresholdcount:8;
2842 		uint32_t	samplerate:4;
2843 		uint32_t	fastresync:1;
2844 		uint32_t	rxlosenable:1;
2845 		uint32_t	eiosenable:1;
2846 		uint32_t	rxlos_test:1;
2847 		uint32_t	bitlocktime:16;
2848 #endif
2849 	} bits;
2850 } pipe_glue_cntl0_t;
2851 
2852 
2853 /*
2854  * Register: PipeGlueCntl1
2855  * Pipe Glue Control 1
2856  *     Receiver Trim Resistance Configuration
2857  *     Transmitter Trim Resistance Configuration
2858  *     Auto Trim Enable
2859  *     50 Ohm Termination Enable
2860  *     Customer select for reference clock frequency
2861  *     EFIFO Same clock select
2862  *     EFIFO start depth
2863  *     Lock to refclk initialization time
2864  */
2865 typedef union {
2866 	uint32_t value;
2867 	struct {
2868 #if defined(_BIG_ENDIAN)
2869 		uint32_t	termrcfg:2;
2870 		uint32_t	termtcfg:2;
2871 		uint32_t	rtrimen:1;
2872 		uint32_t	ref50:1;
2873 		uint32_t	freq_sel:1;
2874 		uint32_t	same_sel:1;
2875 		uint32_t	rsrvd:1;
2876 		uint32_t	start_efifo:3;
2877 		uint32_t	rsrvd1:2;
2878 		uint32_t	inittime:18;
2879 #else
2880 		uint32_t	inittime:18;
2881 		uint32_t	rsrvd1:2;
2882 		uint32_t	start_efifo:3;
2883 		uint32_t	rsrvd:1;
2884 		uint32_t	same_sel:1;
2885 		uint32_t	freq_sel:1;
2886 		uint32_t	ref50:1;
2887 		uint32_t	rtrimen:1;
2888 		uint32_t	termtcfg:2;
2889 		uint32_t	termrcfg:2;
2890 #endif
2891 	} bits;
2892 } pipe_glue_cntl1_t;
2893 
2894 
2895 /*
2896  * Register: HcrReg
2897  * HCR Registers
2898  * Description: Hydra Specific Configuration Registers for use by
2899  * software. These registers are loaded with the SPROM contents at
2900  * power on. A maximum of 128 DWords has been assigned for s/w to
2901  * use. This space generally stores the following informations : MAC
2902  * Address Number of MAC addresses MAC Phy Type Other data fields are
2903  * upto the software to use.
2904  *
2905  * Fields:
2906  *     Hydra specific configuration controlled by software
2907  */
2908 typedef union {
2909 	uint32_t value;
2910 	struct {
2911 #if defined(_BIG_ENDIAN)
2912 		uint32_t	hcr_val:32;
2913 #else
2914 		uint32_t	hcr_val:32;
2915 #endif
2916 	} bits;
2917 } hcr_reg_t;
2918 
2919 
2920 /*
2921  * Register: BlockReset
2922  * Block Reset
2923  * Description: Soft resets to modules. Blade domain modules are
2924  * reset by setting the corresponding block reset to 1. Shared domain
2925  * resets are sent to SPI for processing and corresponding action by
2926  * SPI. Shared domains are reset only if all the blades have
2927  * requested a reset for that block. Below is an example scenario :
2928  * s/w initiates the reset by writing '1' to the dpmRst bit dpmRst
2929  * bit remains '1' until dpmRstStat is detected to be 1. Once
2930  * dpmRstStat is detected to be 1, even if s/w writes 1 to this bit
2931  * again no new reset will be initiated to the shared domain, ie,
2932  * DPM. dpmRstStat is driven by external i/f (shared domain status
2933  * provided by SPI) dpmRstStat bit will show '1' as long as the input
2934  * stays at 1 or until s/w reads the status and is cleared only after
2935  * s/w reads it and if dpmRstStat is 0 by then.
2936  * If Host wants to reset entire Hydra it should do so through the
2937  * mailbox. In this case, the message interprettation is upto the
2938  * software. Writing a '1' to any of these bits generates a single
2939  * pulse to the SP module which then controls the reset of the
2940  * respective block.
2941  *
2942  * Fields:
2943  *     1 : indicates that an active reset has been applied to the SP
2944  *     based on the request from all of the blades. Clears on Read
2945  *     provided the reset to SP has been deasserted by then by SPI.
2946  *     Setting to 1 allows this blade to request Service Processor
2947  *     (Shared) reset. However, SP reset can only occur if all blades
2948  *     agree. The success of reset request is indicated by spRstStat
2949  *     = 1 which is wired-AND of request from all the blades. Current
2950  *     request can be removed by writing a '0' to this bit. This bit
2951  *     clears automatically on detecting spRstStat = 1.
2952  *     Enable blade to service processor (Shared) reset voter
2953  *     registration = 1, disabled = 0
2954  *     Issue power reset to the EP Core Clears to 0, writing 0 has no
2955  *     effect.
2956  *     Issue core reset to the EP Core Clears to 0, writing 0 has no
2957  *     effect.
2958  *     Issue system reset (sysPor) to the PIPE Core This issues reset
2959  *     to the EP core, PCIe domains of Tdc, Rdc, and CIP. This shuts
2960  *     down the PCIe clock until Pipe core comes out of reset. The
2961  *     status of the Pipe core can be read by reading out the
2962  *     cipLinkStat register's pipe core status and pcie reset status
2963  *     bits. Clears to 0, writing 0 has no effect.
2964  *     1 : indicates that an active reset has been applied to the
2965  *     NMAC based on the request from all of the blades. Clears on
2966  *     Read provided the reset to NMAC has been deasserted by then by
2967  *     SPI.
2968  *     1 : indicates that an active reset has been applied to the TDP
2969  *     based on the request from all of the blades. Clears on Read
2970  *     provided the reset to TDP has been deasserted by then by SPI.
2971  *     1 : indicates that an active reset has been applied to the DPM
2972  *     based on the request from all of the blades. Clears on Read
2973  *     provided the reset to DPM has been deasserted by then by SPI.
2974  *     This bit is effective only if sharedVoterEn (bit 24 of this
2975  *     reg) has been enabled. Writing '1' sends a request to SP to
2976  *     reset NMAC if sharedVoterEn=1. Intended for backdoor access.
2977  *     The success of reset request is indicated by nmacRstStat = 1
2978  *     which is wired-AND of request from all the blades. This also
2979  *     means that the reset request is successful only if all the
2980  *     blades requested for reset of this block. Current request can
2981  *     be removed by writing a '0' to this bit. This bit clears
2982  *     automatically on detecting nmacRstStat = 1.
2983  *     This bit is effective only if sharedVoterEn (bit 24 of this
2984  *     reg) has been enabled. Writing '1' sends a request to SP to
2985  *     reset TDP if sharedVoterEn=1. Intended for backdoor access.
2986  *     Intended for backdoor access. The success of reset request is
2987  *     indicated by tdpRstStat = 1 which is wired-AND of request from
2988  *     all the blades. This also means that the reset request is
2989  *     successful only if all the blades requested for reset of this
2990  *     block. Current request can be removed by writing a '0' to this
2991  *     bit. This bit clears automatically on detecting tdpRstStat =
2992  *     1.
2993  *     This bit is effective only if sharedVoterEn (bit 24 of this
2994  *     reg) has been enabled. Writing '1' sends a request to SP to
2995  *     reset DPM if sharedVoterEn=1. Intended for backdoor access.
2996  *     Intended for backdoor access. The success of reset request is
2997  *     indicated by dpmRstStat = 1 which is wired-AND of request from
2998  *     all the blades. This also means that the reset request is
2999  *     successful only if all the blades requested for reset of this
3000  *     block. Current request can be removed by writing a '0' to this
3001  *     bit. This bit clears automatically on detecting dpmRstStat =
3002  *     1.
3003  *     Setting to 1 generates tdcCoreReset and tdcPcieReset to the
3004  *     TDC block. The reset will stay asserted for atleast 4 clock
3005  *     cycles. Clears to 0, writing 0 has no effect.
3006  *     Setting to 1 generates rdcCoreReset and rdcPcieReset to the
3007  *     RDC block. The reset will stay asserted for atleast 4 clock
3008  *     cycles. Clears to 0, writing 0 has no effect.
3009  *     Setting to 1 generates reset to the PFC block. The reset will
3010  *     stay asserted for atleast 4 clock cycles. Clears to 0, writing
3011  *     0 has no effect.
3012  *     Setting to 1 generates reset to the VMAC block. The reset will
3013  *     stay asserted for atleast 4 clock cycles. Clears to 0, writing
3014  *     0 has no effect.
3015  */
3016 typedef union {
3017 	uint32_t value;
3018 	struct {
3019 #if defined(_BIG_ENDIAN)
3020 		uint32_t	rsrvd:13;
3021 		uint32_t	sp_rst_stat:1;
3022 		uint32_t	sp_rst:1;
3023 		uint32_t	shared_voter_en:1;
3024 		uint32_t	epcore_pwr_rst:1;
3025 		uint32_t	epcore_core_rst:1;
3026 		uint32_t	pipe_sys_rst:1;
3027 		uint32_t	nmac_rst_stat:1;
3028 		uint32_t	tdp_rst_stat:1;
3029 		uint32_t	dpm_rst_stat:1;
3030 		uint32_t	rsrvd1:1;
3031 		uint32_t	nmac_rst:1;
3032 		uint32_t	tdp_rst:1;
3033 		uint32_t	dpm_rst:1;
3034 		uint32_t	rsrvd2:1;
3035 		uint32_t	tdc_rst:1;
3036 		uint32_t	rdc_rst:1;
3037 		uint32_t	pfc_rst:1;
3038 		uint32_t	vmac_rst:1;
3039 		uint32_t	rsrvd3:1;
3040 #else
3041 		uint32_t	rsrvd3:1;
3042 		uint32_t	vmac_rst:1;
3043 		uint32_t	pfc_rst:1;
3044 		uint32_t	rdc_rst:1;
3045 		uint32_t	tdc_rst:1;
3046 		uint32_t	rsrvd2:1;
3047 		uint32_t	dpm_rst:1;
3048 		uint32_t	tdp_rst:1;
3049 		uint32_t	nmac_rst:1;
3050 		uint32_t	rsrvd1:1;
3051 		uint32_t	dpm_rst_stat:1;
3052 		uint32_t	tdp_rst_stat:1;
3053 		uint32_t	nmac_rst_stat:1;
3054 		uint32_t	pipe_sys_rst:1;
3055 		uint32_t	epcore_core_rst:1;
3056 		uint32_t	epcore_pwr_rst:1;
3057 		uint32_t	shared_voter_en:1;
3058 		uint32_t	sp_rst:1;
3059 		uint32_t	sp_rst_stat:1;
3060 		uint32_t	rsrvd:13;
3061 #endif
3062 	} bits;
3063 } block_reset_t;
3064 
3065 
3066 /*
3067  * Register: TimeoutCfg
3068  * PIO Timeout Configuration
3069  * Description: PIO Timeout Configuration register to control wait
3070  * time for a PIO access to complete. The timer resolution is in 250
3071  * MHz clock.
3072  * Fields:
3073  *     Programmable timeout counter value for PIO clients who did not
3074  *     ack a transaction in time. Minimum value should be 64.
3075  *     Timeout enable for PIO access to clients. 1 = enable.
3076  */
3077 typedef union {
3078 	uint32_t value;
3079 	struct {
3080 #if defined(_BIG_ENDIAN)
3081 		uint32_t	rsrvd:21;
3082 		uint32_t	tmout_cnt:10;
3083 		uint32_t	tmout_en:1;
3084 #else
3085 		uint32_t	tmout_en:1;
3086 		uint32_t	tmout_cnt:10;
3087 		uint32_t	rsrvd:21;
3088 #endif
3089 	} bits;
3090 } timeout_cfg_t;
3091 
3092 
3093 /*
3094  * Register: HeartCfg
3095  * PIO Heartbeat Config
3096  * Description: PIO Blade presence indication : Heartbeat
3097  * configuration The timer resolution is in 250 MHz clock.
3098  * Fields:
3099  *     Heartbeat countdown 250Mhz clock divider which serves as
3100  *     resolution for the heartTimer.
3101  *     Heartbeat countdown enable
3102  */
3103 typedef union {
3104 	uint32_t value;
3105 	struct {
3106 #if defined(_BIG_ENDIAN)
3107 		uint32_t	divider:28;
3108 		uint32_t	rsrvd:3;
3109 		uint32_t	en:1;
3110 #else
3111 		uint32_t	en:1;
3112 		uint32_t	rsrvd:3;
3113 		uint32_t	divider:28;
3114 #endif
3115 	} bits;
3116 } heart_cfg_t;
3117 
3118 
3119 /*
3120  * Register: HeartTimer
3121  * PIO Heartbeat Timer
3122  * Description: PIO Blade presence indication : Heartbeat timer The
3123  * timer resolution is in 250 MHz clock.
3124  * Fields:
3125  *     Number of heartCfg.divider ticks of the 250Mhz clock before
3126  *     blade presence expires. This register decrements for every
3127  *     heartCfg.divider number of 250MHz clock cycles. It expires to
3128  *     0 and so must be written periodically to reset the timer back
3129  *     to the required value. This counter does not have any effect
3130  *     on CIP functionality.
3131  */
3132 typedef union {
3133 	uint32_t value;
3134 	struct {
3135 #if defined(_BIG_ENDIAN)
3136 		uint32_t	timer:32;
3137 #else
3138 		uint32_t	timer:32;
3139 #endif
3140 	} bits;
3141 } heart_timer_t;
3142 
3143 
3144 /*
3145  * Register: CipGpCtrl
3146  * CIP General Purpose Control Register
3147  */
3148 typedef union {
3149 	uint32_t value;
3150 	struct {
3151 #if defined(_BIG_ENDIAN)
3152 		uint32_t	rsrvd:30;
3153 		uint32_t	dma_override_relaxord:1;
3154 		uint32_t	dma_override_nosnoop:1;
3155 #else
3156 		uint32_t	dma_override_nosnoop:1;
3157 		uint32_t	dma_override_relaxord:1;
3158 		uint32_t	rsrvd:30;
3159 #endif
3160 	} bits;
3161 } cip_gp_ctrl_t;
3162 
3163 
3164 /*
3165  * Register: CipStatus
3166  * CIP Status
3167  * Description: This register returns CIP block's current logic
3168  * status
3169  * Fields:
3170  *     Current state of the cipEpc state machine 00 : epIdle ( wait
3171  *     for EEPROM request from SP or Host ) 01 : waitAck0 ( wait for
3172  *     ack from EEPROM for the first 16 bit read of the DW access )
3173  *     11 : waitAck1 ( wait for ack from EEPROM for the second 16 bit
3174  *     read of the DW access ) 10 : UNDEFINED ( Undefined/Unused
3175  *     state; EPC is never expected to be in this state )
3176  *     Current state of the cipSpc state machine 000 : spReset ( wait
3177  *     for Power-On SPROM download to start) 001 : getAddr ( Get
3178  *     CfgReg Address ) 010 : getData ( Get CfgReg Data ) 011 :
3179  *     ignoreData ( Address phase had an error, so ignore the Data
3180  *     coming in ) 100 : idleCyc ( Idle cycle following an AHB
3181  *     Address phase ) 101 : waitAck0 ( Wait for ack from EP Core
3182  *     during SPROM Download ) 110 : waitAck1 ( Wait for ack from EP
3183  *     Core during register read/write ) 111 : NORMAL ( SPROM
3184  *     Download/Register read/write access completed and wait for
3185  *     SP/Host initiated PCI/AHB/HCR read/write )
3186  *     PCI Bus Number as reported by EP core
3187  *     PCI Bus Device Number as reported by EP core
3188  *     1: current csr access in progress is Local CIP csr access
3189  *     1: current csr access in progress is Blade Domain csr access
3190  *     1: a 64 bit blade domain access is in progress as two 32 bit
3191  *     accesses
3192  *     1: indicates config values were downloaded from SPROM
3193  *     1: indicates non-zero number of HCR config values downloaded
3194  *     from SPROM
3195  *     1: indicates non-zero number of PCI config values downloaded
3196  *     from SPROM
3197  *     1: indicates non-zero number of Pipe config values downloaded
3198  *     from SPROM
3199  */
3200 typedef union {
3201 	uint32_t value;
3202 	struct {
3203 #if defined(_BIG_ENDIAN)
3204 		uint32_t	rsrvd:7;
3205 		uint32_t	cip_epc_sm:2;
3206 		uint32_t	cip_spc_sm:3;
3207 		uint32_t	pbus_num:8;
3208 		uint32_t	pbus_dev_num:5;
3209 		uint32_t	loc_csr_access:1;
3210 		uint32_t	bd_csr_access:1;
3211 		uint32_t	d64_in_progress:1;
3212 		uint32_t	spc_dnld_done:1;
3213 		uint32_t	hcr_nz_cfg:1;
3214 		uint32_t	pci_nz_cfg:1;
3215 		uint32_t	pipe_nz_cfg:1;
3216 #else
3217 		uint32_t	pipe_nz_cfg:1;
3218 		uint32_t	pci_nz_cfg:1;
3219 		uint32_t	hcr_nz_cfg:1;
3220 		uint32_t	spc_dnld_done:1;
3221 		uint32_t	d64_in_progress:1;
3222 		uint32_t	bd_csr_access:1;
3223 		uint32_t	loc_csr_access:1;
3224 		uint32_t	pbus_dev_num:5;
3225 		uint32_t	pbus_num:8;
3226 		uint32_t	cip_spc_sm:3;
3227 		uint32_t	cip_epc_sm:2;
3228 		uint32_t	rsrvd:7;
3229 #endif
3230 	} bits;
3231 } cip_status_t;
3232 
3233 
3234 /*
3235  * Register: CipLinkStat
3236  * Link Status Register
3237  * Description: This register returns the Link status
3238  * Fields:
3239  *     NMAC XPCS-2 Link Status
3240  *     NMAC XPCS-1 Link Status
3241  *     NMAC XPCS-0 Link Status
3242  *     '1' indicates that pipe core went down suddenly when its reset
3243  *     sources are at deactivated level. When this happens, the PCIe
3244  *     domain logics are reset including the EP core, TDC/RDC PCIe
3245  *     domains. All these logics, EP Core, and the pipe core are held
3246  *     at reset until s/w writes 1 to this bit to clear status which
3247  *     will also bring the PCIe domain out of reset
3248  *     pipe core clock & reset status 1: core is up & running, ie,
3249  *     PIPE core is out of reset and clock is ON
3250  *     PCIe domain reset status 1: PCIe domain logics including EP
3251  *     core are out of reset; This also implies that PCIe clock is up
3252  *     and running
3253  *     EP Core XDM Link State
3254  *     EP Core RDM Link State
3255  *     EP Core LTSSM State
3256  */
3257 typedef union {
3258 	uint32_t value;
3259 	struct {
3260 #if defined(_BIG_ENDIAN)
3261 		uint32_t	rsrvd:13;
3262 		uint32_t	xpcs2_link_up:1;
3263 		uint32_t	xpcs1_link_up:1;
3264 		uint32_t	xpcs0_link_up:1;
3265 		uint32_t	rsrvd1:6;
3266 		uint32_t	surprise_pipedn:1;
3267 		uint32_t	pipe_core_stable:1;
3268 		uint32_t	pcie_domain_stable:1;
3269 		uint32_t	xmlh_link_up:1;
3270 		uint32_t	rdlh_link_up:1;
3271 		uint32_t	xmlh_ltssm_state:5;
3272 #else
3273 		uint32_t	xmlh_ltssm_state:5;
3274 		uint32_t	rdlh_link_up:1;
3275 		uint32_t	xmlh_link_up:1;
3276 		uint32_t	pcie_domain_stable:1;
3277 		uint32_t	pipe_core_stable:1;
3278 		uint32_t	surprise_pipedn:1;
3279 		uint32_t	rsrvd1:6;
3280 		uint32_t	xpcs0_link_up:1;
3281 		uint32_t	xpcs1_link_up:1;
3282 		uint32_t	xpcs2_link_up:1;
3283 		uint32_t	rsrvd:13;
3284 #endif
3285 	} bits;
3286 } cip_link_stat_t;
3287 
3288 
3289 /*
3290  * Register: EpcStat
3291  * EEPROM PIO Status
3292  * Description: EEPROM PIO Status The Host may initiate access to the
3293  * EEPROM either thru this register or directly by TRGT1 interfaces
3294  * using ROM BAR access. Note that since the EEPROM can be accessed
3295  * by either Host or SP, access must be granted to the PEU using the
3296  * SPI PROM Control Register eepromPeuEn bit for proper operation.
3297  * All EEPROM accesses initiated from either the Host or SP are
3298  * always acknowledged. If a Host access is not acknowledged, then
3299  * check the SPI PROM Control Register eepromPeuEn bit to make sure
3300  * the PEU to EEPROM access has been enabled. Meanwhile, Host read
3301  * and write accesses through the TRGT1 interface may be held up
3302  * waiting for the acknowledgement. Thus, in order to recover from
3303  * any faulty/stuck condition due to the blocked EEPROM accesses, the
3304  * SP should configure the epcGotoNormal bit in the epcStat register.
3305  * When Host accesses are stuck, only the SP can write into this bit
3306  * to recover from this condition.
3307  * The EEPROM is 1M x 16 bits or 2M bytes. The read address in bits
3308  * [22:2] is byte address. The EEPROM access can only be DW access.
3309  * While accessing through these registers, the lower 2 bits of the
3310  * specified address is ignored resulting in a DW access to the
3311  * EEPROM controller. While accessing through the ROM BAR range, only
3312  * DW accesses are accepted and all other accesses will result in
3313  * error status returned to the host.
3314  * The read will initiate two reads to the EPC and the accumulated
3315  * 32 bit data is returned to the Host either via the Client2 bus or
3316  * in the epcData register depending on the cause of the transaction.
3317  * This means, a read addr=0,1,2,3 will return data from EPC
3318  * locations 0 & 1 which are 16 bits each, and a read to addr=4,5,6,7
3319  * will return data from EPC locations 2,3 which are 16 bits each.
3320  * Some examples for the address translation : 1) when Host gives
3321  * address 0x0000, it means to get bytes 0,1,2, and 3 from the
3322  * EEPROM. These bytes are stored at locations 0x0000 (bytes 0,1) and
3323  * 0x0001 (bytes 2,3) in EEPROM. Hence PEU will present address
3324  * 0x0000 followed by 0x0001 to the EEPROM.
3325  * 2) when Host gives address 0x0004, it means to get bytes 4,5,6,
3326  * and 7 from the EEPROM. These bytes are stored at locations 0x0002
3327  * (bytes 4,5) and 0x0003 (bytes 6,7) in EEPROM. Hence PEU will
3328  * present address 0x0002 followed by 0x0003 to the EEPROM.
3329  * etc ..
3330  *
3331  * Fields:
3332  *     Force the EPC state machine to go to epIdle state. This bit is
3333  *     used to force the EPC to skip the reading of the EEPROM and
3334  *     goto the epIdle state which is normal state for EPC. The bit
3335  *     is auto-cleared after switching to the epIdle state. Both SP
3336  *     and HOST can write into this bit. However care must be taken
3337  *     writing '1' into this bit since setting this bit will flush
3338  *     out any pending EEPROM access request from Host. Hence, this
3339  *     bit should be used only if the EPC State machine (cipEpcSm
3340  *     bits in cipStatus register) is stuck at a non-zero state.
3341  *     EEPROM Byte Address for read operation This field can be
3342  *     updated only if there is no pending EEPROM read access.
3343  *     Software should poll bit 0 of this register (epcRdInit) to
3344  *     make sure that it is '0' before writing into this. If polled
3345  *     epcRdInit value is '1', then write to epcAddr field is
3346  *     ignored. This is to safe-guard the epcAddr value which is
3347  *     being read out the EEPROM.
3348  *     Read access completion status; set to '0' for successful
3349  *     completion by EPC set to '1' to indicate read access error
3350  *     from EPC
3351  * Note: Currently, the EEPROM controller in Hydra does not
3352  *     return any error condition, ie, epcPeuErr = 1'b0 always. And
3353  *     so, for the PIO read access by the Host, the epcStat register
3354  *     in PEU will always show that the access was successful. For
3355  *     EEPROM read initiated through the ROM BAR by the Host, CIP
3356  *     will always return Successful Completion status to the Host.
3357  *     Any error situation is reported only in the Status Register
3358  *     within the EEPROM device. For access information about this
3359  *     register, please refer to the EEPROM/SPI PRMs.
3360  *
3361  *     Read Initiate. SW writes 1 to this bit to initiate a EEPROM
3362  *     read. Clears to 0 on updating the epcData reg. Writing 0 has
3363  *     no effect.
3364  */
3365 typedef union {
3366 	uint32_t value;
3367 	struct {
3368 #if defined(_BIG_ENDIAN)
3369 		uint32_t	epc_goto_normal:1;
3370 		uint32_t	rsrvd:8;
3371 		uint32_t	epc_addr:21;
3372 		uint32_t	epc_cpl_stat:1;
3373 		uint32_t	epc_rd_init:1;
3374 #else
3375 		uint32_t	epc_rd_init:1;
3376 		uint32_t	epc_cpl_stat:1;
3377 		uint32_t	epc_addr:21;
3378 		uint32_t	rsrvd:8;
3379 		uint32_t	epc_goto_normal:1;
3380 #endif
3381 	} bits;
3382 } epc_stat_t;
3383 
3384 
3385 /*
3386  * Register: EpcData
3387  * EEPROM PIO Data
3388  * Description: EEPROM PIO Data The data returned from EEPROM
3389  * controller for the EEPROM access initiated by the EEPROM PIO
3390  * Status register is returned in this register.
3391  * Fields:
3392  *     EEPROM Read Data; valid when rdInit transitioned from 1 to 0.
3393  */
3394 typedef union {
3395 	uint32_t value;
3396 	struct {
3397 #if defined(_BIG_ENDIAN)
3398 		uint32_t	eeprom_data:32;
3399 #else
3400 		uint32_t	eeprom_data:32;
3401 #endif
3402 	} bits;
3403 } epc_data_t;
3404 
3405 
3406 /*
3407  * Register: SpcStat
3408  * SPROM PIO Status
3409  * Description: SPROM PIO Status
3410  * Fields:
3411  *     Force the SPC state machine to go to NORMAL state. This bit is
3412  *     used to force the SPC to skip the downloading of the SPROM
3413  *     contents into the EP/Pipe/Hcr registers. Setting this bit will
3414  *     make CIP to drop any pending requests to the DBI/AHB buses.
3415  *     The bit is auto-cleared after switching to the Normal state.
3416  *     This bit can not be used to terminate a pio access to
3417  *     PCI/PIPE/HCR registers. If a pio access to these registers is
3418  *     not responded to, by the respective block, then the pio access
3419  *     will automatically timeout. The timeout value is specified by
3420  *     the timeoutCfg:tmoutCnt value
3421  */
3422 typedef union {
3423 	uint32_t value;
3424 	struct {
3425 #if defined(_BIG_ENDIAN)
3426 		uint32_t	rsrvd:29;
3427 		uint32_t	spc_goto_normal:1;
3428 		uint32_t	rsrvd1:2;
3429 #else
3430 		uint32_t	rsrvd1:2;
3431 		uint32_t	spc_goto_normal:1;
3432 		uint32_t	rsrvd:29;
3433 #endif
3434 	} bits;
3435 } spc_stat_t;
3436 
3437 
3438 /*
3439  * Register: Host2spiIndaccAddr
3440  * HOST -> SPI Shared Domain Read Address
3441  * Description: Read address set by Host for indirect access to
3442  * shared domain address space The decoding of the address is as
3443  * follows: [23:20] - block select [19:0] - register offset from base
3444  * address of block
3445  * Fields:
3446  *     Address in Shared domain
3447  */
3448 typedef union {
3449 	uint32_t value;
3450 	struct {
3451 #if defined(_BIG_ENDIAN)
3452 		uint32_t	rsrvd:8;
3453 		uint32_t	addr:24;
3454 #else
3455 		uint32_t	addr:24;
3456 		uint32_t	rsrvd:8;
3457 #endif
3458 	} bits;
3459 } host2spi_indacc_addr_t;
3460 
3461 
3462 /*
3463  * Register: Host2spiIndaccCtrl
3464  * HOST -> SPI Shared Domain Read Control
3465  * Description: Control word set by Host for indirect access to the
3466  * shared domain address space Writing to this register initiates the
3467  * indirect access to the shared domain.
3468  * The Host may read or write to a shared domain region data as
3469  * below : Host updates the host2spiIndaccAddr register with address
3470  * of the shared domain reg. For writes, Host updates the
3471  * host2spiIndaccData register with write data Host then writes to
3472  * bit 0 of host2spiIndaccCtrl register to '1' or '0' to initiate the
3473  * read or write access; 1 : write command, 0 : read command Host
3474  * should then poll bit 1 of host2spiIndaccCtrl register for the
3475  * access status. 1 : access is done, 0 : access is in progress
3476  * (busy) Host should then check bit 2 of host2spiIndaccCtrl register
3477  * to know if the command was successful; 1 : access error, 0 :
3478  * access successful For reads, Host then reads the
3479  * host2spiIndaccData register for the read data.
3480  * This register can be written into only when there is no pending
3481  * access, ie, indaccCtrl.cplStat=1. Writes when indaccCtrl.cplStat=0
3482  * is ignored.
3483  *
3484  * Fields:
3485  *     command completion status; 0 : successful completion of
3486  *     command by SPI 1 : access error from SPI
3487  *     command progress status; 0 : access is in progress (busy) 1 :
3488  *     access is done
3489  *     1 : Initiate a write access 0 : Initiate a read access
3490  */
3491 typedef union {
3492 	uint32_t value;
3493 	struct {
3494 #if defined(_BIG_ENDIAN)
3495 		uint32_t	rsrvd:29;
3496 		uint32_t	err_stat:1;
3497 		uint32_t	cpl_stat:1;
3498 		uint32_t	rd_wr_cmd:1;
3499 #else
3500 		uint32_t	rd_wr_cmd:1;
3501 		uint32_t	cpl_stat:1;
3502 		uint32_t	err_stat:1;
3503 		uint32_t	rsrvd:29;
3504 #endif
3505 	} bits;
3506 } host2spi_indacc_ctrl_t;
3507 
3508 
3509 /*
3510  * Register: Host2spiIndaccData
3511  * HOST -> SPI Shared Domain Read/Write Data
3512  * Description: For indirect read access by the Host, this register
3513  * returns the data returned from the Shared Domain For indirect
3514  * write access by the Host, the host should update this register
3515  * with the writeData for the Shared Domain, before writing to the
3516  * host2spiIndaccCtrl register to initiate the access.
3517  * This register can be written into only when there is no pending
3518  * access, ie, indaccCtrl.cplStat=1. Writes when indaccCtrl.cplStat=0
3519  * is ignored.
3520  *
3521  * Fields:
3522  *     Shared domain read/write data
3523  */
3524 typedef union {
3525 	uint32_t value;
3526 	struct {
3527 #if defined(_BIG_ENDIAN)
3528 		uint32_t	data:32;
3529 #else
3530 		uint32_t	data:32;
3531 #endif
3532 	} bits;
3533 } host2spi_indacc_data_t;
3534 
3535 
3536 /*
3537  * Register: BtCtrl0
3538  * Mailbox Control & Access status 0
3539  * Description: Host (blade) <-> SP Block Transfer mailbox control
3540  * and access status register 0.
3541  * Host is allowed 8 bits read/write access to this register ; To do
3542  * the same, it should provide the btCtrl0 address, data on
3543  * hostDataBus[7:0], and assert hostBen[0], SPI is allowed 8 bits
3544  * read/write access to this register ; To do the same, it should
3545  * provide the btCtrl0 address, data on spiDataBus[7:0], and no need
3546  * of spiBen
3547  *
3548  * Fields:
3549  *     The SP sets/clears this bit to indicate if it is busy and can
3550  *     not accept any other request; write 1 to toggle the bit; Read
3551  *     Only by Host.
3552  *     The Host sets/clears this bit to indicate if it is busy and
3553  *     can not accept any other request; Read Only by SP.
3554  *     Reserved for definition by platform. Typical usage could be
3555  *     "heartbeat" mechanism from/to the host. The host sets OEM0 to
3556  *     interrupt the SP and then polls it to be cleared by SP
3557  *     The SP sets this bit when it has detected and queued an SMS
3558  *     message in the SP2HOST buffer that must be reported to the
3559  *     HOST. The Host clears this bit by writing a 1 to it. This bit
3560  *     may generate an intrpt to Host depending on the sp2hostIntEn
3561  *     bit. Writing 0 has no effect
3562  *     The SP writes 1 to this bit after it has finished writing a
3563  *     message into the SP2HOST buffer. The Host clears this bit by
3564  *     writing 1 to it after it has set the hostBusy bit This bit may
3565  *     generate an intrpt to Host depending on the sp2hostIntEn bit.
3566  *     Writing 0 has no effect
3567  *     The Host writes 1 to this bit to generate an interrupt to SP
3568  *     after it has finished writing a message into the HOST2SP
3569  *     buffer. The SP clears this bit by writing 1 to it after it has
3570  *     set the spBusy bit. Writing 0 has no effect
3571  *     The host writes 1 to clear the read pointer to the BT SP2HOST
3572  *     buffer; the SP writes 1 to clear the read pointer to the BT
3573  *     HOST2SP buffer. This bit is always read back as 0; writing 0
3574  *     has no effect.
3575  *     The host writes 1 to clear the write pointer to the BT HOST2SP
3576  *     buffer; the SP writes 1 to clear the write pointer to the BT
3577  *     SP2HOST buffer. This bit is always read back as 0; writing 0
3578  *     has no effect.
3579  */
3580 typedef union {
3581 	uint32_t value;
3582 	struct {
3583 #if defined(_BIG_ENDIAN)
3584 		uint32_t	rsrvd:24;
3585 		uint32_t	sp_busy:1;
3586 		uint32_t	host_busy:1;
3587 		uint32_t	oem0:1;
3588 		uint32_t	sms_atn:1;
3589 		uint32_t	sp2host_atn:1;
3590 		uint32_t	host2sp_atn:1;
3591 		uint32_t	clr_rd_ptr:1;
3592 		uint32_t	clr_wr_ptr:1;
3593 #else
3594 		uint32_t	clr_wr_ptr:1;
3595 		uint32_t	clr_rd_ptr:1;
3596 		uint32_t	host2sp_atn:1;
3597 		uint32_t	sp2host_atn:1;
3598 		uint32_t	sms_atn:1;
3599 		uint32_t	oem0:1;
3600 		uint32_t	host_busy:1;
3601 		uint32_t	sp_busy:1;
3602 		uint32_t	rsrvd:24;
3603 #endif
3604 	} bits;
3605 } bt_ctrl0_t;
3606 
3607 
3608 /*
3609  * Register: BtData0
3610  * Mailbox Data 0
3611  * Description: Host (blade) <-> SP mailbox data register 0.
3612  * Host is allowed a 32 bits read/write access to this register ; To
3613  * do the same, it should provide the btData0 address, data on
3614  * hostDataBus[31:0], and assert hostBen[1], SPI is allowed only 8
3615  * bits read/write access to this register ; To do the same, it
3616  * should provide the btData0 address, data on spiDataBus[7:0], and
3617  * no need of spiBen
3618  * All references to the mail box control bits in this register
3619  * refer to btCtrl0. When spBusy=0 && host2spAtn=0, data is written
3620  * by the host and read by the SP. When hostBusy=0 && sp2hostAtn=0,
3621  * data is written by the SP and read by the Host.
3622  *
3623  * Fields:
3624  *     Bits 7:0 of message data to send to SP/HOST
3625  */
3626 typedef union {
3627 	uint32_t value;
3628 	struct {
3629 #if defined(_BIG_ENDIAN)
3630 		uint32_t	rsrvd:24;
3631 		uint32_t	data:8;
3632 #else
3633 		uint32_t	data:8;
3634 		uint32_t	rsrvd:24;
3635 #endif
3636 	} bits;
3637 } bt_data0_t;
3638 
3639 
3640 /*
3641  * Register: BtIntmask0
3642  * Mailbox Interrupt Mask & Status 0
3643  * Description: Host (blade) <-> SP Block Transfer Interrupt Mask and
3644  * Status register 0
3645  * Host is allowed 8 bits read/write access to this register ; To do
3646  * the same, it should provide the btIntmask0 address, data on
3647  * hostDataBus[23:16], and assert hostBen[2], SPI is allowed 8 bits
3648  * read only access to this register ; To do the same, it should
3649  * provide the btIntmask0 address and no need of spiBen
3650  * All references to the mail box control bits in this register
3651  * refer to btCtrl0
3652  * Fields:
3653  *     The host writes 1 to reset the entire mailbox 0 accesses for
3654  *     error recovery; resets both SP and HOST write and read
3655  *     pointers. Writing 0 has no effect. This is non-sticky. Always
3656  *     read back as 0.
3657  *     Reserved for definition by platform manufacturer for BIOS/SMI
3658  *     Handler use. Generic IPMI software must write this bit as 0
3659  *     and ignore the value on read
3660  *     Reserved for definition by platform manufacturer for BIOS/SMI
3661  *     Handler use. Generic IPMI software must write this bit as 0
3662  *     and ignore the value on read
3663  *     Reserved for definition by platform manufacturer for BIOS/SMI
3664  *     Handler use. Generic IPMI software must write this bit as 0
3665  *     and ignore the value on read
3666  *     SP to HOST Interrupt status This bit reflects the state of the
3667  *     intrpt line to the Host. O/S driver should write 1 to clear.
3668  *     SP to HOST Interrupt Enable The interrupt is generated if
3669  *     sp2hIrqEn is 1 and either sp2hostAtn or smsAtn is 1
3670  */
3671 typedef union {
3672 	uint32_t value;
3673 	struct {
3674 #if defined(_BIG_ENDIAN)
3675 		uint32_t	rsrvd:24;
3676 		uint32_t	mb_master_reset:1;
3677 		uint32_t	rsrvd1:2;
3678 		uint32_t	oem3:1;
3679 		uint32_t	oem2:1;
3680 		uint32_t	oem1:1;
3681 		uint32_t	sp2h_irq:1;
3682 		uint32_t	sp2h_irq_en:1;
3683 #else
3684 		uint32_t	sp2h_irq_en:1;
3685 		uint32_t	sp2h_irq:1;
3686 		uint32_t	oem1:1;
3687 		uint32_t	oem2:1;
3688 		uint32_t	oem3:1;
3689 		uint32_t	rsrvd1:2;
3690 		uint32_t	mb_master_reset:1;
3691 		uint32_t	rsrvd:24;
3692 #endif
3693 	} bits;
3694 } bt_intmask0_t;
3695 
3696 
3697 /*
3698  * Register: BtCtrl1
3699  * Mailbox Control & Access status 1
3700  * Description: Host (blade) <-> SP Block Transfer mailbox control
3701  * and access status register 1.
3702  * Host is allowed 8 bits read/write access to this register ; To do
3703  * the same, it should provide the btCtrl1 address, data on
3704  * hostDataBus[7:0], and assert hostBen[0], SPI is allowed 8 bits
3705  * read/write access to this register ; To do the same, it should
3706  * provide the btCtrl1 address, data on spiDataBus[7:0], and no need
3707  * of spiBen
3708  *
3709  * Fields:
3710  *     The SP sets/clears this bit to indicate that it is busy and
3711  *     can not accept any other request; write 1 to toggle the bit;
3712  *     Read only by Host.
3713  *     The Host sets/clears this bit to indicate that it is busy and
3714  *     can not accept any other request; Read only by SP.
3715  *     Reserved for definition by platform. Typical usage could be
3716  *     "heartbeat" mechanism from/to the host. The host sets OEM0 to
3717  *     interrupt the SP and then polls it to be cleared by SP
3718  *     The SP sets this bit when it has detected and queued an SMS
3719  *     message in the SP2HOST buffer that must be reported to the
3720  *     HOST. The Host clears this bit by writing a 1 to it. This bit
3721  *     may generate an intrpt to Host depending on the sp2hostIntEn
3722  *     bit. Writing 0 has no effect
3723  *     The SP writes 1 to this bit after it has finished writing a
3724  *     message into the SP2HOST buffer. The Host clears this bit by
3725  *     writing 1 to it after it has set the hostBusy bit This bit may
3726  *     generate an intrpt to Host depending on the sp2hostIntEn bit.
3727  *     Writing 0 has no effect
3728  *     The Host writes 1 to this bit to generate an interrupt to SP
3729  *     after it has finished writing a message into the HOST2SP
3730  *     buffer. The SP clears this bit by writing 1 to it after it has
3731  *     set the spBusy bit. Writing 0 has no effect
3732  *     The host writes 1 to clear the read pointer to the BT SP2HOST
3733  *     buffer; the SP writes 1 to clear the read pointer to the BT
3734  *     HOST2SP buffer. This bit is always read back as 0; writing 0
3735  *     has no effect.
3736  *     The host writes 1 to clear the write pointer to the BT HOST2SP
3737  *     buffer; the SP writes 1 to clear the write pointer to the BT
3738  *     SP2HOST buffer. This bit is always read back as 0; writing 0
3739  *     has no effect.
3740  */
3741 typedef union {
3742 	uint32_t value;
3743 	struct {
3744 #if defined(_BIG_ENDIAN)
3745 		uint32_t	rsrvd:24;
3746 		uint32_t	sp_busy:1;
3747 		uint32_t	host_busy:1;
3748 		uint32_t	oem0:1;
3749 		uint32_t	sms_atn:1;
3750 		uint32_t	sp2host_atn:1;
3751 		uint32_t	host2sp_atn:1;
3752 		uint32_t	clr_rd_ptr:1;
3753 		uint32_t	clr_wr_ptr:1;
3754 #else
3755 		uint32_t	clr_wr_ptr:1;
3756 		uint32_t	clr_rd_ptr:1;
3757 		uint32_t	host2sp_atn:1;
3758 		uint32_t	sp2host_atn:1;
3759 		uint32_t	sms_atn:1;
3760 		uint32_t	oem0:1;
3761 		uint32_t	host_busy:1;
3762 		uint32_t	sp_busy:1;
3763 		uint32_t	rsrvd:24;
3764 #endif
3765 	} bits;
3766 } bt_ctrl1_t;
3767 
3768 
3769 /*
3770  * Register: BtData1
3771  * Mailbox Data 1
3772  * Description: Host (blade) <-> SP mailbox data register 1.
3773  * Host is allowed a 32 bits read/write access to this register ; To
3774  * do the same, it should provide the btData1 address, data on
3775  * hostDataBus[31:0], and assert hostBen[1], SPI is allowed only 8
3776  * bits read/write access to this register ; To do the same, it
3777  * should provide the btData1 address, data on spiDataBus[7:0], and
3778  * no need of spiBen
3779  * All references to the mail box control bits in this register
3780  * refer to btCtrl1. When spBusy=0 && host2spAtn=0, data is written
3781  * by the host and read by the SP. When hostBusy=0 && sp2hostAtn=0,
3782  * data is written by the SP and read by the Host.
3783  * Fields:
3784  *     Bits 31:0 of message data to send to SP/HOST
3785  */
3786 typedef union {
3787 	uint32_t value;
3788 	struct {
3789 #if defined(_BIG_ENDIAN)
3790 		uint32_t	rsrvd:24;
3791 		uint32_t	data:8;
3792 #else
3793 		uint32_t	data:8;
3794 		uint32_t	rsrvd:24;
3795 #endif
3796 	} bits;
3797 } bt_data1_t;
3798 
3799 
3800 /*
3801  * Register: BtIntmask1
3802  * Mailbox Interrupt Mask & Status 1
3803  * Description: Host (blade) <-> SP Block Transfer Interrupt Mask and
3804  * Status register 1
3805  * Host is allowed 8 bits read/write access to this register ; To do
3806  * the same, it should provide the btIntmask1 address, data on
3807  * hostDataBus[23:16], and assert hostBen[2], SPI is allowed 8 bits
3808  * read only access to this register ; To do the same, it should
3809  * provide the btIntmask1 address and no need of spiBen
3810  * All references to the mail box control bits in this register
3811  * refer to btCtrl1
3812  * Fields:
3813  *     The host writes 1 to reset the entire mailbox 1 accesses for
3814  *     error recovery; resets both SP and HOST write and read
3815  *     pointers. Writing 0 has no effect. This is non-sticky. Always
3816  *     read back as 0.
3817  *     Reserved for definition by platform manufacturer for BIOS/SMI
3818  *     Handler use. Generic IPMI software must write this bit as 0
3819  *     and ignore the value on read
3820  *     Reserved for definition by platform manufacturer for BIOS/SMI
3821  *     Handler use. Generic IPMI software must write this bit as 0
3822  *     and ignore the value on read
3823  *     Reserved for definition by platform manufacturer for BIOS/SMI
3824  *     Handler use. Generic IPMI software must write this bit as 0
3825  *     and ignore the value on read
3826  *     SP to HOST Interrupt status This bit reflects the state of the
3827  *     intrpt line to the Host. O/S driver should write 1 to clear.
3828  *     SP to HOST Interrupt Enable The interrupt is generated if
3829  *     sp2hIrqEn is 1 and either sp2hostAtn or smsAtn is 1
3830  */
3831 typedef union {
3832 	uint32_t value;
3833 	struct {
3834 #if defined(_BIG_ENDIAN)
3835 		uint32_t	rsrvd:24;
3836 		uint32_t	mb_master_reset:1;
3837 		uint32_t	rsrvd1:2;
3838 		uint32_t	oem3:1;
3839 		uint32_t	oem2:1;
3840 		uint32_t	oem1:1;
3841 		uint32_t	sp2h_irq:1;
3842 		uint32_t	sp2h_irq_en:1;
3843 #else
3844 		uint32_t	sp2h_irq_en:1;
3845 		uint32_t	sp2h_irq:1;
3846 		uint32_t	oem1:1;
3847 		uint32_t	oem2:1;
3848 		uint32_t	oem3:1;
3849 		uint32_t	rsrvd1:2;
3850 		uint32_t	mb_master_reset:1;
3851 		uint32_t	rsrvd:24;
3852 #endif
3853 	} bits;
3854 } bt_intmask1_t;
3855 
3856 
3857 /*
3858  * Register: BtCtrl2
3859  * Mailbox Control & Access status 2
3860  * Description: Host (blade) <-> SP Block Transfer mailbox control
3861  * and access status register 2.
3862  * Host is allowed 8 bits read/write access to this register ; To do
3863  * the same, it should provide the btCtrl2 address, data on
3864  * hostDataBus[7:0], and assert hostBen[0], SPI is allowed 8 bits
3865  * read/write access to this register ; To do the same, it should
3866  * provide the btCtrl2 address, data on spiDataBus[7:0], and no need
3867  * of spiBen
3868  *
3869  * Fields:
3870  *     The SP sets/clears this bit to indicate that it is busy and
3871  *     can not accept any other request; write 1 to toggle the bit;
3872  *     Read only by Host.
3873  *     The Host sets/clears this bit to indicate that it is busy and
3874  *     can not accept any other request; Read only by SP.
3875  *     Reserved for definition by platform. Typical usage could be
3876  *     "heartbeat" mechanism from/to the host. The host sets OEM0 to
3877  *     interrupt the SP and then polls it to be cleared by SP
3878  *     The SP sets this bit when it has detected and queued an SMS
3879  *     message in the SP2HOST buffer that must be reported to the
3880  *     HOST. The Host clears this bit by writing a 1 to it. This bit
3881  *     may generate an intrpt to Host depending on the sp2hostIntEn
3882  *     bit. Writing 0 has no effect
3883  *     The SP writes 1 to this bit after it has finished writing a
3884  *     message into the SP2HOST buffer. The Host clears this bit by
3885  *     writing 1 to it after it has set the hostBusy bit This bit may
3886  *     generate an intrpt to Host depending on the sp2hostIntEn bit.
3887  *     Writing 0 has no effect
3888  *     The Host writes 1 to this bit to generate an interrupt to SP
3889  *     after it has finished writing a message into the HOST2SP
3890  *     buffer. The SP clears this bit by writing 1 to it after it has
3891  *     set the spBusy bit. Writing 0 has no effect
3892  *     The host writes 1 to clear the read pointer to the BT SP2HOST
3893  *     buffer; the SP writes 1 to clear the read pointer to the BT
3894  *     HOST2SP buffer. This bit is always read back as 0; writing 0
3895  *     has no effect.
3896  *     The host writes 1 to clear the write pointer to the BT HOST2SP
3897  *     buffer; the SP writes 1 to clear the write pointer to the BT
3898  *     SP2HOST buffer. This bit is always read back as 0; writing 0
3899  *     has no effect.
3900  */
3901 typedef union {
3902 	uint32_t value;
3903 	struct {
3904 #if defined(_BIG_ENDIAN)
3905 		uint32_t	rsrvd:24;
3906 		uint32_t	sp_busy:1;
3907 		uint32_t	host_busy:1;
3908 		uint32_t	oem0:1;
3909 		uint32_t	sms_atn:1;
3910 		uint32_t	sp2host_atn:1;
3911 		uint32_t	host2sp_atn:1;
3912 		uint32_t	clr_rd_ptr:1;
3913 		uint32_t	clr_wr_ptr:1;
3914 #else
3915 		uint32_t	clr_wr_ptr:1;
3916 		uint32_t	clr_rd_ptr:1;
3917 		uint32_t	host2sp_atn:1;
3918 		uint32_t	sp2host_atn:1;
3919 		uint32_t	sms_atn:1;
3920 		uint32_t	oem0:1;
3921 		uint32_t	host_busy:1;
3922 		uint32_t	sp_busy:1;
3923 		uint32_t	rsrvd:24;
3924 #endif
3925 	} bits;
3926 } bt_ctrl2_t;
3927 
3928 
3929 /*
3930  * Register: BtData2
3931  * Mailbox Data 2
3932  * Description: Host (blade) <-> SP mailbox data register 2. All
3933  * references to the mail box control bits in this register refer to
3934  * btCtrl2.
3935  * Host is allowed a 32 bits read/write access to this register ; To
3936  * do the same, it should provide the btData2 address, data on
3937  * hostDataBus[31:0], and assert hostBen[1], SPI is allowed only 8
3938  * bits read/write access to this register ; To do the same, it
3939  * should provide the btData2 address, data on spiDataBus[7:0], and
3940  * no need of spiBen
3941  * When spBusy=0 && host2spAtn=0, data is written by the host and
3942  * read by the SP. When hostBusy=0 && sp2hostAtn=0, data is written
3943  * by the SP and read by the Host.
3944  * Fields:
3945  *     Bits 31:0 of message data to send to SP/HOST
3946  */
3947 typedef union {
3948 	uint32_t value;
3949 	struct {
3950 #if defined(_BIG_ENDIAN)
3951 		uint32_t	rsrvd:24;
3952 		uint32_t	data:8;
3953 #else
3954 		uint32_t	data:8;
3955 		uint32_t	rsrvd:24;
3956 #endif
3957 	} bits;
3958 } bt_data2_t;
3959 
3960 
3961 /*
3962  * Register: BtIntmask2
3963  * Mailbox Interrupt Mask & Status 2
3964  * Description: Host (blade) <-> SP Block Transfer Interrupt Mask and
3965  * Status register 2
3966  * Host is allowed 8 bits read/write access to this register ; To do
3967  * the same, it should provide the btIntmask2 address, data on
3968  * hostDataBus[23:16], and assert hostBen[2], SPI is allowed 8 bits
3969  * read only access to this register ; To do the same, it should
3970  * provide the btIntmask2 address and no need of spiBen
3971  * All references to the mail box control bits in this register
3972  * refer to btCtrl2
3973  * Fields:
3974  *     The host writes 1 to reset the entire mailbox 2 accesses for
3975  *     error recovery; resets both SP and HOST write and read
3976  *     pointers. Writing 0 has no effect. This is non-sticky. Always
3977  *     read back as 0.
3978  *     Reserved for definition by platform manufacturer for BIOS/SMI
3979  *     Handler use. Generic IPMI software must write this bit as 0
3980  *     and ignore the value on read
3981  *     Reserved for definition by platform manufacturer for BIOS/SMI
3982  *     Handler use. Generic IPMI software must write this bit as 0
3983  *     and ignore the value on read
3984  *     Reserved for definition by platform manufacturer for BIOS/SMI
3985  *     Handler use. Generic IPMI software must write this bit as 0
3986  *     and ignore the value on read
3987  *     SP to HOST Interrupt status This bit reflects the state of the
3988  *     intrpt line to the Host. O/S driver should write 1 to clear.
3989  *     SP to HOST Interrupt Enable The interrupt is generated if
3990  *     sp2hIrqEn is 1 and either sp2hostAtn or smsAtn is 1
3991  */
3992 typedef union {
3993 	uint32_t value;
3994 	struct {
3995 #if defined(_BIG_ENDIAN)
3996 		uint32_t	rsrvd:24;
3997 		uint32_t	mb_master_reset:1;
3998 		uint32_t	rsrvd1:2;
3999 		uint32_t	oem3:1;
4000 		uint32_t	oem2:1;
4001 		uint32_t	oem1:1;
4002 		uint32_t	sp2h_irq:1;
4003 		uint32_t	sp2h_irq_en:1;
4004 #else
4005 		uint32_t	sp2h_irq_en:1;
4006 		uint32_t	sp2h_irq:1;
4007 		uint32_t	oem1:1;
4008 		uint32_t	oem2:1;
4009 		uint32_t	oem3:1;
4010 		uint32_t	rsrvd1:2;
4011 		uint32_t	mb_master_reset:1;
4012 		uint32_t	rsrvd:24;
4013 #endif
4014 	} bits;
4015 } bt_intmask2_t;
4016 
4017 
4018 /*
4019  * Register: BtCtrl3
4020  * Mailbox Control & Access status 3
4021  * Description: Host (blade) <-> SP Block Transfer mailbox control
4022  * and access status register 3.
4023  * Host is allowed 8 bits read/write access to this register ; To do
4024  * the same, it should provide the btCtrl3 address, data on
4025  * hostDataBus[7:0], and assert hostBen[0], SPI is allowed 8 bits
4026  * read/write access to this register ; To do the same, it should
4027  * provide the btCtrl3 address, data on spiDataBus[7:0], and no need
4028  * of spiBen
4029  *
4030  * Fields:
4031  *     The SP sets/clears this bit to indicate that it is busy and
4032  *     can not accept any other request; write 1 to toggle the bit;
4033  *     Read only by Host.
4034  *     The Host sets/clears this bit to indicate that it is busy and
4035  *     can not accept any other request; Read only by SP.
4036  *     Reserved for definition by platform. Typical usage could be
4037  *     "heartbeat" mechanism from/to the host. The host sets OEM0 to
4038  *     interrupt the SP and then polls it to be cleared by SP
4039  *     The SP sets this bit when it has detected and queued an SMS
4040  *     message in the SP2HOST buffer that must be reported to the
4041  *     HOST. The Host clears this bit by writing a 1 to it. This bit
4042  *     may generate an intrpt to Host depending on the sp2hostIntEn
4043  *     bit. Writing 0 has no effect
4044  *     The SP writes 1 to this bit after it has finished writing a
4045  *     message into the SP2HOST buffer. The Host clears this bit by
4046  *     writing 1 to it after it has set the hostBusy bit This bit may
4047  *     generate an intrpt to Host depending on the sp2hostIntEn bit.
4048  *     Writing 0 has no effect
4049  *     The Host writes 1 to this bit to generate an interrupt to SP
4050  *     after it has finished writing a message into the HOST2SP
4051  *     buffer. The SP clears this bit by writing 1 to it after it has
4052  *     set the spBusy bit. Writing 0 has no effect
4053  *     The host writes 1 to clear the read pointer to the BT SP2HOST
4054  *     buffer; the SP writes 1 to clear the read pointer to the BT
4055  *     HOST2SP buffer. This bit is always read back as 0; writing 0
4056  *     has no effect.
4057  *     The host writes 1 to clear the write pointer to the BT HOST2SP
4058  *     buffer; the SP writes 1 to clear the write pointer to the BT
4059  *     SP2HOST buffer. This bit is always read back as 0; writing 0
4060  *     has no effect.
4061  */
4062 typedef union {
4063 	uint32_t value;
4064 	struct {
4065 #if defined(_BIG_ENDIAN)
4066 		uint32_t	rsrvd:24;
4067 		uint32_t	sp_busy:1;
4068 		uint32_t	host_busy:1;
4069 		uint32_t	oem0:1;
4070 		uint32_t	sms_atn:1;
4071 		uint32_t	sp2host_atn:1;
4072 		uint32_t	host2sp_atn:1;
4073 		uint32_t	clr_rd_ptr:1;
4074 		uint32_t	clr_wr_ptr:1;
4075 #else
4076 		uint32_t	clr_wr_ptr:1;
4077 		uint32_t	clr_rd_ptr:1;
4078 		uint32_t	host2sp_atn:1;
4079 		uint32_t	sp2host_atn:1;
4080 		uint32_t	sms_atn:1;
4081 		uint32_t	oem0:1;
4082 		uint32_t	host_busy:1;
4083 		uint32_t	sp_busy:1;
4084 		uint32_t	rsrvd:24;
4085 #endif
4086 	} bits;
4087 } bt_ctrl3_t;
4088 
4089 
4090 /*
4091  * Register: BtData3
4092  * Mailbox Data 3
4093  * Description: Host (blade) <-> SP mailbox data register 3.
4094  * Host is allowed a 32 bits read/write access to this register ; To
4095  * do the same, it should provide the btData3 address, data on
4096  * hostDataBus[31:0], and assert hostBen[1], SPI is allowed only 8
4097  * bits read/write access to this register ; To do the same, it
4098  * should provide the btData3 address, data on spiDataBus[7:0], and
4099  * no need of spiBen
4100  * All references to the mail box control bits in this register
4101  * refer to btCtrl3. When spBusy=0 && host2spAtn=0, data is written
4102  * by the host and read by the SP. When hostBusy=0 && sp2hostAtn=0,
4103  * data is written by the SP and read by the Host.
4104  * Fields:
4105  *     Bits 31:0 of message data to send to SP/HOST
4106  */
4107 typedef union {
4108 	uint32_t value;
4109 	struct {
4110 #if defined(_BIG_ENDIAN)
4111 		uint32_t	rsrvd:24;
4112 		uint32_t	data:8;
4113 #else
4114 		uint32_t	data:8;
4115 		uint32_t	rsrvd:24;
4116 #endif
4117 	} bits;
4118 } bt_data3_t;
4119 
4120 
4121 /*
4122  * Register: BtIntmask3
4123  * Mailbox Interrupt Mask & Status 3
4124  * Description: Host (blade) <-> SP Block Transfer Interrupt Mask and
4125  * Status register 3
4126  * Host is allowed 8 bits read/write access to this register ; To do
4127  * the same, it should provide the btIntmask3 address, data on
4128  * hostDataBus[23:16], and assert hostBen[2], SPI is allowed 8 bits
4129  * read only access to this register ; To do the same, it should
4130  * provide the btIntmask3 address and no need of spiBen
4131  * All references to the mail box control bits in this register
4132  * refer to btCtrl3
4133  * Fields:
4134  *     The host writes 1 to reset the entire mailbox 3 accesses for
4135  *     error recovery; resets both SP and HOST write and read
4136  *     pointers. Writing 0 has no effect. This is non-sticky. Always
4137  *     read back as 0.
4138  *     Reserved for definition by platform manufacturer for BIOS/SMI
4139  *     Handler use. Generic IPMI software must write this bit as 0
4140  *     and ignore the value on read
4141  *     Reserved for definition by platform manufacturer for BIOS/SMI
4142  *     Handler use. Generic IPMI software must write this bit as 0
4143  *     and ignore the value on read
4144  *     Reserved for definition by platform manufacturer for BIOS/SMI
4145  *     Handler use. Generic IPMI software must write this bit as 0
4146  *     and ignore the value on read
4147  *     SP to HOST Interrupt status This bit reflects the state of the
4148  *     intrpt line to the Host. O/S driver should write 1 to clear.
4149  *     SP to HOST Interrupt Enable The interrupt is generated if
4150  *     sp2hIrqEn is 1 and either sp2hostAtn or smsAtn is 1
4151  */
4152 typedef union {
4153 	uint32_t value;
4154 	struct {
4155 #if defined(_BIG_ENDIAN)
4156 		uint32_t	rsrvd:24;
4157 		uint32_t	mb_master_reset:1;
4158 		uint32_t	rsrvd1:2;
4159 		uint32_t	oem3:1;
4160 		uint32_t	oem2:1;
4161 		uint32_t	oem1:1;
4162 		uint32_t	sp2h_irq:1;
4163 		uint32_t	sp2h_irq_en:1;
4164 #else
4165 		uint32_t	sp2h_irq_en:1;
4166 		uint32_t	sp2h_irq:1;
4167 		uint32_t	oem1:1;
4168 		uint32_t	oem2:1;
4169 		uint32_t	oem3:1;
4170 		uint32_t	rsrvd1:2;
4171 		uint32_t	mb_master_reset:1;
4172 		uint32_t	rsrvd:24;
4173 #endif
4174 	} bits;
4175 } bt_intmask3_t;
4176 
4177 
4178 /*
4179  * Register: DebugSel
4180  * CIP Debug Data Select
4181  * Description: Selects the debug data signals from the CIP blocks
4182  * Fields:
4183  *     Selects up to 16 groups of gbtDebug/pipeDebug on
4184  *     peuPhyVdbgDebugPort[31:0]
4185  *     Selects the high DW of the debug data - default is PCIe link
4186  *     status
4187  *     Selects the low DW of the debug data
4188  */
4189 typedef union {
4190 	uint32_t value;
4191 	struct {
4192 #if defined(_BIG_ENDIAN)
4193 		uint32_t	rsrvd:12;
4194 		uint32_t	phy_dbug_sel:4;
4195 		uint32_t	rsrvd1:3;
4196 		uint32_t	cip_hdbug_sel:5;
4197 		uint32_t	rsrvd2:3;
4198 		uint32_t	cip_ldbug_sel:5;
4199 #else
4200 		uint32_t	cip_ldbug_sel:5;
4201 		uint32_t	rsrvd2:3;
4202 		uint32_t	cip_hdbug_sel:5;
4203 		uint32_t	rsrvd1:3;
4204 		uint32_t	phy_dbug_sel:4;
4205 		uint32_t	rsrvd:12;
4206 #endif
4207 	} bits;
4208 } debug_sel_t;
4209 
4210 
4211 /*
4212  * Register: IndaccMem0Ctrl
4213  * CIP Mem0 Debug ctrl
4214  * Description: Debug data signals from the CIP blocks
4215  * Fields:
4216  *     1: rd/wr access is done 0: rd/wr access is in progress
4217  *     1: pkt injection is done 0: pkt injection is in progress
4218  *     Ingress pkt injection enable: write to 1 for single pkt
4219  *     injection. Must be 0 when enabling diagnostic rd/wr access to
4220  *     memories.
4221  *     1: Diagnostic rd/wr access to memories enabled 0: Diagnostic
4222  *     rd/wr access to memories disabled Must be 0 when enabling pkt
4223  *     injection.
4224  *     1: read, 0: write
4225  *     This bit is read/writable only if mem0Diagen=1 or if
4226  *     mem0Diagen bit is also written with '1' along with enabling
4227  *     this bit. Else, the write will not have any effect. 1: Apply
4228  *     the parity mask provided in the Prty register 0: Do not apply
4229  *     the parity mask provided in the Prty register
4230  *     0 : select npdataq memory 1 : select nphdrq memory 2 : select
4231  *     pdataq memory 3 : select phdrq memory 4 : select cpldataq
4232  *     memory 5 : select cplhdrq memory
4233  */
4234 typedef union {
4235 	uint32_t value;
4236 	struct {
4237 #if defined(_BIG_ENDIAN)
4238 		uint32_t	mem0_access_status:1;
4239 		uint32_t	rsrvd:5;
4240 		uint32_t	mem0_pktinj_stat:1;
4241 		uint32_t	mem0_pktinj_en:1;
4242 		uint32_t	rsrvd1:1;
4243 		uint32_t	mem0_diagen:1;
4244 		uint32_t	mem0_command:1;
4245 		uint32_t	mem0_prty_wen:1;
4246 		uint32_t	rsrvd2:1;
4247 		uint32_t	mem0_sel:3;
4248 		uint32_t	mem0_addr:16;
4249 #else
4250 		uint32_t	mem0_addr:16;
4251 		uint32_t	mem0_sel:3;
4252 		uint32_t	rsrvd2:1;
4253 		uint32_t	mem0_prty_wen:1;
4254 		uint32_t	mem0_command:1;
4255 		uint32_t	mem0_diagen:1;
4256 		uint32_t	rsrvd1:1;
4257 		uint32_t	mem0_pktinj_en:1;
4258 		uint32_t	mem0_pktinj_stat:1;
4259 		uint32_t	rsrvd:5;
4260 		uint32_t	mem0_access_status:1;
4261 #endif
4262 	} bits;
4263 } indacc_mem0_ctrl_t;
4264 
4265 
4266 /*
4267  * Register: IndaccMem0Data0
4268  * CIP Mem0 Debug Data0
4269  * Description: Debug data signals from the CIP blocks
4270  * Fields:
4271  *     When pktInjectionEnable is 0: Data[31:0] from/for the memory
4272  *     selected by mem0Sel bits from mem0Ctrl This data is written to
4273  *     the memory when indaccMem0Ctrl register is written with the
4274  *     write command When indaccMem0Ctrl register is written with the
4275  *     read command, this register will hold the Data[31:0] returned
4276  *     from the memory When pktInjectionEnable is 1:
4277  *     debugData0Reg[31:0] is used in the following ways: [17:16] =
4278  *     radmTrgt1Fmt[1:0]: 2'b00 3DW MRd 2'b01 4DW MRd 2'b10 3DW MWr
4279  *     2'b11 4DW MWr [13:12] = radmTrgt1DwLen[1:0]: 2'b01 1DW 2'b10
4280  *     2DW [11:8] = radmTrgt1LastBe[3:0]: 4'b0000 1DW 4'b1111 2DW [7]
4281  *     = radmTrgt1RomInRange 1'b0 PIO Access 1'b1 EEPROM Access [6:4]
4282  *     = radmTrgt1InMembarRange[2:0] 3'b000 PIO Access 3'b010 MSIX
4283  *     Ram/PBA Table Access [1:0] = radmTrgt1Dwen[1:0] 2'b01
4284  *     1DW->last DW is at radmTrgt1Data[31:0] 2'b11 2DW->last DW is
4285  *     at radmTrgt1Data[63:32]
4286  */
4287 typedef union {
4288 	uint32_t value;
4289 	struct {
4290 #if defined(_BIG_ENDIAN)
4291 		uint32_t	mem0_data0:32;
4292 #else
4293 		uint32_t	mem0_data0:32;
4294 #endif
4295 	} bits;
4296 } indacc_mem0_data0_t;
4297 
4298 
4299 /*
4300  * Register: IndaccMem0Data1
4301  * CIP Mem0 Debug Data1
4302  * Description: Debug data signals from the CIP blocks
4303  * Fields:
4304  *     When pktInjectionEnable is 0: Data[63:32] from/for the memory
4305  *     selected by mem0Sel bits from mem0Ctrl This data is written to
4306  *     the memory when indaccMem0Ctrl register is written with the
4307  *     write command When indaccMem0Ctrl register is written with the
4308  *     read command, this register will hold the Data[63:32] returned
4309  *     from the memory When pktInjectionEnable is 1:
4310  *     debugData1Reg[31:0] is used as radmTrgt1Addr[31:0].
4311  */
4312 typedef union {
4313 	uint32_t value;
4314 	struct {
4315 #if defined(_BIG_ENDIAN)
4316 		uint32_t	mem0_data1:32;
4317 #else
4318 		uint32_t	mem0_data1:32;
4319 #endif
4320 	} bits;
4321 } indacc_mem0_data1_t;
4322 
4323 
4324 /*
4325  * Register: IndaccMem0Data2
4326  * CIP Mem0 Debug Data2
4327  * Description: Debug data signals from the CIP blocks
4328  * Fields:
4329  *     When pktInjectionEnable is 0: Data[95:64] from/for the memory
4330  *     selected by mem0Sel bits from mem0Ctrl This data is written to
4331  *     the memory when indaccMem0Ctrl register is written with the
4332  *     write command When indaccMem0Ctrl register is written with the
4333  *     read command, this register will hold the Data[95:64] returned
4334  *     from the memory When pktInjectionEnable is 1:
4335  *     debugData2Reg[31:0] is used as radmTrgt1Data[63:32]. Allows up
4336  *     to QW=2DW access.
4337  */
4338 typedef union {
4339 	uint32_t value;
4340 	struct {
4341 #if defined(_BIG_ENDIAN)
4342 		uint32_t	mem0_data2:32;
4343 #else
4344 		uint32_t	mem0_data2:32;
4345 #endif
4346 	} bits;
4347 } indacc_mem0_data2_t;
4348 
4349 
4350 /*
4351  * Register: IndaccMem0Data3
4352  * CIP Mem0 Debug Data3
4353  * Description: Debug data signals from the CIP blocks
4354  * Fields:
4355  *     When pktInjectionEnable is 0: Data[127:96] from/for the memory
4356  *     selected by mem0Sel bits from mem0Ctrl This data is written to
4357  *     the memory when indaccMem0Ctrl register is written with the
4358  *     write command When indaccMem0Ctrl register is written with the
4359  *     read command, this register will hold the Data[127:96]
4360  *     returned from the memory When pktInjectionEnable is 1:
4361  *     debugData3Reg[31:0] is used as radmTrgt1Data[31:0].
4362  */
4363 typedef union {
4364 	uint32_t value;
4365 	struct {
4366 #if defined(_BIG_ENDIAN)
4367 		uint32_t	mem0_data3:32;
4368 #else
4369 		uint32_t	mem0_data3:32;
4370 #endif
4371 	} bits;
4372 } indacc_mem0_data3_t;
4373 
4374 
4375 /*
4376  * Register: IndaccMem0Prty
4377  * CIP Mem0 Debug Parity
4378  * Description: Debug data signals from the CIP blocks
4379  * Fields:
4380  *     parity mask bits for the memory selected by mem0Sel bits from
4381  *     mem0Ctrl to inject parity error These bits serve two purposes
4382  *     regarding memory parity : - During indirect write access to
4383  *     the memories, the value in this register is applied as mask to
4384  *     the actual parity if prtyWen bit of the indaccCtrl register
4385  *     has been enabled. The masked parity and data are written into
4386  *     the specified memory location. - During indirect read access
4387  *     to the memories, the value in this register is overwritten
4388  *     with the parity value read from the memory location. If the
4389  *     parity mask had been set and enabled to be written into this
4390  *     location it will generate parity error for that memory
4391  *     location
4392  */
4393 typedef union {
4394 	uint32_t value;
4395 	struct {
4396 #if defined(_BIG_ENDIAN)
4397 		uint32_t	rsrvd:18;
4398 		uint32_t	mem0_parity:14;
4399 #else
4400 		uint32_t	mem0_parity:14;
4401 		uint32_t	rsrvd:18;
4402 #endif
4403 	} bits;
4404 } indacc_mem0_prty_t;
4405 
4406 
4407 /*
4408  * Register: IndaccMem1Ctrl
4409  * CIP Mem1 Debug ctrl
4410  * Description: Debug data signals from the CIP blocks
4411  * Fields:
4412  *     1: rd/wr access is done 0: rd/wr access is in progress
4413  *     1: client pkt injection is done 0: client pkt injection is in
4414  *     progress
4415  *     1: client1 pkt injection 0: client0 pkt injection
4416  *     Mutually exclusive: Either client0 or client1 egress pkt
4417  *     injection enable: write to 1 for single pkt injection. Must be
4418  *     0 when enabling diagnostic rd/wr access to memories.
4419  *     1: Diagnostic rd/wr access enabled 0: Diagnostic rd/wr access
4420  *     disabled Must be 0 when enabling pkt injection.
4421  *     1: read, 0: write
4422  *     This bit is read/writable only if mem1Diagen=1 or if
4423  *     mem1Diagen bit is also written with '1' along with enabling
4424  *     this bit. Else, the write will not have any effect. 1: Apply
4425  *     the parity mask provided in the Prty register 0: Do not apply
4426  *     the parity mask provided in the Prty register
4427  *     0 : select retry sot memory 1 : select retry buffer memory 2 :
4428  *     select msix memory 3 : select hcr cfg memory
4429  */
4430 typedef union {
4431 	uint32_t value;
4432 	struct {
4433 #if defined(_BIG_ENDIAN)
4434 		uint32_t	mem1_access_status:1;
4435 		uint32_t	rsrvd:4;
4436 		uint32_t	mem1_pktinj_stat:1;
4437 		uint32_t	mem1_pktinj_client:1;
4438 		uint32_t	mem1_pktinj_en:1;
4439 		uint32_t	rsrvd1:1;
4440 		uint32_t	mem1_diagen:1;
4441 		uint32_t	mem1_command:1;
4442 		uint32_t	mem1_prty_wen:1;
4443 		uint32_t	rsrvd2:2;
4444 		uint32_t	mem1_sel:2;
4445 		uint32_t	mem1_addr:16;
4446 #else
4447 		uint32_t	mem1_addr:16;
4448 		uint32_t	mem1_sel:2;
4449 		uint32_t	rsrvd2:2;
4450 		uint32_t	mem1_prty_wen:1;
4451 		uint32_t	mem1_command:1;
4452 		uint32_t	mem1_diagen:1;
4453 		uint32_t	rsrvd1:1;
4454 		uint32_t	mem1_pktinj_en:1;
4455 		uint32_t	mem1_pktinj_client:1;
4456 		uint32_t	mem1_pktinj_stat:1;
4457 		uint32_t	rsrvd:4;
4458 		uint32_t	mem1_access_status:1;
4459 #endif
4460 	} bits;
4461 } indacc_mem1_ctrl_t;
4462 
4463 
4464 /*
4465  * Register: IndaccMem1Data0
4466  * CIP Mem1 Debug Data0
4467  * Description: Debug data signals from the CIP blocks
4468  * Fields:
4469  *     When pktInjectionEnable is 0: Data[31:0] from/for the memory
4470  *     selected by mem1Sel bits from mem1Ctrl This data is written to
4471  *     the memory when indaccMem1Ctrl register is written with the
4472  *     write command When indaccMem1Ctrl register is written with the
4473  *     read command, this register will hold the Data[31:0] returned
4474  *     from the memory
4475  * When pktInjectionEnable is 1: debugData0Reg[31:0] is used in
4476  *     the following ways: [27:26] = tdcPeuTlp0[or
4477  *     rdcPeuTlp1]_fmt[1:0]: 2'b00 3DW MRd 2'b01 4DW MRd 2'b10 3DW
4478  *     MWr 2'b11 4DW MWr [25:13] = tdcPeuTlp0[or
4479  *     rdcPeuTlp1]_byteLen[12:0]: Note MWr must be limited to 4B =
4480  *     13'b0000000000001. [12:8] = tdcPeuTlp0[or
4481  *     rdcPeuTlp1]_tid[4:0]: 5 lsb of tid (TAG ID) [7:0] =
4482  *     tdcPeuTlp0[or rdcPeuTlp1]_byteEn[7:0]: [7:4] = last DW byte
4483  *     enables [3:0] = first DW byte enables
4484  */
4485 typedef union {
4486 	uint32_t value;
4487 	struct {
4488 #if defined(_BIG_ENDIAN)
4489 		uint32_t	mem1_data0:32;
4490 #else
4491 		uint32_t	mem1_data0:32;
4492 #endif
4493 	} bits;
4494 } indacc_mem1_data0_t;
4495 
4496 
4497 /*
4498  * Register: IndaccMem1Data1
4499  * CIP Mem1 Debug Data1
4500  * Description: Debug data signals from the CIP blocks
4501  * Fields:
4502  *     When pktInjectionEnable is 0: Data[63:32] from/for the memory
4503  *     selected by mem1Sel bits from mem1Ctrl This data is written to
4504  *     the memory when indaccMem1Ctrl register is written with the
4505  *     write command When indaccMem1Ctrl register is written with the
4506  *     read command, this register will hold the Data[63:32] returned
4507  *     from the memory
4508  * When pktInjectionEnable is 1: debugData1Reg[31:0] is used as
4509  *     tdcPeuTlp0[or rdcPeuTlp1]_addr[63:32] high address bits.
4510  */
4511 typedef union {
4512 	uint32_t value;
4513 	struct {
4514 #if defined(_BIG_ENDIAN)
4515 		uint32_t	mem1_data1:32;
4516 #else
4517 		uint32_t	mem1_data1:32;
4518 #endif
4519 	} bits;
4520 } indacc_mem1_data1_t;
4521 
4522 
4523 /*
4524  * Register: IndaccMem1Data2
4525  * CIP Mem1 Debug Data2
4526  * Description: Debug data signals from the CIP blocks
4527  * Fields:
4528  *     When pktInjectionEnable is 0: Data[95:64] from/for the memory
4529  *     selected by mem1Sel bits from mem1Ctrl This data is written to
4530  *     the memory when indaccMem1Ctrl register is written with the
4531  *     write command When indaccMem1Ctrl register is written with the
4532  *     read command, this register will hold the Data[95:64] returned
4533  *     from the memory
4534  * When pktInjectionEnable is 1: debugData2Reg[31:0] is used as
4535  *     tdcPeuTlp0[or rdcPeuTlp1]_addr[31:0] low address bits.
4536  */
4537 typedef union {
4538 	uint32_t value;
4539 	struct {
4540 #if defined(_BIG_ENDIAN)
4541 		uint32_t	mem1_data2:32;
4542 #else
4543 		uint32_t	mem1_data2:32;
4544 #endif
4545 	} bits;
4546 } indacc_mem1_data2_t;
4547 
4548 
4549 /*
4550  * Register: IndaccMem1Data3
4551  * CIP Mem1 Debug Data3
4552  * Description: Debug data signals from the CIP blocks
4553  * Fields:
4554  *     When pktInjectionEnable is 0: Data[127:96] from/for the memory
4555  *     selected by mem1Sel bits from mem1Ctrl This data is written to
4556  *     the memory when indaccMem1Ctrl register is written with the
4557  *     write command When indaccMem1Ctrl register is written with the
4558  *     read command, this register will hold the Data[127:96]
4559  *     returned from the memory
4560  * When pktInjectionEnable is 1: debugData3Reg[31:0] is used as
4561  *     tdcPeuTlp0[or rdcPeuTlp1]_data[31:0] Limited for MWr to 1 DW.
4562  */
4563 typedef union {
4564 	uint32_t value;
4565 	struct {
4566 #if defined(_BIG_ENDIAN)
4567 		uint32_t	mem1_data3:32;
4568 #else
4569 		uint32_t	mem1_data3:32;
4570 #endif
4571 	} bits;
4572 } indacc_mem1_data3_t;
4573 
4574 
4575 /*
4576  * Register: IndaccMem1Prty
4577  * CIP Mem1 Debug Parity
4578  * Description: Debug data signals from the CIP blocks
4579  * Fields:
4580  *     parity mask bits for the memory selected by mem1Sel bits from
4581  *     mem1Ctrl to inject parity error These bits serve two purposes
4582  *     regarding memory parity : - During indirect write access to
4583  *     the memories, the value in this register is applied as mask to
4584  *     the actual parity if prtyWen bit of the indaccCtrl register
4585  *     has been enabled. The masked parity and data are written into
4586  *     the specified memory location. - During indirect read access
4587  *     to the memories, the value in this register is overwritten
4588  *     with the parity value read from the memory location. If the
4589  *     parity mask had been set and enabled to be written into this
4590  *     location it will generate parity error for that memory
4591  *     location
4592  */
4593 typedef union {
4594 	uint32_t value;
4595 	struct {
4596 #if defined(_BIG_ENDIAN)
4597 		uint32_t	rsrvd:20;
4598 		uint32_t	mem1_parity:12;
4599 #else
4600 		uint32_t	mem1_parity:12;
4601 		uint32_t	rsrvd:20;
4602 #endif
4603 	} bits;
4604 } indacc_mem1_prty_t;
4605 
4606 
4607 /*
4608  * Register: PhyDebugTrainingVec
4609  * peuPhy Debug Training Vector
4610  * Description: peuPhy Debug Training Vector register.
4611  * Fields:
4612  *     Hard-coded value for peuPhy wrt global debug training block
4613  *     signatures.
4614  *     Blade Number, the value read depends on the blade this block
4615  *     resides
4616  *     debug training vector the sub-group select value of 0 selects
4617  *     this vector
4618  */
4619 typedef union {
4620 	uint32_t value;
4621 	struct {
4622 #if defined(_BIG_ENDIAN)
4623 		uint32_t	dbg_msb:1;
4624 		uint32_t	bld_num:3;
4625 		uint32_t	phydbg_training_vec:28;
4626 #else
4627 		uint32_t	phydbg_training_vec:28;
4628 		uint32_t	bld_num:3;
4629 		uint32_t	dbg_msb:1;
4630 #endif
4631 	} bits;
4632 } phy_debug_training_vec_t;
4633 
4634 
4635 /*
4636  * Register: PeuDebugTrainingVec
4637  * PEU Debug Training Vector
4638  * Description: PEU Debug Training Vector register.
4639  * Fields:
4640  *     Hard-coded value for PEU (VNMy - core clk domain) wrt global
4641  *     debug training block signatures.
4642  *     Blade Number, the value read depends on the blade this block
4643  *     resides
4644  *     debug training vector the sub-group select value of 0 selects
4645  *     this vector
4646  *     Hard-coded value for PEU (VNMy - core clk domain) wrt global
4647  *     debug training block signatures.
4648  *     Blade Number, the value read depends on the blade this block
4649  *     resides
4650  *     debug training vector the sub-group select value of 0 selects
4651  *     this vector
4652  */
4653 typedef union {
4654 	uint32_t value;
4655 	struct {
4656 #if defined(_BIG_ENDIAN)
4657 		uint32_t	dbgmsb_upper:1;
4658 		uint32_t	bld_num_upper:3;
4659 		uint32_t	peudbg_upper_training_vec:12;
4660 		uint32_t	dbgmsb_lower:1;
4661 		uint32_t	bld_num_lower:3;
4662 		uint32_t	peudbg_lower_training_vec:12;
4663 #else
4664 		uint32_t	peudbg_lower_training_vec:12;
4665 		uint32_t	bld_num_lower:3;
4666 		uint32_t	dbgmsb_lower:1;
4667 		uint32_t	peudbg_upper_training_vec:12;
4668 		uint32_t	bld_num_upper:3;
4669 		uint32_t	dbgmsb_upper:1;
4670 #endif
4671 	} bits;
4672 } peu_debug_training_vec_t;
4673 
4674 
4675 /*
4676  * Register: PipeCfg0
4677  * PIPE Configuration
4678  * Description: These are controls signals for the pipe core and are
4679  * used to define the PIPE core configuration with PipeCfg1 reg value
4680  * (0x08124)
4681  * Fields:
4682  *     If this bit is 1 when pipe reset is released, then the value
4683  *     on the pipe core's input port 'pipeParameter' is loaded into
4684  *     the Pipe Core's internal Rx/Tx Parameter register which is
4685  *     pipeRxTxParam at addr 0x01010. Note that it is software's
4686  *     responsibility to program the pipeParameter (Pipe Cfg1)
4687  *     register correctly: e.g. LOSADJ must be 0x1.
4688  */
4689 typedef union {
4690 	uint32_t value;
4691 	struct {
4692 #if defined(_BIG_ENDIAN)
4693 		uint32_t	rsrvd:21;
4694 		uint32_t	pipe_serdes_x1:1;
4695 		uint32_t	pipe_force_ewrap:1;
4696 		uint32_t	pipe_force_loopback:1;
4697 		uint32_t	pipe_force_parm:1;
4698 		uint32_t	pipe_freq_sel:1;
4699 		uint32_t	pipe_p1_pdown:1;
4700 		uint32_t	pipe_p1_pdtx:1;
4701 		uint32_t	pipe_same_sel:1;
4702 		uint32_t	pipe_system_clk:1;
4703 		uint32_t	gbt_term_i:2;
4704 #else
4705 		uint32_t	gbt_term_i:2;
4706 		uint32_t	pipe_system_clk:1;
4707 		uint32_t	pipe_same_sel:1;
4708 		uint32_t	pipe_p1_pdtx:1;
4709 		uint32_t	pipe_p1_pdown:1;
4710 		uint32_t	pipe_freq_sel:1;
4711 		uint32_t	pipe_force_parm:1;
4712 		uint32_t	pipe_force_loopback:1;
4713 		uint32_t	pipe_force_ewrap:1;
4714 		uint32_t	pipe_serdes_x1:1;
4715 		uint32_t	rsrvd:21;
4716 #endif
4717 	} bits;
4718 } pipe_cfg0_t;
4719 
4720 
4721 /*
4722  * Register: PipeCfg1
4723  * PIPE Configuration
4724  * Description: These values define the PIPE core configuration and
4725  * is presented on the Pipe core's input port 'pipeParameter'.
4726  * The value on the pipe core's input 'pipeParameter' is loaded into
4727  * the pipe core's internal Rx/Tx Parameter register, which is
4728  * pipeRxTxParam at addr 0x01010, by forcing the pipeForceParm bit of
4729  * the Pipe Cfg0 Register at address 0x08120.
4730  *
4731  * Fields:
4732  *     Tx Driver Emphasis
4733  *     Serial output Slew Rate Control
4734  *     Tx Voltage Mux control
4735  *     Tx Voltage Pulse control
4736  *     Output Swing setting
4737  *     Transmitter Clock generator pole adjust
4738  *     Transmitter Clock generator zero adjust
4739  *     Receiver Clock generator pole adjust
4740  *     Receiver Clock generator zero adjust
4741  *     Bias Control for factory testing and debugging
4742  *     Receiver LOS Threshold adjustment. LSI suggests this POR
4743  *     default value must be 0x1 (which is the POR default value of
4744  *     the Pipe Rx/Tx Parameter Register).
4745  *     Receiver Input Equalizer control
4746  */
4747 typedef union {
4748 	uint32_t value;
4749 	struct {
4750 #if defined(_BIG_ENDIAN)
4751 		uint32_t	rsrvd:1;
4752 		uint32_t	emph:3;
4753 		uint32_t	rsrvd1:1;
4754 		uint32_t	risefall:3;
4755 		uint32_t	vmuxlo:2;
4756 		uint32_t	vpulselo:2;
4757 		uint32_t	vtxlo:4;
4758 		uint32_t	tp:2;
4759 		uint32_t	tz:2;
4760 		uint32_t	rp:2;
4761 		uint32_t	rz:2;
4762 		uint32_t	biascntl:1;
4763 		uint32_t	losadj:3;
4764 		uint32_t	rxeq:4;
4765 #else
4766 		uint32_t	rxeq:4;
4767 		uint32_t	losadj:3;
4768 		uint32_t	biascntl:1;
4769 		uint32_t	rz:2;
4770 		uint32_t	rp:2;
4771 		uint32_t	tz:2;
4772 		uint32_t	tp:2;
4773 		uint32_t	vtxlo:4;
4774 		uint32_t	vpulselo:2;
4775 		uint32_t	vmuxlo:2;
4776 		uint32_t	risefall:3;
4777 		uint32_t	rsrvd1:1;
4778 		uint32_t	emph:3;
4779 		uint32_t	rsrvd:1;
4780 #endif
4781 	} bits;
4782 } pipe_cfg1_t;
4783 
4784 
4785 /*
4786  * Register: CipBarMaskCfg
4787  * BAR Mask Config
4788  * Description: To write to the BAR MASK registers in the EP Core PCI
4789  * Config registers This register should be initialised before
4790  * writing the value to into the cipBarMask register. The lower 3
4791  * bits define the BAR register number whose mask value has to be
4792  * over written with the values that will be written into the
4793  * cipBarMask register. [2:0] = 0 thru 5 selects bar0Mask thru
4794  * bar5Mask registers = 6,7 selects Expansion romBarMask register
4795  * Hydra's configuration for the BARs is as below : BAR1, BAR0 :
4796  * Forms 64 bit PIO BAR. BAR1 handles the upper address bits BAR0
4797  * handles the lower address bits BAR3, BAR2 : Forms 64 bit MSIX BAR
4798  * BAR3 handles the upper address bits BAR2 handles the lower address
4799  * bits BAR5, BAR4 : Not used and so disabled. Hence, user writes
4800  * will not have any effect. romBar : Expansion romBar
4801  *
4802  * Fields:
4803  *     0 : bar0Mask 1 : bar1Mask 2 : bar2Mask 3 : bar3Mask 4 :
4804  *     bar4Mask 5 : bar5Mask 6, 7 ; romBarMask
4805  */
4806 typedef union {
4807 	uint32_t value;
4808 	struct {
4809 #if defined(_BIG_ENDIAN)
4810 		uint32_t	rsrvd:29;
4811 		uint32_t	data:3;
4812 #else
4813 		uint32_t	data:3;
4814 		uint32_t	rsrvd:29;
4815 #endif
4816 	} bits;
4817 } cip_bar_mask_cfg_t;
4818 
4819 
4820 /*
4821  * Register: CipBarMask
4822  * BAR Mask
4823  * Description: Value to write to the BAR MASK registers in the EP
4824  * Core PCI Config registers The lower 3 bits of cipMaskCfg register
4825  * define the BAR register number Write to this register will
4826  * initiate the DBI access to the EP Core. The cipBarMaskCfg register
4827  * should be setup before writing to this register. [31:1] = Mask
4828  * value [0] = 1: BAR is enabled; 0: BAR is disabled. Note that the
4829  * BAR must be enabled ([0] == 1) before the Mask value will be
4830  * written into the actual bar mask register. If the BAR is disabled
4831  * ([0]==0), two writes to this register are required before the Mask
4832  * value is written into the actual bar mask register. Refer to EP
4833  * core data book for more details.
4834  *
4835  * Fields:
4836  */
4837 typedef union {
4838 	uint32_t value;
4839 	struct {
4840 #if defined(_BIG_ENDIAN)
4841 		uint32_t	data:32;
4842 #else
4843 		uint32_t	data:32;
4844 #endif
4845 	} bits;
4846 } cip_bar_mask_t;
4847 
4848 
4849 /*
4850  * Register: CipLdsv0Stat
4851  * LDSV0 Status (for debug purpose)
4852  * Description: Returns the status of LDSV0 Flags regardless of their
4853  * group
4854  *
4855  * Fields:
4856  */
4857 typedef union {
4858 	uint32_t value;
4859 	struct {
4860 #if defined(_BIG_ENDIAN)
4861 		uint32_t	data:32;
4862 #else
4863 		uint32_t	data:32;
4864 #endif
4865 	} bits;
4866 } cip_ldsv0_stat_t;
4867 
4868 
4869 /*
4870  * Register: CipLdsv1Stat
4871  * LDSV1 Status (for debug purpose)
4872  * Description: Returns the status of LDSV1 Flags regardless of their
4873  * group
4874  *
4875  * Fields:
4876  */
4877 typedef union {
4878 	uint32_t value;
4879 	struct {
4880 #if defined(_BIG_ENDIAN)
4881 		uint32_t	data:32;
4882 #else
4883 		uint32_t	data:32;
4884 #endif
4885 	} bits;
4886 } cip_ldsv1_stat_t;
4887 
4888 
4889 /*
4890  * Register: PeuIntrStat
4891  * PEU Interrupt Status
4892  * Description: Returns the parity error status of all of the PEU
4893  * RAMs, and external (to peu) block pio access errors. External
4894  * block pio access errors could be due to either host or SPI
4895  * initiated accesses. These fields are RO and can be cleared only
4896  * through a cip reset All these errors feed to devErrStat.peuErr1
4897  * which in turn feed to LDSV1.devErr1
4898  * Partity Error bits: These bits log the very first parity error
4899  * detected in a particular memory. The corresponding memory location
4900  * is logged in respective perrLoc registers. External Block PIO
4901  * Access Error bits: These bits log the very first error that
4902  * resulted in access error. The corresponding address is logged in
4903  * respective accErrLog registers.
4904  * These bits can be set by writing a '1' to the corresponding
4905  * mirror bit in the peuIntrStatMirror register.
4906  * Note: PEU RAM Parity Errors and their corresponding interrupt:
4907  * When these bits are set and the device error status interrupt is
4908  * not masked, the PEU attempts to send the corresponding interrupt
4909  * back to the RC. Depending on which ram is impacted and the
4910  * corresponding logic impacted in the EP core, a coherent interrupt
4911  * message may not be sent in all cases. For the times when the EP
4912  * core is unable to send an interrupt, the SPI interface is to be
4913  * used for error diagnosis as the PEU interrupt status is logged
4914  * regardless of whether the interrupt is sent to the RC. The
4915  * following data was collected via simulation: -Parity error
4916  * impacted rams that likely will be able to send an interrupt:
4917  * npDataq, pDataq, cplDataq, hcr. -Parity error impacted rams that
4918  * may not be able to send an interrupt: npHdrq, pHdrq, cplHdrq, MSIx
4919  * table, retryram, retrysot.
4920  *
4921  * Fields:
4922  *     Error indication from SPROM Controller for Sprom Download
4923  *     access This error indicates that a parity error was detected
4924  *     from SRAM. For more details, please refer to SPROM Controller
4925  *     PRM.
4926  *     Error indication from TDC for PIO access The error location
4927  *     and type are logged in tdcPioaccErrLog
4928  *     Error indication from RDC for PIO access The error location
4929  *     and type are logged in rdcPioaccErrLog
4930  *     Error indication from PFC for PIO access The error location
4931  *     and type are logged in pfcPioaccErrLog
4932  *     Error indication from VMAC for PIO access The error location
4933  *     and type are logged in vmacPioaccErrLog
4934  *     memory in PCIe data path and value unknown until packet flow
4935  *     starts.
4936  *     memory in PCIe data path and value unknown until packet flow
4937  *     starts.
4938  *     memory in PCIe data path and value unknown until packet flow
4939  *     starts.
4940  *     memory in PCIe data path and value unknown until packet flow
4941  *     starts.
4942  *     memory in PCIe data path and value unknown until packet flow
4943  *     starts.
4944  *     memory in PCIe data path and value unknown until packet flow
4945  *     starts.
4946  *     memory in PCIe data path and value unknown until packet flow
4947  *     starts.
4948  *     memory in PCIe data path and value unknown until packet flow
4949  *     starts.
4950  */
4951 typedef union {
4952 	uint32_t value;
4953 	struct {
4954 #if defined(_BIG_ENDIAN)
4955 		uint32_t	rsrvd:11;
4956 		uint32_t	spc_acc_err:1;
4957 		uint32_t	tdc_pioacc_err:1;
4958 		uint32_t	rdc_pioacc_err:1;
4959 		uint32_t	pfc_pioacc_err:1;
4960 		uint32_t	vmac_pioacc_err:1;
4961 		uint32_t	rsrvd1:6;
4962 		uint32_t	cpl_hdrq_parerr:1;
4963 		uint32_t	cpl_dataq_parerr:1;
4964 		uint32_t	retryram_xdlh_parerr:1;
4965 		uint32_t	retrysotram_xdlh_parerr:1;
4966 		uint32_t	p_hdrq_parerr:1;
4967 		uint32_t	p_dataq_parerr:1;
4968 		uint32_t	np_hdrq_parerr:1;
4969 		uint32_t	np_dataq_parerr:1;
4970 		uint32_t	eic_msix_parerr:1;
4971 		uint32_t	hcr_parerr:1;
4972 #else
4973 		uint32_t	hcr_parerr:1;
4974 		uint32_t	eic_msix_parerr:1;
4975 		uint32_t	np_dataq_parerr:1;
4976 		uint32_t	np_hdrq_parerr:1;
4977 		uint32_t	p_dataq_parerr:1;
4978 		uint32_t	p_hdrq_parerr:1;
4979 		uint32_t	retrysotram_xdlh_parerr:1;
4980 		uint32_t	retryram_xdlh_parerr:1;
4981 		uint32_t	cpl_dataq_parerr:1;
4982 		uint32_t	cpl_hdrq_parerr:1;
4983 		uint32_t	rsrvd1:6;
4984 		uint32_t	vmac_pioacc_err:1;
4985 		uint32_t	pfc_pioacc_err:1;
4986 		uint32_t	rdc_pioacc_err:1;
4987 		uint32_t	tdc_pioacc_err:1;
4988 		uint32_t	spc_acc_err:1;
4989 		uint32_t	rsrvd:11;
4990 #endif
4991 	} bits;
4992 } peu_intr_stat_t;
4993 
4994 
4995 /*
4996  * Register: PeuIntrMask
4997  * Parity Error Status Mask
4998  * Description: Masks for interrupt generation for block and parity
4999  * error in the PEU RAMs For the VNM errors (spc, tdc, rdc, pfc, &
5000  * vmac), note that the interrupt message to the host will be delayed
5001  * from the actual moment that the error is detected until the host
5002  * does a PIO access and this mask is cleared.
5003  *
5004  * Fields:
5005  *     1: Mask interrupt generation for access error from SPROM
5006  *     Controller
5007  *     1: Mask interrupt generation for PIO access error from TDC
5008  *     1: Mask interrupt generation for PIO access error from RDC
5009  *     1: Mask interrupt generation for PIO access error from PFC
5010  *     1: Mask interrupt generation for PIO access error from VMAC
5011  *     1: Mask interrupt generation for parity error from Completion
5012  *     Header Q memory
5013  *     1: Mask interrupt generation for parity error from Completion
5014  *     Data Q memory
5015  *     1: Mask interrupt generation for parity error from Retry
5016  *     memory
5017  *     1: Mask interrupt generation for parity error from Retry SOT
5018  *     memory
5019  *     1: Mask interrupt generation for parity error from Posted
5020  *     Header Q memory
5021  *     1: Mask interrupt generation for parity error from Posted Data
5022  *     Q memory
5023  *     1: Mask interrupt generation for parity error from Non-Posted
5024  *     Header Q memory
5025  *     1: Mask interrupt generation for parity error from Non-Posted
5026  *     Data Q memory
5027  *     1: Mask interrupt generation for parity error from MSIX memory
5028  *     1: Mask interrupt generation for parity error from HCR memory
5029  */
5030 typedef union {
5031 	uint32_t value;
5032 	struct {
5033 #if defined(_BIG_ENDIAN)
5034 		uint32_t	rsrvd:11;
5035 		uint32_t	spc_acc_err_mask:1;
5036 		uint32_t	tdc_pioacc_err_mask:1;
5037 		uint32_t	rdc_pioacc_err_mask:1;
5038 		uint32_t	pfc_pioacc_err_mask:1;
5039 		uint32_t	vmac_pioacc_err_mask:1;
5040 		uint32_t	rsrvd1:6;
5041 		uint32_t	cpl_hdrq_parerr_mask:1;
5042 		uint32_t	cpl_dataq_parerr_mask:1;
5043 		uint32_t	retryram_xdlh_parerr_mask:1;
5044 		uint32_t	retrysotram_xdlh_parerr_mask:1;
5045 		uint32_t	p_hdrq_parerr_mask:1;
5046 		uint32_t	p_dataq_parerr_mask:1;
5047 		uint32_t	np_hdrq_parerr_mask:1;
5048 		uint32_t	np_dataq_parerr_mask:1;
5049 		uint32_t	eic_msix_parerr_mask:1;
5050 		uint32_t	hcr_parerr_mask:1;
5051 #else
5052 		uint32_t	hcr_parerr_mask:1;
5053 		uint32_t	eic_msix_parerr_mask:1;
5054 		uint32_t	np_dataq_parerr_mask:1;
5055 		uint32_t	np_hdrq_parerr_mask:1;
5056 		uint32_t	p_dataq_parerr_mask:1;
5057 		uint32_t	p_hdrq_parerr_mask:1;
5058 		uint32_t	retrysotram_xdlh_parerr_mask:1;
5059 		uint32_t	retryram_xdlh_parerr_mask:1;
5060 		uint32_t	cpl_dataq_parerr_mask:1;
5061 		uint32_t	cpl_hdrq_parerr_mask:1;
5062 		uint32_t	rsrvd1:6;
5063 		uint32_t	vmac_pioacc_err_mask:1;
5064 		uint32_t	pfc_pioacc_err_mask:1;
5065 		uint32_t	rdc_pioacc_err_mask:1;
5066 		uint32_t	tdc_pioacc_err_mask:1;
5067 		uint32_t	spc_acc_err_mask:1;
5068 		uint32_t	rsrvd:11;
5069 #endif
5070 	} bits;
5071 } peu_intr_mask_t;
5072 
5073 
5074 /*
5075  * Register: PeuIntrStatMirror
5076  * Parity Error Status Mirror
5077  * Description: Mirror bits for Parity error generation in the PEU
5078  * RAMs When set, the corresponding parity error is generated ; this
5079  * will cause an interrupt to occur if the respective mask bit is not
5080  * set. As the mirror of the Parity Error Status Register, clearing
5081  * of the status bits is controlled by how the Parity Error Status
5082  * Register is cleared. These bits cannot be cleared by writing 0 to
5083  * this register.
5084  *
5085  * Fields:
5086  */
5087 typedef union {
5088 	uint32_t value;
5089 	struct {
5090 #if defined(_BIG_ENDIAN)
5091 		uint32_t	rsrvd:11;
5092 		uint32_t	spc_acc_err_mirror:1;
5093 		uint32_t	tdc_pioacc_err_mirror:1;
5094 		uint32_t	rdc_pioacc_err_mirror:1;
5095 		uint32_t	pfc_pioacc_err_mirror:1;
5096 		uint32_t	vmac_pioacc_err_mirror:1;
5097 		uint32_t	rsrvd1:6;
5098 		uint32_t	cpl_hdrq_parerr_mirror:1;
5099 		uint32_t	cpl_dataq_parerr_mirror:1;
5100 		uint32_t	retryram_xdlh_parerr_mirror:1;
5101 		uint32_t	retrysotram_xdlh_parerr_mirror:1;
5102 		uint32_t	p_hdrq_parerr_mirror:1;
5103 		uint32_t	p_dataq_parerr_mirror:1;
5104 		uint32_t	np_hdrq_parerr_mirror:1;
5105 		uint32_t	np_dataq_parerr_mirror:1;
5106 		uint32_t	eic_msix_parerr_mirror:1;
5107 		uint32_t	hcr_parerr_mirror:1;
5108 #else
5109 		uint32_t	hcr_parerr_mirror:1;
5110 		uint32_t	eic_msix_parerr_mirror:1;
5111 		uint32_t	np_dataq_parerr_mirror:1;
5112 		uint32_t	np_hdrq_parerr_mirror:1;
5113 		uint32_t	p_dataq_parerr_mirror:1;
5114 		uint32_t	p_hdrq_parerr_mirror:1;
5115 		uint32_t	retrysotram_xdlh_parerr_mirror:1;
5116 		uint32_t	retryram_xdlh_parerr_mirror:1;
5117 		uint32_t	cpl_dataq_parerr_mirror:1;
5118 		uint32_t	cpl_hdrq_parerr_mirror:1;
5119 		uint32_t	rsrvd1:6;
5120 		uint32_t	vmac_pioacc_err_mirror:1;
5121 		uint32_t	pfc_pioacc_err_mirror:1;
5122 		uint32_t	rdc_pioacc_err_mirror:1;
5123 		uint32_t	tdc_pioacc_err_mirror:1;
5124 		uint32_t	spc_acc_err_mirror:1;
5125 		uint32_t	rsrvd:11;
5126 #endif
5127 	} bits;
5128 } peu_intr_stat_mirror_t;
5129 
5130 
5131 /*
5132  * Register: CplHdrqPerrLoc
5133  * Completion Header Queue Parity Error Location
5134  * Description: Returns the location of the first parity error
5135  * detected in Completion Header Q
5136  *
5137  * Fields:
5138  */
5139 typedef union {
5140 	uint32_t value;
5141 	struct {
5142 #if defined(_BIG_ENDIAN)
5143 		uint32_t	rsrvd:16;
5144 		uint32_t	cpl_hdrq_parerr_loc:16;
5145 #else
5146 		uint32_t	cpl_hdrq_parerr_loc:16;
5147 		uint32_t	rsrvd:16;
5148 #endif
5149 	} bits;
5150 } cpl_hdrq_perr_loc_t;
5151 
5152 
5153 /*
5154  * Register: CplDataqPerrLoc
5155  * Completion Data Queue Parity Error Location
5156  * Description: Returns the location of the first parity error
5157  * detected in Completion Data Q
5158  *
5159  * Fields:
5160  */
5161 typedef union {
5162 	uint32_t value;
5163 	struct {
5164 #if defined(_BIG_ENDIAN)
5165 		uint32_t	rsrvd:16;
5166 		uint32_t	cpl_dataq_parerr_loc:16;
5167 #else
5168 		uint32_t	cpl_dataq_parerr_loc:16;
5169 		uint32_t	rsrvd:16;
5170 #endif
5171 	} bits;
5172 } cpl_dataq_perr_loc_t;
5173 
5174 
5175 /*
5176  * Register: RetrPerrLoc
5177  * Retry RAM Parity Error Location
5178  * Description: Returns the location of the first parity error
5179  * detected in Retry RAM
5180  *
5181  * Fields:
5182  */
5183 typedef union {
5184 	uint32_t value;
5185 	struct {
5186 #if defined(_BIG_ENDIAN)
5187 		uint32_t	rsrvd:16;
5188 		uint32_t	retr_parerr_loc:16;
5189 #else
5190 		uint32_t	retr_parerr_loc:16;
5191 		uint32_t	rsrvd:16;
5192 #endif
5193 	} bits;
5194 } retr_perr_loc_t;
5195 
5196 
5197 /*
5198  * Register: RetrSotPerrLoc
5199  * Retry SOT RAM Parity Error Location
5200  * Description: Returns the location of the first parity error
5201  * detected in Retry RAM SOT
5202  *
5203  * Fields:
5204  */
5205 typedef union {
5206 	uint32_t value;
5207 	struct {
5208 #if defined(_BIG_ENDIAN)
5209 		uint32_t	rsrvd:16;
5210 		uint32_t	retr_sot_parerr_loc:16;
5211 #else
5212 		uint32_t	retr_sot_parerr_loc:16;
5213 		uint32_t	rsrvd:16;
5214 #endif
5215 	} bits;
5216 } retr_sot_perr_loc_t;
5217 
5218 
5219 /*
5220  * Register: PHdrqPerrLoc
5221  * Posted Header Queue Parity Error Location
5222  * Description: Returns the location of the first parity error
5223  * detected in Posted Header Q
5224  *
5225  * Fields:
5226  */
5227 typedef union {
5228 	uint32_t value;
5229 	struct {
5230 #if defined(_BIG_ENDIAN)
5231 		uint32_t	rsrvd:16;
5232 		uint32_t	p_hdrq_parerr_loc:16;
5233 #else
5234 		uint32_t	p_hdrq_parerr_loc:16;
5235 		uint32_t	rsrvd:16;
5236 #endif
5237 	} bits;
5238 } p_hdrq_perr_loc_t;
5239 
5240 
5241 /*
5242  * Register: PDataqPerrLoc
5243  * Posted Data Queue Parity Error Location
5244  * Description: Returns the location of the first parity error
5245  * detected in Posted Data Q
5246  *
5247  * Fields:
5248  */
5249 typedef union {
5250 	uint32_t value;
5251 	struct {
5252 #if defined(_BIG_ENDIAN)
5253 		uint32_t	rsrvd:16;
5254 		uint32_t	p_dataq_parerr_loc:16;
5255 #else
5256 		uint32_t	p_dataq_parerr_loc:16;
5257 		uint32_t	rsrvd:16;
5258 #endif
5259 	} bits;
5260 } p_dataq_perr_loc_t;
5261 
5262 
5263 /*
5264  * Register: NpHdrqPerrLoc
5265  * Non-Posted Header Queue Parity Error Location
5266  * Description: Returns the location of the first parity error
5267  * detected in Non-Posted Header Q
5268  *
5269  * Fields:
5270  */
5271 typedef union {
5272 	uint32_t value;
5273 	struct {
5274 #if defined(_BIG_ENDIAN)
5275 		uint32_t	rsrvd:16;
5276 		uint32_t	np_hdrq_parerr_loc:16;
5277 #else
5278 		uint32_t	np_hdrq_parerr_loc:16;
5279 		uint32_t	rsrvd:16;
5280 #endif
5281 	} bits;
5282 } np_hdrq_perr_loc_t;
5283 
5284 
5285 /*
5286  * Register: NpDataqPerrLoc
5287  * Non-Posted Data Queue Parity Error Location
5288  * Description: Returns the location of the first parity error
5289  * detected in Non-Posted Data Q
5290  *
5291  * Fields:
5292  */
5293 typedef union {
5294 	uint32_t value;
5295 	struct {
5296 #if defined(_BIG_ENDIAN)
5297 		uint32_t	rsrvd:16;
5298 		uint32_t	np_dataq_parerr_loc:16;
5299 #else
5300 		uint32_t	np_dataq_parerr_loc:16;
5301 		uint32_t	rsrvd:16;
5302 #endif
5303 	} bits;
5304 } np_dataq_perr_loc_t;
5305 
5306 
5307 /*
5308  * Register: MsixPerrLoc
5309  * MSIX Parity Error Location
5310  * Description: Returns the location of the first parity error
5311  * detected in MSIX memory
5312  *
5313  * Fields:
5314  */
5315 typedef union {
5316 	uint32_t value;
5317 	struct {
5318 #if defined(_BIG_ENDIAN)
5319 		uint32_t	rsrvd:16;
5320 		uint32_t	eic_msix_parerr_loc:16;
5321 #else
5322 		uint32_t	eic_msix_parerr_loc:16;
5323 		uint32_t	rsrvd:16;
5324 #endif
5325 	} bits;
5326 } msix_perr_loc_t;
5327 
5328 
5329 /*
5330  * Register: HcrPerrLoc
5331  * HCR Memory Parity Error Location
5332  * Description: Returns the location of the first parity error
5333  * detected in HCR Memory
5334  *
5335  * Fields:
5336  */
5337 typedef union {
5338 	uint32_t value;
5339 	struct {
5340 #if defined(_BIG_ENDIAN)
5341 		uint32_t	rsrvd:16;
5342 		uint32_t	hcr_parerr_loc:16;
5343 #else
5344 		uint32_t	hcr_parerr_loc:16;
5345 		uint32_t	rsrvd:16;
5346 #endif
5347 	} bits;
5348 } hcr_perr_loc_t;
5349 
5350 
5351 /*
5352  * Register: TdcPioaccErrLog
5353  * TDC PIO Access Error Location
5354  * Description: Returns the location of the first transaction
5355  * location that resulted in error
5356  *
5357  * Fields:
5358  *     Type of access error 0 : Block returned error condition 1 :
5359  *     Transaction resulted in time out by CIP
5360  *     Transaction Location that resulted in error
5361  */
5362 typedef union {
5363 	uint32_t value;
5364 	struct {
5365 #if defined(_BIG_ENDIAN)
5366 		uint32_t	rsrvd:11;
5367 		uint32_t	tdc_pioacc_err_type:1;
5368 		uint32_t	tdc_pioacc_err_loc:20;
5369 #else
5370 		uint32_t	tdc_pioacc_err_loc:20;
5371 		uint32_t	tdc_pioacc_err_type:1;
5372 		uint32_t	rsrvd:11;
5373 #endif
5374 	} bits;
5375 } tdc_pioacc_err_log_t;
5376 
5377 
5378 /*
5379  * Register: RdcPioaccErrLog
5380  * RDC PIO Access Error Location
5381  * Description: Returns the location of the first transaction
5382  * location that resulted in error
5383  *
5384  * Fields:
5385  *     Type of access error 0 : Block returned error condition 1 :
5386  *     Transaction resulted in time out by CIP
5387  *     Transaction Location that resulted in error
5388  */
5389 typedef union {
5390 	uint32_t value;
5391 	struct {
5392 #if defined(_BIG_ENDIAN)
5393 		uint32_t	rsrvd:11;
5394 		uint32_t	rdc_pioacc_err_type:1;
5395 		uint32_t	rdc_pioacc_err_loc:20;
5396 #else
5397 		uint32_t	rdc_pioacc_err_loc:20;
5398 		uint32_t	rdc_pioacc_err_type:1;
5399 		uint32_t	rsrvd:11;
5400 #endif
5401 	} bits;
5402 } rdc_pioacc_err_log_t;
5403 
5404 
5405 /*
5406  * Register: PfcPioaccErrLog
5407  * PFC PIO Access Error Location
5408  * Description: Returns the location of the first transaction
5409  * location that resulted in error
5410  *
5411  * Fields:
5412  *     Type of access error 0 : Block returned error condition 1 :
5413  *     Transaction resulted in time out by CIP
5414  *     Transaction Location that resulted in error
5415  */
5416 typedef union {
5417 	uint32_t value;
5418 	struct {
5419 #if defined(_BIG_ENDIAN)
5420 		uint32_t	rsrvd:11;
5421 		uint32_t	pfc_pioacc_err_type:1;
5422 		uint32_t	pfc_pioacc_err_loc:20;
5423 #else
5424 		uint32_t	pfc_pioacc_err_loc:20;
5425 		uint32_t	pfc_pioacc_err_type:1;
5426 		uint32_t	rsrvd:11;
5427 #endif
5428 	} bits;
5429 } pfc_pioacc_err_log_t;
5430 
5431 
5432 /*
5433  * Register: VmacPioaccErrLog
5434  * VMAC PIO Access Error Location
5435  * Description: Returns the location of the first transaction
5436  * location that resulted in error
5437  *
5438  * Fields:
5439  *     Type of access error 0 : Block returned error condition 1 :
5440  *     Transaction resulted in time out by CIP
5441  *     Transaction Location that resulted in error
5442  */
5443 typedef union {
5444 	uint32_t value;
5445 	struct {
5446 #if defined(_BIG_ENDIAN)
5447 		uint32_t	rsrvd:11;
5448 		uint32_t	vmac_pioacc_err_type:1;
5449 		uint32_t	vmac_pioacc_err_loc:20;
5450 #else
5451 		uint32_t	vmac_pioacc_err_loc:20;
5452 		uint32_t	vmac_pioacc_err_type:1;
5453 		uint32_t	rsrvd:11;
5454 #endif
5455 	} bits;
5456 } vmac_pioacc_err_log_t;
5457 
5458 
5459 /*
5460  * Register: LdGrpCtrl
5461  * Logical Device Group Control
5462  * Description: LD Group assignment
5463  * Fields:
5464  *     Logical device group number of this logical device
5465  */
5466 typedef union {
5467 	uint32_t value;
5468 	struct {
5469 #if defined(_BIG_ENDIAN)
5470 		uint32_t	rsrvd:27;
5471 		uint32_t	num:5;
5472 #else
5473 		uint32_t	num:5;
5474 		uint32_t	rsrvd:27;
5475 #endif
5476 	} bits;
5477 } ld_grp_ctrl_t;
5478 
5479 
5480 /*
5481  * Register: DevErrStat
5482  * Device Error Status
5483  * Description: Device Error Status logs errors that cannot be
5484  * attributed to a given dma channel. It does not duplicate errors
5485  * already observable via specific block logical device groups.
5486  * Device Error Status bits [31:16] feed LDSV0.devErr0 Device Error
5487  * Status bits [15:0] feed LDSV1.devErr1
5488  * Fields:
5489  *     Set to 1 if Reorder Buffer/Reorder Table has a single bit
5490  *     ecc/parity error. This error condition is asserted by TDC to
5491  *     PEU.
5492  *     Set to 1 if RX Ctrl or Data FIFO has a single bit ecc error.
5493  *     This error condition is asserted by RDC to PEU.
5494  *     Set to 1 if any of the external block accesses have resulted
5495  *     in error or if a parity error was detected in the SPROM
5496  *     internal ram. Refer to peuIntrStat for the errors that
5497  *     contribute to this bit.
5498  *     Set to 1 if Reorder Buffer/Reorder Table has a double bit
5499  *     ecc/parity error. This error condition is asserted by TDC to
5500  *     PEU.
5501  *     Set to 1 if RX Ctrl or Data FIFO has a double bit ecc error.
5502  *     This error condition is asserted by RDC to PEU.
5503  *     Set to 1 if any PEU ram (MSI-X, retrybuf/sot, p/np/cpl queues)
5504  *     has a parity error Refer to peuIntrStat for the errors that
5505  *     contribute to this bit.
5506  */
5507 typedef union {
5508 	uint32_t value;
5509 	struct {
5510 #if defined(_BIG_ENDIAN)
5511 		uint32_t	rsrvd:13;
5512 		uint32_t	tdc_err0:1;
5513 		uint32_t	rdc_err0:1;
5514 		uint32_t	rsrvd1:1;
5515 		uint32_t	rsrvd2:12;
5516 		uint32_t	vnm_pio_err1:1;
5517 		uint32_t	tdc_err1:1;
5518 		uint32_t	rdc_err1:1;
5519 		uint32_t	peu_err1:1;
5520 #else
5521 		uint32_t	peu_err1:1;
5522 		uint32_t	rdc_err1:1;
5523 		uint32_t	tdc_err1:1;
5524 		uint32_t	vnm_pio_err1:1;
5525 		uint32_t	rsrvd2:12;
5526 		uint32_t	rsrvd1:1;
5527 		uint32_t	rdc_err0:1;
5528 		uint32_t	tdc_err0:1;
5529 		uint32_t	rsrvd:13;
5530 #endif
5531 	} bits;
5532 } dev_err_stat_t;
5533 
5534 
5535 /*
5536  * Register: DevErrMask
5537  * Device Error Mask
5538  * Description: Device Error Mask (gates devErrStat)
5539  * Fields:
5540  *     Mask for TDC error0
5541  *     Mask for RDC error0
5542  *     Mask for VNM PIO Access error
5543  *     Mask for TDC error1
5544  *     Mask for RDC error1
5545  *     Mask for PEU memories parity error
5546  */
5547 typedef union {
5548 	uint32_t value;
5549 	struct {
5550 #if defined(_BIG_ENDIAN)
5551 		uint32_t	rsrvd:13;
5552 		uint32_t	tdc_mask0:1;
5553 		uint32_t	rdc_mask0:1;
5554 		uint32_t	rsrvd1:1;
5555 		uint32_t	rsrvd2:12;
5556 		uint32_t	vnm_pio_mask1:1;
5557 		uint32_t	tdc_mask1:1;
5558 		uint32_t	rdc_mask1:1;
5559 		uint32_t	peu_mask1:1;
5560 #else
5561 		uint32_t	peu_mask1:1;
5562 		uint32_t	rdc_mask1:1;
5563 		uint32_t	tdc_mask1:1;
5564 		uint32_t	vnm_pio_mask1:1;
5565 		uint32_t	rsrvd2:12;
5566 		uint32_t	rsrvd1:1;
5567 		uint32_t	rdc_mask0:1;
5568 		uint32_t	tdc_mask0:1;
5569 		uint32_t	rsrvd:13;
5570 #endif
5571 	} bits;
5572 } dev_err_mask_t;
5573 
5574 
5575 /*
5576  * Register: LdIntrTimRes
5577  * Logical Device Interrupt Timer Resolution
5578  * Description: Logical Device Interrupt Timer Resolution
5579  * Fields:
5580  *     Timer resolution in 250 MHz cycles
5581  */
5582 typedef union {
5583 	uint32_t value;
5584 	struct {
5585 #if defined(_BIG_ENDIAN)
5586 		uint32_t	rsrvd:12;
5587 		uint32_t	res:20;
5588 #else
5589 		uint32_t	res:20;
5590 		uint32_t	rsrvd:12;
5591 #endif
5592 	} bits;
5593 } ld_intr_tim_res_t;
5594 
5595 
5596 /*
5597  * Register: LDSV0
5598  * Logical Device State Vector 0
5599  * Description: Logical Device State Vector 0
5600  * Fields:
5601  *     Interrupt from mail box3 to HOST
5602  *     Interrupt from mail box2 to HOST
5603  *     Interrupt from mail box1 to HOST
5604  *     Interrupt from mail box0 to HOST
5605  *     Flag0 bits for Network MAC
5606  *     Flag0 bits for Virtual MAC
5607  *     Flag0 bits for Tx DMA channels 3-0
5608  *     Flag0 bits for Rx DMA channels 3-0
5609  */
5610 typedef union {
5611 	uint32_t value;
5612 	struct {
5613 #if defined(_BIG_ENDIAN)
5614 		uint32_t	dev_err0:1;
5615 		uint32_t	rsrvd:7;
5616 		uint32_t	mbox3_irq:1;
5617 		uint32_t	mbox2_irq:1;
5618 		uint32_t	mbox1_irq:1;
5619 		uint32_t	mbox0_irq:1;
5620 		uint32_t	rsrvd1:1;
5621 		uint32_t	nmac_f0:1;
5622 		uint32_t	pfc_f0:1;
5623 		uint32_t	vmac_f0:1;
5624 		uint32_t	rsrvd2:4;
5625 		uint32_t	tdc_f0:4;
5626 		uint32_t	rsrvd3:4;
5627 		uint32_t	rdc_f0:4;
5628 #else
5629 		uint32_t	rdc_f0:4;
5630 		uint32_t	rsrvd3:4;
5631 		uint32_t	tdc_f0:4;
5632 		uint32_t	rsrvd2:4;
5633 		uint32_t	vmac_f0:1;
5634 		uint32_t	pfc_f0:1;
5635 		uint32_t	nmac_f0:1;
5636 		uint32_t	rsrvd1:1;
5637 		uint32_t	mbox0_irq:1;
5638 		uint32_t	mbox1_irq:1;
5639 		uint32_t	mbox2_irq:1;
5640 		uint32_t	mbox3_irq:1;
5641 		uint32_t	rsrvd:7;
5642 		uint32_t	dev_err0:1;
5643 #endif
5644 	} bits;
5645 } ldsv0_t;
5646 
5647 
5648 /*
5649  * Register: LDSV1
5650  * Logical Device State Vector 1
5651  * Description: Logical Device State Vector 1
5652  * Fields:
5653  *     Flag1 bits for Network MAC
5654  *     Flag1 bits for Tx DMA channels 3-0
5655  *     Flag1 bits for Rx DMA channels 3-0
5656  */
5657 typedef union {
5658 	uint32_t value;
5659 	struct {
5660 #if defined(_BIG_ENDIAN)
5661 		uint32_t	dev_err1:1;
5662 		uint32_t	rsrvd:7;
5663 		uint32_t	rsrvd1:5;
5664 		uint32_t	nmac_f1:1;
5665 		uint32_t	rsrvd2:1;
5666 		uint32_t	rsrvd3:1;
5667 		uint32_t	rsrvd4:4;
5668 		uint32_t	tdc_f1:4;
5669 		uint32_t	rsrvd5:4;
5670 		uint32_t	rdc_f1:4;
5671 #else
5672 		uint32_t	rdc_f1:4;
5673 		uint32_t	rsrvd5:4;
5674 		uint32_t	tdc_f1:4;
5675 		uint32_t	rsrvd4:4;
5676 		uint32_t	rsrvd3:1;
5677 		uint32_t	rsrvd2:1;
5678 		uint32_t	nmac_f1:1;
5679 		uint32_t	rsrvd1:5;
5680 		uint32_t	rsrvd:7;
5681 		uint32_t	dev_err1:1;
5682 #endif
5683 	} bits;
5684 } ldsv1_t;
5685 
5686 
5687 /*
5688  * Register: LdIntrMask
5689  * Logical Device Interrupt Mask
5690  * Description: Logical Device Interrupt Mask
5691  * Fields:
5692  *     Flag1 mask for logical device N (0-31)
5693  *     Flag0 mask for logical device N (0-31)
5694  */
5695 typedef union {
5696 	uint32_t value;
5697 	struct {
5698 #if defined(_BIG_ENDIAN)
5699 		uint32_t	rsrvd:30;
5700 		uint32_t	ldf1_mask:1;
5701 		uint32_t	ldf0_mask:1;
5702 #else
5703 		uint32_t	ldf0_mask:1;
5704 		uint32_t	ldf1_mask:1;
5705 		uint32_t	rsrvd:30;
5706 #endif
5707 	} bits;
5708 } ld_intr_mask_t;
5709 
5710 
5711 /*
5712  * Register: LdIntrMgmt
5713  * Logical Device Interrupt Management
5714  * Description: Logical Device Interrupt Management
5715  * Fields:
5716  *     SW arms the logical device for interrupt. Cleared by HW after
5717  *     interrupt issued. (1 = arm)
5718  *     Timer set by SW. Hardware counts down.
5719  */
5720 typedef union {
5721 	uint32_t value;
5722 	struct {
5723 #if defined(_BIG_ENDIAN)
5724 		uint32_t	arm:1;
5725 		uint32_t	rsrvd:25;
5726 		uint32_t	timer:6;
5727 #else
5728 		uint32_t	timer:6;
5729 		uint32_t	rsrvd:25;
5730 		uint32_t	arm:1;
5731 #endif
5732 	} bits;
5733 } ld_intr_mgmt_t;
5734 
5735 
5736 /*
5737  * Register: SID
5738  * System Interrupt Data
5739  * Description: System Interrupt Data (MSI Vectors)
5740  * Fields:
5741  *     Data sent along with the interrupt
5742  */
5743 typedef union {
5744 	uint32_t value;
5745 	struct {
5746 #if defined(_BIG_ENDIAN)
5747 		uint32_t	rsrvd:27;
5748 		uint32_t	data:5;
5749 #else
5750 		uint32_t	data:5;
5751 		uint32_t	rsrvd:27;
5752 #endif
5753 	} bits;
5754 } sid_t;
5755 
5756 
5757 #ifdef	__cplusplus
5758 }
5759 #endif
5760 
5761 #endif	/* _HXGE_PEU_HW_H */
5762