xref: /illumos-gate/usr/src/uts/common/io/ena/ena_hw.h (revision 9164a50bf932130cbb5097a16f6986873ce0e6e5)
1 /*
2  * This file and its contents are supplied under the terms of the
3  * Common Development and Distribution License ("CDDL"), version 1.0.
4  * You may only use this file in accordance with the terms of version
5  * 1.0 of the CDDL.
6  *
7  * A full copy of the text of the CDDL should have accompanied this
8  * source.  A copy of the CDDL is also available via the Internet at
9  * http://www.illumos.org/license/CDDL.
10  */
11 
12 /*
13  * Copyright 2024 Oxide Computer Company
14  */
15 
16 /*
17  * This file declares all constants and structures dealing with the
18  * physical ENA device. It is based on the ena_com code of the public
19  * Linux and FreeBSD drivers. While this file is based on the common
20  * code it doesn't share the same type names. Where it is useful, a
21  * "common" reference is added to include the name of the type as
22  * defined in the common code.
23  *
24  * The Linux driver defines enq_admin_aq_entry as the top-level type
25  * for admin command descriptors. From this type you can access the
26  * common bits shared by every descriptor (ena_admin_aq_common_desc)
27  * as well as the control buffer (ena_admin_ctrl_buff_info) which is
28  * present for _some_ commands. Other than that, this top-level type
29  * treats the rest of the data as an opaque array of unsigned 32-bit
30  * integers. Then, for each individual command, the Linux driver
31  * defines a dedicated type, each of which contains the following:
32  *
33  * 1. The common descriptor: ena_admin_aq_common_desc.
34  *
35  * 2. The optional control buffer desc: ena_admin_ctrl_buff_info.
36  *
37  * 3. The command-specific data.
38  *
39  * 4. Optional padding to make sure all commands are 64 bytes in size.
40  *
41  * Furthermore, there may be further common types for commands which
42  * are made up of several sub-commands, e.g. the get/set feature
43  * commands.
44  *
45  * Finally, when a command is passed to the common function for
46  * executing commands (ena_com_execute_admin_command()), it is cast as
47  * a pointer to the top-level type: ena_admin_aq_entry.
48  *
49  * This works for the Linux driver just fine, but it causes lots of
50  * repetition in the structure definitions and also means there is no
51  * easy way to determine all valid commands. This ENA driver has
52  * turned the Linux approach inside out -- the top-level type is a
53  * union of all possible commands: enahw_cmd_desc_t. Each command may
54  * then further sub-type via unions to represent its sub-commands.
55  * This same treatment was given to the response descriptor:
56  * enahw_resp_desc_t.
57  *
58  * What is the point of knowing all this? Well, when referencing the
59  * common type in the comment above the enahw_ type, you need to keep
60  * in mind that the Linux/common type will include all the common
61  * descriptor bits, whereas these types do not.
62  *
63  * The common code DOES NOT pack any of these structures, and thus
64  * neither do we. That means these structures all rely on natural
65  * compiler alignment, just as the common code does. In ena.c you will
66  * find CTASSERTs for many of these structures, to verify they are of
67  * the expected size.
68  */
69 
70 #ifndef	_ENA_HW_H
71 #define	_ENA_HW_H
72 
73 #include <sys/ddi.h>
74 #include <sys/sunddi.h>
75 #include <sys/types.h>
76 #include <sys/debug.h>
77 #include <sys/ethernet.h>
78 
79 /*
80  * The common code sets the upper limit of I/O queues to 128. In this
81  * case a "queue" is a SQ+CQ pair that forms a logical queue or ring
82  * for sending or receiving packets. Thus, at maximum, we may expect
83  * 128 Tx rings, and 128 Rx rings; though, practically speaking, the
84  * number of rings will often be limited by number of CPUs or
85  * available interrupts.
86  *
87  * common: ENA_MAX_NUM_IO_QUEUES
88  */
89 #define	ENAHW_MAX_NUM_IO_QUEUES	128
90 
91 /*
92  * Generate a 32-bit bitmask where the bits between high (inclusive)
93  * and low (inclusive) are set to 1.
94  */
95 #define	GENMASK(h, l)	(((~0U) - (1U << (l)) + 1) & (~0U >> (32 - 1 - (h))))
96 
97 /*
98  * Generate a 64-bit bitmask where bit b is set to 1.
99  */
100 #define	BIT(b)	(1UL << (b))
101 
102 #define	ENAHW_DMA_ADMINQ_ALIGNMENT	8
103 
104 #define	ENAHW_ADMIN_CQ_DESC_BUF_ALIGNMENT	8
105 #define	ENAHW_ADMIN_SQ_DESC_BUF_ALIGNMENT	8
106 #define	ENAHW_AENQ_DESC_BUF_ALIGNMENT		8
107 #define	ENAHW_HOST_INFO_ALIGNMENT		8
108 #define	ENAHW_HOST_INFO_ALLOC_SZ		4096
109 #define	ENAHW_IO_CQ_DESC_BUF_ALIGNMENT		4096
110 #define	ENAHW_IO_SQ_DESC_BUF_ALIGNMENT		8
111 
112 /*
113  * BAR0 register offsets.
114  *
115  * Any register not defined in the common code was marked as a gap,
116  * using the hex address of the register as suffix to make it clear
117  * where the gaps are.
118  */
119 #define	ENAHW_REG_VERSION		0x0
120 #define	ENAHW_REG_CONTROLLER_VERSION	0x4
121 #define	ENAHW_REG_CAPS			0x8
122 #define	ENAHW_REG_CAPS_EXT		0xc
123 #define	ENAHW_REG_ASQ_BASE_LO		0x10
124 #define	ENAHW_REG_ASQ_BASE_HI		0x14
125 #define	ENAHW_REG_ASQ_CAPS		0x18
126 #define	ENAHW_REG_GAP_1C		0x1c
127 #define	ENAHW_REG_ACQ_BASE_LO		0x20
128 #define	ENAHW_REG_ACQ_BASE_HI		0x24
129 #define	ENAHW_REG_ACQ_CAPS		0x28
130 #define	ENAHW_REG_ASQ_DB		0x2c
131 #define	ENAHW_REG_ACQ_TAIL		0x30
132 #define	ENAHW_REG_AENQ_CAPS		0x34
133 #define	ENAHW_REG_AENQ_BASE_LO		0x38
134 #define	ENAHW_REG_AENQ_BASE_HI		0x3c
135 #define	ENAHW_REG_AENQ_HEAD_DB		0x40
136 #define	ENAHW_REG_AENQ_TAIL		0x44
137 #define	ENAHW_REG_GAP_48		0x48
138 #define	ENAHW_REG_INTERRUPT_MASK	0x4c
139 #define	ENAHW_REG_GAP_50		0x50
140 #define	ENAHW_REG_DEV_CTL		0x54
141 #define	ENAHW_REG_DEV_STS		0x58
142 #define	ENAHW_REG_MMIO_REG_READ		0x5c
143 #define	ENAHW_REG_MMIO_RESP_LO		0x60
144 #define	ENAHW_REG_MMIO_RESP_HI		0x64
145 #define	ENAHW_REG_RSS_IND_ENTRY_UPDATE	0x68
146 #define	ENAHW_NUM_REGS		((ENAHW_REG_RSS_IND_ENTRY_UPDATE / 4) + 1)
147 
148 /*
149  * Device Version (Register 0x0)
150  */
151 #define	ENAHW_DEV_MINOR_VSN_MASK	0xff
152 #define	ENAHW_DEV_MAJOR_VSN_SHIFT	8
153 #define	ENAHW_DEV_MAJOR_VSN_MASK	0xff00
154 
155 #define	ENAHW_DEV_MAJOR_VSN(vsn)					\
156 	(((vsn) & ENAHW_DEV_MAJOR_VSN_MASK) >> ENAHW_DEV_MAJOR_VSN_SHIFT)
157 #define	ENAHW_DEV_MINOR_VSN(vsn)		\
158 	((vsn) & ENAHW_DEV_MINOR_VSN_MASK)
159 
160 /*
161  * Controller Version (Register 0x4)
162  */
163 #define	ENAHW_CTRL_SUBMINOR_VSN_MASK	0xff
164 #define	ENAHW_CTRL_MINOR_VSN_SHIFT	8
165 #define	ENAHW_CTRL_MINOR_VSN_MASK	0xff00
166 #define	ENAHW_CTRL_MAJOR_VSN_SHIFT	16
167 #define	ENAHW_CTRL_MAJOR_VSN_MASK	0xff0000
168 #define	ENAHW_CTRL_IMPL_ID_SHIFT	24
169 #define	ENAHW_CTRL_IMPL_ID_MASK		0xff000000
170 
171 #define	ENAHW_CTRL_MAJOR_VSN(vsn)				\
172 	(((vsn) & ENAHW_CTRL_MAJOR_VSN_MASK) >> ENAHW_CTRL_MAJOR_VSN_SHIFT)
173 #define	ENAHW_CTRL_MINOR_VSN(vsn)				\
174 	(((vsn) & ENAHW_CTRL_MINOR_VSN_MASK) >> ENAHW_CTRL_MINOR_VSN_SHIFT)
175 #define	ENAHW_CTRL_SUBMINOR_VSN(vsn)	\
176 	((vsn) & ENAHW_CTRL_SUBMINOR_VSN_MASK)
177 #define	ENAHW_CTRL_IMPL_ID(vsn)				\
178 	(((vsn) & ENAHW_CTRL_IMPL_ID_MASK) >> ENAHW_CTRL_IMPL_ID_SHIFT)
179 
180 /*
181  * Device Caps (Register 0x8)
182  */
183 #define	ENAHW_CAPS_CONTIGUOUS_QUEUE_REQUIRED_MASK	0x1
184 #define	ENAHW_CAPS_RESET_TIMEOUT_SHIFT			1
185 #define	ENAHW_CAPS_RESET_TIMEOUT_MASK			0x3e
186 #define	ENAHW_CAPS_RESET_TIMEOUT(v)		    \
187 	(((v) & ENAHW_CAPS_RESET_TIMEOUT_MASK) >>   \
188 	    ENAHW_CAPS_RESET_TIMEOUT_SHIFT)
189 #define	ENAHW_CAPS_DMA_ADDR_WIDTH_SHIFT			8
190 #define	ENAHW_CAPS_DMA_ADDR_WIDTH_MASK			0xff00
191 #define	ENAHW_CAPS_DMA_ADDR_WIDTH(v)		     \
192 	(((v) & ENAHW_CAPS_DMA_ADDR_WIDTH_MASK) >>   \
193 	    ENAHW_CAPS_DMA_ADDR_WIDTH_SHIFT)
194 #define	ENAHW_CAPS_ADMIN_CMD_TIMEOUT_SHIFT		16
195 #define	ENAHW_CAPS_ADMIN_CMD_TIMEOUT_MASK		0xf0000
196 #define	ENAHW_CAPS_ADMIN_CMD_TIMEOUT(v)			\
197 	(((v) & ENAHW_CAPS_ADMIN_CMD_TIMEOUT_MASK) >>	\
198 	    ENAHW_CAPS_ADMIN_CMD_TIMEOUT_SHIFT)
199 
200 typedef enum enahw_reset_reason_types {
201 	ENAHW_RESET_NORMAL			= 0,
202 	ENAHW_RESET_KEEP_ALIVE_TO		= 1,
203 	ENAHW_RESET_ADMIN_TO			= 2,
204 	ENAHW_RESET_MISS_TX_CMPL		= 3,
205 	ENAHW_RESET_INV_RX_REQ_ID		= 4,
206 	ENAHW_RESET_INV_TX_REQ_ID		= 5,
207 	ENAHW_RESET_TOO_MANY_RX_DESCS		= 6,
208 	ENAHW_RESET_INIT_ERR			= 7,
209 	ENAHW_RESET_DRIVER_INVALID_STATE	= 8,
210 	ENAHW_RESET_OS_TRIGGER			= 9,
211 	ENAHW_RESET_OS_NETDEV_WD		= 10,
212 	ENAHW_RESET_SHUTDOWN			= 11,
213 	ENAHW_RESET_USER_TRIGGER		= 12,
214 	ENAHW_RESET_GENERIC			= 13,
215 	ENAHW_RESET_MISS_INTERRUPT		= 14,
216 	ENAHW_RESET_SUSPECTED_POLL_STARVATION	= 15,
217 	ENAHW_RESET_RX_DESCRIPTOR_MALFORMED	= 16,
218 	ENAHW_RESET_TX_DESCRIPTOR_MALFORMED	= 17,
219 	ENAHW_RESET_MISSING_ADMIN_INTERRUPT	= 18,
220 	ENAHW_RESET_DEVICE_REQUEST		= 19,
221 	ENAHW_RESET_LAST,
222 } enahw_reset_reason_t;
223 
224 #define	ENAHW_RESET_REASON_LSB_SHIFT		0
225 #define	ENAHW_RESET_REASON_LSB_MASK		0xf
226 #define	ENAHW_RESET_REASON_MSB_SHIFT		4
227 #define	ENAHW_RESET_REASON_MSB_MASK		0xf0
228 #define	ENAHW_RESET_REASON_LSB(v)		\
229 	(((v) & ENAHW_RESET_REASON_LSB_MASK) >> ENAHW_RESET_REASON_LSB_SHIFT)
230 #define	ENAHW_RESET_REASON_MSB(v)		\
231 	(((v) & ENAHW_RESET_REASON_MSB_MASK) >> ENAHW_RESET_REASON_MSB_SHIFT)
232 
233 /*
234  * Admin Submission Queue Caps (Register 0x18)
235  */
236 #define	ENAHW_ASQ_CAPS_DEPTH_MASK		0xffff
237 #define	ENAHW_ASQ_CAPS_ENTRY_SIZE_SHIFT		16
238 #define	ENAHW_ASQ_CAPS_ENTRY_SIZE_MASK		0xffff0000
239 
240 #define	ENAHW_ASQ_CAPS_DEPTH(x)	((x) & ENAHW_ASQ_CAPS_DEPTH_MASK)
241 
242 #define	ENAHW_ASQ_CAPS_ENTRY_SIZE(x)			\
243 	(((x) << ENAHW_ASQ_CAPS_ENTRY_SIZE_SHIFT) &	\
244 	    ENAHW_ASQ_CAPS_ENTRY_SIZE_MASK)
245 
246 /*
247  * Admin Completion Queue Caps (Register 0x28)
248  */
249 #define	ENAHW_ACQ_CAPS_DEPTH_MASK	0xffff
250 #define	ENAHW_ACQ_CAPS_ENTRY_SIZE_SHIFT	16
251 #define	ENAHW_ACQ_CAPS_ENTRY_SIZE_MASK	0xffff0000
252 
253 #define	ENAHW_ACQ_CAPS_DEPTH(x)	((x) & ENAHW_ACQ_CAPS_DEPTH_MASK)
254 
255 #define	ENAHW_ACQ_CAPS_ENTRY_SIZE(x)			\
256 	(((x) << ENAHW_ACQ_CAPS_ENTRY_SIZE_SHIFT) &	\
257 	    ENAHW_ACQ_CAPS_ENTRY_SIZE_MASK)
258 
259 /*
260  * Asynchronous Event Notification Queue Caps (Register 0x34)
261  */
262 #define	ENAHW_AENQ_CAPS_DEPTH_MASK		0xffff
263 #define	ENAHW_AENQ_CAPS_ENTRY_SIZE_SHIFT	16
264 #define	ENAHW_AENQ_CAPS_ENTRY_SIZE_MASK		0xffff0000
265 
266 #define	ENAHW_AENQ_CAPS_DEPTH(x) ((x) & ENAHW_AENQ_CAPS_DEPTH_MASK)
267 
268 #define	ENAHW_AENQ_CAPS_ENTRY_SIZE(x)		     \
269 	(((x) << ENAHW_AENQ_CAPS_ENTRY_SIZE_SHIFT) & \
270 	    ENAHW_AENQ_CAPS_ENTRY_SIZE_MASK)
271 
272 /*
273  * Interrupt Mask (Register 0x4c)
274  */
275 #define	ENAHW_INTR_UNMASK	0x0
276 #define	ENAHW_INTR_MASK		0x1
277 
278 /*
279  * Device Control (Register 0x54)
280  */
281 #define	ENAHW_DEV_CTL_DEV_RESET_MASK		0x1
282 #define	ENAHW_DEV_CTL_AQ_RESTART_SHIFT		1
283 #define	ENAHW_DEV_CTL_AQ_RESTART_MASK		0x2
284 #define	ENAHW_DEV_CTL_QUIESCENT_SHIFT		2
285 #define	ENAHW_DEV_CTL_QUIESCENT_MASK		0x4
286 #define	ENAHW_DEV_CTL_IO_RESUME_SHIFT		3
287 #define	ENAHW_DEV_CTL_IO_RESUME_MASK		0x8
288 #define	ENAHW_DEV_CTL_RESET_REASON_EXT_SHIFT	24
289 #define	ENAHW_DEV_CTL_RESET_REASON_EXT_MASK	0xf000000
290 #define	ENAHW_DEV_CTL_RESET_REASON_SHIFT	28
291 #define	ENAHW_DEV_CTL_RESET_REASON_MASK		0xf0000000
292 
293 /*
294  * Device Status (Register 0x58)
295  */
296 #define	ENAHW_DEV_STS_READY_MASK			0x1
297 #define	ENAHW_DEV_STS_AQ_RESTART_IN_PROGRESS_SHIFT	1
298 #define	ENAHW_DEV_STS_AQ_RESTART_IN_PROGRESS_MASK	0x2
299 #define	ENAHW_DEV_STS_AQ_RESTART_FINISHED_SHIFT		2
300 #define	ENAHW_DEV_STS_AQ_RESTART_FINISHED_MASK		0x4
301 #define	ENAHW_DEV_STS_RESET_IN_PROGRESS_SHIFT		3
302 #define	ENAHW_DEV_STS_RESET_IN_PROGRESS_MASK		0x8
303 #define	ENAHW_DEV_STS_RESET_FINISHED_SHIFT		4
304 #define	ENAHW_DEV_STS_RESET_FINISHED_MASK		0x10
305 #define	ENAHW_DEV_STS_FATAL_ERROR_SHIFT			5
306 #define	ENAHW_DEV_STS_FATAL_ERROR_MASK			0x20
307 #define	ENAHW_DEV_STS_QUIESCENT_STATE_IN_PROGRESS_SHIFT	6
308 #define	ENAHW_DEV_STS_QUIESCENT_STATE_IN_PROGRESS_MASK	0x40
309 #define	ENAHW_DEV_STS_QUIESCENT_STATE_ACHIEVED_SHIFT	7
310 #define	ENAHW_DEV_STS_QUIESCENT_STATE_ACHIEVED_MASK	0x80
311 
312 /* common: ena_admin_aenq_common_desc */
313 typedef struct enahw_aenq_desc {
314 	uint16_t	ead_group;
315 	uint16_t	ead_syndrome;
316 	uint8_t		ead_flags;
317 	uint8_t		ead_rsvd1[3];
318 	uint32_t	ead_ts_low;
319 	uint32_t	ead_ts_high;
320 
321 	union {
322 		uint32_t	raw[12];
323 
324 		struct {
325 			uint32_t flags;
326 		} link_change;
327 
328 		struct {
329 			uint32_t rx_drops_low;
330 			uint32_t rx_drops_high;
331 			uint32_t tx_drops_low;
332 			uint32_t tx_drops_high;
333 			uint32_t rx_overruns_low;
334 			uint32_t rx_overruns_high;
335 		} keep_alive;
336 	} ead_payload;
337 } enahw_aenq_desc_t;
338 
339 #define	ENAHW_AENQ_DESC_PHASE_MASK	BIT(0)
340 
341 #define	ENAHW_AENQ_DESC_PHASE(desc)		\
342 	((desc)->ead_flags & ENAHW_AENQ_DESC_PHASE_MASK)
343 
344 #define	ENAHW_AENQ_LINK_CHANGE_LINK_STATUS_MASK	BIT(0)
345 
346 /*
347  * Asynchronous Event Notification Queue groups.
348  *
349  * Note: These values represent the bit position of each feature as
350  * returned by ENAHW_FEAT_AENQ_CONFIG. We encode them this way so that
351  * they can double as an index into the AENQ handlers array.
352  *
353  * common: ena_admin_aenq_group
354  */
355 typedef enum enahw_aenq_groups {
356 	ENAHW_AENQ_GROUP_LINK_CHANGE		= 0,
357 	ENAHW_AENQ_GROUP_FATAL_ERROR		= 1,
358 	ENAHW_AENQ_GROUP_WARNING		= 2,
359 	ENAHW_AENQ_GROUP_NOTIFICATION		= 3,
360 	ENAHW_AENQ_GROUP_KEEP_ALIVE		= 4,
361 	ENAHW_AENQ_GROUP_REFRESH_CAPABILITIES	= 5,
362 	ENAHW_AENQ_GROUP_CONF_NOTIFICATIONS	= 6,
363 	ENAHW_AENQ_GROUP_DEVICE_REQUEST_RESET	= 7,
364 	ENAHW_AENQ_GROUPS_ARR_NUM		= 8,
365 } enahw_aenq_groups_t;
366 
367 /*
368  * The reason for ENAHW_AENQ_GROUP_NOFIFICATION.
369  *
370  * common: ena_admin_aenq_notification_syndrome
371  */
372 typedef enum enahw_aenq_syndrome {
373 	ENAHW_AENQ_SYNDROME_UPDATE_HINTS	= 2,
374 } enahw_aenq_syndrome_t;
375 
376 /*
377  * ENA devices use a 48-bit memory space.
378  *
379  * common: ena_common_mem_addr
380  */
381 typedef struct enahw_addr {
382 	uint32_t	ea_low;
383 	uint16_t	ea_high;
384 	uint16_t	ea_rsvd; /* must be zero */
385 } enahw_addr_t;
386 
387 /* common: ena_admin_ctrl_buff_info */
388 struct enahw_ctrl_buff {
389 	uint32_t	ecb_length;
390 	enahw_addr_t	ecb_addr;
391 };
392 
393 /* common: ena_admin_get_set_feature_common_desc */
394 struct enahw_feat_common {
395 	/*
396 	 * 1:0 Select which value you want.
397 	 *
398 	 *	0x1 = Current value.
399 	 *	0x3 = Default value.
400 	 *
401 	 *	Note: Linux seems to set this to 0 to get the value,
402 	 *	not sure if that's a bug or just another way to get the
403 	 *	current value.
404 	 *
405 	 * 7:3 Reserved.
406 	 */
407 	uint8_t	efc_flags;
408 
409 	/* An id from enahw_feature_id_t. */
410 	uint8_t	efc_id;
411 
412 	/*
413 	 * Each feature is versioned, allowing upgrades to the feature
414 	 * set without breaking backwards compatibility. The driver
415 	 * uses this field to specify which version it supports
416 	 * (starting from zero). Linux doesn't document this very well
417 	 * and sets this value to 0 for most features. We define a set
418 	 * of macros, underneath the enahw_feature_id_t type, clearly
419 	 * documenting the version we support for each feature.
420 	 */
421 	uint8_t	efc_version;
422 	uint8_t	efc_rsvd;
423 };
424 
425 /* common: ena_admin_get_feat_cmd */
426 typedef struct enahw_cmd_get_feat {
427 	struct enahw_ctrl_buff		ecgf_ctrl_buf;
428 	struct enahw_feat_common	ecgf_comm;
429 	uint32_t			egcf_unused[11];
430 } enahw_cmd_get_feat_t;
431 
432 /*
433  * N.B. Linux sets efc_flags to 0 (via memset) when reading the
434  * current value, but the comments say it should be 0x1. We follow the
435  * comments.
436  */
437 #define	ENAHW_GET_FEAT_FLAGS_GET_CURR_VAL(desc)		\
438 	((desc)->ecgf_comm.efc_flags) |= 0x1
439 #define	ENAHW_GET_FEAT_FLAGS_GET_DEF_VAL(desc)		\
440 	((desc)->ecgf_comm.efc_flags) |= 0x3
441 
442 /*
443  * Set the MTU of the device. This value does not include the L2
444  * headers or trailers, only the payload.
445  *
446  * common: ena_admin_set_feature_mtu_desc
447  */
448 typedef struct enahw_feat_mtu {
449 	uint32_t efm_mtu;
450 } enahw_feat_mtu_t;
451 
452 /* common: ena_admin_set_feature_host_attr_desc */
453 typedef struct enahw_feat_host_attr {
454 	enahw_addr_t	efha_os_addr;
455 	enahw_addr_t	efha_debug_addr;
456 	uint32_t	efha_debug_sz;
457 } enahw_feat_host_attr_t;
458 
459 /*
460  * ENAHW_FEAT_AENQ_CONFIG
461  *
462  * common: ena_admin_feature_aenq_desc
463  */
464 typedef struct enahw_feat_aenq {
465 	/* Bitmask of AENQ groups this device supports. */
466 	uint32_t efa_supported_groups;
467 
468 	/* Bitmask of AENQ groups currently enabled. */
469 	uint32_t efa_enabled_groups;
470 } enahw_feat_aenq_t;
471 
472 /* common: ena_admin_set_feat_cmd */
473 typedef struct enahw_cmd_set_feat {
474 	struct enahw_ctrl_buff		ecsf_ctrl_buf;
475 	struct enahw_feat_common	ecsf_comm;
476 
477 	union {
478 		uint32_t			ecsf_raw[11];
479 		enahw_feat_host_attr_t		ecsf_host_attr;
480 		enahw_feat_mtu_t		ecsf_mtu;
481 		enahw_feat_aenq_t		ecsf_aenq;
482 	} ecsf_feat;
483 } enahw_cmd_set_feat_t;
484 
485 /*
486  * Used to populate the host information buffer which the Nitro
487  * hypervisor supposedly uses for display, debugging, and possibly
488  * other purposes.
489  *
490  * common: ena_admin_host_info
491  */
492 typedef struct enahw_host_info {
493 	uint32_t	ehi_os_type;
494 	uint8_t		ehi_os_dist_str[128];
495 	uint32_t	ehi_os_dist;
496 	uint8_t		ehi_kernel_ver_str[32];
497 	uint32_t	ehi_kernel_ver;
498 	uint32_t	ehi_driver_ver;
499 	uint32_t	ehi_supported_net_features[2];
500 	uint16_t	ehi_ena_spec_version;
501 	uint16_t	ehi_bdf;
502 	uint16_t	ehi_num_cpus;
503 	uint16_t	ehi_rsvd;
504 	uint32_t	ehi_driver_supported_features;
505 } enahw_host_info_t;
506 
507 #define	ENAHW_HOST_INFO_MAJOR_MASK				GENMASK(7, 0)
508 #define	ENAHW_HOST_INFO_MINOR_SHIFT				8
509 #define	ENAHW_HOST_INFO_MINOR_MASK				GENMASK(15, 8)
510 #define	ENAHW_HOST_INFO_SUB_MINOR_SHIFT				16
511 #define	ENAHW_HOST_INFO_SUB_MINOR_MASK				GENMASK(23, 16)
512 #define	ENAHW_HOST_INFO_SPEC_MAJOR_SHIFT			8
513 #define	ENAHW_HOST_INFO_MODULE_TYPE_SHIFT			24
514 #define	ENAHW_HOST_INFO_MODULE_TYPE_MASK			GENMASK(31, 24)
515 #define	ENAHW_HOST_INFO_FUNCTION_MASK				GENMASK(2, 0)
516 #define	ENAHW_HOST_INFO_DEVICE_SHIFT				3
517 #define	ENAHW_HOST_INFO_DEVICE_MASK				GENMASK(7, 3)
518 #define	ENAHW_HOST_INFO_BUS_SHIFT				8
519 #define	ENAHW_HOST_INFO_BUS_MASK				GENMASK(15, 8)
520 #define	ENAHW_HOST_INFO_RX_OFFSET_SHIFT				1
521 #define	ENAHW_HOST_INFO_RX_OFFSET_MASK				BIT(1)
522 #define	ENAHW_HOST_INFO_INTERRUPT_MODERATION_SHIFT		2
523 #define	ENAHW_HOST_INFO_INTERRUPT_MODERATION_MASK		BIT(2)
524 #define	ENAHW_HOST_INFO_RX_BUF_MIRRORING_SHIFT			3
525 #define	ENAHW_HOST_INFO_RX_BUF_MIRRORING_MASK			BIT(3)
526 #define	ENAHW_HOST_INFO_RSS_CONFIGURABLE_FUNCTION_KEY_SHIFT	4
527 #define	ENAHW_HOST_INFO_RSS_CONFIGURABLE_FUNCTION_KEY_MASK	BIT(4)
528 #define	ENAHW_HOST_INFO_RX_PAGE_REUSE_SHIFT			6
529 #define	ENAHW_HOST_INFO_RX_PAGE_REUSE_MASK			BIT(6)
530 #define	ENAHW_HOST_INFO_TX_IPV6_CSUM_OFFLOAD_SHIFT		7
531 #define	ENAHW_HOST_INFO_TX_IPV6_CSUM_OFFLOAD_MASK		BIT(7)
532 #define	ENAHW_HOST_INFO_INFO_PHC_SHIFT				8
533 #define	ENAHW_HOST_INFO_INFO_PHC_MASK				BIT(8)
534 
535 /* common: ena_admin_os_type */
536 enum enahw_os_type {
537 	ENAHW_OS_LINUX		= 1,
538 	ENAHW_OS_WIN		= 2,
539 	ENAHW_OS_DPDK		= 3,
540 	ENAHW_OS_FREEBSD	= 4,
541 	ENAHW_OS_IPXE		= 5,
542 	ENAHW_OS_ESXI		= 6,
543 	ENAHW_OS_MACOS		= 7,
544 	ENAHW_OS_GROUPS_NUM	= 7,
545 };
546 
547 /*
548  * Create I/O Completion Queue
549  *
550  * A completion queue is where the device writes responses to I/O
551  * requests. The admin completion queue must be created before such a
552  * command can be issued, see ena_admin_cq_init().
553  *
554  * common: ena_admin_aq_create_cq_cmd
555  */
556 typedef struct enahw_cmd_create_cq {
557 	/*
558 	 * 7-6	reserved
559 	 *
560 	 * 5	interrupt mode: when set the device sends an interrupt
561 	 *	for each completion, otherwise the driver must poll
562 	 *	the queue.
563 	 *
564 	 * 4-0	reserved
565 	 */
566 	uint8_t		ecq_caps_1;
567 
568 	/*
569 	 * 7-5	reserved
570 	 *
571 	 * 4-0	CQ entry size (in words): the size of a single CQ entry
572 	 *	in multiples of 32-bit words.
573 	 *
574 	 *	NOTE: According to the common code the "valid" values
575 	 *	are 4 or 8 -- this is incorrect. The valid values are
576 	 *	2 and 4. The common code does have an "extended" Rx
577 	 *	completion descriptor, ena_eth_io_rx_cdesc_ext, that
578 	 *	is 32 bytes and thus would use a value of 8, but it is
579 	 *	not used by the Linux or FreeBSD drivers, so we do not
580 	 *	bother with it.
581 	 *
582 	 *	Type			Bytes		Value
583 	 *	enahw_tx_cdesc_t	8		2
584 	 *	enahw_rx_cdesc_t	16		4
585 	 */
586 	uint8_t		ecq_caps_2;
587 
588 	/* The number of CQ entries, must be a power of 2. */
589 	uint16_t	ecq_num_descs;
590 
591 	/* The MSI-X vector assigned to this CQ. */
592 	uint32_t	ecq_msix_vector;
593 
594 	/*
595 	 * The CQ's physical base address. The CQ memory must be
596 	 * physically contiguous.
597 	 */
598 	enahw_addr_t	ecq_addr;
599 } enahw_cmd_create_cq_t;
600 
601 #define	ENAHW_CMD_CREATE_CQ_INTERRUPT_MODE_ENABLED_SHIFT	5
602 #define	ENAHW_CMD_CREATE_CQ_INTERRUPT_MODE_ENABLED_MASK		(BIT(5))
603 #define	ENAHW_CMD_CREATE_CQ_DESC_SIZE_WORDS_MASK		(GENMASK(4, 0))
604 
605 #define	ENAHW_CMD_CREATE_CQ_INTERRUPT_MODE_ENABLE(cmd)	\
606 	((cmd)->ecq_caps_1 |= ENAHW_CMD_CREATE_CQ_INTERRUPT_MODE_ENABLED_MASK)
607 
608 #define	ENAHW_CMD_CREATE_CQ_DESC_SIZE_WORDS(cmd, val)		\
609 	(((cmd)->ecq_caps_2) |=					\
610 	    ((val) & ENAHW_CMD_CREATE_CQ_DESC_SIZE_WORDS_MASK))
611 
612 /*
613  * Destroy Completion Queue
614  *
615  * common: ena_admin_aq_destroy_cq_cmd
616  */
617 typedef struct enahw_cmd_destroy_cq {
618 	uint16_t	edcq_idx;
619 	uint16_t	edcq_rsvd;
620 } enahw_cmd_destroy_cq_t;
621 
622 /*
623  * common: ena_admin_aq_create_sq_cmd
624  */
625 typedef struct enahw_cmd_create_sq {
626 	/*
627 	 * 7-5	direction: 0x1 = Tx, 0x2 = Rx
628 	 * 4-0	reserved
629 	 */
630 	uint8_t		ecsq_dir;
631 	uint8_t		ecsq_rsvd1;
632 
633 	/*
634 	 * 7	reserved
635 	 *
636 	 * 6-4	completion policy: How are completion events generated.
637 	 *
638 	 *    See enahw_completion_policy_type_t for a description of
639 	 *    the various values.
640 	 *
641 	 * 3-0	placement policy: Where the descriptor ring and
642 	 *			  headers reside.
643 	 *
644 	 *    See enahw_placement_policy_t for a description of the
645 	 *    various values.
646 	 */
647 	uint8_t		ecsq_caps_2;
648 
649 	/*
650 	 * 7-1	reserved
651 	 *
652 	 * 0	physically contiguous:	When set indicates the descriptor
653 	 *				ring memory is physically contiguous.
654 	 */
655 	uint8_t		ecsq_caps_3;
656 
657 	/*
658 	 * The index of the associated Completion Queue (CQ). The CQ
659 	 * must be created before the SQ.
660 	 */
661 	uint16_t	ecsq_cq_idx;
662 
663 	/* The number of descriptors in this SQ. */
664 	uint16_t	ecsq_num_descs;
665 
666 	/*
667 	 * The base physical address of the SQ. This should not be set
668 	 * for LLQ. Must be page aligned.
669 	 */
670 	enahw_addr_t	ecsq_base;
671 
672 	/*
673 	 * The physical address of the head write-back pointer. Valid
674 	 * only when the completion policy is set to one of the head
675 	 * write-back modes (0x2 or 0x3). Must be cacheline size
676 	 * aligned.
677 	 */
678 	enahw_addr_t	ecsq_head_wb;
679 	uint32_t	ecsq_rsvdw2;
680 	uint32_t	ecsq_rsvdw3;
681 } enahw_cmd_create_sq_t;
682 
683 typedef enum enahw_sq_direction {
684 	ENAHW_SQ_DIRECTION_TX = 1,
685 	ENAHW_SQ_DIRECTION_RX = 2,
686 } enahw_sq_direction_t;
687 
688 typedef enum enahw_placement_policy {
689 	/* Descriptors and headers are in host memory. */
690 	ENAHW_PLACEMENT_POLICY_HOST = 1,
691 
692 	/*
693 	 * Descriptors and headers are in device memory (a.k.a Low
694 	 * Latency Queue).
695 	 */
696 	ENAHW_PLACEMENT_POLICY_DEV = 3,
697 } enahw_placement_policy_t;
698 
699 /*
700  * DESC: Write a CQ entry for each SQ descriptor.
701  *
702  * DESC_ON_DEMAND: Write a CQ entry when requested by the SQ descriptor.
703  *
704  * HEAD_ON_DEMAND: Update head pointer when requested by the SQ
705  *		   descriptor.
706  *
707  * HEAD: Update head pointer for each SQ descriptor.
708  *
709  */
710 typedef enum enahw_completion_policy_type {
711 	ENAHW_COMPLETION_POLICY_DESC		= 0,
712 	ENAHW_COMPLETION_POLICY_DESC_ON_DEMAND	= 1,
713 	ENAHW_COMPLETION_POLICY_HEAD_ON_DEMAND	= 2,
714 	ENAHW_COMPLETION_POLICY_HEAD		= 3,
715 } enahw_completion_policy_type_t;
716 
717 #define	ENAHW_CMD_CREATE_SQ_DIR_SHIFT			5
718 #define	ENAHW_CMD_CREATE_SQ_DIR_MASK			GENMASK(7, 5)
719 #define	ENAHW_CMD_CREATE_SQ_PLACEMENT_POLICY_MASK	GENMASK(3, 0)
720 #define	ENAHW_CMD_CREATE_SQ_COMPLETION_POLICY_SHIFT	4
721 #define	ENAHW_CMD_CREATE_SQ_COMPLETION_POLICY_MASK	GENMASK(6, 4)
722 #define	ENAHW_CMD_CREATE_SQ_PHYSMEM_CONTIG_MASK		BIT(0)
723 
724 #define	ENAHW_CMD_CREATE_SQ_DIR(cmd, val)				\
725 	(((cmd)->ecsq_dir) |= (((val) << ENAHW_CMD_CREATE_SQ_DIR_SHIFT) & \
726 	    ENAHW_CMD_CREATE_SQ_DIR_MASK))
727 
728 #define	ENAHW_CMD_CREATE_SQ_PLACEMENT_POLICY(cmd, val)		\
729 	(((cmd)->ecsq_caps_2) |=				\
730 	    ((val) & ENAHW_CMD_CREATE_SQ_PLACEMENT_POLICY_MASK))
731 
732 #define	ENAHW_CMD_CREATE_SQ_COMPLETION_POLICY(cmd, val)			\
733 	(((cmd)->ecsq_caps_2) |=					\
734 	    (((val) << ENAHW_CMD_CREATE_SQ_COMPLETION_POLICY_SHIFT) &	\
735 		ENAHW_CMD_CREATE_SQ_COMPLETION_POLICY_MASK))
736 
737 #define	ENAHW_CMD_CREATE_SQ_PHYSMEM_CONTIG(cmd)				\
738 	((cmd)->ecsq_caps_3 |= ENAHW_CMD_CREATE_SQ_PHYSMEM_CONTIG_MASK)
739 
740 /* common: ena_admin_sq */
741 typedef struct enahw_cmd_destroy_sq {
742 	uint16_t	edsq_idx;
743 	uint8_t		edsq_dir; /* Tx/Rx */
744 	uint8_t		edsq_rsvd;
745 } enahw_cmd_destroy_sq_t;
746 
747 #define	ENAHW_CMD_DESTROY_SQ_DIR_SHIFT	5
748 #define	ENAHW_CMD_DESTROY_SQ_DIR_MASK	GENMASK(7, 5)
749 
750 #define	ENAHW_CMD_DESTROY_SQ_DIR(cmd, val)				\
751 	(((cmd)->edsq_dir) |= (((val) << ENAHW_CMD_DESTROY_SQ_DIR_SHIFT) & \
752 	    ENAHW_CMD_DESTROY_SQ_DIR_MASK))
753 
754 /* common: ena_admin_aq_get_stats_cmd */
755 typedef struct enahw_cmd_get_stats {
756 	struct enahw_ctrl_buff	ecgs_ctrl_buf;
757 	uint8_t			ecgs_type;
758 	uint8_t			ecgs_scope;
759 	uint16_t		ecgs_rsvd;
760 	uint16_t		ecgs_queue_idx;
761 
762 	/*
763 	 * The device ID for which to query stats from. The sentinel
764 	 * value 0xFFFF indicates a query of the current device.
765 	 * According to the common docs, a "privileged device" may
766 	 * query stats for other ENA devices. However the definition
767 	 * of this "privilege device" is not expanded upon.
768 	 */
769 	uint16_t		ecgs_device_id;
770 } enahw_cmd_get_stats_t;
771 
772 /* Query the stats for my device. */
773 #define	ENAHW_CMD_GET_STATS_MY_DEVICE_ID	0xFFFF
774 
775 /*
776  * BASIC: Returns enahw_resp_basic_stats.
777  *
778  * EXTENDED: According to the Linux documentation returns a buffer in
779  * "string format" with additional statistics per queue and per device ID.
780  *
781  * ENI: According to the Linux documentation it returns "extra HW
782  * stats for specific network interface".
783  *
784  * common: ena_admin_get_stats_type
785  */
786 typedef enum enahw_get_stats_type {
787 	ENAHW_GET_STATS_TYPE_BASIC	= 0,
788 	ENAHW_GET_STATS_TYPE_EXTENDED	= 1,
789 	ENAHW_GET_STATS_TYPE_ENI	= 2,
790 } enahw_get_stats_type_t;
791 
792 /* common: ena_admin_get_stats_scope */
793 typedef enum enahw_get_stats_scope {
794 	ENAHW_GET_STATS_SCOPE_QUEUE	= 0,
795 	ENAHW_GET_STATS_SCOPE_ETH	= 1,
796 } enahw_get_stats_scope_t;
797 
798 /* common: ena_admin_aq_entry */
799 typedef struct enahw_cmd_desc {
800 	uint16_t	ecd_cmd_id;
801 	uint8_t		ecd_opcode;
802 	uint8_t		ecd_flags;
803 
804 	union {
805 		uint32_t			ecd_raw[15];
806 		enahw_cmd_get_feat_t		ecd_get_feat;
807 		enahw_cmd_set_feat_t		ecd_set_feat;
808 		enahw_cmd_create_cq_t		ecd_create_cq;
809 		enahw_cmd_destroy_cq_t		ecd_destroy_cq;
810 		enahw_cmd_create_sq_t		ecd_create_sq;
811 		enahw_cmd_destroy_sq_t		ecd_destroy_sq;
812 		enahw_cmd_get_stats_t		ecd_get_stats;
813 	} ecd_cmd;
814 
815 } enahw_cmd_desc_t;
816 
817 /*
818  * top level commands that may be sent to the Admin Queue.
819  *
820  * common: ena_admin_aq_opcode
821  */
822 typedef enum ena_cmd_opcode {
823 	ENAHW_CMD_NONE		= 0,
824 	ENAHW_CMD_CREATE_SQ	= 1,
825 	ENAHW_CMD_DESTROY_SQ	= 2,
826 	ENAHW_CMD_CREATE_CQ	= 3,
827 	ENAHW_CMD_DESTROY_CQ	= 4,
828 	ENAHW_CMD_GET_FEATURE	= 8,
829 	ENAHW_CMD_SET_FEATURE	= 9,
830 	ENAHW_CMD_GET_STATS	= 11,
831 } enahw_cmd_opcode_t;
832 
833 /* common: ENA_ADMIN_AQ_COMMON_DESC */
834 #define	ENAHW_CMD_ID_MASK	GENMASK(11, 0)
835 #define	ENAHW_CMD_PHASE_MASK	BIT(0)
836 
837 #define	ENAHW_CMD_ID(desc, id)					\
838 	(((desc)->ecd_cmd_id) |= ((id) & ENAHW_CMD_ID_MASK))
839 
840 /*
841  * Subcommands for ENA_ADMIN_{GET,SET}_FEATURE.
842  *
843  * common: ena_admin_aq_feature_id
844  */
845 typedef enum enahw_feature_id {
846 	ENAHW_FEAT_DEVICE_ATTRIBUTES		= 1,
847 	ENAHW_FEAT_MAX_QUEUES_NUM		= 2,
848 	ENAHW_FEAT_HW_HINTS			= 3,
849 	ENAHW_FEAT_LLQ				= 4,
850 	ENAHW_FEAT_EXTRA_PROPERTIES_STRINGS	= 5,
851 	ENAHW_FEAT_EXTRA_PROPERTIES_FLAGS	= 6,
852 	ENAHW_FEAT_MAX_QUEUES_EXT		= 7,
853 	ENAHW_FEAT_RSS_HASH_FUNCTION		= 10,
854 	ENAHW_FEAT_STATELESS_OFFLOAD_CONFIG	= 11,
855 	ENAHW_FEAT_RSS_INDIRECTION_TABLE_CONFIG	= 12,
856 	ENAHW_FEAT_MTU				= 14,
857 	ENAHW_FEAT_RSS_HASH_INPUT		= 18,
858 	ENAHW_FEAT_INTERRUPT_MODERATION		= 20,
859 	ENAHW_FEAT_AENQ_CONFIG			= 26,
860 	ENAHW_FEAT_LINK_CONFIG			= 27,
861 	ENAHW_FEAT_HOST_ATTR_CONFIG		= 28,
862 	ENAHW_FEAT_PHC_CONFIG			= 29,
863 	ENAHW_FEAT_NUM				= 32,
864 } enahw_feature_id_t;
865 
866 /*
867  * Device capabilities.
868  *
869  * common: ena_admin_aq_caps_id
870  */
871 typedef enum enahw_capability_id {
872 	ENAHW_CAP_ENI_STATS			= 0,
873 	ENAHW_CAP_ENA_SRD_INFO			= 1,
874 	ENAHW_CAP_CUSTOMER_METRICS		= 2,
875 	ENAHW_CAP_EXTENDED_RESET_REASONS	= 3,
876 	ENAHW_CAP_CDESC_MBZ			= 4,
877 	ENAHW_CAP_NUM
878 } enahw_capability_id_t;
879 
880 /*
881  * The following macros define the maximum version we support for each
882  * feature. These are the feature versions we use to communicate with
883  * the feature command. Linux has these values spread throughout the
884  * code at the various callsites of ena_com_get_feature(). We choose
885  * to centralize our feature versions to make it easier to audit.
886  */
887 #define	ENAHW_FEAT_DEVICE_ATTRIBUTES_VER		0
888 #define	ENAHW_FEAT_MAX_QUEUES_NUM_VER			0
889 #define	ENAHW_FEAT_HW_HINTS_VER				0
890 #define	ENAHW_FEAT_LLQ_VER				0
891 #define	ENAHW_FEAT_EXTRA_PROPERTIES_STRINGS_VER		0
892 #define	ENAHW_FEAT_EXTRA_PROPERTIES_FLAGS_VER		0
893 #define	ENAHW_FEAT_MAX_QUEUES_EXT_VER			1
894 #define	ENAHW_FEAT_RSS_HASH_FUNCTION_VER		0
895 #define	ENAHW_FEAT_STATELESS_OFFLOAD_CONFIG_VER		0
896 #define	ENAHW_FEAT_RSS_INDIRECTION_TABLE_CONFIG_VER	0
897 #define	ENAHW_FEAT_MTU_VER				0
898 #define	ENAHW_FEAT_RSS_HASH_INPUT_VER			0
899 #define	ENAHW_FEAT_INTERRUPT_MODERATION_VER		0
900 #define	ENAHW_FEAT_AENQ_CONFIG_VER			0
901 #define	ENAHW_FEAT_LINK_CONFIG_VER			0
902 #define	ENAHW_FEAT_HOST_ATTR_CONFIG_VER			0
903 
904 /* common: ena_admin_link_types */
905 typedef enum enahw_link_speeds {
906 	ENAHW_LINK_SPEED_1G		= 0x1,
907 	ENAHW_LINK_SPEED_2_HALF_G	= 0x2,
908 	ENAHW_LINK_SPEED_5G		= 0x4,
909 	ENAHW_LINK_SPEED_10G		= 0x8,
910 	ENAHW_LINK_SPEED_25G		= 0x10,
911 	ENAHW_LINK_SPEED_40G		= 0x20,
912 	ENAHW_LINK_SPEED_50G		= 0x40,
913 	ENAHW_LINK_SPEED_100G		= 0x80,
914 	ENAHW_LINK_SPEED_200G		= 0x100,
915 	ENAHW_LINK_SPEED_400G		= 0x200,
916 } enahw_link_speeds_t;
917 
918 /*
919  * Response to ENAHW_FEAT_HW_HINTS.
920  *
921  * Hints from the device to the driver about what values to use for
922  * various communications between the two. A value of 0 indicates
923  * there is no hint and the driver should provide its own default. All
924  * timeout values are in milliseconds.
925  *
926  * common: ena_admin_ena_hw_hints
927  */
928 
929 #define	ENAHW_HINTS_NO_TIMEOUT	0xffff
930 
931 typedef struct enahw_device_hints {
932 	/*
933 	 * The amount of time the driver should wait for an MMIO read
934 	 * reply before giving up and returning an error.
935 	 */
936 	uint16_t edh_mmio_read_timeout;
937 
938 	/*
939 	 * If the driver has not seen an AENQ keep alive in this
940 	 * timeframe, then consider the device hung and perform a
941 	 * reset.
942 	 * common: driver_watchdog_timeout
943 	 */
944 	uint16_t edh_keep_alive_timeout;
945 
946 	/*
947 	 * The timeperiod in which we expect a Tx to report
948 	 * completion, otherwise it is considered "missed". Initiate a
949 	 * device reset when the number of missed completions is
950 	 * greater than the threshold.
951 	 */
952 	uint16_t edh_tx_comp_timeout;
953 	uint16_t edh_missed_tx_reset_threshold;
954 
955 	/*
956 	 * The timeperiod in which we expect an admin command to
957 	 * report completion.
958 	 */
959 	uint16_t edh_admin_comp_timeout;
960 
961 	/*
962 	 * Used by Linux to set the netdevice 'watchdog_timeo' value.
963 	 * This value is used by the networking stack to determine
964 	 * when a pending transmission has stalled. This is similar to
965 	 * the keep alive timeout, except its viewing progress from
966 	 * the perspective of the network stack itself. This difference
967 	 * is subtle but important: the device could be in a state
968 	 * where it has a functioning keep alive heartbeat, but has a
969 	 * stuck Tx queue impeding forward progress of the networking
970 	 * stack (which in many cases results in a scenario
971 	 * indistinguishable from a complete host hang).
972 	 *
973 	 * The mac layer does not currently provide such
974 	 * functionality, though it could and should be extended to
975 	 * support such a feature.
976 	 */
977 	uint16_t edh_net_wd_timeout;
978 
979 	/*
980 	 * The maximum number of cookies/segments allowed in a DMA
981 	 * scatter-gather list.
982 	 */
983 	uint16_t edh_max_tx_sgl;
984 	uint16_t edh_max_rx_sgl;
985 
986 	uint16_t reserved[8];
987 } enahw_device_hints_t;
988 
989 /*
990  * Response to ENAHW_FEAT_DEVICE_ATTRIBUTES.
991  *
992  * common: ena_admin_device_attr_feature_desc
993  */
994 typedef struct enahw_feat_dev_attr {
995 	uint32_t efda_impl_id;
996 	uint32_t efda_device_version;
997 
998 	/*
999 	 * Bitmap representing supported get/set feature subcommands
1000 	 * (enahw_feature_id).
1001 	 */
1002 	uint32_t efda_supported_features;
1003 
1004 	/*
1005 	 * Bitmap representing device capabilities.
1006 	 * (enahw_capability_id)
1007 	 */
1008 	uint32_t efda_capabilities;
1009 
1010 	/* Number of bits used for physical/virtual address. */
1011 	uint32_t efda_phys_addr_width;
1012 	uint32_t efda_virt_addr_with;
1013 
1014 	/* The unicast MAC address in network byte order. */
1015 	uint8_t efda_mac_addr[6];
1016 	uint8_t efda_rsvd2[2];
1017 	uint32_t efda_max_mtu;
1018 } enahw_feat_dev_attr_t;
1019 
1020 /*
1021  * Response to ENAHW_FEAT_MAX_QUEUES_NUM.
1022  *
1023  * common: ena_admin_queue_feature_desc
1024  */
1025 typedef struct enahw_feat_max_queue {
1026 	uint32_t efmq_max_sq_num;
1027 	uint32_t efmq_max_sq_depth;
1028 	uint32_t efmq_max_cq_num;
1029 	uint32_t efmq_max_cq_depth;
1030 	uint32_t efmq_max_legacy_llq_num;
1031 	uint32_t efmq_max_legacy_llq_depth;
1032 	uint32_t efmq_max_header_size;
1033 
1034 	/*
1035 	 * The maximum number of descriptors a single Tx packet may
1036 	 * span. This includes the meta descriptor.
1037 	 */
1038 	uint16_t efmq_max_per_packet_tx_descs;
1039 
1040 	/*
1041 	 * The maximum number of descriptors a single Rx packet may span.
1042 	 */
1043 	uint16_t efmq_max_per_packet_rx_descs;
1044 } enahw_feat_max_queue_t;
1045 
1046 /*
1047  * Response to ENAHW_FEAT_MAX_QUEUES_EXT.
1048  *
1049  * common: ena_admin_queue_ext_feature_desc
1050  */
1051 typedef struct enahw_feat_max_queue_ext {
1052 	uint8_t efmqe_version;
1053 	uint8_t	efmqe_rsvd[3];
1054 
1055 	uint32_t efmqe_max_tx_sq_num;
1056 	uint32_t efmqe_max_tx_cq_num;
1057 	uint32_t efmqe_max_rx_sq_num;
1058 	uint32_t efmqe_max_rx_cq_num;
1059 	uint32_t efmqe_max_tx_sq_depth;
1060 	uint32_t efmqe_max_tx_cq_depth;
1061 	uint32_t efmqe_max_rx_sq_depth;
1062 	uint32_t efmqe_max_rx_cq_depth;
1063 	uint32_t efmqe_max_tx_header_size;
1064 
1065 	/*
1066 	 * The maximum number of descriptors a single Tx packet may
1067 	 * span. This includes the meta descriptor.
1068 	 */
1069 	uint16_t efmqe_max_per_packet_tx_descs;
1070 
1071 	/*
1072 	 * The maximum number of descriptors a single Rx packet may span.
1073 	 */
1074 	uint16_t efmqe_max_per_packet_rx_descs;
1075 } enahw_feat_max_queue_ext_t;
1076 
1077 /*
1078  * Response to ENA_ADMIN_LINK_CONFIG.
1079  *
1080  * common: ena_admin_get_feature_link_desc
1081  */
1082 typedef struct enahw_feat_link_conf {
1083 	/* Link speed in Mbit/s. */
1084 	uint32_t eflc_speed;
1085 
1086 	/* Bit field of enahw_link_speeds_t. */
1087 	uint32_t eflc_supported;
1088 
1089 	/*
1090 	 * 31-2:	reserved
1091 	 * 1:		duplex - Full Duplex
1092 	 * 0:		autoneg
1093 	 */
1094 	uint32_t eflc_flags;
1095 } enahw_feat_link_conf_t;
1096 
1097 #define	ENAHW_FEAT_LINK_CONF_AUTONEG_MASK	BIT(0)
1098 #define	ENAHW_FEAT_LINK_CONF_DUPLEX_SHIFT	1
1099 #define	ENAHW_FEAT_LINK_CONF_DUPLEX_MASK	BIT(1)
1100 
1101 #define	ENAHW_FEAT_LINK_CONF_AUTONEG(f)				\
1102 	((f)->eflc_flags & ENAHW_FEAT_LINK_CONF_AUTONEG_MASK)
1103 
1104 #define	ENAHW_FEAT_LINK_CONF_FULL_DUPLEX(f)				\
1105 	((((f)->eflc_flags & ENAHW_FEAT_LINK_CONF_DUPLEX_MASK) >>	\
1106 	    ENAHW_FEAT_LINK_CONF_DUPLEX_SHIFT) == 1)
1107 
1108 /*
1109  * Response to ENAHW_FEAT_STATELESS_OFFLOAD_CONFIG.
1110  *
1111  * common: ena_admin_feature_offload_desc
1112  */
1113 typedef struct enahw_feat_offload {
1114 	/*
1115 	 * 0 : Tx IPv4 Header Checksum
1116 	 * 1 : Tx L4/IPv4 Partial Checksum
1117 	 *
1118 	 *    The L4 checksum field should be initialized with pseudo
1119 	 *    header checksum.
1120 	 *
1121 	 * 2 : Tx L4/IPv4 Checksum Full
1122 	 * 3 : Tx L4/IPv6 Partial Checksum
1123 	 *
1124 	 *    The L4 checksum field should be initialized with pseudo
1125 	 *    header checksum.
1126 	 *
1127 	 * 4 : Tx L4/IPv6 Checksum Full
1128 	 * 5 : TCP/IPv4 LSO (aka TSO)
1129 	 * 6 : TCP/IPv6 LSO (aka TSO)
1130 	 * 7 : LSO ECN
1131 	 */
1132 	uint32_t efo_tx;
1133 
1134 	/*
1135 	 * Receive side supported stateless offload.
1136 	 *
1137 	 * 0 : Rx IPv4 Header Checksum
1138 	 * 1 : Rx TCP/UDP + IPv4 Full Checksum
1139 	 * 2 : Rx TCP/UDP + IPv6 Full Checksum
1140 	 * 3 : Rx hash calculation
1141 	 */
1142 	uint32_t efo_rx_supported;
1143 
1144 	/* Linux seems to only check rx_supported. */
1145 	uint32_t efo_rx_enabled;
1146 } enahw_feat_offload_t;
1147 
1148 /* Feature Offloads */
1149 #define	ENAHW_FEAT_OFFLOAD_TX_L3_IPV4_CSUM_MASK		BIT(0)
1150 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_PART_SHIFT	1
1151 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_PART_MASK	BIT(1)
1152 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_FULL_SHIFT	2
1153 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_FULL_MASK	BIT(2)
1154 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_PART_SHIFT	3
1155 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_PART_MASK	BIT(3)
1156 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_FULL_SHIFT	4
1157 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_FULL_MASK	BIT(4)
1158 #define	ENAHW_FEAT_OFFLOAD_TSO_IPV4_SHIFT		5
1159 #define	ENAHW_FEAT_OFFLOAD_TSO_IPV4_MASK		BIT(5)
1160 #define	ENAHW_FEAT_OFFLOAD_TSO_IPV6_SHIFT		6
1161 #define	ENAHW_FEAT_OFFLOAD_TSO_IPV6_MASK		BIT(6)
1162 #define	ENAHW_FEAT_OFFLOAD_TSO_ECN_SHIFT		7
1163 #define	ENAHW_FEAT_OFFLOAD_TSO_ECN_MASK			BIT(7)
1164 #define	ENAHW_FEAT_OFFLOAD_RX_L3_IPV4_CSUM_MASK		BIT(0)
1165 #define	ENAHW_FEAT_OFFLOAD_RX_L4_IPV4_CSUM_SHIFT	1
1166 #define	ENAHW_FEAT_OFFLOAD_RX_L4_IPV4_CSUM_MASK		BIT(1)
1167 #define	ENAHW_FEAT_OFFLOAD_RX_L4_IPV6_CSUM_SHIFT	2
1168 #define	ENAHW_FEAT_OFFLOAD_RX_L4_IPV6_CSUM_MASK		BIT(2)
1169 #define	ENAHW_FEAT_OFFLOAD_RX_HASH_SHIFT		3
1170 #define	ENAHW_FEAT_OFFLOAD_RX_HASH_MASK			BIT(3)
1171 
1172 #define	ENAHW_FEAT_OFFLOAD_TX_L3_IPV4_CSUM(f)				\
1173 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TX_L3_IPV4_CSUM_MASK) != 0)
1174 
1175 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_PART(f)			\
1176 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_PART_MASK) != 0)
1177 
1178 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_FULL(f)			\
1179 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TX_L4_IPV4_CSUM_FULL_MASK) != 0)
1180 
1181 #define	ENAHW_FEAT_OFFLOAD_TSO_IPV4(f)				\
1182 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TSO_IPV4_MASK) != 0)
1183 
1184 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_PART(f)		\
1185 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_PART_MASK) != 0)
1186 
1187 #define	ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_FULL(f)		\
1188 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TX_L4_IPV6_CSUM_FULL_MASK) != 0)
1189 
1190 #define	ENAHW_FEAT_OFFLOAD_TSO_IPV6(f)				\
1191 	(((f)->efo_tx & ENAHW_FEAT_OFFLOAD_TSO_IPV6_MASK) != 0)
1192 
1193 #define	ENAHW_FEAT_OFFLOAD_RX_L3_IPV4_CSUM(f)				\
1194 	(((f)->efo_rx_supported & ENAHW_FEAT_OFFLOAD_RX_L3_IPV4_CSUM_MASK) != 0)
1195 
1196 #define	ENAHW_FEAT_OFFLOAD_RX_L4_IPV4_CSUM(f)				\
1197 	(((f)->efo_rx_supported & ENAHW_FEAT_OFFLOAD_RX_L4_IPV4_CSUM_MASK) != 0)
1198 
1199 #define	ENAHW_FEAT_OFFLOAD_RX_L4_IPV6_CSUM(f)				\
1200 	(((f)->efo_rx_supported & ENAHW_FEAT_OFFLOAD_RX_L4_IPV6_CSUM_MASK) != 0)
1201 
1202 typedef union enahw_resp_get_feat {
1203 	uint32_t			ergf_raw[14];
1204 	enahw_feat_dev_attr_t		ergf_dev_attr;
1205 	enahw_feat_max_queue_t		ergf_max_queue;
1206 	enahw_feat_max_queue_ext_t	ergf_max_queue_ext;
1207 	enahw_feat_aenq_t		ergf_aenq;
1208 	enahw_feat_link_conf_t		ergf_link_conf;
1209 	enahw_feat_offload_t		ergf_offload;
1210 	enahw_device_hints_t		ergf_hints;
1211 } enahw_resp_get_feat_u;
1212 
1213 /*
1214  * common: ena_admin_acq_create_cq_resp_desc
1215  */
1216 typedef struct enahw_resp_create_cq {
1217 	/*
1218 	 * The hardware's index for this queue.
1219 	 */
1220 	uint16_t ercq_idx;
1221 
1222 	/*
1223 	 * Apparently the number of descriptors granted may be
1224 	 * different than that requested.
1225 	 */
1226 	uint16_t ercq_actual_num_descs;
1227 	uint32_t ercq_numa_node_reg_offset;
1228 	/* CQ doorbell register - no longer supported by any ENA adapter */
1229 	uint32_t ercq_head_db_reg_offset;
1230 	uint32_t ercq_interrupt_mask_reg_offset; /* stop intr */
1231 } enahw_resp_create_cq_t;
1232 
1233 /* common: ena_admin_acq_create_sq_resp_desc */
1234 typedef struct enahw_resp_create_sq {
1235 	uint16_t ersq_idx;
1236 	uint16_t ersq_rsvdw1;
1237 	uint32_t ersq_db_reg_offset;
1238 	uint32_t ersq_llq_descs_reg_offset;
1239 	uint32_t ersq_llq_headers_reg_offset;
1240 } enahw_resp_create_sq_t;
1241 
1242 /* common: ena_admin_basic_stats */
1243 typedef struct enahw_resp_basic_stats {
1244 	uint32_t erbs_tx_bytes_low;
1245 	uint32_t erbs_tx_bytes_high;
1246 	uint32_t erbs_tx_pkts_low;
1247 	uint32_t erbs_tx_pkts_high;
1248 	uint32_t erbs_rx_bytes_low;
1249 	uint32_t erbs_rx_bytes_high;
1250 	uint32_t erbs_rx_pkts_low;
1251 	uint32_t erbs_rx_pkts_high;
1252 	uint32_t erbs_rx_drops_low;
1253 	uint32_t erbs_rx_drops_high;
1254 	uint32_t erbs_tx_drops_low;
1255 	uint32_t erbs_tx_drops_high;
1256 	uint32_t erbs_rx_overruns_low;
1257 	uint32_t erbs_rx_overruns_high;
1258 } enahw_resp_basic_stats_t;
1259 
1260 /* common: ena_admin_eni_stats */
1261 typedef struct enahw_resp_eni_stats {
1262 	/*
1263 	 * The number of inbound packets dropped due to aggregate
1264 	 * inbound bandwidth allowance being exceeded.
1265 	 */
1266 	uint64_t eres_bw_in_exceeded;
1267 
1268 	/*
1269 	 * The number of outbound packets dropped due to aggregated outbound
1270 	 * bandwidth allowance being exceeded.
1271 	 */
1272 	uint64_t eres_bw_out_exceeded;
1273 
1274 	/*
1275 	 * The number of packets dropped due to the Packets Per Second
1276 	 * allowance being exceeded.
1277 	 */
1278 	uint64_t eres_pps_exceeded;
1279 
1280 	/*
1281 	 * The number of packets dropped due to connection tracking
1282 	 * allowance being exceeded and leading to failure in
1283 	 * establishment of new connections.
1284 	 */
1285 	uint64_t eres_conns_exceeded;
1286 
1287 	/*
1288 	 * The number of packets dropped due to linklocal packet rate
1289 	 * allowance being exceeded.
1290 	 */
1291 	uint64_t eres_linklocal_exceeded;
1292 } enahw_resp_eni_stats_t;
1293 
1294 /*
1295  * common: ena_admin_acq_entry
1296  */
1297 typedef struct enahw_resp_desc {
1298 	/* The index of the completed command. */
1299 	uint16_t	erd_cmd_id;
1300 
1301 	/* The status of the command (enahw_resp_status_t). */
1302 	uint8_t		erd_status;
1303 
1304 	/*
1305 	 * 7-1	Reserved
1306 	 * 0	Phase
1307 	 */
1308 	uint8_t		erd_flags;
1309 
1310 	/* Extended status. */
1311 	uint16_t	erd_ext_status;
1312 
1313 	/*
1314 	 * The AQ entry (enahw_cmd_desc) index which has been consumed
1315 	 * by the device and can be reused. However, this field is not
1316 	 * used in the other drivers, and it seems to be redundant
1317 	 * with the erd_idx field.
1318 	 */
1319 	uint16_t	erd_sq_head_idx;
1320 
1321 	union {
1322 		uint32_t			raw[14];
1323 		enahw_resp_get_feat_u		erd_get_feat;
1324 		enahw_resp_create_cq_t		erd_create_cq;
1325 		/* destroy_cq: No command-specific response. */
1326 		enahw_resp_create_sq_t		erd_create_sq;
1327 		/* destroy_sq: No command-specific response. */
1328 		enahw_resp_basic_stats_t	erd_basic_stats;
1329 		enahw_resp_eni_stats_t		erd_eni_stats;
1330 	} erd_resp;
1331 } enahw_resp_desc_t;
1332 
1333 /* common: ENA_ADMIN_ACQ_COMMON_DESC */
1334 #define	ENAHW_RESP_CMD_ID_MASK	GENMASK(11, 0)
1335 #define	ENAHW_RESP_PHASE_MASK	0x1
1336 
1337 #define	ENAHW_RESP_CMD_ID(desc)				\
1338 	(((desc)->erd_cmd_id) & ENAHW_RESP_CMD_ID_MASK)
1339 
1340 /*
1341  * The response status of an Admin Queue command.
1342  *
1343  * common: ena_admin_aq_completion_status
1344  */
1345 typedef enum enahw_resp_status {
1346 	ENAHW_RESP_SUCCESS			= 0,
1347 	ENAHW_RESP_RESOURCE_ALLOCATION_FAILURE	= 1,
1348 	ENAHW_RESP_BAD_OPCODE			= 2,
1349 	ENAHW_RESP_UNSUPPORTED_OPCODE		= 3,
1350 	ENAHW_RESP_MALFORMED_REQUEST		= 4,
1351 	/*
1352 	 * At this place in the common code it mentions that there is
1353 	 * "additional status" in the response descriptor's
1354 	 * erd_ext_status field. As the common code never actually
1355 	 * uses this field it's hard to know the exact meaning of the
1356 	 * comment. My best guess is the illegal parameter error
1357 	 * stores additional context in the erd_ext_status field. But
1358 	 * how to interpret that additional context is anyone's guess.
1359 	 */
1360 	ENAHW_RESP_ILLEGAL_PARAMETER		= 5,
1361 	ENAHW_RESP_UNKNOWN_ERROR		= 6,
1362 	ENAHW_RESP_RESOURCE_BUSY		= 7,
1363 } enahw_resp_status_t;
1364 
1365 /*
1366  * I/O macros and structures.
1367  * -------------------------
1368  */
1369 
1370 /*
1371  * The device's L3 and L4 protocol numbers. These are specific to the
1372  * ENA device and not to be confused with IANA protocol numbers.
1373  *
1374  * common: ena_eth_io_l3_proto_index
1375  */
1376 typedef enum enahw_io_l3_proto {
1377 	ENAHW_IO_L3_PROTO_UNKNOWN	= 0,
1378 	ENAHW_IO_L3_PROTO_IPV4		= 8,
1379 	ENAHW_IO_L3_PROTO_IPV6		= 11,
1380 	ENAHW_IO_L3_PROTO_FCOE		= 21,
1381 	ENAHW_IO_L3_PROTO_ROCE		= 22,
1382 } enahw_io_l3_proto_t;
1383 
1384 /* common: ena_eth_io_l4_proto_index */
1385 typedef enum enahw_io_l4_proto {
1386 	ENAHW_IO_L4_PROTO_UNKNOWN		= 0,
1387 	ENAHW_IO_L4_PROTO_TCP			= 12,
1388 	ENAHW_IO_L4_PROTO_UDP			= 13,
1389 	ENAHW_IO_L4_PROTO_ROUTEABLE_ROCE	= 23,
1390 } enahw_io_l4_proto_t;
1391 
1392 /* common: ena_eth_io_tx_desc */
1393 typedef struct enahw_tx_data_desc {
1394 	/*
1395 	 * 15-0   Buffer Length (LENGTH)
1396 	 *
1397 	 *	The buffer length in bytes. This should NOT include the
1398 	 *	Ethernet FCS bytes.
1399 	 *
1400 	 * 21-16  Request ID High Bits [15-10] (REQ_ID_HI)
1401 	 * 22	  Reserved Zero
1402 	 * 23	  Metadata Flag always zero (META_DESC)
1403 	 *
1404 	 *	This flag indicates if the descriptor is a metadata
1405 	 *	descriptor or not. In this case we are defining the Tx
1406 	 *	descriptor, so it's always zero.
1407 	 *
1408 	 * 24	  Phase bit (PHASE)
1409 	 * 25	  Reserved Zero
1410 	 * 26	  First Descriptor Bit (FIRST)
1411 	 *
1412 	 *	Indicates this is the first descriptor for the frame.
1413 	 *
1414 	 * 27	  Last Descriptor Bit (LAST)
1415 	 *
1416 	 *	Indicates this is the last descriptor for the frame.
1417 	 *
1418 	 * 28	  Completion Request Bit (COMP_REQ)
1419 	 *
1420 	 *	Indicates if completion should be posted after the
1421 	 *	frame is transmitted. This bit is only valid on the
1422 	 *	first descriptor.
1423 	 *
1424 	 * 31-29  Reserved Zero
1425 	 */
1426 	uint32_t etd_len_ctrl;
1427 
1428 	/*
1429 	 * 3-0	  L3 Protocol Number (L3_PROTO_IDX)
1430 	 *
1431 	 *	The L3 protocol type, one of enahw_io_l3_proto_t. This
1432 	 *	field is required when L3_CSUM_EN or TSO_EN is set.
1433 	 *
1434 	 * 4	  Don't Fragment Bit (DF)
1435 	 *
1436 	 *	The value of IPv4 DF. This value must copy the value
1437 	 *	found in the packet's IPv4 header.
1438 	 *
1439 	 * 6-5	  Reserved Zero
1440 	 * 7	  TSO Bit (TSO_EN)
1441 	 *
1442 	 *	Enable TCP Segment Offload.
1443 	 *
1444 	 * 12-8	  L4 Protocol Number (L4_PROTO_IDX)
1445 	 *
1446 	 *	The L4 protocol type, one of enahw_io_l4_proto_t. This
1447 	 *	field is required when L4_CSUM_EN or TSO_EN are
1448 	 *	set.
1449 	 *
1450 	 * 13	  L3 Checksum Offload (L3_CSUM_EN)
1451 	 *
1452 	 *	Enable IPv4 header checksum offload.
1453 	 *
1454 	 * 14	  L4 Checksum Offload (L4_CSUM_EN)
1455 	 *
1456 	 *	Enable TCP/UDP checksum offload.
1457 	 *
1458 	 * 15	  Ethernet FCS Disable (ETHERNET_FCS_DIS)
1459 	 *
1460 	 *	Disable the device's Ethernet Frame Check sequence.
1461 	 *
1462 	 * 16	  Reserved Zero
1463 	 * 17	  L4 Partial Checksum Present (L4_CSUM_PARTIAL)
1464 	 *
1465 	 *	When set it indicates the host has already provided
1466 	 *	the pseudo-header checksum. Otherwise, it is up to the
1467 	 *	device to calculate it.
1468 	 *
1469 	 *	When set and using TSO the host stack must remember
1470 	 *	not to include the TCP segment length in the supplied
1471 	 *	pseudo-header.
1472 	 *
1473 	 *	The host stack should provide the pseudo-header
1474 	 *	checksum when using IPv6 with Routing Headers.
1475 	 *
1476 	 * 21-18  Reserved Zero
1477 	 * 31-22  Request ID Low [9-0] (REQ_ID_LO)
1478 	 */
1479 	uint32_t etd_meta_ctrl;
1480 
1481 	/* The low 32 bits of the buffer address. */
1482 	uint32_t etd_buff_addr_lo;
1483 
1484 	/*
1485 	 * address high and header size
1486 	 *
1487 	 * 15-0	Buffer Address High [47-32] (ADDR_HI)
1488 	 *
1489 	 *	The upper 15 bits of the buffer address.
1490 	 *
1491 	 * 23-16  Reserved Zero
1492 	 * 31-24  Header Length (HEADER_LENGTH)
1493 	 *
1494 	 *	This field has dubious documentation in the
1495 	 *	common/Linux driver code, even contradicting itself in
1496 	 *	the same sentence. Here's what it says, verbatim:
1497 	 *
1498 	 *	> Header length. For Low Latency Queues, this fields
1499 	 *	> indicates the number of bytes written to the
1500 	 *	> headers' memory. For normal queues, if packet is TCP
1501 	 *	> or UDP, and longer than max_header_size, then this
1502 	 *	> field should be set to the sum of L4 header offset
1503 	 *	> and L4 header size(without options), otherwise, this
1504 	 *	> field should be set to 0. For both modes, this field
1505 	 *	> must not exceed the max_header_size. max_header_size
1506 	 *	> value is reported by the Max Queues Feature
1507 	 *	> descriptor
1508 	 *
1509 	 *	Here's what one _might_ ascertain from the above.
1510 	 *
1511 	 *	1. This field should always be set in the case of
1512 	 *	   LLQs/device placement.
1513 	 *
1514 	 *	2. This field must _never_ exceed the max header size
1515 	 *	   as reported by feature detection. In our code this
1516 	 *	   would be efmq_max_header_size for older ENA devices
1517 	 *	   and efmqe_max_tx_header_size for newer ones. One
1518 	 *	   empirical data point from a t3.small (with newer
1519 	 *	   device) is a max Tx header size of 128 bytes.
1520 	 *
1521 	 *	3. If the packet is TCP or UDP, and the packet (or the
1522 	 *	   headers?) is longer than the max header size, then
1523 	 *	   this field should be set to the total header size
1524 	 *	   with the exception of TCP header options.
1525 	 *	   Otherwise, if the packet is not TCP or UDP, or if
1526 	 *	   the packet (or header length?) _does not_ exceed
1527 	 *	   the max header size, then set this value to 0.
1528 	 *
1529 	 *	One might think, based on (3), that when the header
1530 	 *	size exceeds the max this field needs to be set, but
1531 	 *	that contradicts (2), which dictates that the total
1532 	 *	header size can never exceed the max. Sure enough, the
1533 	 *	Linux code drops all packets with headers that exceed
1534 	 *	the max. So in that case it would mean that "and
1535 	 *	longer than max_header_size" is referring to the total
1536 	 *	packet length. So for most workloads, the TCP/UDP
1537 	 *	packets should have this field set, to indicate their
1538 	 *	header length. This matches with Linux, which seems to
1539 	 *	set header length regardless of IP protocol.
1540 	 *
1541 	 *	However, the FreeBSD code tells a different story. In
1542 	 *	it's non-LLQ Tx path it has the following comment,
1543 	 *	verbatim:
1544 	 *
1545 	 *	> header_len is just a hint for the device. Because
1546 	 *	> FreeBSD is not giving us information about packet
1547 	 *	> header length and it is not guaranteed that all
1548 	 *	> packet headers will be in the 1st mbuf, setting
1549 	 *	> header_len to 0 is making the device ignore this
1550 	 *	> value and resolve header on it's own.
1551 	 *
1552 	 *	According to this we can just set the value to zero
1553 	 *	and let the device figure it out. This maps better to
1554 	 *	illumos, where we also allow the header to potentially
1555 	 *	span multiple mblks (though we do have access to the
1556 	 *	header sizes via mac_ether_offload_info_t).
1557 	 *
1558 	 *	The upshot: for now we take advantage of the device's
1559 	 *	ability to determine the header length on its own, at
1560 	 *	the potential cost of some performance (not measured).
1561 	 */
1562 	uint32_t etd_buff_addr_hi_hdr_sz;
1563 } enahw_tx_data_desc_t;
1564 
1565 #define	ENAHW_TX_DESC_LENGTH_MASK		GENMASK(15, 0)
1566 #define	ENAHW_TX_DESC_REQ_ID_HI_SHIFT		16
1567 #define	ENAHW_TX_DESC_REQ_ID_HI_MASK		GENMASK(21, 16)
1568 #define	ENAHW_TX_DESC_META_DESC_SHIFT		23
1569 #define	ENAHW_TX_DESC_META_DESC_MASK		BIT(23)
1570 #define	ENAHW_TX_DESC_PHASE_SHIFT		24
1571 #define	ENAHW_TX_DESC_PHASE_MASK		BIT(24)
1572 #define	ENAHW_TX_DESC_FIRST_SHIFT		26
1573 #define	ENAHW_TX_DESC_FIRST_MASK		BIT(26)
1574 #define	ENAHW_TX_DESC_LAST_SHIFT		27
1575 #define	ENAHW_TX_DESC_LAST_MASK			BIT(27)
1576 #define	ENAHW_TX_DESC_COMP_REQ_SHIFT		28
1577 #define	ENAHW_TX_DESC_COMP_REQ_MASK		BIT(28)
1578 #define	ENAHW_TX_DESC_L3_PROTO_IDX_MASK		GENMASK(3, 0)
1579 #define	ENAHW_TX_DESC_DF_SHIFT			4
1580 #define	ENAHW_TX_DESC_DF_MASK			BIT(4)
1581 #define	ENAHW_TX_DESC_TSO_EN_SHIFT		7
1582 #define	ENAHW_TX_DESC_TSO_EN_MASK		BIT(7)
1583 #define	ENAHW_TX_DESC_L4_PROTO_IDX_SHIFT	8
1584 #define	ENAHW_TX_DESC_L4_PROTO_IDX_MASK		GENMASK(12, 8)
1585 #define	ENAHW_TX_DESC_L3_CSUM_EN_SHIFT		13
1586 #define	ENAHW_TX_DESC_L3_CSUM_EN_MASK		BIT(13)
1587 #define	ENAHW_TX_DESC_L4_CSUM_EN_SHIFT		14
1588 #define	ENAHW_TX_DESC_L4_CSUM_EN_MASK		BIT(14)
1589 #define	ENAHW_TX_DESC_ETHERNET_FCS_DIS_SHIFT	15
1590 #define	ENAHW_TX_DESC_ETHERNET_FCS_DIS_MASK	BIT(15)
1591 #define	ENAHW_TX_DESC_L4_CSUM_PARTIAL_SHIFT	17
1592 #define	ENAHW_TX_DESC_L4_CSUM_PARTIAL_MASK	BIT(17)
1593 #define	ENAHW_TX_DESC_REQ_ID_LO_SHIFT		22
1594 #define	ENAHW_TX_DESC_REQ_ID_LO_MASK		GENMASK(31, 22)
1595 #define	ENAHW_TX_DESC_ADDR_HI_MASK		GENMASK(15, 0)
1596 #define	ENAHW_TX_DESC_HEADER_LENGTH_SHIFT	24
1597 #define	ENAHW_TX_DESC_HEADER_LENGTH_MASK	GENMASK(31, 24)
1598 
1599 #define	ENAHW_TX_DESC_LENGTH(desc, len)					\
1600 	(((desc)->etd_len_ctrl) |= ((len) & ENAHW_TX_DESC_LENGTH_MASK))
1601 
1602 #define	ENAHW_TX_DESC_FIRST_ON(desc)				\
1603 	(((desc)->etd_len_ctrl) |= ENAHW_TX_DESC_FIRST_MASK)
1604 
1605 #define	ENAHW_TX_DESC_FIRST_OFF(desc)				\
1606 	(((desc)->etd_len_ctrl) &= ~ENAHW_TX_DESC_FIRST_MASK)
1607 
1608 #define	ENAHW_TX_DESC_REQID_HI(desc, reqid)				\
1609 	(((desc)->etd_len_ctrl) |=					\
1610 	    ((((reqid) >> 10) << ENAHW_TX_DESC_REQ_ID_HI_SHIFT) &	\
1611 		ENAHW_TX_DESC_REQ_ID_HI_MASK))
1612 
1613 #define	ENAHW_TX_DESC_REQID_LO(desc, reqid)				\
1614 	(((desc)->etd_meta_ctrl) |=					\
1615 	    (((reqid) << ENAHW_TX_DESC_REQ_ID_LO_SHIFT) &		\
1616 		ENAHW_TX_DESC_REQ_ID_LO_MASK))
1617 
1618 #define	ENAHW_TX_DESC_PHASE(desc, phase)				\
1619 	(((desc)->etd_len_ctrl) |= (((phase) << ENAHW_TX_DESC_PHASE_SHIFT) & \
1620 	    ENAHW_TX_DESC_PHASE_MASK))
1621 
1622 #define	ENAHW_TX_DESC_LAST_ON(desc)				\
1623 	(((desc)->etd_len_ctrl) |= ENAHW_TX_DESC_LAST_MASK)
1624 
1625 #define	ENAHW_TX_DESC_LAST_OFF(desc)				\
1626 	(((desc)->etd_len_ctrl) &= ~ENAHW_TX_DESC_LAST_MASK)
1627 
1628 #define	ENAHW_TX_DESC_COMP_REQ_ON(desc)				\
1629 	(((desc)->etd_len_ctrl) |= ENAHW_TX_DESC_COMP_REQ_MASK)
1630 
1631 #define	ENAHW_TX_DESC_COMP_REQ_OFF(desc)				\
1632 	(((desc)->etd_len_ctrl) &= ~ENAHW_TX_DESC_COMP_REQ_MASK)
1633 
1634 #define	ENAHW_TX_DESC_META_DESC_ON(desc)				\
1635 	(((desc)->etd_len_ctrl) |= ENAHW_TX_DESC_META_DESC_MASK)
1636 
1637 #define	ENAHW_TX_DESC_META_DESC_OFF(desc)				\
1638 	(((desc)->etd_len_ctrl) &= ~ENAHW_TX_DESC_META_DESC_MASK)
1639 
1640 #define	ENAHW_TX_DESC_ADDR_LO(desc, addr)	\
1641 	(((desc)->etd_buff_addr_lo) = (addr))
1642 
1643 #define	ENAHW_TX_DESC_ADDR_HI(desc, addr)				\
1644 	(((desc)->etd_buff_addr_hi_hdr_sz) |=				\
1645 	    (((addr) >> 32) & ENAHW_TX_DESC_ADDR_HI_MASK))
1646 
1647 #define	ENAHW_TX_DESC_HEADER_LENGTH(desc, len)			\
1648 	(((desc)->etd_buff_addr_hi_hdr_sz) |=			\
1649 	    (((len) << ENAHW_TX_DESC_HEADER_LENGTH_SHIFT) &	\
1650 		ENAHW_TX_DESC_HEADER_LENGTH_MASK))
1651 
1652 #define	ENAHW_TX_DESC_DF_ON(desc)				\
1653 	((desc)->etd_meta_ctrl |= ENAHW_TX_DESC_DF_MASK)
1654 
1655 #define	ENAHW_TX_DESC_TSO_OFF(desc)				\
1656 	(((desc)->etd_meta_ctrl) &= ~ENAHW_TX_DESC_TSO_EN_MASK)
1657 
1658 #define	ENAHW_TX_DESC_L3_CSUM_OFF(desc)				\
1659 	(((desc)->etd_meta_ctrl) &= ~ENAHW_TX_DESC_L3_CSUM_EN_MASK)
1660 
1661 #define	ENAHW_TX_DESC_L4_CSUM_OFF(desc)				\
1662 	(((desc)->etd_meta_ctrl) &= ~ENAHW_TX_DESC_L4_CSUM_EN_MASK)
1663 
1664 #define	ENAHW_TX_DESC_L4_CSUM_PARTIAL_ON(desc)				\
1665 	(((desc)->etd_meta_ctrl) &= ~ENAHW_TX_DESC_L4_CSUM_PARTIAL_MASK)
1666 
1667 /* common: ena_eth_io_tx_meta_desc */
1668 typedef struct enahw_tx_meta_desc {
1669 	/*
1670 	 * 9-0	  Request ID Low [9-0] (REQ_ID_LO)
1671 	 * 13-10  Reserved Zero
1672 	 * 14	  Extended Metadata Valid (EXT_VALID)
1673 	 *
1674 	 *	When set this descriptor contains valid extended
1675 	 *	metadata. The extended metadata includes the L3/L4
1676 	 *	length and offset fields as well as the MSS bits. This
1677 	 *	is needed for TSO.
1678 	 *
1679 	 * 15	  Reserved Zero
1680 	 * 19-16  MSS High Bits (MSS_HI)
1681 	 * 20	  Meta Type (ETH_META_TYPE)
1682 	 *
1683 	 *	If enabled this is an extended metadata descriptor.
1684 	 *	This seems redundant with EXT_VALID.
1685 	 *
1686 	 * 21	  Meta Store (META_STORE)
1687 	 *
1688 	 *	Store the extended metadata in the queue cache.
1689 	 *
1690 	 * 22	  Reserved Zero
1691 	 * 23	  Metadata Flag (META_DESC) -- always one
1692 	 * 24	  Phase (PHASE)
1693 	 * 25	  Reserved Zero
1694 	 * 26	  First Descriptor Bit (FIRST)
1695 	 * 27	  Last Descriptor Bit (LAST)
1696 	 * 28	  Completion Request Bit (COMP_REQ)
1697 	 * 31-29  Reserved Zero
1698 	 */
1699 	uint32_t etmd_len_ctrl;
1700 
1701 	/*
1702 	 * 5-0	  Request ID High Bits [15-10] (REQ_ID_HI)
1703 	 * 31-6	  Reserved Zero
1704 	 */
1705 	uint32_t etmd_word1;
1706 
1707 	/*
1708 	 * 7-0	  L3 Header Length (L3_HDR_LEN)
1709 	 * 15:8	  L3 Header Offset (L3_HDR_OFF)
1710 	 * 21:16  L4 Header Length in Words (L4_HDR_LEN_IN_WORDS)
1711 	 *
1712 	 *    Specifies the L4 header length in words. The device
1713 	 *    assumes the L4 header follows directly after the L3
1714 	 *    header and that the L4 offset is equal to L3_HDR_OFF +
1715 	 *    L3_HDR_LEN.
1716 	 *
1717 	 * 31-22  MSS Low Bits (MSS_LO)
1718 	 */
1719 	uint32_t etmd_word2;
1720 	uint32_t etmd_reserved;
1721 } enahw_tx_meta_desc_t;
1722 
1723 /* common: N/A */
1724 typedef union enahw_tx_desc {
1725 	enahw_tx_data_desc_t etd_data;
1726 	enahw_tx_meta_desc_t etd_meta;
1727 } enahw_tx_desc_t;
1728 
1729 /* common: ena_eth_io_tx_cdesc */
1730 typedef struct enahw_tx_cdesc {
1731 	/*
1732 	 * 15-0	  Request ID Bits
1733 	 * 16	  Reserved Zero
1734 	 */
1735 	uint16_t etc_req_id;
1736 
1737 	/*
1738 	 * Presumably the status of the Tx, though the Linux driver
1739 	 * never checks this field.
1740 	 */
1741 	uint8_t etc_status;
1742 
1743 	/*
1744 	 * 0	  Phase
1745 	 * 7-1	  Reserved Zero
1746 	 */
1747 	uint8_t etc_flags;
1748 
1749 	/*
1750 	 * This isn't documented or used in the Linux driver, but
1751 	 * these probably store the submission queue ID and the
1752 	 * submission queue head index.
1753 	 */
1754 	uint16_t etc_sub_qid;
1755 	uint16_t etc_sq_head_idx;
1756 } enahw_tx_cdesc_t;
1757 
1758 #define	ENAHW_TX_CDESC_PHASE_SHIFT	0
1759 #define	ENAHW_TX_CDESC_PHASE_MASK	BIT(0)
1760 
1761 #define	ENAHW_TX_CDESC_GET_PHASE(cdesc)				\
1762 	((cdesc)->etc_flags & ENAHW_TX_CDESC_PHASE_MASK)
1763 
1764 /* common: ena_eth_io_rx_desc */
1765 typedef struct enahw_rx_desc {
1766 	/*
1767 	 * The length of the buffer provided by the host, in bytes.
1768 	 * Use the value of 0 to indicate 64K.
1769 	 */
1770 	uint16_t erd_length;
1771 	uint8_t erd_reserved1;
1772 
1773 	/*
1774 	 * 0	  Phase (PHASE)
1775 	 * 1	  Reserved Zero
1776 	 * 2	  First (FIRST)
1777 	 *
1778 	 *	Indicates this is the first descriptor for the frame.
1779 	 *
1780 	 * 3	  Last (LAST)
1781 	 *
1782 	 *	Indicates this is the last descriptor for the frame.
1783 	 *
1784 	 * 4	  Completion Request (COMP_REQ)
1785 	 *
1786 	 *	Indicates that a completion request should be generated
1787 	 *	for this descriptor.
1788 	 *
1789 	 * 7-5	  Reserved Zero
1790 	 */
1791 	uint8_t erd_ctrl;
1792 
1793 	/*
1794 	 * 15-0	  Request ID
1795 	 * 16	  Reserved 0
1796 	 */
1797 	uint16_t erd_req_id;
1798 	uint16_t erd_reserved2;
1799 
1800 	/* The physical address of the buffer provided by the host. */
1801 	uint32_t erd_buff_addr_lo;
1802 	uint16_t erd_buff_addr_hi;
1803 	uint16_t erd_reserved3;
1804 } enahw_rx_desc_t;
1805 
1806 #define	ENAHW_RX_DESC_PHASE_MASK	BIT(0)
1807 #define	ENAHW_RX_DESC_FIRST_SHIFT	2
1808 #define	ENAHW_RX_DESC_FIRST_MASK	BIT(2)
1809 #define	ENAHW_RX_DESC_LAST_SHIFT	3
1810 #define	ENAHW_RX_DESC_LAST_MASK		BIT(3)
1811 #define	ENAHW_RX_DESC_COMP_REQ_SHIFT	4
1812 #define	ENAHW_RX_DESC_COMP_REQ_MASK	BIT(4)
1813 
1814 #define	ENAHW_RX_DESC_CLEAR_CTRL(desc)	((desc)->erd_ctrl = 0)
1815 #define	ENAHW_RX_DESC_SET_PHASE(desc, val)				\
1816 	((desc)->erd_ctrl |= ((val) & ENAHW_RX_DESC_PHASE_MASK))
1817 
1818 #define	ENAHW_RX_DESC_SET_FIRST(desc)			\
1819 	((desc)->erd_ctrl |= ENAHW_RX_DESC_FIRST_MASK)
1820 
1821 #define	ENAHW_RX_DESC_SET_LAST(desc)			\
1822 	((desc)->erd_ctrl |= ENAHW_RX_DESC_LAST_MASK)
1823 
1824 #define	ENAHW_RX_DESC_SET_COMP_REQ(desc)			\
1825 	((desc)->erd_ctrl |= ENAHW_RX_DESC_COMP_REQ_MASK)
1826 
1827 /*
1828  * Ethernet parsing information is only valid when last == 1.
1829  *
1830  * common: ena_eth_io_rx_cdesc_base
1831  */
1832 typedef struct enahw_rx_cdesc {
1833 	/*
1834 	 * 4-0	  L3 Protocol Number (L3_PROTO)
1835 	 *
1836 	 *	The L3 protocol type, one of enahw_io_l3_proto_t.
1837 	 *
1838 	 * 6-5	  (SRC_VLAN_CNT)
1839 	 * 7	  Reserved Zero
1840 	 * 12-8	  L4 Protocol Number (L4_PROTO)
1841 	 * 13	  L3 Checksum Error (L3_CSUM_ERR)
1842 	 *
1843 	 *	When set either the L3 checksum failed to match or the
1844 	 *	controller didn't attempt to validate the checksum.
1845 	 *	This bit is valid only when L3_PROTO indicates an IPv4
1846 	 *	packet.
1847 	 *
1848 	 * 14	  L4 Checksum Error (L4_CSUM_ERR)
1849 	 *
1850 	 *	When set either the L4 checksum failed to match or the
1851 	 *	controller didn't attempt to validate the checksum.
1852 	 *	This bit is valid only when L4_PROTO indicates a
1853 	 *	TCP/UDP packet, IPV4_FRAG is not set, and
1854 	 *	L4_CSUM_CHECKED is set.
1855 	 *
1856 	 * 15	  IPv4 Fragmented (IPV4_FRAG)
1857 	 * 16	  L4 Checksum Validated (L4_CSUM_CHECKED)
1858 	 *
1859 	 *	When set it indicates the device attempted to validate
1860 	 *	the L4 checksum.
1861 	 *
1862 	 * 23-17  Reserved Zero
1863 	 * 24	  Phase (PHASE)
1864 	 * 25	  (L3_CSUM2)
1865 	 *
1866 	 *	According to the Linux source this is the "second
1867 	 *	checksum engine result". It's never checked.
1868 	 *
1869 	 * 26	  First Descriptor Bit (FIRST)
1870 	 *
1871 	 *	Indicates the first descriptor for the frame.
1872 	 *
1873 	 * 27	  Last Descriptor Bit (LAST)
1874 	 *
1875 	 *	Indicates the last descriptor for the frame.
1876 	 *
1877 	 * 29-28  Reserved Zero
1878 	 * 30	  Buffer Type (BUFFER)
1879 	 *
1880 	 *	When enabled indicates this is a data descriptor.
1881 	 *	Otherwse, it is a metadata descriptor.
1882 	 *
1883 	 * 31 : reserved31
1884 	 */
1885 	uint32_t erc_status;
1886 	uint16_t erc_length;
1887 	uint16_t erc_req_id;
1888 
1889 	/* 32-bit hash result */
1890 	uint32_t erc_hash;
1891 	uint16_t erc_sub_qid;
1892 
1893 	/*
1894 	 * The device may choose to offset the start of the header
1895 	 * data (which implies this value only applies to the first
1896 	 * descriptor). When and why the device does this is not
1897 	 * documented in the common code. The most likely case would
1898 	 * be for IP header alignment.
1899 	 */
1900 	uint8_t erc_offset;
1901 	uint8_t erc_reserved;
1902 } enahw_rx_cdesc_t;
1903 
1904 #define	ENAHW_RX_CDESC_L3_PROTO_MASK		GENMASK(4, 0)
1905 #define	ENAHW_RX_CDESC_SRC_VLAN_CNT_SHIFT	5
1906 #define	ENAHW_RX_CDESC_SRC_VLAN_CNT_MASK	GENMASK(6, 5)
1907 #define	ENAHW_RX_CDESC_L4_PROTO_SHIFT		8
1908 #define	ENAHW_RX_CDESC_L4_PROTO_MASK		GENMASK(12, 8)
1909 #define	ENAHW_RX_CDESC_L3_CSUM_ERR_SHIFT	13
1910 #define	ENAHW_RX_CDESC_L3_CSUM_ERR_MASK		BIT(13)
1911 #define	ENAHW_RX_CDESC_L4_CSUM_ERR_SHIFT	14
1912 #define	ENAHW_RX_CDESC_L4_CSUM_ERR_MASK		BIT(14)
1913 #define	ENAHW_RX_CDESC_IPV4_FRAG_SHIFT		15
1914 #define	ENAHW_RX_CDESC_IPV4_FRAG_MASK		BIT(15)
1915 #define	ENAHW_RX_CDESC_L4_CSUM_CHECKED_SHIFT	16
1916 #define	ENAHW_RX_CDESC_L4_CSUM_CHECKED_MASK	BIT(16)
1917 #define	ENAHW_RX_CDESC_PHASE_SHIFT		24
1918 #define	ENAHW_RX_CDESC_PHASE_MASK		BIT(24)
1919 #define	ENAHW_RX_CDESC_L3_CSUM2_SHIFT		25
1920 #define	ENAHW_RX_CDESC_L3_CSUM2_MASK		BIT(25)
1921 #define	ENAHW_RX_CDESC_FIRST_SHIFT		26
1922 #define	ENAHW_RX_CDESC_FIRST_MASK		BIT(26)
1923 #define	ENAHW_RX_CDESC_LAST_SHIFT		27
1924 #define	ENAHW_RX_CDESC_LAST_MASK		BIT(27)
1925 #define	ENAHW_RX_CDESC_BUFFER_SHIFT		30
1926 #define	ENAHW_RX_CDESC_BUFFER_MASK		BIT(30)
1927 
1928 #define	ENAHW_RX_CDESC_L3_PROTO(desc)				\
1929 	((desc)->erc_status & ENAHW_RX_CDESC_L3_PROTO_MASK)
1930 
1931 #define	ENAHW_RX_CDESC_L3_CSUM_ERR(desc)				\
1932 	((((desc)->erc_status & ENAHW_RX_CDESC_L3_CSUM_ERR_MASK) >>	\
1933 	    ENAHW_RX_CDESC_L3_CSUM_ERR_SHIFT) != 0)
1934 
1935 #define	ENAHW_RX_CDESC_L4_PROTO(desc)				\
1936 	(((desc)->erc_status & ENAHW_RX_CDESC_L4_PROTO_MASK) >>	\
1937 	    ENAHW_RX_CDESC_L4_PROTO_SHIFT)
1938 
1939 #define	ENAHW_RX_CDESC_L4_CSUM_CHECKED(desc)				\
1940 	((((desc)->erc_status & ENAHW_RX_CDESC_L4_CSUM_CHECKED_MASK) >>	\
1941 	    ENAHW_RX_CDESC_L4_CSUM_CHECKED_SHIFT) != 0)
1942 
1943 #define	ENAHW_RX_CDESC_L4_CSUM_ERR(desc)				\
1944 	((((desc)->erc_status & ENAHW_RX_CDESC_L4_CSUM_ERR_MASK) >>	\
1945 	    ENAHW_RX_CDESC_L4_CSUM_ERR_SHIFT) != 0)
1946 
1947 #define	ENAHW_RX_CDESC_PHASE(desc)			 \
1948 	(((desc)->erc_status & ENAHW_RX_CDESC_PHASE_MASK) >> \
1949 	    ENAHW_RX_CDESC_PHASE_SHIFT)
1950 
1951 #define	ENAHW_RX_CDESC_FIRST(desc)			 \
1952 	((((desc)->erc_status & ENAHW_RX_CDESC_FIRST_MASK) >> \
1953 	    ENAHW_RX_CDESC_FIRST_SHIFT) == 1)
1954 
1955 #define	ENAHW_RX_CDESC_LAST(desc)			 \
1956 	((((desc)->erc_status & ENAHW_RX_CDESC_LAST_MASK) >> \
1957 	    ENAHW_RX_CDESC_LAST_SHIFT) == 1)
1958 
1959 /*
1960  * Controls for the interrupt register mapped to each Rx/Tx CQ.
1961  */
1962 #define	ENAHW_REG_INTR_RX_DELAY_MASK	GENMASK(14, 0)
1963 #define	ENAHW_REG_INTR_TX_DELAY_SHIFT	15
1964 #define	ENAHW_REG_INTR_TX_DELAY_MASK	GENMASK(29, 15)
1965 #define	ENAHW_REG_INTR_UNMASK_SHIFT	30
1966 #define	ENAHW_REG_INTR_UNMASK_MASK	BIT(30)
1967 
1968 #define	ENAHW_REG_INTR_UNMASK(val)		\
1969 	((val) |= ENAHW_REG_INTR_UNMASK_MASK)
1970 
1971 #define	ENAHW_REG_INTR_MASK(val)		\
1972 	((val) &= ~ENAHW_REG_INTR_UNMASK_MASK)
1973 
1974 #endif	/* _ENA_HW_H */
1975