xref: /titanic_50/usr/src/uts/sun4v/sys/vsw_ldc.h (revision c242ec1b4cd260e90178d81575297bb3b3648766)
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 /*
23  * Copyright 2009 Sun Microsystems, Inc.  All rights reserved.
24  * Use is subject to license terms.
25  */
26 
27 /*
28  * This header file contains the basic data structures which the
29  * virtual switch (vsw) uses to communicate with vnet clients.
30  *
31  * The virtual switch reads the machine description (MD) to
32  * determine how many port_t structures to create (each port_t
33  * can support communications to a single network device). The
34  * port_t's are maintained in a linked list.
35  *
36  * Each port in turn contains a number of logical domain channels
37  * (ldc's) which are inter domain communications channels which
38  * are used for passing small messages between the domains. Their
39  * may be an unlimited number of channels associated with each port,
40  * though most devices only use a single channel.
41  *
42  * The ldc is a bi-directional channel, which is divided up into
43  * two directional 'lanes', one outbound from the switch to the
44  * virtual network device, the other inbound to the switch.
45  * Depending on the type of device each lane may have seperate
46  * communication paramaters (such as mtu etc).
47  *
48  * For those network clients which use descriptor rings the
49  * rings are associated with the appropriate lane. I.e. rings
50  * which the switch exports are associated with the outbound lanes
51  * while those which the network clients are exporting to the switch
52  * are associated with the inbound lane.
53  *
54  * In diagram form the data structures look as follows:
55  *
56  * vsw instance
57  *     |
58  *     +----->port_t----->port_t----->port_t----->
59  *		|
60  *		+--->ldc_t--->ldc_t--->ldc_t--->
61  *		       |
62  *		       +--->lane_t (inbound)
63  *		       |       |
64  *		       |       +--->dring--->dring--->
65  *		       |
66  *		       +--->lane_t (outbound)
67  *			       |
68  *			       +--->dring--->dring--->
69  *
70  */
71 
72 #ifndef	_VSW_LDC_H
73 #define	_VSW_LDC_H
74 
75 #ifdef	__cplusplus
76 extern "C" {
77 #endif
78 
79 /*
80  * Default message type.
81  */
82 typedef struct def_msg {
83 	uint64_t	data[8];
84 } def_msg_t;
85 
86 /*
87  * Currently only support one major/minor pair.
88  */
89 #define	VSW_NUM_VER	1
90 
91 typedef struct ver_sup {
92 	uint16_t	ver_major;	/* major version number */
93 	uint16_t	ver_minor;	/* minor version number */
94 } ver_sup_t;
95 
96 /*
97  * Lane states.
98  */
99 #define	VSW_LANE_INACTIV	0x0	/* No params set for lane */
100 
101 #define	VSW_VER_INFO_SENT	0x1	/* Version # sent to peer */
102 #define	VSW_VER_INFO_RECV	0x2	/* Version # recv from peer */
103 #define	VSW_VER_ACK_RECV	0x4
104 #define	VSW_VER_ACK_SENT	0x8
105 #define	VSW_VER_NACK_RECV	0x10
106 #define	VSW_VER_NACK_SENT	0x20
107 
108 #define	VSW_ATTR_INFO_SENT	0x40	/* Attributes sent to peer */
109 #define	VSW_ATTR_INFO_RECV	0x80	/* Peer attributes received */
110 #define	VSW_ATTR_ACK_SENT	0x100
111 #define	VSW_ATTR_ACK_RECV	0x200
112 #define	VSW_ATTR_NACK_SENT	0x400
113 #define	VSW_ATTR_NACK_RECV	0x800
114 
115 #define	VSW_DRING_INFO_SENT	0x1000	/* Dring info sent to peer */
116 #define	VSW_DRING_INFO_RECV	0x2000	/* Dring info received */
117 #define	VSW_DRING_ACK_SENT	0x4000
118 #define	VSW_DRING_ACK_RECV	0x8000
119 #define	VSW_DRING_NACK_SENT	0x10000
120 #define	VSW_DRING_NACK_RECV	0x20000
121 
122 #define	VSW_RDX_INFO_SENT	0x40000	/* RDX sent to peer */
123 #define	VSW_RDX_INFO_RECV	0x80000	/* RDX received from peer */
124 #define	VSW_RDX_ACK_SENT	0x100000
125 #define	VSW_RDX_ACK_RECV	0x200000
126 #define	VSW_RDX_NACK_SENT	0x400000
127 #define	VSW_RDX_NACK_RECV	0x800000
128 
129 #define	VSW_MCST_INFO_SENT	0x1000000
130 #define	VSW_MCST_INFO_RECV	0x2000000
131 #define	VSW_MCST_ACK_SENT	0x4000000
132 #define	VSW_MCST_ACK_RECV	0x8000000
133 #define	VSW_MCST_NACK_SENT	0x10000000
134 #define	VSW_MCST_NACK_RECV	0x20000000
135 
136 #define	VSW_LANE_ACTIVE		0x40000000	/* Lane open to xmit data */
137 
138 /* Handshake milestones */
139 #define	VSW_MILESTONE0		0x1	/* ver info exchanged */
140 #define	VSW_MILESTONE1		0x2	/* attribute exchanged */
141 #define	VSW_MILESTONE2		0x4	/* dring info exchanged */
142 #define	VSW_MILESTONE3		0x8	/* rdx exchanged */
143 #define	VSW_MILESTONE4		0x10	/* handshake complete */
144 
145 /*
146  * Lane direction (relative to ourselves).
147  */
148 #define	INBOUND			0x1
149 #define	OUTBOUND		0x2
150 
151 /* Peer session id received */
152 #define	VSW_PEER_SESSION	0x1
153 
154 /*
155  * Maximum number of consecutive reads of data from channel
156  */
157 #define	VSW_MAX_CHAN_READ	50
158 
159 /*
160  * Currently only support one ldc per port.
161  */
162 #define	VSW_PORT_MAX_LDCS	1	/* max # of ldcs per port */
163 
164 /*
165  * Used for port add/deletion.
166  */
167 #define	VSW_PORT_UPDATED	0x1
168 
169 #define	LDC_TX_SUCCESS		0	/* ldc transmit success */
170 #define	LDC_TX_FAILURE		1	/* ldc transmit failure */
171 #define	LDC_TX_NORESOURCES	2	/* out of descriptors */
172 
173 /*
174  * Descriptor ring info
175  *
176  * Each descriptor element has a pre-allocated data buffer
177  * associated with it, into which data being transmitted is
178  * copied. By pre-allocating we speed up the copying process.
179  * The buffer is re-used once the peer has indicated that it is
180  * finished with the descriptor.
181  */
182 #define	VSW_RING_EL_DATA_SZ	2048	/* Size of data section (bytes) */
183 #define	VSW_PRIV_SIZE	sizeof (vnet_private_desc_t)
184 #define	VSW_PUB_SIZE	sizeof (vnet_public_desc_t)
185 
186 #define	VSW_MAX_COOKIES		((ETHERMTU >> MMU_PAGESHIFT) + 2)
187 
188 /*
189  * LDC pkt tranfer MTU
190  */
191 #define	VSW_LDC_MTU	sizeof (def_msg_t)
192 
193 /*
194  * Size of the mblk in each mblk pool.
195  */
196 #define	VSW_MBLK_SZ_128		128
197 #define	VSW_MBLK_SZ_256		256
198 #define	VSW_MBLK_SZ_2048	2048
199 
200 /*
201  * Number of mblks in each mblk pool.
202  */
203 #define	VSW_NUM_MBLKS	1024
204 
205 /*
206  * Private descriptor
207  */
208 typedef struct vsw_private_desc {
209 	/*
210 	 * Below lock must be held when accessing the state of
211 	 * a descriptor on either the private or public sections
212 	 * of the ring.
213 	 */
214 	kmutex_t		dstate_lock;
215 	uint64_t		dstate;
216 	vnet_public_desc_t	*descp;
217 	ldc_mem_handle_t	memhandle;
218 	void			*datap;
219 	uint64_t		datalen;
220 	uint64_t		ncookies;
221 	ldc_mem_cookie_t	memcookie[VSW_MAX_COOKIES];
222 	int			bound;
223 } vsw_private_desc_t;
224 
225 /*
226  * Descriptor ring structure
227  */
228 typedef struct dring_info {
229 	struct	dring_info	*next;	/* next ring in chain */
230 	kmutex_t		dlock;
231 	uint32_t		num_descriptors;
232 	uint32_t		descriptor_size;
233 	uint32_t		options;
234 	uint32_t		ncookies;
235 	ldc_mem_cookie_t	cookie[1];
236 
237 	ldc_dring_handle_t	handle;
238 	uint64_t		ident;	/* identifier sent to peer */
239 	uint64_t		end_idx;	/* last idx processed */
240 	int64_t			last_ack_recv;
241 
242 	kmutex_t		restart_lock;
243 	boolean_t		restart_reqd;	/* send restart msg */
244 
245 	/*
246 	 * base address of private and public portions of the
247 	 * ring (where appropriate), and data block.
248 	 */
249 	void			*pub_addr;	/* base of public section */
250 	void			*priv_addr;	/* base of private section */
251 	void			*data_addr;	/* base of data section */
252 	size_t			data_sz;	/* size of data section */
253 	size_t			desc_data_sz;	/* size of descr data blk */
254 	uint8_t			dring_mtype;	/* dring mem map type */
255 } dring_info_t;
256 
257 /*
258  * Each ldc connection is comprised of two lanes, incoming
259  * from a peer, and outgoing to that peer. Each lane shares
260  * common ldc parameters and also has private lane-specific
261  * parameters.
262  */
263 typedef struct lane {
264 	uint64_t	lstate;		/* Lane state */
265 	uint16_t	ver_major;	/* Version major number */
266 	uint16_t	ver_minor;	/* Version minor number */
267 	uint64_t	seq_num;	/* Sequence number */
268 	uint64_t	mtu;		/* ETHERMTU */
269 	uint64_t	addr;		/* Unique physical address */
270 	uint8_t		addr_type;	/* Only MAC address at moment */
271 	uint8_t		xfer_mode;	/* Dring or Pkt based */
272 	uint8_t		ack_freq;	/* Only non zero for Pkt based xfer */
273 	krwlock_t	dlistrw;	/* Lock for dring list */
274 	dring_info_t	*dringp;	/* List of drings for this lane */
275 } lane_t;
276 
277 /* channel drain states */
278 #define	VSW_LDC_INIT		0x1	/* Initial non-drain state */
279 #define	VSW_LDC_DRAINING	0x2	/* Channel draining */
280 
281 /*
282  * vnet-protocol-version dependent function prototypes.
283  */
284 typedef int	(*vsw_ldctx_t) (void *, mblk_t *, mblk_t *, uint32_t);
285 typedef void	(*vsw_ldcrx_pktdata_t) (void *, void *, uint32_t);
286 
287 /* ldc information associated with a vsw-port */
288 typedef struct vsw_ldc {
289 	struct vsw_ldc		*ldc_next;	/* next ldc in the list */
290 	struct vsw_port		*ldc_port;	/* associated port */
291 	struct vsw		*ldc_vswp;	/* associated vsw */
292 	kmutex_t		ldc_cblock;	/* sync callback processing */
293 	kmutex_t		ldc_txlock;	/* sync transmits */
294 	kmutex_t		ldc_rxlock;	/* sync rx */
295 	uint64_t		ldc_id;		/* channel number */
296 	ldc_handle_t		ldc_handle;	/* channel handle */
297 	kmutex_t		drain_cv_lock;
298 	kcondvar_t		drain_cv;	/* channel draining */
299 	int			drain_state;
300 	uint32_t		hphase;		/* handshake phase */
301 	int			hcnt;		/* # handshake attempts */
302 	kmutex_t		status_lock;
303 	ldc_status_t		ldc_status;	/* channel status */
304 	uint8_t			reset_active;	/* reset flag */
305 	uint64_t		local_session;	/* Our session id */
306 	uint64_t		peer_session;	/* Our peers session id */
307 	uint8_t			session_status;	/* Session recv'd, sent */
308 	uint32_t		hss_id;		/* Handshake session id */
309 	uint64_t		next_ident;	/* Next dring ident # to use */
310 	lane_t			lane_in;	/* Inbound lane */
311 	lane_t			lane_out;	/* Outbound lane */
312 	uint8_t			dev_class;	/* Peer device class */
313 	vio_multi_pool_t	vmp;		/* Receive mblk pools */
314 	uint32_t		max_rxpool_size; /* max size of rxpool in use */
315 	uint64_t		*ldcmsg;	/* msg buffer for ldc_read() */
316 	uint64_t		msglen;		/* size of ldcmsg */
317 
318 	/* tx thread fields */
319 	kthread_t		*tx_thread;	/* tx thread */
320 	uint32_t		tx_thr_flags;	/* tx thread flags */
321 	kmutex_t		tx_thr_lock;	/* lock for tx thread */
322 	kcondvar_t		tx_thr_cv;	/* cond.var for tx thread */
323 	mblk_t			*tx_mhead;	/* tx mblks head */
324 	mblk_t			*tx_mtail;	/* tx mblks tail */
325 	uint32_t		tx_cnt;		/* # of pkts queued for tx */
326 
327 	/* receive thread fields */
328 	kthread_t		*rx_thread;	/* receive thread */
329 	uint32_t		rx_thr_flags;	/* receive thread flags */
330 	kmutex_t		rx_thr_lock;	/* lock for receive thread */
331 	kcondvar_t		rx_thr_cv;	/* cond.var for recv thread */
332 
333 	vsw_ldctx_t		tx;		/* transmit function */
334 	vsw_ldcrx_pktdata_t	rx_pktdata;	/* process rx raw data msg */
335 
336 	/* channel statistics */
337 	vgen_stats_t		ldc_stats;	/* channel statistics */
338 	kstat_t			*ksp;		/* channel kstats */
339 } vsw_ldc_t;
340 
341 /* worker thread flags */
342 #define	VSW_WTHR_DATARCVD 	0x01	/* data received */
343 #define	VSW_WTHR_STOP 		0x02	/* stop worker thread request */
344 
345 /* list of ldcs per port */
346 typedef struct vsw_ldc_list {
347 	vsw_ldc_t	*head;		/* head of the list */
348 	krwlock_t	lockrw;		/* sync access(rw) to the list */
349 } vsw_ldc_list_t;
350 
351 /* multicast addresses port is interested in */
352 typedef struct mcst_addr {
353 	struct mcst_addr	*nextp;
354 	struct ether_addr	mca;	/* multicast address */
355 	uint64_t		addr;	/* mcast addr converted to hash key */
356 	boolean_t		mac_added; /* added into physical device */
357 } mcst_addr_t;
358 
359 /* Port detach states */
360 #define	VSW_PORT_INIT		0x1	/* Initial non-detach state */
361 #define	VSW_PORT_DETACHING	0x2	/* In process of being detached */
362 #define	VSW_PORT_DETACHABLE	0x4	/* Safe to detach */
363 
364 /* port information associated with a vsw */
365 typedef struct vsw_port {
366 	int			p_instance;	/* port instance */
367 	struct vsw_port		*p_next;	/* next port in the list */
368 	struct vsw		*p_vswp;	/* associated vsw */
369 	int			num_ldcs;	/* # of ldcs in the port */
370 	uint64_t		*ldc_ids;	/* ldc ids */
371 	vsw_ldc_list_t		p_ldclist;	/* list of ldcs for this port */
372 
373 	kmutex_t		tx_lock;	/* transmit lock */
374 	int			(*transmit)(vsw_ldc_t *, mblk_t *);
375 
376 	int			state;		/* port state */
377 	kmutex_t		state_lock;
378 	kcondvar_t		state_cv;
379 
380 	krwlock_t		maccl_rwlock;	/* protect fields below */
381 	mac_client_handle_t	p_mch;		/* mac client handle */
382 	mac_unicast_handle_t	p_muh;		/* mac unicast handle */
383 
384 	kmutex_t		mca_lock;	/* multicast lock */
385 	mcst_addr_t		*mcap;		/* list of multicast addrs */
386 
387 	boolean_t		addr_set;	/* Addr set where */
388 
389 	/*
390 	 * mac address of the port & connected device
391 	 */
392 	struct ether_addr	p_macaddr;
393 	uint16_t		pvid;	/* port vlan id (untagged) */
394 	struct vsw_vlanid	*vids;	/* vlan ids (tagged) */
395 	uint16_t		nvids;	/* # of vids */
396 	mod_hash_t		*vlan_hashp;	/* vlan hash table */
397 	uint32_t		vlan_nchains;	/* # of vlan hash chains */
398 
399 	/* HybridIO related info */
400 	uint32_t		p_hio_enabled;	/* Hybrid mode enabled? */
401 	uint32_t		p_hio_capable;	/* Port capable of HIO */
402 } vsw_port_t;
403 
404 /* list of ports per vsw */
405 typedef struct vsw_port_list {
406 	vsw_port_t	*head;		/* head of the list */
407 	krwlock_t	lockrw;		/* sync access(rw) to the list */
408 	int		num_ports;	/* number of ports in the list */
409 } vsw_port_list_t;
410 
411 /*
412  * Taskq control message
413  */
414 typedef struct vsw_ctrl_task {
415 	vsw_ldc_t	*ldcp;
416 	def_msg_t	pktp;
417 	uint32_t	hss_id;
418 } vsw_ctrl_task_t;
419 
420 /*
421  * State of connection to peer. Some of these states
422  * can be mapped to LDC events as follows:
423  *
424  * VSW_CONN_RESET -> LDC_RESET_EVT
425  * VSW_CONN_UP    -> LDC_UP_EVT
426  */
427 #define	VSW_CONN_UP		0x1	/* Connection come up */
428 #define	VSW_CONN_RESET		0x2	/* Connection reset */
429 #define	VSW_CONN_RESTART	0x4	/* Restarting handshake on connection */
430 
431 typedef struct vsw_conn_evt {
432 	uint16_t	evt;		/* Connection event */
433 	vsw_ldc_t	*ldcp;
434 } vsw_conn_evt_t;
435 
436 /*
437  * Ethernet broadcast address definition.
438  */
439 static	struct	ether_addr	etherbroadcastaddr = {
440 	0xff, 0xff, 0xff, 0xff, 0xff, 0xff
441 };
442 
443 #define	IS_BROADCAST(ehp) \
444 	(bcmp(&ehp->ether_dhost, &etherbroadcastaddr, ETHERADDRL) == 0)
445 #define	IS_MULTICAST(ehp) \
446 	((ehp->ether_dhost.ether_addr_octet[0] & 01) == 1)
447 
448 #define	READ_ENTER(x)	rw_enter(x, RW_READER)
449 #define	WRITE_ENTER(x)	rw_enter(x, RW_WRITER)
450 #define	RW_EXIT(x)	rw_exit(x)
451 
452 #define	VSW_PORT_REFHOLD(portp)	atomic_inc_32(&((portp)->ref_cnt))
453 #define	VSW_PORT_REFRELE(portp)	atomic_dec_32(&((portp)->ref_cnt))
454 
455 #ifdef	__cplusplus
456 }
457 #endif
458 
459 #endif	/* _VSW_LDC_H */
460