1 // SPDX-License-Identifier: GPL-2.0+
2 /*
3 * Copyright 2015-2017 Google, Inc
4 *
5 * USB Power Delivery protocol stack.
6 */
7
8 #include <linux/completion.h>
9 #include <linux/debugfs.h>
10 #include <linux/device.h>
11 #include <linux/hrtimer.h>
12 #include <linux/jiffies.h>
13 #include <linux/kernel.h>
14 #include <linux/kthread.h>
15 #include <linux/module.h>
16 #include <linux/mutex.h>
17 #include <linux/power_supply.h>
18 #include <linux/proc_fs.h>
19 #include <linux/property.h>
20 #include <linux/sched/clock.h>
21 #include <linux/seq_file.h>
22 #include <linux/slab.h>
23 #include <linux/spinlock.h>
24 #include <linux/usb.h>
25 #include <linux/usb/pd.h>
26 #include <linux/usb/pd_ado.h>
27 #include <linux/usb/pd_bdo.h>
28 #include <linux/usb/pd_ext_sdb.h>
29 #include <linux/usb/pd_vdo.h>
30 #include <linux/usb/role.h>
31 #include <linux/usb/tcpm.h>
32 #include <linux/usb/typec_altmode.h>
33
34 #include <uapi/linux/sched/types.h>
35
36 #define FOREACH_STATE(S) \
37 S(INVALID_STATE), \
38 S(TOGGLING), \
39 S(CHECK_CONTAMINANT), \
40 S(SRC_UNATTACHED), \
41 S(SRC_ATTACH_WAIT), \
42 S(SRC_ATTACHED), \
43 S(SRC_STARTUP), \
44 S(SRC_SEND_CAPABILITIES), \
45 S(SRC_SEND_CAPABILITIES_TIMEOUT), \
46 S(SRC_NEGOTIATE_CAPABILITIES), \
47 S(SRC_TRANSITION_SUPPLY), \
48 S(SRC_READY), \
49 S(SRC_WAIT_NEW_CAPABILITIES), \
50 \
51 S(SNK_UNATTACHED), \
52 S(SNK_ATTACH_WAIT), \
53 S(SNK_DEBOUNCED), \
54 S(SNK_ATTACHED), \
55 S(SNK_STARTUP), \
56 S(SNK_DISCOVERY), \
57 S(SNK_DISCOVERY_DEBOUNCE), \
58 S(SNK_DISCOVERY_DEBOUNCE_DONE), \
59 S(SNK_WAIT_CAPABILITIES), \
60 S(SNK_WAIT_CAPABILITIES_TIMEOUT), \
61 S(SNK_NEGOTIATE_CAPABILITIES), \
62 S(SNK_NEGOTIATE_PPS_CAPABILITIES), \
63 S(SNK_TRANSITION_SINK), \
64 S(SNK_TRANSITION_SINK_VBUS), \
65 S(SNK_READY), \
66 \
67 S(ACC_UNATTACHED), \
68 S(DEBUG_ACC_ATTACHED), \
69 S(AUDIO_ACC_ATTACHED), \
70 S(AUDIO_ACC_DEBOUNCE), \
71 \
72 S(HARD_RESET_SEND), \
73 S(HARD_RESET_START), \
74 S(SRC_HARD_RESET_VBUS_OFF), \
75 S(SRC_HARD_RESET_VBUS_ON), \
76 S(SNK_HARD_RESET_SINK_OFF), \
77 S(SNK_HARD_RESET_WAIT_VBUS), \
78 S(SNK_HARD_RESET_SINK_ON), \
79 \
80 S(SOFT_RESET), \
81 S(SRC_SOFT_RESET_WAIT_SNK_TX), \
82 S(SNK_SOFT_RESET), \
83 S(SOFT_RESET_SEND), \
84 \
85 S(DR_SWAP_ACCEPT), \
86 S(DR_SWAP_SEND), \
87 S(DR_SWAP_SEND_TIMEOUT), \
88 S(DR_SWAP_CANCEL), \
89 S(DR_SWAP_CHANGE_DR), \
90 \
91 S(PR_SWAP_ACCEPT), \
92 S(PR_SWAP_SEND), \
93 S(PR_SWAP_SEND_TIMEOUT), \
94 S(PR_SWAP_CANCEL), \
95 S(PR_SWAP_START), \
96 S(PR_SWAP_SRC_SNK_TRANSITION_OFF), \
97 S(PR_SWAP_SRC_SNK_SOURCE_OFF), \
98 S(PR_SWAP_SRC_SNK_SOURCE_OFF_CC_DEBOUNCED), \
99 S(PR_SWAP_SRC_SNK_SINK_ON), \
100 S(PR_SWAP_SNK_SRC_SINK_OFF), \
101 S(PR_SWAP_SNK_SRC_SOURCE_ON), \
102 S(PR_SWAP_SNK_SRC_SOURCE_ON_VBUS_RAMPED_UP), \
103 \
104 S(VCONN_SWAP_ACCEPT), \
105 S(VCONN_SWAP_SEND), \
106 S(VCONN_SWAP_SEND_TIMEOUT), \
107 S(VCONN_SWAP_CANCEL), \
108 S(VCONN_SWAP_START), \
109 S(VCONN_SWAP_WAIT_FOR_VCONN), \
110 S(VCONN_SWAP_TURN_ON_VCONN), \
111 S(VCONN_SWAP_TURN_OFF_VCONN), \
112 S(VCONN_SWAP_SEND_SOFT_RESET), \
113 \
114 S(FR_SWAP_SEND), \
115 S(FR_SWAP_SEND_TIMEOUT), \
116 S(FR_SWAP_SNK_SRC_TRANSITION_TO_OFF), \
117 S(FR_SWAP_SNK_SRC_NEW_SINK_READY), \
118 S(FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED), \
119 S(FR_SWAP_CANCEL), \
120 \
121 S(SNK_TRY), \
122 S(SNK_TRY_WAIT), \
123 S(SNK_TRY_WAIT_DEBOUNCE), \
124 S(SNK_TRY_WAIT_DEBOUNCE_CHECK_VBUS), \
125 S(SRC_TRYWAIT), \
126 S(SRC_TRYWAIT_DEBOUNCE), \
127 S(SRC_TRYWAIT_UNATTACHED), \
128 \
129 S(SRC_TRY), \
130 S(SRC_TRY_WAIT), \
131 S(SRC_TRY_DEBOUNCE), \
132 S(SNK_TRYWAIT), \
133 S(SNK_TRYWAIT_DEBOUNCE), \
134 S(SNK_TRYWAIT_VBUS), \
135 S(BIST_RX), \
136 \
137 S(GET_STATUS_SEND), \
138 S(GET_STATUS_SEND_TIMEOUT), \
139 S(GET_PPS_STATUS_SEND), \
140 S(GET_PPS_STATUS_SEND_TIMEOUT), \
141 \
142 S(GET_SINK_CAP), \
143 S(GET_SINK_CAP_TIMEOUT), \
144 \
145 S(ERROR_RECOVERY), \
146 S(PORT_RESET), \
147 S(PORT_RESET_WAIT_OFF), \
148 \
149 S(AMS_START), \
150 S(CHUNK_NOT_SUPP), \
151 \
152 S(SRC_VDM_IDENTITY_REQUEST)
153
154 #define FOREACH_AMS(S) \
155 S(NONE_AMS), \
156 S(POWER_NEGOTIATION), \
157 S(GOTOMIN), \
158 S(SOFT_RESET_AMS), \
159 S(HARD_RESET), \
160 S(CABLE_RESET), \
161 S(GET_SOURCE_CAPABILITIES), \
162 S(GET_SINK_CAPABILITIES), \
163 S(POWER_ROLE_SWAP), \
164 S(FAST_ROLE_SWAP), \
165 S(DATA_ROLE_SWAP), \
166 S(VCONN_SWAP), \
167 S(SOURCE_ALERT), \
168 S(GETTING_SOURCE_EXTENDED_CAPABILITIES),\
169 S(GETTING_SOURCE_SINK_STATUS), \
170 S(GETTING_BATTERY_CAPABILITIES), \
171 S(GETTING_BATTERY_STATUS), \
172 S(GETTING_MANUFACTURER_INFORMATION), \
173 S(SECURITY), \
174 S(FIRMWARE_UPDATE), \
175 S(DISCOVER_IDENTITY), \
176 S(SOURCE_STARTUP_CABLE_PLUG_DISCOVER_IDENTITY), \
177 S(DISCOVER_SVIDS), \
178 S(DISCOVER_MODES), \
179 S(DFP_TO_UFP_ENTER_MODE), \
180 S(DFP_TO_UFP_EXIT_MODE), \
181 S(DFP_TO_CABLE_PLUG_ENTER_MODE), \
182 S(DFP_TO_CABLE_PLUG_EXIT_MODE), \
183 S(ATTENTION), \
184 S(BIST), \
185 S(UNSTRUCTURED_VDMS), \
186 S(STRUCTURED_VDMS), \
187 S(COUNTRY_INFO), \
188 S(COUNTRY_CODES)
189
190 #define GENERATE_ENUM(e) e
191 #define GENERATE_STRING(s) #s
192
193 enum tcpm_state {
194 FOREACH_STATE(GENERATE_ENUM)
195 };
196
197 static const char * const tcpm_states[] = {
198 FOREACH_STATE(GENERATE_STRING)
199 };
200
201 enum tcpm_ams {
202 FOREACH_AMS(GENERATE_ENUM)
203 };
204
205 static const char * const tcpm_ams_str[] = {
206 FOREACH_AMS(GENERATE_STRING)
207 };
208
209 enum vdm_states {
210 VDM_STATE_ERR_BUSY = -3,
211 VDM_STATE_ERR_SEND = -2,
212 VDM_STATE_ERR_TMOUT = -1,
213 VDM_STATE_DONE = 0,
214 /* Anything >0 represents an active state */
215 VDM_STATE_READY = 1,
216 VDM_STATE_BUSY = 2,
217 VDM_STATE_WAIT_RSP_BUSY = 3,
218 VDM_STATE_SEND_MESSAGE = 4,
219 };
220
221 enum pd_msg_request {
222 PD_MSG_NONE = 0,
223 PD_MSG_CTRL_REJECT,
224 PD_MSG_CTRL_WAIT,
225 PD_MSG_CTRL_NOT_SUPP,
226 PD_MSG_DATA_SINK_CAP,
227 PD_MSG_DATA_SOURCE_CAP,
228 };
229
230 enum adev_actions {
231 ADEV_NONE = 0,
232 ADEV_NOTIFY_USB_AND_QUEUE_VDM,
233 ADEV_QUEUE_VDM,
234 ADEV_QUEUE_VDM_SEND_EXIT_MODE_ON_FAIL,
235 ADEV_ATTENTION,
236 };
237
238 /*
239 * Initial current capability of the new source when vSafe5V is applied during PD3.0 Fast Role Swap.
240 * Based on "Table 6-14 Fixed Supply PDO - Sink" of "USB Power Delivery Specification Revision 3.0,
241 * Version 1.2"
242 */
243 enum frs_typec_current {
244 FRS_NOT_SUPPORTED,
245 FRS_DEFAULT_POWER,
246 FRS_5V_1P5A,
247 FRS_5V_3A,
248 };
249
250 /* Events from low level driver */
251
252 #define TCPM_CC_EVENT BIT(0)
253 #define TCPM_VBUS_EVENT BIT(1)
254 #define TCPM_RESET_EVENT BIT(2)
255 #define TCPM_FRS_EVENT BIT(3)
256 #define TCPM_SOURCING_VBUS BIT(4)
257 #define TCPM_PORT_CLEAN BIT(5)
258 #define TCPM_PORT_ERROR BIT(6)
259
260 #define LOG_BUFFER_ENTRIES 1024
261 #define LOG_BUFFER_ENTRY_SIZE 128
262
263 /* Alternate mode support */
264
265 #define SVID_DISCOVERY_MAX 16
266 #define ALTMODE_DISCOVERY_MAX (SVID_DISCOVERY_MAX * MODE_DISCOVERY_MAX)
267
268 #define GET_SINK_CAP_RETRY_MS 100
269 #define SEND_DISCOVER_RETRY_MS 100
270
271 struct pd_mode_data {
272 int svid_index; /* current SVID index */
273 int nsvids;
274 u16 svids[SVID_DISCOVERY_MAX];
275 int altmodes; /* number of alternate modes */
276 struct typec_altmode_desc altmode_desc[ALTMODE_DISCOVERY_MAX];
277 };
278
279 /*
280 * @min_volt: Actual min voltage at the local port
281 * @req_min_volt: Requested min voltage to the port partner
282 * @max_volt: Actual max voltage at the local port
283 * @req_max_volt: Requested max voltage to the port partner
284 * @max_curr: Actual max current at the local port
285 * @req_max_curr: Requested max current of the port partner
286 * @req_out_volt: Requested output voltage to the port partner
287 * @req_op_curr: Requested operating current to the port partner
288 * @supported: Parter has at least one APDO hence supports PPS
289 * @active: PPS mode is active
290 */
291 struct pd_pps_data {
292 u32 min_volt;
293 u32 req_min_volt;
294 u32 max_volt;
295 u32 req_max_volt;
296 u32 max_curr;
297 u32 req_max_curr;
298 u32 req_out_volt;
299 u32 req_op_curr;
300 bool supported;
301 bool active;
302 };
303
304 struct pd_data {
305 struct usb_power_delivery *pd;
306 struct usb_power_delivery_capabilities *source_cap;
307 struct usb_power_delivery_capabilities_desc source_desc;
308 struct usb_power_delivery_capabilities *sink_cap;
309 struct usb_power_delivery_capabilities_desc sink_desc;
310 unsigned int operating_snk_mw;
311 };
312
313 struct tcpm_port {
314 struct device *dev;
315
316 struct mutex lock; /* tcpm state machine lock */
317 struct kthread_worker *wq;
318
319 struct typec_capability typec_caps;
320 struct typec_port *typec_port;
321
322 struct tcpc_dev *tcpc;
323 struct usb_role_switch *role_sw;
324
325 enum typec_role vconn_role;
326 enum typec_role pwr_role;
327 enum typec_data_role data_role;
328 enum typec_pwr_opmode pwr_opmode;
329
330 struct usb_pd_identity partner_ident;
331 struct typec_partner_desc partner_desc;
332 struct typec_partner *partner;
333
334 struct usb_pd_identity cable_ident;
335 struct typec_cable_desc cable_desc;
336 struct typec_cable *cable;
337 struct typec_plug_desc plug_prime_desc;
338 struct typec_plug *plug_prime;
339
340 enum typec_cc_status cc_req;
341 enum typec_cc_status src_rp; /* work only if pd_supported == false */
342
343 enum typec_cc_status cc1;
344 enum typec_cc_status cc2;
345 enum typec_cc_polarity polarity;
346
347 bool attached;
348 bool connected;
349 bool registered;
350 bool pd_supported;
351 enum typec_port_type port_type;
352
353 /*
354 * Set to true when vbus is greater than VSAFE5V min.
355 * Set to false when vbus falls below vSinkDisconnect max threshold.
356 */
357 bool vbus_present;
358
359 /*
360 * Set to true when vbus is less than VSAFE0V max.
361 * Set to false when vbus is greater than VSAFE0V max.
362 */
363 bool vbus_vsafe0v;
364
365 bool vbus_never_low;
366 bool vbus_source;
367 bool vbus_charge;
368
369 /* Set to true when Discover_Identity Command is expected to be sent in Ready states. */
370 bool send_discover;
371 bool op_vsafe5v;
372
373 int try_role;
374 int try_snk_count;
375 int try_src_count;
376
377 enum pd_msg_request queued_message;
378
379 enum tcpm_state enter_state;
380 enum tcpm_state prev_state;
381 enum tcpm_state state;
382 enum tcpm_state delayed_state;
383 ktime_t delayed_runtime;
384 unsigned long delay_ms;
385
386 spinlock_t pd_event_lock;
387 u32 pd_events;
388
389 struct kthread_work event_work;
390 struct hrtimer state_machine_timer;
391 struct kthread_work state_machine;
392 struct hrtimer vdm_state_machine_timer;
393 struct kthread_work vdm_state_machine;
394 struct hrtimer enable_frs_timer;
395 struct kthread_work enable_frs;
396 struct hrtimer send_discover_timer;
397 struct kthread_work send_discover_work;
398 bool state_machine_running;
399 /* Set to true when VDM State Machine has following actions. */
400 bool vdm_sm_running;
401
402 struct completion tx_complete;
403 enum tcpm_transmit_status tx_status;
404
405 struct mutex swap_lock; /* swap command lock */
406 bool swap_pending;
407 bool non_pd_role_swap;
408 struct completion swap_complete;
409 int swap_status;
410
411 unsigned int negotiated_rev;
412 unsigned int message_id;
413 unsigned int caps_count;
414 unsigned int hard_reset_count;
415 bool pd_capable;
416 bool explicit_contract;
417 unsigned int rx_msgid;
418
419 /* USB PD objects */
420 struct usb_power_delivery **pds;
421 struct pd_data **pd_list;
422 struct usb_power_delivery_capabilities *port_source_caps;
423 struct usb_power_delivery_capabilities *port_sink_caps;
424 struct usb_power_delivery *partner_pd;
425 struct usb_power_delivery_capabilities *partner_source_caps;
426 struct usb_power_delivery_capabilities *partner_sink_caps;
427 struct usb_power_delivery *selected_pd;
428
429 /* Partner capabilities/requests */
430 u32 sink_request;
431 u32 source_caps[PDO_MAX_OBJECTS];
432 unsigned int nr_source_caps;
433 u32 sink_caps[PDO_MAX_OBJECTS];
434 unsigned int nr_sink_caps;
435
436 /* Local capabilities */
437 unsigned int pd_count;
438 u32 src_pdo[PDO_MAX_OBJECTS];
439 unsigned int nr_src_pdo;
440 u32 snk_pdo[PDO_MAX_OBJECTS];
441 unsigned int nr_snk_pdo;
442 u32 snk_vdo_v1[VDO_MAX_OBJECTS];
443 unsigned int nr_snk_vdo_v1;
444 u32 snk_vdo[VDO_MAX_OBJECTS];
445 unsigned int nr_snk_vdo;
446
447 unsigned int operating_snk_mw;
448 bool update_sink_caps;
449
450 /* Requested current / voltage to the port partner */
451 u32 req_current_limit;
452 u32 req_supply_voltage;
453 /* Actual current / voltage limit of the local port */
454 u32 current_limit;
455 u32 supply_voltage;
456
457 /* Used to export TA voltage and current */
458 struct power_supply *psy;
459 struct power_supply_desc psy_desc;
460 enum power_supply_usb_type usb_type;
461
462 u32 bist_request;
463
464 /* PD state for Vendor Defined Messages */
465 enum vdm_states vdm_state;
466 u32 vdm_retries;
467 /* next Vendor Defined Message to send */
468 u32 vdo_data[VDO_MAX_SIZE];
469 u8 vdo_count;
470 /* VDO to retry if UFP responder replied busy */
471 u32 vdo_retry;
472
473 /* PPS */
474 struct pd_pps_data pps_data;
475 struct completion pps_complete;
476 bool pps_pending;
477 int pps_status;
478
479 /* Alternate mode data */
480 struct pd_mode_data mode_data;
481 struct pd_mode_data mode_data_prime;
482 struct typec_altmode *partner_altmode[ALTMODE_DISCOVERY_MAX];
483 struct typec_altmode *plug_prime_altmode[ALTMODE_DISCOVERY_MAX];
484 struct typec_altmode *port_altmode[ALTMODE_DISCOVERY_MAX];
485
486 /* Deadline in jiffies to exit src_try_wait state */
487 unsigned long max_wait;
488
489 /* port belongs to a self powered device */
490 bool self_powered;
491
492 /* Sink FRS */
493 enum frs_typec_current new_source_frs_current;
494
495 /* Sink caps have been queried */
496 bool sink_cap_done;
497
498 /* Collision Avoidance and Atomic Message Sequence */
499 enum tcpm_state upcoming_state;
500 enum tcpm_ams ams;
501 enum tcpm_ams next_ams;
502 bool in_ams;
503
504 /* Auto vbus discharge status */
505 bool auto_vbus_discharge_enabled;
506
507 /*
508 * When set, port requests PD_P_SNK_STDBY_MW upon entering SNK_DISCOVERY and
509 * the actual current limit after RX of PD_CTRL_PSRDY for PD link,
510 * SNK_READY for non-pd link.
511 */
512 bool slow_charger_loop;
513
514 /*
515 * When true indicates that the lower level drivers indicate potential presence
516 * of contaminant in the connector pins based on the tcpm state machine
517 * transitions.
518 */
519 bool potential_contaminant;
520
521 /* SOP* Related Fields */
522 /*
523 * Flag to determine if SOP' Discover Identity is available. The flag
524 * is set if Discover Identity on SOP' does not immediately follow
525 * Discover Identity on SOP.
526 */
527 bool send_discover_prime;
528 /*
529 * tx_sop_type determines which SOP* a message is being sent on.
530 * For messages that are queued and not sent immediately such as in
531 * tcpm_queue_message or messages that send after state changes,
532 * the tx_sop_type is set accordingly.
533 */
534 enum tcpm_transmit_type tx_sop_type;
535 /*
536 * Prior to discovering the port partner's Specification Revision, the
537 * Vconn source and cable plug will use the lower of their two revisions.
538 *
539 * When the port partner's Specification Revision is discovered, the following
540 * rules are put in place.
541 * 1. If the cable revision (1) is lower than the revision negotiated
542 * between the port and partner (2), the port and partner will communicate
543 * on revision (2), but the port and cable will communicate on revision (1).
544 * 2. If the cable revision (1) is higher than the revision negotiated
545 * between the port and partner (2), the port and partner will communicate
546 * on revision (2), and the port and cable will communicate on revision (2)
547 * as well.
548 */
549 unsigned int negotiated_rev_prime;
550 /*
551 * Each SOP* type must maintain their own tx and rx message IDs
552 */
553 unsigned int message_id_prime;
554 unsigned int rx_msgid_prime;
555 #ifdef CONFIG_DEBUG_FS
556 struct dentry *dentry;
557 struct mutex logbuffer_lock; /* log buffer access lock */
558 int logbuffer_head;
559 int logbuffer_tail;
560 u8 *logbuffer[LOG_BUFFER_ENTRIES];
561 #endif
562 };
563
564 struct pd_rx_event {
565 struct kthread_work work;
566 struct tcpm_port *port;
567 struct pd_message msg;
568 enum tcpm_transmit_type rx_sop_type;
569 };
570
571 static const char * const pd_rev[] = {
572 [PD_REV10] = "rev1",
573 [PD_REV20] = "rev2",
574 [PD_REV30] = "rev3",
575 };
576
577 #define tcpm_cc_is_sink(cc) \
578 ((cc) == TYPEC_CC_RP_DEF || (cc) == TYPEC_CC_RP_1_5 || \
579 (cc) == TYPEC_CC_RP_3_0)
580
581 /* As long as cc is pulled up, we can consider it as sink. */
582 #define tcpm_port_is_sink(port) \
583 (tcpm_cc_is_sink((port)->cc1) || tcpm_cc_is_sink((port)->cc2))
584
585 #define tcpm_cc_is_source(cc) ((cc) == TYPEC_CC_RD)
586 #define tcpm_cc_is_audio(cc) ((cc) == TYPEC_CC_RA)
587 #define tcpm_cc_is_open(cc) ((cc) == TYPEC_CC_OPEN)
588
589 #define tcpm_port_is_source(port) \
590 ((tcpm_cc_is_source((port)->cc1) && \
591 !tcpm_cc_is_source((port)->cc2)) || \
592 (tcpm_cc_is_source((port)->cc2) && \
593 !tcpm_cc_is_source((port)->cc1)))
594
595 #define tcpm_port_is_debug(port) \
596 (tcpm_cc_is_source((port)->cc1) && tcpm_cc_is_source((port)->cc2))
597
598 #define tcpm_port_is_audio(port) \
599 (tcpm_cc_is_audio((port)->cc1) && tcpm_cc_is_audio((port)->cc2))
600
601 #define tcpm_port_is_audio_detached(port) \
602 ((tcpm_cc_is_audio((port)->cc1) && tcpm_cc_is_open((port)->cc2)) || \
603 (tcpm_cc_is_audio((port)->cc2) && tcpm_cc_is_open((port)->cc1)))
604
605 #define tcpm_try_snk(port) \
606 ((port)->try_snk_count == 0 && (port)->try_role == TYPEC_SINK && \
607 (port)->port_type == TYPEC_PORT_DRP)
608
609 #define tcpm_try_src(port) \
610 ((port)->try_src_count == 0 && (port)->try_role == TYPEC_SOURCE && \
611 (port)->port_type == TYPEC_PORT_DRP)
612
613 #define tcpm_data_role_for_source(port) \
614 ((port)->typec_caps.data == TYPEC_PORT_UFP ? \
615 TYPEC_DEVICE : TYPEC_HOST)
616
617 #define tcpm_data_role_for_sink(port) \
618 ((port)->typec_caps.data == TYPEC_PORT_DFP ? \
619 TYPEC_HOST : TYPEC_DEVICE)
620
621 #define tcpm_sink_tx_ok(port) \
622 (tcpm_port_is_sink(port) && \
623 ((port)->cc1 == TYPEC_CC_RP_3_0 || (port)->cc2 == TYPEC_CC_RP_3_0))
624
625 #define tcpm_wait_for_discharge(port) \
626 (((port)->auto_vbus_discharge_enabled && !(port)->vbus_vsafe0v) ? PD_T_SAFE_0V : 0)
627
tcpm_default_state(struct tcpm_port * port)628 static enum tcpm_state tcpm_default_state(struct tcpm_port *port)
629 {
630 if (port->port_type == TYPEC_PORT_DRP) {
631 if (port->try_role == TYPEC_SINK)
632 return SNK_UNATTACHED;
633 else if (port->try_role == TYPEC_SOURCE)
634 return SRC_UNATTACHED;
635 /* Fall through to return SRC_UNATTACHED */
636 } else if (port->port_type == TYPEC_PORT_SNK) {
637 return SNK_UNATTACHED;
638 }
639 return SRC_UNATTACHED;
640 }
641
tcpm_port_is_disconnected(struct tcpm_port * port)642 static bool tcpm_port_is_disconnected(struct tcpm_port *port)
643 {
644 return (!port->attached && port->cc1 == TYPEC_CC_OPEN &&
645 port->cc2 == TYPEC_CC_OPEN) ||
646 (port->attached && ((port->polarity == TYPEC_POLARITY_CC1 &&
647 port->cc1 == TYPEC_CC_OPEN) ||
648 (port->polarity == TYPEC_POLARITY_CC2 &&
649 port->cc2 == TYPEC_CC_OPEN)));
650 }
651
652 /*
653 * Logging
654 */
655
656 #ifdef CONFIG_DEBUG_FS
657
tcpm_log_full(struct tcpm_port * port)658 static bool tcpm_log_full(struct tcpm_port *port)
659 {
660 return port->logbuffer_tail ==
661 (port->logbuffer_head + 1) % LOG_BUFFER_ENTRIES;
662 }
663
664 __printf(2, 0)
_tcpm_log(struct tcpm_port * port,const char * fmt,va_list args)665 static void _tcpm_log(struct tcpm_port *port, const char *fmt, va_list args)
666 {
667 char tmpbuffer[LOG_BUFFER_ENTRY_SIZE];
668 u64 ts_nsec = local_clock();
669 unsigned long rem_nsec;
670
671 mutex_lock(&port->logbuffer_lock);
672 if (!port->logbuffer[port->logbuffer_head]) {
673 port->logbuffer[port->logbuffer_head] =
674 kzalloc(LOG_BUFFER_ENTRY_SIZE, GFP_KERNEL);
675 if (!port->logbuffer[port->logbuffer_head]) {
676 mutex_unlock(&port->logbuffer_lock);
677 return;
678 }
679 }
680
681 vsnprintf(tmpbuffer, sizeof(tmpbuffer), fmt, args);
682
683 if (tcpm_log_full(port)) {
684 port->logbuffer_head = max(port->logbuffer_head - 1, 0);
685 strcpy(tmpbuffer, "overflow");
686 }
687
688 if (port->logbuffer_head < 0 ||
689 port->logbuffer_head >= LOG_BUFFER_ENTRIES) {
690 dev_warn(port->dev,
691 "Bad log buffer index %d\n", port->logbuffer_head);
692 goto abort;
693 }
694
695 if (!port->logbuffer[port->logbuffer_head]) {
696 dev_warn(port->dev,
697 "Log buffer index %d is NULL\n", port->logbuffer_head);
698 goto abort;
699 }
700
701 rem_nsec = do_div(ts_nsec, 1000000000);
702 scnprintf(port->logbuffer[port->logbuffer_head],
703 LOG_BUFFER_ENTRY_SIZE, "[%5lu.%06lu] %s",
704 (unsigned long)ts_nsec, rem_nsec / 1000,
705 tmpbuffer);
706 port->logbuffer_head = (port->logbuffer_head + 1) % LOG_BUFFER_ENTRIES;
707
708 abort:
709 mutex_unlock(&port->logbuffer_lock);
710 }
711
712 __printf(2, 3)
tcpm_log(struct tcpm_port * port,const char * fmt,...)713 static void tcpm_log(struct tcpm_port *port, const char *fmt, ...)
714 {
715 va_list args;
716
717 /* Do not log while disconnected and unattached */
718 if (tcpm_port_is_disconnected(port) &&
719 (port->state == SRC_UNATTACHED || port->state == SNK_UNATTACHED ||
720 port->state == TOGGLING || port->state == CHECK_CONTAMINANT))
721 return;
722
723 va_start(args, fmt);
724 _tcpm_log(port, fmt, args);
725 va_end(args);
726 }
727
728 __printf(2, 3)
tcpm_log_force(struct tcpm_port * port,const char * fmt,...)729 static void tcpm_log_force(struct tcpm_port *port, const char *fmt, ...)
730 {
731 va_list args;
732
733 va_start(args, fmt);
734 _tcpm_log(port, fmt, args);
735 va_end(args);
736 }
737
tcpm_log_source_caps(struct tcpm_port * port)738 static void tcpm_log_source_caps(struct tcpm_port *port)
739 {
740 int i;
741
742 for (i = 0; i < port->nr_source_caps; i++) {
743 u32 pdo = port->source_caps[i];
744 enum pd_pdo_type type = pdo_type(pdo);
745 char msg[64];
746
747 switch (type) {
748 case PDO_TYPE_FIXED:
749 scnprintf(msg, sizeof(msg),
750 "%u mV, %u mA [%s%s%s%s%s%s]",
751 pdo_fixed_voltage(pdo),
752 pdo_max_current(pdo),
753 (pdo & PDO_FIXED_DUAL_ROLE) ?
754 "R" : "",
755 (pdo & PDO_FIXED_SUSPEND) ?
756 "S" : "",
757 (pdo & PDO_FIXED_HIGHER_CAP) ?
758 "H" : "",
759 (pdo & PDO_FIXED_USB_COMM) ?
760 "U" : "",
761 (pdo & PDO_FIXED_DATA_SWAP) ?
762 "D" : "",
763 (pdo & PDO_FIXED_EXTPOWER) ?
764 "E" : "");
765 break;
766 case PDO_TYPE_VAR:
767 scnprintf(msg, sizeof(msg),
768 "%u-%u mV, %u mA",
769 pdo_min_voltage(pdo),
770 pdo_max_voltage(pdo),
771 pdo_max_current(pdo));
772 break;
773 case PDO_TYPE_BATT:
774 scnprintf(msg, sizeof(msg),
775 "%u-%u mV, %u mW",
776 pdo_min_voltage(pdo),
777 pdo_max_voltage(pdo),
778 pdo_max_power(pdo));
779 break;
780 case PDO_TYPE_APDO:
781 if (pdo_apdo_type(pdo) == APDO_TYPE_PPS)
782 scnprintf(msg, sizeof(msg),
783 "%u-%u mV, %u mA",
784 pdo_pps_apdo_min_voltage(pdo),
785 pdo_pps_apdo_max_voltage(pdo),
786 pdo_pps_apdo_max_current(pdo));
787 else
788 strcpy(msg, "undefined APDO");
789 break;
790 default:
791 strcpy(msg, "undefined");
792 break;
793 }
794 tcpm_log(port, " PDO %d: type %d, %s",
795 i, type, msg);
796 }
797 }
798
tcpm_debug_show(struct seq_file * s,void * v)799 static int tcpm_debug_show(struct seq_file *s, void *v)
800 {
801 struct tcpm_port *port = s->private;
802 int tail;
803
804 mutex_lock(&port->logbuffer_lock);
805 tail = port->logbuffer_tail;
806 while (tail != port->logbuffer_head) {
807 seq_printf(s, "%s\n", port->logbuffer[tail]);
808 tail = (tail + 1) % LOG_BUFFER_ENTRIES;
809 }
810 if (!seq_has_overflowed(s))
811 port->logbuffer_tail = tail;
812 mutex_unlock(&port->logbuffer_lock);
813
814 return 0;
815 }
816 DEFINE_SHOW_ATTRIBUTE(tcpm_debug);
817
tcpm_debugfs_init(struct tcpm_port * port)818 static void tcpm_debugfs_init(struct tcpm_port *port)
819 {
820 char name[NAME_MAX];
821
822 mutex_init(&port->logbuffer_lock);
823 snprintf(name, NAME_MAX, "tcpm-%s", dev_name(port->dev));
824 port->dentry = debugfs_create_dir(name, usb_debug_root);
825 debugfs_create_file("log", S_IFREG | 0444, port->dentry, port,
826 &tcpm_debug_fops);
827 }
828
tcpm_debugfs_exit(struct tcpm_port * port)829 static void tcpm_debugfs_exit(struct tcpm_port *port)
830 {
831 int i;
832
833 mutex_lock(&port->logbuffer_lock);
834 for (i = 0; i < LOG_BUFFER_ENTRIES; i++) {
835 kfree(port->logbuffer[i]);
836 port->logbuffer[i] = NULL;
837 }
838 mutex_unlock(&port->logbuffer_lock);
839
840 debugfs_remove(port->dentry);
841 }
842
843 #else
844
845 __printf(2, 3)
tcpm_log(const struct tcpm_port * port,const char * fmt,...)846 static void tcpm_log(const struct tcpm_port *port, const char *fmt, ...) { }
847 __printf(2, 3)
tcpm_log_force(struct tcpm_port * port,const char * fmt,...)848 static void tcpm_log_force(struct tcpm_port *port, const char *fmt, ...) { }
tcpm_log_source_caps(struct tcpm_port * port)849 static void tcpm_log_source_caps(struct tcpm_port *port) { }
tcpm_debugfs_init(const struct tcpm_port * port)850 static void tcpm_debugfs_init(const struct tcpm_port *port) { }
tcpm_debugfs_exit(const struct tcpm_port * port)851 static void tcpm_debugfs_exit(const struct tcpm_port *port) { }
852
853 #endif
854
tcpm_set_cc(struct tcpm_port * port,enum typec_cc_status cc)855 static void tcpm_set_cc(struct tcpm_port *port, enum typec_cc_status cc)
856 {
857 tcpm_log(port, "cc:=%d", cc);
858 port->cc_req = cc;
859 port->tcpc->set_cc(port->tcpc, cc);
860 }
861
tcpm_enable_auto_vbus_discharge(struct tcpm_port * port,bool enable)862 static int tcpm_enable_auto_vbus_discharge(struct tcpm_port *port, bool enable)
863 {
864 int ret = 0;
865
866 if (port->tcpc->enable_auto_vbus_discharge) {
867 ret = port->tcpc->enable_auto_vbus_discharge(port->tcpc, enable);
868 tcpm_log_force(port, "%s vbus discharge ret:%d", enable ? "enable" : "disable",
869 ret);
870 if (!ret)
871 port->auto_vbus_discharge_enabled = enable;
872 }
873
874 return ret;
875 }
876
tcpm_apply_rc(struct tcpm_port * port)877 static void tcpm_apply_rc(struct tcpm_port *port)
878 {
879 /*
880 * TCPCI: Move to APPLY_RC state to prevent disconnect during PR_SWAP
881 * when Vbus auto discharge on disconnect is enabled.
882 */
883 if (port->tcpc->enable_auto_vbus_discharge && port->tcpc->apply_rc) {
884 tcpm_log(port, "Apply_RC");
885 port->tcpc->apply_rc(port->tcpc, port->cc_req, port->polarity);
886 tcpm_enable_auto_vbus_discharge(port, false);
887 }
888 }
889
890 /*
891 * Determine RP value to set based on maximum current supported
892 * by a port if configured as source.
893 * Returns CC value to report to link partner.
894 */
tcpm_rp_cc(struct tcpm_port * port)895 static enum typec_cc_status tcpm_rp_cc(struct tcpm_port *port)
896 {
897 const u32 *src_pdo = port->src_pdo;
898 int nr_pdo = port->nr_src_pdo;
899 int i;
900
901 if (!port->pd_supported)
902 return port->src_rp;
903
904 /*
905 * Search for first entry with matching voltage.
906 * It should report the maximum supported current.
907 */
908 for (i = 0; i < nr_pdo; i++) {
909 const u32 pdo = src_pdo[i];
910
911 if (pdo_type(pdo) == PDO_TYPE_FIXED &&
912 pdo_fixed_voltage(pdo) == 5000) {
913 unsigned int curr = pdo_max_current(pdo);
914
915 if (curr >= 3000)
916 return TYPEC_CC_RP_3_0;
917 else if (curr >= 1500)
918 return TYPEC_CC_RP_1_5;
919 return TYPEC_CC_RP_DEF;
920 }
921 }
922
923 return TYPEC_CC_RP_DEF;
924 }
925
tcpm_ams_finish(struct tcpm_port * port)926 static void tcpm_ams_finish(struct tcpm_port *port)
927 {
928 tcpm_log(port, "AMS %s finished", tcpm_ams_str[port->ams]);
929
930 if (port->pd_capable && port->pwr_role == TYPEC_SOURCE) {
931 if (port->negotiated_rev >= PD_REV30)
932 tcpm_set_cc(port, SINK_TX_OK);
933 else
934 tcpm_set_cc(port, SINK_TX_NG);
935 } else if (port->pwr_role == TYPEC_SOURCE) {
936 tcpm_set_cc(port, tcpm_rp_cc(port));
937 }
938
939 port->in_ams = false;
940 port->ams = NONE_AMS;
941 }
942
tcpm_pd_transmit(struct tcpm_port * port,enum tcpm_transmit_type tx_sop_type,const struct pd_message * msg)943 static int tcpm_pd_transmit(struct tcpm_port *port,
944 enum tcpm_transmit_type tx_sop_type,
945 const struct pd_message *msg)
946 {
947 unsigned long time_left;
948 int ret;
949 unsigned int negotiated_rev;
950
951 switch (tx_sop_type) {
952 case TCPC_TX_SOP_PRIME:
953 negotiated_rev = port->negotiated_rev_prime;
954 break;
955 case TCPC_TX_SOP:
956 default:
957 negotiated_rev = port->negotiated_rev;
958 break;
959 }
960
961 if (msg)
962 tcpm_log(port, "PD TX, header: %#x", le16_to_cpu(msg->header));
963 else
964 tcpm_log(port, "PD TX, type: %#x", tx_sop_type);
965
966 reinit_completion(&port->tx_complete);
967 ret = port->tcpc->pd_transmit(port->tcpc, tx_sop_type, msg, negotiated_rev);
968 if (ret < 0)
969 return ret;
970
971 mutex_unlock(&port->lock);
972 time_left = wait_for_completion_timeout(&port->tx_complete,
973 msecs_to_jiffies(PD_T_TCPC_TX_TIMEOUT));
974 mutex_lock(&port->lock);
975 if (!time_left)
976 return -ETIMEDOUT;
977
978 switch (port->tx_status) {
979 case TCPC_TX_SUCCESS:
980 switch (tx_sop_type) {
981 case TCPC_TX_SOP_PRIME:
982 port->message_id_prime = (port->message_id_prime + 1) &
983 PD_HEADER_ID_MASK;
984 break;
985 case TCPC_TX_SOP:
986 default:
987 port->message_id = (port->message_id + 1) &
988 PD_HEADER_ID_MASK;
989 break;
990 }
991 /*
992 * USB PD rev 2.0, 8.3.2.2.1:
993 * USB PD rev 3.0, 8.3.2.1.3:
994 * "... Note that every AMS is Interruptible until the first
995 * Message in the sequence has been successfully sent (GoodCRC
996 * Message received)."
997 */
998 if (port->ams != NONE_AMS)
999 port->in_ams = true;
1000 break;
1001 case TCPC_TX_DISCARDED:
1002 ret = -EAGAIN;
1003 break;
1004 case TCPC_TX_FAILED:
1005 default:
1006 ret = -EIO;
1007 break;
1008 }
1009
1010 /* Some AMS don't expect responses. Finish them here. */
1011 if (port->ams == ATTENTION || port->ams == SOURCE_ALERT)
1012 tcpm_ams_finish(port);
1013
1014 return ret;
1015 }
1016
tcpm_pd_transmit_complete(struct tcpm_port * port,enum tcpm_transmit_status status)1017 void tcpm_pd_transmit_complete(struct tcpm_port *port,
1018 enum tcpm_transmit_status status)
1019 {
1020 tcpm_log(port, "PD TX complete, status: %u", status);
1021 port->tx_status = status;
1022 complete(&port->tx_complete);
1023 }
1024 EXPORT_SYMBOL_GPL(tcpm_pd_transmit_complete);
1025
tcpm_mux_set(struct tcpm_port * port,int state,enum usb_role usb_role,enum typec_orientation orientation)1026 static int tcpm_mux_set(struct tcpm_port *port, int state,
1027 enum usb_role usb_role,
1028 enum typec_orientation orientation)
1029 {
1030 int ret;
1031
1032 tcpm_log(port, "Requesting mux state %d, usb-role %d, orientation %d",
1033 state, usb_role, orientation);
1034
1035 ret = typec_set_orientation(port->typec_port, orientation);
1036 if (ret)
1037 return ret;
1038
1039 if (port->role_sw) {
1040 ret = usb_role_switch_set_role(port->role_sw, usb_role);
1041 if (ret)
1042 return ret;
1043 }
1044
1045 return typec_set_mode(port->typec_port, state);
1046 }
1047
tcpm_set_polarity(struct tcpm_port * port,enum typec_cc_polarity polarity)1048 static int tcpm_set_polarity(struct tcpm_port *port,
1049 enum typec_cc_polarity polarity)
1050 {
1051 int ret;
1052
1053 tcpm_log(port, "polarity %d", polarity);
1054
1055 ret = port->tcpc->set_polarity(port->tcpc, polarity);
1056 if (ret < 0)
1057 return ret;
1058
1059 port->polarity = polarity;
1060
1061 return 0;
1062 }
1063
tcpm_set_vconn(struct tcpm_port * port,bool enable)1064 static int tcpm_set_vconn(struct tcpm_port *port, bool enable)
1065 {
1066 int ret;
1067
1068 tcpm_log(port, "vconn:=%d", enable);
1069
1070 ret = port->tcpc->set_vconn(port->tcpc, enable);
1071 if (!ret) {
1072 port->vconn_role = enable ? TYPEC_SOURCE : TYPEC_SINK;
1073 typec_set_vconn_role(port->typec_port, port->vconn_role);
1074 }
1075
1076 return ret;
1077 }
1078
tcpm_get_current_limit(struct tcpm_port * port)1079 static u32 tcpm_get_current_limit(struct tcpm_port *port)
1080 {
1081 enum typec_cc_status cc;
1082 u32 limit;
1083
1084 cc = port->polarity ? port->cc2 : port->cc1;
1085 switch (cc) {
1086 case TYPEC_CC_RP_1_5:
1087 limit = 1500;
1088 break;
1089 case TYPEC_CC_RP_3_0:
1090 limit = 3000;
1091 break;
1092 case TYPEC_CC_RP_DEF:
1093 default:
1094 if (port->tcpc->get_current_limit)
1095 limit = port->tcpc->get_current_limit(port->tcpc);
1096 else
1097 limit = 0;
1098 break;
1099 }
1100
1101 return limit;
1102 }
1103
tcpm_set_current_limit(struct tcpm_port * port,u32 max_ma,u32 mv)1104 static int tcpm_set_current_limit(struct tcpm_port *port, u32 max_ma, u32 mv)
1105 {
1106 int ret = -EOPNOTSUPP;
1107
1108 tcpm_log(port, "Setting voltage/current limit %u mV %u mA", mv, max_ma);
1109
1110 port->supply_voltage = mv;
1111 port->current_limit = max_ma;
1112 power_supply_changed(port->psy);
1113
1114 if (port->tcpc->set_current_limit)
1115 ret = port->tcpc->set_current_limit(port->tcpc, max_ma, mv);
1116
1117 return ret;
1118 }
1119
tcpm_set_attached_state(struct tcpm_port * port,bool attached)1120 static int tcpm_set_attached_state(struct tcpm_port *port, bool attached)
1121 {
1122 return port->tcpc->set_roles(port->tcpc, attached, port->pwr_role,
1123 port->data_role);
1124 }
1125
tcpm_set_roles(struct tcpm_port * port,bool attached,enum typec_role role,enum typec_data_role data)1126 static int tcpm_set_roles(struct tcpm_port *port, bool attached,
1127 enum typec_role role, enum typec_data_role data)
1128 {
1129 enum typec_orientation orientation;
1130 enum usb_role usb_role;
1131 int ret;
1132
1133 if (port->polarity == TYPEC_POLARITY_CC1)
1134 orientation = TYPEC_ORIENTATION_NORMAL;
1135 else
1136 orientation = TYPEC_ORIENTATION_REVERSE;
1137
1138 if (port->typec_caps.data == TYPEC_PORT_DRD) {
1139 if (data == TYPEC_HOST)
1140 usb_role = USB_ROLE_HOST;
1141 else
1142 usb_role = USB_ROLE_DEVICE;
1143 } else if (port->typec_caps.data == TYPEC_PORT_DFP) {
1144 if (data == TYPEC_HOST) {
1145 if (role == TYPEC_SOURCE)
1146 usb_role = USB_ROLE_HOST;
1147 else
1148 usb_role = USB_ROLE_NONE;
1149 } else {
1150 return -ENOTSUPP;
1151 }
1152 } else {
1153 if (data == TYPEC_DEVICE) {
1154 if (role == TYPEC_SINK)
1155 usb_role = USB_ROLE_DEVICE;
1156 else
1157 usb_role = USB_ROLE_NONE;
1158 } else {
1159 return -ENOTSUPP;
1160 }
1161 }
1162
1163 ret = tcpm_mux_set(port, TYPEC_STATE_USB, usb_role, orientation);
1164 if (ret < 0)
1165 return ret;
1166
1167 ret = port->tcpc->set_roles(port->tcpc, attached, role, data);
1168 if (ret < 0)
1169 return ret;
1170
1171 if (port->tcpc->set_orientation) {
1172 ret = port->tcpc->set_orientation(port->tcpc, orientation);
1173 if (ret < 0)
1174 return ret;
1175 }
1176
1177 port->pwr_role = role;
1178 port->data_role = data;
1179 typec_set_data_role(port->typec_port, data);
1180 typec_set_pwr_role(port->typec_port, role);
1181
1182 return 0;
1183 }
1184
tcpm_set_pwr_role(struct tcpm_port * port,enum typec_role role)1185 static int tcpm_set_pwr_role(struct tcpm_port *port, enum typec_role role)
1186 {
1187 int ret;
1188
1189 ret = port->tcpc->set_roles(port->tcpc, true, role,
1190 port->data_role);
1191 if (ret < 0)
1192 return ret;
1193
1194 port->pwr_role = role;
1195 typec_set_pwr_role(port->typec_port, role);
1196
1197 return 0;
1198 }
1199
1200 /*
1201 * Transform the PDO to be compliant to PD rev2.0.
1202 * Return 0 if the PDO type is not defined in PD rev2.0.
1203 * Otherwise, return the converted PDO.
1204 */
tcpm_forge_legacy_pdo(struct tcpm_port * port,u32 pdo,enum typec_role role)1205 static u32 tcpm_forge_legacy_pdo(struct tcpm_port *port, u32 pdo, enum typec_role role)
1206 {
1207 switch (pdo_type(pdo)) {
1208 case PDO_TYPE_FIXED:
1209 if (role == TYPEC_SINK)
1210 return pdo & ~PDO_FIXED_FRS_CURR_MASK;
1211 else
1212 return pdo & ~PDO_FIXED_UNCHUNK_EXT;
1213 case PDO_TYPE_VAR:
1214 case PDO_TYPE_BATT:
1215 return pdo;
1216 case PDO_TYPE_APDO:
1217 default:
1218 return 0;
1219 }
1220 }
1221
tcpm_pd_send_source_caps(struct tcpm_port * port)1222 static int tcpm_pd_send_source_caps(struct tcpm_port *port)
1223 {
1224 struct pd_message msg;
1225 u32 pdo;
1226 unsigned int i, nr_pdo = 0;
1227
1228 memset(&msg, 0, sizeof(msg));
1229
1230 for (i = 0; i < port->nr_src_pdo; i++) {
1231 if (port->negotiated_rev >= PD_REV30) {
1232 msg.payload[nr_pdo++] = cpu_to_le32(port->src_pdo[i]);
1233 } else {
1234 pdo = tcpm_forge_legacy_pdo(port, port->src_pdo[i], TYPEC_SOURCE);
1235 if (pdo)
1236 msg.payload[nr_pdo++] = cpu_to_le32(pdo);
1237 }
1238 }
1239
1240 if (!nr_pdo) {
1241 /* No source capabilities defined, sink only */
1242 msg.header = PD_HEADER_LE(PD_CTRL_REJECT,
1243 port->pwr_role,
1244 port->data_role,
1245 port->negotiated_rev,
1246 port->message_id, 0);
1247 } else {
1248 msg.header = PD_HEADER_LE(PD_DATA_SOURCE_CAP,
1249 port->pwr_role,
1250 port->data_role,
1251 port->negotiated_rev,
1252 port->message_id,
1253 nr_pdo);
1254 }
1255
1256 return tcpm_pd_transmit(port, TCPC_TX_SOP, &msg);
1257 }
1258
tcpm_pd_send_sink_caps(struct tcpm_port * port)1259 static int tcpm_pd_send_sink_caps(struct tcpm_port *port)
1260 {
1261 struct pd_message msg;
1262 u32 pdo;
1263 unsigned int i, nr_pdo = 0;
1264
1265 memset(&msg, 0, sizeof(msg));
1266
1267 for (i = 0; i < port->nr_snk_pdo; i++) {
1268 if (port->negotiated_rev >= PD_REV30) {
1269 msg.payload[nr_pdo++] = cpu_to_le32(port->snk_pdo[i]);
1270 } else {
1271 pdo = tcpm_forge_legacy_pdo(port, port->snk_pdo[i], TYPEC_SINK);
1272 if (pdo)
1273 msg.payload[nr_pdo++] = cpu_to_le32(pdo);
1274 }
1275 }
1276
1277 if (!nr_pdo) {
1278 /* No sink capabilities defined, source only */
1279 msg.header = PD_HEADER_LE(PD_CTRL_REJECT,
1280 port->pwr_role,
1281 port->data_role,
1282 port->negotiated_rev,
1283 port->message_id, 0);
1284 } else {
1285 msg.header = PD_HEADER_LE(PD_DATA_SINK_CAP,
1286 port->pwr_role,
1287 port->data_role,
1288 port->negotiated_rev,
1289 port->message_id,
1290 nr_pdo);
1291 }
1292
1293 return tcpm_pd_transmit(port, TCPC_TX_SOP, &msg);
1294 }
1295
mod_tcpm_delayed_work(struct tcpm_port * port,unsigned int delay_ms)1296 static void mod_tcpm_delayed_work(struct tcpm_port *port, unsigned int delay_ms)
1297 {
1298 if (delay_ms) {
1299 hrtimer_start(&port->state_machine_timer, ms_to_ktime(delay_ms), HRTIMER_MODE_REL);
1300 } else {
1301 hrtimer_cancel(&port->state_machine_timer);
1302 kthread_queue_work(port->wq, &port->state_machine);
1303 }
1304 }
1305
mod_vdm_delayed_work(struct tcpm_port * port,unsigned int delay_ms)1306 static void mod_vdm_delayed_work(struct tcpm_port *port, unsigned int delay_ms)
1307 {
1308 if (delay_ms) {
1309 hrtimer_start(&port->vdm_state_machine_timer, ms_to_ktime(delay_ms),
1310 HRTIMER_MODE_REL);
1311 } else {
1312 hrtimer_cancel(&port->vdm_state_machine_timer);
1313 kthread_queue_work(port->wq, &port->vdm_state_machine);
1314 }
1315 }
1316
mod_enable_frs_delayed_work(struct tcpm_port * port,unsigned int delay_ms)1317 static void mod_enable_frs_delayed_work(struct tcpm_port *port, unsigned int delay_ms)
1318 {
1319 if (delay_ms) {
1320 hrtimer_start(&port->enable_frs_timer, ms_to_ktime(delay_ms), HRTIMER_MODE_REL);
1321 } else {
1322 hrtimer_cancel(&port->enable_frs_timer);
1323 kthread_queue_work(port->wq, &port->enable_frs);
1324 }
1325 }
1326
mod_send_discover_delayed_work(struct tcpm_port * port,unsigned int delay_ms)1327 static void mod_send_discover_delayed_work(struct tcpm_port *port, unsigned int delay_ms)
1328 {
1329 if (delay_ms) {
1330 hrtimer_start(&port->send_discover_timer, ms_to_ktime(delay_ms), HRTIMER_MODE_REL);
1331 } else {
1332 hrtimer_cancel(&port->send_discover_timer);
1333 kthread_queue_work(port->wq, &port->send_discover_work);
1334 }
1335 }
1336
tcpm_set_state(struct tcpm_port * port,enum tcpm_state state,unsigned int delay_ms)1337 static void tcpm_set_state(struct tcpm_port *port, enum tcpm_state state,
1338 unsigned int delay_ms)
1339 {
1340 if (delay_ms) {
1341 tcpm_log(port, "pending state change %s -> %s @ %u ms [%s %s]",
1342 tcpm_states[port->state], tcpm_states[state], delay_ms,
1343 pd_rev[port->negotiated_rev], tcpm_ams_str[port->ams]);
1344 port->delayed_state = state;
1345 mod_tcpm_delayed_work(port, delay_ms);
1346 port->delayed_runtime = ktime_add(ktime_get(), ms_to_ktime(delay_ms));
1347 port->delay_ms = delay_ms;
1348 } else {
1349 tcpm_log(port, "state change %s -> %s [%s %s]",
1350 tcpm_states[port->state], tcpm_states[state],
1351 pd_rev[port->negotiated_rev], tcpm_ams_str[port->ams]);
1352 port->delayed_state = INVALID_STATE;
1353 port->prev_state = port->state;
1354 port->state = state;
1355 /*
1356 * Don't re-queue the state machine work item if we're currently
1357 * in the state machine and we're immediately changing states.
1358 * tcpm_state_machine_work() will continue running the state
1359 * machine.
1360 */
1361 if (!port->state_machine_running)
1362 mod_tcpm_delayed_work(port, 0);
1363 }
1364 }
1365
tcpm_set_state_cond(struct tcpm_port * port,enum tcpm_state state,unsigned int delay_ms)1366 static void tcpm_set_state_cond(struct tcpm_port *port, enum tcpm_state state,
1367 unsigned int delay_ms)
1368 {
1369 if (port->enter_state == port->state)
1370 tcpm_set_state(port, state, delay_ms);
1371 else
1372 tcpm_log(port,
1373 "skipped %sstate change %s -> %s [%u ms], context state %s [%s %s]",
1374 delay_ms ? "delayed " : "",
1375 tcpm_states[port->state], tcpm_states[state],
1376 delay_ms, tcpm_states[port->enter_state],
1377 pd_rev[port->negotiated_rev], tcpm_ams_str[port->ams]);
1378 }
1379
tcpm_queue_message(struct tcpm_port * port,enum pd_msg_request message)1380 static void tcpm_queue_message(struct tcpm_port *port,
1381 enum pd_msg_request message)
1382 {
1383 port->queued_message = message;
1384 mod_tcpm_delayed_work(port, 0);
1385 }
1386
tcpm_vdm_ams(struct tcpm_port * port)1387 static bool tcpm_vdm_ams(struct tcpm_port *port)
1388 {
1389 switch (port->ams) {
1390 case DISCOVER_IDENTITY:
1391 case SOURCE_STARTUP_CABLE_PLUG_DISCOVER_IDENTITY:
1392 case DISCOVER_SVIDS:
1393 case DISCOVER_MODES:
1394 case DFP_TO_UFP_ENTER_MODE:
1395 case DFP_TO_UFP_EXIT_MODE:
1396 case DFP_TO_CABLE_PLUG_ENTER_MODE:
1397 case DFP_TO_CABLE_PLUG_EXIT_MODE:
1398 case ATTENTION:
1399 case UNSTRUCTURED_VDMS:
1400 case STRUCTURED_VDMS:
1401 break;
1402 default:
1403 return false;
1404 }
1405
1406 return true;
1407 }
1408
tcpm_ams_interruptible(struct tcpm_port * port)1409 static bool tcpm_ams_interruptible(struct tcpm_port *port)
1410 {
1411 switch (port->ams) {
1412 /* Interruptible AMS */
1413 case NONE_AMS:
1414 case SECURITY:
1415 case FIRMWARE_UPDATE:
1416 case DISCOVER_IDENTITY:
1417 case SOURCE_STARTUP_CABLE_PLUG_DISCOVER_IDENTITY:
1418 case DISCOVER_SVIDS:
1419 case DISCOVER_MODES:
1420 case DFP_TO_UFP_ENTER_MODE:
1421 case DFP_TO_UFP_EXIT_MODE:
1422 case DFP_TO_CABLE_PLUG_ENTER_MODE:
1423 case DFP_TO_CABLE_PLUG_EXIT_MODE:
1424 case UNSTRUCTURED_VDMS:
1425 case STRUCTURED_VDMS:
1426 case COUNTRY_INFO:
1427 case COUNTRY_CODES:
1428 break;
1429 /* Non-Interruptible AMS */
1430 default:
1431 if (port->in_ams)
1432 return false;
1433 break;
1434 }
1435
1436 return true;
1437 }
1438
tcpm_ams_start(struct tcpm_port * port,enum tcpm_ams ams)1439 static int tcpm_ams_start(struct tcpm_port *port, enum tcpm_ams ams)
1440 {
1441 int ret = 0;
1442
1443 tcpm_log(port, "AMS %s start", tcpm_ams_str[ams]);
1444
1445 if (!tcpm_ams_interruptible(port) &&
1446 !(ams == HARD_RESET || ams == SOFT_RESET_AMS)) {
1447 port->upcoming_state = INVALID_STATE;
1448 tcpm_log(port, "AMS %s not interruptible, aborting",
1449 tcpm_ams_str[port->ams]);
1450 return -EAGAIN;
1451 }
1452
1453 if (port->pwr_role == TYPEC_SOURCE) {
1454 enum typec_cc_status cc_req = port->cc_req;
1455
1456 port->ams = ams;
1457
1458 if (ams == HARD_RESET) {
1459 tcpm_set_cc(port, tcpm_rp_cc(port));
1460 tcpm_pd_transmit(port, TCPC_TX_HARD_RESET, NULL);
1461 tcpm_set_state(port, HARD_RESET_START, 0);
1462 return ret;
1463 } else if (ams == SOFT_RESET_AMS) {
1464 if (!port->explicit_contract)
1465 tcpm_set_cc(port, tcpm_rp_cc(port));
1466 tcpm_set_state(port, SOFT_RESET_SEND, 0);
1467 return ret;
1468 } else if (tcpm_vdm_ams(port)) {
1469 /* tSinkTx is enforced in vdm_run_state_machine */
1470 if (port->negotiated_rev >= PD_REV30)
1471 tcpm_set_cc(port, SINK_TX_NG);
1472 return ret;
1473 }
1474
1475 if (port->negotiated_rev >= PD_REV30)
1476 tcpm_set_cc(port, SINK_TX_NG);
1477
1478 switch (port->state) {
1479 case SRC_READY:
1480 case SRC_STARTUP:
1481 case SRC_SOFT_RESET_WAIT_SNK_TX:
1482 case SOFT_RESET:
1483 case SOFT_RESET_SEND:
1484 if (port->negotiated_rev >= PD_REV30)
1485 tcpm_set_state(port, AMS_START,
1486 cc_req == SINK_TX_OK ?
1487 PD_T_SINK_TX : 0);
1488 else
1489 tcpm_set_state(port, AMS_START, 0);
1490 break;
1491 default:
1492 if (port->negotiated_rev >= PD_REV30)
1493 tcpm_set_state(port, SRC_READY,
1494 cc_req == SINK_TX_OK ?
1495 PD_T_SINK_TX : 0);
1496 else
1497 tcpm_set_state(port, SRC_READY, 0);
1498 break;
1499 }
1500 } else {
1501 if (port->negotiated_rev >= PD_REV30 &&
1502 !tcpm_sink_tx_ok(port) &&
1503 ams != SOFT_RESET_AMS &&
1504 ams != HARD_RESET) {
1505 port->upcoming_state = INVALID_STATE;
1506 tcpm_log(port, "Sink TX No Go");
1507 return -EAGAIN;
1508 }
1509
1510 port->ams = ams;
1511
1512 if (ams == HARD_RESET) {
1513 tcpm_pd_transmit(port, TCPC_TX_HARD_RESET, NULL);
1514 tcpm_set_state(port, HARD_RESET_START, 0);
1515 return ret;
1516 } else if (tcpm_vdm_ams(port)) {
1517 return ret;
1518 }
1519
1520 if (port->state == SNK_READY ||
1521 port->state == SNK_SOFT_RESET)
1522 tcpm_set_state(port, AMS_START, 0);
1523 else
1524 tcpm_set_state(port, SNK_READY, 0);
1525 }
1526
1527 return ret;
1528 }
1529
1530 /*
1531 * VDM/VDO handling functions
1532 */
tcpm_queue_vdm(struct tcpm_port * port,const u32 header,const u32 * data,int cnt,enum tcpm_transmit_type tx_sop_type)1533 static void tcpm_queue_vdm(struct tcpm_port *port, const u32 header,
1534 const u32 *data, int cnt, enum tcpm_transmit_type tx_sop_type)
1535 {
1536 u32 vdo_hdr = port->vdo_data[0];
1537
1538 WARN_ON(!mutex_is_locked(&port->lock));
1539
1540 /* If is sending discover_identity, handle received message first */
1541 if (PD_VDO_SVDM(vdo_hdr) && PD_VDO_CMD(vdo_hdr) == CMD_DISCOVER_IDENT) {
1542 if (tx_sop_type == TCPC_TX_SOP_PRIME)
1543 port->send_discover_prime = true;
1544 else
1545 port->send_discover = true;
1546 mod_send_discover_delayed_work(port, SEND_DISCOVER_RETRY_MS);
1547 } else {
1548 /* Make sure we are not still processing a previous VDM packet */
1549 WARN_ON(port->vdm_state > VDM_STATE_DONE);
1550 }
1551
1552 port->vdo_count = cnt + 1;
1553 port->vdo_data[0] = header;
1554 memcpy(&port->vdo_data[1], data, sizeof(u32) * cnt);
1555 /* Set ready, vdm state machine will actually send */
1556 port->vdm_retries = 0;
1557 port->vdm_state = VDM_STATE_READY;
1558 port->vdm_sm_running = true;
1559
1560 port->tx_sop_type = tx_sop_type;
1561
1562 mod_vdm_delayed_work(port, 0);
1563 }
1564
tcpm_queue_vdm_unlocked(struct tcpm_port * port,const u32 header,const u32 * data,int cnt,enum tcpm_transmit_type tx_sop_type)1565 static void tcpm_queue_vdm_unlocked(struct tcpm_port *port, const u32 header,
1566 const u32 *data, int cnt, enum tcpm_transmit_type tx_sop_type)
1567 {
1568 if (port->state != SRC_READY && port->state != SNK_READY &&
1569 port->state != SRC_VDM_IDENTITY_REQUEST)
1570 return;
1571
1572 mutex_lock(&port->lock);
1573 tcpm_queue_vdm(port, header, data, cnt, tx_sop_type);
1574 mutex_unlock(&port->lock);
1575 }
1576
svdm_consume_identity(struct tcpm_port * port,const u32 * p,int cnt)1577 static void svdm_consume_identity(struct tcpm_port *port, const u32 *p, int cnt)
1578 {
1579 u32 vdo = p[VDO_INDEX_IDH];
1580 u32 product = p[VDO_INDEX_PRODUCT];
1581
1582 memset(&port->mode_data, 0, sizeof(port->mode_data));
1583
1584 port->partner_ident.id_header = vdo;
1585 port->partner_ident.cert_stat = p[VDO_INDEX_CSTAT];
1586 port->partner_ident.product = product;
1587
1588 if (port->partner)
1589 typec_partner_set_identity(port->partner);
1590
1591 tcpm_log(port, "Identity: %04x:%04x.%04x",
1592 PD_IDH_VID(vdo),
1593 PD_PRODUCT_PID(product), product & 0xffff);
1594 }
1595
svdm_consume_identity_sop_prime(struct tcpm_port * port,const u32 * p,int cnt)1596 static void svdm_consume_identity_sop_prime(struct tcpm_port *port, const u32 *p, int cnt)
1597 {
1598 u32 idh = p[VDO_INDEX_IDH];
1599 u32 product = p[VDO_INDEX_PRODUCT];
1600 int svdm_version;
1601
1602 /*
1603 * Attempt to consume identity only if cable currently is not set
1604 */
1605 if (!IS_ERR_OR_NULL(port->cable))
1606 goto register_plug;
1607
1608 /* Reset cable identity */
1609 memset(&port->cable_ident, 0, sizeof(port->cable_ident));
1610
1611 /* Fill out id header, cert, product, cable VDO 1 */
1612 port->cable_ident.id_header = idh;
1613 port->cable_ident.cert_stat = p[VDO_INDEX_CSTAT];
1614 port->cable_ident.product = product;
1615 port->cable_ident.vdo[0] = p[VDO_INDEX_CABLE_1];
1616
1617 /* Fill out cable desc, infer svdm_version from pd revision */
1618 port->cable_desc.type = (enum typec_plug_type) (VDO_TYPEC_CABLE_TYPE(p[VDO_INDEX_CABLE_1]) +
1619 USB_PLUG_TYPE_A);
1620 port->cable_desc.active = PD_IDH_PTYPE(idh) == IDH_PTYPE_ACABLE ? 1 : 0;
1621 /* Log PD Revision and additional cable VDO from negotiated revision */
1622 switch (port->negotiated_rev_prime) {
1623 case PD_REV30:
1624 port->cable_desc.pd_revision = 0x0300;
1625 if (port->cable_desc.active)
1626 port->cable_ident.vdo[1] = p[VDO_INDEX_CABLE_2];
1627 break;
1628 case PD_REV20:
1629 port->cable_desc.pd_revision = 0x0200;
1630 break;
1631 default:
1632 port->cable_desc.pd_revision = 0x0200;
1633 break;
1634 }
1635 port->cable_desc.identity = &port->cable_ident;
1636 /* Register Cable, set identity and svdm_version */
1637 port->cable = typec_register_cable(port->typec_port, &port->cable_desc);
1638 if (IS_ERR_OR_NULL(port->cable))
1639 return;
1640 typec_cable_set_identity(port->cable);
1641 /* Get SVDM version */
1642 svdm_version = PD_VDO_SVDM_VER(p[VDO_INDEX_HDR]);
1643 typec_cable_set_svdm_version(port->cable, svdm_version);
1644
1645 register_plug:
1646 if (IS_ERR_OR_NULL(port->plug_prime)) {
1647 port->plug_prime_desc.index = TYPEC_PLUG_SOP_P;
1648 port->plug_prime = typec_register_plug(port->cable,
1649 &port->plug_prime_desc);
1650 }
1651 }
1652
svdm_consume_svids(struct tcpm_port * port,const u32 * p,int cnt,enum tcpm_transmit_type rx_sop_type)1653 static bool svdm_consume_svids(struct tcpm_port *port, const u32 *p, int cnt,
1654 enum tcpm_transmit_type rx_sop_type)
1655 {
1656 struct pd_mode_data *pmdata = rx_sop_type == TCPC_TX_SOP_PRIME ?
1657 &port->mode_data_prime : &port->mode_data;
1658 int i;
1659
1660 for (i = 1; i < cnt; i++) {
1661 u16 svid;
1662
1663 svid = (p[i] >> 16) & 0xffff;
1664 if (!svid)
1665 return false;
1666
1667 if (pmdata->nsvids >= SVID_DISCOVERY_MAX)
1668 goto abort;
1669
1670 pmdata->svids[pmdata->nsvids++] = svid;
1671 tcpm_log(port, "SVID %d: 0x%x", pmdata->nsvids, svid);
1672
1673 svid = p[i] & 0xffff;
1674 if (!svid)
1675 return false;
1676
1677 if (pmdata->nsvids >= SVID_DISCOVERY_MAX)
1678 goto abort;
1679
1680 pmdata->svids[pmdata->nsvids++] = svid;
1681 tcpm_log(port, "SVID %d: 0x%x", pmdata->nsvids, svid);
1682 }
1683
1684 /*
1685 * PD3.0 Spec 6.4.4.3.2: The SVIDs are returned 2 per VDO (see Table
1686 * 6-43), and can be returned maximum 6 VDOs per response (see Figure
1687 * 6-19). If the Respondersupports 12 or more SVID then the Discover
1688 * SVIDs Command Shall be executed multiple times until a Discover
1689 * SVIDs VDO is returned ending either with a SVID value of 0x0000 in
1690 * the last part of the last VDO or with a VDO containing two SVIDs
1691 * with values of 0x0000.
1692 *
1693 * However, some odd dockers support SVIDs less than 12 but without
1694 * 0x0000 in the last VDO, so we need to break the Discover SVIDs
1695 * request and return false here.
1696 */
1697 return cnt == 7;
1698 abort:
1699 tcpm_log(port, "SVID_DISCOVERY_MAX(%d) too low!", SVID_DISCOVERY_MAX);
1700 return false;
1701 }
1702
svdm_consume_modes(struct tcpm_port * port,const u32 * p,int cnt,enum tcpm_transmit_type rx_sop_type)1703 static void svdm_consume_modes(struct tcpm_port *port, const u32 *p, int cnt,
1704 enum tcpm_transmit_type rx_sop_type)
1705 {
1706 struct pd_mode_data *pmdata = &port->mode_data;
1707 struct typec_altmode_desc *paltmode;
1708 int i;
1709
1710 switch (rx_sop_type) {
1711 case TCPC_TX_SOP_PRIME:
1712 pmdata = &port->mode_data_prime;
1713 if (pmdata->altmodes >= ARRAY_SIZE(port->plug_prime_altmode)) {
1714 /* Already logged in svdm_consume_svids() */
1715 return;
1716 }
1717 break;
1718 case TCPC_TX_SOP:
1719 pmdata = &port->mode_data;
1720 if (pmdata->altmodes >= ARRAY_SIZE(port->partner_altmode)) {
1721 /* Already logged in svdm_consume_svids() */
1722 return;
1723 }
1724 break;
1725 default:
1726 return;
1727 }
1728
1729 for (i = 1; i < cnt; i++) {
1730 paltmode = &pmdata->altmode_desc[pmdata->altmodes];
1731 memset(paltmode, 0, sizeof(*paltmode));
1732
1733 paltmode->svid = pmdata->svids[pmdata->svid_index];
1734 paltmode->mode = i;
1735 paltmode->vdo = p[i];
1736
1737 tcpm_log(port, " Alternate mode %d: SVID 0x%04x, VDO %d: 0x%08x",
1738 pmdata->altmodes, paltmode->svid,
1739 paltmode->mode, paltmode->vdo);
1740
1741 pmdata->altmodes++;
1742 }
1743 }
1744
tcpm_register_partner_altmodes(struct tcpm_port * port)1745 static void tcpm_register_partner_altmodes(struct tcpm_port *port)
1746 {
1747 struct pd_mode_data *modep = &port->mode_data;
1748 struct typec_altmode *altmode;
1749 int i;
1750
1751 if (!port->partner)
1752 return;
1753
1754 for (i = 0; i < modep->altmodes; i++) {
1755 altmode = typec_partner_register_altmode(port->partner,
1756 &modep->altmode_desc[i]);
1757 if (IS_ERR(altmode)) {
1758 tcpm_log(port, "Failed to register partner SVID 0x%04x",
1759 modep->altmode_desc[i].svid);
1760 altmode = NULL;
1761 }
1762 port->partner_altmode[i] = altmode;
1763 }
1764 }
1765
tcpm_register_plug_altmodes(struct tcpm_port * port)1766 static void tcpm_register_plug_altmodes(struct tcpm_port *port)
1767 {
1768 struct pd_mode_data *modep = &port->mode_data_prime;
1769 struct typec_altmode *altmode;
1770 int i;
1771
1772 typec_plug_set_num_altmodes(port->plug_prime, modep->altmodes);
1773
1774 for (i = 0; i < modep->altmodes; i++) {
1775 altmode = typec_plug_register_altmode(port->plug_prime,
1776 &modep->altmode_desc[i]);
1777 if (IS_ERR(altmode)) {
1778 tcpm_log(port, "Failed to register plug SVID 0x%04x",
1779 modep->altmode_desc[i].svid);
1780 altmode = NULL;
1781 }
1782 port->plug_prime_altmode[i] = altmode;
1783 }
1784 }
1785
1786 #define supports_modal(port) PD_IDH_MODAL_SUPP((port)->partner_ident.id_header)
1787 #define supports_modal_cable(port) PD_IDH_MODAL_SUPP((port)->cable_ident.id_header)
1788 #define supports_host(port) PD_IDH_HOST_SUPP((port->partner_ident.id_header))
1789
1790 /*
1791 * Helper to determine whether the port is capable of SOP' communication at the
1792 * current point in time.
1793 */
tcpm_can_communicate_sop_prime(struct tcpm_port * port)1794 static bool tcpm_can_communicate_sop_prime(struct tcpm_port *port)
1795 {
1796 /* Check to see if tcpc supports SOP' communication */
1797 if (!port->tcpc->cable_comm_capable || !port->tcpc->cable_comm_capable(port->tcpc))
1798 return false;
1799 /*
1800 * Power Delivery 2.0 Section 6.3.11
1801 * Before communicating with a Cable Plug a Port Should ensure that it
1802 * is the Vconn Source and that the Cable Plugs are powered by
1803 * performing a Vconn swap if necessary. Since it cannot be guaranteed
1804 * that the present Vconn Source is supplying Vconn, the only means to
1805 * ensure that the Cable Plugs are powered is for a Port wishing to
1806 * communicate with a Cable Plug is to become the Vconn Source.
1807 *
1808 * Power Delivery 3.0 Section 6.3.11
1809 * Before communicating with a Cable Plug a Port Shall ensure that it
1810 * is the Vconn source.
1811 */
1812 if (port->vconn_role != TYPEC_SOURCE)
1813 return false;
1814 /*
1815 * Power Delivery 2.0 Section 2.4.4
1816 * When no Contract or an Implicit Contract is in place the Source can
1817 * communicate with a Cable Plug using SOP' packets in order to discover
1818 * its characteristics.
1819 *
1820 * Power Delivery 3.0 Section 2.4.4
1821 * When no Contract or an Implicit Contract is in place only the Source
1822 * port that is supplying Vconn is allowed to send packets to a Cable
1823 * Plug and is allowed to respond to packets from the Cable Plug.
1824 */
1825 if (!port->explicit_contract)
1826 return port->pwr_role == TYPEC_SOURCE;
1827 if (port->negotiated_rev == PD_REV30)
1828 return true;
1829 /*
1830 * Power Delivery 2.0 Section 2.4.4
1831 *
1832 * When an Explicit Contract is in place the DFP (either the Source or
1833 * the Sink) can communicate with the Cable Plug(s) using SOP’/SOP”
1834 * Packets (see Figure 2-3).
1835 */
1836 if (port->negotiated_rev == PD_REV20)
1837 return port->data_role == TYPEC_HOST;
1838 return false;
1839 }
1840
tcpm_attempt_vconn_swap_discovery(struct tcpm_port * port)1841 static bool tcpm_attempt_vconn_swap_discovery(struct tcpm_port *port)
1842 {
1843 if (!port->tcpc->attempt_vconn_swap_discovery)
1844 return false;
1845
1846 /* Port is already source, no need to perform swap */
1847 if (port->vconn_role == TYPEC_SOURCE)
1848 return false;
1849
1850 /*
1851 * Partner needs to support Alternate Modes with modal support. If
1852 * partner is also capable of being a USB Host, it could be a device
1853 * that supports Alternate Modes as the DFP.
1854 */
1855 if (!supports_modal(port) || supports_host(port))
1856 return false;
1857
1858 if ((port->negotiated_rev == PD_REV20 && port->data_role == TYPEC_HOST) ||
1859 port->negotiated_rev == PD_REV30)
1860 return port->tcpc->attempt_vconn_swap_discovery(port->tcpc);
1861
1862 return false;
1863 }
1864
1865
tcpm_cable_vdm_supported(struct tcpm_port * port)1866 static bool tcpm_cable_vdm_supported(struct tcpm_port *port)
1867 {
1868 return !IS_ERR_OR_NULL(port->cable) &&
1869 typec_cable_is_active(port->cable) &&
1870 supports_modal_cable(port) &&
1871 tcpm_can_communicate_sop_prime(port);
1872 }
1873
tcpm_pd_svdm(struct tcpm_port * port,struct typec_altmode * adev,const u32 * p,int cnt,u32 * response,enum adev_actions * adev_action,enum tcpm_transmit_type rx_sop_type,enum tcpm_transmit_type * response_tx_sop_type)1874 static int tcpm_pd_svdm(struct tcpm_port *port, struct typec_altmode *adev,
1875 const u32 *p, int cnt, u32 *response,
1876 enum adev_actions *adev_action,
1877 enum tcpm_transmit_type rx_sop_type,
1878 enum tcpm_transmit_type *response_tx_sop_type)
1879 {
1880 struct typec_port *typec = port->typec_port;
1881 struct typec_altmode *pdev, *pdev_prime;
1882 struct pd_mode_data *modep, *modep_prime;
1883 int svdm_version;
1884 int rlen = 0;
1885 int cmd_type;
1886 int cmd;
1887 int i;
1888 int ret;
1889
1890 cmd_type = PD_VDO_CMDT(p[0]);
1891 cmd = PD_VDO_CMD(p[0]);
1892
1893 tcpm_log(port, "Rx VDM cmd 0x%x type %d cmd %d len %d",
1894 p[0], cmd_type, cmd, cnt);
1895
1896 switch (rx_sop_type) {
1897 case TCPC_TX_SOP_PRIME:
1898 modep_prime = &port->mode_data_prime;
1899 pdev_prime = typec_match_altmode(port->plug_prime_altmode,
1900 ALTMODE_DISCOVERY_MAX,
1901 PD_VDO_VID(p[0]),
1902 PD_VDO_OPOS(p[0]));
1903 svdm_version = typec_get_cable_svdm_version(typec);
1904 /*
1905 * Update SVDM version if cable was discovered before port partner.
1906 */
1907 if (!IS_ERR_OR_NULL(port->cable) &&
1908 PD_VDO_SVDM_VER(p[0]) < svdm_version)
1909 typec_cable_set_svdm_version(port->cable, svdm_version);
1910 break;
1911 case TCPC_TX_SOP:
1912 modep = &port->mode_data;
1913 pdev = typec_match_altmode(port->partner_altmode,
1914 ALTMODE_DISCOVERY_MAX,
1915 PD_VDO_VID(p[0]),
1916 PD_VDO_OPOS(p[0]));
1917 svdm_version = typec_get_negotiated_svdm_version(typec);
1918 if (svdm_version < 0)
1919 return 0;
1920 break;
1921 default:
1922 modep = &port->mode_data;
1923 pdev = typec_match_altmode(port->partner_altmode,
1924 ALTMODE_DISCOVERY_MAX,
1925 PD_VDO_VID(p[0]),
1926 PD_VDO_OPOS(p[0]));
1927 svdm_version = typec_get_negotiated_svdm_version(typec);
1928 if (svdm_version < 0)
1929 return 0;
1930 break;
1931 }
1932
1933 switch (cmd_type) {
1934 case CMDT_INIT:
1935 /*
1936 * Only the port or port partner is allowed to initialize SVDM
1937 * commands over SOP'. In case the port partner initializes a
1938 * sequence when it is not allowed to send SOP' messages, drop
1939 * the message should the TCPM port try to process it.
1940 */
1941 if (rx_sop_type == TCPC_TX_SOP_PRIME)
1942 return 0;
1943
1944 switch (cmd) {
1945 case CMD_DISCOVER_IDENT:
1946 if (PD_VDO_VID(p[0]) != USB_SID_PD)
1947 break;
1948
1949 if (IS_ERR_OR_NULL(port->partner))
1950 break;
1951
1952 if (PD_VDO_SVDM_VER(p[0]) < svdm_version) {
1953 typec_partner_set_svdm_version(port->partner,
1954 PD_VDO_SVDM_VER(p[0]));
1955 svdm_version = PD_VDO_SVDM_VER(p[0]);
1956 }
1957
1958 port->ams = DISCOVER_IDENTITY;
1959 /*
1960 * PD2.0 Spec 6.10.3: respond with NAK as DFP (data host)
1961 * PD3.1 Spec 6.4.4.2.5.1: respond with NAK if "invalid field" or
1962 * "wrong configuation" or "Unrecognized"
1963 */
1964 if ((port->data_role == TYPEC_DEVICE || svdm_version >= SVDM_VER_2_0) &&
1965 port->nr_snk_vdo) {
1966 if (svdm_version < SVDM_VER_2_0) {
1967 for (i = 0; i < port->nr_snk_vdo_v1; i++)
1968 response[i + 1] = port->snk_vdo_v1[i];
1969 rlen = port->nr_snk_vdo_v1 + 1;
1970
1971 } else {
1972 for (i = 0; i < port->nr_snk_vdo; i++)
1973 response[i + 1] = port->snk_vdo[i];
1974 rlen = port->nr_snk_vdo + 1;
1975 }
1976 }
1977 break;
1978 case CMD_DISCOVER_SVID:
1979 port->ams = DISCOVER_SVIDS;
1980 break;
1981 case CMD_DISCOVER_MODES:
1982 port->ams = DISCOVER_MODES;
1983 break;
1984 case CMD_ENTER_MODE:
1985 port->ams = DFP_TO_UFP_ENTER_MODE;
1986 break;
1987 case CMD_EXIT_MODE:
1988 port->ams = DFP_TO_UFP_EXIT_MODE;
1989 break;
1990 case CMD_ATTENTION:
1991 /* Attention command does not have response */
1992 *adev_action = ADEV_ATTENTION;
1993 return 0;
1994 default:
1995 break;
1996 }
1997 if (rlen >= 1) {
1998 response[0] = p[0] | VDO_CMDT(CMDT_RSP_ACK);
1999 } else if (rlen == 0) {
2000 response[0] = p[0] | VDO_CMDT(CMDT_RSP_NAK);
2001 rlen = 1;
2002 } else {
2003 response[0] = p[0] | VDO_CMDT(CMDT_RSP_BUSY);
2004 rlen = 1;
2005 }
2006 response[0] = (response[0] & ~VDO_SVDM_VERS_MASK) |
2007 (VDO_SVDM_VERS(typec_get_negotiated_svdm_version(typec)));
2008 break;
2009 case CMDT_RSP_ACK:
2010 /*
2011 * Silently drop message if we are not connected, but can process
2012 * if SOP' Discover Identity prior to explicit contract.
2013 */
2014 if (IS_ERR_OR_NULL(port->partner) &&
2015 !(rx_sop_type == TCPC_TX_SOP_PRIME && cmd == CMD_DISCOVER_IDENT))
2016 break;
2017
2018 tcpm_ams_finish(port);
2019
2020 switch (cmd) {
2021 /*
2022 * SVDM Command Flow for SOP and SOP':
2023 * SOP Discover Identity
2024 * SOP' Discover Identity
2025 * SOP Discover SVIDs
2026 * Discover Modes
2027 * (Active Cables)
2028 * SOP' Discover SVIDs
2029 * Discover Modes
2030 *
2031 * Perform Discover SOP' if the port can communicate with cable
2032 * plug.
2033 */
2034 case CMD_DISCOVER_IDENT:
2035 switch (rx_sop_type) {
2036 case TCPC_TX_SOP:
2037 if (PD_VDO_SVDM_VER(p[0]) < svdm_version) {
2038 typec_partner_set_svdm_version(port->partner,
2039 PD_VDO_SVDM_VER(p[0]));
2040 /* If cable is discovered before partner, downgrade svdm */
2041 if (!IS_ERR_OR_NULL(port->cable) &&
2042 (typec_get_cable_svdm_version(port->typec_port) >
2043 svdm_version))
2044 typec_cable_set_svdm_version(port->cable,
2045 svdm_version);
2046 }
2047 /* 6.4.4.3.1 */
2048 svdm_consume_identity(port, p, cnt);
2049 /* Attempt Vconn swap, delay SOP' discovery if necessary */
2050 if (tcpm_attempt_vconn_swap_discovery(port)) {
2051 port->send_discover_prime = true;
2052 port->upcoming_state = VCONN_SWAP_SEND;
2053 ret = tcpm_ams_start(port, VCONN_SWAP);
2054 if (!ret)
2055 return 0;
2056 /* Cannot perform Vconn swap */
2057 port->upcoming_state = INVALID_STATE;
2058 port->send_discover_prime = false;
2059 }
2060
2061 /*
2062 * Attempt Discover Identity on SOP' if the
2063 * cable was not discovered previously, and use
2064 * the SVDM version of the partner to probe.
2065 */
2066 if (IS_ERR_OR_NULL(port->cable) &&
2067 tcpm_can_communicate_sop_prime(port)) {
2068 *response_tx_sop_type = TCPC_TX_SOP_PRIME;
2069 port->send_discover_prime = true;
2070 response[0] = VDO(USB_SID_PD, 1,
2071 typec_get_negotiated_svdm_version(typec),
2072 CMD_DISCOVER_IDENT);
2073 rlen = 1;
2074 } else {
2075 *response_tx_sop_type = TCPC_TX_SOP;
2076 response[0] = VDO(USB_SID_PD, 1,
2077 typec_get_negotiated_svdm_version(typec),
2078 CMD_DISCOVER_SVID);
2079 rlen = 1;
2080 }
2081 break;
2082 case TCPC_TX_SOP_PRIME:
2083 /*
2084 * svdm_consume_identity_sop_prime will determine
2085 * the svdm_version for the cable moving forward.
2086 */
2087 svdm_consume_identity_sop_prime(port, p, cnt);
2088
2089 /*
2090 * If received in SRC_VDM_IDENTITY_REQUEST, continue
2091 * to SRC_SEND_CAPABILITIES
2092 */
2093 if (port->state == SRC_VDM_IDENTITY_REQUEST) {
2094 tcpm_set_state(port, SRC_SEND_CAPABILITIES, 0);
2095 return 0;
2096 }
2097
2098 *response_tx_sop_type = TCPC_TX_SOP;
2099 response[0] = VDO(USB_SID_PD, 1,
2100 typec_get_negotiated_svdm_version(typec),
2101 CMD_DISCOVER_SVID);
2102 rlen = 1;
2103 break;
2104 default:
2105 return 0;
2106 }
2107 break;
2108 case CMD_DISCOVER_SVID:
2109 *response_tx_sop_type = rx_sop_type;
2110 /* 6.4.4.3.2 */
2111 if (svdm_consume_svids(port, p, cnt, rx_sop_type)) {
2112 response[0] = VDO(USB_SID_PD, 1, svdm_version, CMD_DISCOVER_SVID);
2113 rlen = 1;
2114 } else {
2115 if (rx_sop_type == TCPC_TX_SOP) {
2116 if (modep->nsvids && supports_modal(port)) {
2117 response[0] = VDO(modep->svids[0], 1, svdm_version,
2118 CMD_DISCOVER_MODES);
2119 rlen = 1;
2120 }
2121 } else if (rx_sop_type == TCPC_TX_SOP_PRIME) {
2122 if (modep_prime->nsvids) {
2123 response[0] = VDO(modep_prime->svids[0], 1,
2124 svdm_version, CMD_DISCOVER_MODES);
2125 rlen = 1;
2126 }
2127 }
2128 }
2129 break;
2130 case CMD_DISCOVER_MODES:
2131 if (rx_sop_type == TCPC_TX_SOP) {
2132 /* 6.4.4.3.3 */
2133 svdm_consume_modes(port, p, cnt, rx_sop_type);
2134 modep->svid_index++;
2135 if (modep->svid_index < modep->nsvids) {
2136 u16 svid = modep->svids[modep->svid_index];
2137 *response_tx_sop_type = TCPC_TX_SOP;
2138 response[0] = VDO(svid, 1, svdm_version,
2139 CMD_DISCOVER_MODES);
2140 rlen = 1;
2141 } else if (tcpm_cable_vdm_supported(port)) {
2142 *response_tx_sop_type = TCPC_TX_SOP_PRIME;
2143 response[0] = VDO(USB_SID_PD, 1,
2144 typec_get_cable_svdm_version(typec),
2145 CMD_DISCOVER_SVID);
2146 rlen = 1;
2147 } else {
2148 tcpm_register_partner_altmodes(port);
2149 }
2150 } else if (rx_sop_type == TCPC_TX_SOP_PRIME) {
2151 /* 6.4.4.3.3 */
2152 svdm_consume_modes(port, p, cnt, rx_sop_type);
2153 modep_prime->svid_index++;
2154 if (modep_prime->svid_index < modep_prime->nsvids) {
2155 u16 svid = modep_prime->svids[modep_prime->svid_index];
2156 *response_tx_sop_type = TCPC_TX_SOP_PRIME;
2157 response[0] = VDO(svid, 1,
2158 typec_get_cable_svdm_version(typec),
2159 CMD_DISCOVER_MODES);
2160 rlen = 1;
2161 } else {
2162 tcpm_register_plug_altmodes(port);
2163 tcpm_register_partner_altmodes(port);
2164 }
2165 }
2166 break;
2167 case CMD_ENTER_MODE:
2168 *response_tx_sop_type = rx_sop_type;
2169 if (rx_sop_type == TCPC_TX_SOP) {
2170 if (adev && pdev) {
2171 typec_altmode_update_active(pdev, true);
2172 *adev_action = ADEV_QUEUE_VDM_SEND_EXIT_MODE_ON_FAIL;
2173 }
2174 } else if (rx_sop_type == TCPC_TX_SOP_PRIME) {
2175 if (adev && pdev_prime) {
2176 typec_altmode_update_active(pdev_prime, true);
2177 *adev_action = ADEV_QUEUE_VDM_SEND_EXIT_MODE_ON_FAIL;
2178 }
2179 }
2180 return 0;
2181 case CMD_EXIT_MODE:
2182 *response_tx_sop_type = rx_sop_type;
2183 if (rx_sop_type == TCPC_TX_SOP) {
2184 if (adev && pdev) {
2185 typec_altmode_update_active(pdev, false);
2186 /* Back to USB Operation */
2187 *adev_action = ADEV_NOTIFY_USB_AND_QUEUE_VDM;
2188 return 0;
2189 }
2190 }
2191 break;
2192 case VDO_CMD_VENDOR(0) ... VDO_CMD_VENDOR(15):
2193 break;
2194 default:
2195 /* Unrecognized SVDM */
2196 response[0] = p[0] | VDO_CMDT(CMDT_RSP_NAK);
2197 rlen = 1;
2198 response[0] = (response[0] & ~VDO_SVDM_VERS_MASK) |
2199 (VDO_SVDM_VERS(svdm_version));
2200 break;
2201 }
2202 break;
2203 case CMDT_RSP_NAK:
2204 tcpm_ams_finish(port);
2205 switch (cmd) {
2206 case CMD_DISCOVER_IDENT:
2207 case CMD_DISCOVER_SVID:
2208 case CMD_DISCOVER_MODES:
2209 case VDO_CMD_VENDOR(0) ... VDO_CMD_VENDOR(15):
2210 break;
2211 case CMD_ENTER_MODE:
2212 /* Back to USB Operation */
2213 *adev_action = ADEV_NOTIFY_USB_AND_QUEUE_VDM;
2214 return 0;
2215 default:
2216 /* Unrecognized SVDM */
2217 response[0] = p[0] | VDO_CMDT(CMDT_RSP_NAK);
2218 rlen = 1;
2219 response[0] = (response[0] & ~VDO_SVDM_VERS_MASK) |
2220 (VDO_SVDM_VERS(svdm_version));
2221 break;
2222 }
2223 break;
2224 default:
2225 response[0] = p[0] | VDO_CMDT(CMDT_RSP_NAK);
2226 rlen = 1;
2227 response[0] = (response[0] & ~VDO_SVDM_VERS_MASK) |
2228 (VDO_SVDM_VERS(svdm_version));
2229 break;
2230 }
2231
2232 /* Informing the alternate mode drivers about everything */
2233 *adev_action = ADEV_QUEUE_VDM;
2234 return rlen;
2235 }
2236
2237 static void tcpm_pd_handle_msg(struct tcpm_port *port,
2238 enum pd_msg_request message,
2239 enum tcpm_ams ams);
2240
tcpm_handle_vdm_request(struct tcpm_port * port,const __le32 * payload,int cnt,enum tcpm_transmit_type rx_sop_type)2241 static void tcpm_handle_vdm_request(struct tcpm_port *port,
2242 const __le32 *payload, int cnt,
2243 enum tcpm_transmit_type rx_sop_type)
2244 {
2245 enum adev_actions adev_action = ADEV_NONE;
2246 struct typec_altmode *adev;
2247 u32 p[PD_MAX_PAYLOAD];
2248 u32 response[8] = { };
2249 int i, rlen = 0;
2250 enum tcpm_transmit_type response_tx_sop_type = TCPC_TX_SOP;
2251
2252 for (i = 0; i < cnt; i++)
2253 p[i] = le32_to_cpu(payload[i]);
2254
2255 adev = typec_match_altmode(port->port_altmode, ALTMODE_DISCOVERY_MAX,
2256 PD_VDO_VID(p[0]), PD_VDO_OPOS(p[0]));
2257
2258 if (port->vdm_state == VDM_STATE_BUSY) {
2259 /* If UFP responded busy retry after timeout */
2260 if (PD_VDO_CMDT(p[0]) == CMDT_RSP_BUSY) {
2261 port->vdm_state = VDM_STATE_WAIT_RSP_BUSY;
2262 port->vdo_retry = (p[0] & ~VDO_CMDT_MASK) |
2263 CMDT_INIT;
2264 mod_vdm_delayed_work(port, PD_T_VDM_BUSY);
2265 return;
2266 }
2267 port->vdm_state = VDM_STATE_DONE;
2268 }
2269
2270 if (PD_VDO_SVDM(p[0]) && (adev || tcpm_vdm_ams(port) || port->nr_snk_vdo)) {
2271 /*
2272 * Here a SVDM is received (INIT or RSP or unknown). Set the vdm_sm_running in
2273 * advance because we are dropping the lock but may send VDMs soon.
2274 * For the cases of INIT received:
2275 * - If no response to send, it will be cleared later in this function.
2276 * - If there are responses to send, it will be cleared in the state machine.
2277 * For the cases of RSP received:
2278 * - If no further INIT to send, it will be cleared later in this function.
2279 * - Otherwise, it will be cleared in the state machine if timeout or it will go
2280 * back here until no further INIT to send.
2281 * For the cases of unknown type received:
2282 * - We will send NAK and the flag will be cleared in the state machine.
2283 */
2284 port->vdm_sm_running = true;
2285 rlen = tcpm_pd_svdm(port, adev, p, cnt, response, &adev_action,
2286 rx_sop_type, &response_tx_sop_type);
2287 } else {
2288 if (port->negotiated_rev >= PD_REV30)
2289 tcpm_pd_handle_msg(port, PD_MSG_CTRL_NOT_SUPP, NONE_AMS);
2290 }
2291
2292 /*
2293 * We are done with any state stored in the port struct now, except
2294 * for any port struct changes done by the tcpm_queue_vdm() call
2295 * below, which is a separate operation.
2296 *
2297 * So we can safely release the lock here; and we MUST release the
2298 * lock here to avoid an AB BA lock inversion:
2299 *
2300 * If we keep the lock here then the lock ordering in this path is:
2301 * 1. tcpm_pd_rx_handler take the tcpm port lock
2302 * 2. One of the typec_altmode_* calls below takes the alt-mode's lock
2303 *
2304 * And we also have this ordering:
2305 * 1. alt-mode driver takes the alt-mode's lock
2306 * 2. alt-mode driver calls tcpm_altmode_enter which takes the
2307 * tcpm port lock
2308 *
2309 * Dropping our lock here avoids this.
2310 */
2311 mutex_unlock(&port->lock);
2312
2313 if (adev) {
2314 switch (adev_action) {
2315 case ADEV_NONE:
2316 break;
2317 case ADEV_NOTIFY_USB_AND_QUEUE_VDM:
2318 WARN_ON(typec_altmode_notify(adev, TYPEC_STATE_USB, NULL));
2319 typec_altmode_vdm(adev, p[0], &p[1], cnt);
2320 break;
2321 case ADEV_QUEUE_VDM:
2322 if (response_tx_sop_type == TCPC_TX_SOP_PRIME)
2323 typec_cable_altmode_vdm(adev, TYPEC_PLUG_SOP_P, p[0], &p[1], cnt);
2324 else
2325 typec_altmode_vdm(adev, p[0], &p[1], cnt);
2326 break;
2327 case ADEV_QUEUE_VDM_SEND_EXIT_MODE_ON_FAIL:
2328 if (response_tx_sop_type == TCPC_TX_SOP_PRIME) {
2329 if (typec_cable_altmode_vdm(adev, TYPEC_PLUG_SOP_P,
2330 p[0], &p[1], cnt)) {
2331 int svdm_version = typec_get_cable_svdm_version(
2332 port->typec_port);
2333 if (svdm_version < 0)
2334 break;
2335
2336 response[0] = VDO(adev->svid, 1, svdm_version,
2337 CMD_EXIT_MODE);
2338 response[0] |= VDO_OPOS(adev->mode);
2339 rlen = 1;
2340 }
2341 } else {
2342 if (typec_altmode_vdm(adev, p[0], &p[1], cnt)) {
2343 int svdm_version = typec_get_negotiated_svdm_version(
2344 port->typec_port);
2345 if (svdm_version < 0)
2346 break;
2347
2348 response[0] = VDO(adev->svid, 1, svdm_version,
2349 CMD_EXIT_MODE);
2350 response[0] |= VDO_OPOS(adev->mode);
2351 rlen = 1;
2352 }
2353 }
2354 break;
2355 case ADEV_ATTENTION:
2356 if (typec_altmode_attention(adev, p[1]))
2357 tcpm_log(port, "typec_altmode_attention no port partner altmode");
2358 break;
2359 }
2360 }
2361
2362 /*
2363 * We must re-take the lock here to balance the unlock in
2364 * tcpm_pd_rx_handler, note that no changes, other then the
2365 * tcpm_queue_vdm call, are made while the lock is held again.
2366 * All that is done after the call is unwinding the call stack until
2367 * we return to tcpm_pd_rx_handler and do the unlock there.
2368 */
2369 mutex_lock(&port->lock);
2370
2371 if (rlen > 0)
2372 tcpm_queue_vdm(port, response[0], &response[1], rlen - 1, response_tx_sop_type);
2373 else
2374 port->vdm_sm_running = false;
2375 }
2376
tcpm_send_vdm(struct tcpm_port * port,u32 vid,int cmd,const u32 * data,int count,enum tcpm_transmit_type tx_sop_type)2377 static void tcpm_send_vdm(struct tcpm_port *port, u32 vid, int cmd,
2378 const u32 *data, int count, enum tcpm_transmit_type tx_sop_type)
2379 {
2380 int svdm_version;
2381 u32 header;
2382
2383 switch (tx_sop_type) {
2384 case TCPC_TX_SOP_PRIME:
2385 /*
2386 * If the port partner is discovered, then the port partner's
2387 * SVDM Version will be returned
2388 */
2389 svdm_version = typec_get_cable_svdm_version(port->typec_port);
2390 if (svdm_version < 0)
2391 svdm_version = SVDM_VER_MAX;
2392 break;
2393 case TCPC_TX_SOP:
2394 svdm_version = typec_get_negotiated_svdm_version(port->typec_port);
2395 if (svdm_version < 0)
2396 return;
2397 break;
2398 default:
2399 svdm_version = typec_get_negotiated_svdm_version(port->typec_port);
2400 if (svdm_version < 0)
2401 return;
2402 break;
2403 }
2404
2405 if (WARN_ON(count > VDO_MAX_SIZE - 1))
2406 count = VDO_MAX_SIZE - 1;
2407
2408 /* set VDM header with VID & CMD */
2409 header = VDO(vid, ((vid & USB_SID_PD) == USB_SID_PD) ?
2410 1 : (PD_VDO_CMD(cmd) <= CMD_ATTENTION),
2411 svdm_version, cmd);
2412 tcpm_queue_vdm(port, header, data, count, tx_sop_type);
2413 }
2414
vdm_ready_timeout(u32 vdm_hdr)2415 static unsigned int vdm_ready_timeout(u32 vdm_hdr)
2416 {
2417 unsigned int timeout;
2418 int cmd = PD_VDO_CMD(vdm_hdr);
2419
2420 /* its not a structured VDM command */
2421 if (!PD_VDO_SVDM(vdm_hdr))
2422 return PD_T_VDM_UNSTRUCTURED;
2423
2424 switch (PD_VDO_CMDT(vdm_hdr)) {
2425 case CMDT_INIT:
2426 if (cmd == CMD_ENTER_MODE || cmd == CMD_EXIT_MODE)
2427 timeout = PD_T_VDM_WAIT_MODE_E;
2428 else
2429 timeout = PD_T_VDM_SNDR_RSP;
2430 break;
2431 default:
2432 if (cmd == CMD_ENTER_MODE || cmd == CMD_EXIT_MODE)
2433 timeout = PD_T_VDM_E_MODE;
2434 else
2435 timeout = PD_T_VDM_RCVR_RSP;
2436 break;
2437 }
2438 return timeout;
2439 }
2440
vdm_run_state_machine(struct tcpm_port * port)2441 static void vdm_run_state_machine(struct tcpm_port *port)
2442 {
2443 struct pd_message msg;
2444 int i, res = 0;
2445 u32 vdo_hdr = port->vdo_data[0];
2446 u32 response[8] = { };
2447
2448 switch (port->vdm_state) {
2449 case VDM_STATE_READY:
2450 /* Only transmit VDM if attached */
2451 if (!port->attached) {
2452 port->vdm_state = VDM_STATE_ERR_BUSY;
2453 break;
2454 }
2455
2456 /*
2457 * if there's traffic or we're not in PDO ready state don't send
2458 * a VDM.
2459 */
2460 if (port->state != SRC_READY && port->state != SNK_READY &&
2461 port->state != SRC_VDM_IDENTITY_REQUEST) {
2462 port->vdm_sm_running = false;
2463 break;
2464 }
2465
2466 /* TODO: AMS operation for Unstructured VDM */
2467 if (PD_VDO_SVDM(vdo_hdr) && PD_VDO_CMDT(vdo_hdr) == CMDT_INIT) {
2468 switch (PD_VDO_CMD(vdo_hdr)) {
2469 case CMD_DISCOVER_IDENT:
2470 res = tcpm_ams_start(port, DISCOVER_IDENTITY);
2471 if (res == 0) {
2472 switch (port->tx_sop_type) {
2473 case TCPC_TX_SOP_PRIME:
2474 port->send_discover_prime = false;
2475 break;
2476 case TCPC_TX_SOP:
2477 port->send_discover = false;
2478 break;
2479 default:
2480 port->send_discover = false;
2481 break;
2482 }
2483 } else if (res == -EAGAIN) {
2484 port->vdo_data[0] = 0;
2485 mod_send_discover_delayed_work(port,
2486 SEND_DISCOVER_RETRY_MS);
2487 }
2488 break;
2489 case CMD_DISCOVER_SVID:
2490 res = tcpm_ams_start(port, DISCOVER_SVIDS);
2491 break;
2492 case CMD_DISCOVER_MODES:
2493 res = tcpm_ams_start(port, DISCOVER_MODES);
2494 break;
2495 case CMD_ENTER_MODE:
2496 res = tcpm_ams_start(port, DFP_TO_UFP_ENTER_MODE);
2497 break;
2498 case CMD_EXIT_MODE:
2499 res = tcpm_ams_start(port, DFP_TO_UFP_EXIT_MODE);
2500 break;
2501 case CMD_ATTENTION:
2502 res = tcpm_ams_start(port, ATTENTION);
2503 break;
2504 case VDO_CMD_VENDOR(0) ... VDO_CMD_VENDOR(15):
2505 res = tcpm_ams_start(port, STRUCTURED_VDMS);
2506 break;
2507 default:
2508 res = -EOPNOTSUPP;
2509 break;
2510 }
2511
2512 if (res < 0) {
2513 port->vdm_state = VDM_STATE_ERR_BUSY;
2514 return;
2515 }
2516 }
2517
2518 port->vdm_state = VDM_STATE_SEND_MESSAGE;
2519 mod_vdm_delayed_work(port, (port->negotiated_rev >= PD_REV30 &&
2520 port->pwr_role == TYPEC_SOURCE &&
2521 PD_VDO_SVDM(vdo_hdr) &&
2522 PD_VDO_CMDT(vdo_hdr) == CMDT_INIT) ?
2523 PD_T_SINK_TX : 0);
2524 break;
2525 case VDM_STATE_WAIT_RSP_BUSY:
2526 port->vdo_data[0] = port->vdo_retry;
2527 port->vdo_count = 1;
2528 port->vdm_state = VDM_STATE_READY;
2529 tcpm_ams_finish(port);
2530 break;
2531 case VDM_STATE_BUSY:
2532 port->vdm_state = VDM_STATE_ERR_TMOUT;
2533 if (port->ams != NONE_AMS)
2534 tcpm_ams_finish(port);
2535 break;
2536 case VDM_STATE_ERR_SEND:
2537 /*
2538 * When sending Discover Identity to SOP' before establishing an
2539 * explicit contract, do not retry. Instead, weave sending
2540 * Source_Capabilities over SOP and Discover Identity over SOP'.
2541 */
2542 if (port->state == SRC_VDM_IDENTITY_REQUEST) {
2543 tcpm_ams_finish(port);
2544 port->vdm_state = VDM_STATE_DONE;
2545 tcpm_set_state(port, SRC_SEND_CAPABILITIES, 0);
2546 /*
2547 * A partner which does not support USB PD will not reply,
2548 * so this is not a fatal error. At the same time, some
2549 * devices may not return GoodCRC under some circumstances,
2550 * so we need to retry.
2551 */
2552 } else if (port->vdm_retries < 3) {
2553 tcpm_log(port, "VDM Tx error, retry");
2554 port->vdm_retries++;
2555 port->vdm_state = VDM_STATE_READY;
2556 if (PD_VDO_SVDM(vdo_hdr) && PD_VDO_CMDT(vdo_hdr) == CMDT_INIT)
2557 tcpm_ams_finish(port);
2558 } else {
2559 tcpm_ams_finish(port);
2560 if (port->tx_sop_type == TCPC_TX_SOP)
2561 break;
2562 /* Handle SOP' Transmission Errors */
2563 switch (PD_VDO_CMD(vdo_hdr)) {
2564 /*
2565 * If Discover Identity fails on SOP', then resume
2566 * discovery process on SOP only.
2567 */
2568 case CMD_DISCOVER_IDENT:
2569 port->vdo_data[0] = 0;
2570 response[0] = VDO(USB_SID_PD, 1,
2571 typec_get_negotiated_svdm_version(
2572 port->typec_port),
2573 CMD_DISCOVER_SVID);
2574 tcpm_queue_vdm(port, response[0], &response[1],
2575 0, TCPC_TX_SOP);
2576 break;
2577 /*
2578 * If Discover SVIDs or Discover Modes fail, then
2579 * proceed with Alt Mode discovery process on SOP.
2580 */
2581 case CMD_DISCOVER_SVID:
2582 tcpm_register_partner_altmodes(port);
2583 break;
2584 case CMD_DISCOVER_MODES:
2585 tcpm_register_partner_altmodes(port);
2586 break;
2587 default:
2588 break;
2589 }
2590 }
2591 break;
2592 case VDM_STATE_SEND_MESSAGE:
2593 /* Prepare and send VDM */
2594 memset(&msg, 0, sizeof(msg));
2595 if (port->tx_sop_type == TCPC_TX_SOP_PRIME) {
2596 msg.header = PD_HEADER_LE(PD_DATA_VENDOR_DEF,
2597 0, /* Cable Plug Indicator for DFP/UFP */
2598 0, /* Reserved */
2599 port->negotiated_rev_prime,
2600 port->message_id_prime,
2601 port->vdo_count);
2602 } else {
2603 msg.header = PD_HEADER_LE(PD_DATA_VENDOR_DEF,
2604 port->pwr_role,
2605 port->data_role,
2606 port->negotiated_rev,
2607 port->message_id,
2608 port->vdo_count);
2609 }
2610 for (i = 0; i < port->vdo_count; i++)
2611 msg.payload[i] = cpu_to_le32(port->vdo_data[i]);
2612 res = tcpm_pd_transmit(port, port->tx_sop_type, &msg);
2613 if (res < 0) {
2614 port->vdm_state = VDM_STATE_ERR_SEND;
2615 } else {
2616 unsigned long timeout;
2617
2618 port->vdm_retries = 0;
2619 port->vdo_data[0] = 0;
2620 port->vdm_state = VDM_STATE_BUSY;
2621 timeout = vdm_ready_timeout(vdo_hdr);
2622 mod_vdm_delayed_work(port, timeout);
2623 }
2624 break;
2625 default:
2626 break;
2627 }
2628 }
2629
vdm_state_machine_work(struct kthread_work * work)2630 static void vdm_state_machine_work(struct kthread_work *work)
2631 {
2632 struct tcpm_port *port = container_of(work, struct tcpm_port, vdm_state_machine);
2633 enum vdm_states prev_state;
2634
2635 mutex_lock(&port->lock);
2636
2637 /*
2638 * Continue running as long as the port is not busy and there was
2639 * a state change.
2640 */
2641 do {
2642 prev_state = port->vdm_state;
2643 vdm_run_state_machine(port);
2644 } while (port->vdm_state != prev_state &&
2645 port->vdm_state != VDM_STATE_BUSY &&
2646 port->vdm_state != VDM_STATE_SEND_MESSAGE);
2647
2648 if (port->vdm_state < VDM_STATE_READY)
2649 port->vdm_sm_running = false;
2650
2651 mutex_unlock(&port->lock);
2652 }
2653
2654 enum pdo_err {
2655 PDO_NO_ERR,
2656 PDO_ERR_NO_VSAFE5V,
2657 PDO_ERR_VSAFE5V_NOT_FIRST,
2658 PDO_ERR_PDO_TYPE_NOT_IN_ORDER,
2659 PDO_ERR_FIXED_NOT_SORTED,
2660 PDO_ERR_VARIABLE_BATT_NOT_SORTED,
2661 PDO_ERR_DUPE_PDO,
2662 PDO_ERR_PPS_APDO_NOT_SORTED,
2663 PDO_ERR_DUPE_PPS_APDO,
2664 };
2665
2666 static const char * const pdo_err_msg[] = {
2667 [PDO_ERR_NO_VSAFE5V] =
2668 " err: source/sink caps should at least have vSafe5V",
2669 [PDO_ERR_VSAFE5V_NOT_FIRST] =
2670 " err: vSafe5V Fixed Supply Object Shall always be the first object",
2671 [PDO_ERR_PDO_TYPE_NOT_IN_ORDER] =
2672 " err: PDOs should be in the following order: Fixed; Battery; Variable",
2673 [PDO_ERR_FIXED_NOT_SORTED] =
2674 " err: Fixed supply pdos should be in increasing order of their fixed voltage",
2675 [PDO_ERR_VARIABLE_BATT_NOT_SORTED] =
2676 " err: Variable/Battery supply pdos should be in increasing order of their minimum voltage",
2677 [PDO_ERR_DUPE_PDO] =
2678 " err: Variable/Batt supply pdos cannot have same min/max voltage",
2679 [PDO_ERR_PPS_APDO_NOT_SORTED] =
2680 " err: Programmable power supply apdos should be in increasing order of their maximum voltage",
2681 [PDO_ERR_DUPE_PPS_APDO] =
2682 " err: Programmable power supply apdos cannot have same min/max voltage and max current",
2683 };
2684
tcpm_caps_err(struct tcpm_port * port,const u32 * pdo,unsigned int nr_pdo)2685 static enum pdo_err tcpm_caps_err(struct tcpm_port *port, const u32 *pdo,
2686 unsigned int nr_pdo)
2687 {
2688 unsigned int i;
2689
2690 /* Should at least contain vSafe5v */
2691 if (nr_pdo < 1)
2692 return PDO_ERR_NO_VSAFE5V;
2693
2694 /* The vSafe5V Fixed Supply Object Shall always be the first object */
2695 if (pdo_type(pdo[0]) != PDO_TYPE_FIXED ||
2696 pdo_fixed_voltage(pdo[0]) != VSAFE5V)
2697 return PDO_ERR_VSAFE5V_NOT_FIRST;
2698
2699 for (i = 1; i < nr_pdo; i++) {
2700 if (pdo_type(pdo[i]) < pdo_type(pdo[i - 1])) {
2701 return PDO_ERR_PDO_TYPE_NOT_IN_ORDER;
2702 } else if (pdo_type(pdo[i]) == pdo_type(pdo[i - 1])) {
2703 enum pd_pdo_type type = pdo_type(pdo[i]);
2704
2705 switch (type) {
2706 /*
2707 * The remaining Fixed Supply Objects, if
2708 * present, shall be sent in voltage order;
2709 * lowest to highest.
2710 */
2711 case PDO_TYPE_FIXED:
2712 if (pdo_fixed_voltage(pdo[i]) <=
2713 pdo_fixed_voltage(pdo[i - 1]))
2714 return PDO_ERR_FIXED_NOT_SORTED;
2715 break;
2716 /*
2717 * The Battery Supply Objects and Variable
2718 * supply, if present shall be sent in Minimum
2719 * Voltage order; lowest to highest.
2720 */
2721 case PDO_TYPE_VAR:
2722 case PDO_TYPE_BATT:
2723 if (pdo_min_voltage(pdo[i]) <
2724 pdo_min_voltage(pdo[i - 1]))
2725 return PDO_ERR_VARIABLE_BATT_NOT_SORTED;
2726 else if ((pdo_min_voltage(pdo[i]) ==
2727 pdo_min_voltage(pdo[i - 1])) &&
2728 (pdo_max_voltage(pdo[i]) ==
2729 pdo_max_voltage(pdo[i - 1])))
2730 return PDO_ERR_DUPE_PDO;
2731 break;
2732 /*
2733 * The Programmable Power Supply APDOs, if present,
2734 * shall be sent in Maximum Voltage order;
2735 * lowest to highest.
2736 */
2737 case PDO_TYPE_APDO:
2738 if (pdo_apdo_type(pdo[i]) != APDO_TYPE_PPS)
2739 break;
2740
2741 if (pdo_pps_apdo_max_voltage(pdo[i]) <
2742 pdo_pps_apdo_max_voltage(pdo[i - 1]))
2743 return PDO_ERR_PPS_APDO_NOT_SORTED;
2744 else if (pdo_pps_apdo_min_voltage(pdo[i]) ==
2745 pdo_pps_apdo_min_voltage(pdo[i - 1]) &&
2746 pdo_pps_apdo_max_voltage(pdo[i]) ==
2747 pdo_pps_apdo_max_voltage(pdo[i - 1]) &&
2748 pdo_pps_apdo_max_current(pdo[i]) ==
2749 pdo_pps_apdo_max_current(pdo[i - 1]))
2750 return PDO_ERR_DUPE_PPS_APDO;
2751 break;
2752 default:
2753 tcpm_log_force(port, " Unknown pdo type");
2754 }
2755 }
2756 }
2757
2758 return PDO_NO_ERR;
2759 }
2760
tcpm_validate_caps(struct tcpm_port * port,const u32 * pdo,unsigned int nr_pdo)2761 static int tcpm_validate_caps(struct tcpm_port *port, const u32 *pdo,
2762 unsigned int nr_pdo)
2763 {
2764 enum pdo_err err_index = tcpm_caps_err(port, pdo, nr_pdo);
2765
2766 if (err_index != PDO_NO_ERR) {
2767 tcpm_log_force(port, " %s", pdo_err_msg[err_index]);
2768 return -EINVAL;
2769 }
2770
2771 return 0;
2772 }
2773
tcpm_altmode_enter(struct typec_altmode * altmode,u32 * vdo)2774 static int tcpm_altmode_enter(struct typec_altmode *altmode, u32 *vdo)
2775 {
2776 struct tcpm_port *port = typec_altmode_get_drvdata(altmode);
2777 int svdm_version;
2778 u32 header;
2779
2780 svdm_version = typec_get_negotiated_svdm_version(port->typec_port);
2781 if (svdm_version < 0)
2782 return svdm_version;
2783
2784 header = VDO(altmode->svid, vdo ? 2 : 1, svdm_version, CMD_ENTER_MODE);
2785 header |= VDO_OPOS(altmode->mode);
2786
2787 tcpm_queue_vdm_unlocked(port, header, vdo, vdo ? 1 : 0, TCPC_TX_SOP);
2788 return 0;
2789 }
2790
tcpm_altmode_exit(struct typec_altmode * altmode)2791 static int tcpm_altmode_exit(struct typec_altmode *altmode)
2792 {
2793 struct tcpm_port *port = typec_altmode_get_drvdata(altmode);
2794 int svdm_version;
2795 u32 header;
2796
2797 svdm_version = typec_get_negotiated_svdm_version(port->typec_port);
2798 if (svdm_version < 0)
2799 return svdm_version;
2800
2801 header = VDO(altmode->svid, 1, svdm_version, CMD_EXIT_MODE);
2802 header |= VDO_OPOS(altmode->mode);
2803
2804 tcpm_queue_vdm_unlocked(port, header, NULL, 0, TCPC_TX_SOP);
2805 return 0;
2806 }
2807
tcpm_altmode_vdm(struct typec_altmode * altmode,u32 header,const u32 * data,int count)2808 static int tcpm_altmode_vdm(struct typec_altmode *altmode,
2809 u32 header, const u32 *data, int count)
2810 {
2811 struct tcpm_port *port = typec_altmode_get_drvdata(altmode);
2812
2813 tcpm_queue_vdm_unlocked(port, header, data, count - 1, TCPC_TX_SOP);
2814
2815 return 0;
2816 }
2817
2818 static const struct typec_altmode_ops tcpm_altmode_ops = {
2819 .enter = tcpm_altmode_enter,
2820 .exit = tcpm_altmode_exit,
2821 .vdm = tcpm_altmode_vdm,
2822 };
2823
2824
tcpm_cable_altmode_enter(struct typec_altmode * altmode,enum typec_plug_index sop,u32 * vdo)2825 static int tcpm_cable_altmode_enter(struct typec_altmode *altmode, enum typec_plug_index sop,
2826 u32 *vdo)
2827 {
2828 struct tcpm_port *port = typec_altmode_get_drvdata(altmode);
2829 int svdm_version;
2830 u32 header;
2831
2832 svdm_version = typec_get_cable_svdm_version(port->typec_port);
2833 if (svdm_version < 0)
2834 return svdm_version;
2835
2836 header = VDO(altmode->svid, vdo ? 2 : 1, svdm_version, CMD_ENTER_MODE);
2837 header |= VDO_OPOS(altmode->mode);
2838
2839 tcpm_queue_vdm_unlocked(port, header, vdo, vdo ? 1 : 0, TCPC_TX_SOP_PRIME);
2840 return 0;
2841 }
2842
tcpm_cable_altmode_exit(struct typec_altmode * altmode,enum typec_plug_index sop)2843 static int tcpm_cable_altmode_exit(struct typec_altmode *altmode, enum typec_plug_index sop)
2844 {
2845 struct tcpm_port *port = typec_altmode_get_drvdata(altmode);
2846 int svdm_version;
2847 u32 header;
2848
2849 svdm_version = typec_get_cable_svdm_version(port->typec_port);
2850 if (svdm_version < 0)
2851 return svdm_version;
2852
2853 header = VDO(altmode->svid, 1, svdm_version, CMD_EXIT_MODE);
2854 header |= VDO_OPOS(altmode->mode);
2855
2856 tcpm_queue_vdm_unlocked(port, header, NULL, 0, TCPC_TX_SOP_PRIME);
2857 return 0;
2858 }
2859
tcpm_cable_altmode_vdm(struct typec_altmode * altmode,enum typec_plug_index sop,u32 header,const u32 * data,int count)2860 static int tcpm_cable_altmode_vdm(struct typec_altmode *altmode, enum typec_plug_index sop,
2861 u32 header, const u32 *data, int count)
2862 {
2863 struct tcpm_port *port = typec_altmode_get_drvdata(altmode);
2864
2865 tcpm_queue_vdm_unlocked(port, header, data, count - 1, TCPC_TX_SOP_PRIME);
2866
2867 return 0;
2868 }
2869
2870 static const struct typec_cable_ops tcpm_cable_ops = {
2871 .enter = tcpm_cable_altmode_enter,
2872 .exit = tcpm_cable_altmode_exit,
2873 .vdm = tcpm_cable_altmode_vdm,
2874 };
2875
2876 /*
2877 * PD (data, control) command handling functions
2878 */
ready_state(struct tcpm_port * port)2879 static inline enum tcpm_state ready_state(struct tcpm_port *port)
2880 {
2881 if (port->pwr_role == TYPEC_SOURCE)
2882 return SRC_READY;
2883 else
2884 return SNK_READY;
2885 }
2886
2887 static int tcpm_pd_send_control(struct tcpm_port *port,
2888 enum pd_ctrl_msg_type type,
2889 enum tcpm_transmit_type tx_sop_type);
2890
tcpm_handle_alert(struct tcpm_port * port,const __le32 * payload,int cnt)2891 static void tcpm_handle_alert(struct tcpm_port *port, const __le32 *payload,
2892 int cnt)
2893 {
2894 u32 p0 = le32_to_cpu(payload[0]);
2895 unsigned int type = usb_pd_ado_type(p0);
2896
2897 if (!type) {
2898 tcpm_log(port, "Alert message received with no type");
2899 tcpm_queue_message(port, PD_MSG_CTRL_NOT_SUPP);
2900 return;
2901 }
2902
2903 /* Just handling non-battery alerts for now */
2904 if (!(type & USB_PD_ADO_TYPE_BATT_STATUS_CHANGE)) {
2905 if (port->pwr_role == TYPEC_SOURCE) {
2906 port->upcoming_state = GET_STATUS_SEND;
2907 tcpm_ams_start(port, GETTING_SOURCE_SINK_STATUS);
2908 } else {
2909 /*
2910 * Do not check SinkTxOk here in case the Source doesn't set its Rp to
2911 * SinkTxOk in time.
2912 */
2913 port->ams = GETTING_SOURCE_SINK_STATUS;
2914 tcpm_set_state(port, GET_STATUS_SEND, 0);
2915 }
2916 } else {
2917 tcpm_queue_message(port, PD_MSG_CTRL_NOT_SUPP);
2918 }
2919 }
2920
tcpm_set_auto_vbus_discharge_threshold(struct tcpm_port * port,enum typec_pwr_opmode mode,bool pps_active,u32 requested_vbus_voltage)2921 static int tcpm_set_auto_vbus_discharge_threshold(struct tcpm_port *port,
2922 enum typec_pwr_opmode mode, bool pps_active,
2923 u32 requested_vbus_voltage)
2924 {
2925 int ret;
2926
2927 if (!port->tcpc->set_auto_vbus_discharge_threshold)
2928 return 0;
2929
2930 ret = port->tcpc->set_auto_vbus_discharge_threshold(port->tcpc, mode, pps_active,
2931 requested_vbus_voltage);
2932 tcpm_log_force(port,
2933 "set_auto_vbus_discharge_threshold mode:%d pps_active:%c vbus:%u ret:%d",
2934 mode, pps_active ? 'y' : 'n', requested_vbus_voltage, ret);
2935
2936 return ret;
2937 }
2938
tcpm_pd_handle_state(struct tcpm_port * port,enum tcpm_state state,enum tcpm_ams ams,unsigned int delay_ms)2939 static void tcpm_pd_handle_state(struct tcpm_port *port,
2940 enum tcpm_state state,
2941 enum tcpm_ams ams,
2942 unsigned int delay_ms)
2943 {
2944 switch (port->state) {
2945 case SRC_READY:
2946 case SNK_READY:
2947 port->ams = ams;
2948 tcpm_set_state(port, state, delay_ms);
2949 break;
2950 /* 8.3.3.4.1.1 and 6.8.1 power transitioning */
2951 case SNK_TRANSITION_SINK:
2952 case SNK_TRANSITION_SINK_VBUS:
2953 case SRC_TRANSITION_SUPPLY:
2954 tcpm_set_state(port, HARD_RESET_SEND, 0);
2955 break;
2956 default:
2957 if (!tcpm_ams_interruptible(port)) {
2958 tcpm_set_state(port, port->pwr_role == TYPEC_SOURCE ?
2959 SRC_SOFT_RESET_WAIT_SNK_TX :
2960 SNK_SOFT_RESET,
2961 0);
2962 } else {
2963 /* process the Message 6.8.1 */
2964 port->upcoming_state = state;
2965 port->next_ams = ams;
2966 tcpm_set_state(port, ready_state(port), delay_ms);
2967 }
2968 break;
2969 }
2970 }
2971
tcpm_pd_handle_msg(struct tcpm_port * port,enum pd_msg_request message,enum tcpm_ams ams)2972 static void tcpm_pd_handle_msg(struct tcpm_port *port,
2973 enum pd_msg_request message,
2974 enum tcpm_ams ams)
2975 {
2976 switch (port->state) {
2977 case SRC_READY:
2978 case SNK_READY:
2979 port->ams = ams;
2980 tcpm_queue_message(port, message);
2981 break;
2982 /* PD 3.0 Spec 8.3.3.4.1.1 and 6.8.1 */
2983 case SNK_TRANSITION_SINK:
2984 case SNK_TRANSITION_SINK_VBUS:
2985 case SRC_TRANSITION_SUPPLY:
2986 tcpm_set_state(port, HARD_RESET_SEND, 0);
2987 break;
2988 default:
2989 if (!tcpm_ams_interruptible(port)) {
2990 tcpm_set_state(port, port->pwr_role == TYPEC_SOURCE ?
2991 SRC_SOFT_RESET_WAIT_SNK_TX :
2992 SNK_SOFT_RESET,
2993 0);
2994 } else {
2995 port->next_ams = ams;
2996 tcpm_set_state(port, ready_state(port), 0);
2997 /* 6.8.1 process the Message */
2998 tcpm_queue_message(port, message);
2999 }
3000 break;
3001 }
3002 }
3003
tcpm_register_source_caps(struct tcpm_port * port)3004 static int tcpm_register_source_caps(struct tcpm_port *port)
3005 {
3006 struct usb_power_delivery_desc desc = { port->negotiated_rev };
3007 struct usb_power_delivery_capabilities_desc caps = { };
3008 struct usb_power_delivery_capabilities *cap = port->partner_source_caps;
3009
3010 if (!port->partner_pd)
3011 port->partner_pd = usb_power_delivery_register(NULL, &desc);
3012 if (IS_ERR(port->partner_pd))
3013 return PTR_ERR(port->partner_pd);
3014
3015 memcpy(caps.pdo, port->source_caps, sizeof(u32) * port->nr_source_caps);
3016 caps.role = TYPEC_SOURCE;
3017
3018 if (cap) {
3019 usb_power_delivery_unregister_capabilities(cap);
3020 port->partner_source_caps = NULL;
3021 }
3022
3023 cap = usb_power_delivery_register_capabilities(port->partner_pd, &caps);
3024 if (IS_ERR(cap))
3025 return PTR_ERR(cap);
3026
3027 port->partner_source_caps = cap;
3028
3029 return 0;
3030 }
3031
tcpm_register_sink_caps(struct tcpm_port * port)3032 static int tcpm_register_sink_caps(struct tcpm_port *port)
3033 {
3034 struct usb_power_delivery_desc desc = { port->negotiated_rev };
3035 struct usb_power_delivery_capabilities_desc caps = { };
3036 struct usb_power_delivery_capabilities *cap;
3037
3038 if (!port->partner_pd)
3039 port->partner_pd = usb_power_delivery_register(NULL, &desc);
3040 if (IS_ERR(port->partner_pd))
3041 return PTR_ERR(port->partner_pd);
3042
3043 memcpy(caps.pdo, port->sink_caps, sizeof(u32) * port->nr_sink_caps);
3044 caps.role = TYPEC_SINK;
3045
3046 cap = usb_power_delivery_register_capabilities(port->partner_pd, &caps);
3047 if (IS_ERR(cap))
3048 return PTR_ERR(cap);
3049
3050 port->partner_sink_caps = cap;
3051
3052 return 0;
3053 }
3054
tcpm_pd_data_request(struct tcpm_port * port,const struct pd_message * msg,enum tcpm_transmit_type rx_sop_type)3055 static void tcpm_pd_data_request(struct tcpm_port *port,
3056 const struct pd_message *msg,
3057 enum tcpm_transmit_type rx_sop_type)
3058 {
3059 enum pd_data_msg_type type = pd_header_type_le(msg->header);
3060 unsigned int cnt = pd_header_cnt_le(msg->header);
3061 unsigned int rev = pd_header_rev_le(msg->header);
3062 unsigned int i;
3063 enum frs_typec_current partner_frs_current;
3064 bool frs_enable;
3065 int ret;
3066
3067 if (tcpm_vdm_ams(port) && type != PD_DATA_VENDOR_DEF) {
3068 port->vdm_state = VDM_STATE_ERR_BUSY;
3069 tcpm_ams_finish(port);
3070 mod_vdm_delayed_work(port, 0);
3071 }
3072
3073 switch (type) {
3074 case PD_DATA_SOURCE_CAP:
3075 for (i = 0; i < cnt; i++)
3076 port->source_caps[i] = le32_to_cpu(msg->payload[i]);
3077
3078 port->nr_source_caps = cnt;
3079
3080 tcpm_log_source_caps(port);
3081
3082 tcpm_validate_caps(port, port->source_caps,
3083 port->nr_source_caps);
3084
3085 tcpm_register_source_caps(port);
3086
3087 /*
3088 * Adjust revision in subsequent message headers, as required,
3089 * to comply with 6.2.1.1.5 of the USB PD 3.0 spec. We don't
3090 * support Rev 1.0 so just do nothing in that scenario.
3091 */
3092 if (rev == PD_REV10) {
3093 if (port->ams == GET_SOURCE_CAPABILITIES)
3094 tcpm_ams_finish(port);
3095 break;
3096 }
3097
3098 if (rev < PD_MAX_REV) {
3099 port->negotiated_rev = rev;
3100 if (port->negotiated_rev_prime > port->negotiated_rev)
3101 port->negotiated_rev_prime = port->negotiated_rev;
3102 }
3103
3104 if (port->pwr_role == TYPEC_SOURCE) {
3105 if (port->ams == GET_SOURCE_CAPABILITIES)
3106 tcpm_pd_handle_state(port, SRC_READY, NONE_AMS, 0);
3107 /* Unexpected Source Capabilities */
3108 else
3109 tcpm_pd_handle_msg(port,
3110 port->negotiated_rev < PD_REV30 ?
3111 PD_MSG_CTRL_REJECT :
3112 PD_MSG_CTRL_NOT_SUPP,
3113 NONE_AMS);
3114 } else if (port->state == SNK_WAIT_CAPABILITIES ||
3115 port->state == SNK_WAIT_CAPABILITIES_TIMEOUT) {
3116 /*
3117 * This message may be received even if VBUS is not
3118 * present. This is quite unexpected; see USB PD
3119 * specification, sections 8.3.3.6.3.1 and 8.3.3.6.3.2.
3120 * However, at the same time, we must be ready to
3121 * receive this message and respond to it 15ms after
3122 * receiving PS_RDY during power swap operations, no matter
3123 * if VBUS is available or not (USB PD specification,
3124 * section 6.5.9.2).
3125 * So we need to accept the message either way,
3126 * but be prepared to keep waiting for VBUS after it was
3127 * handled.
3128 */
3129 port->ams = POWER_NEGOTIATION;
3130 port->in_ams = true;
3131 tcpm_set_state(port, SNK_NEGOTIATE_CAPABILITIES, 0);
3132 } else {
3133 if (port->ams == GET_SOURCE_CAPABILITIES)
3134 tcpm_ams_finish(port);
3135 tcpm_pd_handle_state(port, SNK_NEGOTIATE_CAPABILITIES,
3136 POWER_NEGOTIATION, 0);
3137 }
3138 break;
3139 case PD_DATA_REQUEST:
3140 /*
3141 * Adjust revision in subsequent message headers, as required,
3142 * to comply with 6.2.1.1.5 of the USB PD 3.0 spec. We don't
3143 * support Rev 1.0 so just reject in that scenario.
3144 */
3145 if (rev == PD_REV10) {
3146 tcpm_pd_handle_msg(port,
3147 port->negotiated_rev < PD_REV30 ?
3148 PD_MSG_CTRL_REJECT :
3149 PD_MSG_CTRL_NOT_SUPP,
3150 NONE_AMS);
3151 break;
3152 }
3153
3154 if (rev < PD_MAX_REV) {
3155 port->negotiated_rev = rev;
3156 if (port->negotiated_rev_prime > port->negotiated_rev)
3157 port->negotiated_rev_prime = port->negotiated_rev;
3158 }
3159
3160 if (port->pwr_role != TYPEC_SOURCE || cnt != 1) {
3161 tcpm_pd_handle_msg(port,
3162 port->negotiated_rev < PD_REV30 ?
3163 PD_MSG_CTRL_REJECT :
3164 PD_MSG_CTRL_NOT_SUPP,
3165 NONE_AMS);
3166 break;
3167 }
3168
3169 port->sink_request = le32_to_cpu(msg->payload[0]);
3170
3171 if (port->vdm_sm_running && port->explicit_contract) {
3172 tcpm_pd_handle_msg(port, PD_MSG_CTRL_WAIT, port->ams);
3173 break;
3174 }
3175
3176 if (port->state == SRC_SEND_CAPABILITIES)
3177 tcpm_set_state(port, SRC_NEGOTIATE_CAPABILITIES, 0);
3178 else
3179 tcpm_pd_handle_state(port, SRC_NEGOTIATE_CAPABILITIES,
3180 POWER_NEGOTIATION, 0);
3181 break;
3182 case PD_DATA_SINK_CAP:
3183 /* We don't do anything with this at the moment... */
3184 for (i = 0; i < cnt; i++)
3185 port->sink_caps[i] = le32_to_cpu(msg->payload[i]);
3186
3187 partner_frs_current = (port->sink_caps[0] & PDO_FIXED_FRS_CURR_MASK) >>
3188 PDO_FIXED_FRS_CURR_SHIFT;
3189 frs_enable = partner_frs_current && (partner_frs_current <=
3190 port->new_source_frs_current);
3191 tcpm_log(port,
3192 "Port partner FRS capable partner_frs_current:%u port_frs_current:%u enable:%c",
3193 partner_frs_current, port->new_source_frs_current, frs_enable ? 'y' : 'n');
3194 if (frs_enable) {
3195 ret = port->tcpc->enable_frs(port->tcpc, true);
3196 tcpm_log(port, "Enable FRS %s, ret:%d\n", ret ? "fail" : "success", ret);
3197 }
3198
3199 port->nr_sink_caps = cnt;
3200 port->sink_cap_done = true;
3201 tcpm_register_sink_caps(port);
3202
3203 if (port->ams == GET_SINK_CAPABILITIES)
3204 tcpm_set_state(port, ready_state(port), 0);
3205 /* Unexpected Sink Capabilities */
3206 else
3207 tcpm_pd_handle_msg(port,
3208 port->negotiated_rev < PD_REV30 ?
3209 PD_MSG_CTRL_REJECT :
3210 PD_MSG_CTRL_NOT_SUPP,
3211 NONE_AMS);
3212 break;
3213 case PD_DATA_VENDOR_DEF:
3214 tcpm_handle_vdm_request(port, msg->payload, cnt, rx_sop_type);
3215 break;
3216 case PD_DATA_BIST:
3217 port->bist_request = le32_to_cpu(msg->payload[0]);
3218 tcpm_pd_handle_state(port, BIST_RX, BIST, 0);
3219 break;
3220 case PD_DATA_ALERT:
3221 if (port->state != SRC_READY && port->state != SNK_READY)
3222 tcpm_pd_handle_state(port, port->pwr_role == TYPEC_SOURCE ?
3223 SRC_SOFT_RESET_WAIT_SNK_TX : SNK_SOFT_RESET,
3224 NONE_AMS, 0);
3225 else
3226 tcpm_handle_alert(port, msg->payload, cnt);
3227 break;
3228 case PD_DATA_BATT_STATUS:
3229 case PD_DATA_GET_COUNTRY_INFO:
3230 /* Currently unsupported */
3231 tcpm_pd_handle_msg(port, port->negotiated_rev < PD_REV30 ?
3232 PD_MSG_CTRL_REJECT :
3233 PD_MSG_CTRL_NOT_SUPP,
3234 NONE_AMS);
3235 break;
3236 default:
3237 tcpm_pd_handle_msg(port, port->negotiated_rev < PD_REV30 ?
3238 PD_MSG_CTRL_REJECT :
3239 PD_MSG_CTRL_NOT_SUPP,
3240 NONE_AMS);
3241 tcpm_log(port, "Unrecognized data message type %#x", type);
3242 break;
3243 }
3244 }
3245
tcpm_pps_complete(struct tcpm_port * port,int result)3246 static void tcpm_pps_complete(struct tcpm_port *port, int result)
3247 {
3248 if (port->pps_pending) {
3249 port->pps_status = result;
3250 port->pps_pending = false;
3251 complete(&port->pps_complete);
3252 }
3253 }
3254
tcpm_pd_ctrl_request(struct tcpm_port * port,const struct pd_message * msg,enum tcpm_transmit_type rx_sop_type)3255 static void tcpm_pd_ctrl_request(struct tcpm_port *port,
3256 const struct pd_message *msg,
3257 enum tcpm_transmit_type rx_sop_type)
3258 {
3259 enum pd_ctrl_msg_type type = pd_header_type_le(msg->header);
3260 enum tcpm_state next_state;
3261 unsigned int rev = pd_header_rev_le(msg->header);
3262
3263 /*
3264 * Stop VDM state machine if interrupted by other Messages while NOT_SUPP is allowed in
3265 * VDM AMS if waiting for VDM responses and will be handled later.
3266 */
3267 if (tcpm_vdm_ams(port) && type != PD_CTRL_NOT_SUPP && type != PD_CTRL_GOOD_CRC) {
3268 port->vdm_state = VDM_STATE_ERR_BUSY;
3269 tcpm_ams_finish(port);
3270 mod_vdm_delayed_work(port, 0);
3271 }
3272
3273 switch (type) {
3274 case PD_CTRL_GOOD_CRC:
3275 case PD_CTRL_PING:
3276 break;
3277 case PD_CTRL_GET_SOURCE_CAP:
3278 tcpm_pd_handle_msg(port, PD_MSG_DATA_SOURCE_CAP, GET_SOURCE_CAPABILITIES);
3279 break;
3280 case PD_CTRL_GET_SINK_CAP:
3281 tcpm_pd_handle_msg(port, PD_MSG_DATA_SINK_CAP, GET_SINK_CAPABILITIES);
3282 break;
3283 case PD_CTRL_GOTO_MIN:
3284 break;
3285 case PD_CTRL_PS_RDY:
3286 switch (port->state) {
3287 case SNK_TRANSITION_SINK:
3288 if (port->vbus_present) {
3289 tcpm_set_current_limit(port,
3290 port->req_current_limit,
3291 port->req_supply_voltage);
3292 port->explicit_contract = true;
3293 tcpm_set_auto_vbus_discharge_threshold(port,
3294 TYPEC_PWR_MODE_PD,
3295 port->pps_data.active,
3296 port->supply_voltage);
3297 tcpm_set_state(port, SNK_READY, 0);
3298 } else {
3299 /*
3300 * Seen after power swap. Keep waiting for VBUS
3301 * in a transitional state.
3302 */
3303 tcpm_set_state(port,
3304 SNK_TRANSITION_SINK_VBUS, 0);
3305 }
3306 break;
3307 case PR_SWAP_SRC_SNK_SOURCE_OFF_CC_DEBOUNCED:
3308 tcpm_set_state(port, PR_SWAP_SRC_SNK_SINK_ON, 0);
3309 break;
3310 case PR_SWAP_SNK_SRC_SINK_OFF:
3311 tcpm_set_state(port, PR_SWAP_SNK_SRC_SOURCE_ON, 0);
3312 break;
3313 case VCONN_SWAP_WAIT_FOR_VCONN:
3314 tcpm_set_state(port, VCONN_SWAP_TURN_OFF_VCONN, 0);
3315 break;
3316 case FR_SWAP_SNK_SRC_TRANSITION_TO_OFF:
3317 tcpm_set_state(port, FR_SWAP_SNK_SRC_NEW_SINK_READY, 0);
3318 break;
3319 default:
3320 tcpm_pd_handle_state(port,
3321 port->pwr_role == TYPEC_SOURCE ?
3322 SRC_SOFT_RESET_WAIT_SNK_TX :
3323 SNK_SOFT_RESET,
3324 NONE_AMS, 0);
3325 break;
3326 }
3327 break;
3328 case PD_CTRL_REJECT:
3329 case PD_CTRL_WAIT:
3330 case PD_CTRL_NOT_SUPP:
3331 switch (port->state) {
3332 case SNK_NEGOTIATE_CAPABILITIES:
3333 /* USB PD specification, Figure 8-43 */
3334 if (port->explicit_contract)
3335 next_state = SNK_READY;
3336 else
3337 next_state = SNK_WAIT_CAPABILITIES;
3338
3339 /* Threshold was relaxed before sending Request. Restore it back. */
3340 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_PD,
3341 port->pps_data.active,
3342 port->supply_voltage);
3343 tcpm_set_state(port, next_state, 0);
3344 break;
3345 case SNK_NEGOTIATE_PPS_CAPABILITIES:
3346 /* Revert data back from any requested PPS updates */
3347 port->pps_data.req_out_volt = port->supply_voltage;
3348 port->pps_data.req_op_curr = port->current_limit;
3349 port->pps_status = (type == PD_CTRL_WAIT ?
3350 -EAGAIN : -EOPNOTSUPP);
3351
3352 /* Threshold was relaxed before sending Request. Restore it back. */
3353 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_PD,
3354 port->pps_data.active,
3355 port->supply_voltage);
3356
3357 tcpm_set_state(port, SNK_READY, 0);
3358 break;
3359 case DR_SWAP_SEND:
3360 port->swap_status = (type == PD_CTRL_WAIT ?
3361 -EAGAIN : -EOPNOTSUPP);
3362 tcpm_set_state(port, DR_SWAP_CANCEL, 0);
3363 break;
3364 case PR_SWAP_SEND:
3365 port->swap_status = (type == PD_CTRL_WAIT ?
3366 -EAGAIN : -EOPNOTSUPP);
3367 tcpm_set_state(port, PR_SWAP_CANCEL, 0);
3368 break;
3369 case VCONN_SWAP_SEND:
3370 port->swap_status = (type == PD_CTRL_WAIT ?
3371 -EAGAIN : -EOPNOTSUPP);
3372 tcpm_set_state(port, VCONN_SWAP_CANCEL, 0);
3373 break;
3374 case FR_SWAP_SEND:
3375 tcpm_set_state(port, FR_SWAP_CANCEL, 0);
3376 break;
3377 case GET_SINK_CAP:
3378 port->sink_cap_done = true;
3379 tcpm_set_state(port, ready_state(port), 0);
3380 break;
3381 /*
3382 * Some port partners do not support GET_STATUS, avoid soft reset the link to
3383 * prevent redundant power re-negotiation
3384 */
3385 case GET_STATUS_SEND:
3386 tcpm_set_state(port, ready_state(port), 0);
3387 break;
3388 case SRC_READY:
3389 case SNK_READY:
3390 if (port->vdm_state > VDM_STATE_READY) {
3391 port->vdm_state = VDM_STATE_DONE;
3392 if (tcpm_vdm_ams(port))
3393 tcpm_ams_finish(port);
3394 mod_vdm_delayed_work(port, 0);
3395 break;
3396 }
3397 fallthrough;
3398 default:
3399 tcpm_pd_handle_state(port,
3400 port->pwr_role == TYPEC_SOURCE ?
3401 SRC_SOFT_RESET_WAIT_SNK_TX :
3402 SNK_SOFT_RESET,
3403 NONE_AMS, 0);
3404 break;
3405 }
3406 break;
3407 case PD_CTRL_ACCEPT:
3408 switch (port->state) {
3409 case SNK_NEGOTIATE_CAPABILITIES:
3410 port->pps_data.active = false;
3411 tcpm_set_state(port, SNK_TRANSITION_SINK, 0);
3412 break;
3413 case SNK_NEGOTIATE_PPS_CAPABILITIES:
3414 port->pps_data.active = true;
3415 port->pps_data.min_volt = port->pps_data.req_min_volt;
3416 port->pps_data.max_volt = port->pps_data.req_max_volt;
3417 port->pps_data.max_curr = port->pps_data.req_max_curr;
3418 port->req_supply_voltage = port->pps_data.req_out_volt;
3419 port->req_current_limit = port->pps_data.req_op_curr;
3420 power_supply_changed(port->psy);
3421 tcpm_set_state(port, SNK_TRANSITION_SINK, 0);
3422 break;
3423 case SOFT_RESET_SEND:
3424 if (port->ams == SOFT_RESET_AMS)
3425 tcpm_ams_finish(port);
3426 /*
3427 * SOP' Soft Reset is done after Vconn Swap,
3428 * which returns to ready state
3429 */
3430 if (rx_sop_type == TCPC_TX_SOP_PRIME) {
3431 if (rev < port->negotiated_rev_prime)
3432 port->negotiated_rev_prime = rev;
3433 tcpm_set_state(port, ready_state(port), 0);
3434 break;
3435 }
3436 if (port->pwr_role == TYPEC_SOURCE) {
3437 port->upcoming_state = SRC_SEND_CAPABILITIES;
3438 tcpm_ams_start(port, POWER_NEGOTIATION);
3439 } else {
3440 tcpm_set_state(port, SNK_WAIT_CAPABILITIES, 0);
3441 }
3442 break;
3443 case DR_SWAP_SEND:
3444 tcpm_set_state(port, DR_SWAP_CHANGE_DR, 0);
3445 break;
3446 case PR_SWAP_SEND:
3447 tcpm_set_state(port, PR_SWAP_START, 0);
3448 break;
3449 case VCONN_SWAP_SEND:
3450 tcpm_set_state(port, VCONN_SWAP_START, 0);
3451 break;
3452 case FR_SWAP_SEND:
3453 tcpm_set_state(port, FR_SWAP_SNK_SRC_TRANSITION_TO_OFF, 0);
3454 break;
3455 default:
3456 tcpm_pd_handle_state(port,
3457 port->pwr_role == TYPEC_SOURCE ?
3458 SRC_SOFT_RESET_WAIT_SNK_TX :
3459 SNK_SOFT_RESET,
3460 NONE_AMS, 0);
3461 break;
3462 }
3463 break;
3464 case PD_CTRL_SOFT_RESET:
3465 port->ams = SOFT_RESET_AMS;
3466 tcpm_set_state(port, SOFT_RESET, 0);
3467 break;
3468 case PD_CTRL_DR_SWAP:
3469 /*
3470 * XXX
3471 * 6.3.9: If an alternate mode is active, a request to swap
3472 * alternate modes shall trigger a port reset.
3473 */
3474 if (port->typec_caps.data != TYPEC_PORT_DRD) {
3475 tcpm_pd_handle_msg(port,
3476 port->negotiated_rev < PD_REV30 ?
3477 PD_MSG_CTRL_REJECT :
3478 PD_MSG_CTRL_NOT_SUPP,
3479 NONE_AMS);
3480 } else {
3481 if (port->send_discover && port->negotiated_rev < PD_REV30) {
3482 tcpm_queue_message(port, PD_MSG_CTRL_WAIT);
3483 break;
3484 }
3485
3486 tcpm_pd_handle_state(port, DR_SWAP_ACCEPT, DATA_ROLE_SWAP, 0);
3487 }
3488 break;
3489 case PD_CTRL_PR_SWAP:
3490 if (port->port_type != TYPEC_PORT_DRP) {
3491 tcpm_pd_handle_msg(port,
3492 port->negotiated_rev < PD_REV30 ?
3493 PD_MSG_CTRL_REJECT :
3494 PD_MSG_CTRL_NOT_SUPP,
3495 NONE_AMS);
3496 } else {
3497 if (port->send_discover && port->negotiated_rev < PD_REV30) {
3498 tcpm_queue_message(port, PD_MSG_CTRL_WAIT);
3499 break;
3500 }
3501
3502 tcpm_pd_handle_state(port, PR_SWAP_ACCEPT, POWER_ROLE_SWAP, 0);
3503 }
3504 break;
3505 case PD_CTRL_VCONN_SWAP:
3506 if (port->send_discover && port->negotiated_rev < PD_REV30) {
3507 tcpm_queue_message(port, PD_MSG_CTRL_WAIT);
3508 break;
3509 }
3510
3511 tcpm_pd_handle_state(port, VCONN_SWAP_ACCEPT, VCONN_SWAP, 0);
3512 break;
3513 case PD_CTRL_GET_SOURCE_CAP_EXT:
3514 case PD_CTRL_GET_STATUS:
3515 case PD_CTRL_FR_SWAP:
3516 case PD_CTRL_GET_PPS_STATUS:
3517 case PD_CTRL_GET_COUNTRY_CODES:
3518 /* Currently not supported */
3519 tcpm_pd_handle_msg(port,
3520 port->negotiated_rev < PD_REV30 ?
3521 PD_MSG_CTRL_REJECT :
3522 PD_MSG_CTRL_NOT_SUPP,
3523 NONE_AMS);
3524 break;
3525 default:
3526 tcpm_pd_handle_msg(port,
3527 port->negotiated_rev < PD_REV30 ?
3528 PD_MSG_CTRL_REJECT :
3529 PD_MSG_CTRL_NOT_SUPP,
3530 NONE_AMS);
3531 tcpm_log(port, "Unrecognized ctrl message type %#x", type);
3532 break;
3533 }
3534 }
3535
tcpm_pd_ext_msg_request(struct tcpm_port * port,const struct pd_message * msg)3536 static void tcpm_pd_ext_msg_request(struct tcpm_port *port,
3537 const struct pd_message *msg)
3538 {
3539 enum pd_ext_msg_type type = pd_header_type_le(msg->header);
3540 unsigned int data_size = pd_ext_header_data_size_le(msg->ext_msg.header);
3541
3542 /* stopping VDM state machine if interrupted by other Messages */
3543 if (tcpm_vdm_ams(port)) {
3544 port->vdm_state = VDM_STATE_ERR_BUSY;
3545 tcpm_ams_finish(port);
3546 mod_vdm_delayed_work(port, 0);
3547 }
3548
3549 if (!(le16_to_cpu(msg->ext_msg.header) & PD_EXT_HDR_CHUNKED)) {
3550 tcpm_pd_handle_msg(port, PD_MSG_CTRL_NOT_SUPP, NONE_AMS);
3551 tcpm_log(port, "Unchunked extended messages unsupported");
3552 return;
3553 }
3554
3555 if (data_size > PD_EXT_MAX_CHUNK_DATA) {
3556 tcpm_pd_handle_state(port, CHUNK_NOT_SUPP, NONE_AMS, PD_T_CHUNK_NOT_SUPP);
3557 tcpm_log(port, "Chunk handling not yet supported");
3558 return;
3559 }
3560
3561 switch (type) {
3562 case PD_EXT_STATUS:
3563 case PD_EXT_PPS_STATUS:
3564 if (port->ams == GETTING_SOURCE_SINK_STATUS) {
3565 tcpm_ams_finish(port);
3566 tcpm_set_state(port, ready_state(port), 0);
3567 } else {
3568 /* unexpected Status or PPS_Status Message */
3569 tcpm_pd_handle_state(port, port->pwr_role == TYPEC_SOURCE ?
3570 SRC_SOFT_RESET_WAIT_SNK_TX : SNK_SOFT_RESET,
3571 NONE_AMS, 0);
3572 }
3573 break;
3574 case PD_EXT_SOURCE_CAP_EXT:
3575 case PD_EXT_GET_BATT_CAP:
3576 case PD_EXT_GET_BATT_STATUS:
3577 case PD_EXT_BATT_CAP:
3578 case PD_EXT_GET_MANUFACTURER_INFO:
3579 case PD_EXT_MANUFACTURER_INFO:
3580 case PD_EXT_SECURITY_REQUEST:
3581 case PD_EXT_SECURITY_RESPONSE:
3582 case PD_EXT_FW_UPDATE_REQUEST:
3583 case PD_EXT_FW_UPDATE_RESPONSE:
3584 case PD_EXT_COUNTRY_INFO:
3585 case PD_EXT_COUNTRY_CODES:
3586 tcpm_pd_handle_msg(port, PD_MSG_CTRL_NOT_SUPP, NONE_AMS);
3587 break;
3588 default:
3589 tcpm_pd_handle_msg(port, PD_MSG_CTRL_NOT_SUPP, NONE_AMS);
3590 tcpm_log(port, "Unrecognized extended message type %#x", type);
3591 break;
3592 }
3593 }
3594
tcpm_pd_rx_handler(struct kthread_work * work)3595 static void tcpm_pd_rx_handler(struct kthread_work *work)
3596 {
3597 struct pd_rx_event *event = container_of(work,
3598 struct pd_rx_event, work);
3599 const struct pd_message *msg = &event->msg;
3600 unsigned int cnt = pd_header_cnt_le(msg->header);
3601 struct tcpm_port *port = event->port;
3602 enum tcpm_transmit_type rx_sop_type = event->rx_sop_type;
3603
3604 mutex_lock(&port->lock);
3605
3606 tcpm_log(port, "PD RX, header: %#x [%d]", le16_to_cpu(msg->header),
3607 port->attached);
3608
3609 if (port->attached) {
3610 enum pd_ctrl_msg_type type = pd_header_type_le(msg->header);
3611 unsigned int msgid = pd_header_msgid_le(msg->header);
3612
3613 /*
3614 * Drop SOP' messages if cannot receive via
3615 * tcpm_can_communicate_sop_prime
3616 */
3617 if (rx_sop_type == TCPC_TX_SOP_PRIME &&
3618 !tcpm_can_communicate_sop_prime(port))
3619 goto done;
3620
3621 /*
3622 * USB PD standard, 6.6.1.2:
3623 * "... if MessageID value in a received Message is the
3624 * same as the stored value, the receiver shall return a
3625 * GoodCRC Message with that MessageID value and drop
3626 * the Message (this is a retry of an already received
3627 * Message). Note: this shall not apply to the Soft_Reset
3628 * Message which always has a MessageID value of zero."
3629 */
3630 switch (rx_sop_type) {
3631 case TCPC_TX_SOP_PRIME:
3632 if (msgid == port->rx_msgid_prime)
3633 goto done;
3634 port->rx_msgid_prime = msgid;
3635 break;
3636 case TCPC_TX_SOP:
3637 default:
3638 if (msgid == port->rx_msgid && type != PD_CTRL_SOFT_RESET)
3639 goto done;
3640 port->rx_msgid = msgid;
3641 break;
3642 }
3643
3644 /*
3645 * If both ends believe to be DFP/host, we have a data role
3646 * mismatch.
3647 */
3648 if (!!(le16_to_cpu(msg->header) & PD_HEADER_DATA_ROLE) ==
3649 (port->data_role == TYPEC_HOST) && rx_sop_type == TCPC_TX_SOP) {
3650 tcpm_log(port,
3651 "Data role mismatch, initiating error recovery");
3652 tcpm_set_state(port, ERROR_RECOVERY, 0);
3653 } else {
3654 if (le16_to_cpu(msg->header) & PD_HEADER_EXT_HDR)
3655 tcpm_pd_ext_msg_request(port, msg);
3656 else if (cnt)
3657 tcpm_pd_data_request(port, msg, rx_sop_type);
3658 else
3659 tcpm_pd_ctrl_request(port, msg, rx_sop_type);
3660 }
3661 }
3662
3663 done:
3664 mutex_unlock(&port->lock);
3665 kfree(event);
3666 }
3667
tcpm_pd_receive(struct tcpm_port * port,const struct pd_message * msg,enum tcpm_transmit_type rx_sop_type)3668 void tcpm_pd_receive(struct tcpm_port *port, const struct pd_message *msg,
3669 enum tcpm_transmit_type rx_sop_type)
3670 {
3671 struct pd_rx_event *event;
3672
3673 event = kzalloc(sizeof(*event), GFP_ATOMIC);
3674 if (!event)
3675 return;
3676
3677 kthread_init_work(&event->work, tcpm_pd_rx_handler);
3678 event->port = port;
3679 event->rx_sop_type = rx_sop_type;
3680 memcpy(&event->msg, msg, sizeof(*msg));
3681 kthread_queue_work(port->wq, &event->work);
3682 }
3683 EXPORT_SYMBOL_GPL(tcpm_pd_receive);
3684
tcpm_pd_send_control(struct tcpm_port * port,enum pd_ctrl_msg_type type,enum tcpm_transmit_type tx_sop_type)3685 static int tcpm_pd_send_control(struct tcpm_port *port,
3686 enum pd_ctrl_msg_type type,
3687 enum tcpm_transmit_type tx_sop_type)
3688 {
3689 struct pd_message msg;
3690
3691 memset(&msg, 0, sizeof(msg));
3692 switch (tx_sop_type) {
3693 case TCPC_TX_SOP_PRIME:
3694 msg.header = PD_HEADER_LE(type,
3695 0, /* Cable Plug Indicator for DFP/UFP */
3696 0, /* Reserved */
3697 port->negotiated_rev,
3698 port->message_id_prime,
3699 0);
3700 break;
3701 case TCPC_TX_SOP:
3702 msg.header = PD_HEADER_LE(type,
3703 port->pwr_role,
3704 port->data_role,
3705 port->negotiated_rev,
3706 port->message_id,
3707 0);
3708 break;
3709 default:
3710 msg.header = PD_HEADER_LE(type,
3711 port->pwr_role,
3712 port->data_role,
3713 port->negotiated_rev,
3714 port->message_id,
3715 0);
3716 break;
3717 }
3718
3719 return tcpm_pd_transmit(port, tx_sop_type, &msg);
3720 }
3721
3722 /*
3723 * Send queued message without affecting state.
3724 * Return true if state machine should go back to sleep,
3725 * false otherwise.
3726 */
tcpm_send_queued_message(struct tcpm_port * port)3727 static bool tcpm_send_queued_message(struct tcpm_port *port)
3728 {
3729 enum pd_msg_request queued_message;
3730 int ret;
3731
3732 do {
3733 queued_message = port->queued_message;
3734 port->queued_message = PD_MSG_NONE;
3735
3736 switch (queued_message) {
3737 case PD_MSG_CTRL_WAIT:
3738 tcpm_pd_send_control(port, PD_CTRL_WAIT, TCPC_TX_SOP);
3739 break;
3740 case PD_MSG_CTRL_REJECT:
3741 tcpm_pd_send_control(port, PD_CTRL_REJECT, TCPC_TX_SOP);
3742 break;
3743 case PD_MSG_CTRL_NOT_SUPP:
3744 tcpm_pd_send_control(port, PD_CTRL_NOT_SUPP, TCPC_TX_SOP);
3745 break;
3746 case PD_MSG_DATA_SINK_CAP:
3747 ret = tcpm_pd_send_sink_caps(port);
3748 if (ret < 0) {
3749 tcpm_log(port, "Unable to send snk caps, ret=%d", ret);
3750 tcpm_set_state(port, SNK_SOFT_RESET, 0);
3751 }
3752 tcpm_ams_finish(port);
3753 break;
3754 case PD_MSG_DATA_SOURCE_CAP:
3755 ret = tcpm_pd_send_source_caps(port);
3756 if (ret < 0) {
3757 tcpm_log(port,
3758 "Unable to send src caps, ret=%d",
3759 ret);
3760 tcpm_set_state(port, SOFT_RESET_SEND, 0);
3761 } else if (port->pwr_role == TYPEC_SOURCE) {
3762 tcpm_ams_finish(port);
3763 tcpm_set_state(port, HARD_RESET_SEND,
3764 PD_T_SENDER_RESPONSE);
3765 } else {
3766 tcpm_ams_finish(port);
3767 }
3768 break;
3769 default:
3770 break;
3771 }
3772 } while (port->queued_message != PD_MSG_NONE);
3773
3774 if (port->delayed_state != INVALID_STATE) {
3775 if (ktime_after(port->delayed_runtime, ktime_get())) {
3776 mod_tcpm_delayed_work(port, ktime_to_ms(ktime_sub(port->delayed_runtime,
3777 ktime_get())));
3778 return true;
3779 }
3780 port->delayed_state = INVALID_STATE;
3781 }
3782 return false;
3783 }
3784
tcpm_pd_check_request(struct tcpm_port * port)3785 static int tcpm_pd_check_request(struct tcpm_port *port)
3786 {
3787 u32 pdo, rdo = port->sink_request;
3788 unsigned int max, op, pdo_max, index;
3789 enum pd_pdo_type type;
3790
3791 index = rdo_index(rdo);
3792 if (!index || index > port->nr_src_pdo)
3793 return -EINVAL;
3794
3795 pdo = port->src_pdo[index - 1];
3796 type = pdo_type(pdo);
3797 switch (type) {
3798 case PDO_TYPE_FIXED:
3799 case PDO_TYPE_VAR:
3800 max = rdo_max_current(rdo);
3801 op = rdo_op_current(rdo);
3802 pdo_max = pdo_max_current(pdo);
3803
3804 if (op > pdo_max)
3805 return -EINVAL;
3806 if (max > pdo_max && !(rdo & RDO_CAP_MISMATCH))
3807 return -EINVAL;
3808
3809 if (type == PDO_TYPE_FIXED)
3810 tcpm_log(port,
3811 "Requested %u mV, %u mA for %u / %u mA",
3812 pdo_fixed_voltage(pdo), pdo_max, op, max);
3813 else
3814 tcpm_log(port,
3815 "Requested %u -> %u mV, %u mA for %u / %u mA",
3816 pdo_min_voltage(pdo), pdo_max_voltage(pdo),
3817 pdo_max, op, max);
3818 break;
3819 case PDO_TYPE_BATT:
3820 max = rdo_max_power(rdo);
3821 op = rdo_op_power(rdo);
3822 pdo_max = pdo_max_power(pdo);
3823
3824 if (op > pdo_max)
3825 return -EINVAL;
3826 if (max > pdo_max && !(rdo & RDO_CAP_MISMATCH))
3827 return -EINVAL;
3828 tcpm_log(port,
3829 "Requested %u -> %u mV, %u mW for %u / %u mW",
3830 pdo_min_voltage(pdo), pdo_max_voltage(pdo),
3831 pdo_max, op, max);
3832 break;
3833 default:
3834 return -EINVAL;
3835 }
3836
3837 port->op_vsafe5v = index == 1;
3838
3839 return 0;
3840 }
3841
3842 #define min_power(x, y) min(pdo_max_power(x), pdo_max_power(y))
3843 #define min_current(x, y) min(pdo_max_current(x), pdo_max_current(y))
3844
tcpm_pd_select_pdo(struct tcpm_port * port,int * sink_pdo,int * src_pdo)3845 static int tcpm_pd_select_pdo(struct tcpm_port *port, int *sink_pdo,
3846 int *src_pdo)
3847 {
3848 unsigned int i, j, max_src_mv = 0, min_src_mv = 0, max_mw = 0,
3849 max_mv = 0, src_mw = 0, src_ma = 0, max_snk_mv = 0,
3850 min_snk_mv = 0;
3851 int ret = -EINVAL;
3852
3853 port->pps_data.supported = false;
3854 port->usb_type = POWER_SUPPLY_USB_TYPE_PD;
3855 power_supply_changed(port->psy);
3856
3857 /*
3858 * Select the source PDO providing the most power which has a
3859 * matchig sink cap.
3860 */
3861 for (i = 0; i < port->nr_source_caps; i++) {
3862 u32 pdo = port->source_caps[i];
3863 enum pd_pdo_type type = pdo_type(pdo);
3864
3865 switch (type) {
3866 case PDO_TYPE_FIXED:
3867 max_src_mv = pdo_fixed_voltage(pdo);
3868 min_src_mv = max_src_mv;
3869 break;
3870 case PDO_TYPE_BATT:
3871 case PDO_TYPE_VAR:
3872 max_src_mv = pdo_max_voltage(pdo);
3873 min_src_mv = pdo_min_voltage(pdo);
3874 break;
3875 case PDO_TYPE_APDO:
3876 if (pdo_apdo_type(pdo) == APDO_TYPE_PPS) {
3877 port->pps_data.supported = true;
3878 port->usb_type =
3879 POWER_SUPPLY_USB_TYPE_PD_PPS;
3880 power_supply_changed(port->psy);
3881 }
3882 continue;
3883 default:
3884 tcpm_log(port, "Invalid source PDO type, ignoring");
3885 continue;
3886 }
3887
3888 switch (type) {
3889 case PDO_TYPE_FIXED:
3890 case PDO_TYPE_VAR:
3891 src_ma = pdo_max_current(pdo);
3892 src_mw = src_ma * min_src_mv / 1000;
3893 break;
3894 case PDO_TYPE_BATT:
3895 src_mw = pdo_max_power(pdo);
3896 break;
3897 case PDO_TYPE_APDO:
3898 continue;
3899 default:
3900 tcpm_log(port, "Invalid source PDO type, ignoring");
3901 continue;
3902 }
3903
3904 for (j = 0; j < port->nr_snk_pdo; j++) {
3905 pdo = port->snk_pdo[j];
3906
3907 switch (pdo_type(pdo)) {
3908 case PDO_TYPE_FIXED:
3909 max_snk_mv = pdo_fixed_voltage(pdo);
3910 min_snk_mv = max_snk_mv;
3911 break;
3912 case PDO_TYPE_BATT:
3913 case PDO_TYPE_VAR:
3914 max_snk_mv = pdo_max_voltage(pdo);
3915 min_snk_mv = pdo_min_voltage(pdo);
3916 break;
3917 case PDO_TYPE_APDO:
3918 continue;
3919 default:
3920 tcpm_log(port, "Invalid sink PDO type, ignoring");
3921 continue;
3922 }
3923
3924 if (max_src_mv <= max_snk_mv &&
3925 min_src_mv >= min_snk_mv) {
3926 /* Prefer higher voltages if available */
3927 if ((src_mw == max_mw && min_src_mv > max_mv) ||
3928 src_mw > max_mw) {
3929 *src_pdo = i;
3930 *sink_pdo = j;
3931 max_mw = src_mw;
3932 max_mv = min_src_mv;
3933 ret = 0;
3934 }
3935 }
3936 }
3937 }
3938
3939 return ret;
3940 }
3941
tcpm_pd_select_pps_apdo(struct tcpm_port * port)3942 static unsigned int tcpm_pd_select_pps_apdo(struct tcpm_port *port)
3943 {
3944 unsigned int i, src_ma, max_temp_mw = 0, max_op_ma, op_mw;
3945 unsigned int src_pdo = 0;
3946 u32 pdo, src;
3947
3948 for (i = 1; i < port->nr_source_caps; ++i) {
3949 pdo = port->source_caps[i];
3950
3951 switch (pdo_type(pdo)) {
3952 case PDO_TYPE_APDO:
3953 if (pdo_apdo_type(pdo) != APDO_TYPE_PPS) {
3954 tcpm_log(port, "Not PPS APDO (source), ignoring");
3955 continue;
3956 }
3957
3958 if (port->pps_data.req_out_volt > pdo_pps_apdo_max_voltage(pdo) ||
3959 port->pps_data.req_out_volt < pdo_pps_apdo_min_voltage(pdo))
3960 continue;
3961
3962 src_ma = pdo_pps_apdo_max_current(pdo);
3963 max_op_ma = min(src_ma, port->pps_data.req_op_curr);
3964 op_mw = max_op_ma * port->pps_data.req_out_volt / 1000;
3965 if (op_mw > max_temp_mw) {
3966 src_pdo = i;
3967 max_temp_mw = op_mw;
3968 }
3969 break;
3970 default:
3971 tcpm_log(port, "Not APDO type (source), ignoring");
3972 continue;
3973 }
3974 }
3975
3976 if (src_pdo) {
3977 src = port->source_caps[src_pdo];
3978
3979 port->pps_data.req_min_volt = pdo_pps_apdo_min_voltage(src);
3980 port->pps_data.req_max_volt = pdo_pps_apdo_max_voltage(src);
3981 port->pps_data.req_max_curr = pdo_pps_apdo_max_current(src);
3982 port->pps_data.req_op_curr = min(port->pps_data.req_max_curr,
3983 port->pps_data.req_op_curr);
3984 }
3985
3986 return src_pdo;
3987 }
3988
tcpm_pd_build_request(struct tcpm_port * port,u32 * rdo)3989 static int tcpm_pd_build_request(struct tcpm_port *port, u32 *rdo)
3990 {
3991 unsigned int mv, ma, mw, flags;
3992 unsigned int max_ma, max_mw;
3993 enum pd_pdo_type type;
3994 u32 pdo, matching_snk_pdo;
3995 int src_pdo_index = 0;
3996 int snk_pdo_index = 0;
3997 int ret;
3998
3999 ret = tcpm_pd_select_pdo(port, &snk_pdo_index, &src_pdo_index);
4000 if (ret < 0)
4001 return ret;
4002
4003 pdo = port->source_caps[src_pdo_index];
4004 matching_snk_pdo = port->snk_pdo[snk_pdo_index];
4005 type = pdo_type(pdo);
4006
4007 switch (type) {
4008 case PDO_TYPE_FIXED:
4009 mv = pdo_fixed_voltage(pdo);
4010 break;
4011 case PDO_TYPE_BATT:
4012 case PDO_TYPE_VAR:
4013 mv = pdo_min_voltage(pdo);
4014 break;
4015 default:
4016 tcpm_log(port, "Invalid PDO selected!");
4017 return -EINVAL;
4018 }
4019
4020 /* Select maximum available current within the sink pdo's limit */
4021 if (type == PDO_TYPE_BATT) {
4022 mw = min_power(pdo, matching_snk_pdo);
4023 ma = 1000 * mw / mv;
4024 } else {
4025 ma = min_current(pdo, matching_snk_pdo);
4026 mw = ma * mv / 1000;
4027 }
4028
4029 flags = RDO_USB_COMM | RDO_NO_SUSPEND;
4030
4031 /* Set mismatch bit if offered power is less than operating power */
4032 max_ma = ma;
4033 max_mw = mw;
4034 if (mw < port->operating_snk_mw) {
4035 flags |= RDO_CAP_MISMATCH;
4036 if (type == PDO_TYPE_BATT &&
4037 (pdo_max_power(matching_snk_pdo) > pdo_max_power(pdo)))
4038 max_mw = pdo_max_power(matching_snk_pdo);
4039 else if (pdo_max_current(matching_snk_pdo) >
4040 pdo_max_current(pdo))
4041 max_ma = pdo_max_current(matching_snk_pdo);
4042 }
4043
4044 tcpm_log(port, "cc=%d cc1=%d cc2=%d vbus=%d vconn=%s polarity=%d",
4045 port->cc_req, port->cc1, port->cc2, port->vbus_source,
4046 port->vconn_role == TYPEC_SOURCE ? "source" : "sink",
4047 port->polarity);
4048
4049 if (type == PDO_TYPE_BATT) {
4050 *rdo = RDO_BATT(src_pdo_index + 1, mw, max_mw, flags);
4051
4052 tcpm_log(port, "Requesting PDO %d: %u mV, %u mW%s",
4053 src_pdo_index, mv, mw,
4054 flags & RDO_CAP_MISMATCH ? " [mismatch]" : "");
4055 } else {
4056 *rdo = RDO_FIXED(src_pdo_index + 1, ma, max_ma, flags);
4057
4058 tcpm_log(port, "Requesting PDO %d: %u mV, %u mA%s",
4059 src_pdo_index, mv, ma,
4060 flags & RDO_CAP_MISMATCH ? " [mismatch]" : "");
4061 }
4062
4063 port->req_current_limit = ma;
4064 port->req_supply_voltage = mv;
4065
4066 return 0;
4067 }
4068
tcpm_pd_send_request(struct tcpm_port * port)4069 static int tcpm_pd_send_request(struct tcpm_port *port)
4070 {
4071 struct pd_message msg;
4072 int ret;
4073 u32 rdo;
4074
4075 ret = tcpm_pd_build_request(port, &rdo);
4076 if (ret < 0)
4077 return ret;
4078
4079 /*
4080 * Relax the threshold as voltage will be adjusted after Accept Message plus tSrcTransition.
4081 * It is safer to modify the threshold here.
4082 */
4083 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_USB, false, 0);
4084
4085 memset(&msg, 0, sizeof(msg));
4086 msg.header = PD_HEADER_LE(PD_DATA_REQUEST,
4087 port->pwr_role,
4088 port->data_role,
4089 port->negotiated_rev,
4090 port->message_id, 1);
4091 msg.payload[0] = cpu_to_le32(rdo);
4092
4093 return tcpm_pd_transmit(port, TCPC_TX_SOP, &msg);
4094 }
4095
tcpm_pd_build_pps_request(struct tcpm_port * port,u32 * rdo)4096 static int tcpm_pd_build_pps_request(struct tcpm_port *port, u32 *rdo)
4097 {
4098 unsigned int out_mv, op_ma, op_mw, max_mv, max_ma, flags;
4099 unsigned int src_pdo_index;
4100
4101 src_pdo_index = tcpm_pd_select_pps_apdo(port);
4102 if (!src_pdo_index)
4103 return -EOPNOTSUPP;
4104
4105 max_mv = port->pps_data.req_max_volt;
4106 max_ma = port->pps_data.req_max_curr;
4107 out_mv = port->pps_data.req_out_volt;
4108 op_ma = port->pps_data.req_op_curr;
4109
4110 flags = RDO_USB_COMM | RDO_NO_SUSPEND;
4111
4112 op_mw = (op_ma * out_mv) / 1000;
4113 if (op_mw < port->operating_snk_mw) {
4114 /*
4115 * Try raising current to meet power needs. If that's not enough
4116 * then try upping the voltage. If that's still not enough
4117 * then we've obviously chosen a PPS APDO which really isn't
4118 * suitable so abandon ship.
4119 */
4120 op_ma = (port->operating_snk_mw * 1000) / out_mv;
4121 if ((port->operating_snk_mw * 1000) % out_mv)
4122 ++op_ma;
4123 op_ma += RDO_PROG_CURR_MA_STEP - (op_ma % RDO_PROG_CURR_MA_STEP);
4124
4125 if (op_ma > max_ma) {
4126 op_ma = max_ma;
4127 out_mv = (port->operating_snk_mw * 1000) / op_ma;
4128 if ((port->operating_snk_mw * 1000) % op_ma)
4129 ++out_mv;
4130 out_mv += RDO_PROG_VOLT_MV_STEP -
4131 (out_mv % RDO_PROG_VOLT_MV_STEP);
4132
4133 if (out_mv > max_mv) {
4134 tcpm_log(port, "Invalid PPS APDO selected!");
4135 return -EINVAL;
4136 }
4137 }
4138 }
4139
4140 tcpm_log(port, "cc=%d cc1=%d cc2=%d vbus=%d vconn=%s polarity=%d",
4141 port->cc_req, port->cc1, port->cc2, port->vbus_source,
4142 port->vconn_role == TYPEC_SOURCE ? "source" : "sink",
4143 port->polarity);
4144
4145 *rdo = RDO_PROG(src_pdo_index + 1, out_mv, op_ma, flags);
4146
4147 tcpm_log(port, "Requesting APDO %d: %u mV, %u mA",
4148 src_pdo_index, out_mv, op_ma);
4149
4150 port->pps_data.req_op_curr = op_ma;
4151 port->pps_data.req_out_volt = out_mv;
4152
4153 return 0;
4154 }
4155
tcpm_pd_send_pps_request(struct tcpm_port * port)4156 static int tcpm_pd_send_pps_request(struct tcpm_port *port)
4157 {
4158 struct pd_message msg;
4159 int ret;
4160 u32 rdo;
4161
4162 ret = tcpm_pd_build_pps_request(port, &rdo);
4163 if (ret < 0)
4164 return ret;
4165
4166 /* Relax the threshold as voltage will be adjusted right after Accept Message. */
4167 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_USB, false, 0);
4168
4169 memset(&msg, 0, sizeof(msg));
4170 msg.header = PD_HEADER_LE(PD_DATA_REQUEST,
4171 port->pwr_role,
4172 port->data_role,
4173 port->negotiated_rev,
4174 port->message_id, 1);
4175 msg.payload[0] = cpu_to_le32(rdo);
4176
4177 return tcpm_pd_transmit(port, TCPC_TX_SOP, &msg);
4178 }
4179
tcpm_set_vbus(struct tcpm_port * port,bool enable)4180 static int tcpm_set_vbus(struct tcpm_port *port, bool enable)
4181 {
4182 int ret;
4183
4184 if (enable && port->vbus_charge)
4185 return -EINVAL;
4186
4187 tcpm_log(port, "vbus:=%d charge=%d", enable, port->vbus_charge);
4188
4189 ret = port->tcpc->set_vbus(port->tcpc, enable, port->vbus_charge);
4190 if (ret < 0)
4191 return ret;
4192
4193 port->vbus_source = enable;
4194 return 0;
4195 }
4196
tcpm_set_charge(struct tcpm_port * port,bool charge)4197 static int tcpm_set_charge(struct tcpm_port *port, bool charge)
4198 {
4199 int ret;
4200
4201 if (charge && port->vbus_source)
4202 return -EINVAL;
4203
4204 if (charge != port->vbus_charge) {
4205 tcpm_log(port, "vbus=%d charge:=%d", port->vbus_source, charge);
4206 ret = port->tcpc->set_vbus(port->tcpc, port->vbus_source,
4207 charge);
4208 if (ret < 0)
4209 return ret;
4210 }
4211 port->vbus_charge = charge;
4212 power_supply_changed(port->psy);
4213 return 0;
4214 }
4215
tcpm_start_toggling(struct tcpm_port * port,enum typec_cc_status cc)4216 static bool tcpm_start_toggling(struct tcpm_port *port, enum typec_cc_status cc)
4217 {
4218 int ret;
4219
4220 if (!port->tcpc->start_toggling)
4221 return false;
4222
4223 tcpm_log_force(port, "Start toggling");
4224 ret = port->tcpc->start_toggling(port->tcpc, port->port_type, cc);
4225 return ret == 0;
4226 }
4227
tcpm_init_vbus(struct tcpm_port * port)4228 static int tcpm_init_vbus(struct tcpm_port *port)
4229 {
4230 int ret;
4231
4232 ret = port->tcpc->set_vbus(port->tcpc, false, false);
4233 port->vbus_source = false;
4234 port->vbus_charge = false;
4235 return ret;
4236 }
4237
tcpm_init_vconn(struct tcpm_port * port)4238 static int tcpm_init_vconn(struct tcpm_port *port)
4239 {
4240 int ret;
4241
4242 ret = port->tcpc->set_vconn(port->tcpc, false);
4243 port->vconn_role = TYPEC_SINK;
4244 return ret;
4245 }
4246
tcpm_typec_connect(struct tcpm_port * port)4247 static void tcpm_typec_connect(struct tcpm_port *port)
4248 {
4249 struct typec_partner *partner;
4250
4251 if (!port->connected) {
4252 port->connected = true;
4253 /* Make sure we don't report stale identity information */
4254 memset(&port->partner_ident, 0, sizeof(port->partner_ident));
4255 port->partner_desc.usb_pd = port->pd_capable;
4256 if (tcpm_port_is_debug(port))
4257 port->partner_desc.accessory = TYPEC_ACCESSORY_DEBUG;
4258 else if (tcpm_port_is_audio(port))
4259 port->partner_desc.accessory = TYPEC_ACCESSORY_AUDIO;
4260 else
4261 port->partner_desc.accessory = TYPEC_ACCESSORY_NONE;
4262 partner = typec_register_partner(port->typec_port, &port->partner_desc);
4263 if (IS_ERR(partner)) {
4264 dev_err(port->dev, "Failed to register partner (%ld)\n", PTR_ERR(partner));
4265 return;
4266 }
4267
4268 port->partner = partner;
4269 typec_partner_set_usb_power_delivery(port->partner, port->partner_pd);
4270 }
4271 }
4272
tcpm_src_attach(struct tcpm_port * port)4273 static int tcpm_src_attach(struct tcpm_port *port)
4274 {
4275 enum typec_cc_polarity polarity =
4276 port->cc2 == TYPEC_CC_RD ? TYPEC_POLARITY_CC2
4277 : TYPEC_POLARITY_CC1;
4278 int ret;
4279
4280 if (port->attached)
4281 return 0;
4282
4283 ret = tcpm_set_polarity(port, polarity);
4284 if (ret < 0)
4285 return ret;
4286
4287 tcpm_enable_auto_vbus_discharge(port, true);
4288
4289 ret = tcpm_set_roles(port, true, TYPEC_SOURCE, tcpm_data_role_for_source(port));
4290 if (ret < 0)
4291 return ret;
4292
4293 if (port->pd_supported) {
4294 ret = port->tcpc->set_pd_rx(port->tcpc, true);
4295 if (ret < 0)
4296 goto out_disable_mux;
4297 }
4298
4299 /*
4300 * USB Type-C specification, version 1.2,
4301 * chapter 4.5.2.2.8.1 (Attached.SRC Requirements)
4302 * Enable VCONN only if the non-RD port is set to RA.
4303 */
4304 if ((polarity == TYPEC_POLARITY_CC1 && port->cc2 == TYPEC_CC_RA) ||
4305 (polarity == TYPEC_POLARITY_CC2 && port->cc1 == TYPEC_CC_RA)) {
4306 ret = tcpm_set_vconn(port, true);
4307 if (ret < 0)
4308 goto out_disable_pd;
4309 }
4310
4311 ret = tcpm_set_vbus(port, true);
4312 if (ret < 0)
4313 goto out_disable_vconn;
4314
4315 port->pd_capable = false;
4316
4317 port->partner = NULL;
4318
4319 port->attached = true;
4320 port->send_discover = true;
4321 port->send_discover_prime = false;
4322
4323 return 0;
4324
4325 out_disable_vconn:
4326 tcpm_set_vconn(port, false);
4327 out_disable_pd:
4328 if (port->pd_supported)
4329 port->tcpc->set_pd_rx(port->tcpc, false);
4330 out_disable_mux:
4331 tcpm_mux_set(port, TYPEC_STATE_SAFE, USB_ROLE_NONE,
4332 TYPEC_ORIENTATION_NONE);
4333 return ret;
4334 }
4335
tcpm_typec_disconnect(struct tcpm_port * port)4336 static void tcpm_typec_disconnect(struct tcpm_port *port)
4337 {
4338 /*
4339 * Unregister plug/cable outside of port->connected because cable can
4340 * be discovered before SRC_READY/SNK_READY states where port->connected
4341 * is set.
4342 */
4343 typec_unregister_plug(port->plug_prime);
4344 typec_unregister_cable(port->cable);
4345 port->plug_prime = NULL;
4346 port->cable = NULL;
4347 if (port->connected) {
4348 if (port->partner) {
4349 typec_partner_set_usb_power_delivery(port->partner, NULL);
4350 typec_unregister_partner(port->partner);
4351 port->partner = NULL;
4352 }
4353 port->connected = false;
4354 }
4355 }
4356
tcpm_unregister_altmodes(struct tcpm_port * port)4357 static void tcpm_unregister_altmodes(struct tcpm_port *port)
4358 {
4359 struct pd_mode_data *modep = &port->mode_data;
4360 struct pd_mode_data *modep_prime = &port->mode_data_prime;
4361 int i;
4362
4363 for (i = 0; i < modep->altmodes; i++) {
4364 typec_unregister_altmode(port->partner_altmode[i]);
4365 port->partner_altmode[i] = NULL;
4366 }
4367 for (i = 0; i < modep_prime->altmodes; i++) {
4368 typec_unregister_altmode(port->plug_prime_altmode[i]);
4369 port->plug_prime_altmode[i] = NULL;
4370 }
4371
4372 memset(modep, 0, sizeof(*modep));
4373 memset(modep_prime, 0, sizeof(*modep_prime));
4374 }
4375
tcpm_set_partner_usb_comm_capable(struct tcpm_port * port,bool capable)4376 static void tcpm_set_partner_usb_comm_capable(struct tcpm_port *port, bool capable)
4377 {
4378 tcpm_log(port, "Setting usb_comm capable %s", capable ? "true" : "false");
4379
4380 if (port->tcpc->set_partner_usb_comm_capable)
4381 port->tcpc->set_partner_usb_comm_capable(port->tcpc, capable);
4382 }
4383
tcpm_reset_port(struct tcpm_port * port)4384 static void tcpm_reset_port(struct tcpm_port *port)
4385 {
4386 tcpm_enable_auto_vbus_discharge(port, false);
4387 port->in_ams = false;
4388 port->ams = NONE_AMS;
4389 port->vdm_sm_running = false;
4390 tcpm_unregister_altmodes(port);
4391 tcpm_typec_disconnect(port);
4392 port->attached = false;
4393 port->pd_capable = false;
4394 port->pps_data.supported = false;
4395 tcpm_set_partner_usb_comm_capable(port, false);
4396
4397 /*
4398 * First Rx ID should be 0; set this to a sentinel of -1 so that
4399 * we can check tcpm_pd_rx_handler() if we had seen it before.
4400 */
4401 port->rx_msgid = -1;
4402 port->rx_msgid_prime = -1;
4403
4404 port->tcpc->set_pd_rx(port->tcpc, false);
4405 tcpm_init_vbus(port); /* also disables charging */
4406 tcpm_init_vconn(port);
4407 tcpm_set_current_limit(port, 0, 0);
4408 tcpm_set_polarity(port, TYPEC_POLARITY_CC1);
4409 tcpm_mux_set(port, TYPEC_STATE_SAFE, USB_ROLE_NONE,
4410 TYPEC_ORIENTATION_NONE);
4411 tcpm_set_attached_state(port, false);
4412 port->try_src_count = 0;
4413 port->try_snk_count = 0;
4414 port->usb_type = POWER_SUPPLY_USB_TYPE_C;
4415 power_supply_changed(port->psy);
4416 port->nr_sink_caps = 0;
4417 port->sink_cap_done = false;
4418 if (port->tcpc->enable_frs)
4419 port->tcpc->enable_frs(port->tcpc, false);
4420
4421 usb_power_delivery_unregister_capabilities(port->partner_sink_caps);
4422 port->partner_sink_caps = NULL;
4423 usb_power_delivery_unregister_capabilities(port->partner_source_caps);
4424 port->partner_source_caps = NULL;
4425 usb_power_delivery_unregister(port->partner_pd);
4426 port->partner_pd = NULL;
4427 }
4428
tcpm_detach(struct tcpm_port * port)4429 static void tcpm_detach(struct tcpm_port *port)
4430 {
4431 if (tcpm_port_is_disconnected(port))
4432 port->hard_reset_count = 0;
4433
4434 if (!port->attached)
4435 return;
4436
4437 if (port->tcpc->set_bist_data) {
4438 tcpm_log(port, "disable BIST MODE TESTDATA");
4439 port->tcpc->set_bist_data(port->tcpc, false);
4440 }
4441
4442 tcpm_reset_port(port);
4443 }
4444
tcpm_src_detach(struct tcpm_port * port)4445 static void tcpm_src_detach(struct tcpm_port *port)
4446 {
4447 tcpm_detach(port);
4448 }
4449
tcpm_snk_attach(struct tcpm_port * port)4450 static int tcpm_snk_attach(struct tcpm_port *port)
4451 {
4452 int ret;
4453
4454 if (port->attached)
4455 return 0;
4456
4457 ret = tcpm_set_polarity(port, port->cc2 != TYPEC_CC_OPEN ?
4458 TYPEC_POLARITY_CC2 : TYPEC_POLARITY_CC1);
4459 if (ret < 0)
4460 return ret;
4461
4462 tcpm_enable_auto_vbus_discharge(port, true);
4463
4464 ret = tcpm_set_roles(port, true, TYPEC_SINK, tcpm_data_role_for_sink(port));
4465 if (ret < 0)
4466 return ret;
4467
4468 port->pd_capable = false;
4469
4470 port->partner = NULL;
4471
4472 port->attached = true;
4473 port->send_discover = true;
4474 port->send_discover_prime = false;
4475
4476 return 0;
4477 }
4478
tcpm_snk_detach(struct tcpm_port * port)4479 static void tcpm_snk_detach(struct tcpm_port *port)
4480 {
4481 tcpm_detach(port);
4482 }
4483
tcpm_acc_attach(struct tcpm_port * port)4484 static int tcpm_acc_attach(struct tcpm_port *port)
4485 {
4486 int ret;
4487
4488 if (port->attached)
4489 return 0;
4490
4491 ret = tcpm_set_roles(port, true, TYPEC_SOURCE,
4492 tcpm_data_role_for_source(port));
4493 if (ret < 0)
4494 return ret;
4495
4496 port->partner = NULL;
4497
4498 tcpm_typec_connect(port);
4499
4500 port->attached = true;
4501
4502 return 0;
4503 }
4504
tcpm_acc_detach(struct tcpm_port * port)4505 static void tcpm_acc_detach(struct tcpm_port *port)
4506 {
4507 tcpm_detach(port);
4508 }
4509
hard_reset_state(struct tcpm_port * port)4510 static inline enum tcpm_state hard_reset_state(struct tcpm_port *port)
4511 {
4512 if (port->hard_reset_count < PD_N_HARD_RESET_COUNT)
4513 return HARD_RESET_SEND;
4514 if (port->pd_capable)
4515 return ERROR_RECOVERY;
4516 if (port->pwr_role == TYPEC_SOURCE)
4517 return SRC_UNATTACHED;
4518 if (port->state == SNK_WAIT_CAPABILITIES ||
4519 port->state == SNK_WAIT_CAPABILITIES_TIMEOUT)
4520 return SNK_READY;
4521 return SNK_UNATTACHED;
4522 }
4523
unattached_state(struct tcpm_port * port)4524 static inline enum tcpm_state unattached_state(struct tcpm_port *port)
4525 {
4526 if (port->port_type == TYPEC_PORT_DRP) {
4527 if (port->pwr_role == TYPEC_SOURCE)
4528 return SRC_UNATTACHED;
4529 else
4530 return SNK_UNATTACHED;
4531 } else if (port->port_type == TYPEC_PORT_SRC) {
4532 return SRC_UNATTACHED;
4533 }
4534
4535 return SNK_UNATTACHED;
4536 }
4537
tcpm_swap_complete(struct tcpm_port * port,int result)4538 static void tcpm_swap_complete(struct tcpm_port *port, int result)
4539 {
4540 if (port->swap_pending) {
4541 port->swap_status = result;
4542 port->swap_pending = false;
4543 port->non_pd_role_swap = false;
4544 complete(&port->swap_complete);
4545 }
4546 }
4547
tcpm_get_pwr_opmode(enum typec_cc_status cc)4548 static enum typec_pwr_opmode tcpm_get_pwr_opmode(enum typec_cc_status cc)
4549 {
4550 switch (cc) {
4551 case TYPEC_CC_RP_1_5:
4552 return TYPEC_PWR_MODE_1_5A;
4553 case TYPEC_CC_RP_3_0:
4554 return TYPEC_PWR_MODE_3_0A;
4555 case TYPEC_CC_RP_DEF:
4556 default:
4557 return TYPEC_PWR_MODE_USB;
4558 }
4559 }
4560
tcpm_pwr_opmode_to_rp(enum typec_pwr_opmode opmode)4561 static enum typec_cc_status tcpm_pwr_opmode_to_rp(enum typec_pwr_opmode opmode)
4562 {
4563 switch (opmode) {
4564 case TYPEC_PWR_MODE_USB:
4565 return TYPEC_CC_RP_DEF;
4566 case TYPEC_PWR_MODE_1_5A:
4567 return TYPEC_CC_RP_1_5;
4568 case TYPEC_PWR_MODE_3_0A:
4569 case TYPEC_PWR_MODE_PD:
4570 default:
4571 return TYPEC_CC_RP_3_0;
4572 }
4573 }
4574
tcpm_set_initial_svdm_version(struct tcpm_port * port)4575 static void tcpm_set_initial_svdm_version(struct tcpm_port *port)
4576 {
4577 if (!port->partner)
4578 return;
4579
4580 switch (port->negotiated_rev) {
4581 case PD_REV30:
4582 break;
4583 /*
4584 * 6.4.4.2.3 Structured VDM Version
4585 * 2.0 states "At this time, there is only one version (1.0) defined.
4586 * This field Shall be set to zero to indicate Version 1.0."
4587 * 3.0 states "This field Shall be set to 01b to indicate Version 2.0."
4588 * To ensure that we follow the Power Delivery revision we are currently
4589 * operating on, downgrade the SVDM version to the highest one supported
4590 * by the Power Delivery revision.
4591 */
4592 case PD_REV20:
4593 typec_partner_set_svdm_version(port->partner, SVDM_VER_1_0);
4594 break;
4595 default:
4596 typec_partner_set_svdm_version(port->partner, SVDM_VER_1_0);
4597 break;
4598 }
4599 }
4600
run_state_machine(struct tcpm_port * port)4601 static void run_state_machine(struct tcpm_port *port)
4602 {
4603 int ret;
4604 enum typec_pwr_opmode opmode;
4605 unsigned int msecs;
4606 enum tcpm_state upcoming_state;
4607
4608 if (port->tcpc->check_contaminant && port->state != CHECK_CONTAMINANT)
4609 port->potential_contaminant = ((port->enter_state == SRC_ATTACH_WAIT &&
4610 port->state == SRC_UNATTACHED) ||
4611 (port->enter_state == SNK_ATTACH_WAIT &&
4612 port->state == SNK_UNATTACHED) ||
4613 (port->enter_state == SNK_DEBOUNCED &&
4614 port->state == SNK_UNATTACHED));
4615
4616 port->enter_state = port->state;
4617 switch (port->state) {
4618 case TOGGLING:
4619 break;
4620 case CHECK_CONTAMINANT:
4621 port->tcpc->check_contaminant(port->tcpc);
4622 break;
4623 /* SRC states */
4624 case SRC_UNATTACHED:
4625 if (!port->non_pd_role_swap)
4626 tcpm_swap_complete(port, -ENOTCONN);
4627 tcpm_src_detach(port);
4628 if (port->potential_contaminant) {
4629 tcpm_set_state(port, CHECK_CONTAMINANT, 0);
4630 break;
4631 }
4632 if (tcpm_start_toggling(port, tcpm_rp_cc(port))) {
4633 tcpm_set_state(port, TOGGLING, 0);
4634 break;
4635 }
4636 tcpm_set_cc(port, tcpm_rp_cc(port));
4637 if (port->port_type == TYPEC_PORT_DRP)
4638 tcpm_set_state(port, SNK_UNATTACHED, PD_T_DRP_SNK);
4639 break;
4640 case SRC_ATTACH_WAIT:
4641 if (tcpm_port_is_debug(port))
4642 tcpm_set_state(port, DEBUG_ACC_ATTACHED,
4643 PD_T_CC_DEBOUNCE);
4644 else if (tcpm_port_is_audio(port))
4645 tcpm_set_state(port, AUDIO_ACC_ATTACHED,
4646 PD_T_CC_DEBOUNCE);
4647 else if (tcpm_port_is_source(port) && port->vbus_vsafe0v)
4648 tcpm_set_state(port,
4649 tcpm_try_snk(port) ? SNK_TRY
4650 : SRC_ATTACHED,
4651 PD_T_CC_DEBOUNCE);
4652 break;
4653
4654 case SNK_TRY:
4655 port->try_snk_count++;
4656 /*
4657 * Requirements:
4658 * - Do not drive vconn or vbus
4659 * - Terminate CC pins (both) to Rd
4660 * Action:
4661 * - Wait for tDRPTry (PD_T_DRP_TRY).
4662 * Until then, ignore any state changes.
4663 */
4664 tcpm_set_cc(port, TYPEC_CC_RD);
4665 tcpm_set_state(port, SNK_TRY_WAIT, PD_T_DRP_TRY);
4666 break;
4667 case SNK_TRY_WAIT:
4668 if (tcpm_port_is_sink(port)) {
4669 tcpm_set_state(port, SNK_TRY_WAIT_DEBOUNCE, 0);
4670 } else {
4671 tcpm_set_state(port, SRC_TRYWAIT, 0);
4672 port->max_wait = 0;
4673 }
4674 break;
4675 case SNK_TRY_WAIT_DEBOUNCE:
4676 tcpm_set_state(port, SNK_TRY_WAIT_DEBOUNCE_CHECK_VBUS,
4677 PD_T_TRY_CC_DEBOUNCE);
4678 break;
4679 case SNK_TRY_WAIT_DEBOUNCE_CHECK_VBUS:
4680 if (port->vbus_present && tcpm_port_is_sink(port))
4681 tcpm_set_state(port, SNK_ATTACHED, 0);
4682 else
4683 port->max_wait = 0;
4684 break;
4685 case SRC_TRYWAIT:
4686 tcpm_set_cc(port, tcpm_rp_cc(port));
4687 if (port->max_wait == 0) {
4688 port->max_wait = jiffies +
4689 msecs_to_jiffies(PD_T_DRP_TRY);
4690 tcpm_set_state(port, SRC_TRYWAIT_UNATTACHED,
4691 PD_T_DRP_TRY);
4692 } else {
4693 if (time_is_after_jiffies(port->max_wait))
4694 tcpm_set_state(port, SRC_TRYWAIT_UNATTACHED,
4695 jiffies_to_msecs(port->max_wait -
4696 jiffies));
4697 else
4698 tcpm_set_state(port, SNK_UNATTACHED, 0);
4699 }
4700 break;
4701 case SRC_TRYWAIT_DEBOUNCE:
4702 tcpm_set_state(port, SRC_ATTACHED, PD_T_CC_DEBOUNCE);
4703 break;
4704 case SRC_TRYWAIT_UNATTACHED:
4705 tcpm_set_state(port, SNK_UNATTACHED, 0);
4706 break;
4707
4708 case SRC_ATTACHED:
4709 ret = tcpm_src_attach(port);
4710 tcpm_set_state(port, SRC_UNATTACHED,
4711 ret < 0 ? 0 : PD_T_PS_SOURCE_ON);
4712 break;
4713 case SRC_STARTUP:
4714 opmode = tcpm_get_pwr_opmode(tcpm_rp_cc(port));
4715 typec_set_pwr_opmode(port->typec_port, opmode);
4716 port->pwr_opmode = TYPEC_PWR_MODE_USB;
4717 port->caps_count = 0;
4718 port->negotiated_rev = PD_MAX_REV;
4719 port->negotiated_rev_prime = PD_MAX_REV;
4720 port->message_id = 0;
4721 port->message_id_prime = 0;
4722 port->rx_msgid = -1;
4723 port->rx_msgid_prime = -1;
4724 port->explicit_contract = false;
4725 /* SNK -> SRC POWER/FAST_ROLE_SWAP finished */
4726 if (port->ams == POWER_ROLE_SWAP ||
4727 port->ams == FAST_ROLE_SWAP)
4728 tcpm_ams_finish(port);
4729 if (!port->pd_supported) {
4730 tcpm_set_state(port, SRC_READY, 0);
4731 break;
4732 }
4733 port->upcoming_state = SRC_SEND_CAPABILITIES;
4734 tcpm_ams_start(port, POWER_NEGOTIATION);
4735 break;
4736 case SRC_SEND_CAPABILITIES:
4737 port->caps_count++;
4738 if (port->caps_count > PD_N_CAPS_COUNT) {
4739 tcpm_set_state(port, SRC_READY, 0);
4740 break;
4741 }
4742 ret = tcpm_pd_send_source_caps(port);
4743 if (ret < 0) {
4744 if (tcpm_can_communicate_sop_prime(port) &&
4745 IS_ERR_OR_NULL(port->cable))
4746 tcpm_set_state(port, SRC_VDM_IDENTITY_REQUEST, 0);
4747 else
4748 tcpm_set_state(port, SRC_SEND_CAPABILITIES,
4749 PD_T_SEND_SOURCE_CAP);
4750 } else {
4751 /*
4752 * Per standard, we should clear the reset counter here.
4753 * However, that can result in state machine hang-ups.
4754 * Reset it only in READY state to improve stability.
4755 */
4756 /* port->hard_reset_count = 0; */
4757 port->caps_count = 0;
4758 port->pd_capable = true;
4759 tcpm_set_state_cond(port, SRC_SEND_CAPABILITIES_TIMEOUT,
4760 PD_T_SEND_SOURCE_CAP);
4761 }
4762 break;
4763 case SRC_SEND_CAPABILITIES_TIMEOUT:
4764 /*
4765 * Error recovery for a PD_DATA_SOURCE_CAP reply timeout.
4766 *
4767 * PD 2.0 sinks are supposed to accept src-capabilities with a
4768 * 3.0 header and simply ignore any src PDOs which the sink does
4769 * not understand such as PPS but some 2.0 sinks instead ignore
4770 * the entire PD_DATA_SOURCE_CAP message, causing contract
4771 * negotiation to fail.
4772 *
4773 * After PD_N_HARD_RESET_COUNT hard-reset attempts, we try
4774 * sending src-capabilities with a lower PD revision to
4775 * make these broken sinks work.
4776 */
4777 if (port->hard_reset_count < PD_N_HARD_RESET_COUNT) {
4778 tcpm_set_state(port, HARD_RESET_SEND, 0);
4779 } else if (port->negotiated_rev > PD_REV20) {
4780 port->negotiated_rev--;
4781 port->hard_reset_count = 0;
4782 tcpm_set_state(port, SRC_SEND_CAPABILITIES, 0);
4783 } else {
4784 tcpm_set_state(port, hard_reset_state(port), 0);
4785 }
4786 break;
4787 case SRC_NEGOTIATE_CAPABILITIES:
4788 ret = tcpm_pd_check_request(port);
4789 if (ret < 0) {
4790 tcpm_pd_send_control(port, PD_CTRL_REJECT, TCPC_TX_SOP);
4791 if (!port->explicit_contract) {
4792 tcpm_set_state(port,
4793 SRC_WAIT_NEW_CAPABILITIES, 0);
4794 } else {
4795 tcpm_set_state(port, SRC_READY, 0);
4796 }
4797 } else {
4798 tcpm_pd_send_control(port, PD_CTRL_ACCEPT, TCPC_TX_SOP);
4799 tcpm_set_partner_usb_comm_capable(port,
4800 !!(port->sink_request & RDO_USB_COMM));
4801 tcpm_set_state(port, SRC_TRANSITION_SUPPLY,
4802 PD_T_SRC_TRANSITION);
4803 }
4804 break;
4805 case SRC_TRANSITION_SUPPLY:
4806 /* XXX: regulator_set_voltage(vbus, ...) */
4807 tcpm_pd_send_control(port, PD_CTRL_PS_RDY, TCPC_TX_SOP);
4808 port->explicit_contract = true;
4809 typec_set_pwr_opmode(port->typec_port, TYPEC_PWR_MODE_PD);
4810 port->pwr_opmode = TYPEC_PWR_MODE_PD;
4811 tcpm_set_state_cond(port, SRC_READY, 0);
4812 break;
4813 case SRC_READY:
4814 #if 1
4815 port->hard_reset_count = 0;
4816 #endif
4817 port->try_src_count = 0;
4818
4819 tcpm_swap_complete(port, 0);
4820 tcpm_typec_connect(port);
4821
4822 if (port->ams != NONE_AMS)
4823 tcpm_ams_finish(port);
4824 if (port->next_ams != NONE_AMS) {
4825 port->ams = port->next_ams;
4826 port->next_ams = NONE_AMS;
4827 }
4828
4829 /*
4830 * If previous AMS is interrupted, switch to the upcoming
4831 * state.
4832 */
4833 if (port->upcoming_state != INVALID_STATE) {
4834 upcoming_state = port->upcoming_state;
4835 port->upcoming_state = INVALID_STATE;
4836 tcpm_set_state(port, upcoming_state, 0);
4837 break;
4838 }
4839
4840 /*
4841 * 6.4.4.3.1 Discover Identity
4842 * "The Discover Identity Command Shall only be sent to SOP when there is an
4843 * Explicit Contract."
4844 *
4845 * Discover Identity on SOP' should be discovered prior to the
4846 * ready state, but if done after a Vconn Swap following Discover
4847 * Identity on SOP then the discovery process can be run here
4848 * as well.
4849 */
4850 if (port->explicit_contract) {
4851 if (port->send_discover_prime) {
4852 port->tx_sop_type = TCPC_TX_SOP_PRIME;
4853 } else {
4854 port->tx_sop_type = TCPC_TX_SOP;
4855 tcpm_set_initial_svdm_version(port);
4856 }
4857 mod_send_discover_delayed_work(port, 0);
4858 } else {
4859 port->send_discover = false;
4860 port->send_discover_prime = false;
4861 }
4862
4863 /*
4864 * 6.3.5
4865 * Sending ping messages is not necessary if
4866 * - the source operates at vSafe5V
4867 * or
4868 * - The system is not operating in PD mode
4869 * or
4870 * - Both partners are connected using a Type-C connector
4871 *
4872 * There is no actual need to send PD messages since the local
4873 * port type-c and the spec does not clearly say whether PD is
4874 * possible when type-c is connected to Type-A/B
4875 */
4876 break;
4877 case SRC_WAIT_NEW_CAPABILITIES:
4878 /* Nothing to do... */
4879 break;
4880
4881 /* SNK states */
4882 case SNK_UNATTACHED:
4883 if (!port->non_pd_role_swap)
4884 tcpm_swap_complete(port, -ENOTCONN);
4885 tcpm_pps_complete(port, -ENOTCONN);
4886 tcpm_snk_detach(port);
4887 if (port->potential_contaminant) {
4888 tcpm_set_state(port, CHECK_CONTAMINANT, 0);
4889 break;
4890 }
4891 if (tcpm_start_toggling(port, TYPEC_CC_RD)) {
4892 tcpm_set_state(port, TOGGLING, 0);
4893 break;
4894 }
4895 tcpm_set_cc(port, TYPEC_CC_RD);
4896 if (port->port_type == TYPEC_PORT_DRP)
4897 tcpm_set_state(port, SRC_UNATTACHED, PD_T_DRP_SRC);
4898 break;
4899 case SNK_ATTACH_WAIT:
4900 if ((port->cc1 == TYPEC_CC_OPEN &&
4901 port->cc2 != TYPEC_CC_OPEN) ||
4902 (port->cc1 != TYPEC_CC_OPEN &&
4903 port->cc2 == TYPEC_CC_OPEN))
4904 tcpm_set_state(port, SNK_DEBOUNCED,
4905 PD_T_CC_DEBOUNCE);
4906 else if (tcpm_port_is_disconnected(port))
4907 tcpm_set_state(port, SNK_UNATTACHED,
4908 PD_T_PD_DEBOUNCE);
4909 break;
4910 case SNK_DEBOUNCED:
4911 if (tcpm_port_is_disconnected(port))
4912 tcpm_set_state(port, SNK_UNATTACHED,
4913 PD_T_PD_DEBOUNCE);
4914 else if (port->vbus_present)
4915 tcpm_set_state(port,
4916 tcpm_try_src(port) ? SRC_TRY
4917 : SNK_ATTACHED,
4918 0);
4919 break;
4920 case SRC_TRY:
4921 port->try_src_count++;
4922 tcpm_set_cc(port, tcpm_rp_cc(port));
4923 port->max_wait = 0;
4924 tcpm_set_state(port, SRC_TRY_WAIT, 0);
4925 break;
4926 case SRC_TRY_WAIT:
4927 if (port->max_wait == 0) {
4928 port->max_wait = jiffies +
4929 msecs_to_jiffies(PD_T_DRP_TRY);
4930 msecs = PD_T_DRP_TRY;
4931 } else {
4932 if (time_is_after_jiffies(port->max_wait))
4933 msecs = jiffies_to_msecs(port->max_wait -
4934 jiffies);
4935 else
4936 msecs = 0;
4937 }
4938 tcpm_set_state(port, SNK_TRYWAIT, msecs);
4939 break;
4940 case SRC_TRY_DEBOUNCE:
4941 tcpm_set_state(port, SRC_ATTACHED, PD_T_PD_DEBOUNCE);
4942 break;
4943 case SNK_TRYWAIT:
4944 tcpm_set_cc(port, TYPEC_CC_RD);
4945 tcpm_set_state(port, SNK_TRYWAIT_VBUS, PD_T_CC_DEBOUNCE);
4946 break;
4947 case SNK_TRYWAIT_VBUS:
4948 /*
4949 * TCPM stays in this state indefinitely until VBUS
4950 * is detected as long as Rp is not detected for
4951 * more than a time period of tPDDebounce.
4952 */
4953 if (port->vbus_present && tcpm_port_is_sink(port)) {
4954 tcpm_set_state(port, SNK_ATTACHED, 0);
4955 break;
4956 }
4957 if (!tcpm_port_is_sink(port))
4958 tcpm_set_state(port, SNK_TRYWAIT_DEBOUNCE, 0);
4959 break;
4960 case SNK_TRYWAIT_DEBOUNCE:
4961 tcpm_set_state(port, SNK_UNATTACHED, PD_T_PD_DEBOUNCE);
4962 break;
4963 case SNK_ATTACHED:
4964 ret = tcpm_snk_attach(port);
4965 if (ret < 0)
4966 tcpm_set_state(port, SNK_UNATTACHED, 0);
4967 else
4968 tcpm_set_state(port, SNK_STARTUP, 0);
4969 break;
4970 case SNK_STARTUP:
4971 opmode = tcpm_get_pwr_opmode(port->polarity ?
4972 port->cc2 : port->cc1);
4973 typec_set_pwr_opmode(port->typec_port, opmode);
4974 port->pwr_opmode = TYPEC_PWR_MODE_USB;
4975 port->negotiated_rev = PD_MAX_REV;
4976 port->negotiated_rev_prime = PD_MAX_REV;
4977 port->message_id = 0;
4978 port->message_id_prime = 0;
4979 port->rx_msgid = -1;
4980 port->rx_msgid_prime = -1;
4981 port->explicit_contract = false;
4982
4983 if (port->ams == POWER_ROLE_SWAP ||
4984 port->ams == FAST_ROLE_SWAP)
4985 /* SRC -> SNK POWER/FAST_ROLE_SWAP finished */
4986 tcpm_ams_finish(port);
4987
4988 tcpm_set_state(port, SNK_DISCOVERY, 0);
4989 break;
4990 case SNK_DISCOVERY:
4991 if (port->vbus_present) {
4992 u32 current_lim = tcpm_get_current_limit(port);
4993
4994 if (port->slow_charger_loop && (current_lim > PD_P_SNK_STDBY_MW / 5))
4995 current_lim = PD_P_SNK_STDBY_MW / 5;
4996 tcpm_set_current_limit(port, current_lim, 5000);
4997 /* Not sink vbus if operational current is 0mA */
4998 tcpm_set_charge(port, !port->pd_supported ||
4999 pdo_max_current(port->snk_pdo[0]));
5000
5001 if (!port->pd_supported)
5002 tcpm_set_state(port, SNK_READY, 0);
5003 else
5004 tcpm_set_state(port, SNK_WAIT_CAPABILITIES, 0);
5005 break;
5006 }
5007 /*
5008 * For DRP, timeouts differ. Also, handling is supposed to be
5009 * different and much more complex (dead battery detection;
5010 * see USB power delivery specification, section 8.3.3.6.1.5.1).
5011 */
5012 tcpm_set_state(port, hard_reset_state(port),
5013 port->port_type == TYPEC_PORT_DRP ?
5014 PD_T_DB_DETECT : PD_T_NO_RESPONSE);
5015 break;
5016 case SNK_DISCOVERY_DEBOUNCE:
5017 tcpm_set_state(port, SNK_DISCOVERY_DEBOUNCE_DONE,
5018 PD_T_CC_DEBOUNCE);
5019 break;
5020 case SNK_DISCOVERY_DEBOUNCE_DONE:
5021 if (!tcpm_port_is_disconnected(port) &&
5022 tcpm_port_is_sink(port) &&
5023 ktime_after(port->delayed_runtime, ktime_get())) {
5024 tcpm_set_state(port, SNK_DISCOVERY,
5025 ktime_to_ms(ktime_sub(port->delayed_runtime, ktime_get())));
5026 break;
5027 }
5028 tcpm_set_state(port, unattached_state(port), 0);
5029 break;
5030 case SNK_WAIT_CAPABILITIES:
5031 ret = port->tcpc->set_pd_rx(port->tcpc, true);
5032 if (ret < 0) {
5033 tcpm_set_state(port, SNK_READY, 0);
5034 break;
5035 }
5036 /*
5037 * If VBUS has never been low, and we time out waiting
5038 * for source cap, try a soft reset first, in case we
5039 * were already in a stable contract before this boot.
5040 * Do this only once.
5041 */
5042 if (port->vbus_never_low) {
5043 port->vbus_never_low = false;
5044 tcpm_set_state(port, SNK_SOFT_RESET,
5045 PD_T_SINK_WAIT_CAP);
5046 } else {
5047 if (!port->self_powered)
5048 upcoming_state = SNK_WAIT_CAPABILITIES_TIMEOUT;
5049 else
5050 upcoming_state = hard_reset_state(port);
5051 tcpm_set_state(port, upcoming_state, PD_T_SINK_WAIT_CAP);
5052 }
5053 break;
5054 case SNK_WAIT_CAPABILITIES_TIMEOUT:
5055 /*
5056 * There are some USB PD sources in the field, which do not
5057 * properly implement the specification and fail to start
5058 * sending Source Capability messages after a soft reset. The
5059 * specification suggests to do a hard reset when no Source
5060 * capability message is received within PD_T_SINK_WAIT_CAP,
5061 * but that might effectively kil the machine's power source.
5062 *
5063 * This slightly diverges from the specification and tries to
5064 * recover from this by explicitly asking for the capabilities
5065 * using the Get_Source_Cap control message before falling back
5066 * to a hard reset. The control message should also be supported
5067 * and handled by all USB PD source and dual role devices
5068 * according to the specification.
5069 */
5070 if (tcpm_pd_send_control(port, PD_CTRL_GET_SOURCE_CAP, TCPC_TX_SOP))
5071 tcpm_set_state_cond(port, hard_reset_state(port), 0);
5072 else
5073 tcpm_set_state(port, hard_reset_state(port), PD_T_SINK_WAIT_CAP);
5074 break;
5075 case SNK_NEGOTIATE_CAPABILITIES:
5076 port->pd_capable = true;
5077 tcpm_set_partner_usb_comm_capable(port,
5078 !!(port->source_caps[0] & PDO_FIXED_USB_COMM));
5079 port->hard_reset_count = 0;
5080 ret = tcpm_pd_send_request(port);
5081 if (ret < 0) {
5082 /* Restore back to the original state */
5083 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_PD,
5084 port->pps_data.active,
5085 port->supply_voltage);
5086 /* Let the Source send capabilities again. */
5087 tcpm_set_state(port, SNK_WAIT_CAPABILITIES, 0);
5088 } else {
5089 tcpm_set_state_cond(port, hard_reset_state(port),
5090 PD_T_SENDER_RESPONSE);
5091 }
5092 break;
5093 case SNK_NEGOTIATE_PPS_CAPABILITIES:
5094 ret = tcpm_pd_send_pps_request(port);
5095 if (ret < 0) {
5096 /* Restore back to the original state */
5097 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_PD,
5098 port->pps_data.active,
5099 port->supply_voltage);
5100 port->pps_status = ret;
5101 /*
5102 * If this was called due to updates to sink
5103 * capabilities, and pps is no longer valid, we should
5104 * safely fall back to a standard PDO.
5105 */
5106 if (port->update_sink_caps)
5107 tcpm_set_state(port, SNK_NEGOTIATE_CAPABILITIES, 0);
5108 else
5109 tcpm_set_state(port, SNK_READY, 0);
5110 } else {
5111 tcpm_set_state_cond(port, hard_reset_state(port),
5112 PD_T_SENDER_RESPONSE);
5113 }
5114 break;
5115 case SNK_TRANSITION_SINK:
5116 /* From the USB PD spec:
5117 * "The Sink Shall transition to Sink Standby before a positive or
5118 * negative voltage transition of VBUS. During Sink Standby
5119 * the Sink Shall reduce its power draw to pSnkStdby."
5120 *
5121 * This is not applicable to PPS though as the port can continue
5122 * to draw negotiated power without switching to standby.
5123 */
5124 if (port->supply_voltage != port->req_supply_voltage && !port->pps_data.active &&
5125 port->current_limit * port->supply_voltage / 1000 > PD_P_SNK_STDBY_MW) {
5126 u32 stdby_ma = PD_P_SNK_STDBY_MW * 1000 / port->supply_voltage;
5127
5128 tcpm_log(port, "Setting standby current %u mV @ %u mA",
5129 port->supply_voltage, stdby_ma);
5130 tcpm_set_current_limit(port, stdby_ma, port->supply_voltage);
5131 }
5132 fallthrough;
5133 case SNK_TRANSITION_SINK_VBUS:
5134 tcpm_set_state(port, hard_reset_state(port),
5135 PD_T_PS_TRANSITION);
5136 break;
5137 case SNK_READY:
5138 port->try_snk_count = 0;
5139 port->update_sink_caps = false;
5140 if (port->explicit_contract) {
5141 typec_set_pwr_opmode(port->typec_port,
5142 TYPEC_PWR_MODE_PD);
5143 port->pwr_opmode = TYPEC_PWR_MODE_PD;
5144 }
5145
5146 if (!port->pd_capable && port->slow_charger_loop)
5147 tcpm_set_current_limit(port, tcpm_get_current_limit(port), 5000);
5148 tcpm_swap_complete(port, 0);
5149 tcpm_typec_connect(port);
5150 if (port->pd_capable && port->source_caps[0] & PDO_FIXED_DUAL_ROLE)
5151 mod_enable_frs_delayed_work(port, 0);
5152 tcpm_pps_complete(port, port->pps_status);
5153
5154 if (port->ams != NONE_AMS)
5155 tcpm_ams_finish(port);
5156 if (port->next_ams != NONE_AMS) {
5157 port->ams = port->next_ams;
5158 port->next_ams = NONE_AMS;
5159 }
5160
5161 /*
5162 * If previous AMS is interrupted, switch to the upcoming
5163 * state.
5164 */
5165 if (port->upcoming_state != INVALID_STATE) {
5166 upcoming_state = port->upcoming_state;
5167 port->upcoming_state = INVALID_STATE;
5168 tcpm_set_state(port, upcoming_state, 0);
5169 break;
5170 }
5171
5172 /*
5173 * 6.4.4.3.1 Discover Identity
5174 * "The Discover Identity Command Shall only be sent to SOP when there is an
5175 * Explicit Contract."
5176 *
5177 * Discover Identity on SOP' should be discovered prior to the
5178 * ready state, but if done after a Vconn Swap following Discover
5179 * Identity on SOP then the discovery process can be run here
5180 * as well.
5181 */
5182 if (port->explicit_contract) {
5183 if (port->send_discover_prime) {
5184 port->tx_sop_type = TCPC_TX_SOP_PRIME;
5185 } else {
5186 port->tx_sop_type = TCPC_TX_SOP;
5187 tcpm_set_initial_svdm_version(port);
5188 }
5189 mod_send_discover_delayed_work(port, 0);
5190 } else {
5191 port->send_discover = false;
5192 port->send_discover_prime = false;
5193 }
5194
5195 power_supply_changed(port->psy);
5196 break;
5197
5198 /* Accessory states */
5199 case ACC_UNATTACHED:
5200 tcpm_acc_detach(port);
5201 tcpm_set_state(port, SRC_UNATTACHED, 0);
5202 break;
5203 case DEBUG_ACC_ATTACHED:
5204 case AUDIO_ACC_ATTACHED:
5205 ret = tcpm_acc_attach(port);
5206 if (ret < 0)
5207 tcpm_set_state(port, ACC_UNATTACHED, 0);
5208 break;
5209 case AUDIO_ACC_DEBOUNCE:
5210 tcpm_set_state(port, ACC_UNATTACHED, PD_T_CC_DEBOUNCE);
5211 break;
5212
5213 /* Hard_Reset states */
5214 case HARD_RESET_SEND:
5215 if (port->ams != NONE_AMS)
5216 tcpm_ams_finish(port);
5217 if (!port->self_powered && port->port_type == TYPEC_PORT_SNK)
5218 dev_err(port->dev, "Initiating hard-reset, which might result in machine power-loss.\n");
5219 /*
5220 * State machine will be directed to HARD_RESET_START,
5221 * thus set upcoming_state to INVALID_STATE.
5222 */
5223 port->upcoming_state = INVALID_STATE;
5224 tcpm_ams_start(port, HARD_RESET);
5225 break;
5226 case HARD_RESET_START:
5227 port->sink_cap_done = false;
5228 if (port->tcpc->enable_frs)
5229 port->tcpc->enable_frs(port->tcpc, false);
5230 port->hard_reset_count++;
5231 port->tcpc->set_pd_rx(port->tcpc, false);
5232 tcpm_unregister_altmodes(port);
5233 port->nr_sink_caps = 0;
5234 port->send_discover = true;
5235 port->send_discover_prime = false;
5236 if (port->pwr_role == TYPEC_SOURCE)
5237 tcpm_set_state(port, SRC_HARD_RESET_VBUS_OFF,
5238 PD_T_PS_HARD_RESET);
5239 else
5240 tcpm_set_state(port, SNK_HARD_RESET_SINK_OFF, 0);
5241 break;
5242 case SRC_HARD_RESET_VBUS_OFF:
5243 /*
5244 * 7.1.5 Response to Hard Resets
5245 * Hard Reset Signaling indicates a communication failure has occurred and the
5246 * Source Shall stop driving VCONN, Shall remove Rp from the VCONN pin and Shall
5247 * drive VBUS to vSafe0V as shown in Figure 7-9.
5248 */
5249 tcpm_set_vconn(port, false);
5250 tcpm_set_vbus(port, false);
5251 tcpm_set_roles(port, port->self_powered, TYPEC_SOURCE,
5252 tcpm_data_role_for_source(port));
5253 /*
5254 * If tcpc fails to notify vbus off, TCPM will wait for PD_T_SAFE_0V +
5255 * PD_T_SRC_RECOVER before turning vbus back on.
5256 * From Table 7-12 Sequence Description for a Source Initiated Hard Reset:
5257 * 4. Policy Engine waits tPSHardReset after sending Hard Reset Signaling and then
5258 * tells the Device Policy Manager to instruct the power supply to perform a
5259 * Hard Reset. The transition to vSafe0V Shall occur within tSafe0V (t2).
5260 * 5. After tSrcRecover the Source applies power to VBUS in an attempt to
5261 * re-establish communication with the Sink and resume USB Default Operation.
5262 * The transition to vSafe5V Shall occur within tSrcTurnOn(t4).
5263 */
5264 tcpm_set_state(port, SRC_HARD_RESET_VBUS_ON, PD_T_SAFE_0V + PD_T_SRC_RECOVER);
5265 break;
5266 case SRC_HARD_RESET_VBUS_ON:
5267 tcpm_set_vconn(port, true);
5268 tcpm_set_vbus(port, true);
5269 if (port->ams == HARD_RESET)
5270 tcpm_ams_finish(port);
5271 if (port->pd_supported)
5272 port->tcpc->set_pd_rx(port->tcpc, true);
5273 tcpm_set_attached_state(port, true);
5274 tcpm_set_state(port, SRC_UNATTACHED, PD_T_PS_SOURCE_ON);
5275 break;
5276 case SNK_HARD_RESET_SINK_OFF:
5277 /* Do not discharge/disconnect during hard reseet */
5278 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_USB, false, 0);
5279 memset(&port->pps_data, 0, sizeof(port->pps_data));
5280 tcpm_set_vconn(port, false);
5281 if (port->pd_capable)
5282 tcpm_set_charge(port, false);
5283 tcpm_set_roles(port, port->self_powered, TYPEC_SINK,
5284 tcpm_data_role_for_sink(port));
5285 /*
5286 * VBUS may or may not toggle, depending on the adapter.
5287 * If it doesn't toggle, transition to SNK_HARD_RESET_SINK_ON
5288 * directly after timeout.
5289 */
5290 tcpm_set_state(port, SNK_HARD_RESET_SINK_ON, PD_T_SAFE_0V);
5291 break;
5292 case SNK_HARD_RESET_WAIT_VBUS:
5293 if (port->ams == HARD_RESET)
5294 tcpm_ams_finish(port);
5295 /* Assume we're disconnected if VBUS doesn't come back. */
5296 tcpm_set_state(port, SNK_UNATTACHED,
5297 PD_T_SRC_RECOVER_MAX + PD_T_SRC_TURN_ON);
5298 break;
5299 case SNK_HARD_RESET_SINK_ON:
5300 /* Note: There is no guarantee that VBUS is on in this state */
5301 /*
5302 * XXX:
5303 * The specification suggests that dual mode ports in sink
5304 * mode should transition to state PE_SRC_Transition_to_default.
5305 * See USB power delivery specification chapter 8.3.3.6.1.3.
5306 * This would mean to
5307 * - turn off VCONN, reset power supply
5308 * - request hardware reset
5309 * - turn on VCONN
5310 * - Transition to state PE_Src_Startup
5311 * SNK only ports shall transition to state Snk_Startup
5312 * (see chapter 8.3.3.3.8).
5313 * Similar, dual-mode ports in source mode should transition
5314 * to PE_SNK_Transition_to_default.
5315 */
5316 if (port->pd_capable) {
5317 tcpm_set_current_limit(port,
5318 tcpm_get_current_limit(port),
5319 5000);
5320 /* Not sink vbus if operational current is 0mA */
5321 tcpm_set_charge(port, !!pdo_max_current(port->snk_pdo[0]));
5322 }
5323 if (port->ams == HARD_RESET)
5324 tcpm_ams_finish(port);
5325 tcpm_set_attached_state(port, true);
5326 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_USB, false, VSAFE5V);
5327 tcpm_set_state(port, SNK_STARTUP, 0);
5328 break;
5329
5330 /* Soft_Reset states */
5331 case SOFT_RESET:
5332 port->message_id = 0;
5333 port->rx_msgid = -1;
5334 /* remove existing capabilities */
5335 usb_power_delivery_unregister_capabilities(port->partner_source_caps);
5336 port->partner_source_caps = NULL;
5337 tcpm_pd_send_control(port, PD_CTRL_ACCEPT, TCPC_TX_SOP);
5338 tcpm_ams_finish(port);
5339 if (port->pwr_role == TYPEC_SOURCE) {
5340 port->upcoming_state = SRC_SEND_CAPABILITIES;
5341 tcpm_ams_start(port, POWER_NEGOTIATION);
5342 } else {
5343 tcpm_set_state(port, SNK_WAIT_CAPABILITIES, 0);
5344 }
5345 break;
5346 case SRC_SOFT_RESET_WAIT_SNK_TX:
5347 case SNK_SOFT_RESET:
5348 if (port->ams != NONE_AMS)
5349 tcpm_ams_finish(port);
5350 port->upcoming_state = SOFT_RESET_SEND;
5351 tcpm_ams_start(port, SOFT_RESET_AMS);
5352 break;
5353 case SOFT_RESET_SEND:
5354 /*
5355 * Power Delivery 3.0 Section 6.3.13
5356 *
5357 * A Soft_Reset Message Shall be targeted at a specific entity
5358 * depending on the type of SOP* packet used.
5359 */
5360 if (port->tx_sop_type == TCPC_TX_SOP_PRIME) {
5361 port->message_id_prime = 0;
5362 port->rx_msgid_prime = -1;
5363 tcpm_pd_send_control(port, PD_CTRL_SOFT_RESET, TCPC_TX_SOP_PRIME);
5364 tcpm_set_state_cond(port, ready_state(port), PD_T_SENDER_RESPONSE);
5365 } else {
5366 port->message_id = 0;
5367 port->rx_msgid = -1;
5368 /* remove existing capabilities */
5369 usb_power_delivery_unregister_capabilities(port->partner_source_caps);
5370 port->partner_source_caps = NULL;
5371 if (tcpm_pd_send_control(port, PD_CTRL_SOFT_RESET, TCPC_TX_SOP))
5372 tcpm_set_state_cond(port, hard_reset_state(port), 0);
5373 else
5374 tcpm_set_state_cond(port, hard_reset_state(port),
5375 PD_T_SENDER_RESPONSE);
5376 }
5377 break;
5378
5379 /* DR_Swap states */
5380 case DR_SWAP_SEND:
5381 tcpm_pd_send_control(port, PD_CTRL_DR_SWAP, TCPC_TX_SOP);
5382 if (port->data_role == TYPEC_DEVICE || port->negotiated_rev > PD_REV20) {
5383 port->send_discover = true;
5384 port->send_discover_prime = false;
5385 }
5386 tcpm_set_state_cond(port, DR_SWAP_SEND_TIMEOUT,
5387 PD_T_SENDER_RESPONSE);
5388 break;
5389 case DR_SWAP_ACCEPT:
5390 tcpm_pd_send_control(port, PD_CTRL_ACCEPT, TCPC_TX_SOP);
5391 if (port->data_role == TYPEC_DEVICE || port->negotiated_rev > PD_REV20) {
5392 port->send_discover = true;
5393 port->send_discover_prime = false;
5394 }
5395 tcpm_set_state_cond(port, DR_SWAP_CHANGE_DR, 0);
5396 break;
5397 case DR_SWAP_SEND_TIMEOUT:
5398 tcpm_swap_complete(port, -ETIMEDOUT);
5399 port->send_discover = false;
5400 port->send_discover_prime = false;
5401 tcpm_ams_finish(port);
5402 tcpm_set_state(port, ready_state(port), 0);
5403 break;
5404 case DR_SWAP_CHANGE_DR:
5405 tcpm_unregister_altmodes(port);
5406 if (port->data_role == TYPEC_HOST)
5407 tcpm_set_roles(port, true, port->pwr_role,
5408 TYPEC_DEVICE);
5409 else
5410 tcpm_set_roles(port, true, port->pwr_role,
5411 TYPEC_HOST);
5412 tcpm_ams_finish(port);
5413 tcpm_set_state(port, ready_state(port), 0);
5414 break;
5415
5416 case FR_SWAP_SEND:
5417 if (tcpm_pd_send_control(port, PD_CTRL_FR_SWAP, TCPC_TX_SOP)) {
5418 tcpm_set_state(port, ERROR_RECOVERY, 0);
5419 break;
5420 }
5421 tcpm_set_state_cond(port, FR_SWAP_SEND_TIMEOUT, PD_T_SENDER_RESPONSE);
5422 break;
5423 case FR_SWAP_SEND_TIMEOUT:
5424 tcpm_set_state(port, ERROR_RECOVERY, 0);
5425 break;
5426 case FR_SWAP_SNK_SRC_TRANSITION_TO_OFF:
5427 tcpm_set_state(port, ERROR_RECOVERY, PD_T_PS_SOURCE_OFF);
5428 break;
5429 case FR_SWAP_SNK_SRC_NEW_SINK_READY:
5430 if (port->vbus_source)
5431 tcpm_set_state(port, FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED, 0);
5432 else
5433 tcpm_set_state(port, ERROR_RECOVERY, PD_T_RECEIVER_RESPONSE);
5434 break;
5435 case FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED:
5436 tcpm_set_pwr_role(port, TYPEC_SOURCE);
5437 if (tcpm_pd_send_control(port, PD_CTRL_PS_RDY, TCPC_TX_SOP)) {
5438 tcpm_set_state(port, ERROR_RECOVERY, 0);
5439 break;
5440 }
5441 tcpm_set_cc(port, tcpm_rp_cc(port));
5442 tcpm_set_state(port, SRC_STARTUP, PD_T_SWAP_SRC_START);
5443 break;
5444
5445 /* PR_Swap states */
5446 case PR_SWAP_ACCEPT:
5447 tcpm_pd_send_control(port, PD_CTRL_ACCEPT, TCPC_TX_SOP);
5448 tcpm_set_state(port, PR_SWAP_START, 0);
5449 break;
5450 case PR_SWAP_SEND:
5451 tcpm_pd_send_control(port, PD_CTRL_PR_SWAP, TCPC_TX_SOP);
5452 tcpm_set_state_cond(port, PR_SWAP_SEND_TIMEOUT,
5453 PD_T_SENDER_RESPONSE);
5454 break;
5455 case PR_SWAP_SEND_TIMEOUT:
5456 tcpm_swap_complete(port, -ETIMEDOUT);
5457 tcpm_set_state(port, ready_state(port), 0);
5458 break;
5459 case PR_SWAP_START:
5460 tcpm_apply_rc(port);
5461 if (port->pwr_role == TYPEC_SOURCE)
5462 tcpm_set_state(port, PR_SWAP_SRC_SNK_TRANSITION_OFF,
5463 PD_T_SRC_TRANSITION);
5464 else
5465 tcpm_set_state(port, PR_SWAP_SNK_SRC_SINK_OFF, 0);
5466 break;
5467 case PR_SWAP_SRC_SNK_TRANSITION_OFF:
5468 /*
5469 * Prevent vbus discharge circuit from turning on during PR_SWAP
5470 * as this is not a disconnect.
5471 */
5472 tcpm_set_vbus(port, false);
5473 port->explicit_contract = false;
5474 /* allow time for Vbus discharge, must be < tSrcSwapStdby */
5475 tcpm_set_state(port, PR_SWAP_SRC_SNK_SOURCE_OFF,
5476 PD_T_SRCSWAPSTDBY);
5477 break;
5478 case PR_SWAP_SRC_SNK_SOURCE_OFF:
5479 tcpm_set_cc(port, TYPEC_CC_RD);
5480 /* allow CC debounce */
5481 tcpm_set_state(port, PR_SWAP_SRC_SNK_SOURCE_OFF_CC_DEBOUNCED,
5482 PD_T_CC_DEBOUNCE);
5483 break;
5484 case PR_SWAP_SRC_SNK_SOURCE_OFF_CC_DEBOUNCED:
5485 /*
5486 * USB-PD standard, 6.2.1.4, Port Power Role:
5487 * "During the Power Role Swap Sequence, for the initial Source
5488 * Port, the Port Power Role field shall be set to Sink in the
5489 * PS_RDY Message indicating that the initial Source’s power
5490 * supply is turned off"
5491 */
5492 tcpm_set_pwr_role(port, TYPEC_SINK);
5493 if (tcpm_pd_send_control(port, PD_CTRL_PS_RDY, TCPC_TX_SOP)) {
5494 tcpm_set_state(port, ERROR_RECOVERY, 0);
5495 break;
5496 }
5497 tcpm_set_state(port, ERROR_RECOVERY, PD_T_PS_SOURCE_ON_PRS);
5498 break;
5499 case PR_SWAP_SRC_SNK_SINK_ON:
5500 tcpm_enable_auto_vbus_discharge(port, true);
5501 /* Set the vbus disconnect threshold for implicit contract */
5502 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_USB, false, VSAFE5V);
5503 tcpm_set_state(port, SNK_STARTUP, 0);
5504 break;
5505 case PR_SWAP_SNK_SRC_SINK_OFF:
5506 /* will be source, remove existing capabilities */
5507 usb_power_delivery_unregister_capabilities(port->partner_source_caps);
5508 port->partner_source_caps = NULL;
5509 /*
5510 * Prevent vbus discharge circuit from turning on during PR_SWAP
5511 * as this is not a disconnect.
5512 */
5513 tcpm_set_auto_vbus_discharge_threshold(port, TYPEC_PWR_MODE_USB,
5514 port->pps_data.active, 0);
5515 tcpm_set_charge(port, false);
5516 tcpm_set_state(port, hard_reset_state(port),
5517 PD_T_PS_SOURCE_OFF);
5518 break;
5519 case PR_SWAP_SNK_SRC_SOURCE_ON:
5520 tcpm_enable_auto_vbus_discharge(port, true);
5521 tcpm_set_cc(port, tcpm_rp_cc(port));
5522 tcpm_set_vbus(port, true);
5523 /*
5524 * allow time VBUS ramp-up, must be < tNewSrc
5525 * Also, this window overlaps with CC debounce as well.
5526 * So, Wait for the max of two which is PD_T_NEWSRC
5527 */
5528 tcpm_set_state(port, PR_SWAP_SNK_SRC_SOURCE_ON_VBUS_RAMPED_UP,
5529 PD_T_NEWSRC);
5530 break;
5531 case PR_SWAP_SNK_SRC_SOURCE_ON_VBUS_RAMPED_UP:
5532 /*
5533 * USB PD standard, 6.2.1.4:
5534 * "Subsequent Messages initiated by the Policy Engine,
5535 * such as the PS_RDY Message sent to indicate that Vbus
5536 * is ready, will have the Port Power Role field set to
5537 * Source."
5538 */
5539 tcpm_set_pwr_role(port, TYPEC_SOURCE);
5540 tcpm_pd_send_control(port, PD_CTRL_PS_RDY, TCPC_TX_SOP);
5541 tcpm_set_state(port, SRC_STARTUP, PD_T_SWAP_SRC_START);
5542 break;
5543
5544 case VCONN_SWAP_ACCEPT:
5545 tcpm_pd_send_control(port, PD_CTRL_ACCEPT, TCPC_TX_SOP);
5546 tcpm_ams_finish(port);
5547 tcpm_set_state(port, VCONN_SWAP_START, 0);
5548 break;
5549 case VCONN_SWAP_SEND:
5550 tcpm_pd_send_control(port, PD_CTRL_VCONN_SWAP, TCPC_TX_SOP);
5551 tcpm_set_state(port, VCONN_SWAP_SEND_TIMEOUT,
5552 PD_T_SENDER_RESPONSE);
5553 break;
5554 case VCONN_SWAP_SEND_TIMEOUT:
5555 tcpm_swap_complete(port, -ETIMEDOUT);
5556 tcpm_set_state(port, ready_state(port), 0);
5557 break;
5558 case VCONN_SWAP_START:
5559 if (port->vconn_role == TYPEC_SOURCE)
5560 tcpm_set_state(port, VCONN_SWAP_WAIT_FOR_VCONN, 0);
5561 else
5562 tcpm_set_state(port, VCONN_SWAP_TURN_ON_VCONN, 0);
5563 break;
5564 case VCONN_SWAP_WAIT_FOR_VCONN:
5565 tcpm_set_state(port, hard_reset_state(port),
5566 PD_T_VCONN_SOURCE_ON);
5567 break;
5568 case VCONN_SWAP_TURN_ON_VCONN:
5569 ret = tcpm_set_vconn(port, true);
5570 tcpm_pd_send_control(port, PD_CTRL_PS_RDY, TCPC_TX_SOP);
5571 /*
5572 * USB PD 3.0 Section 6.4.4.3.1
5573 *
5574 * Note that a Cable Plug or VPD will not be ready for PD
5575 * Communication until tVCONNStable after VCONN has been applied
5576 */
5577 if (!ret)
5578 tcpm_set_state(port, VCONN_SWAP_SEND_SOFT_RESET,
5579 PD_T_VCONN_STABLE);
5580 else
5581 tcpm_set_state(port, ready_state(port), 0);
5582 break;
5583 case VCONN_SWAP_TURN_OFF_VCONN:
5584 tcpm_set_vconn(port, false);
5585 tcpm_set_state(port, ready_state(port), 0);
5586 break;
5587 case VCONN_SWAP_SEND_SOFT_RESET:
5588 tcpm_swap_complete(port, port->swap_status);
5589 if (tcpm_can_communicate_sop_prime(port)) {
5590 port->tx_sop_type = TCPC_TX_SOP_PRIME;
5591 port->upcoming_state = SOFT_RESET_SEND;
5592 tcpm_ams_start(port, SOFT_RESET_AMS);
5593 } else {
5594 tcpm_set_state(port, ready_state(port), 0);
5595 }
5596 break;
5597
5598 case DR_SWAP_CANCEL:
5599 case PR_SWAP_CANCEL:
5600 case VCONN_SWAP_CANCEL:
5601 tcpm_swap_complete(port, port->swap_status);
5602 if (port->pwr_role == TYPEC_SOURCE)
5603 tcpm_set_state(port, SRC_READY, 0);
5604 else
5605 tcpm_set_state(port, SNK_READY, 0);
5606 break;
5607 case FR_SWAP_CANCEL:
5608 if (port->pwr_role == TYPEC_SOURCE)
5609 tcpm_set_state(port, SRC_READY, 0);
5610 else
5611 tcpm_set_state(port, SNK_READY, 0);
5612 break;
5613
5614 case BIST_RX:
5615 switch (BDO_MODE_MASK(port->bist_request)) {
5616 case BDO_MODE_CARRIER2:
5617 tcpm_pd_transmit(port, TCPC_TX_BIST_MODE_2, NULL);
5618 tcpm_set_state(port, unattached_state(port),
5619 PD_T_BIST_CONT_MODE);
5620 break;
5621 case BDO_MODE_TESTDATA:
5622 if (port->tcpc->set_bist_data) {
5623 tcpm_log(port, "Enable BIST MODE TESTDATA");
5624 port->tcpc->set_bist_data(port->tcpc, true);
5625 }
5626 break;
5627 default:
5628 break;
5629 }
5630 break;
5631 case GET_STATUS_SEND:
5632 tcpm_pd_send_control(port, PD_CTRL_GET_STATUS, TCPC_TX_SOP);
5633 tcpm_set_state(port, GET_STATUS_SEND_TIMEOUT,
5634 PD_T_SENDER_RESPONSE);
5635 break;
5636 case GET_STATUS_SEND_TIMEOUT:
5637 tcpm_set_state(port, ready_state(port), 0);
5638 break;
5639 case GET_PPS_STATUS_SEND:
5640 tcpm_pd_send_control(port, PD_CTRL_GET_PPS_STATUS, TCPC_TX_SOP);
5641 tcpm_set_state(port, GET_PPS_STATUS_SEND_TIMEOUT,
5642 PD_T_SENDER_RESPONSE);
5643 break;
5644 case GET_PPS_STATUS_SEND_TIMEOUT:
5645 tcpm_set_state(port, ready_state(port), 0);
5646 break;
5647 case GET_SINK_CAP:
5648 tcpm_pd_send_control(port, PD_CTRL_GET_SINK_CAP, TCPC_TX_SOP);
5649 tcpm_set_state(port, GET_SINK_CAP_TIMEOUT, PD_T_SENDER_RESPONSE);
5650 break;
5651 case GET_SINK_CAP_TIMEOUT:
5652 port->sink_cap_done = true;
5653 tcpm_set_state(port, ready_state(port), 0);
5654 break;
5655 case ERROR_RECOVERY:
5656 tcpm_swap_complete(port, -EPROTO);
5657 tcpm_pps_complete(port, -EPROTO);
5658 tcpm_set_state(port, PORT_RESET, 0);
5659 break;
5660 case PORT_RESET:
5661 tcpm_reset_port(port);
5662 if (port->self_powered)
5663 tcpm_set_cc(port, TYPEC_CC_OPEN);
5664 else
5665 tcpm_set_cc(port, tcpm_default_state(port) == SNK_UNATTACHED ?
5666 TYPEC_CC_RD : tcpm_rp_cc(port));
5667 tcpm_set_state(port, PORT_RESET_WAIT_OFF,
5668 PD_T_ERROR_RECOVERY);
5669 break;
5670 case PORT_RESET_WAIT_OFF:
5671 tcpm_set_state(port,
5672 tcpm_default_state(port),
5673 port->vbus_present ? PD_T_PS_SOURCE_OFF : 0);
5674 break;
5675
5676 /* AMS intermediate state */
5677 case AMS_START:
5678 if (port->upcoming_state == INVALID_STATE) {
5679 tcpm_set_state(port, port->pwr_role == TYPEC_SOURCE ?
5680 SRC_READY : SNK_READY, 0);
5681 break;
5682 }
5683
5684 upcoming_state = port->upcoming_state;
5685 port->upcoming_state = INVALID_STATE;
5686 tcpm_set_state(port, upcoming_state, 0);
5687 break;
5688
5689 /* Chunk state */
5690 case CHUNK_NOT_SUPP:
5691 tcpm_pd_send_control(port, PD_CTRL_NOT_SUPP, TCPC_TX_SOP);
5692 tcpm_set_state(port, port->pwr_role == TYPEC_SOURCE ? SRC_READY : SNK_READY, 0);
5693 break;
5694
5695 /* Cable states */
5696 case SRC_VDM_IDENTITY_REQUEST:
5697 port->send_discover_prime = true;
5698 port->tx_sop_type = TCPC_TX_SOP_PRIME;
5699 mod_send_discover_delayed_work(port, 0);
5700 port->upcoming_state = SRC_SEND_CAPABILITIES;
5701 break;
5702
5703 default:
5704 WARN(1, "Unexpected port state %d\n", port->state);
5705 break;
5706 }
5707 }
5708
tcpm_state_machine_work(struct kthread_work * work)5709 static void tcpm_state_machine_work(struct kthread_work *work)
5710 {
5711 struct tcpm_port *port = container_of(work, struct tcpm_port, state_machine);
5712 enum tcpm_state prev_state;
5713
5714 mutex_lock(&port->lock);
5715 port->state_machine_running = true;
5716
5717 if (port->queued_message && tcpm_send_queued_message(port))
5718 goto done;
5719
5720 /* If we were queued due to a delayed state change, update it now */
5721 if (port->delayed_state) {
5722 tcpm_log(port, "state change %s -> %s [delayed %ld ms]",
5723 tcpm_states[port->state],
5724 tcpm_states[port->delayed_state], port->delay_ms);
5725 port->prev_state = port->state;
5726 port->state = port->delayed_state;
5727 port->delayed_state = INVALID_STATE;
5728 }
5729
5730 /*
5731 * Continue running as long as we have (non-delayed) state changes
5732 * to make.
5733 */
5734 do {
5735 prev_state = port->state;
5736 run_state_machine(port);
5737 if (port->queued_message)
5738 tcpm_send_queued_message(port);
5739 } while (port->state != prev_state && !port->delayed_state);
5740
5741 done:
5742 port->state_machine_running = false;
5743 mutex_unlock(&port->lock);
5744 }
5745
_tcpm_cc_change(struct tcpm_port * port,enum typec_cc_status cc1,enum typec_cc_status cc2)5746 static void _tcpm_cc_change(struct tcpm_port *port, enum typec_cc_status cc1,
5747 enum typec_cc_status cc2)
5748 {
5749 enum typec_cc_status old_cc1, old_cc2;
5750 enum tcpm_state new_state;
5751
5752 old_cc1 = port->cc1;
5753 old_cc2 = port->cc2;
5754 port->cc1 = cc1;
5755 port->cc2 = cc2;
5756
5757 tcpm_log_force(port,
5758 "CC1: %u -> %u, CC2: %u -> %u [state %s, polarity %d, %s]",
5759 old_cc1, cc1, old_cc2, cc2, tcpm_states[port->state],
5760 port->polarity,
5761 tcpm_port_is_disconnected(port) ? "disconnected"
5762 : "connected");
5763
5764 switch (port->state) {
5765 case TOGGLING:
5766 if (tcpm_port_is_debug(port) || tcpm_port_is_audio(port) ||
5767 tcpm_port_is_source(port))
5768 tcpm_set_state(port, SRC_ATTACH_WAIT, 0);
5769 else if (tcpm_port_is_sink(port))
5770 tcpm_set_state(port, SNK_ATTACH_WAIT, 0);
5771 break;
5772 case CHECK_CONTAMINANT:
5773 /* Wait for Toggling to be resumed */
5774 break;
5775 case SRC_UNATTACHED:
5776 case ACC_UNATTACHED:
5777 if (tcpm_port_is_debug(port) || tcpm_port_is_audio(port) ||
5778 tcpm_port_is_source(port))
5779 tcpm_set_state(port, SRC_ATTACH_WAIT, 0);
5780 break;
5781 case SRC_ATTACH_WAIT:
5782 if (tcpm_port_is_disconnected(port) ||
5783 tcpm_port_is_audio_detached(port))
5784 tcpm_set_state(port, SRC_UNATTACHED, 0);
5785 else if (cc1 != old_cc1 || cc2 != old_cc2)
5786 tcpm_set_state(port, SRC_ATTACH_WAIT, 0);
5787 break;
5788 case SRC_ATTACHED:
5789 case SRC_STARTUP:
5790 case SRC_SEND_CAPABILITIES:
5791 case SRC_READY:
5792 if (tcpm_port_is_disconnected(port) ||
5793 !tcpm_port_is_source(port)) {
5794 if (port->port_type == TYPEC_PORT_SRC)
5795 tcpm_set_state(port, SRC_UNATTACHED, tcpm_wait_for_discharge(port));
5796 else
5797 tcpm_set_state(port, SNK_UNATTACHED, tcpm_wait_for_discharge(port));
5798 }
5799 break;
5800 case SNK_UNATTACHED:
5801 if (tcpm_port_is_sink(port))
5802 tcpm_set_state(port, SNK_ATTACH_WAIT, 0);
5803 break;
5804 case SNK_ATTACH_WAIT:
5805 if ((port->cc1 == TYPEC_CC_OPEN &&
5806 port->cc2 != TYPEC_CC_OPEN) ||
5807 (port->cc1 != TYPEC_CC_OPEN &&
5808 port->cc2 == TYPEC_CC_OPEN))
5809 new_state = SNK_DEBOUNCED;
5810 else if (tcpm_port_is_disconnected(port))
5811 new_state = SNK_UNATTACHED;
5812 else
5813 break;
5814 if (new_state != port->delayed_state)
5815 tcpm_set_state(port, SNK_ATTACH_WAIT, 0);
5816 break;
5817 case SNK_DEBOUNCED:
5818 if (tcpm_port_is_disconnected(port))
5819 new_state = SNK_UNATTACHED;
5820 else if (port->vbus_present)
5821 new_state = tcpm_try_src(port) ? SRC_TRY : SNK_ATTACHED;
5822 else
5823 new_state = SNK_UNATTACHED;
5824 if (new_state != port->delayed_state)
5825 tcpm_set_state(port, SNK_DEBOUNCED, 0);
5826 break;
5827 case SNK_READY:
5828 /*
5829 * EXIT condition is based primarily on vbus disconnect and CC is secondary.
5830 * "A port that has entered into USB PD communications with the Source and
5831 * has seen the CC voltage exceed vRd-USB may monitor the CC pin to detect
5832 * cable disconnect in addition to monitoring VBUS.
5833 *
5834 * A port that is monitoring the CC voltage for disconnect (but is not in
5835 * the process of a USB PD PR_Swap or USB PD FR_Swap) shall transition to
5836 * Unattached.SNK within tSinkDisconnect after the CC voltage remains below
5837 * vRd-USB for tPDDebounce."
5838 *
5839 * When set_auto_vbus_discharge_threshold is enabled, CC pins go
5840 * away before vbus decays to disconnect threshold. Allow
5841 * disconnect to be driven by vbus disconnect when auto vbus
5842 * discharge is enabled.
5843 */
5844 if (!port->auto_vbus_discharge_enabled && tcpm_port_is_disconnected(port))
5845 tcpm_set_state(port, unattached_state(port), 0);
5846 else if (!port->pd_capable &&
5847 (cc1 != old_cc1 || cc2 != old_cc2))
5848 tcpm_set_current_limit(port,
5849 tcpm_get_current_limit(port),
5850 5000);
5851 break;
5852
5853 case AUDIO_ACC_ATTACHED:
5854 if (cc1 == TYPEC_CC_OPEN || cc2 == TYPEC_CC_OPEN)
5855 tcpm_set_state(port, AUDIO_ACC_DEBOUNCE, 0);
5856 break;
5857 case AUDIO_ACC_DEBOUNCE:
5858 if (tcpm_port_is_audio(port))
5859 tcpm_set_state(port, AUDIO_ACC_ATTACHED, 0);
5860 break;
5861
5862 case DEBUG_ACC_ATTACHED:
5863 if (cc1 == TYPEC_CC_OPEN || cc2 == TYPEC_CC_OPEN)
5864 tcpm_set_state(port, ACC_UNATTACHED, 0);
5865 break;
5866
5867 case SNK_TRY:
5868 /* Do nothing, waiting for timeout */
5869 break;
5870
5871 case SNK_DISCOVERY:
5872 /* CC line is unstable, wait for debounce */
5873 if (tcpm_port_is_disconnected(port))
5874 tcpm_set_state(port, SNK_DISCOVERY_DEBOUNCE, 0);
5875 break;
5876 case SNK_DISCOVERY_DEBOUNCE:
5877 break;
5878
5879 case SRC_TRYWAIT:
5880 /* Hand over to state machine if needed */
5881 if (!port->vbus_present && tcpm_port_is_source(port))
5882 tcpm_set_state(port, SRC_TRYWAIT_DEBOUNCE, 0);
5883 break;
5884 case SRC_TRYWAIT_DEBOUNCE:
5885 if (port->vbus_present || !tcpm_port_is_source(port))
5886 tcpm_set_state(port, SRC_TRYWAIT, 0);
5887 break;
5888 case SNK_TRY_WAIT_DEBOUNCE:
5889 if (!tcpm_port_is_sink(port)) {
5890 port->max_wait = 0;
5891 tcpm_set_state(port, SRC_TRYWAIT, 0);
5892 }
5893 break;
5894 case SRC_TRY_WAIT:
5895 if (tcpm_port_is_source(port))
5896 tcpm_set_state(port, SRC_TRY_DEBOUNCE, 0);
5897 break;
5898 case SRC_TRY_DEBOUNCE:
5899 tcpm_set_state(port, SRC_TRY_WAIT, 0);
5900 break;
5901 case SNK_TRYWAIT_DEBOUNCE:
5902 if (tcpm_port_is_sink(port))
5903 tcpm_set_state(port, SNK_TRYWAIT_VBUS, 0);
5904 break;
5905 case SNK_TRYWAIT_VBUS:
5906 if (!tcpm_port_is_sink(port))
5907 tcpm_set_state(port, SNK_TRYWAIT_DEBOUNCE, 0);
5908 break;
5909 case SNK_TRY_WAIT_DEBOUNCE_CHECK_VBUS:
5910 if (!tcpm_port_is_sink(port))
5911 tcpm_set_state(port, SRC_TRYWAIT, PD_T_TRY_CC_DEBOUNCE);
5912 else
5913 tcpm_set_state(port, SNK_TRY_WAIT_DEBOUNCE_CHECK_VBUS, 0);
5914 break;
5915 case SNK_TRYWAIT:
5916 /* Do nothing, waiting for tCCDebounce */
5917 break;
5918 case PR_SWAP_SNK_SRC_SINK_OFF:
5919 case PR_SWAP_SRC_SNK_TRANSITION_OFF:
5920 case PR_SWAP_SRC_SNK_SOURCE_OFF:
5921 case PR_SWAP_SRC_SNK_SOURCE_OFF_CC_DEBOUNCED:
5922 case PR_SWAP_SNK_SRC_SOURCE_ON:
5923 /*
5924 * CC state change is expected in PR_SWAP
5925 * Ignore it.
5926 */
5927 break;
5928 case FR_SWAP_SEND:
5929 case FR_SWAP_SEND_TIMEOUT:
5930 case FR_SWAP_SNK_SRC_TRANSITION_TO_OFF:
5931 case FR_SWAP_SNK_SRC_NEW_SINK_READY:
5932 case FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED:
5933 /* Do nothing, CC change expected */
5934 break;
5935
5936 case PORT_RESET:
5937 case PORT_RESET_WAIT_OFF:
5938 /*
5939 * State set back to default mode once the timer completes.
5940 * Ignore CC changes here.
5941 */
5942 break;
5943 default:
5944 /*
5945 * While acting as sink and auto vbus discharge is enabled, Allow disconnect
5946 * to be driven by vbus disconnect.
5947 */
5948 if (tcpm_port_is_disconnected(port) && !(port->pwr_role == TYPEC_SINK &&
5949 port->auto_vbus_discharge_enabled))
5950 tcpm_set_state(port, unattached_state(port), 0);
5951 break;
5952 }
5953 }
5954
_tcpm_pd_vbus_on(struct tcpm_port * port)5955 static void _tcpm_pd_vbus_on(struct tcpm_port *port)
5956 {
5957 tcpm_log_force(port, "VBUS on");
5958 port->vbus_present = true;
5959 /*
5960 * When vbus_present is true i.e. Voltage at VBUS is greater than VSAFE5V implicitly
5961 * states that vbus is not at VSAFE0V, hence clear the vbus_vsafe0v flag here.
5962 */
5963 port->vbus_vsafe0v = false;
5964
5965 switch (port->state) {
5966 case SNK_TRANSITION_SINK_VBUS:
5967 port->explicit_contract = true;
5968 tcpm_set_state(port, SNK_READY, 0);
5969 break;
5970 case SNK_DISCOVERY:
5971 tcpm_set_state(port, SNK_DISCOVERY, 0);
5972 break;
5973
5974 case SNK_DEBOUNCED:
5975 tcpm_set_state(port, tcpm_try_src(port) ? SRC_TRY
5976 : SNK_ATTACHED,
5977 0);
5978 break;
5979 case SNK_HARD_RESET_WAIT_VBUS:
5980 tcpm_set_state(port, SNK_HARD_RESET_SINK_ON, 0);
5981 break;
5982 case SRC_ATTACHED:
5983 tcpm_set_state(port, SRC_STARTUP, 0);
5984 break;
5985 case SRC_HARD_RESET_VBUS_ON:
5986 tcpm_set_state(port, SRC_STARTUP, 0);
5987 break;
5988
5989 case SNK_TRY:
5990 /* Do nothing, waiting for timeout */
5991 break;
5992 case SRC_TRYWAIT:
5993 /* Do nothing, Waiting for Rd to be detected */
5994 break;
5995 case SRC_TRYWAIT_DEBOUNCE:
5996 tcpm_set_state(port, SRC_TRYWAIT, 0);
5997 break;
5998 case SNK_TRY_WAIT_DEBOUNCE:
5999 /* Do nothing, waiting for PD_DEBOUNCE to do be done */
6000 break;
6001 case SNK_TRYWAIT:
6002 /* Do nothing, waiting for tCCDebounce */
6003 break;
6004 case SNK_TRYWAIT_VBUS:
6005 if (tcpm_port_is_sink(port))
6006 tcpm_set_state(port, SNK_ATTACHED, 0);
6007 break;
6008 case SNK_TRYWAIT_DEBOUNCE:
6009 /* Do nothing, waiting for Rp */
6010 break;
6011 case SNK_TRY_WAIT_DEBOUNCE_CHECK_VBUS:
6012 if (port->vbus_present && tcpm_port_is_sink(port))
6013 tcpm_set_state(port, SNK_ATTACHED, 0);
6014 break;
6015 case SRC_TRY_WAIT:
6016 case SRC_TRY_DEBOUNCE:
6017 /* Do nothing, waiting for sink detection */
6018 break;
6019 case FR_SWAP_SEND:
6020 case FR_SWAP_SEND_TIMEOUT:
6021 case FR_SWAP_SNK_SRC_TRANSITION_TO_OFF:
6022 case FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED:
6023 if (port->tcpc->frs_sourcing_vbus)
6024 port->tcpc->frs_sourcing_vbus(port->tcpc);
6025 break;
6026 case FR_SWAP_SNK_SRC_NEW_SINK_READY:
6027 if (port->tcpc->frs_sourcing_vbus)
6028 port->tcpc->frs_sourcing_vbus(port->tcpc);
6029 tcpm_set_state(port, FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED, 0);
6030 break;
6031
6032 case PORT_RESET:
6033 case PORT_RESET_WAIT_OFF:
6034 /*
6035 * State set back to default mode once the timer completes.
6036 * Ignore vbus changes here.
6037 */
6038 break;
6039
6040 default:
6041 break;
6042 }
6043 }
6044
_tcpm_pd_vbus_off(struct tcpm_port * port)6045 static void _tcpm_pd_vbus_off(struct tcpm_port *port)
6046 {
6047 tcpm_log_force(port, "VBUS off");
6048 port->vbus_present = false;
6049 port->vbus_never_low = false;
6050 switch (port->state) {
6051 case SNK_HARD_RESET_SINK_OFF:
6052 tcpm_set_state(port, SNK_HARD_RESET_WAIT_VBUS, 0);
6053 break;
6054 case HARD_RESET_SEND:
6055 break;
6056 case SNK_TRY:
6057 /* Do nothing, waiting for timeout */
6058 break;
6059 case SRC_TRYWAIT:
6060 /* Hand over to state machine if needed */
6061 if (tcpm_port_is_source(port))
6062 tcpm_set_state(port, SRC_TRYWAIT_DEBOUNCE, 0);
6063 break;
6064 case SNK_TRY_WAIT_DEBOUNCE:
6065 /* Do nothing, waiting for PD_DEBOUNCE to do be done */
6066 break;
6067 case SNK_TRYWAIT:
6068 case SNK_TRYWAIT_VBUS:
6069 case SNK_TRYWAIT_DEBOUNCE:
6070 break;
6071 case SNK_ATTACH_WAIT:
6072 case SNK_DEBOUNCED:
6073 /* Do nothing, as TCPM is still waiting for vbus to reaach VSAFE5V to connect */
6074 break;
6075
6076 case SNK_NEGOTIATE_CAPABILITIES:
6077 break;
6078
6079 case PR_SWAP_SRC_SNK_TRANSITION_OFF:
6080 tcpm_set_state(port, PR_SWAP_SRC_SNK_SOURCE_OFF, 0);
6081 break;
6082
6083 case PR_SWAP_SNK_SRC_SINK_OFF:
6084 /* Do nothing, expected */
6085 break;
6086
6087 case PR_SWAP_SNK_SRC_SOURCE_ON:
6088 /*
6089 * Do nothing when vbus off notification is received.
6090 * TCPM can wait for PD_T_NEWSRC in PR_SWAP_SNK_SRC_SOURCE_ON
6091 * for the vbus source to ramp up.
6092 */
6093 break;
6094
6095 case PORT_RESET_WAIT_OFF:
6096 tcpm_set_state(port, tcpm_default_state(port), 0);
6097 break;
6098
6099 case SRC_TRY_WAIT:
6100 case SRC_TRY_DEBOUNCE:
6101 /* Do nothing, waiting for sink detection */
6102 break;
6103
6104 case SRC_STARTUP:
6105 case SRC_SEND_CAPABILITIES:
6106 case SRC_SEND_CAPABILITIES_TIMEOUT:
6107 case SRC_NEGOTIATE_CAPABILITIES:
6108 case SRC_TRANSITION_SUPPLY:
6109 case SRC_READY:
6110 case SRC_WAIT_NEW_CAPABILITIES:
6111 /*
6112 * Force to unattached state to re-initiate connection.
6113 * DRP port should move to Unattached.SNK instead of Unattached.SRC if
6114 * sink removed. Although sink removal here is due to source's vbus collapse,
6115 * treat it the same way for consistency.
6116 */
6117 if (port->port_type == TYPEC_PORT_SRC)
6118 tcpm_set_state(port, SRC_UNATTACHED, tcpm_wait_for_discharge(port));
6119 else
6120 tcpm_set_state(port, SNK_UNATTACHED, tcpm_wait_for_discharge(port));
6121 break;
6122
6123 case PORT_RESET:
6124 /*
6125 * State set back to default mode once the timer completes.
6126 * Ignore vbus changes here.
6127 */
6128 break;
6129
6130 case FR_SWAP_SEND:
6131 case FR_SWAP_SEND_TIMEOUT:
6132 case FR_SWAP_SNK_SRC_TRANSITION_TO_OFF:
6133 case FR_SWAP_SNK_SRC_NEW_SINK_READY:
6134 case FR_SWAP_SNK_SRC_SOURCE_VBUS_APPLIED:
6135 /* Do nothing, vbus drop expected */
6136 break;
6137
6138 case SNK_HARD_RESET_WAIT_VBUS:
6139 /* Do nothing, its OK to receive vbus off events */
6140 break;
6141
6142 default:
6143 if (port->pwr_role == TYPEC_SINK && port->attached)
6144 tcpm_set_state(port, SNK_UNATTACHED, tcpm_wait_for_discharge(port));
6145 break;
6146 }
6147 }
6148
_tcpm_pd_vbus_vsafe0v(struct tcpm_port * port)6149 static void _tcpm_pd_vbus_vsafe0v(struct tcpm_port *port)
6150 {
6151 tcpm_log_force(port, "VBUS VSAFE0V");
6152 port->vbus_vsafe0v = true;
6153 switch (port->state) {
6154 case SRC_HARD_RESET_VBUS_OFF:
6155 /*
6156 * After establishing the vSafe0V voltage condition on VBUS, the Source Shall wait
6157 * tSrcRecover before re-applying VCONN and restoring VBUS to vSafe5V.
6158 */
6159 tcpm_set_state(port, SRC_HARD_RESET_VBUS_ON, PD_T_SRC_RECOVER);
6160 break;
6161 case SRC_ATTACH_WAIT:
6162 if (tcpm_port_is_source(port))
6163 tcpm_set_state(port, tcpm_try_snk(port) ? SNK_TRY : SRC_ATTACHED,
6164 PD_T_CC_DEBOUNCE);
6165 break;
6166 case SRC_STARTUP:
6167 case SRC_SEND_CAPABILITIES:
6168 case SRC_SEND_CAPABILITIES_TIMEOUT:
6169 case SRC_NEGOTIATE_CAPABILITIES:
6170 case SRC_TRANSITION_SUPPLY:
6171 case SRC_READY:
6172 case SRC_WAIT_NEW_CAPABILITIES:
6173 if (port->auto_vbus_discharge_enabled) {
6174 if (port->port_type == TYPEC_PORT_SRC)
6175 tcpm_set_state(port, SRC_UNATTACHED, 0);
6176 else
6177 tcpm_set_state(port, SNK_UNATTACHED, 0);
6178 }
6179 break;
6180 case PR_SWAP_SNK_SRC_SINK_OFF:
6181 case PR_SWAP_SNK_SRC_SOURCE_ON:
6182 /* Do nothing, vsafe0v is expected during transition */
6183 break;
6184 case SNK_ATTACH_WAIT:
6185 case SNK_DEBOUNCED:
6186 /*Do nothing, still waiting for VSAFE5V for connect */
6187 break;
6188 case SNK_HARD_RESET_WAIT_VBUS:
6189 /* Do nothing, its OK to receive vbus off events */
6190 break;
6191 default:
6192 if (port->pwr_role == TYPEC_SINK && port->auto_vbus_discharge_enabled)
6193 tcpm_set_state(port, SNK_UNATTACHED, 0);
6194 break;
6195 }
6196 }
6197
_tcpm_pd_hard_reset(struct tcpm_port * port)6198 static void _tcpm_pd_hard_reset(struct tcpm_port *port)
6199 {
6200 tcpm_log_force(port, "Received hard reset");
6201 if (port->bist_request == BDO_MODE_TESTDATA && port->tcpc->set_bist_data)
6202 port->tcpc->set_bist_data(port->tcpc, false);
6203
6204 switch (port->state) {
6205 case TOGGLING:
6206 case ERROR_RECOVERY:
6207 case PORT_RESET:
6208 case PORT_RESET_WAIT_OFF:
6209 return;
6210 default:
6211 break;
6212 }
6213
6214 if (port->ams != NONE_AMS)
6215 port->ams = NONE_AMS;
6216 if (port->hard_reset_count < PD_N_HARD_RESET_COUNT)
6217 port->ams = HARD_RESET;
6218 /*
6219 * If we keep receiving hard reset requests, executing the hard reset
6220 * must have failed. Revert to error recovery if that happens.
6221 */
6222 tcpm_set_state(port,
6223 port->hard_reset_count < PD_N_HARD_RESET_COUNT ?
6224 HARD_RESET_START : ERROR_RECOVERY,
6225 0);
6226 }
6227
tcpm_pd_event_handler(struct kthread_work * work)6228 static void tcpm_pd_event_handler(struct kthread_work *work)
6229 {
6230 struct tcpm_port *port = container_of(work, struct tcpm_port,
6231 event_work);
6232 u32 events;
6233
6234 mutex_lock(&port->lock);
6235
6236 spin_lock(&port->pd_event_lock);
6237 while (port->pd_events) {
6238 events = port->pd_events;
6239 port->pd_events = 0;
6240 spin_unlock(&port->pd_event_lock);
6241 if (events & TCPM_RESET_EVENT)
6242 _tcpm_pd_hard_reset(port);
6243 if (events & TCPM_VBUS_EVENT) {
6244 bool vbus;
6245
6246 vbus = port->tcpc->get_vbus(port->tcpc);
6247 if (vbus) {
6248 _tcpm_pd_vbus_on(port);
6249 } else {
6250 _tcpm_pd_vbus_off(port);
6251 /*
6252 * When TCPC does not support detecting vsafe0v voltage level,
6253 * treat vbus absent as vsafe0v. Else invoke is_vbus_vsafe0v
6254 * to see if vbus has discharge to VSAFE0V.
6255 */
6256 if (!port->tcpc->is_vbus_vsafe0v ||
6257 port->tcpc->is_vbus_vsafe0v(port->tcpc))
6258 _tcpm_pd_vbus_vsafe0v(port);
6259 }
6260 }
6261 if (events & TCPM_CC_EVENT) {
6262 enum typec_cc_status cc1, cc2;
6263
6264 if (port->tcpc->get_cc(port->tcpc, &cc1, &cc2) == 0)
6265 _tcpm_cc_change(port, cc1, cc2);
6266 }
6267 if (events & TCPM_FRS_EVENT) {
6268 if (port->state == SNK_READY) {
6269 int ret;
6270
6271 port->upcoming_state = FR_SWAP_SEND;
6272 ret = tcpm_ams_start(port, FAST_ROLE_SWAP);
6273 if (ret == -EAGAIN)
6274 port->upcoming_state = INVALID_STATE;
6275 } else {
6276 tcpm_log(port, "Discarding FRS_SIGNAL! Not in sink ready");
6277 }
6278 }
6279 if (events & TCPM_SOURCING_VBUS) {
6280 tcpm_log(port, "sourcing vbus");
6281 /*
6282 * In fast role swap case TCPC autonomously sources vbus. Set vbus_source
6283 * true as TCPM wouldn't have called tcpm_set_vbus.
6284 *
6285 * When vbus is sourced on the command on TCPM i.e. TCPM called
6286 * tcpm_set_vbus to source vbus, vbus_source would already be true.
6287 */
6288 port->vbus_source = true;
6289 _tcpm_pd_vbus_on(port);
6290 }
6291 if (events & TCPM_PORT_CLEAN) {
6292 tcpm_log(port, "port clean");
6293 if (port->state == CHECK_CONTAMINANT) {
6294 if (tcpm_start_toggling(port, tcpm_rp_cc(port)))
6295 tcpm_set_state(port, TOGGLING, 0);
6296 else
6297 tcpm_set_state(port, tcpm_default_state(port), 0);
6298 }
6299 }
6300 if (events & TCPM_PORT_ERROR) {
6301 tcpm_log(port, "port triggering error recovery");
6302 tcpm_set_state(port, ERROR_RECOVERY, 0);
6303 }
6304
6305 spin_lock(&port->pd_event_lock);
6306 }
6307 spin_unlock(&port->pd_event_lock);
6308 mutex_unlock(&port->lock);
6309 }
6310
tcpm_cc_change(struct tcpm_port * port)6311 void tcpm_cc_change(struct tcpm_port *port)
6312 {
6313 spin_lock(&port->pd_event_lock);
6314 port->pd_events |= TCPM_CC_EVENT;
6315 spin_unlock(&port->pd_event_lock);
6316 kthread_queue_work(port->wq, &port->event_work);
6317 }
6318 EXPORT_SYMBOL_GPL(tcpm_cc_change);
6319
tcpm_vbus_change(struct tcpm_port * port)6320 void tcpm_vbus_change(struct tcpm_port *port)
6321 {
6322 spin_lock(&port->pd_event_lock);
6323 port->pd_events |= TCPM_VBUS_EVENT;
6324 spin_unlock(&port->pd_event_lock);
6325 kthread_queue_work(port->wq, &port->event_work);
6326 }
6327 EXPORT_SYMBOL_GPL(tcpm_vbus_change);
6328
tcpm_pd_hard_reset(struct tcpm_port * port)6329 void tcpm_pd_hard_reset(struct tcpm_port *port)
6330 {
6331 spin_lock(&port->pd_event_lock);
6332 port->pd_events = TCPM_RESET_EVENT;
6333 spin_unlock(&port->pd_event_lock);
6334 kthread_queue_work(port->wq, &port->event_work);
6335 }
6336 EXPORT_SYMBOL_GPL(tcpm_pd_hard_reset);
6337
tcpm_sink_frs(struct tcpm_port * port)6338 void tcpm_sink_frs(struct tcpm_port *port)
6339 {
6340 spin_lock(&port->pd_event_lock);
6341 port->pd_events |= TCPM_FRS_EVENT;
6342 spin_unlock(&port->pd_event_lock);
6343 kthread_queue_work(port->wq, &port->event_work);
6344 }
6345 EXPORT_SYMBOL_GPL(tcpm_sink_frs);
6346
tcpm_sourcing_vbus(struct tcpm_port * port)6347 void tcpm_sourcing_vbus(struct tcpm_port *port)
6348 {
6349 spin_lock(&port->pd_event_lock);
6350 port->pd_events |= TCPM_SOURCING_VBUS;
6351 spin_unlock(&port->pd_event_lock);
6352 kthread_queue_work(port->wq, &port->event_work);
6353 }
6354 EXPORT_SYMBOL_GPL(tcpm_sourcing_vbus);
6355
tcpm_port_clean(struct tcpm_port * port)6356 void tcpm_port_clean(struct tcpm_port *port)
6357 {
6358 spin_lock(&port->pd_event_lock);
6359 port->pd_events |= TCPM_PORT_CLEAN;
6360 spin_unlock(&port->pd_event_lock);
6361 kthread_queue_work(port->wq, &port->event_work);
6362 }
6363 EXPORT_SYMBOL_GPL(tcpm_port_clean);
6364
tcpm_port_is_toggling(struct tcpm_port * port)6365 bool tcpm_port_is_toggling(struct tcpm_port *port)
6366 {
6367 return port->port_type == TYPEC_PORT_DRP && port->state == TOGGLING;
6368 }
6369 EXPORT_SYMBOL_GPL(tcpm_port_is_toggling);
6370
tcpm_port_error_recovery(struct tcpm_port * port)6371 void tcpm_port_error_recovery(struct tcpm_port *port)
6372 {
6373 spin_lock(&port->pd_event_lock);
6374 port->pd_events |= TCPM_PORT_ERROR;
6375 spin_unlock(&port->pd_event_lock);
6376 kthread_queue_work(port->wq, &port->event_work);
6377 }
6378 EXPORT_SYMBOL_GPL(tcpm_port_error_recovery);
6379
tcpm_enable_frs_work(struct kthread_work * work)6380 static void tcpm_enable_frs_work(struct kthread_work *work)
6381 {
6382 struct tcpm_port *port = container_of(work, struct tcpm_port, enable_frs);
6383 int ret;
6384
6385 mutex_lock(&port->lock);
6386 /* Not FRS capable */
6387 if (!port->connected || port->port_type != TYPEC_PORT_DRP ||
6388 port->pwr_opmode != TYPEC_PWR_MODE_PD ||
6389 !port->tcpc->enable_frs ||
6390 /* Sink caps queried */
6391 port->sink_cap_done || port->negotiated_rev < PD_REV30)
6392 goto unlock;
6393
6394 /* Send when the state machine is idle */
6395 if (port->state != SNK_READY || port->vdm_sm_running || port->send_discover ||
6396 port->send_discover_prime)
6397 goto resched;
6398
6399 port->upcoming_state = GET_SINK_CAP;
6400 ret = tcpm_ams_start(port, GET_SINK_CAPABILITIES);
6401 if (ret == -EAGAIN) {
6402 port->upcoming_state = INVALID_STATE;
6403 } else {
6404 port->sink_cap_done = true;
6405 goto unlock;
6406 }
6407 resched:
6408 mod_enable_frs_delayed_work(port, GET_SINK_CAP_RETRY_MS);
6409 unlock:
6410 mutex_unlock(&port->lock);
6411 }
6412
tcpm_send_discover_work(struct kthread_work * work)6413 static void tcpm_send_discover_work(struct kthread_work *work)
6414 {
6415 struct tcpm_port *port = container_of(work, struct tcpm_port, send_discover_work);
6416
6417 mutex_lock(&port->lock);
6418 /* No need to send DISCOVER_IDENTITY anymore */
6419 if (!port->send_discover && !port->send_discover_prime)
6420 goto unlock;
6421
6422 if (port->data_role == TYPEC_DEVICE && port->negotiated_rev < PD_REV30) {
6423 port->send_discover = false;
6424 port->send_discover_prime = false;
6425 goto unlock;
6426 }
6427
6428 /* Retry if the port is not idle */
6429 if ((port->state != SRC_READY && port->state != SNK_READY &&
6430 port->state != SRC_VDM_IDENTITY_REQUEST) || port->vdm_sm_running) {
6431 mod_send_discover_delayed_work(port, SEND_DISCOVER_RETRY_MS);
6432 goto unlock;
6433 }
6434
6435 tcpm_send_vdm(port, USB_SID_PD, CMD_DISCOVER_IDENT, NULL, 0, port->tx_sop_type);
6436
6437 unlock:
6438 mutex_unlock(&port->lock);
6439 }
6440
tcpm_dr_set(struct typec_port * p,enum typec_data_role data)6441 static int tcpm_dr_set(struct typec_port *p, enum typec_data_role data)
6442 {
6443 struct tcpm_port *port = typec_get_drvdata(p);
6444 int ret;
6445
6446 mutex_lock(&port->swap_lock);
6447 mutex_lock(&port->lock);
6448
6449 if (port->typec_caps.data != TYPEC_PORT_DRD) {
6450 ret = -EINVAL;
6451 goto port_unlock;
6452 }
6453 if (port->state != SRC_READY && port->state != SNK_READY) {
6454 ret = -EAGAIN;
6455 goto port_unlock;
6456 }
6457
6458 if (port->data_role == data) {
6459 ret = 0;
6460 goto port_unlock;
6461 }
6462
6463 /*
6464 * XXX
6465 * 6.3.9: If an alternate mode is active, a request to swap
6466 * alternate modes shall trigger a port reset.
6467 * Reject data role swap request in this case.
6468 */
6469
6470 if (!port->pd_capable) {
6471 /*
6472 * If the partner is not PD capable, reset the port to
6473 * trigger a role change. This can only work if a preferred
6474 * role is configured, and if it matches the requested role.
6475 */
6476 if (port->try_role == TYPEC_NO_PREFERRED_ROLE ||
6477 port->try_role == port->pwr_role) {
6478 ret = -EINVAL;
6479 goto port_unlock;
6480 }
6481 port->non_pd_role_swap = true;
6482 tcpm_set_state(port, PORT_RESET, 0);
6483 } else {
6484 port->upcoming_state = DR_SWAP_SEND;
6485 ret = tcpm_ams_start(port, DATA_ROLE_SWAP);
6486 if (ret == -EAGAIN) {
6487 port->upcoming_state = INVALID_STATE;
6488 goto port_unlock;
6489 }
6490 }
6491
6492 port->swap_status = 0;
6493 port->swap_pending = true;
6494 reinit_completion(&port->swap_complete);
6495 mutex_unlock(&port->lock);
6496
6497 if (!wait_for_completion_timeout(&port->swap_complete,
6498 msecs_to_jiffies(PD_ROLE_SWAP_TIMEOUT)))
6499 ret = -ETIMEDOUT;
6500 else
6501 ret = port->swap_status;
6502
6503 port->non_pd_role_swap = false;
6504 goto swap_unlock;
6505
6506 port_unlock:
6507 mutex_unlock(&port->lock);
6508 swap_unlock:
6509 mutex_unlock(&port->swap_lock);
6510 return ret;
6511 }
6512
tcpm_pr_set(struct typec_port * p,enum typec_role role)6513 static int tcpm_pr_set(struct typec_port *p, enum typec_role role)
6514 {
6515 struct tcpm_port *port = typec_get_drvdata(p);
6516 int ret;
6517
6518 mutex_lock(&port->swap_lock);
6519 mutex_lock(&port->lock);
6520
6521 if (port->port_type != TYPEC_PORT_DRP) {
6522 ret = -EINVAL;
6523 goto port_unlock;
6524 }
6525 if (port->state != SRC_READY && port->state != SNK_READY) {
6526 ret = -EAGAIN;
6527 goto port_unlock;
6528 }
6529
6530 if (role == port->pwr_role) {
6531 ret = 0;
6532 goto port_unlock;
6533 }
6534
6535 port->upcoming_state = PR_SWAP_SEND;
6536 ret = tcpm_ams_start(port, POWER_ROLE_SWAP);
6537 if (ret == -EAGAIN) {
6538 port->upcoming_state = INVALID_STATE;
6539 goto port_unlock;
6540 }
6541
6542 port->swap_status = 0;
6543 port->swap_pending = true;
6544 reinit_completion(&port->swap_complete);
6545 mutex_unlock(&port->lock);
6546
6547 if (!wait_for_completion_timeout(&port->swap_complete,
6548 msecs_to_jiffies(PD_ROLE_SWAP_TIMEOUT)))
6549 ret = -ETIMEDOUT;
6550 else
6551 ret = port->swap_status;
6552
6553 goto swap_unlock;
6554
6555 port_unlock:
6556 mutex_unlock(&port->lock);
6557 swap_unlock:
6558 mutex_unlock(&port->swap_lock);
6559 return ret;
6560 }
6561
tcpm_vconn_set(struct typec_port * p,enum typec_role role)6562 static int tcpm_vconn_set(struct typec_port *p, enum typec_role role)
6563 {
6564 struct tcpm_port *port = typec_get_drvdata(p);
6565 int ret;
6566
6567 mutex_lock(&port->swap_lock);
6568 mutex_lock(&port->lock);
6569
6570 if (port->state != SRC_READY && port->state != SNK_READY) {
6571 ret = -EAGAIN;
6572 goto port_unlock;
6573 }
6574
6575 if (role == port->vconn_role) {
6576 ret = 0;
6577 goto port_unlock;
6578 }
6579
6580 port->upcoming_state = VCONN_SWAP_SEND;
6581 ret = tcpm_ams_start(port, VCONN_SWAP);
6582 if (ret == -EAGAIN) {
6583 port->upcoming_state = INVALID_STATE;
6584 goto port_unlock;
6585 }
6586
6587 port->swap_status = 0;
6588 port->swap_pending = true;
6589 reinit_completion(&port->swap_complete);
6590 mutex_unlock(&port->lock);
6591
6592 if (!wait_for_completion_timeout(&port->swap_complete,
6593 msecs_to_jiffies(PD_ROLE_SWAP_TIMEOUT)))
6594 ret = -ETIMEDOUT;
6595 else
6596 ret = port->swap_status;
6597
6598 goto swap_unlock;
6599
6600 port_unlock:
6601 mutex_unlock(&port->lock);
6602 swap_unlock:
6603 mutex_unlock(&port->swap_lock);
6604 return ret;
6605 }
6606
tcpm_try_role(struct typec_port * p,int role)6607 static int tcpm_try_role(struct typec_port *p, int role)
6608 {
6609 struct tcpm_port *port = typec_get_drvdata(p);
6610 struct tcpc_dev *tcpc = port->tcpc;
6611 int ret = 0;
6612
6613 mutex_lock(&port->lock);
6614 if (tcpc->try_role)
6615 ret = tcpc->try_role(tcpc, role);
6616 if (!ret)
6617 port->try_role = role;
6618 port->try_src_count = 0;
6619 port->try_snk_count = 0;
6620 mutex_unlock(&port->lock);
6621
6622 return ret;
6623 }
6624
tcpm_pps_set_op_curr(struct tcpm_port * port,u16 req_op_curr)6625 static int tcpm_pps_set_op_curr(struct tcpm_port *port, u16 req_op_curr)
6626 {
6627 unsigned int target_mw;
6628 int ret;
6629
6630 mutex_lock(&port->swap_lock);
6631 mutex_lock(&port->lock);
6632
6633 if (!port->pps_data.active) {
6634 ret = -EOPNOTSUPP;
6635 goto port_unlock;
6636 }
6637
6638 if (port->state != SNK_READY) {
6639 ret = -EAGAIN;
6640 goto port_unlock;
6641 }
6642
6643 if (req_op_curr > port->pps_data.max_curr) {
6644 ret = -EINVAL;
6645 goto port_unlock;
6646 }
6647
6648 target_mw = (req_op_curr * port->supply_voltage) / 1000;
6649 if (target_mw < port->operating_snk_mw) {
6650 ret = -EINVAL;
6651 goto port_unlock;
6652 }
6653
6654 port->upcoming_state = SNK_NEGOTIATE_PPS_CAPABILITIES;
6655 ret = tcpm_ams_start(port, POWER_NEGOTIATION);
6656 if (ret == -EAGAIN) {
6657 port->upcoming_state = INVALID_STATE;
6658 goto port_unlock;
6659 }
6660
6661 /* Round down operating current to align with PPS valid steps */
6662 req_op_curr = req_op_curr - (req_op_curr % RDO_PROG_CURR_MA_STEP);
6663
6664 reinit_completion(&port->pps_complete);
6665 port->pps_data.req_op_curr = req_op_curr;
6666 port->pps_status = 0;
6667 port->pps_pending = true;
6668 mutex_unlock(&port->lock);
6669
6670 if (!wait_for_completion_timeout(&port->pps_complete,
6671 msecs_to_jiffies(PD_PPS_CTRL_TIMEOUT)))
6672 ret = -ETIMEDOUT;
6673 else
6674 ret = port->pps_status;
6675
6676 goto swap_unlock;
6677
6678 port_unlock:
6679 mutex_unlock(&port->lock);
6680 swap_unlock:
6681 mutex_unlock(&port->swap_lock);
6682
6683 return ret;
6684 }
6685
tcpm_pps_set_out_volt(struct tcpm_port * port,u16 req_out_volt)6686 static int tcpm_pps_set_out_volt(struct tcpm_port *port, u16 req_out_volt)
6687 {
6688 unsigned int target_mw;
6689 int ret;
6690
6691 mutex_lock(&port->swap_lock);
6692 mutex_lock(&port->lock);
6693
6694 if (!port->pps_data.active) {
6695 ret = -EOPNOTSUPP;
6696 goto port_unlock;
6697 }
6698
6699 if (port->state != SNK_READY) {
6700 ret = -EAGAIN;
6701 goto port_unlock;
6702 }
6703
6704 target_mw = (port->current_limit * req_out_volt) / 1000;
6705 if (target_mw < port->operating_snk_mw) {
6706 ret = -EINVAL;
6707 goto port_unlock;
6708 }
6709
6710 port->upcoming_state = SNK_NEGOTIATE_PPS_CAPABILITIES;
6711 ret = tcpm_ams_start(port, POWER_NEGOTIATION);
6712 if (ret == -EAGAIN) {
6713 port->upcoming_state = INVALID_STATE;
6714 goto port_unlock;
6715 }
6716
6717 /* Round down output voltage to align with PPS valid steps */
6718 req_out_volt = req_out_volt - (req_out_volt % RDO_PROG_VOLT_MV_STEP);
6719
6720 reinit_completion(&port->pps_complete);
6721 port->pps_data.req_out_volt = req_out_volt;
6722 port->pps_status = 0;
6723 port->pps_pending = true;
6724 mutex_unlock(&port->lock);
6725
6726 if (!wait_for_completion_timeout(&port->pps_complete,
6727 msecs_to_jiffies(PD_PPS_CTRL_TIMEOUT)))
6728 ret = -ETIMEDOUT;
6729 else
6730 ret = port->pps_status;
6731
6732 goto swap_unlock;
6733
6734 port_unlock:
6735 mutex_unlock(&port->lock);
6736 swap_unlock:
6737 mutex_unlock(&port->swap_lock);
6738
6739 return ret;
6740 }
6741
tcpm_pps_activate(struct tcpm_port * port,bool activate)6742 static int tcpm_pps_activate(struct tcpm_port *port, bool activate)
6743 {
6744 int ret = 0;
6745
6746 mutex_lock(&port->swap_lock);
6747 mutex_lock(&port->lock);
6748
6749 if (!port->pps_data.supported) {
6750 ret = -EOPNOTSUPP;
6751 goto port_unlock;
6752 }
6753
6754 /* Trying to deactivate PPS when already deactivated so just bail */
6755 if (!port->pps_data.active && !activate)
6756 goto port_unlock;
6757
6758 if (port->state != SNK_READY) {
6759 ret = -EAGAIN;
6760 goto port_unlock;
6761 }
6762
6763 if (activate)
6764 port->upcoming_state = SNK_NEGOTIATE_PPS_CAPABILITIES;
6765 else
6766 port->upcoming_state = SNK_NEGOTIATE_CAPABILITIES;
6767 ret = tcpm_ams_start(port, POWER_NEGOTIATION);
6768 if (ret == -EAGAIN) {
6769 port->upcoming_state = INVALID_STATE;
6770 goto port_unlock;
6771 }
6772
6773 reinit_completion(&port->pps_complete);
6774 port->pps_status = 0;
6775 port->pps_pending = true;
6776
6777 /* Trigger PPS request or move back to standard PDO contract */
6778 if (activate) {
6779 port->pps_data.req_out_volt = port->supply_voltage;
6780 port->pps_data.req_op_curr = port->current_limit;
6781 }
6782 mutex_unlock(&port->lock);
6783
6784 if (!wait_for_completion_timeout(&port->pps_complete,
6785 msecs_to_jiffies(PD_PPS_CTRL_TIMEOUT)))
6786 ret = -ETIMEDOUT;
6787 else
6788 ret = port->pps_status;
6789
6790 goto swap_unlock;
6791
6792 port_unlock:
6793 mutex_unlock(&port->lock);
6794 swap_unlock:
6795 mutex_unlock(&port->swap_lock);
6796
6797 return ret;
6798 }
6799
tcpm_init(struct tcpm_port * port)6800 static void tcpm_init(struct tcpm_port *port)
6801 {
6802 enum typec_cc_status cc1, cc2;
6803
6804 port->tcpc->init(port->tcpc);
6805
6806 tcpm_reset_port(port);
6807
6808 /*
6809 * XXX
6810 * Should possibly wait for VBUS to settle if it was enabled locally
6811 * since tcpm_reset_port() will disable VBUS.
6812 */
6813 port->vbus_present = port->tcpc->get_vbus(port->tcpc);
6814 if (port->vbus_present)
6815 port->vbus_never_low = true;
6816
6817 /*
6818 * 1. When vbus_present is true, voltage on VBUS is already at VSAFE5V.
6819 * So implicitly vbus_vsafe0v = false.
6820 *
6821 * 2. When vbus_present is false and TCPC does NOT support querying
6822 * vsafe0v status, then, it's best to assume vbus is at VSAFE0V i.e.
6823 * vbus_vsafe0v is true.
6824 *
6825 * 3. When vbus_present is false and TCPC does support querying vsafe0v,
6826 * then, query tcpc for vsafe0v status.
6827 */
6828 if (port->vbus_present)
6829 port->vbus_vsafe0v = false;
6830 else if (!port->tcpc->is_vbus_vsafe0v)
6831 port->vbus_vsafe0v = true;
6832 else
6833 port->vbus_vsafe0v = port->tcpc->is_vbus_vsafe0v(port->tcpc);
6834
6835 tcpm_set_state(port, tcpm_default_state(port), 0);
6836
6837 if (port->tcpc->get_cc(port->tcpc, &cc1, &cc2) == 0)
6838 _tcpm_cc_change(port, cc1, cc2);
6839
6840 /*
6841 * Some adapters need a clean slate at startup, and won't recover
6842 * otherwise. So do not try to be fancy and force a clean disconnect.
6843 */
6844 tcpm_set_state(port, PORT_RESET, 0);
6845 }
6846
tcpm_port_type_set(struct typec_port * p,enum typec_port_type type)6847 static int tcpm_port_type_set(struct typec_port *p, enum typec_port_type type)
6848 {
6849 struct tcpm_port *port = typec_get_drvdata(p);
6850
6851 mutex_lock(&port->lock);
6852 if (type == port->port_type)
6853 goto port_unlock;
6854
6855 port->port_type = type;
6856
6857 if (!port->connected) {
6858 tcpm_set_state(port, PORT_RESET, 0);
6859 } else if (type == TYPEC_PORT_SNK) {
6860 if (!(port->pwr_role == TYPEC_SINK &&
6861 port->data_role == TYPEC_DEVICE))
6862 tcpm_set_state(port, PORT_RESET, 0);
6863 } else if (type == TYPEC_PORT_SRC) {
6864 if (!(port->pwr_role == TYPEC_SOURCE &&
6865 port->data_role == TYPEC_HOST))
6866 tcpm_set_state(port, PORT_RESET, 0);
6867 }
6868
6869 port_unlock:
6870 mutex_unlock(&port->lock);
6871 return 0;
6872 }
6873
tcpm_find_pd_data(struct tcpm_port * port,struct usb_power_delivery * pd)6874 static struct pd_data *tcpm_find_pd_data(struct tcpm_port *port, struct usb_power_delivery *pd)
6875 {
6876 int i;
6877
6878 for (i = 0; port->pd_list[i]; i++) {
6879 if (port->pd_list[i]->pd == pd)
6880 return port->pd_list[i];
6881 }
6882
6883 return ERR_PTR(-ENODATA);
6884 }
6885
tcpm_pd_get(struct typec_port * p)6886 static struct usb_power_delivery **tcpm_pd_get(struct typec_port *p)
6887 {
6888 struct tcpm_port *port = typec_get_drvdata(p);
6889
6890 return port->pds;
6891 }
6892
tcpm_pd_set(struct typec_port * p,struct usb_power_delivery * pd)6893 static int tcpm_pd_set(struct typec_port *p, struct usb_power_delivery *pd)
6894 {
6895 struct tcpm_port *port = typec_get_drvdata(p);
6896 struct pd_data *data;
6897 int i, ret = 0;
6898
6899 mutex_lock(&port->lock);
6900
6901 if (port->selected_pd == pd)
6902 goto unlock;
6903
6904 data = tcpm_find_pd_data(port, pd);
6905 if (IS_ERR(data)) {
6906 ret = PTR_ERR(data);
6907 goto unlock;
6908 }
6909
6910 if (data->sink_desc.pdo[0]) {
6911 for (i = 0; i < PDO_MAX_OBJECTS && data->sink_desc.pdo[i]; i++)
6912 port->snk_pdo[i] = data->sink_desc.pdo[i];
6913 port->nr_snk_pdo = i;
6914 port->operating_snk_mw = data->operating_snk_mw;
6915 }
6916
6917 if (data->source_desc.pdo[0]) {
6918 for (i = 0; i < PDO_MAX_OBJECTS && data->source_desc.pdo[i]; i++)
6919 port->src_pdo[i] = data->source_desc.pdo[i];
6920 port->nr_src_pdo = i;
6921 }
6922
6923 switch (port->state) {
6924 case SRC_UNATTACHED:
6925 case SRC_ATTACH_WAIT:
6926 case SRC_TRYWAIT:
6927 tcpm_set_cc(port, tcpm_rp_cc(port));
6928 break;
6929 case SRC_SEND_CAPABILITIES:
6930 case SRC_SEND_CAPABILITIES_TIMEOUT:
6931 case SRC_NEGOTIATE_CAPABILITIES:
6932 case SRC_READY:
6933 case SRC_WAIT_NEW_CAPABILITIES:
6934 port->caps_count = 0;
6935 port->upcoming_state = SRC_SEND_CAPABILITIES;
6936 ret = tcpm_ams_start(port, POWER_NEGOTIATION);
6937 if (ret == -EAGAIN) {
6938 port->upcoming_state = INVALID_STATE;
6939 goto unlock;
6940 }
6941 break;
6942 case SNK_NEGOTIATE_CAPABILITIES:
6943 case SNK_NEGOTIATE_PPS_CAPABILITIES:
6944 case SNK_READY:
6945 case SNK_TRANSITION_SINK:
6946 case SNK_TRANSITION_SINK_VBUS:
6947 if (port->pps_data.active)
6948 port->upcoming_state = SNK_NEGOTIATE_PPS_CAPABILITIES;
6949 else if (port->pd_capable)
6950 port->upcoming_state = SNK_NEGOTIATE_CAPABILITIES;
6951 else
6952 break;
6953
6954 port->update_sink_caps = true;
6955
6956 ret = tcpm_ams_start(port, POWER_NEGOTIATION);
6957 if (ret == -EAGAIN) {
6958 port->upcoming_state = INVALID_STATE;
6959 goto unlock;
6960 }
6961 break;
6962 default:
6963 break;
6964 }
6965
6966 port->port_source_caps = data->source_cap;
6967 port->port_sink_caps = data->sink_cap;
6968 typec_port_set_usb_power_delivery(p, NULL);
6969 port->selected_pd = pd;
6970 typec_port_set_usb_power_delivery(p, port->selected_pd);
6971 unlock:
6972 mutex_unlock(&port->lock);
6973 return ret;
6974 }
6975
6976 static const struct typec_operations tcpm_ops = {
6977 .try_role = tcpm_try_role,
6978 .dr_set = tcpm_dr_set,
6979 .pr_set = tcpm_pr_set,
6980 .vconn_set = tcpm_vconn_set,
6981 .port_type_set = tcpm_port_type_set,
6982 .pd_get = tcpm_pd_get,
6983 .pd_set = tcpm_pd_set
6984 };
6985
tcpm_tcpc_reset(struct tcpm_port * port)6986 void tcpm_tcpc_reset(struct tcpm_port *port)
6987 {
6988 mutex_lock(&port->lock);
6989 /* XXX: Maintain PD connection if possible? */
6990 tcpm_init(port);
6991 mutex_unlock(&port->lock);
6992 }
6993 EXPORT_SYMBOL_GPL(tcpm_tcpc_reset);
6994
tcpm_port_unregister_pd(struct tcpm_port * port)6995 static void tcpm_port_unregister_pd(struct tcpm_port *port)
6996 {
6997 int i;
6998
6999 port->port_sink_caps = NULL;
7000 port->port_source_caps = NULL;
7001 for (i = 0; i < port->pd_count; i++) {
7002 usb_power_delivery_unregister_capabilities(port->pd_list[i]->sink_cap);
7003 usb_power_delivery_unregister_capabilities(port->pd_list[i]->source_cap);
7004 devm_kfree(port->dev, port->pd_list[i]);
7005 port->pd_list[i] = NULL;
7006 usb_power_delivery_unregister(port->pds[i]);
7007 port->pds[i] = NULL;
7008 }
7009 }
7010
tcpm_port_register_pd(struct tcpm_port * port)7011 static int tcpm_port_register_pd(struct tcpm_port *port)
7012 {
7013 struct usb_power_delivery_desc desc = { port->typec_caps.pd_revision };
7014 struct usb_power_delivery_capabilities *cap;
7015 int ret, i;
7016
7017 if (!port->nr_src_pdo && !port->nr_snk_pdo)
7018 return 0;
7019
7020 for (i = 0; i < port->pd_count; i++) {
7021 port->pds[i] = usb_power_delivery_register(port->dev, &desc);
7022 if (IS_ERR(port->pds[i])) {
7023 ret = PTR_ERR(port->pds[i]);
7024 goto err_unregister;
7025 }
7026 port->pd_list[i]->pd = port->pds[i];
7027
7028 if (port->pd_list[i]->source_desc.pdo[0]) {
7029 cap = usb_power_delivery_register_capabilities(port->pds[i],
7030 &port->pd_list[i]->source_desc);
7031 if (IS_ERR(cap)) {
7032 ret = PTR_ERR(cap);
7033 goto err_unregister;
7034 }
7035 port->pd_list[i]->source_cap = cap;
7036 }
7037
7038 if (port->pd_list[i]->sink_desc.pdo[0]) {
7039 cap = usb_power_delivery_register_capabilities(port->pds[i],
7040 &port->pd_list[i]->sink_desc);
7041 if (IS_ERR(cap)) {
7042 ret = PTR_ERR(cap);
7043 goto err_unregister;
7044 }
7045 port->pd_list[i]->sink_cap = cap;
7046 }
7047 }
7048
7049 port->port_source_caps = port->pd_list[0]->source_cap;
7050 port->port_sink_caps = port->pd_list[0]->sink_cap;
7051 port->selected_pd = port->pds[0];
7052 return 0;
7053
7054 err_unregister:
7055 tcpm_port_unregister_pd(port);
7056
7057 return ret;
7058 }
7059
tcpm_fw_get_caps(struct tcpm_port * port,struct fwnode_handle * fwnode)7060 static int tcpm_fw_get_caps(struct tcpm_port *port, struct fwnode_handle *fwnode)
7061 {
7062 struct fwnode_handle *capabilities, *child, *caps = NULL;
7063 unsigned int nr_src_pdo, nr_snk_pdo;
7064 const char *opmode_str;
7065 u32 *src_pdo, *snk_pdo;
7066 u32 uw, frs_current;
7067 int ret = 0, i;
7068 int mode;
7069
7070 if (!fwnode)
7071 return -EINVAL;
7072
7073 /*
7074 * This fwnode has a "compatible" property, but is never populated as a
7075 * struct device. Instead we simply parse it to read the properties.
7076 * This it breaks fw_devlink=on. To maintain backward compatibility
7077 * with existing DT files, we work around this by deleting any
7078 * fwnode_links to/from this fwnode.
7079 */
7080 fw_devlink_purge_absent_suppliers(fwnode);
7081
7082 ret = typec_get_fw_cap(&port->typec_caps, fwnode);
7083 if (ret < 0)
7084 return ret;
7085
7086 mode = 0;
7087
7088 if (fwnode_property_read_bool(fwnode, "accessory-mode-audio"))
7089 port->typec_caps.accessory[mode++] = TYPEC_ACCESSORY_AUDIO;
7090
7091 if (fwnode_property_read_bool(fwnode, "accessory-mode-debug"))
7092 port->typec_caps.accessory[mode++] = TYPEC_ACCESSORY_DEBUG;
7093
7094 port->port_type = port->typec_caps.type;
7095 port->pd_supported = !fwnode_property_read_bool(fwnode, "pd-disable");
7096 port->slow_charger_loop = fwnode_property_read_bool(fwnode, "slow-charger-loop");
7097 port->self_powered = fwnode_property_read_bool(fwnode, "self-powered");
7098
7099 if (!port->pd_supported) {
7100 ret = fwnode_property_read_string(fwnode, "typec-power-opmode", &opmode_str);
7101 if (ret)
7102 return ret;
7103 ret = typec_find_pwr_opmode(opmode_str);
7104 if (ret < 0)
7105 return ret;
7106 port->src_rp = tcpm_pwr_opmode_to_rp(ret);
7107 return 0;
7108 }
7109
7110 /* The following code are applicable to pd-capable ports, i.e. pd_supported is true. */
7111
7112 /* FRS can only be supported by DRP ports */
7113 if (port->port_type == TYPEC_PORT_DRP) {
7114 ret = fwnode_property_read_u32(fwnode, "new-source-frs-typec-current",
7115 &frs_current);
7116 if (!ret && frs_current <= FRS_5V_3A)
7117 port->new_source_frs_current = frs_current;
7118
7119 if (ret)
7120 ret = 0;
7121 }
7122
7123 /* For the backward compatibility, "capabilities" node is optional. */
7124 capabilities = fwnode_get_named_child_node(fwnode, "capabilities");
7125 if (!capabilities) {
7126 port->pd_count = 1;
7127 } else {
7128 fwnode_for_each_child_node(capabilities, child)
7129 port->pd_count++;
7130
7131 if (!port->pd_count) {
7132 ret = -ENODATA;
7133 goto put_capabilities;
7134 }
7135 }
7136
7137 port->pds = devm_kcalloc(port->dev, port->pd_count, sizeof(struct usb_power_delivery *),
7138 GFP_KERNEL);
7139 if (!port->pds) {
7140 ret = -ENOMEM;
7141 goto put_capabilities;
7142 }
7143
7144 port->pd_list = devm_kcalloc(port->dev, port->pd_count, sizeof(struct pd_data *),
7145 GFP_KERNEL);
7146 if (!port->pd_list) {
7147 ret = -ENOMEM;
7148 goto put_capabilities;
7149 }
7150
7151 for (i = 0; i < port->pd_count; i++) {
7152 port->pd_list[i] = devm_kzalloc(port->dev, sizeof(struct pd_data), GFP_KERNEL);
7153 if (!port->pd_list[i]) {
7154 ret = -ENOMEM;
7155 goto put_capabilities;
7156 }
7157
7158 src_pdo = port->pd_list[i]->source_desc.pdo;
7159 port->pd_list[i]->source_desc.role = TYPEC_SOURCE;
7160 snk_pdo = port->pd_list[i]->sink_desc.pdo;
7161 port->pd_list[i]->sink_desc.role = TYPEC_SINK;
7162
7163 /* If "capabilities" is NULL, fall back to single pd cap population. */
7164 if (!capabilities)
7165 caps = fwnode;
7166 else
7167 caps = fwnode_get_next_child_node(capabilities, caps);
7168
7169 if (port->port_type != TYPEC_PORT_SNK) {
7170 ret = fwnode_property_count_u32(caps, "source-pdos");
7171 if (ret == 0) {
7172 ret = -EINVAL;
7173 goto put_caps;
7174 }
7175 if (ret < 0)
7176 goto put_caps;
7177
7178 nr_src_pdo = min(ret, PDO_MAX_OBJECTS);
7179 ret = fwnode_property_read_u32_array(caps, "source-pdos", src_pdo,
7180 nr_src_pdo);
7181 if (ret)
7182 goto put_caps;
7183
7184 ret = tcpm_validate_caps(port, src_pdo, nr_src_pdo);
7185 if (ret)
7186 goto put_caps;
7187
7188 if (i == 0) {
7189 port->nr_src_pdo = nr_src_pdo;
7190 memcpy_and_pad(port->src_pdo, sizeof(u32) * PDO_MAX_OBJECTS,
7191 port->pd_list[0]->source_desc.pdo,
7192 sizeof(u32) * nr_src_pdo,
7193 0);
7194 }
7195 }
7196
7197 if (port->port_type != TYPEC_PORT_SRC) {
7198 ret = fwnode_property_count_u32(caps, "sink-pdos");
7199 if (ret == 0) {
7200 ret = -EINVAL;
7201 goto put_caps;
7202 }
7203
7204 if (ret < 0)
7205 goto put_caps;
7206
7207 nr_snk_pdo = min(ret, PDO_MAX_OBJECTS);
7208 ret = fwnode_property_read_u32_array(caps, "sink-pdos", snk_pdo,
7209 nr_snk_pdo);
7210 if (ret)
7211 goto put_caps;
7212
7213 ret = tcpm_validate_caps(port, snk_pdo, nr_snk_pdo);
7214 if (ret)
7215 goto put_caps;
7216
7217 if (fwnode_property_read_u32(caps, "op-sink-microwatt", &uw) < 0) {
7218 ret = -EINVAL;
7219 goto put_caps;
7220 }
7221
7222 port->pd_list[i]->operating_snk_mw = uw / 1000;
7223
7224 if (i == 0) {
7225 port->nr_snk_pdo = nr_snk_pdo;
7226 memcpy_and_pad(port->snk_pdo, sizeof(u32) * PDO_MAX_OBJECTS,
7227 port->pd_list[0]->sink_desc.pdo,
7228 sizeof(u32) * nr_snk_pdo,
7229 0);
7230 port->operating_snk_mw = port->pd_list[0]->operating_snk_mw;
7231 }
7232 }
7233 }
7234
7235 put_caps:
7236 if (caps != fwnode)
7237 fwnode_handle_put(caps);
7238 put_capabilities:
7239 fwnode_handle_put(capabilities);
7240 return ret;
7241 }
7242
tcpm_fw_get_snk_vdos(struct tcpm_port * port,struct fwnode_handle * fwnode)7243 static int tcpm_fw_get_snk_vdos(struct tcpm_port *port, struct fwnode_handle *fwnode)
7244 {
7245 int ret;
7246
7247 /* sink-vdos is optional */
7248 ret = fwnode_property_count_u32(fwnode, "sink-vdos");
7249 if (ret < 0)
7250 return 0;
7251
7252 port->nr_snk_vdo = min(ret, VDO_MAX_OBJECTS);
7253 if (port->nr_snk_vdo) {
7254 ret = fwnode_property_read_u32_array(fwnode, "sink-vdos",
7255 port->snk_vdo,
7256 port->nr_snk_vdo);
7257 if (ret < 0)
7258 return ret;
7259 }
7260
7261 /* If sink-vdos is found, sink-vdos-v1 is expected for backward compatibility. */
7262 if (port->nr_snk_vdo) {
7263 ret = fwnode_property_count_u32(fwnode, "sink-vdos-v1");
7264 if (ret < 0)
7265 return ret;
7266 else if (ret == 0)
7267 return -ENODATA;
7268
7269 port->nr_snk_vdo_v1 = min(ret, VDO_MAX_OBJECTS);
7270 ret = fwnode_property_read_u32_array(fwnode, "sink-vdos-v1",
7271 port->snk_vdo_v1,
7272 port->nr_snk_vdo_v1);
7273 if (ret < 0)
7274 return ret;
7275 }
7276
7277 return 0;
7278 }
7279
7280 /* Power Supply access to expose source power information */
7281 enum tcpm_psy_online_states {
7282 TCPM_PSY_OFFLINE = 0,
7283 TCPM_PSY_FIXED_ONLINE,
7284 TCPM_PSY_PROG_ONLINE,
7285 };
7286
7287 static enum power_supply_property tcpm_psy_props[] = {
7288 POWER_SUPPLY_PROP_USB_TYPE,
7289 POWER_SUPPLY_PROP_ONLINE,
7290 POWER_SUPPLY_PROP_VOLTAGE_MIN,
7291 POWER_SUPPLY_PROP_VOLTAGE_MAX,
7292 POWER_SUPPLY_PROP_VOLTAGE_NOW,
7293 POWER_SUPPLY_PROP_CURRENT_MAX,
7294 POWER_SUPPLY_PROP_CURRENT_NOW,
7295 };
7296
tcpm_psy_get_online(struct tcpm_port * port,union power_supply_propval * val)7297 static int tcpm_psy_get_online(struct tcpm_port *port,
7298 union power_supply_propval *val)
7299 {
7300 if (port->vbus_charge) {
7301 if (port->pps_data.active)
7302 val->intval = TCPM_PSY_PROG_ONLINE;
7303 else
7304 val->intval = TCPM_PSY_FIXED_ONLINE;
7305 } else {
7306 val->intval = TCPM_PSY_OFFLINE;
7307 }
7308
7309 return 0;
7310 }
7311
tcpm_psy_get_voltage_min(struct tcpm_port * port,union power_supply_propval * val)7312 static int tcpm_psy_get_voltage_min(struct tcpm_port *port,
7313 union power_supply_propval *val)
7314 {
7315 if (port->pps_data.active)
7316 val->intval = port->pps_data.min_volt * 1000;
7317 else
7318 val->intval = port->supply_voltage * 1000;
7319
7320 return 0;
7321 }
7322
tcpm_psy_get_voltage_max(struct tcpm_port * port,union power_supply_propval * val)7323 static int tcpm_psy_get_voltage_max(struct tcpm_port *port,
7324 union power_supply_propval *val)
7325 {
7326 if (port->pps_data.active)
7327 val->intval = port->pps_data.max_volt * 1000;
7328 else
7329 val->intval = port->supply_voltage * 1000;
7330
7331 return 0;
7332 }
7333
tcpm_psy_get_voltage_now(struct tcpm_port * port,union power_supply_propval * val)7334 static int tcpm_psy_get_voltage_now(struct tcpm_port *port,
7335 union power_supply_propval *val)
7336 {
7337 val->intval = port->supply_voltage * 1000;
7338
7339 return 0;
7340 }
7341
tcpm_psy_get_current_max(struct tcpm_port * port,union power_supply_propval * val)7342 static int tcpm_psy_get_current_max(struct tcpm_port *port,
7343 union power_supply_propval *val)
7344 {
7345 if (port->pps_data.active)
7346 val->intval = port->pps_data.max_curr * 1000;
7347 else
7348 val->intval = port->current_limit * 1000;
7349
7350 return 0;
7351 }
7352
tcpm_psy_get_current_now(struct tcpm_port * port,union power_supply_propval * val)7353 static int tcpm_psy_get_current_now(struct tcpm_port *port,
7354 union power_supply_propval *val)
7355 {
7356 val->intval = port->current_limit * 1000;
7357
7358 return 0;
7359 }
7360
tcpm_psy_get_input_power_limit(struct tcpm_port * port,union power_supply_propval * val)7361 static int tcpm_psy_get_input_power_limit(struct tcpm_port *port,
7362 union power_supply_propval *val)
7363 {
7364 unsigned int src_mv, src_ma, max_src_uw = 0;
7365 unsigned int i, tmp;
7366
7367 for (i = 0; i < port->nr_source_caps; i++) {
7368 u32 pdo = port->source_caps[i];
7369
7370 if (pdo_type(pdo) == PDO_TYPE_FIXED) {
7371 src_mv = pdo_fixed_voltage(pdo);
7372 src_ma = pdo_max_current(pdo);
7373 tmp = src_mv * src_ma;
7374 max_src_uw = tmp > max_src_uw ? tmp : max_src_uw;
7375 }
7376 }
7377
7378 val->intval = max_src_uw;
7379 return 0;
7380 }
7381
tcpm_psy_get_prop(struct power_supply * psy,enum power_supply_property psp,union power_supply_propval * val)7382 static int tcpm_psy_get_prop(struct power_supply *psy,
7383 enum power_supply_property psp,
7384 union power_supply_propval *val)
7385 {
7386 struct tcpm_port *port = power_supply_get_drvdata(psy);
7387 int ret = 0;
7388
7389 switch (psp) {
7390 case POWER_SUPPLY_PROP_USB_TYPE:
7391 val->intval = port->usb_type;
7392 break;
7393 case POWER_SUPPLY_PROP_ONLINE:
7394 ret = tcpm_psy_get_online(port, val);
7395 break;
7396 case POWER_SUPPLY_PROP_VOLTAGE_MIN:
7397 ret = tcpm_psy_get_voltage_min(port, val);
7398 break;
7399 case POWER_SUPPLY_PROP_VOLTAGE_MAX:
7400 ret = tcpm_psy_get_voltage_max(port, val);
7401 break;
7402 case POWER_SUPPLY_PROP_VOLTAGE_NOW:
7403 ret = tcpm_psy_get_voltage_now(port, val);
7404 break;
7405 case POWER_SUPPLY_PROP_CURRENT_MAX:
7406 ret = tcpm_psy_get_current_max(port, val);
7407 break;
7408 case POWER_SUPPLY_PROP_CURRENT_NOW:
7409 ret = tcpm_psy_get_current_now(port, val);
7410 break;
7411 case POWER_SUPPLY_PROP_INPUT_POWER_LIMIT:
7412 tcpm_psy_get_input_power_limit(port, val);
7413 break;
7414 default:
7415 ret = -EINVAL;
7416 break;
7417 }
7418
7419 return ret;
7420 }
7421
tcpm_psy_set_online(struct tcpm_port * port,const union power_supply_propval * val)7422 static int tcpm_psy_set_online(struct tcpm_port *port,
7423 const union power_supply_propval *val)
7424 {
7425 int ret;
7426
7427 switch (val->intval) {
7428 case TCPM_PSY_FIXED_ONLINE:
7429 ret = tcpm_pps_activate(port, false);
7430 break;
7431 case TCPM_PSY_PROG_ONLINE:
7432 ret = tcpm_pps_activate(port, true);
7433 break;
7434 default:
7435 ret = -EINVAL;
7436 break;
7437 }
7438
7439 return ret;
7440 }
7441
tcpm_psy_set_prop(struct power_supply * psy,enum power_supply_property psp,const union power_supply_propval * val)7442 static int tcpm_psy_set_prop(struct power_supply *psy,
7443 enum power_supply_property psp,
7444 const union power_supply_propval *val)
7445 {
7446 struct tcpm_port *port = power_supply_get_drvdata(psy);
7447 int ret;
7448
7449 /*
7450 * All the properties below are related to USB PD. The check needs to be
7451 * property specific when a non-pd related property is added.
7452 */
7453 if (!port->pd_supported)
7454 return -EOPNOTSUPP;
7455
7456 switch (psp) {
7457 case POWER_SUPPLY_PROP_ONLINE:
7458 ret = tcpm_psy_set_online(port, val);
7459 break;
7460 case POWER_SUPPLY_PROP_VOLTAGE_NOW:
7461 ret = tcpm_pps_set_out_volt(port, val->intval / 1000);
7462 break;
7463 case POWER_SUPPLY_PROP_CURRENT_NOW:
7464 if (val->intval > port->pps_data.max_curr * 1000)
7465 ret = -EINVAL;
7466 else
7467 ret = tcpm_pps_set_op_curr(port, val->intval / 1000);
7468 break;
7469 default:
7470 ret = -EINVAL;
7471 break;
7472 }
7473 power_supply_changed(port->psy);
7474 return ret;
7475 }
7476
tcpm_psy_prop_writeable(struct power_supply * psy,enum power_supply_property psp)7477 static int tcpm_psy_prop_writeable(struct power_supply *psy,
7478 enum power_supply_property psp)
7479 {
7480 switch (psp) {
7481 case POWER_SUPPLY_PROP_ONLINE:
7482 case POWER_SUPPLY_PROP_VOLTAGE_NOW:
7483 case POWER_SUPPLY_PROP_CURRENT_NOW:
7484 return 1;
7485 default:
7486 return 0;
7487 }
7488 }
7489
7490 static const char *tcpm_psy_name_prefix = "tcpm-source-psy-";
7491
devm_tcpm_psy_register(struct tcpm_port * port)7492 static int devm_tcpm_psy_register(struct tcpm_port *port)
7493 {
7494 struct power_supply_config psy_cfg = {};
7495 const char *port_dev_name = dev_name(port->dev);
7496 size_t psy_name_len = strlen(tcpm_psy_name_prefix) +
7497 strlen(port_dev_name) + 1;
7498 char *psy_name;
7499
7500 psy_cfg.drv_data = port;
7501 psy_cfg.fwnode = dev_fwnode(port->dev);
7502 psy_name = devm_kzalloc(port->dev, psy_name_len, GFP_KERNEL);
7503 if (!psy_name)
7504 return -ENOMEM;
7505
7506 snprintf(psy_name, psy_name_len, "%s%s", tcpm_psy_name_prefix,
7507 port_dev_name);
7508 port->psy_desc.name = psy_name;
7509 port->psy_desc.type = POWER_SUPPLY_TYPE_USB;
7510 port->psy_desc.usb_types = BIT(POWER_SUPPLY_USB_TYPE_C) |
7511 BIT(POWER_SUPPLY_USB_TYPE_PD) |
7512 BIT(POWER_SUPPLY_USB_TYPE_PD_PPS);
7513 port->psy_desc.properties = tcpm_psy_props;
7514 port->psy_desc.num_properties = ARRAY_SIZE(tcpm_psy_props);
7515 port->psy_desc.get_property = tcpm_psy_get_prop;
7516 port->psy_desc.set_property = tcpm_psy_set_prop;
7517 port->psy_desc.property_is_writeable = tcpm_psy_prop_writeable;
7518
7519 port->usb_type = POWER_SUPPLY_USB_TYPE_C;
7520
7521 port->psy = devm_power_supply_register(port->dev, &port->psy_desc,
7522 &psy_cfg);
7523
7524 return PTR_ERR_OR_ZERO(port->psy);
7525 }
7526
state_machine_timer_handler(struct hrtimer * timer)7527 static enum hrtimer_restart state_machine_timer_handler(struct hrtimer *timer)
7528 {
7529 struct tcpm_port *port = container_of(timer, struct tcpm_port, state_machine_timer);
7530
7531 if (port->registered)
7532 kthread_queue_work(port->wq, &port->state_machine);
7533 return HRTIMER_NORESTART;
7534 }
7535
vdm_state_machine_timer_handler(struct hrtimer * timer)7536 static enum hrtimer_restart vdm_state_machine_timer_handler(struct hrtimer *timer)
7537 {
7538 struct tcpm_port *port = container_of(timer, struct tcpm_port, vdm_state_machine_timer);
7539
7540 if (port->registered)
7541 kthread_queue_work(port->wq, &port->vdm_state_machine);
7542 return HRTIMER_NORESTART;
7543 }
7544
enable_frs_timer_handler(struct hrtimer * timer)7545 static enum hrtimer_restart enable_frs_timer_handler(struct hrtimer *timer)
7546 {
7547 struct tcpm_port *port = container_of(timer, struct tcpm_port, enable_frs_timer);
7548
7549 if (port->registered)
7550 kthread_queue_work(port->wq, &port->enable_frs);
7551 return HRTIMER_NORESTART;
7552 }
7553
send_discover_timer_handler(struct hrtimer * timer)7554 static enum hrtimer_restart send_discover_timer_handler(struct hrtimer *timer)
7555 {
7556 struct tcpm_port *port = container_of(timer, struct tcpm_port, send_discover_timer);
7557
7558 if (port->registered)
7559 kthread_queue_work(port->wq, &port->send_discover_work);
7560 return HRTIMER_NORESTART;
7561 }
7562
tcpm_register_port(struct device * dev,struct tcpc_dev * tcpc)7563 struct tcpm_port *tcpm_register_port(struct device *dev, struct tcpc_dev *tcpc)
7564 {
7565 struct tcpm_port *port;
7566 int err;
7567
7568 if (!dev || !tcpc ||
7569 !tcpc->get_vbus || !tcpc->set_cc || !tcpc->get_cc ||
7570 !tcpc->set_polarity || !tcpc->set_vconn || !tcpc->set_vbus ||
7571 !tcpc->set_pd_rx || !tcpc->set_roles || !tcpc->pd_transmit)
7572 return ERR_PTR(-EINVAL);
7573
7574 port = devm_kzalloc(dev, sizeof(*port), GFP_KERNEL);
7575 if (!port)
7576 return ERR_PTR(-ENOMEM);
7577
7578 port->dev = dev;
7579 port->tcpc = tcpc;
7580
7581 mutex_init(&port->lock);
7582 mutex_init(&port->swap_lock);
7583
7584 port->wq = kthread_create_worker(0, dev_name(dev));
7585 if (IS_ERR(port->wq))
7586 return ERR_CAST(port->wq);
7587 sched_set_fifo(port->wq->task);
7588
7589 kthread_init_work(&port->state_machine, tcpm_state_machine_work);
7590 kthread_init_work(&port->vdm_state_machine, vdm_state_machine_work);
7591 kthread_init_work(&port->event_work, tcpm_pd_event_handler);
7592 kthread_init_work(&port->enable_frs, tcpm_enable_frs_work);
7593 kthread_init_work(&port->send_discover_work, tcpm_send_discover_work);
7594 hrtimer_init(&port->state_machine_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL);
7595 port->state_machine_timer.function = state_machine_timer_handler;
7596 hrtimer_init(&port->vdm_state_machine_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL);
7597 port->vdm_state_machine_timer.function = vdm_state_machine_timer_handler;
7598 hrtimer_init(&port->enable_frs_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL);
7599 port->enable_frs_timer.function = enable_frs_timer_handler;
7600 hrtimer_init(&port->send_discover_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL);
7601 port->send_discover_timer.function = send_discover_timer_handler;
7602
7603 spin_lock_init(&port->pd_event_lock);
7604
7605 init_completion(&port->tx_complete);
7606 init_completion(&port->swap_complete);
7607 init_completion(&port->pps_complete);
7608 tcpm_debugfs_init(port);
7609
7610 err = tcpm_fw_get_caps(port, tcpc->fwnode);
7611 if (err < 0)
7612 goto out_destroy_wq;
7613 err = tcpm_fw_get_snk_vdos(port, tcpc->fwnode);
7614 if (err < 0)
7615 goto out_destroy_wq;
7616
7617 port->try_role = port->typec_caps.prefer_role;
7618
7619 port->typec_caps.revision = 0x0120; /* Type-C spec release 1.2 */
7620 port->typec_caps.pd_revision = 0x0300; /* USB-PD spec release 3.0 */
7621 port->typec_caps.svdm_version = SVDM_VER_2_0;
7622 port->typec_caps.driver_data = port;
7623 port->typec_caps.ops = &tcpm_ops;
7624 port->typec_caps.orientation_aware = 1;
7625
7626 port->partner_desc.identity = &port->partner_ident;
7627
7628 port->role_sw = usb_role_switch_get(port->dev);
7629 if (!port->role_sw)
7630 port->role_sw = fwnode_usb_role_switch_get(tcpc->fwnode);
7631 if (IS_ERR(port->role_sw)) {
7632 err = PTR_ERR(port->role_sw);
7633 goto out_destroy_wq;
7634 }
7635
7636 err = devm_tcpm_psy_register(port);
7637 if (err)
7638 goto out_role_sw_put;
7639 power_supply_changed(port->psy);
7640
7641 err = tcpm_port_register_pd(port);
7642 if (err)
7643 goto out_role_sw_put;
7644
7645 if (port->pds)
7646 port->typec_caps.pd = port->pds[0];
7647
7648 port->typec_port = typec_register_port(port->dev, &port->typec_caps);
7649 if (IS_ERR(port->typec_port)) {
7650 err = PTR_ERR(port->typec_port);
7651 goto out_unregister_pd;
7652 }
7653
7654 typec_port_register_altmodes(port->typec_port,
7655 &tcpm_altmode_ops, port,
7656 port->port_altmode, ALTMODE_DISCOVERY_MAX);
7657 typec_port_register_cable_ops(port->port_altmode, ARRAY_SIZE(port->port_altmode),
7658 &tcpm_cable_ops);
7659 port->registered = true;
7660
7661 mutex_lock(&port->lock);
7662 tcpm_init(port);
7663 mutex_unlock(&port->lock);
7664
7665 tcpm_log(port, "%s: registered", dev_name(dev));
7666 return port;
7667
7668 out_unregister_pd:
7669 tcpm_port_unregister_pd(port);
7670 out_role_sw_put:
7671 usb_role_switch_put(port->role_sw);
7672 out_destroy_wq:
7673 tcpm_debugfs_exit(port);
7674 kthread_destroy_worker(port->wq);
7675 return ERR_PTR(err);
7676 }
7677 EXPORT_SYMBOL_GPL(tcpm_register_port);
7678
tcpm_unregister_port(struct tcpm_port * port)7679 void tcpm_unregister_port(struct tcpm_port *port)
7680 {
7681 int i;
7682
7683 port->registered = false;
7684 kthread_destroy_worker(port->wq);
7685
7686 hrtimer_cancel(&port->send_discover_timer);
7687 hrtimer_cancel(&port->enable_frs_timer);
7688 hrtimer_cancel(&port->vdm_state_machine_timer);
7689 hrtimer_cancel(&port->state_machine_timer);
7690
7691 tcpm_reset_port(port);
7692
7693 tcpm_port_unregister_pd(port);
7694
7695 for (i = 0; i < ARRAY_SIZE(port->port_altmode); i++)
7696 typec_unregister_altmode(port->port_altmode[i]);
7697 typec_unregister_port(port->typec_port);
7698 usb_role_switch_put(port->role_sw);
7699 tcpm_debugfs_exit(port);
7700 }
7701 EXPORT_SYMBOL_GPL(tcpm_unregister_port);
7702
7703 MODULE_AUTHOR("Guenter Roeck <groeck@chromium.org>");
7704 MODULE_DESCRIPTION("USB Type-C Port Manager");
7705 MODULE_LICENSE("GPL");
7706