1 // SPDX-License-Identifier: BSD-3-Clause
2 /*
3 * Copyright (c) 2020, MIPI Alliance, Inc.
4 *
5 * Author: Nicolas Pitre <npitre@baylibre.com>
6 *
7 * I3C HCI v1.0/v1.1 Command Descriptor Handling
8 */
9
10 #include <linux/bitfield.h>
11 #include <linux/i3c/master.h>
12
13 #include "hci.h"
14 #include "cmd.h"
15 #include "dat.h"
16 #include "dct.h"
17
18
19 /*
20 * Address Assignment Command
21 */
22
23 #define CMD_0_ATTR_A FIELD_PREP(CMD_0_ATTR, 0x2)
24
25 #define CMD_A0_TOC W0_BIT_(31)
26 #define CMD_A0_ROC W0_BIT_(30)
27 #define CMD_A0_DEV_COUNT(v) FIELD_PREP(W0_MASK(29, 26), v)
28 #define CMD_A0_DEV_INDEX(v) FIELD_PREP(W0_MASK(20, 16), v)
29 #define CMD_A0_CMD(v) FIELD_PREP(W0_MASK(14, 7), v)
30 #define CMD_A0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
31
32 /*
33 * Immediate Data Transfer Command
34 */
35
36 #define CMD_0_ATTR_I FIELD_PREP(CMD_0_ATTR, 0x1)
37
38 #define CMD_I1_DATA_BYTE_4(v) FIELD_PREP(W1_MASK(63, 56), v)
39 #define CMD_I1_DATA_BYTE_3(v) FIELD_PREP(W1_MASK(55, 48), v)
40 #define CMD_I1_DATA_BYTE_2(v) FIELD_PREP(W1_MASK(47, 40), v)
41 #define CMD_I1_DATA_BYTE_1(v) FIELD_PREP(W1_MASK(39, 32), v)
42 #define CMD_I1_DEF_BYTE(v) FIELD_PREP(W1_MASK(39, 32), v)
43 #define CMD_I0_TOC W0_BIT_(31)
44 #define CMD_I0_ROC W0_BIT_(30)
45 #define CMD_I0_RNW W0_BIT_(29)
46 #define CMD_I0_MODE(v) FIELD_PREP(W0_MASK(28, 26), v)
47 #define CMD_I0_DTT(v) FIELD_PREP(W0_MASK(25, 23), v)
48 #define CMD_I0_DEV_INDEX(v) FIELD_PREP(W0_MASK(20, 16), v)
49 #define CMD_I0_CP W0_BIT_(15)
50 #define CMD_I0_CMD(v) FIELD_PREP(W0_MASK(14, 7), v)
51 #define CMD_I0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
52
53 /*
54 * Regular Data Transfer Command
55 */
56
57 #define CMD_0_ATTR_R FIELD_PREP(CMD_0_ATTR, 0x0)
58
59 #define CMD_R1_DATA_LENGTH(v) FIELD_PREP(W1_MASK(63, 48), v)
60 #define CMD_R1_DEF_BYTE(v) FIELD_PREP(W1_MASK(39, 32), v)
61 #define CMD_R0_TOC W0_BIT_(31)
62 #define CMD_R0_ROC W0_BIT_(30)
63 #define CMD_R0_RNW W0_BIT_(29)
64 #define CMD_R0_MODE(v) FIELD_PREP(W0_MASK(28, 26), v)
65 #define CMD_R0_DBP W0_BIT_(25)
66 #define CMD_R0_DEV_INDEX(v) FIELD_PREP(W0_MASK(20, 16), v)
67 #define CMD_R0_CP W0_BIT_(15)
68 #define CMD_R0_CMD(v) FIELD_PREP(W0_MASK(14, 7), v)
69 #define CMD_R0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
70
71 /*
72 * Combo Transfer (Write + Write/Read) Command
73 */
74
75 #define CMD_0_ATTR_C FIELD_PREP(CMD_0_ATTR, 0x3)
76
77 #define CMD_C1_DATA_LENGTH(v) FIELD_PREP(W1_MASK(63, 48), v)
78 #define CMD_C1_OFFSET(v) FIELD_PREP(W1_MASK(47, 32), v)
79 #define CMD_C0_TOC W0_BIT_(31)
80 #define CMD_C0_ROC W0_BIT_(30)
81 #define CMD_C0_RNW W0_BIT_(29)
82 #define CMD_C0_MODE(v) FIELD_PREP(W0_MASK(28, 26), v)
83 #define CMD_C0_16_BIT_SUBOFFSET W0_BIT_(25)
84 #define CMD_C0_FIRST_PHASE_MODE W0_BIT_(24)
85 #define CMD_C0_DATA_LENGTH_POSITION(v) FIELD_PREP(W0_MASK(23, 22), v)
86 #define CMD_C0_DEV_INDEX(v) FIELD_PREP(W0_MASK(20, 16), v)
87 #define CMD_C0_CP W0_BIT_(15)
88 #define CMD_C0_CMD(v) FIELD_PREP(W0_MASK(14, 7), v)
89 #define CMD_C0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
90
91 /*
92 * Internal Control Command
93 */
94
95 #define CMD_0_ATTR_M FIELD_PREP(CMD_0_ATTR, 0x7)
96
97 #define CMD_M1_VENDOR_SPECIFIC W1_MASK(63, 32)
98 #define CMD_M0_MIPI_RESERVED W0_MASK(31, 12)
99 #define CMD_M0_MIPI_CMD W0_MASK(11, 8)
100 #define CMD_M0_VENDOR_INFO_PRESENT W0_BIT_( 7)
101 #define CMD_M0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
102
103
104 /* Data Transfer Speed and Mode */
105 enum hci_cmd_mode {
106 MODE_I3C_SDR0 = 0x0,
107 MODE_I3C_SDR1 = 0x1,
108 MODE_I3C_SDR2 = 0x2,
109 MODE_I3C_SDR3 = 0x3,
110 MODE_I3C_SDR4 = 0x4,
111 MODE_I3C_HDR_TSx = 0x5,
112 MODE_I3C_HDR_DDR = 0x6,
113 MODE_I3C_HDR_BT = 0x7,
114 MODE_I3C_Fm_FmP = 0x8,
115 MODE_I2C_Fm = 0x0,
116 MODE_I2C_FmP = 0x1,
117 MODE_I2C_UD1 = 0x2,
118 MODE_I2C_UD2 = 0x3,
119 MODE_I2C_UD3 = 0x4,
120 };
121
get_i3c_mode(struct i3c_hci * hci)122 static enum hci_cmd_mode get_i3c_mode(struct i3c_hci *hci)
123 {
124 struct i3c_bus *bus = i3c_master_get_bus(&hci->master);
125
126 if (bus->scl_rate.i3c >= 12500000)
127 return MODE_I3C_SDR0;
128 if (bus->scl_rate.i3c > 8000000)
129 return MODE_I3C_SDR1;
130 if (bus->scl_rate.i3c > 6000000)
131 return MODE_I3C_SDR2;
132 if (bus->scl_rate.i3c > 4000000)
133 return MODE_I3C_SDR3;
134 if (bus->scl_rate.i3c > 2000000)
135 return MODE_I3C_SDR4;
136 return MODE_I3C_Fm_FmP;
137 }
138
get_i2c_mode(struct i3c_hci * hci)139 static enum hci_cmd_mode get_i2c_mode(struct i3c_hci *hci)
140 {
141 struct i3c_bus *bus = i3c_master_get_bus(&hci->master);
142
143 if (bus->scl_rate.i2c >= 1000000)
144 return MODE_I2C_FmP;
145 return MODE_I2C_Fm;
146 }
147
fill_data_bytes(struct hci_xfer * xfer,u8 * data,unsigned int data_len)148 static void fill_data_bytes(struct hci_xfer *xfer, u8 *data,
149 unsigned int data_len)
150 {
151 xfer->cmd_desc[1] = 0;
152 switch (data_len) {
153 case 4:
154 xfer->cmd_desc[1] |= CMD_I1_DATA_BYTE_4(data[3]);
155 fallthrough;
156 case 3:
157 xfer->cmd_desc[1] |= CMD_I1_DATA_BYTE_3(data[2]);
158 fallthrough;
159 case 2:
160 xfer->cmd_desc[1] |= CMD_I1_DATA_BYTE_2(data[1]);
161 fallthrough;
162 case 1:
163 xfer->cmd_desc[1] |= CMD_I1_DATA_BYTE_1(data[0]);
164 fallthrough;
165 case 0:
166 break;
167 }
168 /* we consumed all the data with the cmd descriptor */
169 xfer->data = NULL;
170 }
171
hci_cmd_v1_prep_ccc(struct i3c_hci * hci,struct hci_xfer * xfer,u8 ccc_addr,u8 ccc_cmd,bool raw)172 static int hci_cmd_v1_prep_ccc(struct i3c_hci *hci,
173 struct hci_xfer *xfer,
174 u8 ccc_addr, u8 ccc_cmd, bool raw)
175 {
176 unsigned int dat_idx = 0;
177 enum hci_cmd_mode mode = get_i3c_mode(hci);
178 u8 *data = xfer->data;
179 unsigned int data_len = xfer->data_len;
180 bool rnw = xfer->rnw;
181 int ret;
182
183 /* this should never happen */
184 if (WARN_ON(raw))
185 return -EINVAL;
186
187 if (ccc_addr != I3C_BROADCAST_ADDR) {
188 ret = mipi_i3c_hci_dat_v1.get_index(hci, ccc_addr);
189 if (ret < 0)
190 return ret;
191 dat_idx = ret;
192 }
193
194 xfer->cmd_tid = hci_get_tid();
195
196 if (!rnw && data_len <= 4) {
197 /* we use an Immediate Data Transfer Command */
198 xfer->cmd_desc[0] =
199 CMD_0_ATTR_I |
200 CMD_I0_TID(xfer->cmd_tid) |
201 CMD_I0_CMD(ccc_cmd) | CMD_I0_CP |
202 CMD_I0_DEV_INDEX(dat_idx) |
203 CMD_I0_DTT(data_len) |
204 CMD_I0_MODE(mode);
205 fill_data_bytes(xfer, data, data_len);
206 } else {
207 /* we use a Regular Data Transfer Command */
208 xfer->cmd_desc[0] =
209 CMD_0_ATTR_R |
210 CMD_R0_TID(xfer->cmd_tid) |
211 CMD_R0_CMD(ccc_cmd) | CMD_R0_CP |
212 CMD_R0_DEV_INDEX(dat_idx) |
213 CMD_R0_MODE(mode) |
214 (rnw ? CMD_R0_RNW : 0);
215 xfer->cmd_desc[1] =
216 CMD_R1_DATA_LENGTH(data_len);
217 }
218
219 return 0;
220 }
221
hci_cmd_v1_prep_i3c_xfer(struct i3c_hci * hci,struct i3c_dev_desc * dev,struct hci_xfer * xfer)222 static void hci_cmd_v1_prep_i3c_xfer(struct i3c_hci *hci,
223 struct i3c_dev_desc *dev,
224 struct hci_xfer *xfer)
225 {
226 struct i3c_hci_dev_data *dev_data = i3c_dev_get_master_data(dev);
227 unsigned int dat_idx = dev_data->dat_idx;
228 enum hci_cmd_mode mode = get_i3c_mode(hci);
229 u8 *data = xfer->data;
230 unsigned int data_len = xfer->data_len;
231 bool rnw = xfer->rnw;
232
233 xfer->cmd_tid = hci_get_tid();
234
235 if (!rnw && data_len <= 4) {
236 /* we use an Immediate Data Transfer Command */
237 xfer->cmd_desc[0] =
238 CMD_0_ATTR_I |
239 CMD_I0_TID(xfer->cmd_tid) |
240 CMD_I0_DEV_INDEX(dat_idx) |
241 CMD_I0_DTT(data_len) |
242 CMD_I0_MODE(mode);
243 fill_data_bytes(xfer, data, data_len);
244 } else {
245 /* we use a Regular Data Transfer Command */
246 xfer->cmd_desc[0] =
247 CMD_0_ATTR_R |
248 CMD_R0_TID(xfer->cmd_tid) |
249 CMD_R0_DEV_INDEX(dat_idx) |
250 CMD_R0_MODE(mode) |
251 (rnw ? CMD_R0_RNW : 0);
252 xfer->cmd_desc[1] =
253 CMD_R1_DATA_LENGTH(data_len);
254 }
255 }
256
hci_cmd_v1_prep_i2c_xfer(struct i3c_hci * hci,struct i2c_dev_desc * dev,struct hci_xfer * xfer)257 static void hci_cmd_v1_prep_i2c_xfer(struct i3c_hci *hci,
258 struct i2c_dev_desc *dev,
259 struct hci_xfer *xfer)
260 {
261 struct i3c_hci_dev_data *dev_data = i2c_dev_get_master_data(dev);
262 unsigned int dat_idx = dev_data->dat_idx;
263 enum hci_cmd_mode mode = get_i2c_mode(hci);
264 u8 *data = xfer->data;
265 unsigned int data_len = xfer->data_len;
266 bool rnw = xfer->rnw;
267
268 xfer->cmd_tid = hci_get_tid();
269
270 if (!rnw && data_len <= 4) {
271 /* we use an Immediate Data Transfer Command */
272 xfer->cmd_desc[0] =
273 CMD_0_ATTR_I |
274 CMD_I0_TID(xfer->cmd_tid) |
275 CMD_I0_DEV_INDEX(dat_idx) |
276 CMD_I0_DTT(data_len) |
277 CMD_I0_MODE(mode);
278 fill_data_bytes(xfer, data, data_len);
279 } else {
280 /* we use a Regular Data Transfer Command */
281 xfer->cmd_desc[0] =
282 CMD_0_ATTR_R |
283 CMD_R0_TID(xfer->cmd_tid) |
284 CMD_R0_DEV_INDEX(dat_idx) |
285 CMD_R0_MODE(mode) |
286 (rnw ? CMD_R0_RNW : 0);
287 xfer->cmd_desc[1] =
288 CMD_R1_DATA_LENGTH(data_len);
289 }
290 }
291
hci_cmd_v1_daa(struct i3c_hci * hci)292 static int hci_cmd_v1_daa(struct i3c_hci *hci)
293 {
294 struct hci_xfer *xfer;
295 int ret, dat_idx = -1;
296 u8 next_addr = 0;
297 u64 pid;
298 unsigned int dcr, bcr;
299 DECLARE_COMPLETION_ONSTACK(done);
300
301 xfer = hci_alloc_xfer(2);
302 if (!xfer)
303 return -ENOMEM;
304
305 /*
306 * Simple for now: we allocate a temporary DAT entry, do a single
307 * DAA, register the device which will allocate its own DAT entry
308 * via the core callback, then free the temporary DAT entry.
309 * Loop until there is no more devices to assign an address to.
310 * Yes, there is room for improvements.
311 */
312 for (;;) {
313 ret = mipi_i3c_hci_dat_v1.alloc_entry(hci);
314 if (ret < 0)
315 break;
316 dat_idx = ret;
317 ret = i3c_master_get_free_addr(&hci->master, next_addr);
318 if (ret < 0)
319 break;
320 next_addr = ret;
321
322 DBG("next_addr = 0x%02x, DAA using DAT %d", next_addr, dat_idx);
323 mipi_i3c_hci_dat_v1.set_dynamic_addr(hci, dat_idx, next_addr);
324 mipi_i3c_hci_dct_index_reset(hci);
325
326 xfer->cmd_tid = hci_get_tid();
327 xfer->cmd_desc[0] =
328 CMD_0_ATTR_A |
329 CMD_A0_TID(xfer->cmd_tid) |
330 CMD_A0_CMD(I3C_CCC_ENTDAA) |
331 CMD_A0_DEV_INDEX(dat_idx) |
332 CMD_A0_DEV_COUNT(1) |
333 CMD_A0_ROC | CMD_A0_TOC;
334 xfer->cmd_desc[1] = 0;
335 hci->io->queue_xfer(hci, xfer, 1);
336 if (!wait_for_completion_timeout(&done, HZ) &&
337 hci->io->dequeue_xfer(hci, xfer, 1)) {
338 ret = -ETIME;
339 break;
340 }
341 if (RESP_STATUS(xfer[0].response) == RESP_ERR_NACK &&
342 RESP_DATA_LENGTH(xfer->response) == 1) {
343 ret = 0; /* no more devices to be assigned */
344 break;
345 }
346 if (RESP_STATUS(xfer[0].response) != RESP_SUCCESS) {
347 ret = -EIO;
348 break;
349 }
350
351 i3c_hci_dct_get_val(hci, 0, &pid, &dcr, &bcr);
352 DBG("assigned address %#x to device PID=0x%llx DCR=%#x BCR=%#x",
353 next_addr, pid, dcr, bcr);
354
355 mipi_i3c_hci_dat_v1.free_entry(hci, dat_idx);
356 dat_idx = -1;
357
358 /*
359 * TODO: Extend the subsystem layer to allow for registering
360 * new device and provide BCR/DCR/PID at the same time.
361 */
362 ret = i3c_master_add_i3c_dev_locked(&hci->master, next_addr);
363 if (ret)
364 break;
365 }
366
367 if (dat_idx >= 0)
368 mipi_i3c_hci_dat_v1.free_entry(hci, dat_idx);
369 hci_free_xfer(xfer, 1);
370 return ret;
371 }
372
373 const struct hci_cmd_ops mipi_i3c_hci_cmd_v1 = {
374 .prep_ccc = hci_cmd_v1_prep_ccc,
375 .prep_i3c_xfer = hci_cmd_v1_prep_i3c_xfer,
376 .prep_i2c_xfer = hci_cmd_v1_prep_i2c_xfer,
377 .perform_daa = hci_cmd_v1_daa,
378 };
379