1 /* 2 * cyttsp4_core.c 3 * Cypress TrueTouch(TM) Standard Product V4 Core driver module. 4 * For use with Cypress Txx4xx parts. 5 * Supported parts include: 6 * TMA4XX 7 * TMA1036 8 * 9 * Copyright (C) 2012 Cypress Semiconductor 10 * 11 * This program is free software; you can redistribute it and/or 12 * modify it under the terms of the GNU General Public License 13 * version 2, and only version 2, as published by the 14 * Free Software Foundation. 15 * 16 * This program is distributed in the hope that it will be useful, 17 * but WITHOUT ANY WARRANTY; without even the implied warranty of 18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 19 * GNU General Public License for more details. 20 * 21 * Contact Cypress Semiconductor at www.cypress.com <ttdrivers@cypress.com> 22 * 23 */ 24 25 #include "cyttsp4_core.h" 26 #include <linux/delay.h> 27 #include <linux/gpio.h> 28 #include <linux/input/mt.h> 29 #include <linux/interrupt.h> 30 #include <linux/pm_runtime.h> 31 #include <linux/sched.h> 32 #include <linux/slab.h> 33 34 /* Timeout in ms. */ 35 #define CY_CORE_REQUEST_EXCLUSIVE_TIMEOUT 500 36 #define CY_CORE_SLEEP_REQUEST_EXCLUSIVE_TIMEOUT 5000 37 #define CY_CORE_MODE_CHANGE_TIMEOUT 1000 38 #define CY_CORE_RESET_AND_WAIT_TIMEOUT 500 39 #define CY_CORE_WAKEUP_TIMEOUT 500 40 41 #define CY_CORE_STARTUP_RETRY_COUNT 3 42 43 static const u8 ldr_exit[] = { 44 0xFF, 0x01, 0x3B, 0x00, 0x00, 0x4F, 0x6D, 0x17 45 }; 46 47 static const u8 ldr_err_app[] = { 48 0x01, 0x02, 0x00, 0x00, 0x55, 0xDD, 0x17 49 }; 50 51 static inline size_t merge_bytes(u8 high, u8 low) 52 { 53 return (high << 8) + low; 54 } 55 56 #ifdef VERBOSE_DEBUG 57 static void cyttsp4_pr_buf(struct device *dev, u8 *pr_buf, u8 *dptr, int size, 58 const char *data_name) 59 { 60 int i, k; 61 const char fmt[] = "%02X "; 62 int max; 63 64 if (!size) 65 return; 66 67 max = (CY_MAX_PRBUF_SIZE - 1) - sizeof(CY_PR_TRUNCATED); 68 69 pr_buf[0] = 0; 70 for (i = k = 0; i < size && k < max; i++, k += 3) 71 scnprintf(pr_buf + k, CY_MAX_PRBUF_SIZE, fmt, dptr[i]); 72 73 dev_vdbg(dev, "%s: %s[0..%d]=%s%s\n", __func__, data_name, size - 1, 74 pr_buf, size <= max ? "" : CY_PR_TRUNCATED); 75 } 76 #else 77 #define cyttsp4_pr_buf(dev, pr_buf, dptr, size, data_name) do { } while (0) 78 #endif 79 80 static int cyttsp4_load_status_regs(struct cyttsp4 *cd) 81 { 82 struct cyttsp4_sysinfo *si = &cd->sysinfo; 83 struct device *dev = cd->dev; 84 int rc; 85 86 rc = cyttsp4_adap_read(cd, CY_REG_BASE, si->si_ofs.mode_size, 87 si->xy_mode); 88 if (rc < 0) 89 dev_err(dev, "%s: fail read mode regs r=%d\n", 90 __func__, rc); 91 else 92 cyttsp4_pr_buf(dev, cd->pr_buf, si->xy_mode, 93 si->si_ofs.mode_size, "xy_mode"); 94 95 return rc; 96 } 97 98 static int cyttsp4_handshake(struct cyttsp4 *cd, u8 mode) 99 { 100 u8 cmd = mode ^ CY_HST_TOGGLE; 101 int rc; 102 103 /* 104 * Mode change issued, handshaking now will cause endless mode change 105 * requests, for sync mode modechange will do same with handshake 106 * */ 107 if (mode & CY_HST_MODE_CHANGE) 108 return 0; 109 110 rc = cyttsp4_adap_write(cd, CY_REG_BASE, sizeof(cmd), &cmd); 111 if (rc < 0) 112 dev_err(cd->dev, "%s: bus write fail on handshake (ret=%d)\n", 113 __func__, rc); 114 115 return rc; 116 } 117 118 static int cyttsp4_hw_soft_reset(struct cyttsp4 *cd) 119 { 120 u8 cmd = CY_HST_RESET; 121 int rc = cyttsp4_adap_write(cd, CY_REG_BASE, sizeof(cmd), &cmd); 122 if (rc < 0) { 123 dev_err(cd->dev, "%s: FAILED to execute SOFT reset\n", 124 __func__); 125 return rc; 126 } 127 return 0; 128 } 129 130 static int cyttsp4_hw_hard_reset(struct cyttsp4 *cd) 131 { 132 if (cd->cpdata->xres) { 133 cd->cpdata->xres(cd->cpdata, cd->dev); 134 dev_dbg(cd->dev, "%s: execute HARD reset\n", __func__); 135 return 0; 136 } 137 dev_err(cd->dev, "%s: FAILED to execute HARD reset\n", __func__); 138 return -ENOSYS; 139 } 140 141 static int cyttsp4_hw_reset(struct cyttsp4 *cd) 142 { 143 int rc = cyttsp4_hw_hard_reset(cd); 144 if (rc == -ENOSYS) 145 rc = cyttsp4_hw_soft_reset(cd); 146 return rc; 147 } 148 149 /* 150 * Gets number of bits for a touch filed as parameter, 151 * sets maximum value for field which is used as bit mask 152 * and returns number of bytes required for that field 153 */ 154 static int cyttsp4_bits_2_bytes(unsigned int nbits, size_t *max) 155 { 156 *max = 1UL << nbits; 157 return (nbits + 7) / 8; 158 } 159 160 static int cyttsp4_si_data_offsets(struct cyttsp4 *cd) 161 { 162 struct cyttsp4_sysinfo *si = &cd->sysinfo; 163 int rc = cyttsp4_adap_read(cd, CY_REG_BASE, sizeof(si->si_data), 164 &si->si_data); 165 if (rc < 0) { 166 dev_err(cd->dev, "%s: fail read sysinfo data offsets r=%d\n", 167 __func__, rc); 168 return rc; 169 } 170 171 /* Print sysinfo data offsets */ 172 cyttsp4_pr_buf(cd->dev, cd->pr_buf, (u8 *)&si->si_data, 173 sizeof(si->si_data), "sysinfo_data_offsets"); 174 175 /* convert sysinfo data offset bytes into integers */ 176 177 si->si_ofs.map_sz = merge_bytes(si->si_data.map_szh, 178 si->si_data.map_szl); 179 si->si_ofs.map_sz = merge_bytes(si->si_data.map_szh, 180 si->si_data.map_szl); 181 si->si_ofs.cydata_ofs = merge_bytes(si->si_data.cydata_ofsh, 182 si->si_data.cydata_ofsl); 183 si->si_ofs.test_ofs = merge_bytes(si->si_data.test_ofsh, 184 si->si_data.test_ofsl); 185 si->si_ofs.pcfg_ofs = merge_bytes(si->si_data.pcfg_ofsh, 186 si->si_data.pcfg_ofsl); 187 si->si_ofs.opcfg_ofs = merge_bytes(si->si_data.opcfg_ofsh, 188 si->si_data.opcfg_ofsl); 189 si->si_ofs.ddata_ofs = merge_bytes(si->si_data.ddata_ofsh, 190 si->si_data.ddata_ofsl); 191 si->si_ofs.mdata_ofs = merge_bytes(si->si_data.mdata_ofsh, 192 si->si_data.mdata_ofsl); 193 return rc; 194 } 195 196 static int cyttsp4_si_get_cydata(struct cyttsp4 *cd) 197 { 198 struct cyttsp4_sysinfo *si = &cd->sysinfo; 199 int read_offset; 200 int mfgid_sz, calc_mfgid_sz; 201 void *p; 202 int rc; 203 204 si->si_ofs.cydata_size = si->si_ofs.test_ofs - si->si_ofs.cydata_ofs; 205 dev_dbg(cd->dev, "%s: cydata size: %Zd\n", __func__, 206 si->si_ofs.cydata_size); 207 208 p = krealloc(si->si_ptrs.cydata, si->si_ofs.cydata_size, GFP_KERNEL); 209 if (p == NULL) { 210 dev_err(cd->dev, "%s: fail alloc cydata memory\n", __func__); 211 return -ENOMEM; 212 } 213 si->si_ptrs.cydata = p; 214 215 read_offset = si->si_ofs.cydata_ofs; 216 217 /* Read the CYDA registers up to MFGID field */ 218 rc = cyttsp4_adap_read(cd, read_offset, 219 offsetof(struct cyttsp4_cydata, mfgid_sz) 220 + sizeof(si->si_ptrs.cydata->mfgid_sz), 221 si->si_ptrs.cydata); 222 if (rc < 0) { 223 dev_err(cd->dev, "%s: fail read cydata r=%d\n", 224 __func__, rc); 225 return rc; 226 } 227 228 /* Check MFGID size */ 229 mfgid_sz = si->si_ptrs.cydata->mfgid_sz; 230 calc_mfgid_sz = si->si_ofs.cydata_size - sizeof(struct cyttsp4_cydata); 231 if (mfgid_sz != calc_mfgid_sz) { 232 dev_err(cd->dev, "%s: mismatch in MFGID size, reported:%d calculated:%d\n", 233 __func__, mfgid_sz, calc_mfgid_sz); 234 return -EINVAL; 235 } 236 237 read_offset += offsetof(struct cyttsp4_cydata, mfgid_sz) 238 + sizeof(si->si_ptrs.cydata->mfgid_sz); 239 240 /* Read the CYDA registers for MFGID field */ 241 rc = cyttsp4_adap_read(cd, read_offset, si->si_ptrs.cydata->mfgid_sz, 242 si->si_ptrs.cydata->mfg_id); 243 if (rc < 0) { 244 dev_err(cd->dev, "%s: fail read cydata r=%d\n", 245 __func__, rc); 246 return rc; 247 } 248 249 read_offset += si->si_ptrs.cydata->mfgid_sz; 250 251 /* Read the rest of the CYDA registers */ 252 rc = cyttsp4_adap_read(cd, read_offset, 253 sizeof(struct cyttsp4_cydata) 254 - offsetof(struct cyttsp4_cydata, cyito_idh), 255 &si->si_ptrs.cydata->cyito_idh); 256 if (rc < 0) { 257 dev_err(cd->dev, "%s: fail read cydata r=%d\n", 258 __func__, rc); 259 return rc; 260 } 261 262 cyttsp4_pr_buf(cd->dev, cd->pr_buf, (u8 *)si->si_ptrs.cydata, 263 si->si_ofs.cydata_size, "sysinfo_cydata"); 264 return rc; 265 } 266 267 static int cyttsp4_si_get_test_data(struct cyttsp4 *cd) 268 { 269 struct cyttsp4_sysinfo *si = &cd->sysinfo; 270 void *p; 271 int rc; 272 273 si->si_ofs.test_size = si->si_ofs.pcfg_ofs - si->si_ofs.test_ofs; 274 275 p = krealloc(si->si_ptrs.test, si->si_ofs.test_size, GFP_KERNEL); 276 if (p == NULL) { 277 dev_err(cd->dev, "%s: fail alloc test memory\n", __func__); 278 return -ENOMEM; 279 } 280 si->si_ptrs.test = p; 281 282 rc = cyttsp4_adap_read(cd, si->si_ofs.test_ofs, si->si_ofs.test_size, 283 si->si_ptrs.test); 284 if (rc < 0) { 285 dev_err(cd->dev, "%s: fail read test data r=%d\n", 286 __func__, rc); 287 return rc; 288 } 289 290 cyttsp4_pr_buf(cd->dev, cd->pr_buf, 291 (u8 *)si->si_ptrs.test, si->si_ofs.test_size, 292 "sysinfo_test_data"); 293 if (si->si_ptrs.test->post_codel & 294 CY_POST_CODEL_WDG_RST) 295 dev_info(cd->dev, "%s: %s codel=%02X\n", 296 __func__, "Reset was a WATCHDOG RESET", 297 si->si_ptrs.test->post_codel); 298 299 if (!(si->si_ptrs.test->post_codel & 300 CY_POST_CODEL_CFG_DATA_CRC_FAIL)) 301 dev_info(cd->dev, "%s: %s codel=%02X\n", __func__, 302 "Config Data CRC FAIL", 303 si->si_ptrs.test->post_codel); 304 305 if (!(si->si_ptrs.test->post_codel & 306 CY_POST_CODEL_PANEL_TEST_FAIL)) 307 dev_info(cd->dev, "%s: %s codel=%02X\n", 308 __func__, "PANEL TEST FAIL", 309 si->si_ptrs.test->post_codel); 310 311 dev_info(cd->dev, "%s: SCANNING is %s codel=%02X\n", 312 __func__, si->si_ptrs.test->post_codel & 0x08 ? 313 "ENABLED" : "DISABLED", 314 si->si_ptrs.test->post_codel); 315 return rc; 316 } 317 318 static int cyttsp4_si_get_pcfg_data(struct cyttsp4 *cd) 319 { 320 struct cyttsp4_sysinfo *si = &cd->sysinfo; 321 void *p; 322 int rc; 323 324 si->si_ofs.pcfg_size = si->si_ofs.opcfg_ofs - si->si_ofs.pcfg_ofs; 325 326 p = krealloc(si->si_ptrs.pcfg, si->si_ofs.pcfg_size, GFP_KERNEL); 327 if (p == NULL) { 328 rc = -ENOMEM; 329 dev_err(cd->dev, "%s: fail alloc pcfg memory r=%d\n", 330 __func__, rc); 331 return rc; 332 } 333 si->si_ptrs.pcfg = p; 334 335 rc = cyttsp4_adap_read(cd, si->si_ofs.pcfg_ofs, si->si_ofs.pcfg_size, 336 si->si_ptrs.pcfg); 337 if (rc < 0) { 338 dev_err(cd->dev, "%s: fail read pcfg data r=%d\n", 339 __func__, rc); 340 return rc; 341 } 342 343 si->si_ofs.max_x = merge_bytes((si->si_ptrs.pcfg->res_xh 344 & CY_PCFG_RESOLUTION_X_MASK), si->si_ptrs.pcfg->res_xl); 345 si->si_ofs.x_origin = !!(si->si_ptrs.pcfg->res_xh 346 & CY_PCFG_ORIGIN_X_MASK); 347 si->si_ofs.max_y = merge_bytes((si->si_ptrs.pcfg->res_yh 348 & CY_PCFG_RESOLUTION_Y_MASK), si->si_ptrs.pcfg->res_yl); 349 si->si_ofs.y_origin = !!(si->si_ptrs.pcfg->res_yh 350 & CY_PCFG_ORIGIN_Y_MASK); 351 si->si_ofs.max_p = merge_bytes(si->si_ptrs.pcfg->max_zh, 352 si->si_ptrs.pcfg->max_zl); 353 354 cyttsp4_pr_buf(cd->dev, cd->pr_buf, 355 (u8 *)si->si_ptrs.pcfg, 356 si->si_ofs.pcfg_size, "sysinfo_pcfg_data"); 357 return rc; 358 } 359 360 static int cyttsp4_si_get_opcfg_data(struct cyttsp4 *cd) 361 { 362 struct cyttsp4_sysinfo *si = &cd->sysinfo; 363 struct cyttsp4_tch_abs_params *tch; 364 struct cyttsp4_tch_rec_params *tch_old, *tch_new; 365 enum cyttsp4_tch_abs abs; 366 int i; 367 void *p; 368 int rc; 369 370 si->si_ofs.opcfg_size = si->si_ofs.ddata_ofs - si->si_ofs.opcfg_ofs; 371 372 p = krealloc(si->si_ptrs.opcfg, si->si_ofs.opcfg_size, GFP_KERNEL); 373 if (p == NULL) { 374 dev_err(cd->dev, "%s: fail alloc opcfg memory\n", __func__); 375 rc = -ENOMEM; 376 goto cyttsp4_si_get_opcfg_data_exit; 377 } 378 si->si_ptrs.opcfg = p; 379 380 rc = cyttsp4_adap_read(cd, si->si_ofs.opcfg_ofs, si->si_ofs.opcfg_size, 381 si->si_ptrs.opcfg); 382 if (rc < 0) { 383 dev_err(cd->dev, "%s: fail read opcfg data r=%d\n", 384 __func__, rc); 385 goto cyttsp4_si_get_opcfg_data_exit; 386 } 387 si->si_ofs.cmd_ofs = si->si_ptrs.opcfg->cmd_ofs; 388 si->si_ofs.rep_ofs = si->si_ptrs.opcfg->rep_ofs; 389 si->si_ofs.rep_sz = (si->si_ptrs.opcfg->rep_szh * 256) + 390 si->si_ptrs.opcfg->rep_szl; 391 si->si_ofs.num_btns = si->si_ptrs.opcfg->num_btns; 392 si->si_ofs.num_btn_regs = (si->si_ofs.num_btns + 393 CY_NUM_BTN_PER_REG - 1) / CY_NUM_BTN_PER_REG; 394 si->si_ofs.tt_stat_ofs = si->si_ptrs.opcfg->tt_stat_ofs; 395 si->si_ofs.obj_cfg0 = si->si_ptrs.opcfg->obj_cfg0; 396 si->si_ofs.max_tchs = si->si_ptrs.opcfg->max_tchs & 397 CY_BYTE_OFS_MASK; 398 si->si_ofs.tch_rec_size = si->si_ptrs.opcfg->tch_rec_size & 399 CY_BYTE_OFS_MASK; 400 401 /* Get the old touch fields */ 402 for (abs = CY_TCH_X; abs < CY_NUM_TCH_FIELDS; abs++) { 403 tch = &si->si_ofs.tch_abs[abs]; 404 tch_old = &si->si_ptrs.opcfg->tch_rec_old[abs]; 405 406 tch->ofs = tch_old->loc & CY_BYTE_OFS_MASK; 407 tch->size = cyttsp4_bits_2_bytes(tch_old->size, 408 &tch->max); 409 tch->bofs = (tch_old->loc & CY_BOFS_MASK) >> CY_BOFS_SHIFT; 410 } 411 412 /* button fields */ 413 si->si_ofs.btn_rec_size = si->si_ptrs.opcfg->btn_rec_size; 414 si->si_ofs.btn_diff_ofs = si->si_ptrs.opcfg->btn_diff_ofs; 415 si->si_ofs.btn_diff_size = si->si_ptrs.opcfg->btn_diff_size; 416 417 if (si->si_ofs.tch_rec_size > CY_TMA1036_TCH_REC_SIZE) { 418 /* Get the extended touch fields */ 419 for (i = 0; i < CY_NUM_EXT_TCH_FIELDS; abs++, i++) { 420 tch = &si->si_ofs.tch_abs[abs]; 421 tch_new = &si->si_ptrs.opcfg->tch_rec_new[i]; 422 423 tch->ofs = tch_new->loc & CY_BYTE_OFS_MASK; 424 tch->size = cyttsp4_bits_2_bytes(tch_new->size, 425 &tch->max); 426 tch->bofs = (tch_new->loc & CY_BOFS_MASK) >> CY_BOFS_SHIFT; 427 } 428 } 429 430 for (abs = 0; abs < CY_TCH_NUM_ABS; abs++) { 431 dev_dbg(cd->dev, "%s: tch_rec_%s\n", __func__, 432 cyttsp4_tch_abs_string[abs]); 433 dev_dbg(cd->dev, "%s: ofs =%2Zd\n", __func__, 434 si->si_ofs.tch_abs[abs].ofs); 435 dev_dbg(cd->dev, "%s: siz =%2Zd\n", __func__, 436 si->si_ofs.tch_abs[abs].size); 437 dev_dbg(cd->dev, "%s: max =%2Zd\n", __func__, 438 si->si_ofs.tch_abs[abs].max); 439 dev_dbg(cd->dev, "%s: bofs=%2Zd\n", __func__, 440 si->si_ofs.tch_abs[abs].bofs); 441 } 442 443 si->si_ofs.mode_size = si->si_ofs.tt_stat_ofs + 1; 444 si->si_ofs.data_size = si->si_ofs.max_tchs * 445 si->si_ptrs.opcfg->tch_rec_size; 446 447 cyttsp4_pr_buf(cd->dev, cd->pr_buf, (u8 *)si->si_ptrs.opcfg, 448 si->si_ofs.opcfg_size, "sysinfo_opcfg_data"); 449 450 cyttsp4_si_get_opcfg_data_exit: 451 return rc; 452 } 453 454 static int cyttsp4_si_get_ddata(struct cyttsp4 *cd) 455 { 456 struct cyttsp4_sysinfo *si = &cd->sysinfo; 457 void *p; 458 int rc; 459 460 si->si_ofs.ddata_size = si->si_ofs.mdata_ofs - si->si_ofs.ddata_ofs; 461 462 p = krealloc(si->si_ptrs.ddata, si->si_ofs.ddata_size, GFP_KERNEL); 463 if (p == NULL) { 464 dev_err(cd->dev, "%s: fail alloc ddata memory\n", __func__); 465 return -ENOMEM; 466 } 467 si->si_ptrs.ddata = p; 468 469 rc = cyttsp4_adap_read(cd, si->si_ofs.ddata_ofs, si->si_ofs.ddata_size, 470 si->si_ptrs.ddata); 471 if (rc < 0) 472 dev_err(cd->dev, "%s: fail read ddata data r=%d\n", 473 __func__, rc); 474 else 475 cyttsp4_pr_buf(cd->dev, cd->pr_buf, 476 (u8 *)si->si_ptrs.ddata, 477 si->si_ofs.ddata_size, "sysinfo_ddata"); 478 return rc; 479 } 480 481 static int cyttsp4_si_get_mdata(struct cyttsp4 *cd) 482 { 483 struct cyttsp4_sysinfo *si = &cd->sysinfo; 484 void *p; 485 int rc; 486 487 si->si_ofs.mdata_size = si->si_ofs.map_sz - si->si_ofs.mdata_ofs; 488 489 p = krealloc(si->si_ptrs.mdata, si->si_ofs.mdata_size, GFP_KERNEL); 490 if (p == NULL) { 491 dev_err(cd->dev, "%s: fail alloc mdata memory\n", __func__); 492 return -ENOMEM; 493 } 494 si->si_ptrs.mdata = p; 495 496 rc = cyttsp4_adap_read(cd, si->si_ofs.mdata_ofs, si->si_ofs.mdata_size, 497 si->si_ptrs.mdata); 498 if (rc < 0) 499 dev_err(cd->dev, "%s: fail read mdata data r=%d\n", 500 __func__, rc); 501 else 502 cyttsp4_pr_buf(cd->dev, cd->pr_buf, 503 (u8 *)si->si_ptrs.mdata, 504 si->si_ofs.mdata_size, "sysinfo_mdata"); 505 return rc; 506 } 507 508 static int cyttsp4_si_get_btn_data(struct cyttsp4 *cd) 509 { 510 struct cyttsp4_sysinfo *si = &cd->sysinfo; 511 int btn; 512 int num_defined_keys; 513 u16 *key_table; 514 void *p; 515 int rc = 0; 516 517 if (si->si_ofs.num_btns) { 518 si->si_ofs.btn_keys_size = si->si_ofs.num_btns * 519 sizeof(struct cyttsp4_btn); 520 521 p = krealloc(si->btn, si->si_ofs.btn_keys_size, 522 GFP_KERNEL|__GFP_ZERO); 523 if (p == NULL) { 524 dev_err(cd->dev, "%s: %s\n", __func__, 525 "fail alloc btn_keys memory"); 526 return -ENOMEM; 527 } 528 si->btn = p; 529 530 if (cd->cpdata->sett[CY_IC_GRPNUM_BTN_KEYS] == NULL) 531 num_defined_keys = 0; 532 else if (cd->cpdata->sett[CY_IC_GRPNUM_BTN_KEYS]->data == NULL) 533 num_defined_keys = 0; 534 else 535 num_defined_keys = cd->cpdata->sett 536 [CY_IC_GRPNUM_BTN_KEYS]->size; 537 538 for (btn = 0; btn < si->si_ofs.num_btns && 539 btn < num_defined_keys; btn++) { 540 key_table = (u16 *)cd->cpdata->sett 541 [CY_IC_GRPNUM_BTN_KEYS]->data; 542 si->btn[btn].key_code = key_table[btn]; 543 si->btn[btn].state = CY_BTN_RELEASED; 544 si->btn[btn].enabled = true; 545 } 546 for (; btn < si->si_ofs.num_btns; btn++) { 547 si->btn[btn].key_code = KEY_RESERVED; 548 si->btn[btn].state = CY_BTN_RELEASED; 549 si->btn[btn].enabled = true; 550 } 551 552 return rc; 553 } 554 555 si->si_ofs.btn_keys_size = 0; 556 kfree(si->btn); 557 si->btn = NULL; 558 return rc; 559 } 560 561 static int cyttsp4_si_get_op_data_ptrs(struct cyttsp4 *cd) 562 { 563 struct cyttsp4_sysinfo *si = &cd->sysinfo; 564 void *p; 565 566 p = krealloc(si->xy_mode, si->si_ofs.mode_size, GFP_KERNEL|__GFP_ZERO); 567 if (p == NULL) 568 return -ENOMEM; 569 si->xy_mode = p; 570 571 p = krealloc(si->xy_data, si->si_ofs.data_size, GFP_KERNEL|__GFP_ZERO); 572 if (p == NULL) 573 return -ENOMEM; 574 si->xy_data = p; 575 576 p = krealloc(si->btn_rec_data, 577 si->si_ofs.btn_rec_size * si->si_ofs.num_btns, 578 GFP_KERNEL|__GFP_ZERO); 579 if (p == NULL) 580 return -ENOMEM; 581 si->btn_rec_data = p; 582 583 return 0; 584 } 585 586 static void cyttsp4_si_put_log_data(struct cyttsp4 *cd) 587 { 588 struct cyttsp4_sysinfo *si = &cd->sysinfo; 589 dev_dbg(cd->dev, "%s: cydata_ofs =%4Zd siz=%4Zd\n", __func__, 590 si->si_ofs.cydata_ofs, si->si_ofs.cydata_size); 591 dev_dbg(cd->dev, "%s: test_ofs =%4Zd siz=%4Zd\n", __func__, 592 si->si_ofs.test_ofs, si->si_ofs.test_size); 593 dev_dbg(cd->dev, "%s: pcfg_ofs =%4Zd siz=%4Zd\n", __func__, 594 si->si_ofs.pcfg_ofs, si->si_ofs.pcfg_size); 595 dev_dbg(cd->dev, "%s: opcfg_ofs =%4Zd siz=%4Zd\n", __func__, 596 si->si_ofs.opcfg_ofs, si->si_ofs.opcfg_size); 597 dev_dbg(cd->dev, "%s: ddata_ofs =%4Zd siz=%4Zd\n", __func__, 598 si->si_ofs.ddata_ofs, si->si_ofs.ddata_size); 599 dev_dbg(cd->dev, "%s: mdata_ofs =%4Zd siz=%4Zd\n", __func__, 600 si->si_ofs.mdata_ofs, si->si_ofs.mdata_size); 601 602 dev_dbg(cd->dev, "%s: cmd_ofs =%4Zd\n", __func__, 603 si->si_ofs.cmd_ofs); 604 dev_dbg(cd->dev, "%s: rep_ofs =%4Zd\n", __func__, 605 si->si_ofs.rep_ofs); 606 dev_dbg(cd->dev, "%s: rep_sz =%4Zd\n", __func__, 607 si->si_ofs.rep_sz); 608 dev_dbg(cd->dev, "%s: num_btns =%4Zd\n", __func__, 609 si->si_ofs.num_btns); 610 dev_dbg(cd->dev, "%s: num_btn_regs =%4Zd\n", __func__, 611 si->si_ofs.num_btn_regs); 612 dev_dbg(cd->dev, "%s: tt_stat_ofs =%4Zd\n", __func__, 613 si->si_ofs.tt_stat_ofs); 614 dev_dbg(cd->dev, "%s: tch_rec_size =%4Zd\n", __func__, 615 si->si_ofs.tch_rec_size); 616 dev_dbg(cd->dev, "%s: max_tchs =%4Zd\n", __func__, 617 si->si_ofs.max_tchs); 618 dev_dbg(cd->dev, "%s: mode_size =%4Zd\n", __func__, 619 si->si_ofs.mode_size); 620 dev_dbg(cd->dev, "%s: data_size =%4Zd\n", __func__, 621 si->si_ofs.data_size); 622 dev_dbg(cd->dev, "%s: map_sz =%4Zd\n", __func__, 623 si->si_ofs.map_sz); 624 625 dev_dbg(cd->dev, "%s: btn_rec_size =%2Zd\n", __func__, 626 si->si_ofs.btn_rec_size); 627 dev_dbg(cd->dev, "%s: btn_diff_ofs =%2Zd\n", __func__, 628 si->si_ofs.btn_diff_ofs); 629 dev_dbg(cd->dev, "%s: btn_diff_size =%2Zd\n", __func__, 630 si->si_ofs.btn_diff_size); 631 632 dev_dbg(cd->dev, "%s: max_x = 0x%04ZX (%Zd)\n", __func__, 633 si->si_ofs.max_x, si->si_ofs.max_x); 634 dev_dbg(cd->dev, "%s: x_origin = %Zd (%s)\n", __func__, 635 si->si_ofs.x_origin, 636 si->si_ofs.x_origin == CY_NORMAL_ORIGIN ? 637 "left corner" : "right corner"); 638 dev_dbg(cd->dev, "%s: max_y = 0x%04ZX (%Zd)\n", __func__, 639 si->si_ofs.max_y, si->si_ofs.max_y); 640 dev_dbg(cd->dev, "%s: y_origin = %Zd (%s)\n", __func__, 641 si->si_ofs.y_origin, 642 si->si_ofs.y_origin == CY_NORMAL_ORIGIN ? 643 "upper corner" : "lower corner"); 644 dev_dbg(cd->dev, "%s: max_p = 0x%04ZX (%Zd)\n", __func__, 645 si->si_ofs.max_p, si->si_ofs.max_p); 646 647 dev_dbg(cd->dev, "%s: xy_mode=%p xy_data=%p\n", __func__, 648 si->xy_mode, si->xy_data); 649 } 650 651 static int cyttsp4_get_sysinfo_regs(struct cyttsp4 *cd) 652 { 653 struct cyttsp4_sysinfo *si = &cd->sysinfo; 654 int rc; 655 656 rc = cyttsp4_si_data_offsets(cd); 657 if (rc < 0) 658 return rc; 659 660 rc = cyttsp4_si_get_cydata(cd); 661 if (rc < 0) 662 return rc; 663 664 rc = cyttsp4_si_get_test_data(cd); 665 if (rc < 0) 666 return rc; 667 668 rc = cyttsp4_si_get_pcfg_data(cd); 669 if (rc < 0) 670 return rc; 671 672 rc = cyttsp4_si_get_opcfg_data(cd); 673 if (rc < 0) 674 return rc; 675 676 rc = cyttsp4_si_get_ddata(cd); 677 if (rc < 0) 678 return rc; 679 680 rc = cyttsp4_si_get_mdata(cd); 681 if (rc < 0) 682 return rc; 683 684 rc = cyttsp4_si_get_btn_data(cd); 685 if (rc < 0) 686 return rc; 687 688 rc = cyttsp4_si_get_op_data_ptrs(cd); 689 if (rc < 0) { 690 dev_err(cd->dev, "%s: failed to get_op_data\n", 691 __func__); 692 return rc; 693 } 694 695 cyttsp4_si_put_log_data(cd); 696 697 /* provide flow control handshake */ 698 rc = cyttsp4_handshake(cd, si->si_data.hst_mode); 699 if (rc < 0) 700 dev_err(cd->dev, "%s: handshake fail on sysinfo reg\n", 701 __func__); 702 703 si->ready = true; 704 return rc; 705 } 706 707 static void cyttsp4_queue_startup_(struct cyttsp4 *cd) 708 { 709 if (cd->startup_state == STARTUP_NONE) { 710 cd->startup_state = STARTUP_QUEUED; 711 schedule_work(&cd->startup_work); 712 dev_dbg(cd->dev, "%s: cyttsp4_startup queued\n", __func__); 713 } else { 714 dev_dbg(cd->dev, "%s: startup_state = %d\n", __func__, 715 cd->startup_state); 716 } 717 } 718 719 static void cyttsp4_report_slot_liftoff(struct cyttsp4_mt_data *md, 720 int max_slots) 721 { 722 int t; 723 724 if (md->num_prv_tch == 0) 725 return; 726 727 for (t = 0; t < max_slots; t++) { 728 input_mt_slot(md->input, t); 729 input_mt_report_slot_state(md->input, 730 MT_TOOL_FINGER, false); 731 } 732 } 733 734 static void cyttsp4_lift_all(struct cyttsp4_mt_data *md) 735 { 736 if (!md->si) 737 return; 738 739 if (md->num_prv_tch != 0) { 740 cyttsp4_report_slot_liftoff(md, 741 md->si->si_ofs.tch_abs[CY_TCH_T].max); 742 input_sync(md->input); 743 md->num_prv_tch = 0; 744 } 745 } 746 747 static void cyttsp4_get_touch_axis(struct cyttsp4_mt_data *md, 748 int *axis, int size, int max, u8 *xy_data, int bofs) 749 { 750 int nbyte; 751 int next; 752 753 for (nbyte = 0, *axis = 0, next = 0; nbyte < size; nbyte++) { 754 dev_vdbg(&md->input->dev, 755 "%s: *axis=%02X(%d) size=%d max=%08X xy_data=%p" 756 " xy_data[%d]=%02X(%d) bofs=%d\n", 757 __func__, *axis, *axis, size, max, xy_data, next, 758 xy_data[next], xy_data[next], bofs); 759 *axis = (*axis * 256) + (xy_data[next] >> bofs); 760 next++; 761 } 762 763 *axis &= max - 1; 764 765 dev_vdbg(&md->input->dev, 766 "%s: *axis=%02X(%d) size=%d max=%08X xy_data=%p" 767 " xy_data[%d]=%02X(%d)\n", 768 __func__, *axis, *axis, size, max, xy_data, next, 769 xy_data[next], xy_data[next]); 770 } 771 772 static void cyttsp4_get_touch(struct cyttsp4_mt_data *md, 773 struct cyttsp4_touch *touch, u8 *xy_data) 774 { 775 struct device *dev = &md->input->dev; 776 struct cyttsp4_sysinfo *si = md->si; 777 enum cyttsp4_tch_abs abs; 778 bool flipped; 779 780 for (abs = CY_TCH_X; abs < CY_TCH_NUM_ABS; abs++) { 781 cyttsp4_get_touch_axis(md, &touch->abs[abs], 782 si->si_ofs.tch_abs[abs].size, 783 si->si_ofs.tch_abs[abs].max, 784 xy_data + si->si_ofs.tch_abs[abs].ofs, 785 si->si_ofs.tch_abs[abs].bofs); 786 dev_vdbg(dev, "%s: get %s=%04X(%d)\n", __func__, 787 cyttsp4_tch_abs_string[abs], 788 touch->abs[abs], touch->abs[abs]); 789 } 790 791 if (md->pdata->flags & CY_FLAG_FLIP) { 792 swap(touch->abs[CY_TCH_X], touch->abs[CY_TCH_Y]); 793 flipped = true; 794 } else 795 flipped = false; 796 797 if (md->pdata->flags & CY_FLAG_INV_X) { 798 if (flipped) 799 touch->abs[CY_TCH_X] = md->si->si_ofs.max_y - 800 touch->abs[CY_TCH_X]; 801 else 802 touch->abs[CY_TCH_X] = md->si->si_ofs.max_x - 803 touch->abs[CY_TCH_X]; 804 } 805 if (md->pdata->flags & CY_FLAG_INV_Y) { 806 if (flipped) 807 touch->abs[CY_TCH_Y] = md->si->si_ofs.max_x - 808 touch->abs[CY_TCH_Y]; 809 else 810 touch->abs[CY_TCH_Y] = md->si->si_ofs.max_y - 811 touch->abs[CY_TCH_Y]; 812 } 813 814 dev_vdbg(dev, "%s: flip=%s inv-x=%s inv-y=%s x=%04X(%d) y=%04X(%d)\n", 815 __func__, flipped ? "true" : "false", 816 md->pdata->flags & CY_FLAG_INV_X ? "true" : "false", 817 md->pdata->flags & CY_FLAG_INV_Y ? "true" : "false", 818 touch->abs[CY_TCH_X], touch->abs[CY_TCH_X], 819 touch->abs[CY_TCH_Y], touch->abs[CY_TCH_Y]); 820 } 821 822 static void cyttsp4_final_sync(struct input_dev *input, int max_slots, int *ids) 823 { 824 int t; 825 826 for (t = 0; t < max_slots; t++) { 827 if (ids[t]) 828 continue; 829 input_mt_slot(input, t); 830 input_mt_report_slot_state(input, MT_TOOL_FINGER, false); 831 } 832 833 input_sync(input); 834 } 835 836 static void cyttsp4_get_mt_touches(struct cyttsp4_mt_data *md, int num_cur_tch) 837 { 838 struct device *dev = &md->input->dev; 839 struct cyttsp4_sysinfo *si = md->si; 840 struct cyttsp4_touch tch; 841 int sig; 842 int i, j, t = 0; 843 int ids[max(CY_TMA1036_MAX_TCH, CY_TMA4XX_MAX_TCH)]; 844 845 memset(ids, 0, si->si_ofs.tch_abs[CY_TCH_T].max * sizeof(int)); 846 for (i = 0; i < num_cur_tch; i++) { 847 cyttsp4_get_touch(md, &tch, si->xy_data + 848 (i * si->si_ofs.tch_rec_size)); 849 if ((tch.abs[CY_TCH_T] < md->pdata->frmwrk->abs 850 [(CY_ABS_ID_OST * CY_NUM_ABS_SET) + CY_MIN_OST]) || 851 (tch.abs[CY_TCH_T] > md->pdata->frmwrk->abs 852 [(CY_ABS_ID_OST * CY_NUM_ABS_SET) + CY_MAX_OST])) { 853 dev_err(dev, "%s: tch=%d -> bad trk_id=%d max_id=%d\n", 854 __func__, i, tch.abs[CY_TCH_T], 855 md->pdata->frmwrk->abs[(CY_ABS_ID_OST * 856 CY_NUM_ABS_SET) + CY_MAX_OST]); 857 continue; 858 } 859 860 /* use 0 based track id's */ 861 sig = md->pdata->frmwrk->abs 862 [(CY_ABS_ID_OST * CY_NUM_ABS_SET) + 0]; 863 if (sig != CY_IGNORE_VALUE) { 864 t = tch.abs[CY_TCH_T] - md->pdata->frmwrk->abs 865 [(CY_ABS_ID_OST * CY_NUM_ABS_SET) + CY_MIN_OST]; 866 if (tch.abs[CY_TCH_E] == CY_EV_LIFTOFF) { 867 dev_dbg(dev, "%s: t=%d e=%d lift-off\n", 868 __func__, t, tch.abs[CY_TCH_E]); 869 goto cyttsp4_get_mt_touches_pr_tch; 870 } 871 input_mt_slot(md->input, t); 872 input_mt_report_slot_state(md->input, MT_TOOL_FINGER, 873 true); 874 ids[t] = true; 875 } 876 877 /* all devices: position and pressure fields */ 878 for (j = 0; j <= CY_ABS_W_OST; j++) { 879 sig = md->pdata->frmwrk->abs[((CY_ABS_X_OST + j) * 880 CY_NUM_ABS_SET) + 0]; 881 if (sig != CY_IGNORE_VALUE) 882 input_report_abs(md->input, sig, 883 tch.abs[CY_TCH_X + j]); 884 } 885 if (si->si_ofs.tch_rec_size > CY_TMA1036_TCH_REC_SIZE) { 886 /* 887 * TMA400 size and orientation fields: 888 * if pressure is non-zero and major touch 889 * signal is zero, then set major and minor touch 890 * signals to minimum non-zero value 891 */ 892 if (tch.abs[CY_TCH_P] > 0 && tch.abs[CY_TCH_MAJ] == 0) 893 tch.abs[CY_TCH_MAJ] = tch.abs[CY_TCH_MIN] = 1; 894 895 /* Get the extended touch fields */ 896 for (j = 0; j < CY_NUM_EXT_TCH_FIELDS; j++) { 897 sig = md->pdata->frmwrk->abs 898 [((CY_ABS_MAJ_OST + j) * 899 CY_NUM_ABS_SET) + 0]; 900 if (sig != CY_IGNORE_VALUE) 901 input_report_abs(md->input, sig, 902 tch.abs[CY_TCH_MAJ + j]); 903 } 904 } 905 906 cyttsp4_get_mt_touches_pr_tch: 907 if (si->si_ofs.tch_rec_size > CY_TMA1036_TCH_REC_SIZE) 908 dev_dbg(dev, 909 "%s: t=%d x=%d y=%d z=%d M=%d m=%d o=%d e=%d\n", 910 __func__, t, 911 tch.abs[CY_TCH_X], 912 tch.abs[CY_TCH_Y], 913 tch.abs[CY_TCH_P], 914 tch.abs[CY_TCH_MAJ], 915 tch.abs[CY_TCH_MIN], 916 tch.abs[CY_TCH_OR], 917 tch.abs[CY_TCH_E]); 918 else 919 dev_dbg(dev, 920 "%s: t=%d x=%d y=%d z=%d e=%d\n", __func__, 921 t, 922 tch.abs[CY_TCH_X], 923 tch.abs[CY_TCH_Y], 924 tch.abs[CY_TCH_P], 925 tch.abs[CY_TCH_E]); 926 } 927 928 cyttsp4_final_sync(md->input, si->si_ofs.tch_abs[CY_TCH_T].max, ids); 929 930 md->num_prv_tch = num_cur_tch; 931 932 return; 933 } 934 935 /* read xy_data for all current touches */ 936 static int cyttsp4_xy_worker(struct cyttsp4 *cd) 937 { 938 struct cyttsp4_mt_data *md = &cd->md; 939 struct device *dev = &md->input->dev; 940 struct cyttsp4_sysinfo *si = md->si; 941 u8 num_cur_tch; 942 u8 hst_mode; 943 u8 rep_len; 944 u8 rep_stat; 945 u8 tt_stat; 946 int rc = 0; 947 948 /* 949 * Get event data from cyttsp4 device. 950 * The event data includes all data 951 * for all active touches. 952 * Event data also includes button data 953 */ 954 /* 955 * Use 2 reads: 956 * 1st read to get mode + button bytes + touch count (core) 957 * 2nd read (optional) to get touch 1 - touch n data 958 */ 959 hst_mode = si->xy_mode[CY_REG_BASE]; 960 rep_len = si->xy_mode[si->si_ofs.rep_ofs]; 961 rep_stat = si->xy_mode[si->si_ofs.rep_ofs + 1]; 962 tt_stat = si->xy_mode[si->si_ofs.tt_stat_ofs]; 963 dev_vdbg(dev, "%s: %s%02X %s%d %s%02X %s%02X\n", __func__, 964 "hst_mode=", hst_mode, "rep_len=", rep_len, 965 "rep_stat=", rep_stat, "tt_stat=", tt_stat); 966 967 num_cur_tch = GET_NUM_TOUCHES(tt_stat); 968 dev_vdbg(dev, "%s: num_cur_tch=%d\n", __func__, num_cur_tch); 969 970 if (rep_len == 0 && num_cur_tch > 0) { 971 dev_err(dev, "%s: report length error rep_len=%d num_tch=%d\n", 972 __func__, rep_len, num_cur_tch); 973 goto cyttsp4_xy_worker_exit; 974 } 975 976 /* read touches */ 977 if (num_cur_tch > 0) { 978 rc = cyttsp4_adap_read(cd, si->si_ofs.tt_stat_ofs + 1, 979 num_cur_tch * si->si_ofs.tch_rec_size, 980 si->xy_data); 981 if (rc < 0) { 982 dev_err(dev, "%s: read fail on touch regs r=%d\n", 983 __func__, rc); 984 goto cyttsp4_xy_worker_exit; 985 } 986 } 987 988 /* print xy data */ 989 cyttsp4_pr_buf(dev, cd->pr_buf, si->xy_data, num_cur_tch * 990 si->si_ofs.tch_rec_size, "xy_data"); 991 992 /* check any error conditions */ 993 if (IS_BAD_PKT(rep_stat)) { 994 dev_dbg(dev, "%s: Invalid buffer detected\n", __func__); 995 rc = 0; 996 goto cyttsp4_xy_worker_exit; 997 } 998 999 if (IS_LARGE_AREA(tt_stat)) 1000 dev_dbg(dev, "%s: Large area detected\n", __func__); 1001 1002 if (num_cur_tch > si->si_ofs.max_tchs) { 1003 dev_err(dev, "%s: too many tch; set to max tch (n=%d c=%Zd)\n", 1004 __func__, num_cur_tch, si->si_ofs.max_tchs); 1005 num_cur_tch = si->si_ofs.max_tchs; 1006 } 1007 1008 /* extract xy_data for all currently reported touches */ 1009 dev_vdbg(dev, "%s: extract data num_cur_tch=%d\n", __func__, 1010 num_cur_tch); 1011 if (num_cur_tch) 1012 cyttsp4_get_mt_touches(md, num_cur_tch); 1013 else 1014 cyttsp4_lift_all(md); 1015 1016 rc = 0; 1017 1018 cyttsp4_xy_worker_exit: 1019 return rc; 1020 } 1021 1022 static int cyttsp4_mt_attention(struct cyttsp4 *cd) 1023 { 1024 struct device *dev = cd->dev; 1025 struct cyttsp4_mt_data *md = &cd->md; 1026 int rc = 0; 1027 1028 if (!md->si) 1029 return 0; 1030 1031 mutex_lock(&md->report_lock); 1032 if (!md->is_suspended) { 1033 /* core handles handshake */ 1034 rc = cyttsp4_xy_worker(cd); 1035 } else { 1036 dev_vdbg(dev, "%s: Ignoring report while suspended\n", 1037 __func__); 1038 } 1039 mutex_unlock(&md->report_lock); 1040 if (rc < 0) 1041 dev_err(dev, "%s: xy_worker error r=%d\n", __func__, rc); 1042 1043 return rc; 1044 } 1045 1046 static irqreturn_t cyttsp4_irq(int irq, void *handle) 1047 { 1048 struct cyttsp4 *cd = handle; 1049 struct device *dev = cd->dev; 1050 enum cyttsp4_mode cur_mode; 1051 u8 cmd_ofs = cd->sysinfo.si_ofs.cmd_ofs; 1052 u8 mode[3]; 1053 int rc; 1054 1055 /* 1056 * Check whether this IRQ should be ignored (external) 1057 * This should be the very first thing to check since 1058 * ignore_irq may be set for a very short period of time 1059 */ 1060 if (atomic_read(&cd->ignore_irq)) { 1061 dev_vdbg(dev, "%s: Ignoring IRQ\n", __func__); 1062 return IRQ_HANDLED; 1063 } 1064 1065 dev_dbg(dev, "%s int:0x%x\n", __func__, cd->int_status); 1066 1067 mutex_lock(&cd->system_lock); 1068 1069 /* Just to debug */ 1070 if (cd->sleep_state == SS_SLEEP_ON || cd->sleep_state == SS_SLEEPING) 1071 dev_vdbg(dev, "%s: Received IRQ while in sleep\n", __func__); 1072 1073 rc = cyttsp4_adap_read(cd, CY_REG_BASE, sizeof(mode), mode); 1074 if (rc) { 1075 dev_err(cd->dev, "%s: Fail read adapter r=%d\n", __func__, rc); 1076 goto cyttsp4_irq_exit; 1077 } 1078 dev_vdbg(dev, "%s mode[0-2]:0x%X 0x%X 0x%X\n", __func__, 1079 mode[0], mode[1], mode[2]); 1080 1081 if (IS_BOOTLOADER(mode[0], mode[1])) { 1082 cur_mode = CY_MODE_BOOTLOADER; 1083 dev_vdbg(dev, "%s: bl running\n", __func__); 1084 if (cd->mode == CY_MODE_BOOTLOADER) { 1085 /* Signal bootloader heartbeat heard */ 1086 wake_up(&cd->wait_q); 1087 goto cyttsp4_irq_exit; 1088 } 1089 1090 /* switch to bootloader */ 1091 dev_dbg(dev, "%s: restart switch to bl m=%d -> m=%d\n", 1092 __func__, cd->mode, cur_mode); 1093 1094 /* catch operation->bl glitch */ 1095 if (cd->mode != CY_MODE_UNKNOWN) { 1096 /* Incase startup_state do not let startup_() */ 1097 cd->mode = CY_MODE_UNKNOWN; 1098 cyttsp4_queue_startup_(cd); 1099 goto cyttsp4_irq_exit; 1100 } 1101 1102 /* 1103 * do not wake thread on this switch since 1104 * it is possible to get an early heartbeat 1105 * prior to performing the reset 1106 */ 1107 cd->mode = cur_mode; 1108 1109 goto cyttsp4_irq_exit; 1110 } 1111 1112 switch (mode[0] & CY_HST_MODE) { 1113 case CY_HST_OPERATE: 1114 cur_mode = CY_MODE_OPERATIONAL; 1115 dev_vdbg(dev, "%s: operational\n", __func__); 1116 break; 1117 case CY_HST_CAT: 1118 cur_mode = CY_MODE_CAT; 1119 dev_vdbg(dev, "%s: CaT\n", __func__); 1120 break; 1121 case CY_HST_SYSINFO: 1122 cur_mode = CY_MODE_SYSINFO; 1123 dev_vdbg(dev, "%s: sysinfo\n", __func__); 1124 break; 1125 default: 1126 cur_mode = CY_MODE_UNKNOWN; 1127 dev_err(dev, "%s: unknown HST mode 0x%02X\n", __func__, 1128 mode[0]); 1129 break; 1130 } 1131 1132 /* Check whether this IRQ should be ignored (internal) */ 1133 if (cd->int_status & CY_INT_IGNORE) { 1134 dev_vdbg(dev, "%s: Ignoring IRQ\n", __func__); 1135 goto cyttsp4_irq_exit; 1136 } 1137 1138 /* Check for wake up interrupt */ 1139 if (cd->int_status & CY_INT_AWAKE) { 1140 cd->int_status &= ~CY_INT_AWAKE; 1141 wake_up(&cd->wait_q); 1142 dev_vdbg(dev, "%s: Received wake up interrupt\n", __func__); 1143 goto cyttsp4_irq_handshake; 1144 } 1145 1146 /* Expecting mode change interrupt */ 1147 if ((cd->int_status & CY_INT_MODE_CHANGE) 1148 && (mode[0] & CY_HST_MODE_CHANGE) == 0) { 1149 cd->int_status &= ~CY_INT_MODE_CHANGE; 1150 dev_dbg(dev, "%s: finish mode switch m=%d -> m=%d\n", 1151 __func__, cd->mode, cur_mode); 1152 cd->mode = cur_mode; 1153 wake_up(&cd->wait_q); 1154 goto cyttsp4_irq_handshake; 1155 } 1156 1157 /* compare current core mode to current device mode */ 1158 dev_vdbg(dev, "%s: cd->mode=%d cur_mode=%d\n", 1159 __func__, cd->mode, cur_mode); 1160 if ((mode[0] & CY_HST_MODE_CHANGE) == 0 && cd->mode != cur_mode) { 1161 /* Unexpected mode change occurred */ 1162 dev_err(dev, "%s %d->%d 0x%x\n", __func__, cd->mode, 1163 cur_mode, cd->int_status); 1164 dev_dbg(dev, "%s: Unexpected mode change, startup\n", 1165 __func__); 1166 cyttsp4_queue_startup_(cd); 1167 goto cyttsp4_irq_exit; 1168 } 1169 1170 /* Expecting command complete interrupt */ 1171 dev_vdbg(dev, "%s: command byte:0x%x\n", __func__, mode[cmd_ofs]); 1172 if ((cd->int_status & CY_INT_EXEC_CMD) 1173 && mode[cmd_ofs] & CY_CMD_COMPLETE) { 1174 cd->int_status &= ~CY_INT_EXEC_CMD; 1175 dev_vdbg(dev, "%s: Received command complete interrupt\n", 1176 __func__); 1177 wake_up(&cd->wait_q); 1178 /* 1179 * It is possible to receive a single interrupt for 1180 * command complete and touch/button status report. 1181 * Continue processing for a possible status report. 1182 */ 1183 } 1184 1185 /* This should be status report, read status regs */ 1186 if (cd->mode == CY_MODE_OPERATIONAL) { 1187 dev_vdbg(dev, "%s: Read status registers\n", __func__); 1188 rc = cyttsp4_load_status_regs(cd); 1189 if (rc < 0) 1190 dev_err(dev, "%s: fail read mode regs r=%d\n", 1191 __func__, rc); 1192 } 1193 1194 cyttsp4_mt_attention(cd); 1195 1196 cyttsp4_irq_handshake: 1197 /* handshake the event */ 1198 dev_vdbg(dev, "%s: Handshake mode=0x%02X r=%d\n", 1199 __func__, mode[0], rc); 1200 rc = cyttsp4_handshake(cd, mode[0]); 1201 if (rc < 0) 1202 dev_err(dev, "%s: Fail handshake mode=0x%02X r=%d\n", 1203 __func__, mode[0], rc); 1204 1205 /* 1206 * a non-zero udelay period is required for using 1207 * IRQF_TRIGGER_LOW in order to delay until the 1208 * device completes isr deassert 1209 */ 1210 udelay(cd->cpdata->level_irq_udelay); 1211 1212 cyttsp4_irq_exit: 1213 mutex_unlock(&cd->system_lock); 1214 return IRQ_HANDLED; 1215 } 1216 1217 static void cyttsp4_start_wd_timer(struct cyttsp4 *cd) 1218 { 1219 if (!CY_WATCHDOG_TIMEOUT) 1220 return; 1221 1222 mod_timer(&cd->watchdog_timer, jiffies + 1223 msecs_to_jiffies(CY_WATCHDOG_TIMEOUT)); 1224 } 1225 1226 static void cyttsp4_stop_wd_timer(struct cyttsp4 *cd) 1227 { 1228 if (!CY_WATCHDOG_TIMEOUT) 1229 return; 1230 1231 /* 1232 * Ensure we wait until the watchdog timer 1233 * running on a different CPU finishes 1234 */ 1235 del_timer_sync(&cd->watchdog_timer); 1236 cancel_work_sync(&cd->watchdog_work); 1237 del_timer_sync(&cd->watchdog_timer); 1238 } 1239 1240 static void cyttsp4_watchdog_timer(unsigned long handle) 1241 { 1242 struct cyttsp4 *cd = (struct cyttsp4 *)handle; 1243 1244 dev_vdbg(cd->dev, "%s: Watchdog timer triggered\n", __func__); 1245 1246 schedule_work(&cd->watchdog_work); 1247 1248 return; 1249 } 1250 1251 static int cyttsp4_request_exclusive(struct cyttsp4 *cd, void *ownptr, 1252 int timeout_ms) 1253 { 1254 int t = msecs_to_jiffies(timeout_ms); 1255 bool with_timeout = (timeout_ms != 0); 1256 1257 mutex_lock(&cd->system_lock); 1258 if (!cd->exclusive_dev && cd->exclusive_waits == 0) { 1259 cd->exclusive_dev = ownptr; 1260 goto exit; 1261 } 1262 1263 cd->exclusive_waits++; 1264 wait: 1265 mutex_unlock(&cd->system_lock); 1266 if (with_timeout) { 1267 t = wait_event_timeout(cd->wait_q, !cd->exclusive_dev, t); 1268 if (IS_TMO(t)) { 1269 dev_err(cd->dev, "%s: tmo waiting exclusive access\n", 1270 __func__); 1271 mutex_lock(&cd->system_lock); 1272 cd->exclusive_waits--; 1273 mutex_unlock(&cd->system_lock); 1274 return -ETIME; 1275 } 1276 } else { 1277 wait_event(cd->wait_q, !cd->exclusive_dev); 1278 } 1279 mutex_lock(&cd->system_lock); 1280 if (cd->exclusive_dev) 1281 goto wait; 1282 cd->exclusive_dev = ownptr; 1283 cd->exclusive_waits--; 1284 exit: 1285 mutex_unlock(&cd->system_lock); 1286 1287 return 0; 1288 } 1289 1290 /* 1291 * returns error if was not owned 1292 */ 1293 static int cyttsp4_release_exclusive(struct cyttsp4 *cd, void *ownptr) 1294 { 1295 mutex_lock(&cd->system_lock); 1296 if (cd->exclusive_dev != ownptr) { 1297 mutex_unlock(&cd->system_lock); 1298 return -EINVAL; 1299 } 1300 1301 dev_vdbg(cd->dev, "%s: exclusive_dev %p freed\n", 1302 __func__, cd->exclusive_dev); 1303 cd->exclusive_dev = NULL; 1304 wake_up(&cd->wait_q); 1305 mutex_unlock(&cd->system_lock); 1306 return 0; 1307 } 1308 1309 static int cyttsp4_wait_bl_heartbeat(struct cyttsp4 *cd) 1310 { 1311 long t; 1312 int rc = 0; 1313 1314 /* wait heartbeat */ 1315 dev_vdbg(cd->dev, "%s: wait heartbeat...\n", __func__); 1316 t = wait_event_timeout(cd->wait_q, cd->mode == CY_MODE_BOOTLOADER, 1317 msecs_to_jiffies(CY_CORE_RESET_AND_WAIT_TIMEOUT)); 1318 if (IS_TMO(t)) { 1319 dev_err(cd->dev, "%s: tmo waiting bl heartbeat cd->mode=%d\n", 1320 __func__, cd->mode); 1321 rc = -ETIME; 1322 } 1323 1324 return rc; 1325 } 1326 1327 static int cyttsp4_wait_sysinfo_mode(struct cyttsp4 *cd) 1328 { 1329 long t; 1330 1331 dev_vdbg(cd->dev, "%s: wait sysinfo...\n", __func__); 1332 1333 t = wait_event_timeout(cd->wait_q, cd->mode == CY_MODE_SYSINFO, 1334 msecs_to_jiffies(CY_CORE_MODE_CHANGE_TIMEOUT)); 1335 if (IS_TMO(t)) { 1336 dev_err(cd->dev, "%s: tmo waiting exit bl cd->mode=%d\n", 1337 __func__, cd->mode); 1338 mutex_lock(&cd->system_lock); 1339 cd->int_status &= ~CY_INT_MODE_CHANGE; 1340 mutex_unlock(&cd->system_lock); 1341 return -ETIME; 1342 } 1343 1344 return 0; 1345 } 1346 1347 static int cyttsp4_reset_and_wait(struct cyttsp4 *cd) 1348 { 1349 int rc; 1350 1351 /* reset hardware */ 1352 mutex_lock(&cd->system_lock); 1353 dev_dbg(cd->dev, "%s: reset hw...\n", __func__); 1354 rc = cyttsp4_hw_reset(cd); 1355 cd->mode = CY_MODE_UNKNOWN; 1356 mutex_unlock(&cd->system_lock); 1357 if (rc < 0) { 1358 dev_err(cd->dev, "%s:Fail hw reset r=%d\n", __func__, rc); 1359 return rc; 1360 } 1361 1362 return cyttsp4_wait_bl_heartbeat(cd); 1363 } 1364 1365 /* 1366 * returns err if refused or timeout; block until mode change complete 1367 * bit is set (mode change interrupt) 1368 */ 1369 static int cyttsp4_set_mode(struct cyttsp4 *cd, int new_mode) 1370 { 1371 u8 new_dev_mode; 1372 u8 mode; 1373 long t; 1374 int rc; 1375 1376 switch (new_mode) { 1377 case CY_MODE_OPERATIONAL: 1378 new_dev_mode = CY_HST_OPERATE; 1379 break; 1380 case CY_MODE_SYSINFO: 1381 new_dev_mode = CY_HST_SYSINFO; 1382 break; 1383 case CY_MODE_CAT: 1384 new_dev_mode = CY_HST_CAT; 1385 break; 1386 default: 1387 dev_err(cd->dev, "%s: invalid mode: %02X(%d)\n", 1388 __func__, new_mode, new_mode); 1389 return -EINVAL; 1390 } 1391 1392 /* change mode */ 1393 dev_dbg(cd->dev, "%s: %s=%p new_dev_mode=%02X new_mode=%d\n", 1394 __func__, "have exclusive", cd->exclusive_dev, 1395 new_dev_mode, new_mode); 1396 1397 mutex_lock(&cd->system_lock); 1398 rc = cyttsp4_adap_read(cd, CY_REG_BASE, sizeof(mode), &mode); 1399 if (rc < 0) { 1400 mutex_unlock(&cd->system_lock); 1401 dev_err(cd->dev, "%s: Fail read mode r=%d\n", 1402 __func__, rc); 1403 goto exit; 1404 } 1405 1406 /* Clear device mode bits and set to new mode */ 1407 mode &= ~CY_HST_MODE; 1408 mode |= new_dev_mode | CY_HST_MODE_CHANGE; 1409 1410 cd->int_status |= CY_INT_MODE_CHANGE; 1411 rc = cyttsp4_adap_write(cd, CY_REG_BASE, sizeof(mode), &mode); 1412 mutex_unlock(&cd->system_lock); 1413 if (rc < 0) { 1414 dev_err(cd->dev, "%s: Fail write mode change r=%d\n", 1415 __func__, rc); 1416 goto exit; 1417 } 1418 1419 /* wait for mode change done interrupt */ 1420 t = wait_event_timeout(cd->wait_q, 1421 (cd->int_status & CY_INT_MODE_CHANGE) == 0, 1422 msecs_to_jiffies(CY_CORE_MODE_CHANGE_TIMEOUT)); 1423 dev_dbg(cd->dev, "%s: back from wait t=%ld cd->mode=%d\n", 1424 __func__, t, cd->mode); 1425 1426 if (IS_TMO(t)) { 1427 dev_err(cd->dev, "%s: %s\n", __func__, 1428 "tmo waiting mode change"); 1429 mutex_lock(&cd->system_lock); 1430 cd->int_status &= ~CY_INT_MODE_CHANGE; 1431 mutex_unlock(&cd->system_lock); 1432 rc = -EINVAL; 1433 } 1434 1435 exit: 1436 return rc; 1437 } 1438 1439 static void cyttsp4_watchdog_work(struct work_struct *work) 1440 { 1441 struct cyttsp4 *cd = 1442 container_of(work, struct cyttsp4, watchdog_work); 1443 u8 *mode; 1444 int retval; 1445 1446 mutex_lock(&cd->system_lock); 1447 retval = cyttsp4_load_status_regs(cd); 1448 if (retval < 0) { 1449 dev_err(cd->dev, 1450 "%s: failed to access device in watchdog timer r=%d\n", 1451 __func__, retval); 1452 cyttsp4_queue_startup_(cd); 1453 goto cyttsp4_timer_watchdog_exit_error; 1454 } 1455 mode = &cd->sysinfo.xy_mode[CY_REG_BASE]; 1456 if (IS_BOOTLOADER(mode[0], mode[1])) { 1457 dev_err(cd->dev, 1458 "%s: device found in bootloader mode when operational mode\n", 1459 __func__); 1460 cyttsp4_queue_startup_(cd); 1461 goto cyttsp4_timer_watchdog_exit_error; 1462 } 1463 1464 cyttsp4_start_wd_timer(cd); 1465 cyttsp4_timer_watchdog_exit_error: 1466 mutex_unlock(&cd->system_lock); 1467 return; 1468 } 1469 1470 static int cyttsp4_core_sleep_(struct cyttsp4 *cd) 1471 { 1472 enum cyttsp4_sleep_state ss = SS_SLEEP_ON; 1473 enum cyttsp4_int_state int_status = CY_INT_IGNORE; 1474 int rc = 0; 1475 u8 mode[2]; 1476 1477 /* Already in sleep mode? */ 1478 mutex_lock(&cd->system_lock); 1479 if (cd->sleep_state == SS_SLEEP_ON) { 1480 mutex_unlock(&cd->system_lock); 1481 return 0; 1482 } 1483 cd->sleep_state = SS_SLEEPING; 1484 mutex_unlock(&cd->system_lock); 1485 1486 cyttsp4_stop_wd_timer(cd); 1487 1488 /* Wait until currently running IRQ handler exits and disable IRQ */ 1489 disable_irq(cd->irq); 1490 1491 dev_vdbg(cd->dev, "%s: write DEEP SLEEP...\n", __func__); 1492 mutex_lock(&cd->system_lock); 1493 rc = cyttsp4_adap_read(cd, CY_REG_BASE, sizeof(mode), &mode); 1494 if (rc) { 1495 mutex_unlock(&cd->system_lock); 1496 dev_err(cd->dev, "%s: Fail read adapter r=%d\n", __func__, rc); 1497 goto error; 1498 } 1499 1500 if (IS_BOOTLOADER(mode[0], mode[1])) { 1501 mutex_unlock(&cd->system_lock); 1502 dev_err(cd->dev, "%s: Device in BOOTLOADER mode.\n", __func__); 1503 rc = -EINVAL; 1504 goto error; 1505 } 1506 1507 mode[0] |= CY_HST_SLEEP; 1508 rc = cyttsp4_adap_write(cd, CY_REG_BASE, sizeof(mode[0]), &mode[0]); 1509 mutex_unlock(&cd->system_lock); 1510 if (rc) { 1511 dev_err(cd->dev, "%s: Fail write adapter r=%d\n", __func__, rc); 1512 goto error; 1513 } 1514 dev_vdbg(cd->dev, "%s: write DEEP SLEEP succeeded\n", __func__); 1515 1516 if (cd->cpdata->power) { 1517 dev_dbg(cd->dev, "%s: Power down HW\n", __func__); 1518 rc = cd->cpdata->power(cd->cpdata, 0, cd->dev, &cd->ignore_irq); 1519 } else { 1520 dev_dbg(cd->dev, "%s: No power function\n", __func__); 1521 rc = 0; 1522 } 1523 if (rc < 0) { 1524 dev_err(cd->dev, "%s: HW Power down fails r=%d\n", 1525 __func__, rc); 1526 goto error; 1527 } 1528 1529 /* Give time to FW to sleep */ 1530 msleep(50); 1531 1532 goto exit; 1533 1534 error: 1535 ss = SS_SLEEP_OFF; 1536 int_status = CY_INT_NONE; 1537 cyttsp4_start_wd_timer(cd); 1538 1539 exit: 1540 mutex_lock(&cd->system_lock); 1541 cd->sleep_state = ss; 1542 cd->int_status |= int_status; 1543 mutex_unlock(&cd->system_lock); 1544 enable_irq(cd->irq); 1545 return rc; 1546 } 1547 1548 static int cyttsp4_startup_(struct cyttsp4 *cd) 1549 { 1550 int retry = CY_CORE_STARTUP_RETRY_COUNT; 1551 int rc; 1552 1553 cyttsp4_stop_wd_timer(cd); 1554 1555 reset: 1556 if (retry != CY_CORE_STARTUP_RETRY_COUNT) 1557 dev_dbg(cd->dev, "%s: Retry %d\n", __func__, 1558 CY_CORE_STARTUP_RETRY_COUNT - retry); 1559 1560 /* reset hardware and wait for heartbeat */ 1561 rc = cyttsp4_reset_and_wait(cd); 1562 if (rc < 0) { 1563 dev_err(cd->dev, "%s: Error on h/w reset r=%d\n", __func__, rc); 1564 if (retry--) 1565 goto reset; 1566 goto exit; 1567 } 1568 1569 /* exit bl into sysinfo mode */ 1570 dev_vdbg(cd->dev, "%s: write exit ldr...\n", __func__); 1571 mutex_lock(&cd->system_lock); 1572 cd->int_status &= ~CY_INT_IGNORE; 1573 cd->int_status |= CY_INT_MODE_CHANGE; 1574 1575 rc = cyttsp4_adap_write(cd, CY_REG_BASE, sizeof(ldr_exit), 1576 (u8 *)ldr_exit); 1577 mutex_unlock(&cd->system_lock); 1578 if (rc < 0) { 1579 dev_err(cd->dev, "%s: Fail write r=%d\n", __func__, rc); 1580 if (retry--) 1581 goto reset; 1582 goto exit; 1583 } 1584 1585 rc = cyttsp4_wait_sysinfo_mode(cd); 1586 if (rc < 0) { 1587 u8 buf[sizeof(ldr_err_app)]; 1588 int rc1; 1589 1590 /* Check for invalid/corrupted touch application */ 1591 rc1 = cyttsp4_adap_read(cd, CY_REG_BASE, sizeof(ldr_err_app), 1592 buf); 1593 if (rc1) { 1594 dev_err(cd->dev, "%s: Fail read r=%d\n", __func__, rc1); 1595 } else if (!memcmp(buf, ldr_err_app, sizeof(ldr_err_app))) { 1596 dev_err(cd->dev, "%s: Error launching touch application\n", 1597 __func__); 1598 mutex_lock(&cd->system_lock); 1599 cd->invalid_touch_app = true; 1600 mutex_unlock(&cd->system_lock); 1601 goto exit_no_wd; 1602 } 1603 1604 if (retry--) 1605 goto reset; 1606 goto exit; 1607 } 1608 1609 mutex_lock(&cd->system_lock); 1610 cd->invalid_touch_app = false; 1611 mutex_unlock(&cd->system_lock); 1612 1613 /* read sysinfo data */ 1614 dev_vdbg(cd->dev, "%s: get sysinfo regs..\n", __func__); 1615 rc = cyttsp4_get_sysinfo_regs(cd); 1616 if (rc < 0) { 1617 dev_err(cd->dev, "%s: failed to get sysinfo regs rc=%d\n", 1618 __func__, rc); 1619 if (retry--) 1620 goto reset; 1621 goto exit; 1622 } 1623 1624 rc = cyttsp4_set_mode(cd, CY_MODE_OPERATIONAL); 1625 if (rc < 0) { 1626 dev_err(cd->dev, "%s: failed to set mode to operational rc=%d\n", 1627 __func__, rc); 1628 if (retry--) 1629 goto reset; 1630 goto exit; 1631 } 1632 1633 cyttsp4_lift_all(&cd->md); 1634 1635 /* restore to sleep if was suspended */ 1636 mutex_lock(&cd->system_lock); 1637 if (cd->sleep_state == SS_SLEEP_ON) { 1638 cd->sleep_state = SS_SLEEP_OFF; 1639 mutex_unlock(&cd->system_lock); 1640 cyttsp4_core_sleep_(cd); 1641 goto exit_no_wd; 1642 } 1643 mutex_unlock(&cd->system_lock); 1644 1645 exit: 1646 cyttsp4_start_wd_timer(cd); 1647 exit_no_wd: 1648 return rc; 1649 } 1650 1651 static int cyttsp4_startup(struct cyttsp4 *cd) 1652 { 1653 int rc; 1654 1655 mutex_lock(&cd->system_lock); 1656 cd->startup_state = STARTUP_RUNNING; 1657 mutex_unlock(&cd->system_lock); 1658 1659 rc = cyttsp4_request_exclusive(cd, cd->dev, 1660 CY_CORE_REQUEST_EXCLUSIVE_TIMEOUT); 1661 if (rc < 0) { 1662 dev_err(cd->dev, "%s: fail get exclusive ex=%p own=%p\n", 1663 __func__, cd->exclusive_dev, cd->dev); 1664 goto exit; 1665 } 1666 1667 rc = cyttsp4_startup_(cd); 1668 1669 if (cyttsp4_release_exclusive(cd, cd->dev) < 0) 1670 /* Don't return fail code, mode is already changed. */ 1671 dev_err(cd->dev, "%s: fail to release exclusive\n", __func__); 1672 else 1673 dev_vdbg(cd->dev, "%s: pass release exclusive\n", __func__); 1674 1675 exit: 1676 mutex_lock(&cd->system_lock); 1677 cd->startup_state = STARTUP_NONE; 1678 mutex_unlock(&cd->system_lock); 1679 1680 /* Wake the waiters for end of startup */ 1681 wake_up(&cd->wait_q); 1682 1683 return rc; 1684 } 1685 1686 static void cyttsp4_startup_work_function(struct work_struct *work) 1687 { 1688 struct cyttsp4 *cd = container_of(work, struct cyttsp4, startup_work); 1689 int rc; 1690 1691 rc = cyttsp4_startup(cd); 1692 if (rc < 0) 1693 dev_err(cd->dev, "%s: Fail queued startup r=%d\n", 1694 __func__, rc); 1695 } 1696 1697 static void cyttsp4_free_si_ptrs(struct cyttsp4 *cd) 1698 { 1699 struct cyttsp4_sysinfo *si = &cd->sysinfo; 1700 1701 if (!si) 1702 return; 1703 1704 kfree(si->si_ptrs.cydata); 1705 kfree(si->si_ptrs.test); 1706 kfree(si->si_ptrs.pcfg); 1707 kfree(si->si_ptrs.opcfg); 1708 kfree(si->si_ptrs.ddata); 1709 kfree(si->si_ptrs.mdata); 1710 kfree(si->btn); 1711 kfree(si->xy_mode); 1712 kfree(si->xy_data); 1713 kfree(si->btn_rec_data); 1714 } 1715 1716 #ifdef CONFIG_PM 1717 static int cyttsp4_core_sleep(struct cyttsp4 *cd) 1718 { 1719 int rc; 1720 1721 rc = cyttsp4_request_exclusive(cd, cd->dev, 1722 CY_CORE_SLEEP_REQUEST_EXCLUSIVE_TIMEOUT); 1723 if (rc < 0) { 1724 dev_err(cd->dev, "%s: fail get exclusive ex=%p own=%p\n", 1725 __func__, cd->exclusive_dev, cd->dev); 1726 return 0; 1727 } 1728 1729 rc = cyttsp4_core_sleep_(cd); 1730 1731 if (cyttsp4_release_exclusive(cd, cd->dev) < 0) 1732 dev_err(cd->dev, "%s: fail to release exclusive\n", __func__); 1733 else 1734 dev_vdbg(cd->dev, "%s: pass release exclusive\n", __func__); 1735 1736 return rc; 1737 } 1738 1739 static int cyttsp4_core_wake_(struct cyttsp4 *cd) 1740 { 1741 struct device *dev = cd->dev; 1742 int rc; 1743 u8 mode; 1744 int t; 1745 1746 /* Already woken? */ 1747 mutex_lock(&cd->system_lock); 1748 if (cd->sleep_state == SS_SLEEP_OFF) { 1749 mutex_unlock(&cd->system_lock); 1750 return 0; 1751 } 1752 cd->int_status &= ~CY_INT_IGNORE; 1753 cd->int_status |= CY_INT_AWAKE; 1754 cd->sleep_state = SS_WAKING; 1755 1756 if (cd->cpdata->power) { 1757 dev_dbg(dev, "%s: Power up HW\n", __func__); 1758 rc = cd->cpdata->power(cd->cpdata, 1, dev, &cd->ignore_irq); 1759 } else { 1760 dev_dbg(dev, "%s: No power function\n", __func__); 1761 rc = -ENOSYS; 1762 } 1763 if (rc < 0) { 1764 dev_err(dev, "%s: HW Power up fails r=%d\n", 1765 __func__, rc); 1766 1767 /* Initiate a read transaction to wake up */ 1768 cyttsp4_adap_read(cd, CY_REG_BASE, sizeof(mode), &mode); 1769 } else 1770 dev_vdbg(cd->dev, "%s: HW power up succeeds\n", 1771 __func__); 1772 mutex_unlock(&cd->system_lock); 1773 1774 t = wait_event_timeout(cd->wait_q, 1775 (cd->int_status & CY_INT_AWAKE) == 0, 1776 msecs_to_jiffies(CY_CORE_WAKEUP_TIMEOUT)); 1777 if (IS_TMO(t)) { 1778 dev_err(dev, "%s: TMO waiting for wakeup\n", __func__); 1779 mutex_lock(&cd->system_lock); 1780 cd->int_status &= ~CY_INT_AWAKE; 1781 /* Try starting up */ 1782 cyttsp4_queue_startup_(cd); 1783 mutex_unlock(&cd->system_lock); 1784 } 1785 1786 mutex_lock(&cd->system_lock); 1787 cd->sleep_state = SS_SLEEP_OFF; 1788 mutex_unlock(&cd->system_lock); 1789 1790 cyttsp4_start_wd_timer(cd); 1791 1792 return 0; 1793 } 1794 1795 static int cyttsp4_core_wake(struct cyttsp4 *cd) 1796 { 1797 int rc; 1798 1799 rc = cyttsp4_request_exclusive(cd, cd->dev, 1800 CY_CORE_REQUEST_EXCLUSIVE_TIMEOUT); 1801 if (rc < 0) { 1802 dev_err(cd->dev, "%s: fail get exclusive ex=%p own=%p\n", 1803 __func__, cd->exclusive_dev, cd->dev); 1804 return 0; 1805 } 1806 1807 rc = cyttsp4_core_wake_(cd); 1808 1809 if (cyttsp4_release_exclusive(cd, cd->dev) < 0) 1810 dev_err(cd->dev, "%s: fail to release exclusive\n", __func__); 1811 else 1812 dev_vdbg(cd->dev, "%s: pass release exclusive\n", __func__); 1813 1814 return rc; 1815 } 1816 1817 static int cyttsp4_core_suspend(struct device *dev) 1818 { 1819 struct cyttsp4 *cd = dev_get_drvdata(dev); 1820 struct cyttsp4_mt_data *md = &cd->md; 1821 int rc; 1822 1823 md->is_suspended = true; 1824 1825 rc = cyttsp4_core_sleep(cd); 1826 if (rc < 0) { 1827 dev_err(dev, "%s: Error on sleep\n", __func__); 1828 return -EAGAIN; 1829 } 1830 return 0; 1831 } 1832 1833 static int cyttsp4_core_resume(struct device *dev) 1834 { 1835 struct cyttsp4 *cd = dev_get_drvdata(dev); 1836 struct cyttsp4_mt_data *md = &cd->md; 1837 int rc; 1838 1839 md->is_suspended = false; 1840 1841 rc = cyttsp4_core_wake(cd); 1842 if (rc < 0) { 1843 dev_err(dev, "%s: Error on wake\n", __func__); 1844 return -EAGAIN; 1845 } 1846 1847 return 0; 1848 } 1849 #endif 1850 1851 const struct dev_pm_ops cyttsp4_pm_ops = { 1852 SET_SYSTEM_SLEEP_PM_OPS(cyttsp4_core_suspend, cyttsp4_core_resume) 1853 SET_RUNTIME_PM_OPS(cyttsp4_core_suspend, cyttsp4_core_resume, NULL) 1854 }; 1855 EXPORT_SYMBOL_GPL(cyttsp4_pm_ops); 1856 1857 static int cyttsp4_mt_open(struct input_dev *input) 1858 { 1859 pm_runtime_get(input->dev.parent); 1860 return 0; 1861 } 1862 1863 static void cyttsp4_mt_close(struct input_dev *input) 1864 { 1865 struct cyttsp4_mt_data *md = input_get_drvdata(input); 1866 mutex_lock(&md->report_lock); 1867 if (!md->is_suspended) 1868 pm_runtime_put(input->dev.parent); 1869 mutex_unlock(&md->report_lock); 1870 } 1871 1872 1873 static int cyttsp4_setup_input_device(struct cyttsp4 *cd) 1874 { 1875 struct device *dev = cd->dev; 1876 struct cyttsp4_mt_data *md = &cd->md; 1877 int signal = CY_IGNORE_VALUE; 1878 int max_x, max_y, max_p, min, max; 1879 int max_x_tmp, max_y_tmp; 1880 int i; 1881 int rc; 1882 1883 dev_vdbg(dev, "%s: Initialize event signals\n", __func__); 1884 __set_bit(EV_ABS, md->input->evbit); 1885 __set_bit(EV_REL, md->input->evbit); 1886 __set_bit(EV_KEY, md->input->evbit); 1887 1888 max_x_tmp = md->si->si_ofs.max_x; 1889 max_y_tmp = md->si->si_ofs.max_y; 1890 1891 /* get maximum values from the sysinfo data */ 1892 if (md->pdata->flags & CY_FLAG_FLIP) { 1893 max_x = max_y_tmp - 1; 1894 max_y = max_x_tmp - 1; 1895 } else { 1896 max_x = max_x_tmp - 1; 1897 max_y = max_y_tmp - 1; 1898 } 1899 max_p = md->si->si_ofs.max_p; 1900 1901 /* set event signal capabilities */ 1902 for (i = 0; i < (md->pdata->frmwrk->size / CY_NUM_ABS_SET); i++) { 1903 signal = md->pdata->frmwrk->abs 1904 [(i * CY_NUM_ABS_SET) + CY_SIGNAL_OST]; 1905 if (signal != CY_IGNORE_VALUE) { 1906 __set_bit(signal, md->input->absbit); 1907 min = md->pdata->frmwrk->abs 1908 [(i * CY_NUM_ABS_SET) + CY_MIN_OST]; 1909 max = md->pdata->frmwrk->abs 1910 [(i * CY_NUM_ABS_SET) + CY_MAX_OST]; 1911 if (i == CY_ABS_ID_OST) { 1912 /* shift track ids down to start at 0 */ 1913 max = max - min; 1914 min = min - min; 1915 } else if (i == CY_ABS_X_OST) 1916 max = max_x; 1917 else if (i == CY_ABS_Y_OST) 1918 max = max_y; 1919 else if (i == CY_ABS_P_OST) 1920 max = max_p; 1921 input_set_abs_params(md->input, signal, min, max, 1922 md->pdata->frmwrk->abs 1923 [(i * CY_NUM_ABS_SET) + CY_FUZZ_OST], 1924 md->pdata->frmwrk->abs 1925 [(i * CY_NUM_ABS_SET) + CY_FLAT_OST]); 1926 dev_dbg(dev, "%s: register signal=%02X min=%d max=%d\n", 1927 __func__, signal, min, max); 1928 if ((i == CY_ABS_ID_OST) && 1929 (md->si->si_ofs.tch_rec_size < 1930 CY_TMA4XX_TCH_REC_SIZE)) 1931 break; 1932 } 1933 } 1934 1935 input_mt_init_slots(md->input, md->si->si_ofs.tch_abs[CY_TCH_T].max, 1936 INPUT_MT_DIRECT); 1937 rc = input_register_device(md->input); 1938 if (rc < 0) 1939 dev_err(dev, "%s: Error, failed register input device r=%d\n", 1940 __func__, rc); 1941 return rc; 1942 } 1943 1944 static int cyttsp4_mt_probe(struct cyttsp4 *cd) 1945 { 1946 struct device *dev = cd->dev; 1947 struct cyttsp4_mt_data *md = &cd->md; 1948 struct cyttsp4_mt_platform_data *pdata = cd->pdata->mt_pdata; 1949 int rc = 0; 1950 1951 mutex_init(&md->report_lock); 1952 md->pdata = pdata; 1953 /* Create the input device and register it. */ 1954 dev_vdbg(dev, "%s: Create the input device and register it\n", 1955 __func__); 1956 md->input = input_allocate_device(); 1957 if (md->input == NULL) { 1958 dev_err(dev, "%s: Error, failed to allocate input device\n", 1959 __func__); 1960 rc = -ENOSYS; 1961 goto error_alloc_failed; 1962 } 1963 1964 md->input->name = pdata->inp_dev_name; 1965 scnprintf(md->phys, sizeof(md->phys)-1, "%s", dev_name(dev)); 1966 md->input->phys = md->phys; 1967 md->input->id.bustype = cd->bus_ops->bustype; 1968 md->input->dev.parent = dev; 1969 md->input->open = cyttsp4_mt_open; 1970 md->input->close = cyttsp4_mt_close; 1971 input_set_drvdata(md->input, md); 1972 1973 /* get sysinfo */ 1974 md->si = &cd->sysinfo; 1975 if (!md->si) { 1976 dev_err(dev, "%s: Fail get sysinfo pointer from core p=%p\n", 1977 __func__, md->si); 1978 goto error_get_sysinfo; 1979 } 1980 1981 rc = cyttsp4_setup_input_device(cd); 1982 if (rc) 1983 goto error_init_input; 1984 1985 return 0; 1986 1987 error_init_input: 1988 input_free_device(md->input); 1989 error_get_sysinfo: 1990 input_set_drvdata(md->input, NULL); 1991 error_alloc_failed: 1992 dev_err(dev, "%s failed.\n", __func__); 1993 return rc; 1994 } 1995 1996 struct cyttsp4 *cyttsp4_probe(const struct cyttsp4_bus_ops *ops, 1997 struct device *dev, u16 irq, size_t xfer_buf_size) 1998 { 1999 struct cyttsp4 *cd; 2000 struct cyttsp4_platform_data *pdata = dev_get_platdata(dev); 2001 unsigned long irq_flags; 2002 int rc = 0; 2003 2004 if (!pdata || !pdata->core_pdata || !pdata->mt_pdata) { 2005 dev_err(dev, "%s: Missing platform data\n", __func__); 2006 rc = -ENODEV; 2007 goto error_no_pdata; 2008 } 2009 2010 cd = kzalloc(sizeof(*cd), GFP_KERNEL); 2011 if (!cd) { 2012 dev_err(dev, "%s: Error, kzalloc\n", __func__); 2013 rc = -ENOMEM; 2014 goto error_alloc_data; 2015 } 2016 2017 cd->xfer_buf = kzalloc(xfer_buf_size, GFP_KERNEL); 2018 if (!cd->xfer_buf) { 2019 dev_err(dev, "%s: Error, kzalloc\n", __func__); 2020 rc = -ENOMEM; 2021 goto error_free_cd; 2022 } 2023 2024 /* Initialize device info */ 2025 cd->dev = dev; 2026 cd->pdata = pdata; 2027 cd->cpdata = pdata->core_pdata; 2028 cd->bus_ops = ops; 2029 2030 /* Initialize mutexes and spinlocks */ 2031 mutex_init(&cd->system_lock); 2032 mutex_init(&cd->adap_lock); 2033 2034 /* Initialize wait queue */ 2035 init_waitqueue_head(&cd->wait_q); 2036 2037 /* Initialize works */ 2038 INIT_WORK(&cd->startup_work, cyttsp4_startup_work_function); 2039 INIT_WORK(&cd->watchdog_work, cyttsp4_watchdog_work); 2040 2041 /* Initialize IRQ */ 2042 cd->irq = gpio_to_irq(cd->cpdata->irq_gpio); 2043 if (cd->irq < 0) { 2044 rc = -EINVAL; 2045 goto error_free_xfer; 2046 } 2047 2048 dev_set_drvdata(dev, cd); 2049 2050 /* Call platform init function */ 2051 if (cd->cpdata->init) { 2052 dev_dbg(cd->dev, "%s: Init HW\n", __func__); 2053 rc = cd->cpdata->init(cd->cpdata, 1, cd->dev); 2054 } else { 2055 dev_dbg(cd->dev, "%s: No HW INIT function\n", __func__); 2056 rc = 0; 2057 } 2058 if (rc < 0) 2059 dev_err(cd->dev, "%s: HW Init fail r=%d\n", __func__, rc); 2060 2061 dev_dbg(dev, "%s: initialize threaded irq=%d\n", __func__, cd->irq); 2062 if (cd->cpdata->level_irq_udelay > 0) 2063 /* use level triggered interrupts */ 2064 irq_flags = IRQF_TRIGGER_LOW | IRQF_ONESHOT; 2065 else 2066 /* use edge triggered interrupts */ 2067 irq_flags = IRQF_TRIGGER_FALLING | IRQF_ONESHOT; 2068 2069 rc = request_threaded_irq(cd->irq, NULL, cyttsp4_irq, irq_flags, 2070 dev_name(dev), cd); 2071 if (rc < 0) { 2072 dev_err(dev, "%s: Error, could not request irq\n", __func__); 2073 goto error_request_irq; 2074 } 2075 2076 /* Setup watchdog timer */ 2077 setup_timer(&cd->watchdog_timer, cyttsp4_watchdog_timer, 2078 (unsigned long)cd); 2079 2080 /* 2081 * call startup directly to ensure that the device 2082 * is tested before leaving the probe 2083 */ 2084 rc = cyttsp4_startup(cd); 2085 2086 /* Do not fail probe if startup fails but the device is detected */ 2087 if (rc < 0 && cd->mode == CY_MODE_UNKNOWN) { 2088 dev_err(cd->dev, "%s: Fail initial startup r=%d\n", 2089 __func__, rc); 2090 goto error_startup; 2091 } 2092 2093 rc = cyttsp4_mt_probe(cd); 2094 if (rc < 0) { 2095 dev_err(dev, "%s: Error, fail mt probe\n", __func__); 2096 goto error_startup; 2097 } 2098 2099 pm_runtime_enable(dev); 2100 2101 return cd; 2102 2103 error_startup: 2104 cancel_work_sync(&cd->startup_work); 2105 cyttsp4_stop_wd_timer(cd); 2106 pm_runtime_disable(dev); 2107 cyttsp4_free_si_ptrs(cd); 2108 free_irq(cd->irq, cd); 2109 error_request_irq: 2110 if (cd->cpdata->init) 2111 cd->cpdata->init(cd->cpdata, 0, dev); 2112 error_free_xfer: 2113 kfree(cd->xfer_buf); 2114 error_free_cd: 2115 kfree(cd); 2116 error_alloc_data: 2117 error_no_pdata: 2118 dev_err(dev, "%s failed.\n", __func__); 2119 return ERR_PTR(rc); 2120 } 2121 EXPORT_SYMBOL_GPL(cyttsp4_probe); 2122 2123 static void cyttsp4_mt_release(struct cyttsp4_mt_data *md) 2124 { 2125 input_unregister_device(md->input); 2126 input_set_drvdata(md->input, NULL); 2127 } 2128 2129 int cyttsp4_remove(struct cyttsp4 *cd) 2130 { 2131 struct device *dev = cd->dev; 2132 2133 cyttsp4_mt_release(&cd->md); 2134 2135 /* 2136 * Suspend the device before freeing the startup_work and stopping 2137 * the watchdog since sleep function restarts watchdog on failure 2138 */ 2139 pm_runtime_suspend(dev); 2140 pm_runtime_disable(dev); 2141 2142 cancel_work_sync(&cd->startup_work); 2143 2144 cyttsp4_stop_wd_timer(cd); 2145 2146 free_irq(cd->irq, cd); 2147 if (cd->cpdata->init) 2148 cd->cpdata->init(cd->cpdata, 0, dev); 2149 cyttsp4_free_si_ptrs(cd); 2150 kfree(cd); 2151 return 0; 2152 } 2153 EXPORT_SYMBOL_GPL(cyttsp4_remove); 2154 2155 MODULE_LICENSE("GPL"); 2156 MODULE_DESCRIPTION("Cypress TrueTouch(R) Standard touchscreen core driver"); 2157 MODULE_AUTHOR("Cypress"); 2158