1 /* 2 * Copyright (c) 2013-2018 The Linux Foundation. All rights reserved. 3 * 4 * Permission to use, copy, modify, and/or distribute this software for 5 * any purpose with or without fee is hereby granted, provided that the 6 * above copyright notice and this permission notice appear in all 7 * copies. 8 * 9 * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL 10 * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED 11 * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE 12 * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL 13 * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR 14 * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER 15 * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR 16 * PERFORMANCE OF THIS SOFTWARE. 17 */ 18 19 #include "targcfg.h" 20 #include "qdf_lock.h" 21 #include "qdf_status.h" 22 #include "qdf_status.h" 23 #include <qdf_atomic.h> /* qdf_atomic_read */ 24 #include <targaddrs.h> 25 #include "hif_io32.h" 26 #include <hif.h> 27 #include <target_type.h> 28 #include "regtable.h" 29 #define ATH_MODULE_NAME hif 30 #include <a_debug.h> 31 #include "hif_main.h" 32 #include "ce_api.h" 33 #include "qdf_trace.h" 34 #include "pld_common.h" 35 #include "hif_debug.h" 36 #include "ce_internal.h" 37 #include "ce_reg.h" 38 #include "ce_assignment.h" 39 #include "ce_tasklet.h" 40 #ifndef CONFIG_WIN 41 #include "qwlan_version.h" 42 #endif 43 #include "qdf_module.h" 44 45 #define CE_POLL_TIMEOUT 10 /* ms */ 46 47 #define AGC_DUMP 1 48 #define CHANINFO_DUMP 2 49 #define BB_WATCHDOG_DUMP 3 50 #ifdef CONFIG_ATH_PCIE_ACCESS_DEBUG 51 #define PCIE_ACCESS_DUMP 4 52 #endif 53 #include "mp_dev.h" 54 55 #if (defined(QCA_WIFI_QCA8074) || defined(QCA_WIFI_QCA6290)) && \ 56 !defined(QCA_WIFI_SUPPORT_SRNG) 57 #define QCA_WIFI_SUPPORT_SRNG 58 #endif 59 60 /* Forward references */ 61 QDF_STATUS hif_post_recv_buffers_for_pipe(struct HIF_CE_pipe_info *pipe_info); 62 63 /* 64 * Fix EV118783, poll to check whether a BMI response comes 65 * other than waiting for the interruption which may be lost. 66 */ 67 /* #define BMI_RSP_POLLING */ 68 #define BMI_RSP_TO_MILLISEC 1000 69 70 #ifdef CONFIG_BYPASS_QMI 71 #define BYPASS_QMI 1 72 #else 73 #define BYPASS_QMI 0 74 #endif 75 76 #ifdef CONFIG_WIN 77 #if ENABLE_10_4_FW_HDR 78 #define WDI_IPA_SERVICE_GROUP 5 79 #define WDI_IPA_TX_SVC MAKE_SERVICE_ID(WDI_IPA_SERVICE_GROUP, 0) 80 #define HTT_DATA2_MSG_SVC MAKE_SERVICE_ID(HTT_SERVICE_GROUP, 1) 81 #define HTT_DATA3_MSG_SVC MAKE_SERVICE_ID(HTT_SERVICE_GROUP, 2) 82 #endif /* ENABLE_10_4_FW_HDR */ 83 #endif 84 85 QDF_STATUS hif_post_recv_buffers(struct hif_softc *scn); 86 static void hif_config_rri_on_ddr(struct hif_softc *scn); 87 88 /** 89 * hif_target_access_log_dump() - dump access log 90 * 91 * dump access log 92 * 93 * Return: n/a 94 */ 95 #ifdef CONFIG_ATH_PCIE_ACCESS_DEBUG 96 static void hif_target_access_log_dump(void) 97 { 98 hif_target_dump_access_log(); 99 } 100 #endif 101 102 103 void hif_trigger_dump(struct hif_opaque_softc *hif_ctx, 104 uint8_t cmd_id, bool start) 105 { 106 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 107 108 switch (cmd_id) { 109 case AGC_DUMP: 110 if (start) 111 priv_start_agc(scn); 112 else 113 priv_dump_agc(scn); 114 break; 115 case CHANINFO_DUMP: 116 if (start) 117 priv_start_cap_chaninfo(scn); 118 else 119 priv_dump_chaninfo(scn); 120 break; 121 case BB_WATCHDOG_DUMP: 122 priv_dump_bbwatchdog(scn); 123 break; 124 #ifdef CONFIG_ATH_PCIE_ACCESS_DEBUG 125 case PCIE_ACCESS_DUMP: 126 hif_target_access_log_dump(); 127 break; 128 #endif 129 default: 130 HIF_ERROR("%s: Invalid htc dump command", __func__); 131 break; 132 } 133 } 134 135 static void ce_poll_timeout(void *arg) 136 { 137 struct CE_state *CE_state = (struct CE_state *)arg; 138 139 if (CE_state->timer_inited) { 140 ce_per_engine_service(CE_state->scn, CE_state->id); 141 qdf_timer_mod(&CE_state->poll_timer, CE_POLL_TIMEOUT); 142 } 143 } 144 145 static unsigned int roundup_pwr2(unsigned int n) 146 { 147 int i; 148 unsigned int test_pwr2; 149 150 if (!(n & (n - 1))) 151 return n; /* already a power of 2 */ 152 153 test_pwr2 = 4; 154 for (i = 0; i < 29; i++) { 155 if (test_pwr2 > n) 156 return test_pwr2; 157 test_pwr2 = test_pwr2 << 1; 158 } 159 160 QDF_ASSERT(0); /* n too large */ 161 return 0; 162 } 163 164 #define ADRASTEA_SRC_WR_INDEX_OFFSET 0x3C 165 #define ADRASTEA_DST_WR_INDEX_OFFSET 0x40 166 167 static struct shadow_reg_cfg target_shadow_reg_cfg_map[] = { 168 { 0, ADRASTEA_SRC_WR_INDEX_OFFSET}, 169 { 3, ADRASTEA_SRC_WR_INDEX_OFFSET}, 170 { 4, ADRASTEA_SRC_WR_INDEX_OFFSET}, 171 { 5, ADRASTEA_SRC_WR_INDEX_OFFSET}, 172 { 7, ADRASTEA_SRC_WR_INDEX_OFFSET}, 173 { 1, ADRASTEA_DST_WR_INDEX_OFFSET}, 174 { 2, ADRASTEA_DST_WR_INDEX_OFFSET}, 175 { 7, ADRASTEA_DST_WR_INDEX_OFFSET}, 176 { 8, ADRASTEA_DST_WR_INDEX_OFFSET}, 177 #ifdef QCA_WIFI_3_0_ADRASTEA 178 { 9, ADRASTEA_DST_WR_INDEX_OFFSET}, 179 { 10, ADRASTEA_DST_WR_INDEX_OFFSET}, 180 { 11, ADRASTEA_DST_WR_INDEX_OFFSET}, 181 #endif 182 }; 183 184 #ifdef QCN7605_SUPPORT 185 static struct shadow_reg_cfg target_shadow_reg_cfg_map_qcn7605[] = { 186 { 0, ADRASTEA_SRC_WR_INDEX_OFFSET}, 187 { 4, ADRASTEA_SRC_WR_INDEX_OFFSET}, 188 { 5, ADRASTEA_SRC_WR_INDEX_OFFSET}, 189 { 3, ADRASTEA_DST_WR_INDEX_OFFSET}, 190 { 1, ADRASTEA_DST_WR_INDEX_OFFSET}, 191 { 2, ADRASTEA_DST_WR_INDEX_OFFSET}, 192 { 7, ADRASTEA_DST_WR_INDEX_OFFSET}, 193 { 8, ADRASTEA_DST_WR_INDEX_OFFSET}, 194 }; 195 #endif 196 197 #ifdef WLAN_FEATURE_EPPING 198 static struct shadow_reg_cfg target_shadow_reg_cfg_epping[] = { 199 { 0, ADRASTEA_SRC_WR_INDEX_OFFSET}, 200 { 3, ADRASTEA_SRC_WR_INDEX_OFFSET}, 201 { 4, ADRASTEA_SRC_WR_INDEX_OFFSET}, 202 { 7, ADRASTEA_SRC_WR_INDEX_OFFSET}, 203 { 1, ADRASTEA_DST_WR_INDEX_OFFSET}, 204 { 2, ADRASTEA_DST_WR_INDEX_OFFSET}, 205 { 5, ADRASTEA_DST_WR_INDEX_OFFSET}, 206 { 7, ADRASTEA_DST_WR_INDEX_OFFSET}, 207 { 8, ADRASTEA_DST_WR_INDEX_OFFSET}, 208 }; 209 #endif 210 211 /* CE_PCI TABLE */ 212 /* 213 * NOTE: the table below is out of date, though still a useful reference. 214 * Refer to target_service_to_ce_map and hif_map_service_to_pipe for the actual 215 * mapping of HTC services to HIF pipes. 216 */ 217 /* 218 * This authoritative table defines Copy Engine configuration and the mapping 219 * of services/endpoints to CEs. A subset of this information is passed to 220 * the Target during startup as a prerequisite to entering BMI phase. 221 * See: 222 * target_service_to_ce_map - Target-side mapping 223 * hif_map_service_to_pipe - Host-side mapping 224 * target_ce_config - Target-side configuration 225 * host_ce_config - Host-side configuration 226 ============================================================================ 227 Purpose | Service / Endpoint | CE | Dire | Xfer | Xfer 228 | | | ctio | Size | Frequency 229 | | | n | | 230 ============================================================================ 231 tx | HTT_DATA (downlink) | CE 0 | h->t | medium - | very frequent 232 descriptor | | | | O(100B) | and regular 233 download | | | | | 234 ---------------------------------------------------------------------------- 235 rx | HTT_DATA (uplink) | CE 1 | t->h | small - | frequent and 236 indication | | | | O(10B) | regular 237 upload | | | | | 238 ---------------------------------------------------------------------------- 239 MSDU | DATA_BK (uplink) | CE 2 | t->h | large - | rare 240 upload | | | | O(1000B) | (frequent 241 e.g. noise | | | | | during IP1.0 242 packets | | | | | testing) 243 ---------------------------------------------------------------------------- 244 MSDU | DATA_BK (downlink) | CE 3 | h->t | large - | very rare 245 download | | | | O(1000B) | (frequent 246 e.g. | | | | | during IP1.0 247 misdirecte | | | | | testing) 248 d EAPOL | | | | | 249 packets | | | | | 250 ---------------------------------------------------------------------------- 251 n/a | DATA_BE, DATA_VI | CE 2 | t->h | | never(?) 252 | DATA_VO (uplink) | | | | 253 ---------------------------------------------------------------------------- 254 n/a | DATA_BE, DATA_VI | CE 3 | h->t | | never(?) 255 | DATA_VO (downlink) | | | | 256 ---------------------------------------------------------------------------- 257 WMI events | WMI_CONTROL (uplink) | CE 4 | t->h | medium - | infrequent 258 | | | | O(100B) | 259 ---------------------------------------------------------------------------- 260 WMI | WMI_CONTROL | CE 5 | h->t | medium - | infrequent 261 messages | (downlink) | | | O(100B) | 262 | | | | | 263 ---------------------------------------------------------------------------- 264 n/a | HTC_CTRL_RSVD, | CE 1 | t->h | | never(?) 265 | HTC_RAW_STREAMS | | | | 266 | (uplink) | | | | 267 ---------------------------------------------------------------------------- 268 n/a | HTC_CTRL_RSVD, | CE 0 | h->t | | never(?) 269 | HTC_RAW_STREAMS | | | | 270 | (downlink) | | | | 271 ---------------------------------------------------------------------------- 272 diag | none (raw CE) | CE 7 | t<>h | 4 | Diag Window 273 | | | | | infrequent 274 ============================================================================ 275 */ 276 277 /* 278 * Map from service/endpoint to Copy Engine. 279 * This table is derived from the CE_PCI TABLE, above. 280 * It is passed to the Target at startup for use by firmware. 281 */ 282 static struct service_to_pipe target_service_to_ce_map_wlan[] = { 283 { 284 WMI_DATA_VO_SVC, 285 PIPEDIR_OUT, /* out = UL = host -> target */ 286 3, 287 }, 288 { 289 WMI_DATA_VO_SVC, 290 PIPEDIR_IN, /* in = DL = target -> host */ 291 2, 292 }, 293 { 294 WMI_DATA_BK_SVC, 295 PIPEDIR_OUT, /* out = UL = host -> target */ 296 3, 297 }, 298 { 299 WMI_DATA_BK_SVC, 300 PIPEDIR_IN, /* in = DL = target -> host */ 301 2, 302 }, 303 { 304 WMI_DATA_BE_SVC, 305 PIPEDIR_OUT, /* out = UL = host -> target */ 306 3, 307 }, 308 { 309 WMI_DATA_BE_SVC, 310 PIPEDIR_IN, /* in = DL = target -> host */ 311 2, 312 }, 313 { 314 WMI_DATA_VI_SVC, 315 PIPEDIR_OUT, /* out = UL = host -> target */ 316 3, 317 }, 318 { 319 WMI_DATA_VI_SVC, 320 PIPEDIR_IN, /* in = DL = target -> host */ 321 2, 322 }, 323 { 324 WMI_CONTROL_SVC, 325 PIPEDIR_OUT, /* out = UL = host -> target */ 326 3, 327 }, 328 { 329 WMI_CONTROL_SVC, 330 PIPEDIR_IN, /* in = DL = target -> host */ 331 2, 332 }, 333 { 334 HTC_CTRL_RSVD_SVC, 335 PIPEDIR_OUT, /* out = UL = host -> target */ 336 0, /* could be moved to 3 (share with WMI) */ 337 }, 338 { 339 HTC_CTRL_RSVD_SVC, 340 PIPEDIR_IN, /* in = DL = target -> host */ 341 2, 342 }, 343 { 344 HTC_RAW_STREAMS_SVC, /* not currently used */ 345 PIPEDIR_OUT, /* out = UL = host -> target */ 346 0, 347 }, 348 { 349 HTC_RAW_STREAMS_SVC, /* not currently used */ 350 PIPEDIR_IN, /* in = DL = target -> host */ 351 2, 352 }, 353 { 354 HTT_DATA_MSG_SVC, 355 PIPEDIR_OUT, /* out = UL = host -> target */ 356 4, 357 }, 358 { 359 HTT_DATA_MSG_SVC, 360 PIPEDIR_IN, /* in = DL = target -> host */ 361 1, 362 }, 363 { 364 WDI_IPA_TX_SVC, 365 PIPEDIR_OUT, /* in = DL = target -> host */ 366 5, 367 }, 368 #if defined(QCA_WIFI_3_0_ADRASTEA) 369 { 370 HTT_DATA2_MSG_SVC, 371 PIPEDIR_IN, /* in = DL = target -> host */ 372 9, 373 }, 374 { 375 HTT_DATA3_MSG_SVC, 376 PIPEDIR_IN, /* in = DL = target -> host */ 377 10, 378 }, 379 { 380 PACKET_LOG_SVC, 381 PIPEDIR_IN, /* in = DL = target -> host */ 382 11, 383 }, 384 #endif 385 /* (Additions here) */ 386 387 { /* Must be last */ 388 0, 389 0, 390 0, 391 }, 392 }; 393 394 /* PIPEDIR_OUT = HOST to Target */ 395 /* PIPEDIR_IN = TARGET to HOST */ 396 #if (defined(QCA_WIFI_QCA8074)) 397 static struct service_to_pipe target_service_to_ce_map_qca8074[] = { 398 { WMI_DATA_VO_SVC, PIPEDIR_OUT, 3, }, 399 { WMI_DATA_VO_SVC, PIPEDIR_IN, 2, }, 400 { WMI_DATA_BK_SVC, PIPEDIR_OUT, 3, }, 401 { WMI_DATA_BK_SVC, PIPEDIR_IN, 2, }, 402 { WMI_DATA_BE_SVC, PIPEDIR_OUT, 3, }, 403 { WMI_DATA_BE_SVC, PIPEDIR_IN, 2, }, 404 { WMI_DATA_VI_SVC, PIPEDIR_OUT, 3, }, 405 { WMI_DATA_VI_SVC, PIPEDIR_IN, 2, }, 406 { WMI_CONTROL_SVC, PIPEDIR_OUT, 3, }, 407 { WMI_CONTROL_SVC, PIPEDIR_IN, 2, }, 408 { WMI_CONTROL_SVC_WMAC1, PIPEDIR_OUT, 7}, 409 { WMI_CONTROL_SVC_WMAC1, PIPEDIR_IN, 2}, 410 { HTC_CTRL_RSVD_SVC, PIPEDIR_OUT, 0, }, 411 { HTC_CTRL_RSVD_SVC, PIPEDIR_IN, 1, }, 412 { HTC_RAW_STREAMS_SVC, PIPEDIR_OUT, 0}, 413 { HTC_RAW_STREAMS_SVC, PIPEDIR_IN, 1 }, 414 { HTT_DATA_MSG_SVC, PIPEDIR_OUT, 4, }, 415 { HTT_DATA_MSG_SVC, PIPEDIR_IN, 1, }, 416 { PACKET_LOG_SVC, PIPEDIR_IN, 5, }, 417 /* (Additions here) */ 418 { 0, 0, 0, }, 419 }; 420 #else 421 static struct service_to_pipe target_service_to_ce_map_qca8074[] = { 422 }; 423 #endif 424 425 /* PIPEDIR_OUT = HOST to Target */ 426 /* PIPEDIR_IN = TARGET to HOST */ 427 #ifdef QCN7605_SUPPORT 428 static struct service_to_pipe target_service_to_ce_map_qcn7605[] = { 429 { WMI_DATA_VO_SVC, PIPEDIR_OUT, 0, }, 430 { WMI_DATA_VO_SVC, PIPEDIR_IN, 2, }, 431 { WMI_DATA_BK_SVC, PIPEDIR_OUT, 0, }, 432 { WMI_DATA_BK_SVC, PIPEDIR_IN, 2, }, 433 { WMI_DATA_BE_SVC, PIPEDIR_OUT, 0, }, 434 { WMI_DATA_BE_SVC, PIPEDIR_IN, 2, }, 435 { WMI_DATA_VI_SVC, PIPEDIR_OUT, 0, }, 436 { WMI_DATA_VI_SVC, PIPEDIR_IN, 2, }, 437 { WMI_CONTROL_SVC, PIPEDIR_OUT, 0, }, 438 { WMI_CONTROL_SVC, PIPEDIR_IN, 2, }, 439 { HTC_CTRL_RSVD_SVC, PIPEDIR_OUT, 0, }, 440 { HTC_CTRL_RSVD_SVC, PIPEDIR_IN, 2, }, 441 { HTC_RAW_STREAMS_SVC, PIPEDIR_OUT, 0, }, 442 { HTC_RAW_STREAMS_SVC, PIPEDIR_IN, 2, }, 443 { HTT_DATA_MSG_SVC, PIPEDIR_OUT, 4, }, 444 { HTT_DATA_MSG_SVC, PIPEDIR_IN, 1, }, 445 { HTT_DATA2_MSG_SVC, PIPEDIR_IN, 3, }, 446 #ifdef IPA_OFFLOAD 447 { WDI_IPA_TX_SVC, PIPEDIR_OUT, 5, }, 448 #else 449 { HTT_DATA3_MSG_SVC, PIPEDIR_IN, 8, }, 450 #endif 451 { PACKET_LOG_SVC, PIPEDIR_IN, 7, }, 452 /* (Additions here) */ 453 { 0, 0, 0, }, 454 }; 455 #endif 456 457 #if (defined(QCA_WIFI_QCA6290)) 458 #ifdef CONFIG_WIN 459 static struct service_to_pipe target_service_to_ce_map_qca6290[] = { 460 { WMI_DATA_VO_SVC, PIPEDIR_OUT, 3, }, 461 { WMI_DATA_VO_SVC, PIPEDIR_IN , 2, }, 462 { WMI_DATA_BK_SVC, PIPEDIR_OUT, 3, }, 463 { WMI_DATA_BK_SVC, PIPEDIR_IN , 2, }, 464 { WMI_DATA_BE_SVC, PIPEDIR_OUT, 3, }, 465 { WMI_DATA_BE_SVC, PIPEDIR_IN , 2, }, 466 { WMI_DATA_VI_SVC, PIPEDIR_OUT, 3, }, 467 { WMI_DATA_VI_SVC, PIPEDIR_IN , 2, }, 468 { WMI_CONTROL_SVC, PIPEDIR_OUT, 3, }, 469 { WMI_CONTROL_SVC, PIPEDIR_IN , 2, }, 470 { HTC_CTRL_RSVD_SVC, PIPEDIR_OUT, 0, }, 471 { HTC_CTRL_RSVD_SVC, PIPEDIR_IN , 2, }, 472 { HTT_DATA_MSG_SVC, PIPEDIR_OUT, 4, }, 473 { HTT_DATA_MSG_SVC, PIPEDIR_IN , 1, }, 474 { WMI_CONTROL_SVC_WMAC1, PIPEDIR_OUT, 7}, 475 { WMI_CONTROL_SVC_WMAC1, PIPEDIR_IN, 2}, 476 { PACKET_LOG_SVC, PIPEDIR_IN, 5, }, 477 /* (Additions here) */ 478 { 0, 0, 0, }, 479 }; 480 #else 481 static struct service_to_pipe target_service_to_ce_map_qca6290[] = { 482 { WMI_DATA_VO_SVC, PIPEDIR_OUT, 3, }, 483 { WMI_DATA_VO_SVC, PIPEDIR_IN, 2, }, 484 { WMI_DATA_BK_SVC, PIPEDIR_OUT, 3, }, 485 { WMI_DATA_BK_SVC, PIPEDIR_IN, 2, }, 486 { WMI_DATA_BE_SVC, PIPEDIR_OUT, 3, }, 487 { WMI_DATA_BE_SVC, PIPEDIR_IN, 2, }, 488 { WMI_DATA_VI_SVC, PIPEDIR_OUT, 3, }, 489 { WMI_DATA_VI_SVC, PIPEDIR_IN, 2, }, 490 { WMI_CONTROL_SVC, PIPEDIR_OUT, 3, }, 491 { WMI_CONTROL_SVC, PIPEDIR_IN, 2, }, 492 { HTC_CTRL_RSVD_SVC, PIPEDIR_OUT, 0, }, 493 { HTC_CTRL_RSVD_SVC, PIPEDIR_IN, 2, }, 494 { HTT_DATA_MSG_SVC, PIPEDIR_OUT, 4, }, 495 { HTT_DATA_MSG_SVC, PIPEDIR_IN, 1, }, 496 /* (Additions here) */ 497 { 0, 0, 0, }, 498 }; 499 #endif 500 #else 501 static struct service_to_pipe target_service_to_ce_map_qca6290[] = { 502 }; 503 #endif 504 505 #if (defined(QCA_WIFI_QCA6390)) 506 static struct service_to_pipe target_service_to_ce_map_qca6390[] = { 507 { WMI_DATA_VO_SVC, PIPEDIR_OUT, 3, }, 508 { WMI_DATA_VO_SVC, PIPEDIR_IN, 2, }, 509 { WMI_DATA_BK_SVC, PIPEDIR_OUT, 3, }, 510 { WMI_DATA_BK_SVC, PIPEDIR_IN, 2, }, 511 { WMI_DATA_BE_SVC, PIPEDIR_OUT, 3, }, 512 { WMI_DATA_BE_SVC, PIPEDIR_IN, 2, }, 513 { WMI_DATA_VI_SVC, PIPEDIR_OUT, 3, }, 514 { WMI_DATA_VI_SVC, PIPEDIR_IN, 2, }, 515 { WMI_CONTROL_SVC, PIPEDIR_OUT, 3, }, 516 { WMI_CONTROL_SVC, PIPEDIR_IN, 2, }, 517 { HTC_CTRL_RSVD_SVC, PIPEDIR_OUT, 0, }, 518 { HTC_CTRL_RSVD_SVC, PIPEDIR_IN, 2, }, 519 { HTT_DATA_MSG_SVC, PIPEDIR_OUT, 4, }, 520 { HTT_DATA_MSG_SVC, PIPEDIR_IN, 1, }, 521 /* (Additions here) */ 522 { 0, 0, 0, }, 523 }; 524 #else 525 static struct service_to_pipe target_service_to_ce_map_qca6390[] = { 526 }; 527 #endif 528 529 static struct service_to_pipe target_service_to_ce_map_ar900b[] = { 530 { 531 WMI_DATA_VO_SVC, 532 PIPEDIR_OUT, /* out = UL = host -> target */ 533 3, 534 }, 535 { 536 WMI_DATA_VO_SVC, 537 PIPEDIR_IN, /* in = DL = target -> host */ 538 2, 539 }, 540 { 541 WMI_DATA_BK_SVC, 542 PIPEDIR_OUT, /* out = UL = host -> target */ 543 3, 544 }, 545 { 546 WMI_DATA_BK_SVC, 547 PIPEDIR_IN, /* in = DL = target -> host */ 548 2, 549 }, 550 { 551 WMI_DATA_BE_SVC, 552 PIPEDIR_OUT, /* out = UL = host -> target */ 553 3, 554 }, 555 { 556 WMI_DATA_BE_SVC, 557 PIPEDIR_IN, /* in = DL = target -> host */ 558 2, 559 }, 560 { 561 WMI_DATA_VI_SVC, 562 PIPEDIR_OUT, /* out = UL = host -> target */ 563 3, 564 }, 565 { 566 WMI_DATA_VI_SVC, 567 PIPEDIR_IN, /* in = DL = target -> host */ 568 2, 569 }, 570 { 571 WMI_CONTROL_SVC, 572 PIPEDIR_OUT, /* out = UL = host -> target */ 573 3, 574 }, 575 { 576 WMI_CONTROL_SVC, 577 PIPEDIR_IN, /* in = DL = target -> host */ 578 2, 579 }, 580 { 581 HTC_CTRL_RSVD_SVC, 582 PIPEDIR_OUT, /* out = UL = host -> target */ 583 0, /* could be moved to 3 (share with WMI) */ 584 }, 585 { 586 HTC_CTRL_RSVD_SVC, 587 PIPEDIR_IN, /* in = DL = target -> host */ 588 1, 589 }, 590 { 591 HTC_RAW_STREAMS_SVC, /* not currently used */ 592 PIPEDIR_OUT, /* out = UL = host -> target */ 593 0, 594 }, 595 { 596 HTC_RAW_STREAMS_SVC, /* not currently used */ 597 PIPEDIR_IN, /* in = DL = target -> host */ 598 1, 599 }, 600 { 601 HTT_DATA_MSG_SVC, 602 PIPEDIR_OUT, /* out = UL = host -> target */ 603 4, 604 }, 605 #ifdef WLAN_FEATURE_FASTPATH 606 { 607 HTT_DATA_MSG_SVC, 608 PIPEDIR_IN, /* in = DL = target -> host */ 609 5, 610 }, 611 #else /* WLAN_FEATURE_FASTPATH */ 612 { 613 HTT_DATA_MSG_SVC, 614 PIPEDIR_IN, /* in = DL = target -> host */ 615 1, 616 }, 617 #endif /* WLAN_FEATURE_FASTPATH */ 618 619 /* (Additions here) */ 620 621 { /* Must be last */ 622 0, 623 0, 624 0, 625 }, 626 }; 627 628 static struct shadow_reg_cfg *target_shadow_reg_cfg = target_shadow_reg_cfg_map; 629 static int shadow_cfg_sz = sizeof(target_shadow_reg_cfg_map); 630 631 #ifdef WLAN_FEATURE_EPPING 632 static struct service_to_pipe target_service_to_ce_map_wlan_epping[] = { 633 {WMI_DATA_VO_SVC, PIPEDIR_OUT, 3,}, /* out = UL = host -> target */ 634 {WMI_DATA_VO_SVC, PIPEDIR_IN, 2,}, /* in = DL = target -> host */ 635 {WMI_DATA_BK_SVC, PIPEDIR_OUT, 4,}, /* out = UL = host -> target */ 636 {WMI_DATA_BK_SVC, PIPEDIR_IN, 1,}, /* in = DL = target -> host */ 637 {WMI_DATA_BE_SVC, PIPEDIR_OUT, 3,}, /* out = UL = host -> target */ 638 {WMI_DATA_BE_SVC, PIPEDIR_IN, 2,}, /* in = DL = target -> host */ 639 {WMI_DATA_VI_SVC, PIPEDIR_OUT, 3,}, /* out = UL = host -> target */ 640 {WMI_DATA_VI_SVC, PIPEDIR_IN, 2,}, /* in = DL = target -> host */ 641 {WMI_CONTROL_SVC, PIPEDIR_OUT, 3,}, /* out = UL = host -> target */ 642 {WMI_CONTROL_SVC, PIPEDIR_IN, 2,}, /* in = DL = target -> host */ 643 {HTC_CTRL_RSVD_SVC, PIPEDIR_OUT, 0,}, /* out = UL = host -> target */ 644 {HTC_CTRL_RSVD_SVC, PIPEDIR_IN, 2,}, /* in = DL = target -> host */ 645 {HTC_RAW_STREAMS_SVC, PIPEDIR_OUT, 0,}, /* out = UL = host -> target */ 646 {HTC_RAW_STREAMS_SVC, PIPEDIR_IN, 2,}, /* in = DL = target -> host */ 647 {HTT_DATA_MSG_SVC, PIPEDIR_OUT, 4,}, /* out = UL = host -> target */ 648 {HTT_DATA_MSG_SVC, PIPEDIR_IN, 1,}, /* in = DL = target -> host */ 649 {0, 0, 0,}, /* Must be last */ 650 }; 651 652 void hif_select_epping_service_to_pipe_map(struct service_to_pipe 653 **tgt_svc_map_to_use, 654 uint32_t *sz_tgt_svc_map_to_use) 655 { 656 *tgt_svc_map_to_use = target_service_to_ce_map_wlan_epping; 657 *sz_tgt_svc_map_to_use = 658 sizeof(target_service_to_ce_map_wlan_epping); 659 } 660 #endif 661 662 #ifdef QCN7605_SUPPORT 663 static inline 664 void hif_select_ce_map_qcn7605(struct service_to_pipe **tgt_svc_map_to_use, 665 uint32_t *sz_tgt_svc_map_to_use) 666 { 667 *tgt_svc_map_to_use = target_service_to_ce_map_qcn7605; 668 *sz_tgt_svc_map_to_use = sizeof(target_service_to_ce_map_qcn7605); 669 } 670 #else 671 static inline 672 void hif_select_ce_map_qcn7605(struct service_to_pipe **tgt_svc_map_to_use, 673 uint32_t *sz_tgt_svc_map_to_use) 674 { 675 HIF_ERROR("%s: QCN7605 not supported", __func__); 676 } 677 #endif 678 679 static void hif_select_service_to_pipe_map(struct hif_softc *scn, 680 struct service_to_pipe **tgt_svc_map_to_use, 681 uint32_t *sz_tgt_svc_map_to_use) 682 { 683 uint32_t mode = hif_get_conparam(scn); 684 struct hif_target_info *tgt_info = &scn->target_info; 685 686 if (QDF_IS_EPPING_ENABLED(mode)) { 687 hif_select_epping_service_to_pipe_map(tgt_svc_map_to_use, 688 sz_tgt_svc_map_to_use); 689 } else { 690 switch (tgt_info->target_type) { 691 default: 692 *tgt_svc_map_to_use = target_service_to_ce_map_wlan; 693 *sz_tgt_svc_map_to_use = 694 sizeof(target_service_to_ce_map_wlan); 695 break; 696 case TARGET_TYPE_QCN7605: 697 hif_select_ce_map_qcn7605(tgt_svc_map_to_use, 698 sz_tgt_svc_map_to_use); 699 break; 700 case TARGET_TYPE_AR900B: 701 case TARGET_TYPE_QCA9984: 702 case TARGET_TYPE_IPQ4019: 703 case TARGET_TYPE_QCA9888: 704 case TARGET_TYPE_AR9888: 705 case TARGET_TYPE_AR9888V2: 706 *tgt_svc_map_to_use = target_service_to_ce_map_ar900b; 707 *sz_tgt_svc_map_to_use = 708 sizeof(target_service_to_ce_map_ar900b); 709 break; 710 case TARGET_TYPE_QCA6290: 711 *tgt_svc_map_to_use = target_service_to_ce_map_qca6290; 712 *sz_tgt_svc_map_to_use = 713 sizeof(target_service_to_ce_map_qca6290); 714 break; 715 case TARGET_TYPE_QCA6390: 716 *tgt_svc_map_to_use = target_service_to_ce_map_qca6390; 717 *sz_tgt_svc_map_to_use = 718 sizeof(target_service_to_ce_map_qca6390); 719 break; 720 case TARGET_TYPE_QCA8074: 721 case TARGET_TYPE_QCA8074V2: 722 *tgt_svc_map_to_use = target_service_to_ce_map_qca8074; 723 *sz_tgt_svc_map_to_use = 724 sizeof(target_service_to_ce_map_qca8074); 725 break; 726 } 727 } 728 } 729 730 /** 731 * ce_mark_datapath() - marks the ce_state->htt_rx_data accordingly 732 * @ce_state : pointer to the state context of the CE 733 * 734 * Description: 735 * Sets htt_rx_data attribute of the state structure if the 736 * CE serves one of the HTT DATA services. 737 * 738 * Return: 739 * false (attribute set to false) 740 * true (attribute set to true); 741 */ 742 static bool ce_mark_datapath(struct CE_state *ce_state) 743 { 744 struct service_to_pipe *svc_map; 745 uint32_t map_sz, map_len; 746 int i; 747 bool rc = false; 748 749 if (ce_state != NULL) { 750 hif_select_service_to_pipe_map(ce_state->scn, &svc_map, 751 &map_sz); 752 753 map_len = map_sz / sizeof(struct service_to_pipe); 754 for (i = 0; i < map_len; i++) { 755 if ((svc_map[i].pipenum == ce_state->id) && 756 ((svc_map[i].service_id == HTT_DATA_MSG_SVC) || 757 (svc_map[i].service_id == HTT_DATA2_MSG_SVC) || 758 (svc_map[i].service_id == HTT_DATA3_MSG_SVC))) { 759 /* HTT CEs are unidirectional */ 760 if (svc_map[i].pipedir == PIPEDIR_IN) 761 ce_state->htt_rx_data = true; 762 else 763 ce_state->htt_tx_data = true; 764 rc = true; 765 } 766 } 767 } 768 return rc; 769 } 770 771 /** 772 * ce_ring_test_initial_indexes() - tests the initial ce ring indexes 773 * @ce_id: ce in question 774 * @ring: ring state being examined 775 * @type: "src_ring" or "dest_ring" string for identifying the ring 776 * 777 * Warns on non-zero index values. 778 * Causes a kernel panic if the ring is not empty durring initialization. 779 */ 780 static void ce_ring_test_initial_indexes(int ce_id, struct CE_ring_state *ring, 781 char *type) 782 { 783 if (ring->write_index != 0 || ring->sw_index != 0) 784 HIF_ERROR("ce %d, %s, initial sw_index = %d, initial write_index =%d", 785 ce_id, type, ring->sw_index, ring->write_index); 786 if (ring->write_index != ring->sw_index) 787 QDF_BUG(0); 788 } 789 790 #ifdef IPA_OFFLOAD 791 /** 792 * ce_alloc_desc_ring() - Allocate copyengine descriptor ring 793 * @scn: softc instance 794 * @ce_id: ce in question 795 * @base_addr: pointer to copyengine ring base address 796 * @ce_ring: copyengine instance 797 * @nentries: number of entries should be allocated 798 * @desc_size: ce desc size 799 * 800 * Return: QDF_STATUS_SUCCESS - for success 801 */ 802 static QDF_STATUS ce_alloc_desc_ring(struct hif_softc *scn, unsigned int CE_id, 803 qdf_dma_addr_t *base_addr, 804 struct CE_ring_state *ce_ring, 805 unsigned int nentries, uint32_t desc_size) 806 { 807 if (CE_id == HIF_PCI_IPA_UC_ASSIGNED_CE) { 808 scn->ipa_ce_ring = qdf_mem_shared_mem_alloc(scn->qdf_dev, 809 nentries * desc_size + CE_DESC_RING_ALIGN); 810 if (!scn->ipa_ce_ring) { 811 HIF_ERROR("%s: Failed to allocate memory for IPA ce ring", 812 __func__); 813 return QDF_STATUS_E_NOMEM; 814 } 815 *base_addr = qdf_mem_get_dma_addr(scn->qdf_dev, 816 &scn->ipa_ce_ring->mem_info); 817 ce_ring->base_addr_owner_space_unaligned = 818 scn->ipa_ce_ring->vaddr; 819 } else { 820 ce_ring->base_addr_owner_space_unaligned = 821 qdf_mem_alloc_consistent(scn->qdf_dev, 822 scn->qdf_dev->dev, 823 (nentries * desc_size + 824 CE_DESC_RING_ALIGN), 825 base_addr); 826 if (!ce_ring->base_addr_owner_space_unaligned) { 827 HIF_ERROR("%s: Failed to allocate DMA memory for ce ring id : %u", 828 __func__, CE_id); 829 return QDF_STATUS_E_NOMEM; 830 } 831 } 832 return QDF_STATUS_SUCCESS; 833 } 834 835 /** 836 * ce_free_desc_ring() - Frees copyengine descriptor ring 837 * @scn: softc instance 838 * @ce_id: ce in question 839 * @ce_ring: copyengine instance 840 * @desc_size: ce desc size 841 * 842 * Return: None 843 */ 844 static void ce_free_desc_ring(struct hif_softc *scn, unsigned int CE_id, 845 struct CE_ring_state *ce_ring, uint32_t desc_size) 846 { 847 if (CE_id == HIF_PCI_IPA_UC_ASSIGNED_CE) { 848 qdf_mem_shared_mem_free(scn->qdf_dev, 849 scn->ipa_ce_ring); 850 ce_ring->base_addr_owner_space_unaligned = NULL; 851 } else { 852 qdf_mem_free_consistent(scn->qdf_dev, scn->qdf_dev->dev, 853 ce_ring->nentries * desc_size + CE_DESC_RING_ALIGN, 854 ce_ring->base_addr_owner_space_unaligned, 855 ce_ring->base_addr_CE_space, 0); 856 ce_ring->base_addr_owner_space_unaligned = NULL; 857 } 858 } 859 #else 860 static QDF_STATUS ce_alloc_desc_ring(struct hif_softc *scn, unsigned int CE_id, 861 qdf_dma_addr_t *base_addr, 862 struct CE_ring_state *ce_ring, 863 unsigned int nentries, uint32_t desc_size) 864 { 865 ce_ring->base_addr_owner_space_unaligned = 866 qdf_mem_alloc_consistent(scn->qdf_dev, scn->qdf_dev->dev, 867 (nentries * desc_size + 868 CE_DESC_RING_ALIGN), base_addr); 869 if (!ce_ring->base_addr_owner_space_unaligned) { 870 HIF_ERROR("%s: Failed to allocate DMA memory for ce ring id : %u", 871 __func__, CE_id); 872 return QDF_STATUS_E_NOMEM; 873 } 874 return QDF_STATUS_SUCCESS; 875 } 876 877 static void ce_free_desc_ring(struct hif_softc *scn, unsigned int CE_id, 878 struct CE_ring_state *ce_ring, uint32_t desc_size) 879 { 880 qdf_mem_free_consistent(scn->qdf_dev, scn->qdf_dev->dev, 881 ce_ring->nentries * desc_size + CE_DESC_RING_ALIGN, 882 ce_ring->base_addr_owner_space_unaligned, 883 ce_ring->base_addr_CE_space, 0); 884 ce_ring->base_addr_owner_space_unaligned = NULL; 885 } 886 #endif /* IPA_OFFLOAD */ 887 888 /** 889 * ce_srng_based() - Does this target use srng 890 * @ce_state : pointer to the state context of the CE 891 * 892 * Description: 893 * returns true if the target is SRNG based 894 * 895 * Return: 896 * false (attribute set to false) 897 * true (attribute set to true); 898 */ 899 bool ce_srng_based(struct hif_softc *scn) 900 { 901 struct hif_opaque_softc *hif_hdl = GET_HIF_OPAQUE_HDL(scn); 902 struct hif_target_info *tgt_info = hif_get_target_info_handle(hif_hdl); 903 904 switch (tgt_info->target_type) { 905 case TARGET_TYPE_QCA8074: 906 case TARGET_TYPE_QCA8074V2: 907 case TARGET_TYPE_QCA6290: 908 case TARGET_TYPE_QCA6390: 909 return true; 910 default: 911 return false; 912 } 913 return false; 914 } 915 qdf_export_symbol(ce_srng_based); 916 917 #ifdef QCA_WIFI_SUPPORT_SRNG 918 static struct ce_ops *ce_services_attach(struct hif_softc *scn) 919 { 920 if (ce_srng_based(scn)) 921 return ce_services_srng(); 922 923 return ce_services_legacy(); 924 } 925 926 927 #else /* QCA_LITHIUM */ 928 static struct ce_ops *ce_services_attach(struct hif_softc *scn) 929 { 930 return ce_services_legacy(); 931 } 932 #endif /* QCA_LITHIUM */ 933 934 static void hif_prepare_hal_shadow_register_cfg(struct hif_softc *scn, 935 struct pld_shadow_reg_v2_cfg **shadow_config, 936 int *num_shadow_registers_configured) { 937 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 938 939 return hif_state->ce_services->ce_prepare_shadow_register_v2_cfg( 940 scn, shadow_config, num_shadow_registers_configured); 941 } 942 943 static inline uint32_t ce_get_desc_size(struct hif_softc *scn, 944 uint8_t ring_type) 945 { 946 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 947 948 return hif_state->ce_services->ce_get_desc_size(ring_type); 949 } 950 951 952 static struct CE_ring_state *ce_alloc_ring_state(struct CE_state *CE_state, 953 uint8_t ring_type, uint32_t nentries) 954 { 955 uint32_t ce_nbytes; 956 char *ptr; 957 qdf_dma_addr_t base_addr; 958 struct CE_ring_state *ce_ring; 959 uint32_t desc_size; 960 struct hif_softc *scn = CE_state->scn; 961 962 ce_nbytes = sizeof(struct CE_ring_state) 963 + (nentries * sizeof(void *)); 964 ptr = qdf_mem_malloc(ce_nbytes); 965 if (!ptr) 966 return NULL; 967 968 ce_ring = (struct CE_ring_state *)ptr; 969 ptr += sizeof(struct CE_ring_state); 970 ce_ring->nentries = nentries; 971 ce_ring->nentries_mask = nentries - 1; 972 973 ce_ring->low_water_mark_nentries = 0; 974 ce_ring->high_water_mark_nentries = nentries; 975 ce_ring->per_transfer_context = (void **)ptr; 976 977 desc_size = ce_get_desc_size(scn, ring_type); 978 979 /* Legacy platforms that do not support cache 980 * coherent DMA are unsupported 981 */ 982 if (ce_alloc_desc_ring(scn, CE_state->id, &base_addr, 983 ce_ring, nentries, 984 desc_size) != 985 QDF_STATUS_SUCCESS) { 986 HIF_ERROR("%s: ring has no DMA mem", 987 __func__); 988 qdf_mem_free(ptr); 989 return NULL; 990 } 991 ce_ring->base_addr_CE_space_unaligned = base_addr; 992 993 /* Correctly initialize memory to 0 to 994 * prevent garbage data crashing system 995 * when download firmware 996 */ 997 qdf_mem_zero(ce_ring->base_addr_owner_space_unaligned, 998 nentries * desc_size + 999 CE_DESC_RING_ALIGN); 1000 1001 if (ce_ring->base_addr_CE_space_unaligned & (CE_DESC_RING_ALIGN - 1)) { 1002 1003 ce_ring->base_addr_CE_space = 1004 (ce_ring->base_addr_CE_space_unaligned + 1005 CE_DESC_RING_ALIGN - 1) & ~(CE_DESC_RING_ALIGN - 1); 1006 1007 ce_ring->base_addr_owner_space = (void *) 1008 (((size_t) ce_ring->base_addr_owner_space_unaligned + 1009 CE_DESC_RING_ALIGN - 1) & ~(CE_DESC_RING_ALIGN - 1)); 1010 } else { 1011 ce_ring->base_addr_CE_space = 1012 ce_ring->base_addr_CE_space_unaligned; 1013 ce_ring->base_addr_owner_space = 1014 ce_ring->base_addr_owner_space_unaligned; 1015 } 1016 1017 return ce_ring; 1018 } 1019 1020 static int ce_ring_setup(struct hif_softc *scn, uint8_t ring_type, 1021 uint32_t ce_id, struct CE_ring_state *ring, 1022 struct CE_attr *attr) 1023 { 1024 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 1025 1026 return hif_state->ce_services->ce_ring_setup(scn, ring_type, ce_id, 1027 ring, attr); 1028 } 1029 1030 int hif_ce_bus_early_suspend(struct hif_softc *scn) 1031 { 1032 uint8_t ul_pipe, dl_pipe; 1033 int ce_id, status, ul_is_polled, dl_is_polled; 1034 struct CE_state *ce_state; 1035 1036 status = hif_map_service_to_pipe(&scn->osc, WMI_CONTROL_SVC, 1037 &ul_pipe, &dl_pipe, 1038 &ul_is_polled, &dl_is_polled); 1039 if (status) { 1040 HIF_ERROR("%s: pipe_mapping failure", __func__); 1041 return status; 1042 } 1043 1044 for (ce_id = 0; ce_id < scn->ce_count; ce_id++) { 1045 if (ce_id == ul_pipe) 1046 continue; 1047 if (ce_id == dl_pipe) 1048 continue; 1049 1050 ce_state = scn->ce_id_to_state[ce_id]; 1051 qdf_spin_lock_bh(&ce_state->ce_index_lock); 1052 if (ce_state->state == CE_RUNNING) 1053 ce_state->state = CE_PAUSED; 1054 qdf_spin_unlock_bh(&ce_state->ce_index_lock); 1055 } 1056 1057 return status; 1058 } 1059 1060 int hif_ce_bus_late_resume(struct hif_softc *scn) 1061 { 1062 int ce_id; 1063 struct CE_state *ce_state; 1064 int write_index; 1065 bool index_updated; 1066 1067 for (ce_id = 0; ce_id < scn->ce_count; ce_id++) { 1068 ce_state = scn->ce_id_to_state[ce_id]; 1069 qdf_spin_lock_bh(&ce_state->ce_index_lock); 1070 if (ce_state->state == CE_PENDING) { 1071 write_index = ce_state->src_ring->write_index; 1072 CE_SRC_RING_WRITE_IDX_SET(scn, ce_state->ctrl_addr, 1073 write_index); 1074 ce_state->state = CE_RUNNING; 1075 index_updated = true; 1076 } else { 1077 index_updated = false; 1078 } 1079 1080 if (ce_state->state == CE_PAUSED) 1081 ce_state->state = CE_RUNNING; 1082 qdf_spin_unlock_bh(&ce_state->ce_index_lock); 1083 1084 if (index_updated) 1085 hif_record_ce_desc_event(scn, ce_id, 1086 RESUME_WRITE_INDEX_UPDATE, 1087 NULL, NULL, write_index, 0); 1088 } 1089 1090 return 0; 1091 } 1092 1093 /** 1094 * ce_oom_recovery() - try to recover rx ce from oom condition 1095 * @context: CE_state of the CE with oom rx ring 1096 * 1097 * the executing work Will continue to be rescheduled until 1098 * at least 1 descriptor is successfully posted to the rx ring. 1099 * 1100 * return: none 1101 */ 1102 static void ce_oom_recovery(void *context) 1103 { 1104 struct CE_state *ce_state = context; 1105 struct hif_softc *scn = ce_state->scn; 1106 struct HIF_CE_state *ce_softc = HIF_GET_CE_STATE(scn); 1107 struct HIF_CE_pipe_info *pipe_info = 1108 &ce_softc->pipe_info[ce_state->id]; 1109 1110 hif_post_recv_buffers_for_pipe(pipe_info); 1111 } 1112 1113 #if HIF_CE_DEBUG_DATA_BUF 1114 /** 1115 * alloc_mem_ce_debug_hist_data() - Allocate mem for the data pointed by 1116 * the CE descriptors. 1117 * Allocate HIF_CE_HISTORY_MAX records by CE_DEBUG_MAX_DATA_BUF_SIZE 1118 * @scn: hif scn handle 1119 * ce_id: Copy Engine Id 1120 * 1121 * Return: QDF_STATUS 1122 */ 1123 QDF_STATUS alloc_mem_ce_debug_hist_data(struct hif_softc *scn, uint32_t ce_id) 1124 { 1125 struct hif_ce_desc_event *event = NULL; 1126 struct hif_ce_desc_event *hist_ev = NULL; 1127 uint32_t index = 0; 1128 1129 hist_ev = 1130 (struct hif_ce_desc_event *)scn->hif_ce_desc_hist.hist_ev[ce_id]; 1131 1132 if (!hist_ev) 1133 return QDF_STATUS_E_NOMEM; 1134 1135 for (index = 0; index < HIF_CE_HISTORY_MAX; index++) { 1136 event = &hist_ev[index]; 1137 event->data = 1138 (uint8_t *)qdf_mem_malloc(CE_DEBUG_MAX_DATA_BUF_SIZE); 1139 if (event->data == NULL) 1140 return QDF_STATUS_E_NOMEM; 1141 } 1142 return QDF_STATUS_SUCCESS; 1143 } 1144 1145 /** 1146 * free_mem_ce_debug_hist_data() - Free mem of the data pointed by 1147 * the CE descriptors. 1148 * @scn: hif scn handle 1149 * ce_id: Copy Engine Id 1150 * 1151 * Return: 1152 */ 1153 void free_mem_ce_debug_hist_data(struct hif_softc *scn, uint32_t ce_id) 1154 { 1155 struct hif_ce_desc_event *event = NULL; 1156 struct hif_ce_desc_event *hist_ev = NULL; 1157 uint32_t index = 0; 1158 1159 hist_ev = 1160 (struct hif_ce_desc_event *)scn->hif_ce_desc_hist.hist_ev[ce_id]; 1161 1162 if (!hist_ev) 1163 return; 1164 1165 for (index = 0; index < HIF_CE_HISTORY_MAX; index++) { 1166 event = &hist_ev[index]; 1167 if (event->data != NULL) 1168 qdf_mem_free(event->data); 1169 event->data = NULL; 1170 event = NULL; 1171 } 1172 } 1173 #endif /* HIF_CE_DEBUG_DATA_BUF */ 1174 1175 /* 1176 * Note: For MCL, #if defined (HIF_CONFIG_SLUB_DEBUG_ON) needs to be checked 1177 * for defined here 1178 */ 1179 #if HIF_CE_DEBUG_DATA_BUF 1180 /** 1181 * alloc_mem_ce_debug_history() - Allocate mem for the CE descriptors storing 1182 * @scn: hif scn handle 1183 * ce_id: Copy Engine Id 1184 * 1185 * Return: QDF_STATUS 1186 */ 1187 static inline QDF_STATUS alloc_mem_ce_debug_history(struct hif_softc *scn, 1188 unsigned int CE_id) 1189 { 1190 scn->hif_ce_desc_hist.hist_ev[CE_id] = (struct hif_ce_desc_event *) 1191 qdf_mem_malloc(HIF_CE_HISTORY_MAX * sizeof(struct hif_ce_desc_event)); 1192 1193 if (scn->hif_ce_desc_hist.hist_ev[CE_id] == NULL) { 1194 scn->hif_ce_desc_hist.enable[CE_id] = 0; 1195 return QDF_STATUS_E_NOMEM; 1196 } else { 1197 scn->hif_ce_desc_hist.enable[CE_id] = 1; 1198 return QDF_STATUS_SUCCESS; 1199 } 1200 } 1201 1202 /** 1203 * free_mem_ce_debug_history() - Free mem allocated for the CE descriptors 1204 * storing. 1205 * @scn: hif scn handle 1206 * ce_id: Copy Engine Id 1207 * 1208 * Return: 1209 */ 1210 static inline void free_mem_ce_debug_history(struct hif_softc *scn, 1211 unsigned int CE_id) 1212 { 1213 struct ce_desc_hist *ce_hist = &scn->hif_ce_desc_hist; 1214 struct hif_ce_desc_event *hist_ev = 1215 (struct hif_ce_desc_event *)ce_hist->hist_ev[CE_id]; 1216 1217 if (!hist_ev) 1218 return; 1219 1220 #if HIF_CE_DEBUG_DATA_BUF 1221 if (ce_hist->data_enable[CE_id] == 1) { 1222 ce_hist->data_enable[CE_id] = 0; 1223 free_mem_ce_debug_hist_data(scn, CE_id); 1224 } 1225 #endif 1226 ce_hist->enable[CE_id] = 0; 1227 qdf_mem_free(ce_hist->hist_ev[CE_id]); 1228 ce_hist->hist_ev[CE_id] = NULL; 1229 } 1230 1231 /** 1232 * reset_ce_debug_history() - reset the index and ce id used for dumping the 1233 * CE records on the console using sysfs. 1234 * @scn: hif scn handle 1235 * 1236 * Return: 1237 */ 1238 static inline void reset_ce_debug_history(struct hif_softc *scn) 1239 { 1240 struct ce_desc_hist *ce_hist = &scn->hif_ce_desc_hist; 1241 /* Initialise the CE debug history sysfs interface inputs ce_id and 1242 * index. Disable data storing 1243 */ 1244 ce_hist->hist_index = 0; 1245 ce_hist->hist_id = 0; 1246 } 1247 #else /*Note: #if defined(HIF_CONFIG_SLUB_DEBUG_ON) || HIF_CE_DEBUG_DATA_BUF */ 1248 static inline QDF_STATUS alloc_mem_ce_debug_history(struct hif_softc *scn, 1249 unsigned int CE_id) 1250 { 1251 return QDF_STATUS_SUCCESS; 1252 } 1253 1254 static inline void free_mem_ce_debug_history(struct hif_softc *scn, 1255 unsigned int CE_id) 1256 { 1257 } 1258 1259 static inline void reset_ce_debug_history(struct hif_softc *scn) 1260 { 1261 } 1262 #endif /*Note: defined(HIF_CONFIG_SLUB_DEBUG_ON) || HIF_CE_DEBUG_DATA_BUF */ 1263 1264 void ce_enable_polling(void *cestate) 1265 { 1266 struct CE_state *CE_state = (struct CE_state *)cestate; 1267 1268 if (CE_state && CE_state->attr_flags & CE_ATTR_ENABLE_POLL) 1269 CE_state->timer_inited = true; 1270 } 1271 1272 void ce_disable_polling(void *cestate) 1273 { 1274 struct CE_state *CE_state = (struct CE_state *)cestate; 1275 1276 if (CE_state && CE_state->attr_flags & CE_ATTR_ENABLE_POLL) 1277 CE_state->timer_inited = false; 1278 } 1279 1280 /* 1281 * Initialize a Copy Engine based on caller-supplied attributes. 1282 * This may be called once to initialize both source and destination 1283 * rings or it may be called twice for separate source and destination 1284 * initialization. It may be that only one side or the other is 1285 * initialized by software/firmware. 1286 * 1287 * This should be called durring the initialization sequence before 1288 * interupts are enabled, so we don't have to worry about thread safety. 1289 */ 1290 struct CE_handle *ce_init(struct hif_softc *scn, 1291 unsigned int CE_id, struct CE_attr *attr) 1292 { 1293 struct CE_state *CE_state; 1294 uint32_t ctrl_addr; 1295 unsigned int nentries; 1296 bool malloc_CE_state = false; 1297 bool malloc_src_ring = false; 1298 int status; 1299 1300 QDF_ASSERT(CE_id < scn->ce_count); 1301 ctrl_addr = CE_BASE_ADDRESS(CE_id); 1302 CE_state = scn->ce_id_to_state[CE_id]; 1303 1304 if (!CE_state) { 1305 CE_state = 1306 (struct CE_state *)qdf_mem_malloc(sizeof(*CE_state)); 1307 if (!CE_state) { 1308 HIF_ERROR("%s: CE_state has no mem", __func__); 1309 return NULL; 1310 } 1311 malloc_CE_state = true; 1312 qdf_spinlock_create(&CE_state->ce_index_lock); 1313 1314 CE_state->id = CE_id; 1315 CE_state->ctrl_addr = ctrl_addr; 1316 CE_state->state = CE_RUNNING; 1317 CE_state->attr_flags = attr->flags; 1318 } 1319 CE_state->scn = scn; 1320 1321 qdf_atomic_init(&CE_state->rx_pending); 1322 if (attr == NULL) { 1323 /* Already initialized; caller wants the handle */ 1324 return (struct CE_handle *)CE_state; 1325 } 1326 1327 if (CE_state->src_sz_max) 1328 QDF_ASSERT(CE_state->src_sz_max == attr->src_sz_max); 1329 else 1330 CE_state->src_sz_max = attr->src_sz_max; 1331 1332 ce_init_ce_desc_event_log(scn, CE_id, 1333 attr->src_nentries + attr->dest_nentries); 1334 1335 /* source ring setup */ 1336 nentries = attr->src_nentries; 1337 if (nentries) { 1338 struct CE_ring_state *src_ring; 1339 1340 nentries = roundup_pwr2(nentries); 1341 if (CE_state->src_ring) { 1342 QDF_ASSERT(CE_state->src_ring->nentries == nentries); 1343 } else { 1344 src_ring = CE_state->src_ring = 1345 ce_alloc_ring_state(CE_state, 1346 CE_RING_SRC, 1347 nentries); 1348 if (!src_ring) { 1349 /* cannot allocate src ring. If the 1350 * CE_state is allocated locally free 1351 * CE_State and return error. 1352 */ 1353 HIF_ERROR("%s: src ring has no mem", __func__); 1354 if (malloc_CE_state) { 1355 /* allocated CE_state locally */ 1356 qdf_mem_free(CE_state); 1357 malloc_CE_state = false; 1358 } 1359 return NULL; 1360 } 1361 /* we can allocate src ring. Mark that the src ring is 1362 * allocated locally 1363 */ 1364 malloc_src_ring = true; 1365 1366 /* 1367 * Also allocate a shadow src ring in 1368 * regular mem to use for faster access. 1369 */ 1370 src_ring->shadow_base_unaligned = 1371 qdf_mem_malloc(nentries * 1372 sizeof(struct CE_src_desc) + 1373 CE_DESC_RING_ALIGN); 1374 if (src_ring->shadow_base_unaligned == NULL) { 1375 HIF_ERROR("%s: src ring no shadow_base mem", 1376 __func__); 1377 goto error_no_dma_mem; 1378 } 1379 src_ring->shadow_base = (struct CE_src_desc *) 1380 (((size_t) src_ring->shadow_base_unaligned + 1381 CE_DESC_RING_ALIGN - 1) & 1382 ~(CE_DESC_RING_ALIGN - 1)); 1383 1384 status = ce_ring_setup(scn, CE_RING_SRC, CE_id, 1385 src_ring, attr); 1386 if (status < 0) 1387 goto error_target_access; 1388 1389 ce_ring_test_initial_indexes(CE_id, src_ring, 1390 "src_ring"); 1391 } 1392 } 1393 1394 /* destination ring setup */ 1395 nentries = attr->dest_nentries; 1396 if (nentries) { 1397 struct CE_ring_state *dest_ring; 1398 1399 nentries = roundup_pwr2(nentries); 1400 if (CE_state->dest_ring) { 1401 QDF_ASSERT(CE_state->dest_ring->nentries == nentries); 1402 } else { 1403 dest_ring = CE_state->dest_ring = 1404 ce_alloc_ring_state(CE_state, 1405 CE_RING_DEST, 1406 nentries); 1407 if (!dest_ring) { 1408 /* cannot allocate dst ring. If the CE_state 1409 * or src ring is allocated locally free 1410 * CE_State and src ring and return error. 1411 */ 1412 HIF_ERROR("%s: dest ring has no mem", 1413 __func__); 1414 goto error_no_dma_mem; 1415 } 1416 1417 status = ce_ring_setup(scn, CE_RING_DEST, CE_id, 1418 dest_ring, attr); 1419 if (status < 0) 1420 goto error_target_access; 1421 1422 ce_ring_test_initial_indexes(CE_id, dest_ring, 1423 "dest_ring"); 1424 1425 /* For srng based target, init status ring here */ 1426 if (ce_srng_based(CE_state->scn)) { 1427 CE_state->status_ring = 1428 ce_alloc_ring_state(CE_state, 1429 CE_RING_STATUS, 1430 nentries); 1431 if (CE_state->status_ring == NULL) { 1432 /*Allocation failed. Cleanup*/ 1433 qdf_mem_free(CE_state->dest_ring); 1434 if (malloc_src_ring) { 1435 qdf_mem_free 1436 (CE_state->src_ring); 1437 CE_state->src_ring = NULL; 1438 malloc_src_ring = false; 1439 } 1440 if (malloc_CE_state) { 1441 /* allocated CE_state locally */ 1442 scn->ce_id_to_state[CE_id] = 1443 NULL; 1444 qdf_mem_free(CE_state); 1445 malloc_CE_state = false; 1446 } 1447 1448 return NULL; 1449 } 1450 1451 status = ce_ring_setup(scn, CE_RING_STATUS, 1452 CE_id, CE_state->status_ring, 1453 attr); 1454 if (status < 0) 1455 goto error_target_access; 1456 1457 } 1458 1459 /* epping */ 1460 /* poll timer */ 1461 if (CE_state->attr_flags & CE_ATTR_ENABLE_POLL) { 1462 qdf_timer_init(scn->qdf_dev, 1463 &CE_state->poll_timer, 1464 ce_poll_timeout, 1465 CE_state, 1466 QDF_TIMER_TYPE_WAKE_APPS); 1467 ce_enable_polling(CE_state); 1468 qdf_timer_mod(&CE_state->poll_timer, 1469 CE_POLL_TIMEOUT); 1470 } 1471 } 1472 } 1473 1474 if (!ce_srng_based(scn)) { 1475 /* Enable CE error interrupts */ 1476 if (Q_TARGET_ACCESS_BEGIN(scn) < 0) 1477 goto error_target_access; 1478 CE_ERROR_INTR_ENABLE(scn, ctrl_addr); 1479 if (Q_TARGET_ACCESS_END(scn) < 0) 1480 goto error_target_access; 1481 } 1482 1483 qdf_create_work(scn->qdf_dev, &CE_state->oom_allocation_work, 1484 ce_oom_recovery, CE_state); 1485 1486 /* update the htt_data attribute */ 1487 ce_mark_datapath(CE_state); 1488 scn->ce_id_to_state[CE_id] = CE_state; 1489 1490 alloc_mem_ce_debug_history(scn, CE_id); 1491 1492 return (struct CE_handle *)CE_state; 1493 1494 error_target_access: 1495 error_no_dma_mem: 1496 ce_fini((struct CE_handle *)CE_state); 1497 return NULL; 1498 } 1499 1500 #ifdef WLAN_FEATURE_FASTPATH 1501 /** 1502 * hif_enable_fastpath() Update that we have enabled fastpath mode 1503 * @hif_ctx: HIF context 1504 * 1505 * For use in data path 1506 * 1507 * Retrun: void 1508 */ 1509 void hif_enable_fastpath(struct hif_opaque_softc *hif_ctx) 1510 { 1511 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 1512 1513 if (ce_srng_based(scn)) { 1514 HIF_INFO("%s, srng rings do not support fastpath", __func__); 1515 return; 1516 } 1517 HIF_DBG("%s, Enabling fastpath mode", __func__); 1518 scn->fastpath_mode_on = true; 1519 } 1520 1521 /** 1522 * hif_is_fastpath_mode_enabled - API to query if fasthpath mode is enabled 1523 * @hif_ctx: HIF Context 1524 * 1525 * For use in data path to skip HTC 1526 * 1527 * Return: bool 1528 */ 1529 bool hif_is_fastpath_mode_enabled(struct hif_opaque_softc *hif_ctx) 1530 { 1531 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 1532 1533 return scn->fastpath_mode_on; 1534 } 1535 1536 /** 1537 * hif_is_polled_mode_enabled - API to query if polling is enabled on all CEs 1538 * @hif_ctx: HIF Context 1539 * 1540 * API to check if polling is enabled on all CEs. Returns true when polling 1541 * is enabled on all CEs. 1542 * 1543 * Return: bool 1544 */ 1545 bool hif_is_polled_mode_enabled(struct hif_opaque_softc *hif_ctx) 1546 { 1547 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 1548 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 1549 struct CE_attr *attr; 1550 int id; 1551 1552 for (id = 0; id < scn->ce_count; id++) { 1553 attr = &hif_state->host_ce_config[id]; 1554 if (attr && (attr->dest_nentries) && 1555 !(attr->flags & CE_ATTR_ENABLE_POLL)) 1556 return false; 1557 } 1558 return true; 1559 } 1560 qdf_export_symbol(hif_is_polled_mode_enabled); 1561 1562 /** 1563 * hif_get_ce_handle - API to get CE handle for FastPath mode 1564 * @hif_ctx: HIF Context 1565 * @id: CopyEngine Id 1566 * 1567 * API to return CE handle for fastpath mode 1568 * 1569 * Return: void 1570 */ 1571 void *hif_get_ce_handle(struct hif_opaque_softc *hif_ctx, int id) 1572 { 1573 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 1574 1575 return scn->ce_id_to_state[id]; 1576 } 1577 1578 /** 1579 * ce_h2t_tx_ce_cleanup() Place holder function for H2T CE cleanup. 1580 * No processing is required inside this function. 1581 * @ce_hdl: Cope engine handle 1582 * Using an assert, this function makes sure that, 1583 * the TX CE has been processed completely. 1584 * 1585 * This is called while dismantling CE structures. No other thread 1586 * should be using these structures while dismantling is occurring 1587 * therfore no locking is needed. 1588 * 1589 * Return: none 1590 */ 1591 void ce_h2t_tx_ce_cleanup(struct CE_handle *ce_hdl) 1592 { 1593 struct CE_state *ce_state = (struct CE_state *)ce_hdl; 1594 struct CE_ring_state *src_ring = ce_state->src_ring; 1595 struct hif_softc *sc = ce_state->scn; 1596 uint32_t sw_index, write_index; 1597 1598 if (hif_is_nss_wifi_enabled(sc)) 1599 return; 1600 1601 if (sc->fastpath_mode_on && ce_state->htt_tx_data) { 1602 HIF_DBG("%s %d Fastpath mode ON, Cleaning up HTT Tx CE", 1603 __func__, __LINE__); 1604 sw_index = src_ring->sw_index; 1605 write_index = src_ring->sw_index; 1606 1607 /* At this point Tx CE should be clean */ 1608 qdf_assert_always(sw_index == write_index); 1609 } 1610 } 1611 1612 /** 1613 * ce_t2h_msg_ce_cleanup() - Cleanup buffers on the t2h datapath msg queue. 1614 * @ce_hdl: Handle to CE 1615 * 1616 * These buffers are never allocated on the fly, but 1617 * are allocated only once during HIF start and freed 1618 * only once during HIF stop. 1619 * NOTE: 1620 * The assumption here is there is no in-flight DMA in progress 1621 * currently, so that buffers can be freed up safely. 1622 * 1623 * Return: NONE 1624 */ 1625 void ce_t2h_msg_ce_cleanup(struct CE_handle *ce_hdl) 1626 { 1627 struct CE_state *ce_state = (struct CE_state *)ce_hdl; 1628 struct CE_ring_state *dst_ring = ce_state->dest_ring; 1629 qdf_nbuf_t nbuf; 1630 int i; 1631 1632 if (ce_state->scn->fastpath_mode_on == false) 1633 return; 1634 1635 if (!ce_state->htt_rx_data) 1636 return; 1637 1638 /* 1639 * when fastpath_mode is on and for datapath CEs. Unlike other CE's, 1640 * this CE is completely full: does not leave one blank space, to 1641 * distinguish between empty queue & full queue. So free all the 1642 * entries. 1643 */ 1644 for (i = 0; i < dst_ring->nentries; i++) { 1645 nbuf = dst_ring->per_transfer_context[i]; 1646 1647 /* 1648 * The reasons for doing this check are: 1649 * 1) Protect against calling cleanup before allocating buffers 1650 * 2) In a corner case, FASTPATH_mode_on may be set, but we 1651 * could have a partially filled ring, because of a memory 1652 * allocation failure in the middle of allocating ring. 1653 * This check accounts for that case, checking 1654 * fastpath_mode_on flag or started flag would not have 1655 * covered that case. This is not in performance path, 1656 * so OK to do this. 1657 */ 1658 if (nbuf) { 1659 qdf_nbuf_unmap_single(ce_state->scn->qdf_dev, nbuf, 1660 QDF_DMA_FROM_DEVICE); 1661 qdf_nbuf_free(nbuf); 1662 } 1663 } 1664 } 1665 1666 /** 1667 * hif_update_fastpath_recv_bufs_cnt() - Increments the Rx buf count by 1 1668 * @scn: HIF handle 1669 * 1670 * Datapath Rx CEs are special case, where we reuse all the message buffers. 1671 * Hence we have to post all the entries in the pipe, even, in the beginning 1672 * unlike for other CE pipes where one less than dest_nentries are filled in 1673 * the beginning. 1674 * 1675 * Return: None 1676 */ 1677 static void hif_update_fastpath_recv_bufs_cnt(struct hif_softc *scn) 1678 { 1679 int pipe_num; 1680 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 1681 1682 if (scn->fastpath_mode_on == false) 1683 return; 1684 1685 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 1686 struct HIF_CE_pipe_info *pipe_info = 1687 &hif_state->pipe_info[pipe_num]; 1688 struct CE_state *ce_state = 1689 scn->ce_id_to_state[pipe_info->pipe_num]; 1690 1691 if (ce_state->htt_rx_data) 1692 atomic_inc(&pipe_info->recv_bufs_needed); 1693 } 1694 } 1695 #else 1696 static inline void hif_update_fastpath_recv_bufs_cnt(struct hif_softc *scn) 1697 { 1698 } 1699 1700 static inline bool ce_is_fastpath_enabled(struct hif_softc *scn) 1701 { 1702 return false; 1703 } 1704 1705 static inline bool ce_is_fastpath_handler_registered(struct CE_state *ce_state) 1706 { 1707 return false; 1708 } 1709 #endif /* WLAN_FEATURE_FASTPATH */ 1710 1711 void ce_fini(struct CE_handle *copyeng) 1712 { 1713 struct CE_state *CE_state = (struct CE_state *)copyeng; 1714 unsigned int CE_id = CE_state->id; 1715 struct hif_softc *scn = CE_state->scn; 1716 uint32_t desc_size; 1717 1718 bool inited = CE_state->timer_inited; 1719 CE_state->state = CE_UNUSED; 1720 scn->ce_id_to_state[CE_id] = NULL; 1721 /* Set the flag to false first to stop processing in ce_poll_timeout */ 1722 ce_disable_polling(CE_state); 1723 1724 qdf_lro_deinit(CE_state->lro_data); 1725 1726 if (CE_state->src_ring) { 1727 /* Cleanup the datapath Tx ring */ 1728 ce_h2t_tx_ce_cleanup(copyeng); 1729 1730 desc_size = ce_get_desc_size(scn, CE_RING_SRC); 1731 if (CE_state->src_ring->shadow_base_unaligned) 1732 qdf_mem_free(CE_state->src_ring->shadow_base_unaligned); 1733 if (CE_state->src_ring->base_addr_owner_space_unaligned) 1734 ce_free_desc_ring(scn, CE_state->id, 1735 CE_state->src_ring, 1736 desc_size); 1737 qdf_mem_free(CE_state->src_ring); 1738 } 1739 if (CE_state->dest_ring) { 1740 /* Cleanup the datapath Rx ring */ 1741 ce_t2h_msg_ce_cleanup(copyeng); 1742 1743 desc_size = ce_get_desc_size(scn, CE_RING_DEST); 1744 if (CE_state->dest_ring->base_addr_owner_space_unaligned) 1745 ce_free_desc_ring(scn, CE_state->id, 1746 CE_state->dest_ring, 1747 desc_size); 1748 qdf_mem_free(CE_state->dest_ring); 1749 1750 /* epping */ 1751 if (inited) { 1752 qdf_timer_free(&CE_state->poll_timer); 1753 } 1754 } 1755 if ((ce_srng_based(CE_state->scn)) && (CE_state->status_ring)) { 1756 /* Cleanup the datapath Tx ring */ 1757 ce_h2t_tx_ce_cleanup(copyeng); 1758 1759 if (CE_state->status_ring->shadow_base_unaligned) 1760 qdf_mem_free( 1761 CE_state->status_ring->shadow_base_unaligned); 1762 1763 desc_size = ce_get_desc_size(scn, CE_RING_STATUS); 1764 if (CE_state->status_ring->base_addr_owner_space_unaligned) 1765 ce_free_desc_ring(scn, CE_state->id, 1766 CE_state->status_ring, 1767 desc_size); 1768 qdf_mem_free(CE_state->status_ring); 1769 } 1770 1771 free_mem_ce_debug_history(scn, CE_id); 1772 reset_ce_debug_history(scn); 1773 ce_deinit_ce_desc_event_log(scn, CE_id); 1774 1775 qdf_spinlock_destroy(&CE_state->ce_index_lock); 1776 qdf_mem_free(CE_state); 1777 } 1778 1779 void hif_detach_htc(struct hif_opaque_softc *hif_ctx) 1780 { 1781 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_ctx); 1782 1783 qdf_mem_zero(&hif_state->msg_callbacks_pending, 1784 sizeof(hif_state->msg_callbacks_pending)); 1785 qdf_mem_zero(&hif_state->msg_callbacks_current, 1786 sizeof(hif_state->msg_callbacks_current)); 1787 } 1788 1789 /* Send the first nbytes bytes of the buffer */ 1790 QDF_STATUS 1791 hif_send_head(struct hif_opaque_softc *hif_ctx, 1792 uint8_t pipe, unsigned int transfer_id, unsigned int nbytes, 1793 qdf_nbuf_t nbuf, unsigned int data_attr) 1794 { 1795 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 1796 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_ctx); 1797 struct HIF_CE_pipe_info *pipe_info = &(hif_state->pipe_info[pipe]); 1798 struct CE_handle *ce_hdl = pipe_info->ce_hdl; 1799 int bytes = nbytes, nfrags = 0; 1800 struct ce_sendlist sendlist; 1801 int status, i = 0; 1802 unsigned int mux_id = 0; 1803 1804 if (nbytes > qdf_nbuf_len(nbuf)) { 1805 HIF_ERROR("%s: nbytes:%d nbuf_len:%d", __func__, nbytes, 1806 (uint32_t)qdf_nbuf_len(nbuf)); 1807 QDF_ASSERT(0); 1808 } 1809 1810 transfer_id = 1811 (mux_id & MUX_ID_MASK) | 1812 (transfer_id & TRANSACTION_ID_MASK); 1813 data_attr &= DESC_DATA_FLAG_MASK; 1814 /* 1815 * The common case involves sending multiple fragments within a 1816 * single download (the tx descriptor and the tx frame header). 1817 * So, optimize for the case of multiple fragments by not even 1818 * checking whether it's necessary to use a sendlist. 1819 * The overhead of using a sendlist for a single buffer download 1820 * is not a big deal, since it happens rarely (for WMI messages). 1821 */ 1822 ce_sendlist_init(&sendlist); 1823 do { 1824 qdf_dma_addr_t frag_paddr; 1825 int frag_bytes; 1826 1827 frag_paddr = qdf_nbuf_get_frag_paddr(nbuf, nfrags); 1828 frag_bytes = qdf_nbuf_get_frag_len(nbuf, nfrags); 1829 /* 1830 * Clear the packet offset for all but the first CE desc. 1831 */ 1832 if (i++ > 0) 1833 data_attr &= ~QDF_CE_TX_PKT_OFFSET_BIT_M; 1834 1835 status = ce_sendlist_buf_add(&sendlist, frag_paddr, 1836 frag_bytes > 1837 bytes ? bytes : frag_bytes, 1838 qdf_nbuf_get_frag_is_wordstream 1839 (nbuf, 1840 nfrags) ? 0 : 1841 CE_SEND_FLAG_SWAP_DISABLE, 1842 data_attr); 1843 if (status != QDF_STATUS_SUCCESS) { 1844 HIF_ERROR("%s: error, frag_num %d larger than limit", 1845 __func__, nfrags); 1846 return status; 1847 } 1848 bytes -= frag_bytes; 1849 nfrags++; 1850 } while (bytes > 0); 1851 1852 /* Make sure we have resources to handle this request */ 1853 qdf_spin_lock_bh(&pipe_info->completion_freeq_lock); 1854 if (pipe_info->num_sends_allowed < nfrags) { 1855 qdf_spin_unlock_bh(&pipe_info->completion_freeq_lock); 1856 ce_pkt_error_count_incr(hif_state, HIF_PIPE_NO_RESOURCE); 1857 return QDF_STATUS_E_RESOURCES; 1858 } 1859 pipe_info->num_sends_allowed -= nfrags; 1860 qdf_spin_unlock_bh(&pipe_info->completion_freeq_lock); 1861 1862 if (qdf_unlikely(ce_hdl == NULL)) { 1863 HIF_ERROR("%s: error CE handle is null", __func__); 1864 return A_ERROR; 1865 } 1866 1867 QDF_NBUF_UPDATE_TX_PKT_COUNT(nbuf, QDF_NBUF_TX_PKT_HIF); 1868 DPTRACE(qdf_dp_trace(nbuf, QDF_DP_TRACE_HIF_PACKET_PTR_RECORD, 1869 QDF_TRACE_DEFAULT_PDEV_ID, qdf_nbuf_data_addr(nbuf), 1870 sizeof(qdf_nbuf_data(nbuf)), QDF_TX)); 1871 status = ce_sendlist_send(ce_hdl, nbuf, &sendlist, transfer_id); 1872 QDF_ASSERT(status == QDF_STATUS_SUCCESS); 1873 1874 return status; 1875 } 1876 1877 void hif_send_complete_check(struct hif_opaque_softc *hif_ctx, uint8_t pipe, 1878 int force) 1879 { 1880 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 1881 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_ctx); 1882 1883 if (!force) { 1884 int resources; 1885 /* 1886 * Decide whether to actually poll for completions, or just 1887 * wait for a later chance. If there seem to be plenty of 1888 * resources left, then just wait, since checking involves 1889 * reading a CE register, which is a relatively expensive 1890 * operation. 1891 */ 1892 resources = hif_get_free_queue_number(hif_ctx, pipe); 1893 /* 1894 * If at least 50% of the total resources are still available, 1895 * don't bother checking again yet. 1896 */ 1897 if (resources > (hif_state->host_ce_config[pipe].src_nentries >> 1898 1)) 1899 return; 1900 } 1901 #if ATH_11AC_TXCOMPACT 1902 ce_per_engine_servicereap(scn, pipe); 1903 #else 1904 ce_per_engine_service(scn, pipe); 1905 #endif 1906 } 1907 1908 uint16_t 1909 hif_get_free_queue_number(struct hif_opaque_softc *hif_ctx, uint8_t pipe) 1910 { 1911 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_ctx); 1912 struct HIF_CE_pipe_info *pipe_info = &(hif_state->pipe_info[pipe]); 1913 uint16_t rv; 1914 1915 qdf_spin_lock_bh(&pipe_info->completion_freeq_lock); 1916 rv = pipe_info->num_sends_allowed; 1917 qdf_spin_unlock_bh(&pipe_info->completion_freeq_lock); 1918 return rv; 1919 } 1920 1921 /* Called by lower (CE) layer when a send to Target completes. */ 1922 static void 1923 hif_pci_ce_send_done(struct CE_handle *copyeng, void *ce_context, 1924 void *transfer_context, qdf_dma_addr_t CE_data, 1925 unsigned int nbytes, unsigned int transfer_id, 1926 unsigned int sw_index, unsigned int hw_index, 1927 unsigned int toeplitz_hash_result) 1928 { 1929 struct HIF_CE_pipe_info *pipe_info = 1930 (struct HIF_CE_pipe_info *)ce_context; 1931 struct HIF_CE_state *hif_state = pipe_info->HIF_CE_state; 1932 struct hif_softc *scn = HIF_GET_SOFTC(hif_state); 1933 unsigned int sw_idx = sw_index, hw_idx = hw_index; 1934 struct hif_msg_callbacks *msg_callbacks = 1935 &pipe_info->pipe_callbacks; 1936 1937 do { 1938 /* 1939 * The upper layer callback will be triggered 1940 * when last fragment is complteted. 1941 */ 1942 if (transfer_context != CE_SENDLIST_ITEM_CTXT) { 1943 if (scn->target_status == TARGET_STATUS_RESET) { 1944 1945 qdf_nbuf_unmap_single(scn->qdf_dev, 1946 transfer_context, 1947 QDF_DMA_TO_DEVICE); 1948 qdf_nbuf_free(transfer_context); 1949 } else 1950 msg_callbacks->txCompletionHandler( 1951 msg_callbacks->Context, 1952 transfer_context, transfer_id, 1953 toeplitz_hash_result); 1954 } 1955 1956 qdf_spin_lock(&pipe_info->completion_freeq_lock); 1957 pipe_info->num_sends_allowed++; 1958 qdf_spin_unlock(&pipe_info->completion_freeq_lock); 1959 } while (ce_completed_send_next(copyeng, 1960 &ce_context, &transfer_context, 1961 &CE_data, &nbytes, &transfer_id, 1962 &sw_idx, &hw_idx, 1963 &toeplitz_hash_result) == QDF_STATUS_SUCCESS); 1964 } 1965 1966 /** 1967 * hif_ce_do_recv(): send message from copy engine to upper layers 1968 * @msg_callbacks: structure containing callback and callback context 1969 * @netbuff: skb containing message 1970 * @nbytes: number of bytes in the message 1971 * @pipe_info: used for the pipe_number info 1972 * 1973 * Checks the packet length, configures the length in the netbuff, 1974 * and calls the upper layer callback. 1975 * 1976 * return: None 1977 */ 1978 static inline void hif_ce_do_recv(struct hif_msg_callbacks *msg_callbacks, 1979 qdf_nbuf_t netbuf, int nbytes, 1980 struct HIF_CE_pipe_info *pipe_info) { 1981 if (nbytes <= pipe_info->buf_sz) { 1982 qdf_nbuf_set_pktlen(netbuf, nbytes); 1983 msg_callbacks-> 1984 rxCompletionHandler(msg_callbacks->Context, 1985 netbuf, pipe_info->pipe_num); 1986 } else { 1987 HIF_ERROR("%s: Invalid Rx msg buf:%pK nbytes:%d", 1988 __func__, netbuf, nbytes); 1989 1990 qdf_nbuf_free(netbuf); 1991 } 1992 } 1993 1994 /* Called by lower (CE) layer when data is received from the Target. */ 1995 static void 1996 hif_pci_ce_recv_data(struct CE_handle *copyeng, void *ce_context, 1997 void *transfer_context, qdf_dma_addr_t CE_data, 1998 unsigned int nbytes, unsigned int transfer_id, 1999 unsigned int flags) 2000 { 2001 struct HIF_CE_pipe_info *pipe_info = 2002 (struct HIF_CE_pipe_info *)ce_context; 2003 struct HIF_CE_state *hif_state = pipe_info->HIF_CE_state; 2004 struct CE_state *ce_state = (struct CE_state *) copyeng; 2005 struct hif_softc *scn = HIF_GET_SOFTC(hif_state); 2006 #ifdef HIF_PCI 2007 struct hif_pci_softc *hif_pci_sc = HIF_GET_PCI_SOFTC(hif_state); 2008 #endif 2009 struct hif_msg_callbacks *msg_callbacks = 2010 &pipe_info->pipe_callbacks; 2011 2012 do { 2013 #ifdef HIF_PCI 2014 hif_pm_runtime_mark_last_busy(hif_pci_sc->dev); 2015 #endif 2016 qdf_nbuf_unmap_single(scn->qdf_dev, 2017 (qdf_nbuf_t) transfer_context, 2018 QDF_DMA_FROM_DEVICE); 2019 2020 atomic_inc(&pipe_info->recv_bufs_needed); 2021 hif_post_recv_buffers_for_pipe(pipe_info); 2022 if (scn->target_status == TARGET_STATUS_RESET) 2023 qdf_nbuf_free(transfer_context); 2024 else 2025 hif_ce_do_recv(msg_callbacks, transfer_context, 2026 nbytes, pipe_info); 2027 2028 /* Set up force_break flag if num of receices reaches 2029 * MAX_NUM_OF_RECEIVES 2030 */ 2031 ce_state->receive_count++; 2032 if (qdf_unlikely(hif_ce_service_should_yield(scn, ce_state))) { 2033 ce_state->force_break = 1; 2034 break; 2035 } 2036 } while (ce_completed_recv_next(copyeng, &ce_context, &transfer_context, 2037 &CE_data, &nbytes, &transfer_id, 2038 &flags) == QDF_STATUS_SUCCESS); 2039 2040 } 2041 2042 /* TBDXXX: Set CE High Watermark; invoke txResourceAvailHandler in response */ 2043 2044 void 2045 hif_post_init(struct hif_opaque_softc *hif_ctx, void *unused, 2046 struct hif_msg_callbacks *callbacks) 2047 { 2048 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_ctx); 2049 2050 #ifdef CONFIG_ATH_PCIE_ACCESS_DEBUG 2051 spin_lock_init(&pcie_access_log_lock); 2052 #endif 2053 /* Save callbacks for later installation */ 2054 qdf_mem_copy(&hif_state->msg_callbacks_pending, callbacks, 2055 sizeof(hif_state->msg_callbacks_pending)); 2056 2057 } 2058 2059 static int hif_completion_thread_startup(struct HIF_CE_state *hif_state) 2060 { 2061 struct CE_handle *ce_diag = hif_state->ce_diag; 2062 int pipe_num; 2063 struct hif_softc *scn = HIF_GET_SOFTC(hif_state); 2064 struct hif_msg_callbacks *hif_msg_callbacks = 2065 &hif_state->msg_callbacks_current; 2066 2067 /* daemonize("hif_compl_thread"); */ 2068 2069 if (scn->ce_count == 0) { 2070 HIF_ERROR("%s: Invalid ce_count", __func__); 2071 return -EINVAL; 2072 } 2073 2074 if (!hif_msg_callbacks || 2075 !hif_msg_callbacks->rxCompletionHandler || 2076 !hif_msg_callbacks->txCompletionHandler) { 2077 HIF_ERROR("%s: no completion handler registered", __func__); 2078 return -EFAULT; 2079 } 2080 2081 A_TARGET_ACCESS_LIKELY(scn); 2082 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 2083 struct CE_attr attr; 2084 struct HIF_CE_pipe_info *pipe_info; 2085 2086 pipe_info = &hif_state->pipe_info[pipe_num]; 2087 if (pipe_info->ce_hdl == ce_diag) 2088 continue; /* Handle Diagnostic CE specially */ 2089 attr = hif_state->host_ce_config[pipe_num]; 2090 if (attr.src_nentries) { 2091 /* pipe used to send to target */ 2092 HIF_DBG("%s: pipe_num:%d pipe_info:0x%pK", 2093 __func__, pipe_num, pipe_info); 2094 ce_send_cb_register(pipe_info->ce_hdl, 2095 hif_pci_ce_send_done, pipe_info, 2096 attr.flags & CE_ATTR_DISABLE_INTR); 2097 pipe_info->num_sends_allowed = attr.src_nentries - 1; 2098 } 2099 if (attr.dest_nentries) { 2100 /* pipe used to receive from target */ 2101 ce_recv_cb_register(pipe_info->ce_hdl, 2102 hif_pci_ce_recv_data, pipe_info, 2103 attr.flags & CE_ATTR_DISABLE_INTR); 2104 } 2105 2106 if (attr.src_nentries) 2107 qdf_spinlock_create(&pipe_info->completion_freeq_lock); 2108 2109 qdf_mem_copy(&pipe_info->pipe_callbacks, hif_msg_callbacks, 2110 sizeof(pipe_info->pipe_callbacks)); 2111 } 2112 2113 A_TARGET_ACCESS_UNLIKELY(scn); 2114 return 0; 2115 } 2116 2117 /* 2118 * Install pending msg callbacks. 2119 * 2120 * TBDXXX: This hack is needed because upper layers install msg callbacks 2121 * for use with HTC before BMI is done; yet this HIF implementation 2122 * needs to continue to use BMI msg callbacks. Really, upper layers 2123 * should not register HTC callbacks until AFTER BMI phase. 2124 */ 2125 static void hif_msg_callbacks_install(struct hif_softc *scn) 2126 { 2127 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2128 2129 qdf_mem_copy(&hif_state->msg_callbacks_current, 2130 &hif_state->msg_callbacks_pending, 2131 sizeof(hif_state->msg_callbacks_pending)); 2132 } 2133 2134 void hif_get_default_pipe(struct hif_opaque_softc *hif_hdl, uint8_t *ULPipe, 2135 uint8_t *DLPipe) 2136 { 2137 int ul_is_polled, dl_is_polled; 2138 2139 (void)hif_map_service_to_pipe(hif_hdl, HTC_CTRL_RSVD_SVC, 2140 ULPipe, DLPipe, &ul_is_polled, &dl_is_polled); 2141 } 2142 2143 /** 2144 * hif_dump_pipe_debug_count() - Log error count 2145 * @scn: hif_softc pointer. 2146 * 2147 * Output the pipe error counts of each pipe to log file 2148 * 2149 * Return: N/A 2150 */ 2151 void hif_dump_pipe_debug_count(struct hif_softc *scn) 2152 { 2153 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2154 int pipe_num; 2155 2156 if (hif_state == NULL) { 2157 HIF_ERROR("%s hif_state is NULL", __func__); 2158 return; 2159 } 2160 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 2161 struct HIF_CE_pipe_info *pipe_info; 2162 2163 pipe_info = &hif_state->pipe_info[pipe_num]; 2164 2165 if (pipe_info->nbuf_alloc_err_count > 0 || 2166 pipe_info->nbuf_dma_err_count > 0 || 2167 pipe_info->nbuf_ce_enqueue_err_count) 2168 HIF_ERROR( 2169 "%s: pipe_id = %d, recv_bufs_needed = %d, nbuf_alloc_err_count = %u, nbuf_dma_err_count = %u, nbuf_ce_enqueue_err_count = %u", 2170 __func__, pipe_info->pipe_num, 2171 atomic_read(&pipe_info->recv_bufs_needed), 2172 pipe_info->nbuf_alloc_err_count, 2173 pipe_info->nbuf_dma_err_count, 2174 pipe_info->nbuf_ce_enqueue_err_count); 2175 } 2176 } 2177 2178 static void hif_post_recv_buffers_failure(struct HIF_CE_pipe_info *pipe_info, 2179 void *nbuf, uint32_t *error_cnt, 2180 enum hif_ce_event_type failure_type, 2181 const char *failure_type_string) 2182 { 2183 int bufs_needed_tmp = atomic_inc_return(&pipe_info->recv_bufs_needed); 2184 struct CE_state *CE_state = (struct CE_state *)pipe_info->ce_hdl; 2185 struct hif_softc *scn = HIF_GET_SOFTC(pipe_info->HIF_CE_state); 2186 int ce_id = CE_state->id; 2187 uint32_t error_cnt_tmp; 2188 2189 qdf_spin_lock_bh(&pipe_info->recv_bufs_needed_lock); 2190 error_cnt_tmp = ++(*error_cnt); 2191 qdf_spin_unlock_bh(&pipe_info->recv_bufs_needed_lock); 2192 HIF_DBG("%s: pipe_num %d, needed %d, err_cnt = %u, fail_type = %s", 2193 __func__, pipe_info->pipe_num, bufs_needed_tmp, error_cnt_tmp, 2194 failure_type_string); 2195 hif_record_ce_desc_event(scn, ce_id, failure_type, 2196 NULL, nbuf, bufs_needed_tmp, 0); 2197 /* if we fail to allocate the last buffer for an rx pipe, 2198 * there is no trigger to refill the ce and we will 2199 * eventually crash 2200 */ 2201 if (bufs_needed_tmp == CE_state->dest_ring->nentries - 1) 2202 qdf_sched_work(scn->qdf_dev, &CE_state->oom_allocation_work); 2203 2204 } 2205 2206 2207 2208 2209 QDF_STATUS hif_post_recv_buffers_for_pipe(struct HIF_CE_pipe_info *pipe_info) 2210 { 2211 struct CE_handle *ce_hdl; 2212 qdf_size_t buf_sz; 2213 struct hif_softc *scn = HIF_GET_SOFTC(pipe_info->HIF_CE_state); 2214 QDF_STATUS status; 2215 uint32_t bufs_posted = 0; 2216 2217 buf_sz = pipe_info->buf_sz; 2218 if (buf_sz == 0) { 2219 /* Unused Copy Engine */ 2220 return QDF_STATUS_SUCCESS; 2221 } 2222 2223 ce_hdl = pipe_info->ce_hdl; 2224 2225 qdf_spin_lock_bh(&pipe_info->recv_bufs_needed_lock); 2226 while (atomic_read(&pipe_info->recv_bufs_needed) > 0) { 2227 qdf_dma_addr_t CE_data; /* CE space buffer address */ 2228 qdf_nbuf_t nbuf; 2229 2230 atomic_dec(&pipe_info->recv_bufs_needed); 2231 qdf_spin_unlock_bh(&pipe_info->recv_bufs_needed_lock); 2232 2233 nbuf = qdf_nbuf_alloc(scn->qdf_dev, buf_sz, 0, 4, false); 2234 if (!nbuf) { 2235 hif_post_recv_buffers_failure(pipe_info, nbuf, 2236 &pipe_info->nbuf_alloc_err_count, 2237 HIF_RX_NBUF_ALLOC_FAILURE, 2238 "HIF_RX_NBUF_ALLOC_FAILURE"); 2239 return QDF_STATUS_E_NOMEM; 2240 } 2241 2242 /* 2243 * qdf_nbuf_peek_header(nbuf, &data, &unused); 2244 * CE_data = dma_map_single(dev, data, buf_sz, ); 2245 * DMA_FROM_DEVICE); 2246 */ 2247 status = qdf_nbuf_map_single(scn->qdf_dev, nbuf, 2248 QDF_DMA_FROM_DEVICE); 2249 2250 if (qdf_unlikely(status != QDF_STATUS_SUCCESS)) { 2251 hif_post_recv_buffers_failure(pipe_info, nbuf, 2252 &pipe_info->nbuf_dma_err_count, 2253 HIF_RX_NBUF_MAP_FAILURE, 2254 "HIF_RX_NBUF_MAP_FAILURE"); 2255 qdf_nbuf_free(nbuf); 2256 return status; 2257 } 2258 2259 CE_data = qdf_nbuf_get_frag_paddr(nbuf, 0); 2260 2261 qdf_mem_dma_sync_single_for_device(scn->qdf_dev, CE_data, 2262 buf_sz, DMA_FROM_DEVICE); 2263 status = ce_recv_buf_enqueue(ce_hdl, (void *)nbuf, CE_data); 2264 if (qdf_unlikely(status != QDF_STATUS_SUCCESS)) { 2265 hif_post_recv_buffers_failure(pipe_info, nbuf, 2266 &pipe_info->nbuf_ce_enqueue_err_count, 2267 HIF_RX_NBUF_ENQUEUE_FAILURE, 2268 "HIF_RX_NBUF_ENQUEUE_FAILURE"); 2269 2270 qdf_nbuf_unmap_single(scn->qdf_dev, nbuf, 2271 QDF_DMA_FROM_DEVICE); 2272 qdf_nbuf_free(nbuf); 2273 return status; 2274 } 2275 2276 qdf_spin_lock_bh(&pipe_info->recv_bufs_needed_lock); 2277 bufs_posted++; 2278 } 2279 pipe_info->nbuf_alloc_err_count = 2280 (pipe_info->nbuf_alloc_err_count > bufs_posted) ? 2281 pipe_info->nbuf_alloc_err_count - bufs_posted : 0; 2282 pipe_info->nbuf_dma_err_count = 2283 (pipe_info->nbuf_dma_err_count > bufs_posted) ? 2284 pipe_info->nbuf_dma_err_count - bufs_posted : 0; 2285 pipe_info->nbuf_ce_enqueue_err_count = 2286 (pipe_info->nbuf_ce_enqueue_err_count > bufs_posted) ? 2287 pipe_info->nbuf_ce_enqueue_err_count - bufs_posted : 0; 2288 2289 qdf_spin_unlock_bh(&pipe_info->recv_bufs_needed_lock); 2290 2291 return QDF_STATUS_SUCCESS; 2292 } 2293 2294 /* 2295 * Try to post all desired receive buffers for all pipes. 2296 * Returns 0 for non fastpath rx copy engine as 2297 * oom_allocation_work will be scheduled to recover any 2298 * failures, non-zero if unable to completely replenish 2299 * receive buffers for fastpath rx Copy engine. 2300 */ 2301 QDF_STATUS hif_post_recv_buffers(struct hif_softc *scn) 2302 { 2303 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2304 int pipe_num; 2305 struct CE_state *ce_state = NULL; 2306 QDF_STATUS qdf_status; 2307 2308 A_TARGET_ACCESS_LIKELY(scn); 2309 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 2310 struct HIF_CE_pipe_info *pipe_info; 2311 2312 ce_state = scn->ce_id_to_state[pipe_num]; 2313 pipe_info = &hif_state->pipe_info[pipe_num]; 2314 2315 if (hif_is_nss_wifi_enabled(scn) && 2316 ce_state && (ce_state->htt_rx_data)) 2317 continue; 2318 2319 qdf_status = hif_post_recv_buffers_for_pipe(pipe_info); 2320 if (!QDF_IS_STATUS_SUCCESS(qdf_status) && ce_state && 2321 ce_state->htt_rx_data && 2322 scn->fastpath_mode_on) { 2323 A_TARGET_ACCESS_UNLIKELY(scn); 2324 return qdf_status; 2325 } 2326 } 2327 2328 A_TARGET_ACCESS_UNLIKELY(scn); 2329 2330 return QDF_STATUS_SUCCESS; 2331 } 2332 2333 QDF_STATUS hif_start(struct hif_opaque_softc *hif_ctx) 2334 { 2335 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 2336 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2337 QDF_STATUS qdf_status = QDF_STATUS_SUCCESS; 2338 2339 hif_update_fastpath_recv_bufs_cnt(scn); 2340 2341 hif_msg_callbacks_install(scn); 2342 2343 if (hif_completion_thread_startup(hif_state)) 2344 return QDF_STATUS_E_FAILURE; 2345 2346 /* enable buffer cleanup */ 2347 hif_state->started = true; 2348 2349 /* Post buffers once to start things off. */ 2350 qdf_status = hif_post_recv_buffers(scn); 2351 if (!QDF_IS_STATUS_SUCCESS(qdf_status)) { 2352 /* cleanup is done in hif_ce_disable */ 2353 HIF_ERROR("%s:failed to post buffers", __func__); 2354 return qdf_status; 2355 } 2356 2357 return qdf_status; 2358 } 2359 2360 static void hif_recv_buffer_cleanup_on_pipe(struct HIF_CE_pipe_info *pipe_info) 2361 { 2362 struct hif_softc *scn; 2363 struct CE_handle *ce_hdl; 2364 uint32_t buf_sz; 2365 struct HIF_CE_state *hif_state; 2366 qdf_nbuf_t netbuf; 2367 qdf_dma_addr_t CE_data; 2368 void *per_CE_context; 2369 2370 buf_sz = pipe_info->buf_sz; 2371 /* Unused Copy Engine */ 2372 if (buf_sz == 0) 2373 return; 2374 2375 2376 hif_state = pipe_info->HIF_CE_state; 2377 if (!hif_state->started) 2378 return; 2379 2380 scn = HIF_GET_SOFTC(hif_state); 2381 ce_hdl = pipe_info->ce_hdl; 2382 2383 if (scn->qdf_dev == NULL) 2384 return; 2385 while (ce_revoke_recv_next 2386 (ce_hdl, &per_CE_context, (void **)&netbuf, 2387 &CE_data) == QDF_STATUS_SUCCESS) { 2388 if (netbuf) { 2389 qdf_nbuf_unmap_single(scn->qdf_dev, netbuf, 2390 QDF_DMA_FROM_DEVICE); 2391 qdf_nbuf_free(netbuf); 2392 } 2393 } 2394 } 2395 2396 static void hif_send_buffer_cleanup_on_pipe(struct HIF_CE_pipe_info *pipe_info) 2397 { 2398 struct CE_handle *ce_hdl; 2399 struct HIF_CE_state *hif_state; 2400 struct hif_softc *scn; 2401 qdf_nbuf_t netbuf; 2402 void *per_CE_context; 2403 qdf_dma_addr_t CE_data; 2404 unsigned int nbytes; 2405 unsigned int id; 2406 uint32_t buf_sz; 2407 uint32_t toeplitz_hash_result; 2408 2409 buf_sz = pipe_info->buf_sz; 2410 if (buf_sz == 0) { 2411 /* Unused Copy Engine */ 2412 return; 2413 } 2414 2415 hif_state = pipe_info->HIF_CE_state; 2416 if (!hif_state->started) { 2417 return; 2418 } 2419 2420 scn = HIF_GET_SOFTC(hif_state); 2421 2422 ce_hdl = pipe_info->ce_hdl; 2423 2424 while (ce_cancel_send_next 2425 (ce_hdl, &per_CE_context, 2426 (void **)&netbuf, &CE_data, &nbytes, 2427 &id, &toeplitz_hash_result) == QDF_STATUS_SUCCESS) { 2428 if (netbuf != CE_SENDLIST_ITEM_CTXT) { 2429 /* 2430 * Packets enqueued by htt_h2t_ver_req_msg() and 2431 * htt_h2t_rx_ring_cfg_msg_ll() have already been 2432 * freed in htt_htc_misc_pkt_pool_free() in 2433 * wlantl_close(), so do not free them here again 2434 * by checking whether it's the endpoint 2435 * which they are queued in. 2436 */ 2437 if (id == scn->htc_htt_tx_endpoint) 2438 return; 2439 /* Indicate the completion to higher 2440 * layer to free the buffer 2441 */ 2442 if (pipe_info->pipe_callbacks.txCompletionHandler) 2443 pipe_info->pipe_callbacks. 2444 txCompletionHandler(pipe_info-> 2445 pipe_callbacks.Context, 2446 netbuf, id, toeplitz_hash_result); 2447 } 2448 } 2449 } 2450 2451 /* 2452 * Cleanup residual buffers for device shutdown: 2453 * buffers that were enqueued for receive 2454 * buffers that were to be sent 2455 * Note: Buffers that had completed but which were 2456 * not yet processed are on a completion queue. They 2457 * are handled when the completion thread shuts down. 2458 */ 2459 static void hif_buffer_cleanup(struct HIF_CE_state *hif_state) 2460 { 2461 int pipe_num; 2462 struct hif_softc *scn = HIF_GET_SOFTC(hif_state); 2463 struct CE_state *ce_state; 2464 2465 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 2466 struct HIF_CE_pipe_info *pipe_info; 2467 2468 ce_state = scn->ce_id_to_state[pipe_num]; 2469 if (hif_is_nss_wifi_enabled(scn) && ce_state && 2470 ((ce_state->htt_tx_data) || 2471 (ce_state->htt_rx_data))) { 2472 continue; 2473 } 2474 2475 pipe_info = &hif_state->pipe_info[pipe_num]; 2476 hif_recv_buffer_cleanup_on_pipe(pipe_info); 2477 hif_send_buffer_cleanup_on_pipe(pipe_info); 2478 } 2479 } 2480 2481 void hif_flush_surprise_remove(struct hif_opaque_softc *hif_ctx) 2482 { 2483 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 2484 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2485 2486 hif_buffer_cleanup(hif_state); 2487 } 2488 2489 static void hif_destroy_oom_work(struct hif_softc *scn) 2490 { 2491 struct CE_state *ce_state; 2492 int ce_id; 2493 2494 for (ce_id = 0; ce_id < scn->ce_count; ce_id++) { 2495 ce_state = scn->ce_id_to_state[ce_id]; 2496 if (ce_state) 2497 qdf_destroy_work(scn->qdf_dev, 2498 &ce_state->oom_allocation_work); 2499 } 2500 } 2501 2502 void hif_ce_stop(struct hif_softc *scn) 2503 { 2504 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2505 int pipe_num; 2506 2507 /* 2508 * before cleaning up any memory, ensure irq & 2509 * bottom half contexts will not be re-entered 2510 */ 2511 hif_disable_isr(&scn->osc); 2512 hif_destroy_oom_work(scn); 2513 scn->hif_init_done = false; 2514 2515 /* 2516 * At this point, asynchronous threads are stopped, 2517 * The Target should not DMA nor interrupt, Host code may 2518 * not initiate anything more. So we just need to clean 2519 * up Host-side state. 2520 */ 2521 2522 if (scn->athdiag_procfs_inited) { 2523 athdiag_procfs_remove(); 2524 scn->athdiag_procfs_inited = false; 2525 } 2526 2527 hif_buffer_cleanup(hif_state); 2528 2529 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 2530 struct HIF_CE_pipe_info *pipe_info; 2531 struct CE_attr attr; 2532 struct CE_handle *ce_diag = hif_state->ce_diag; 2533 2534 pipe_info = &hif_state->pipe_info[pipe_num]; 2535 if (pipe_info->ce_hdl) { 2536 if (pipe_info->ce_hdl != ce_diag) { 2537 attr = hif_state->host_ce_config[pipe_num]; 2538 if (attr.src_nentries) 2539 qdf_spinlock_destroy(&pipe_info-> 2540 completion_freeq_lock); 2541 } 2542 ce_fini(pipe_info->ce_hdl); 2543 pipe_info->ce_hdl = NULL; 2544 pipe_info->buf_sz = 0; 2545 qdf_spinlock_destroy(&pipe_info->recv_bufs_needed_lock); 2546 } 2547 } 2548 2549 if (hif_state->sleep_timer_init) { 2550 qdf_timer_stop(&hif_state->sleep_timer); 2551 qdf_timer_free(&hif_state->sleep_timer); 2552 hif_state->sleep_timer_init = false; 2553 } 2554 2555 hif_state->started = false; 2556 } 2557 2558 #ifdef QCN7605_SUPPORT 2559 static inline 2560 void hif_get_shadow_reg_cfg_qcn7605(struct shadow_reg_cfg 2561 **target_shadow_reg_cfg_ret, 2562 uint32_t *shadow_cfg_sz_ret) 2563 { 2564 if (target_shadow_reg_cfg_ret) 2565 *target_shadow_reg_cfg_ret = target_shadow_reg_cfg_map_qcn7605; 2566 if (shadow_cfg_sz_ret) 2567 *shadow_cfg_sz_ret = sizeof(target_shadow_reg_cfg_map_qcn7605); 2568 } 2569 #else 2570 static inline 2571 void hif_get_shadow_reg_cfg_qcn7605(struct shadow_reg_cfg 2572 **target_shadow_reg_cfg_ret, 2573 uint32_t *shadow_cfg_sz_ret) 2574 { 2575 HIF_ERROR("QCN7605 not supported"); 2576 } 2577 #endif 2578 2579 static void hif_get_shadow_reg_cfg(struct hif_softc *scn, 2580 struct shadow_reg_cfg 2581 **target_shadow_reg_cfg_ret, 2582 uint32_t *shadow_cfg_sz_ret) 2583 { 2584 struct hif_opaque_softc *hif_hdl = GET_HIF_OPAQUE_HDL(scn); 2585 struct hif_target_info *tgt_info = hif_get_target_info_handle(hif_hdl); 2586 2587 switch (tgt_info->target_type) { 2588 case TARGET_TYPE_QCN7605: 2589 hif_get_shadow_reg_cfg_qcn7605(target_shadow_reg_cfg_ret, 2590 shadow_cfg_sz_ret); 2591 break; 2592 default: 2593 if (target_shadow_reg_cfg_ret) 2594 *target_shadow_reg_cfg_ret = target_shadow_reg_cfg; 2595 if (shadow_cfg_sz_ret) 2596 *shadow_cfg_sz_ret = shadow_cfg_sz; 2597 } 2598 } 2599 2600 /** 2601 * hif_get_target_ce_config() - get copy engine configuration 2602 * @target_ce_config_ret: basic copy engine configuration 2603 * @target_ce_config_sz_ret: size of the basic configuration in bytes 2604 * @target_service_to_ce_map_ret: service mapping for the copy engines 2605 * @target_service_to_ce_map_sz_ret: size of the mapping in bytes 2606 * @target_shadow_reg_cfg_ret: shadow register configuration 2607 * @shadow_cfg_sz_ret: size of the shadow register configuration in bytes 2608 * 2609 * providing accessor to these values outside of this file. 2610 * currently these are stored in static pointers to const sections. 2611 * there are multiple configurations that are selected from at compile time. 2612 * Runtime selection would need to consider mode, target type and bus type. 2613 * 2614 * Return: return by parameter. 2615 */ 2616 void hif_get_target_ce_config(struct hif_softc *scn, 2617 struct CE_pipe_config **target_ce_config_ret, 2618 uint32_t *target_ce_config_sz_ret, 2619 struct service_to_pipe **target_service_to_ce_map_ret, 2620 uint32_t *target_service_to_ce_map_sz_ret, 2621 struct shadow_reg_cfg **target_shadow_reg_cfg_ret, 2622 uint32_t *shadow_cfg_sz_ret) 2623 { 2624 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2625 2626 *target_ce_config_ret = hif_state->target_ce_config; 2627 *target_ce_config_sz_ret = hif_state->target_ce_config_sz; 2628 2629 hif_select_service_to_pipe_map(scn, target_service_to_ce_map_ret, 2630 target_service_to_ce_map_sz_ret); 2631 hif_get_shadow_reg_cfg(scn, target_shadow_reg_cfg_ret, 2632 shadow_cfg_sz_ret); 2633 } 2634 2635 #ifdef CONFIG_SHADOW_V2 2636 static void hif_print_hal_shadow_register_cfg(struct pld_wlan_enable_cfg *cfg) 2637 { 2638 int i; 2639 QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR, 2640 "%s: num_config %d", __func__, cfg->num_shadow_reg_v2_cfg); 2641 2642 for (i = 0; i < cfg->num_shadow_reg_v2_cfg; i++) { 2643 QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_INFO, 2644 "%s: i %d, val %x", __func__, i, 2645 cfg->shadow_reg_v2_cfg[i].addr); 2646 } 2647 } 2648 2649 #else 2650 static void hif_print_hal_shadow_register_cfg(struct pld_wlan_enable_cfg *cfg) 2651 { 2652 QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR, 2653 "%s: CONFIG_SHADOW_V2 not defined", __func__); 2654 } 2655 #endif 2656 2657 /** 2658 * hif_wlan_enable(): call the platform driver to enable wlan 2659 * @scn: HIF Context 2660 * 2661 * This function passes the con_mode and CE configuration to 2662 * platform driver to enable wlan. 2663 * 2664 * Return: linux error code 2665 */ 2666 int hif_wlan_enable(struct hif_softc *scn) 2667 { 2668 struct pld_wlan_enable_cfg cfg; 2669 enum pld_driver_mode mode; 2670 uint32_t con_mode = hif_get_conparam(scn); 2671 2672 hif_get_target_ce_config(scn, 2673 (struct CE_pipe_config **)&cfg.ce_tgt_cfg, 2674 &cfg.num_ce_tgt_cfg, 2675 (struct service_to_pipe **)&cfg.ce_svc_cfg, 2676 &cfg.num_ce_svc_pipe_cfg, 2677 (struct shadow_reg_cfg **)&cfg.shadow_reg_cfg, 2678 &cfg.num_shadow_reg_cfg); 2679 2680 /* translate from structure size to array size */ 2681 cfg.num_ce_tgt_cfg /= sizeof(struct CE_pipe_config); 2682 cfg.num_ce_svc_pipe_cfg /= sizeof(struct service_to_pipe); 2683 cfg.num_shadow_reg_cfg /= sizeof(struct shadow_reg_cfg); 2684 2685 hif_prepare_hal_shadow_register_cfg(scn, &cfg.shadow_reg_v2_cfg, 2686 &cfg.num_shadow_reg_v2_cfg); 2687 2688 hif_print_hal_shadow_register_cfg(&cfg); 2689 2690 if (QDF_GLOBAL_FTM_MODE == con_mode) 2691 mode = PLD_FTM; 2692 else if (QDF_GLOBAL_COLDBOOT_CALIB_MODE == con_mode) 2693 mode = PLD_COLDBOOT_CALIBRATION; 2694 else if (QDF_IS_EPPING_ENABLED(con_mode)) 2695 mode = PLD_EPPING; 2696 else 2697 mode = PLD_MISSION; 2698 2699 if (BYPASS_QMI) 2700 return 0; 2701 else 2702 return pld_wlan_enable(scn->qdf_dev->dev, &cfg, 2703 mode, QWLAN_VERSIONSTR); 2704 } 2705 2706 #ifdef WLAN_FEATURE_EPPING 2707 2708 #define CE_EPPING_USES_IRQ true 2709 2710 void hif_ce_prepare_epping_config(struct HIF_CE_state *hif_state) 2711 { 2712 if (CE_EPPING_USES_IRQ) 2713 hif_state->host_ce_config = host_ce_config_wlan_epping_irq; 2714 else 2715 hif_state->host_ce_config = host_ce_config_wlan_epping_poll; 2716 hif_state->target_ce_config = target_ce_config_wlan_epping; 2717 hif_state->target_ce_config_sz = sizeof(target_ce_config_wlan_epping); 2718 target_shadow_reg_cfg = target_shadow_reg_cfg_epping; 2719 shadow_cfg_sz = sizeof(target_shadow_reg_cfg_epping); 2720 } 2721 #endif 2722 2723 #ifdef QCN7605_SUPPORT 2724 static inline 2725 void hif_set_ce_config_qcn7605(struct hif_softc *scn, 2726 struct HIF_CE_state *hif_state) 2727 { 2728 hif_state->host_ce_config = host_ce_config_wlan_qcn7605; 2729 hif_state->target_ce_config = target_ce_config_wlan_qcn7605; 2730 hif_state->target_ce_config_sz = 2731 sizeof(target_ce_config_wlan_qcn7605); 2732 scn->ce_count = QCN7605_CE_COUNT; 2733 } 2734 #else 2735 static inline 2736 void hif_set_ce_config_qcn7605(struct hif_softc *scn, 2737 struct HIF_CE_state *hif_state) 2738 { 2739 HIF_ERROR("QCN7605 not supported"); 2740 } 2741 #endif 2742 2743 /** 2744 * hif_ce_prepare_config() - load the correct static tables. 2745 * @scn: hif context 2746 * 2747 * Epping uses different static attribute tables than mission mode. 2748 */ 2749 void hif_ce_prepare_config(struct hif_softc *scn) 2750 { 2751 uint32_t mode = hif_get_conparam(scn); 2752 struct hif_opaque_softc *hif_hdl = GET_HIF_OPAQUE_HDL(scn); 2753 struct hif_target_info *tgt_info = hif_get_target_info_handle(hif_hdl); 2754 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2755 2756 hif_state->ce_services = ce_services_attach(scn); 2757 2758 scn->ce_count = HOST_CE_COUNT; 2759 /* if epping is enabled we need to use the epping configuration. */ 2760 if (QDF_IS_EPPING_ENABLED(mode)) { 2761 hif_ce_prepare_epping_config(hif_state); 2762 } 2763 2764 switch (tgt_info->target_type) { 2765 default: 2766 hif_state->host_ce_config = host_ce_config_wlan; 2767 hif_state->target_ce_config = target_ce_config_wlan; 2768 hif_state->target_ce_config_sz = sizeof(target_ce_config_wlan); 2769 break; 2770 case TARGET_TYPE_QCN7605: 2771 hif_set_ce_config_qcn7605(scn, hif_state); 2772 break; 2773 case TARGET_TYPE_AR900B: 2774 case TARGET_TYPE_QCA9984: 2775 case TARGET_TYPE_IPQ4019: 2776 case TARGET_TYPE_QCA9888: 2777 if (hif_is_attribute_set(scn, HIF_LOWDESC_CE_NO_PKTLOG_CFG)) { 2778 hif_state->host_ce_config = 2779 host_lowdesc_ce_cfg_wlan_ar900b_nopktlog; 2780 } else if (hif_is_attribute_set(scn, HIF_LOWDESC_CE_CFG)) { 2781 hif_state->host_ce_config = 2782 host_lowdesc_ce_cfg_wlan_ar900b; 2783 } else { 2784 hif_state->host_ce_config = host_ce_config_wlan_ar900b; 2785 } 2786 2787 hif_state->target_ce_config = target_ce_config_wlan_ar900b; 2788 hif_state->target_ce_config_sz = 2789 sizeof(target_ce_config_wlan_ar900b); 2790 2791 break; 2792 2793 case TARGET_TYPE_AR9888: 2794 case TARGET_TYPE_AR9888V2: 2795 if (hif_is_attribute_set(scn, HIF_LOWDESC_CE_CFG)) { 2796 hif_state->host_ce_config = host_lowdesc_ce_cfg_wlan_ar9888; 2797 } else { 2798 hif_state->host_ce_config = host_ce_config_wlan_ar9888; 2799 } 2800 2801 hif_state->target_ce_config = target_ce_config_wlan_ar9888; 2802 hif_state->target_ce_config_sz = 2803 sizeof(target_ce_config_wlan_ar9888); 2804 2805 break; 2806 2807 case TARGET_TYPE_QCA8074: 2808 case TARGET_TYPE_QCA8074V2: 2809 if (scn->bus_type == QDF_BUS_TYPE_PCI) { 2810 hif_state->host_ce_config = 2811 host_ce_config_wlan_qca8074_pci; 2812 hif_state->target_ce_config = 2813 target_ce_config_wlan_qca8074_pci; 2814 hif_state->target_ce_config_sz = 2815 sizeof(target_ce_config_wlan_qca8074_pci); 2816 } else { 2817 hif_state->host_ce_config = host_ce_config_wlan_qca8074; 2818 hif_state->target_ce_config = 2819 target_ce_config_wlan_qca8074; 2820 hif_state->target_ce_config_sz = 2821 sizeof(target_ce_config_wlan_qca8074); 2822 } 2823 break; 2824 case TARGET_TYPE_QCA6290: 2825 hif_state->host_ce_config = host_ce_config_wlan_qca6290; 2826 hif_state->target_ce_config = target_ce_config_wlan_qca6290; 2827 hif_state->target_ce_config_sz = 2828 sizeof(target_ce_config_wlan_qca6290); 2829 2830 scn->ce_count = QCA_6290_CE_COUNT; 2831 break; 2832 case TARGET_TYPE_QCA6390: 2833 hif_state->host_ce_config = host_ce_config_wlan_qca6390; 2834 hif_state->target_ce_config = target_ce_config_wlan_qca6390; 2835 hif_state->target_ce_config_sz = 2836 sizeof(target_ce_config_wlan_qca6390); 2837 2838 scn->ce_count = QCA_6390_CE_COUNT; 2839 break; 2840 } 2841 QDF_BUG(scn->ce_count <= CE_COUNT_MAX); 2842 } 2843 2844 /** 2845 * hif_ce_open() - do ce specific allocations 2846 * @hif_sc: pointer to hif context 2847 * 2848 * return: 0 for success or QDF_STATUS_E_NOMEM 2849 */ 2850 QDF_STATUS hif_ce_open(struct hif_softc *hif_sc) 2851 { 2852 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_sc); 2853 2854 qdf_spinlock_create(&hif_state->irq_reg_lock); 2855 qdf_spinlock_create(&hif_state->keep_awake_lock); 2856 return QDF_STATUS_SUCCESS; 2857 } 2858 2859 /** 2860 * hif_ce_close() - do ce specific free 2861 * @hif_sc: pointer to hif context 2862 */ 2863 void hif_ce_close(struct hif_softc *hif_sc) 2864 { 2865 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_sc); 2866 2867 qdf_spinlock_destroy(&hif_state->irq_reg_lock); 2868 qdf_spinlock_destroy(&hif_state->keep_awake_lock); 2869 } 2870 2871 /** 2872 * hif_unconfig_ce() - ensure resources from hif_config_ce are freed 2873 * @hif_sc: hif context 2874 * 2875 * uses state variables to support cleaning up when hif_config_ce fails. 2876 */ 2877 void hif_unconfig_ce(struct hif_softc *hif_sc) 2878 { 2879 int pipe_num; 2880 struct HIF_CE_pipe_info *pipe_info; 2881 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(hif_sc); 2882 struct hif_opaque_softc *hif_hdl = GET_HIF_OPAQUE_HDL(hif_sc); 2883 2884 for (pipe_num = 0; pipe_num < hif_sc->ce_count; pipe_num++) { 2885 pipe_info = &hif_state->pipe_info[pipe_num]; 2886 if (pipe_info->ce_hdl) { 2887 ce_unregister_irq(hif_state, (1 << pipe_num)); 2888 } 2889 } 2890 deinit_tasklet_workers(hif_hdl); 2891 for (pipe_num = 0; pipe_num < hif_sc->ce_count; pipe_num++) { 2892 pipe_info = &hif_state->pipe_info[pipe_num]; 2893 if (pipe_info->ce_hdl) { 2894 ce_fini(pipe_info->ce_hdl); 2895 pipe_info->ce_hdl = NULL; 2896 pipe_info->buf_sz = 0; 2897 qdf_spinlock_destroy(&pipe_info->recv_bufs_needed_lock); 2898 } 2899 } 2900 if (hif_sc->athdiag_procfs_inited) { 2901 athdiag_procfs_remove(); 2902 hif_sc->athdiag_procfs_inited = false; 2903 } 2904 } 2905 2906 #ifdef CONFIG_BYPASS_QMI 2907 #define FW_SHARED_MEM (2 * 1024 * 1024) 2908 2909 /** 2910 * hif_post_static_buf_to_target() - post static buffer to WLAN FW 2911 * @scn: pointer to HIF structure 2912 * 2913 * WLAN FW needs 2MB memory from DDR when QMI is disabled. 2914 * 2915 * Return: void 2916 */ 2917 static void hif_post_static_buf_to_target(struct hif_softc *scn) 2918 { 2919 void *target_va; 2920 phys_addr_t target_pa; 2921 2922 target_va = qdf_mem_alloc_consistent(scn->qdf_dev, scn->qdf_dev->dev, 2923 FW_SHARED_MEM, &target_pa); 2924 if (NULL == target_va) { 2925 HIF_TRACE("Memory allocation failed could not post target buf"); 2926 return; 2927 } 2928 hif_write32_mb(scn, scn->mem + BYPASS_QMI_TEMP_REGISTER, target_pa); 2929 HIF_TRACE("target va %pK target pa %pa", target_va, &target_pa); 2930 } 2931 #else 2932 static inline void hif_post_static_buf_to_target(struct hif_softc *scn) 2933 { 2934 } 2935 #endif 2936 2937 static int hif_srng_sleep_state_adjust(struct hif_softc *scn, bool sleep_ok, 2938 bool wait_for_it) 2939 { 2940 /* todo */ 2941 return 0; 2942 } 2943 2944 /** 2945 * hif_config_ce() - configure copy engines 2946 * @scn: hif context 2947 * 2948 * Prepares fw, copy engine hardware and host sw according 2949 * to the attributes selected by hif_ce_prepare_config. 2950 * 2951 * also calls athdiag_procfs_init 2952 * 2953 * return: 0 for success nonzero for failure. 2954 */ 2955 int hif_config_ce(struct hif_softc *scn) 2956 { 2957 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 2958 struct hif_opaque_softc *hif_hdl = GET_HIF_OPAQUE_HDL(scn); 2959 struct HIF_CE_pipe_info *pipe_info; 2960 int pipe_num; 2961 struct CE_state *ce_state = NULL; 2962 2963 #ifdef ADRASTEA_SHADOW_REGISTERS 2964 int i; 2965 #endif 2966 QDF_STATUS rv = QDF_STATUS_SUCCESS; 2967 2968 scn->notice_send = true; 2969 scn->ce_service_max_rx_ind_flush = MSG_FLUSH_NUM; 2970 2971 hif_post_static_buf_to_target(scn); 2972 2973 hif_state->fw_indicator_address = FW_INDICATOR_ADDRESS; 2974 2975 hif_config_rri_on_ddr(scn); 2976 2977 if (ce_srng_based(scn)) 2978 scn->bus_ops.hif_target_sleep_state_adjust = 2979 &hif_srng_sleep_state_adjust; 2980 2981 /* Initialise the CE debug history sysfs interface inputs ce_id and 2982 * index. Disable data storing 2983 */ 2984 reset_ce_debug_history(scn); 2985 2986 for (pipe_num = 0; pipe_num < scn->ce_count; pipe_num++) { 2987 struct CE_attr *attr; 2988 2989 pipe_info = &hif_state->pipe_info[pipe_num]; 2990 pipe_info->pipe_num = pipe_num; 2991 pipe_info->HIF_CE_state = hif_state; 2992 attr = &hif_state->host_ce_config[pipe_num]; 2993 2994 pipe_info->ce_hdl = ce_init(scn, pipe_num, attr); 2995 ce_state = scn->ce_id_to_state[pipe_num]; 2996 if (!ce_state) { 2997 A_TARGET_ACCESS_UNLIKELY(scn); 2998 goto err; 2999 } 3000 qdf_spinlock_create(&pipe_info->recv_bufs_needed_lock); 3001 QDF_ASSERT(pipe_info->ce_hdl != NULL); 3002 if (pipe_info->ce_hdl == NULL) { 3003 rv = QDF_STATUS_E_FAILURE; 3004 A_TARGET_ACCESS_UNLIKELY(scn); 3005 goto err; 3006 } 3007 3008 ce_state->lro_data = qdf_lro_init(); 3009 3010 if (attr->flags & CE_ATTR_DIAG) { 3011 /* Reserve the ultimate CE for 3012 * Diagnostic Window support 3013 */ 3014 hif_state->ce_diag = pipe_info->ce_hdl; 3015 continue; 3016 } 3017 3018 if (hif_is_nss_wifi_enabled(scn) && ce_state && 3019 (ce_state->htt_rx_data)) 3020 continue; 3021 3022 pipe_info->buf_sz = (qdf_size_t) (attr->src_sz_max); 3023 if (attr->dest_nentries > 0) { 3024 atomic_set(&pipe_info->recv_bufs_needed, 3025 init_buffer_count(attr->dest_nentries - 1)); 3026 /*SRNG based CE has one entry less */ 3027 if (ce_srng_based(scn)) 3028 atomic_dec(&pipe_info->recv_bufs_needed); 3029 } else { 3030 atomic_set(&pipe_info->recv_bufs_needed, 0); 3031 } 3032 ce_tasklet_init(hif_state, (1 << pipe_num)); 3033 ce_register_irq(hif_state, (1 << pipe_num)); 3034 } 3035 3036 if (athdiag_procfs_init(scn) != 0) { 3037 A_TARGET_ACCESS_UNLIKELY(scn); 3038 goto err; 3039 } 3040 scn->athdiag_procfs_inited = true; 3041 3042 HIF_DBG("%s: ce_init done", __func__); 3043 3044 init_tasklet_workers(hif_hdl); 3045 3046 HIF_DBG("%s: X, ret = %d", __func__, rv); 3047 3048 #ifdef ADRASTEA_SHADOW_REGISTERS 3049 HIF_DBG("%s, Using Shadow Registers instead of CE Registers", __func__); 3050 for (i = 0; i < NUM_SHADOW_REGISTERS; i++) { 3051 HIF_DBG("%s Shadow Register%d is mapped to address %x", 3052 __func__, i, 3053 (A_TARGET_READ(scn, (SHADOW_ADDRESS(i))) << 2)); 3054 } 3055 #endif 3056 3057 return rv != QDF_STATUS_SUCCESS; 3058 3059 err: 3060 /* Failure, so clean up */ 3061 hif_unconfig_ce(scn); 3062 HIF_TRACE("%s: X, ret = %d", __func__, rv); 3063 return QDF_STATUS_SUCCESS != QDF_STATUS_E_FAILURE; 3064 } 3065 3066 #ifdef WLAN_FEATURE_FASTPATH 3067 /** 3068 * hif_ce_fastpath_cb_register() - Register callback for fastpath msg handler 3069 * @handler: Callback funtcion 3070 * @context: handle for callback function 3071 * 3072 * Return: QDF_STATUS_SUCCESS on success or QDF_STATUS_E_FAILURE 3073 */ 3074 int hif_ce_fastpath_cb_register(struct hif_opaque_softc *hif_ctx, 3075 fastpath_msg_handler handler, 3076 void *context) 3077 { 3078 struct CE_state *ce_state; 3079 struct hif_softc *scn = HIF_GET_SOFTC(hif_ctx); 3080 int i; 3081 3082 if (!scn) { 3083 HIF_ERROR("%s: scn is NULL", __func__); 3084 QDF_ASSERT(0); 3085 return QDF_STATUS_E_FAILURE; 3086 } 3087 3088 if (!scn->fastpath_mode_on) { 3089 HIF_WARN("%s: Fastpath mode disabled", __func__); 3090 return QDF_STATUS_E_FAILURE; 3091 } 3092 3093 for (i = 0; i < scn->ce_count; i++) { 3094 ce_state = scn->ce_id_to_state[i]; 3095 if (ce_state->htt_rx_data) { 3096 ce_state->fastpath_handler = handler; 3097 ce_state->context = context; 3098 } 3099 } 3100 3101 return QDF_STATUS_SUCCESS; 3102 } 3103 qdf_export_symbol(hif_ce_fastpath_cb_register); 3104 #endif 3105 3106 #ifdef IPA_OFFLOAD 3107 /** 3108 * hif_ce_ipa_get_ce_resource() - get uc resource on hif 3109 * @scn: bus context 3110 * @ce_sr_base_paddr: copyengine source ring base physical address 3111 * @ce_sr_ring_size: copyengine source ring size 3112 * @ce_reg_paddr: copyengine register physical address 3113 * 3114 * IPA micro controller data path offload feature enabled, 3115 * HIF should release copy engine related resource information to IPA UC 3116 * IPA UC will access hardware resource with released information 3117 * 3118 * Return: None 3119 */ 3120 void hif_ce_ipa_get_ce_resource(struct hif_softc *scn, 3121 qdf_shared_mem_t **ce_sr, 3122 uint32_t *ce_sr_ring_size, 3123 qdf_dma_addr_t *ce_reg_paddr) 3124 { 3125 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 3126 struct HIF_CE_pipe_info *pipe_info = 3127 &(hif_state->pipe_info[HIF_PCI_IPA_UC_ASSIGNED_CE]); 3128 struct CE_handle *ce_hdl = pipe_info->ce_hdl; 3129 3130 ce_ipa_get_resource(ce_hdl, ce_sr, ce_sr_ring_size, 3131 ce_reg_paddr); 3132 } 3133 #endif /* IPA_OFFLOAD */ 3134 3135 3136 #ifdef ADRASTEA_SHADOW_REGISTERS 3137 3138 /* 3139 * Current shadow register config 3140 * 3141 * ----------------------------------------------------------- 3142 * Shadow Register | CE | src/dst write index 3143 * ----------------------------------------------------------- 3144 * 0 | 0 | src 3145 * 1 No Config - Doesn't point to anything 3146 * 2 No Config - Doesn't point to anything 3147 * 3 | 3 | src 3148 * 4 | 4 | src 3149 * 5 | 5 | src 3150 * 6 No Config - Doesn't point to anything 3151 * 7 | 7 | src 3152 * 8 No Config - Doesn't point to anything 3153 * 9 No Config - Doesn't point to anything 3154 * 10 No Config - Doesn't point to anything 3155 * 11 No Config - Doesn't point to anything 3156 * ----------------------------------------------------------- 3157 * 12 No Config - Doesn't point to anything 3158 * 13 | 1 | dst 3159 * 14 | 2 | dst 3160 * 15 No Config - Doesn't point to anything 3161 * 16 No Config - Doesn't point to anything 3162 * 17 No Config - Doesn't point to anything 3163 * 18 No Config - Doesn't point to anything 3164 * 19 | 7 | dst 3165 * 20 | 8 | dst 3166 * 21 No Config - Doesn't point to anything 3167 * 22 No Config - Doesn't point to anything 3168 * 23 No Config - Doesn't point to anything 3169 * ----------------------------------------------------------- 3170 * 3171 * 3172 * ToDo - Move shadow register config to following in the future 3173 * This helps free up a block of shadow registers towards the end. 3174 * Can be used for other purposes 3175 * 3176 * ----------------------------------------------------------- 3177 * Shadow Register | CE | src/dst write index 3178 * ----------------------------------------------------------- 3179 * 0 | 0 | src 3180 * 1 | 3 | src 3181 * 2 | 4 | src 3182 * 3 | 5 | src 3183 * 4 | 7 | src 3184 * ----------------------------------------------------------- 3185 * 5 | 1 | dst 3186 * 6 | 2 | dst 3187 * 7 | 7 | dst 3188 * 8 | 8 | dst 3189 * ----------------------------------------------------------- 3190 * 9 No Config - Doesn't point to anything 3191 * 12 No Config - Doesn't point to anything 3192 * 13 No Config - Doesn't point to anything 3193 * 14 No Config - Doesn't point to anything 3194 * 15 No Config - Doesn't point to anything 3195 * 16 No Config - Doesn't point to anything 3196 * 17 No Config - Doesn't point to anything 3197 * 18 No Config - Doesn't point to anything 3198 * 19 No Config - Doesn't point to anything 3199 * 20 No Config - Doesn't point to anything 3200 * 21 No Config - Doesn't point to anything 3201 * 22 No Config - Doesn't point to anything 3202 * 23 No Config - Doesn't point to anything 3203 * ----------------------------------------------------------- 3204 */ 3205 #ifndef QCN7605_SUPPORT 3206 u32 shadow_sr_wr_ind_addr(struct hif_softc *scn, u32 ctrl_addr) 3207 { 3208 u32 addr = 0; 3209 u32 ce = COPY_ENGINE_ID(ctrl_addr); 3210 3211 switch (ce) { 3212 case 0: 3213 addr = SHADOW_VALUE0; 3214 break; 3215 case 3: 3216 addr = SHADOW_VALUE3; 3217 break; 3218 case 4: 3219 addr = SHADOW_VALUE4; 3220 break; 3221 case 5: 3222 addr = SHADOW_VALUE5; 3223 break; 3224 case 7: 3225 addr = SHADOW_VALUE7; 3226 break; 3227 default: 3228 HIF_ERROR("invalid CE ctrl_addr (CE=%d)", ce); 3229 QDF_ASSERT(0); 3230 } 3231 return addr; 3232 3233 } 3234 3235 u32 shadow_dst_wr_ind_addr(struct hif_softc *scn, u32 ctrl_addr) 3236 { 3237 u32 addr = 0; 3238 u32 ce = COPY_ENGINE_ID(ctrl_addr); 3239 3240 switch (ce) { 3241 case 1: 3242 addr = SHADOW_VALUE13; 3243 break; 3244 case 2: 3245 addr = SHADOW_VALUE14; 3246 break; 3247 case 5: 3248 addr = SHADOW_VALUE17; 3249 break; 3250 case 7: 3251 addr = SHADOW_VALUE19; 3252 break; 3253 case 8: 3254 addr = SHADOW_VALUE20; 3255 break; 3256 case 9: 3257 addr = SHADOW_VALUE21; 3258 break; 3259 case 10: 3260 addr = SHADOW_VALUE22; 3261 break; 3262 case 11: 3263 addr = SHADOW_VALUE23; 3264 break; 3265 default: 3266 HIF_ERROR("invalid CE ctrl_addr (CE=%d)", ce); 3267 QDF_ASSERT(0); 3268 } 3269 3270 return addr; 3271 3272 } 3273 #else 3274 u32 shadow_sr_wr_ind_addr(struct hif_softc *scn, u32 ctrl_addr) 3275 { 3276 u32 addr = 0; 3277 u32 ce = COPY_ENGINE_ID(ctrl_addr); 3278 3279 switch (ce) { 3280 case 0: 3281 addr = SHADOW_VALUE0; 3282 break; 3283 case 4: 3284 addr = SHADOW_VALUE4; 3285 break; 3286 case 5: 3287 addr = SHADOW_VALUE5; 3288 break; 3289 default: 3290 HIF_ERROR("invalid CE ctrl_addr (CE=%d)", ce); 3291 QDF_ASSERT(0); 3292 } 3293 return addr; 3294 } 3295 3296 u32 shadow_dst_wr_ind_addr(struct hif_softc *scn, u32 ctrl_addr) 3297 { 3298 u32 addr = 0; 3299 u32 ce = COPY_ENGINE_ID(ctrl_addr); 3300 3301 switch (ce) { 3302 case 1: 3303 addr = SHADOW_VALUE13; 3304 break; 3305 case 2: 3306 addr = SHADOW_VALUE14; 3307 break; 3308 case 3: 3309 addr = SHADOW_VALUE15; 3310 break; 3311 case 5: 3312 addr = SHADOW_VALUE17; 3313 break; 3314 case 7: 3315 addr = SHADOW_VALUE19; 3316 break; 3317 case 8: 3318 addr = SHADOW_VALUE20; 3319 break; 3320 case 9: 3321 addr = SHADOW_VALUE21; 3322 break; 3323 case 10: 3324 addr = SHADOW_VALUE22; 3325 break; 3326 case 11: 3327 addr = SHADOW_VALUE23; 3328 break; 3329 default: 3330 HIF_ERROR("invalid CE ctrl_addr (CE=%d)", ce); 3331 QDF_ASSERT(0); 3332 } 3333 3334 return addr; 3335 } 3336 #endif 3337 #endif 3338 3339 #if defined(FEATURE_LRO) 3340 void *hif_ce_get_lro_ctx(struct hif_opaque_softc *hif_hdl, int ctx_id) 3341 { 3342 struct CE_state *ce_state; 3343 struct hif_softc *scn = HIF_GET_SOFTC(hif_hdl); 3344 3345 ce_state = scn->ce_id_to_state[ctx_id]; 3346 3347 return ce_state->lro_data; 3348 } 3349 #endif 3350 3351 /** 3352 * hif_map_service_to_pipe() - returns the ce ids pertaining to 3353 * this service 3354 * @scn: hif_softc pointer. 3355 * @svc_id: Service ID for which the mapping is needed. 3356 * @ul_pipe: address of the container in which ul pipe is returned. 3357 * @dl_pipe: address of the container in which dl pipe is returned. 3358 * @ul_is_polled: address of the container in which a bool 3359 * indicating if the UL CE for this service 3360 * is polled is returned. 3361 * @dl_is_polled: address of the container in which a bool 3362 * indicating if the DL CE for this service 3363 * is polled is returned. 3364 * 3365 * Return: Indicates whether the service has been found in the table. 3366 * Upon return, ul_is_polled is updated only if ul_pipe is updated. 3367 * There will be warning logs if either leg has not been updated 3368 * because it missed the entry in the table (but this is not an err). 3369 */ 3370 int hif_map_service_to_pipe(struct hif_opaque_softc *hif_hdl, uint16_t svc_id, 3371 uint8_t *ul_pipe, uint8_t *dl_pipe, int *ul_is_polled, 3372 int *dl_is_polled) 3373 { 3374 int status = QDF_STATUS_E_INVAL; 3375 unsigned int i; 3376 struct service_to_pipe element; 3377 struct service_to_pipe *tgt_svc_map_to_use; 3378 uint32_t sz_tgt_svc_map_to_use; 3379 struct hif_softc *scn = HIF_GET_SOFTC(hif_hdl); 3380 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 3381 bool dl_updated = false; 3382 bool ul_updated = false; 3383 3384 hif_select_service_to_pipe_map(scn, &tgt_svc_map_to_use, 3385 &sz_tgt_svc_map_to_use); 3386 3387 *dl_is_polled = 0; /* polling for received messages not supported */ 3388 3389 for (i = 0; i < (sz_tgt_svc_map_to_use/sizeof(element)); i++) { 3390 3391 memcpy(&element, &tgt_svc_map_to_use[i], sizeof(element)); 3392 if (element.service_id == svc_id) { 3393 if (element.pipedir == PIPEDIR_OUT) { 3394 *ul_pipe = element.pipenum; 3395 *ul_is_polled = 3396 (hif_state->host_ce_config[*ul_pipe].flags & 3397 CE_ATTR_DISABLE_INTR) != 0; 3398 ul_updated = true; 3399 } else if (element.pipedir == PIPEDIR_IN) { 3400 *dl_pipe = element.pipenum; 3401 dl_updated = true; 3402 } 3403 status = QDF_STATUS_SUCCESS; 3404 } 3405 } 3406 if (ul_updated == false) 3407 HIF_DBG("ul pipe is NOT updated for service %d", svc_id); 3408 if (dl_updated == false) 3409 HIF_DBG("dl pipe is NOT updated for service %d", svc_id); 3410 3411 return status; 3412 } 3413 3414 #ifdef SHADOW_REG_DEBUG 3415 inline uint32_t DEBUG_CE_SRC_RING_READ_IDX_GET(struct hif_softc *scn, 3416 uint32_t CE_ctrl_addr) 3417 { 3418 uint32_t read_from_hw, srri_from_ddr = 0; 3419 3420 read_from_hw = A_TARGET_READ(scn, CE_ctrl_addr + CURRENT_SRRI_ADDRESS); 3421 3422 srri_from_ddr = SRRI_FROM_DDR_ADDR(VADDR_FOR_CE(scn, CE_ctrl_addr)); 3423 3424 if (read_from_hw != srri_from_ddr) { 3425 HIF_ERROR("%s: error: read from ddr = %d actual read from register = %d, CE_MISC_INT_STATUS_GET = 0x%x", 3426 __func__, srri_from_ddr, read_from_hw, 3427 CE_MISC_INT_STATUS_GET(scn, CE_ctrl_addr)); 3428 QDF_ASSERT(0); 3429 } 3430 return srri_from_ddr; 3431 } 3432 3433 3434 inline uint32_t DEBUG_CE_DEST_RING_READ_IDX_GET(struct hif_softc *scn, 3435 uint32_t CE_ctrl_addr) 3436 { 3437 uint32_t read_from_hw, drri_from_ddr = 0; 3438 3439 read_from_hw = A_TARGET_READ(scn, CE_ctrl_addr + CURRENT_DRRI_ADDRESS); 3440 3441 drri_from_ddr = DRRI_FROM_DDR_ADDR(VADDR_FOR_CE(scn, CE_ctrl_addr)); 3442 3443 if (read_from_hw != drri_from_ddr) { 3444 HIF_ERROR("error: read from ddr = %d actual read from register = %d, CE_MISC_INT_STATUS_GET = 0x%x", 3445 drri_from_ddr, read_from_hw, 3446 CE_MISC_INT_STATUS_GET(scn, CE_ctrl_addr)); 3447 QDF_ASSERT(0); 3448 } 3449 return drri_from_ddr; 3450 } 3451 3452 #endif 3453 3454 #ifdef ADRASTEA_RRI_ON_DDR 3455 /** 3456 * hif_get_src_ring_read_index(): Called to get the SRRI 3457 * 3458 * @scn: hif_softc pointer 3459 * @CE_ctrl_addr: base address of the CE whose RRI is to be read 3460 * 3461 * This function returns the SRRI to the caller. For CEs that 3462 * dont have interrupts enabled, we look at the DDR based SRRI 3463 * 3464 * Return: SRRI 3465 */ 3466 inline unsigned int hif_get_src_ring_read_index(struct hif_softc *scn, 3467 uint32_t CE_ctrl_addr) 3468 { 3469 struct CE_attr attr; 3470 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 3471 3472 attr = hif_state->host_ce_config[COPY_ENGINE_ID(CE_ctrl_addr)]; 3473 if (attr.flags & CE_ATTR_DISABLE_INTR) { 3474 return CE_SRC_RING_READ_IDX_GET_FROM_DDR(scn, CE_ctrl_addr); 3475 } else { 3476 if (TARGET_REGISTER_ACCESS_ALLOWED(scn)) 3477 return A_TARGET_READ(scn, 3478 (CE_ctrl_addr) + CURRENT_SRRI_ADDRESS); 3479 else 3480 return CE_SRC_RING_READ_IDX_GET_FROM_DDR(scn, 3481 CE_ctrl_addr); 3482 } 3483 } 3484 3485 /** 3486 * hif_get_dst_ring_read_index(): Called to get the DRRI 3487 * 3488 * @scn: hif_softc pointer 3489 * @CE_ctrl_addr: base address of the CE whose RRI is to be read 3490 * 3491 * This function returns the DRRI to the caller. For CEs that 3492 * dont have interrupts enabled, we look at the DDR based DRRI 3493 * 3494 * Return: DRRI 3495 */ 3496 inline unsigned int hif_get_dst_ring_read_index(struct hif_softc *scn, 3497 uint32_t CE_ctrl_addr) 3498 { 3499 struct CE_attr attr; 3500 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 3501 3502 attr = hif_state->host_ce_config[COPY_ENGINE_ID(CE_ctrl_addr)]; 3503 3504 if (attr.flags & CE_ATTR_DISABLE_INTR) { 3505 return CE_DEST_RING_READ_IDX_GET_FROM_DDR(scn, CE_ctrl_addr); 3506 } else { 3507 if (TARGET_REGISTER_ACCESS_ALLOWED(scn)) 3508 return A_TARGET_READ(scn, 3509 (CE_ctrl_addr) + CURRENT_DRRI_ADDRESS); 3510 else 3511 return CE_DEST_RING_READ_IDX_GET_FROM_DDR(scn, 3512 CE_ctrl_addr); 3513 } 3514 } 3515 3516 /** 3517 * hif_config_rri_on_ddr(): Configure the RRI on DDR mechanism 3518 * 3519 * @scn: hif_softc pointer 3520 * 3521 * This function allocates non cached memory on ddr and sends 3522 * the physical address of this memory to the CE hardware. The 3523 * hardware updates the RRI on this particular location. 3524 * 3525 * Return: None 3526 */ 3527 static inline void hif_config_rri_on_ddr(struct hif_softc *scn) 3528 { 3529 unsigned int i; 3530 qdf_dma_addr_t paddr_rri_on_ddr; 3531 uint32_t high_paddr, low_paddr; 3532 3533 scn->vaddr_rri_on_ddr = 3534 (uint32_t *)qdf_mem_alloc_consistent(scn->qdf_dev, 3535 scn->qdf_dev->dev, (CE_COUNT*sizeof(uint32_t)), 3536 &paddr_rri_on_ddr); 3537 3538 scn->paddr_rri_on_ddr = paddr_rri_on_ddr; 3539 low_paddr = BITS0_TO_31(paddr_rri_on_ddr); 3540 high_paddr = BITS32_TO_35(paddr_rri_on_ddr); 3541 3542 HIF_DBG("%s using srri and drri from DDR", __func__); 3543 3544 WRITE_CE_DDR_ADDRESS_FOR_RRI_LOW(scn, low_paddr); 3545 WRITE_CE_DDR_ADDRESS_FOR_RRI_HIGH(scn, high_paddr); 3546 3547 for (i = 0; i < CE_COUNT; i++) 3548 CE_IDX_UPD_EN_SET(scn, CE_BASE_ADDRESS(i)); 3549 3550 qdf_mem_zero(scn->vaddr_rri_on_ddr, CE_COUNT*sizeof(uint32_t)); 3551 3552 } 3553 #else 3554 3555 /** 3556 * hif_config_rri_on_ddr(): Configure the RRI on DDR mechanism 3557 * 3558 * @scn: hif_softc pointer 3559 * 3560 * This is a dummy implementation for platforms that don't 3561 * support this functionality. 3562 * 3563 * Return: None 3564 */ 3565 static inline void hif_config_rri_on_ddr(struct hif_softc *scn) 3566 { 3567 } 3568 #endif 3569 3570 /** 3571 * hif_dump_ce_registers() - dump ce registers 3572 * @scn: hif_opaque_softc pointer. 3573 * 3574 * Output the copy engine registers 3575 * 3576 * Return: 0 for success or error code 3577 */ 3578 int hif_dump_ce_registers(struct hif_softc *scn) 3579 { 3580 struct hif_opaque_softc *hif_hdl = GET_HIF_OPAQUE_HDL(scn); 3581 uint32_t ce_reg_address = CE0_BASE_ADDRESS; 3582 uint32_t ce_reg_values[CE_USEFUL_SIZE >> 2]; 3583 uint32_t ce_reg_word_size = CE_USEFUL_SIZE >> 2; 3584 uint16_t i; 3585 QDF_STATUS status; 3586 3587 for (i = 0; i < scn->ce_count; i++, ce_reg_address += CE_OFFSET) { 3588 if (scn->ce_id_to_state[i] == NULL) { 3589 HIF_DBG("CE%d not used.", i); 3590 continue; 3591 } 3592 3593 status = hif_diag_read_mem(hif_hdl, ce_reg_address, 3594 (uint8_t *) &ce_reg_values[0], 3595 ce_reg_word_size * sizeof(uint32_t)); 3596 3597 if (status != QDF_STATUS_SUCCESS) { 3598 HIF_ERROR("Dumping CE register failed!"); 3599 return -EACCES; 3600 } 3601 HIF_ERROR("CE%d=>\n", i); 3602 qdf_trace_hex_dump(QDF_MODULE_ID_HIF, QDF_TRACE_LEVEL_DEBUG, 3603 (uint8_t *) &ce_reg_values[0], 3604 ce_reg_word_size * sizeof(uint32_t)); 3605 qdf_print("ADDR:[0x%08X], SR_WR_INDEX:%d", (ce_reg_address 3606 + SR_WR_INDEX_ADDRESS), 3607 ce_reg_values[SR_WR_INDEX_ADDRESS/4]); 3608 qdf_print("ADDR:[0x%08X], CURRENT_SRRI:%d", (ce_reg_address 3609 + CURRENT_SRRI_ADDRESS), 3610 ce_reg_values[CURRENT_SRRI_ADDRESS/4]); 3611 qdf_print("ADDR:[0x%08X], DST_WR_INDEX:%d", (ce_reg_address 3612 + DST_WR_INDEX_ADDRESS), 3613 ce_reg_values[DST_WR_INDEX_ADDRESS/4]); 3614 qdf_print("ADDR:[0x%08X], CURRENT_DRRI:%d", (ce_reg_address 3615 + CURRENT_DRRI_ADDRESS), 3616 ce_reg_values[CURRENT_DRRI_ADDRESS/4]); 3617 qdf_print("---"); 3618 } 3619 return 0; 3620 } 3621 qdf_export_symbol(hif_dump_ce_registers); 3622 #ifdef QCA_NSS_WIFI_OFFLOAD_SUPPORT 3623 struct hif_pipe_addl_info *hif_get_addl_pipe_info(struct hif_opaque_softc *osc, 3624 struct hif_pipe_addl_info *hif_info, uint32_t pipe) 3625 { 3626 struct hif_softc *scn = HIF_GET_SOFTC(osc); 3627 struct hif_pci_softc *sc = HIF_GET_PCI_SOFTC(scn); 3628 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(osc); 3629 struct HIF_CE_pipe_info *pipe_info = &(hif_state->pipe_info[pipe]); 3630 struct CE_handle *ce_hdl = pipe_info->ce_hdl; 3631 struct CE_state *ce_state = (struct CE_state *)ce_hdl; 3632 struct CE_ring_state *src_ring = ce_state->src_ring; 3633 struct CE_ring_state *dest_ring = ce_state->dest_ring; 3634 3635 if (src_ring) { 3636 hif_info->ul_pipe.nentries = src_ring->nentries; 3637 hif_info->ul_pipe.nentries_mask = src_ring->nentries_mask; 3638 hif_info->ul_pipe.sw_index = src_ring->sw_index; 3639 hif_info->ul_pipe.write_index = src_ring->write_index; 3640 hif_info->ul_pipe.hw_index = src_ring->hw_index; 3641 hif_info->ul_pipe.base_addr_CE_space = 3642 src_ring->base_addr_CE_space; 3643 hif_info->ul_pipe.base_addr_owner_space = 3644 src_ring->base_addr_owner_space; 3645 } 3646 3647 3648 if (dest_ring) { 3649 hif_info->dl_pipe.nentries = dest_ring->nentries; 3650 hif_info->dl_pipe.nentries_mask = dest_ring->nentries_mask; 3651 hif_info->dl_pipe.sw_index = dest_ring->sw_index; 3652 hif_info->dl_pipe.write_index = dest_ring->write_index; 3653 hif_info->dl_pipe.hw_index = dest_ring->hw_index; 3654 hif_info->dl_pipe.base_addr_CE_space = 3655 dest_ring->base_addr_CE_space; 3656 hif_info->dl_pipe.base_addr_owner_space = 3657 dest_ring->base_addr_owner_space; 3658 } 3659 3660 hif_info->pci_mem = pci_resource_start(sc->pdev, 0); 3661 hif_info->ctrl_addr = ce_state->ctrl_addr; 3662 3663 return hif_info; 3664 } 3665 qdf_export_symbol(hif_get_addl_pipe_info); 3666 3667 uint32_t hif_set_nss_wifiol_mode(struct hif_opaque_softc *osc, uint32_t mode) 3668 { 3669 struct hif_softc *scn = HIF_GET_SOFTC(osc); 3670 3671 scn->nss_wifi_ol_mode = mode; 3672 return 0; 3673 } 3674 qdf_export_symbol(hif_set_nss_wifiol_mode); 3675 #endif 3676 3677 void hif_set_attribute(struct hif_opaque_softc *osc, uint8_t hif_attrib) 3678 { 3679 struct hif_softc *scn = HIF_GET_SOFTC(osc); 3680 scn->hif_attribute = hif_attrib; 3681 } 3682 3683 3684 /* disable interrupts (only applicable for legacy copy engine currently */ 3685 void hif_disable_interrupt(struct hif_opaque_softc *osc, uint32_t pipe_num) 3686 { 3687 struct hif_softc *scn = HIF_GET_SOFTC(osc); 3688 struct CE_state *CE_state = scn->ce_id_to_state[pipe_num]; 3689 uint32_t ctrl_addr = CE_state->ctrl_addr; 3690 3691 Q_TARGET_ACCESS_BEGIN(scn); 3692 CE_COPY_COMPLETE_INTR_DISABLE(scn, ctrl_addr); 3693 Q_TARGET_ACCESS_END(scn); 3694 } 3695 qdf_export_symbol(hif_disable_interrupt); 3696 3697 /** 3698 * hif_fw_event_handler() - hif fw event handler 3699 * @hif_state: pointer to hif ce state structure 3700 * 3701 * Process fw events and raise HTC callback to process fw events. 3702 * 3703 * Return: none 3704 */ 3705 static inline void hif_fw_event_handler(struct HIF_CE_state *hif_state) 3706 { 3707 struct hif_msg_callbacks *msg_callbacks = 3708 &hif_state->msg_callbacks_current; 3709 3710 if (!msg_callbacks->fwEventHandler) 3711 return; 3712 3713 msg_callbacks->fwEventHandler(msg_callbacks->Context, 3714 QDF_STATUS_E_FAILURE); 3715 } 3716 3717 #ifndef QCA_WIFI_3_0 3718 /** 3719 * hif_fw_interrupt_handler() - FW interrupt handler 3720 * @irq: irq number 3721 * @arg: the user pointer 3722 * 3723 * Called from the PCI interrupt handler when a 3724 * firmware-generated interrupt to the Host. 3725 * 3726 * only registered for legacy ce devices 3727 * 3728 * Return: status of handled irq 3729 */ 3730 irqreturn_t hif_fw_interrupt_handler(int irq, void *arg) 3731 { 3732 struct hif_softc *scn = arg; 3733 struct HIF_CE_state *hif_state = HIF_GET_CE_STATE(scn); 3734 uint32_t fw_indicator_address, fw_indicator; 3735 3736 if (Q_TARGET_ACCESS_BEGIN(scn) < 0) 3737 return ATH_ISR_NOSCHED; 3738 3739 fw_indicator_address = hif_state->fw_indicator_address; 3740 /* For sudden unplug this will return ~0 */ 3741 fw_indicator = A_TARGET_READ(scn, fw_indicator_address); 3742 3743 if ((fw_indicator != ~0) && (fw_indicator & FW_IND_EVENT_PENDING)) { 3744 /* ACK: clear Target-side pending event */ 3745 A_TARGET_WRITE(scn, fw_indicator_address, 3746 fw_indicator & ~FW_IND_EVENT_PENDING); 3747 if (Q_TARGET_ACCESS_END(scn) < 0) 3748 return ATH_ISR_SCHED; 3749 3750 if (hif_state->started) { 3751 hif_fw_event_handler(hif_state); 3752 } else { 3753 /* 3754 * Probable Target failure before we're prepared 3755 * to handle it. Generally unexpected. 3756 * fw_indicator used as bitmap, and defined as below: 3757 * FW_IND_EVENT_PENDING 0x1 3758 * FW_IND_INITIALIZED 0x2 3759 * FW_IND_NEEDRECOVER 0x4 3760 */ 3761 AR_DEBUG_PRINTF(ATH_DEBUG_ERR, 3762 ("%s: Early firmware event indicated 0x%x\n", 3763 __func__, fw_indicator)); 3764 } 3765 } else { 3766 if (Q_TARGET_ACCESS_END(scn) < 0) 3767 return ATH_ISR_SCHED; 3768 } 3769 3770 return ATH_ISR_SCHED; 3771 } 3772 #else 3773 irqreturn_t hif_fw_interrupt_handler(int irq, void *arg) 3774 { 3775 return ATH_ISR_SCHED; 3776 } 3777 #endif /* #ifdef QCA_WIFI_3_0 */ 3778 3779 3780 /** 3781 * hif_wlan_disable(): call the platform driver to disable wlan 3782 * @scn: HIF Context 3783 * 3784 * This function passes the con_mode to platform driver to disable 3785 * wlan. 3786 * 3787 * Return: void 3788 */ 3789 void hif_wlan_disable(struct hif_softc *scn) 3790 { 3791 enum pld_driver_mode mode; 3792 uint32_t con_mode = hif_get_conparam(scn); 3793 3794 if (scn->target_status == TARGET_STATUS_RESET) 3795 return; 3796 3797 if (QDF_GLOBAL_FTM_MODE == con_mode) 3798 mode = PLD_FTM; 3799 else if (QDF_IS_EPPING_ENABLED(con_mode)) 3800 mode = PLD_EPPING; 3801 else 3802 mode = PLD_MISSION; 3803 3804 pld_wlan_disable(scn->qdf_dev->dev, mode); 3805 } 3806 3807 int hif_get_wake_ce_id(struct hif_softc *scn, uint8_t *ce_id) 3808 { 3809 QDF_STATUS status; 3810 uint8_t ul_pipe, dl_pipe; 3811 int ul_is_polled, dl_is_polled; 3812 3813 /* DL pipe for HTC_CTRL_RSVD_SVC should map to the wake CE */ 3814 status = hif_map_service_to_pipe(GET_HIF_OPAQUE_HDL(scn), 3815 HTC_CTRL_RSVD_SVC, 3816 &ul_pipe, &dl_pipe, 3817 &ul_is_polled, &dl_is_polled); 3818 if (status) { 3819 HIF_ERROR("%s: failed to map pipe: %d", __func__, status); 3820 return qdf_status_to_os_return(status); 3821 } 3822 3823 *ce_id = dl_pipe; 3824 3825 return 0; 3826 } 3827