1 // SPDX-License-Identifier: GPL-2.0 2 #include <linux/delay.h> 3 4 #include "nitrox_dev.h" 5 #include "nitrox_csr.h" 6 7 #define PLL_REF_CLK 50 8 #define MAX_CSR_RETRIES 10 9 10 /** 11 * emu_enable_cores - Enable EMU cluster cores. 12 * @ndev: NITROX device 13 */ 14 static void emu_enable_cores(struct nitrox_device *ndev) 15 { 16 union emu_se_enable emu_se; 17 union emu_ae_enable emu_ae; 18 int i; 19 20 /* AE cores 20 per cluster */ 21 emu_ae.value = 0; 22 emu_ae.s.enable = 0xfffff; 23 24 /* SE cores 16 per cluster */ 25 emu_se.value = 0; 26 emu_se.s.enable = 0xffff; 27 28 /* enable per cluster cores */ 29 for (i = 0; i < NR_CLUSTERS; i++) { 30 nitrox_write_csr(ndev, EMU_AE_ENABLEX(i), emu_ae.value); 31 nitrox_write_csr(ndev, EMU_SE_ENABLEX(i), emu_se.value); 32 } 33 } 34 35 /** 36 * nitrox_config_emu_unit - configure EMU unit. 37 * @ndev: NITROX device 38 */ 39 void nitrox_config_emu_unit(struct nitrox_device *ndev) 40 { 41 union emu_wd_int_ena_w1s emu_wd_int; 42 union emu_ge_int_ena_w1s emu_ge_int; 43 u64 offset; 44 int i; 45 46 /* enable cores */ 47 emu_enable_cores(ndev); 48 49 /* enable general error and watch dog interrupts */ 50 emu_ge_int.value = 0; 51 emu_ge_int.s.se_ge = 0xffff; 52 emu_ge_int.s.ae_ge = 0xfffff; 53 emu_wd_int.value = 0; 54 emu_wd_int.s.se_wd = 1; 55 56 for (i = 0; i < NR_CLUSTERS; i++) { 57 offset = EMU_WD_INT_ENA_W1SX(i); 58 nitrox_write_csr(ndev, offset, emu_wd_int.value); 59 offset = EMU_GE_INT_ENA_W1SX(i); 60 nitrox_write_csr(ndev, offset, emu_ge_int.value); 61 } 62 } 63 64 static void reset_pkt_input_ring(struct nitrox_device *ndev, int ring) 65 { 66 union nps_pkt_in_instr_ctl pkt_in_ctl; 67 union nps_pkt_in_done_cnts pkt_in_cnts; 68 int max_retries = MAX_CSR_RETRIES; 69 u64 offset; 70 71 /* step 1: disable the ring, clear enable bit */ 72 offset = NPS_PKT_IN_INSTR_CTLX(ring); 73 pkt_in_ctl.value = nitrox_read_csr(ndev, offset); 74 pkt_in_ctl.s.enb = 0; 75 nitrox_write_csr(ndev, offset, pkt_in_ctl.value); 76 77 /* step 2: wait to clear [ENB] */ 78 usleep_range(100, 150); 79 do { 80 pkt_in_ctl.value = nitrox_read_csr(ndev, offset); 81 if (!pkt_in_ctl.s.enb) 82 break; 83 udelay(50); 84 } while (max_retries--); 85 86 /* step 3: clear done counts */ 87 offset = NPS_PKT_IN_DONE_CNTSX(ring); 88 pkt_in_cnts.value = nitrox_read_csr(ndev, offset); 89 nitrox_write_csr(ndev, offset, pkt_in_cnts.value); 90 usleep_range(50, 100); 91 } 92 93 void enable_pkt_input_ring(struct nitrox_device *ndev, int ring) 94 { 95 union nps_pkt_in_instr_ctl pkt_in_ctl; 96 int max_retries = MAX_CSR_RETRIES; 97 u64 offset; 98 99 /* 64-byte instruction size */ 100 offset = NPS_PKT_IN_INSTR_CTLX(ring); 101 pkt_in_ctl.value = nitrox_read_csr(ndev, offset); 102 pkt_in_ctl.s.is64b = 1; 103 pkt_in_ctl.s.enb = 1; 104 nitrox_write_csr(ndev, offset, pkt_in_ctl.value); 105 106 /* wait for set [ENB] */ 107 do { 108 pkt_in_ctl.value = nitrox_read_csr(ndev, offset); 109 if (pkt_in_ctl.s.enb) 110 break; 111 udelay(50); 112 } while (max_retries--); 113 } 114 115 /** 116 * nitrox_config_pkt_input_rings - configure Packet Input Rings 117 * @ndev: NITROX device 118 */ 119 void nitrox_config_pkt_input_rings(struct nitrox_device *ndev) 120 { 121 int i; 122 123 for (i = 0; i < ndev->nr_queues; i++) { 124 struct nitrox_cmdq *cmdq = &ndev->pkt_inq[i]; 125 union nps_pkt_in_instr_rsize pkt_in_rsize; 126 union nps_pkt_in_instr_baoff_dbell pkt_in_dbell; 127 u64 offset; 128 129 reset_pkt_input_ring(ndev, i); 130 131 /** 132 * step 4: 133 * configure ring base address 16-byte aligned, 134 * size and interrupt threshold. 135 */ 136 offset = NPS_PKT_IN_INSTR_BADDRX(i); 137 nitrox_write_csr(ndev, offset, cmdq->dma); 138 139 /* configure ring size */ 140 offset = NPS_PKT_IN_INSTR_RSIZEX(i); 141 pkt_in_rsize.value = 0; 142 pkt_in_rsize.s.rsize = ndev->qlen; 143 nitrox_write_csr(ndev, offset, pkt_in_rsize.value); 144 145 /* set high threshold for pkt input ring interrupts */ 146 offset = NPS_PKT_IN_INT_LEVELSX(i); 147 nitrox_write_csr(ndev, offset, 0xffffffff); 148 149 /* step 5: clear off door bell counts */ 150 offset = NPS_PKT_IN_INSTR_BAOFF_DBELLX(i); 151 pkt_in_dbell.value = 0; 152 pkt_in_dbell.s.dbell = 0xffffffff; 153 nitrox_write_csr(ndev, offset, pkt_in_dbell.value); 154 155 /* enable the ring */ 156 enable_pkt_input_ring(ndev, i); 157 } 158 } 159 160 static void reset_pkt_solicit_port(struct nitrox_device *ndev, int port) 161 { 162 union nps_pkt_slc_ctl pkt_slc_ctl; 163 union nps_pkt_slc_cnts pkt_slc_cnts; 164 int max_retries = MAX_CSR_RETRIES; 165 u64 offset; 166 167 /* step 1: disable slc port */ 168 offset = NPS_PKT_SLC_CTLX(port); 169 pkt_slc_ctl.value = nitrox_read_csr(ndev, offset); 170 pkt_slc_ctl.s.enb = 0; 171 nitrox_write_csr(ndev, offset, pkt_slc_ctl.value); 172 173 /* step 2 */ 174 usleep_range(100, 150); 175 /* wait to clear [ENB] */ 176 do { 177 pkt_slc_ctl.value = nitrox_read_csr(ndev, offset); 178 if (!pkt_slc_ctl.s.enb) 179 break; 180 udelay(50); 181 } while (max_retries--); 182 183 /* step 3: clear slc counters */ 184 offset = NPS_PKT_SLC_CNTSX(port); 185 pkt_slc_cnts.value = nitrox_read_csr(ndev, offset); 186 nitrox_write_csr(ndev, offset, pkt_slc_cnts.value); 187 usleep_range(50, 100); 188 } 189 190 void enable_pkt_solicit_port(struct nitrox_device *ndev, int port) 191 { 192 union nps_pkt_slc_ctl pkt_slc_ctl; 193 int max_retries = MAX_CSR_RETRIES; 194 u64 offset; 195 196 offset = NPS_PKT_SLC_CTLX(port); 197 pkt_slc_ctl.value = 0; 198 pkt_slc_ctl.s.enb = 1; 199 /* 200 * 8 trailing 0x00 bytes will be added 201 * to the end of the outgoing packet. 202 */ 203 pkt_slc_ctl.s.z = 1; 204 /* enable response header */ 205 pkt_slc_ctl.s.rh = 1; 206 nitrox_write_csr(ndev, offset, pkt_slc_ctl.value); 207 208 /* wait to set [ENB] */ 209 do { 210 pkt_slc_ctl.value = nitrox_read_csr(ndev, offset); 211 if (pkt_slc_ctl.s.enb) 212 break; 213 udelay(50); 214 } while (max_retries--); 215 } 216 217 static void config_pkt_solicit_port(struct nitrox_device *ndev, int port) 218 { 219 union nps_pkt_slc_int_levels pkt_slc_int; 220 u64 offset; 221 222 reset_pkt_solicit_port(ndev, port); 223 224 /* step 4: configure interrupt levels */ 225 offset = NPS_PKT_SLC_INT_LEVELSX(port); 226 pkt_slc_int.value = 0; 227 /* time interrupt threshold */ 228 pkt_slc_int.s.timet = 0x3fffff; 229 nitrox_write_csr(ndev, offset, pkt_slc_int.value); 230 231 /* enable the solicit port */ 232 enable_pkt_solicit_port(ndev, port); 233 } 234 235 void nitrox_config_pkt_solicit_ports(struct nitrox_device *ndev) 236 { 237 int i; 238 239 for (i = 0; i < ndev->nr_queues; i++) 240 config_pkt_solicit_port(ndev, i); 241 } 242 243 /** 244 * enable_nps_interrupts - enable NPS interrutps 245 * @ndev: NITROX device. 246 * 247 * This includes NPS core, packet in and slc interrupts. 248 */ 249 static void enable_nps_interrupts(struct nitrox_device *ndev) 250 { 251 union nps_core_int_ena_w1s core_int; 252 253 /* NPS core interrutps */ 254 core_int.value = 0; 255 core_int.s.host_wr_err = 1; 256 core_int.s.host_wr_timeout = 1; 257 core_int.s.exec_wr_timeout = 1; 258 core_int.s.npco_dma_malform = 1; 259 core_int.s.host_nps_wr_err = 1; 260 nitrox_write_csr(ndev, NPS_CORE_INT_ENA_W1S, core_int.value); 261 262 /* NPS packet in ring interrupts */ 263 nitrox_write_csr(ndev, NPS_PKT_IN_RERR_LO_ENA_W1S, (~0ULL)); 264 nitrox_write_csr(ndev, NPS_PKT_IN_RERR_HI_ENA_W1S, (~0ULL)); 265 nitrox_write_csr(ndev, NPS_PKT_IN_ERR_TYPE_ENA_W1S, (~0ULL)); 266 /* NPS packet slc port interrupts */ 267 nitrox_write_csr(ndev, NPS_PKT_SLC_RERR_HI_ENA_W1S, (~0ULL)); 268 nitrox_write_csr(ndev, NPS_PKT_SLC_RERR_LO_ENA_W1S, (~0ULL)); 269 nitrox_write_csr(ndev, NPS_PKT_SLC_ERR_TYPE_ENA_W1S, (~0uLL)); 270 } 271 272 void nitrox_config_nps_unit(struct nitrox_device *ndev) 273 { 274 union nps_core_gbl_vfcfg core_gbl_vfcfg; 275 276 /* endian control information */ 277 nitrox_write_csr(ndev, NPS_CORE_CONTROL, 1ULL); 278 279 /* disable ILK interface */ 280 core_gbl_vfcfg.value = 0; 281 core_gbl_vfcfg.s.ilk_disable = 1; 282 core_gbl_vfcfg.s.cfg = __NDEV_MODE_PF; 283 nitrox_write_csr(ndev, NPS_CORE_GBL_VFCFG, core_gbl_vfcfg.value); 284 /* config input and solicit ports */ 285 nitrox_config_pkt_input_rings(ndev); 286 nitrox_config_pkt_solicit_ports(ndev); 287 288 /* enable interrupts */ 289 enable_nps_interrupts(ndev); 290 } 291 292 void nitrox_config_pom_unit(struct nitrox_device *ndev) 293 { 294 union pom_int_ena_w1s pom_int; 295 int i; 296 297 /* enable pom interrupts */ 298 pom_int.value = 0; 299 pom_int.s.illegal_dport = 1; 300 nitrox_write_csr(ndev, POM_INT_ENA_W1S, pom_int.value); 301 302 /* enable perf counters */ 303 for (i = 0; i < ndev->hw.se_cores; i++) 304 nitrox_write_csr(ndev, POM_PERF_CTL, BIT_ULL(i)); 305 } 306 307 /** 308 * nitrox_config_rand_unit - enable NITROX random number unit 309 * @ndev: NITROX device 310 */ 311 void nitrox_config_rand_unit(struct nitrox_device *ndev) 312 { 313 union efl_rnm_ctl_status efl_rnm_ctl; 314 u64 offset; 315 316 offset = EFL_RNM_CTL_STATUS; 317 efl_rnm_ctl.value = nitrox_read_csr(ndev, offset); 318 efl_rnm_ctl.s.ent_en = 1; 319 efl_rnm_ctl.s.rng_en = 1; 320 nitrox_write_csr(ndev, offset, efl_rnm_ctl.value); 321 } 322 323 void nitrox_config_efl_unit(struct nitrox_device *ndev) 324 { 325 int i; 326 327 for (i = 0; i < NR_CLUSTERS; i++) { 328 union efl_core_int_ena_w1s efl_core_int; 329 u64 offset; 330 331 /* EFL core interrupts */ 332 offset = EFL_CORE_INT_ENA_W1SX(i); 333 efl_core_int.value = 0; 334 efl_core_int.s.len_ovr = 1; 335 efl_core_int.s.d_left = 1; 336 efl_core_int.s.epci_decode_err = 1; 337 nitrox_write_csr(ndev, offset, efl_core_int.value); 338 339 offset = EFL_CORE_VF_ERR_INT0_ENA_W1SX(i); 340 nitrox_write_csr(ndev, offset, (~0ULL)); 341 offset = EFL_CORE_VF_ERR_INT1_ENA_W1SX(i); 342 nitrox_write_csr(ndev, offset, (~0ULL)); 343 } 344 } 345 346 void nitrox_config_bmi_unit(struct nitrox_device *ndev) 347 { 348 union bmi_ctl bmi_ctl; 349 union bmi_int_ena_w1s bmi_int_ena; 350 u64 offset; 351 352 /* no threshold limits for PCIe */ 353 offset = BMI_CTL; 354 bmi_ctl.value = nitrox_read_csr(ndev, offset); 355 bmi_ctl.s.max_pkt_len = 0xff; 356 bmi_ctl.s.nps_free_thrsh = 0xff; 357 bmi_ctl.s.nps_hdrq_thrsh = 0x7a; 358 nitrox_write_csr(ndev, offset, bmi_ctl.value); 359 360 /* enable interrupts */ 361 offset = BMI_INT_ENA_W1S; 362 bmi_int_ena.value = 0; 363 bmi_int_ena.s.max_len_err_nps = 1; 364 bmi_int_ena.s.pkt_rcv_err_nps = 1; 365 bmi_int_ena.s.fpf_undrrn = 1; 366 nitrox_write_csr(ndev, offset, bmi_int_ena.value); 367 } 368 369 void nitrox_config_bmo_unit(struct nitrox_device *ndev) 370 { 371 union bmo_ctl2 bmo_ctl2; 372 u64 offset; 373 374 /* no threshold limits for PCIe */ 375 offset = BMO_CTL2; 376 bmo_ctl2.value = nitrox_read_csr(ndev, offset); 377 bmo_ctl2.s.nps_slc_buf_thrsh = 0xff; 378 nitrox_write_csr(ndev, offset, bmo_ctl2.value); 379 } 380 381 void invalidate_lbc(struct nitrox_device *ndev) 382 { 383 union lbc_inval_ctl lbc_ctl; 384 union lbc_inval_status lbc_stat; 385 int max_retries = MAX_CSR_RETRIES; 386 u64 offset; 387 388 /* invalidate LBC */ 389 offset = LBC_INVAL_CTL; 390 lbc_ctl.value = nitrox_read_csr(ndev, offset); 391 lbc_ctl.s.cam_inval_start = 1; 392 nitrox_write_csr(ndev, offset, lbc_ctl.value); 393 394 offset = LBC_INVAL_STATUS; 395 do { 396 lbc_stat.value = nitrox_read_csr(ndev, offset); 397 if (lbc_stat.s.done) 398 break; 399 udelay(50); 400 } while (max_retries--); 401 } 402 403 void nitrox_config_lbc_unit(struct nitrox_device *ndev) 404 { 405 union lbc_int_ena_w1s lbc_int_ena; 406 u64 offset; 407 408 invalidate_lbc(ndev); 409 410 /* enable interrupts */ 411 offset = LBC_INT_ENA_W1S; 412 lbc_int_ena.value = 0; 413 lbc_int_ena.s.dma_rd_err = 1; 414 lbc_int_ena.s.over_fetch_err = 1; 415 lbc_int_ena.s.cam_inval_abort = 1; 416 lbc_int_ena.s.cam_hard_err = 1; 417 nitrox_write_csr(ndev, offset, lbc_int_ena.value); 418 419 offset = LBC_PLM_VF1_64_INT_ENA_W1S; 420 nitrox_write_csr(ndev, offset, (~0ULL)); 421 offset = LBC_PLM_VF65_128_INT_ENA_W1S; 422 nitrox_write_csr(ndev, offset, (~0ULL)); 423 424 offset = LBC_ELM_VF1_64_INT_ENA_W1S; 425 nitrox_write_csr(ndev, offset, (~0ULL)); 426 offset = LBC_ELM_VF65_128_INT_ENA_W1S; 427 nitrox_write_csr(ndev, offset, (~0ULL)); 428 } 429 430 void config_nps_core_vfcfg_mode(struct nitrox_device *ndev, enum vf_mode mode) 431 { 432 union nps_core_gbl_vfcfg vfcfg; 433 434 vfcfg.value = nitrox_read_csr(ndev, NPS_CORE_GBL_VFCFG); 435 vfcfg.s.cfg = mode & 0x7; 436 437 nitrox_write_csr(ndev, NPS_CORE_GBL_VFCFG, vfcfg.value); 438 } 439 440 void nitrox_get_hwinfo(struct nitrox_device *ndev) 441 { 442 union emu_fuse_map emu_fuse; 443 union rst_boot rst_boot; 444 union fus_dat1 fus_dat1; 445 unsigned char name[IFNAMSIZ * 2] = {}; 446 int i, dead_cores; 447 u64 offset; 448 449 /* get core frequency */ 450 offset = RST_BOOT; 451 rst_boot.value = nitrox_read_csr(ndev, offset); 452 ndev->hw.freq = (rst_boot.pnr_mul + 3) * PLL_REF_CLK; 453 454 for (i = 0; i < NR_CLUSTERS; i++) { 455 offset = EMU_FUSE_MAPX(i); 456 emu_fuse.value = nitrox_read_csr(ndev, offset); 457 if (emu_fuse.s.valid) { 458 dead_cores = hweight32(emu_fuse.s.ae_fuse); 459 ndev->hw.ae_cores += AE_CORES_PER_CLUSTER - dead_cores; 460 dead_cores = hweight16(emu_fuse.s.se_fuse); 461 ndev->hw.se_cores += SE_CORES_PER_CLUSTER - dead_cores; 462 } 463 } 464 /* find zip hardware availability */ 465 offset = FUS_DAT1; 466 fus_dat1.value = nitrox_read_csr(ndev, offset); 467 if (!fus_dat1.nozip) { 468 dead_cores = hweight8(fus_dat1.zip_info); 469 ndev->hw.zip_cores = ZIP_MAX_CORES - dead_cores; 470 } 471 472 /* determine the partname CNN55<cores>-<freq><pincount>-<rev>*/ 473 if (ndev->hw.ae_cores == AE_MAX_CORES) { 474 switch (ndev->hw.se_cores) { 475 case SE_MAX_CORES: 476 i = snprintf(name, sizeof(name), "CNN5560"); 477 break; 478 case 40: 479 i = snprintf(name, sizeof(name), "CNN5560s"); 480 break; 481 } 482 } else if (ndev->hw.ae_cores == (AE_MAX_CORES / 2)) { 483 i = snprintf(name, sizeof(name), "CNN5530"); 484 } else { 485 i = snprintf(name, sizeof(name), "CNN5560i"); 486 } 487 488 snprintf(name + i, sizeof(name) - i, "-%3dBG676-1.%u", 489 ndev->hw.freq, ndev->hw.revision_id); 490 491 /* copy partname */ 492 strncpy(ndev->hw.partname, name, sizeof(ndev->hw.partname)); 493 } 494 495 void enable_pf2vf_mbox_interrupts(struct nitrox_device *ndev) 496 { 497 u64 value = ~0ULL; 498 u64 reg_addr; 499 500 /* Mailbox interrupt low enable set register */ 501 reg_addr = NPS_PKT_MBOX_INT_LO_ENA_W1S; 502 nitrox_write_csr(ndev, reg_addr, value); 503 504 /* Mailbox interrupt high enable set register */ 505 reg_addr = NPS_PKT_MBOX_INT_HI_ENA_W1S; 506 nitrox_write_csr(ndev, reg_addr, value); 507 } 508 509 void disable_pf2vf_mbox_interrupts(struct nitrox_device *ndev) 510 { 511 u64 value = ~0ULL; 512 u64 reg_addr; 513 514 /* Mailbox interrupt low enable clear register */ 515 reg_addr = NPS_PKT_MBOX_INT_LO_ENA_W1C; 516 nitrox_write_csr(ndev, reg_addr, value); 517 518 /* Mailbox interrupt high enable clear register */ 519 reg_addr = NPS_PKT_MBOX_INT_HI_ENA_W1C; 520 nitrox_write_csr(ndev, reg_addr, value); 521 } 522