// SPDX-License-Identifier: Apache-2.0 /* Copyright 2013-2019 IBM Corp. */ #include #include #include #include #include #include #include #include #include #include #define NPU2_IRQ_BASE_SHIFT 13 #define NPU2_N_DL_IRQS 35 #define NPU2_N_DL_IRQS_ALIGN 64 /* * We use the indirect method because it uses the same addresses as * the MMIO offsets (NPU RING) */ static void npu2_scom_set_addr(uint64_t gcid, uint64_t scom_base, uint64_t addr, uint64_t size) { addr = SETFIELD(NPU2_MISC_DA_ADDR, 0ull, addr); addr = SETFIELD(NPU2_MISC_DA_LEN, addr, size); xscom_write(gcid, scom_base + NPU2_MISC_SCOM_IND_SCOM_ADDR, addr); } void npu2_scom_write(uint64_t gcid, uint64_t scom_base, uint64_t reg, uint64_t size, uint64_t val) { npu2_scom_set_addr(gcid, scom_base, reg, size); xscom_write(gcid, scom_base + NPU2_MISC_SCOM_IND_SCOM_DATA, val); } uint64_t npu2_scom_read(uint64_t gcid, uint64_t scom_base, uint64_t reg, uint64_t size) { uint64_t val; npu2_scom_set_addr(gcid, scom_base, reg, size); xscom_read(gcid, scom_base + NPU2_MISC_SCOM_IND_SCOM_DATA, &val); return val; } void npu2_write_4b(struct npu2 *p, uint64_t reg, uint32_t val) { npu2_scom_write(p->chip_id, p->xscom_base, reg, NPU2_MISC_DA_LEN_4B, (uint64_t)val << 32); } uint32_t npu2_read_4b(struct npu2 *p, uint64_t reg) { return npu2_scom_read(p->chip_id, p->xscom_base, reg, NPU2_MISC_DA_LEN_4B) >> 32; } void npu2_write(struct npu2 *p, uint64_t reg, uint64_t val) { npu2_scom_write(p->chip_id, p->xscom_base, reg, NPU2_MISC_DA_LEN_8B, val); } uint64_t npu2_read(struct npu2 *p, uint64_t reg) { return npu2_scom_read(p->chip_id, p->xscom_base, reg, NPU2_MISC_DA_LEN_8B); } void npu2_write_mask(struct npu2 *p, uint64_t reg, uint64_t val, uint64_t mask) { uint64_t new_val; new_val = npu2_read(p, reg); new_val &= ~mask; new_val |= val & mask; npu2_scom_write(p->chip_id, p->xscom_base, reg, NPU2_MISC_DA_LEN_8B, new_val); } void npu2_write_mask_4b(struct npu2 *p, uint64_t reg, uint32_t val, uint32_t mask) { uint32_t new_val; new_val = npu2_read_4b(p, reg); new_val &= ~mask; new_val |= val & mask; npu2_scom_write(p->chip_id, p->xscom_base, reg, NPU2_MISC_DA_LEN_4B, (uint64_t)new_val << 32); } typedef struct { const char *name; uint32_t block; uint32_t offset; } npu2_scom_dump_t; static npu2_scom_dump_t npu2_scom_dump_global[] = { /* CQ State Machine */ { "CS.SM0.MISC.CERR_MESSAGE0", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG0 }, { "CS.SM1.MISC.CERR_MESSAGE0", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG0 }, { "CS.SM2.MISC.CERR_MESSAGE0", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG0 }, { "CS.SM3.MISC.CERR_MESSAGE0", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG0 }, { "CS.SM0.MISC.CERR_MESSAGE1", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG1 }, { "CS.SM1.MISC.CERR_MESSAGE1", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG1 }, { "CS.SM2.MISC.CERR_MESSAGE1", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG1 }, { "CS.SM3.MISC.CERR_MESSAGE1", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG1 }, { "CS.SM0.MISC.CERR_MESSAGE2", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG2 }, { "CS.SM1.MISC.CERR_MESSAGE2", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG2 }, { "CS.SM2.MISC.CERR_MESSAGE2", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG2 }, { "CS.SM3.MISC.CERR_MESSAGE2", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG2 }, { "CS.SM0.MISC.CERR_MESSAGE3", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG3 }, { "CS.SM1.MISC.CERR_MESSAGE3", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG3 }, { "CS.SM2.MISC.CERR_MESSAGE3", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG3 }, { "CS.SM3.MISC.CERR_MESSAGE3", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG3 }, { "CS.SM0.MISC.CERR_MESSAGE4", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG4 }, { "CS.SM1.MISC.CERR_MESSAGE4", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG4 }, { "CS.SM2.MISC.CERR_MESSAGE4", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG4 }, { "CS.SM3.MISC.CERR_MESSAGE4", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG4 }, { "CS.SM0.MISC.CERR_MESSAGE5", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG5 }, { "CS.SM1.MISC.CERR_MESSAGE5", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG5 }, { "CS.SM2.MISC.CERR_MESSAGE5", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG5 }, { "CS.SM3.MISC.CERR_MESSAGE5", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG5 }, { "CS.SM0.MISC.CERR_MESSAGE6", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_MSG6 }, { "CS.SM1.MISC.CERR_MESSAGE6", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_MSG6 }, { "CS.SM2.MISC.CERR_MESSAGE6", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_MSG6 }, { "CS.SM3.MISC.CERR_MESSAGE6", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_MSG6 }, { "CS.SM0.MISC.CERR_FIRST0", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_FIRST0 }, { "CS.SM1.MISC.CERR_FIRST0", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_FIRST0 }, { "CS.SM2.MISC.CERR_FIRST0", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_FIRST0 }, { "CS.SM3.MISC.CERR_FIRST0", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_FIRST0 }, { "CS.SM0.MISC.CERR_FIRST1", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_FIRST1 }, { "CS.SM1.MISC.CERR_FIRST1", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_FIRST1 }, { "CS.SM2.MISC.CERR_FIRST1", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_FIRST1 }, { "CS.SM3.MISC.CERR_FIRST1", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_FIRST1 }, { "CS.SM0.MISC.CERR_FIRST2", NPU2_BLOCK_SM_0, NPU2_C_ERR_RPT_FIRST2 }, { "CS.SM1.MISC.CERR_FIRST2", NPU2_BLOCK_SM_1, NPU2_C_ERR_RPT_FIRST2 }, { "CS.SM2.MISC.CERR_FIRST2", NPU2_BLOCK_SM_2, NPU2_C_ERR_RPT_FIRST2 }, { "CS.SM3.MISC.CERR_FIRST2", NPU2_BLOCK_SM_3, NPU2_C_ERR_RPT_FIRST2 }, /* CQ Control */ { "CS.CTL.MISC.CERR_MESSAGE0", NPU2_BLOCK_CTL, NPU2_CQ_C_ERR_RPT_MSG0 }, { "CS.CTL.MISC.CERR_MESSAGE1", NPU2_BLOCK_CTL, NPU2_CQ_C_ERR_RPT_MSG1 }, { "CS.CTL.MISC.CERR_FIRST0", NPU2_BLOCK_CTL, NPU2_CQ_C_ERR_RPT_FIRST0 }, { "CS.CTL.MISC.CERR_FIRST1", NPU2_BLOCK_CTL, NPU2_CQ_C_ERR_RPT_FIRST1 }, /* CQ Data */ { "DAT.MISC.CERR_ECC_HOLD", NPU2_BLOCK_DAT, NPU2_CQ_DAT_ECC_STATUS }, { "DAT.MISC.CERR_ECC_MASK", NPU2_BLOCK_DAT, NPU2_CQ_DAT_ECC_MASK }, { "DAT.MISC.CERR_ECC_FIRST", NPU2_BLOCK_DAT, NPU2_CQ_DAT_ECC_FIRST }, { "DAT.MISC.REM0", NPU2_BLOCK_DAT, NPU2_CQ_DAT_RAS_MSG0 }, { "DAT.MISC.REM1", NPU2_BLOCK_DAT, NPU2_CQ_DAT_RAS_MSG1 }, }; static npu2_scom_dump_t npu2_scom_dump_nvlink[] = { { "NTL0.REGS.CERR_FIRST1", NPU2_BLOCK_NTL0, NPU2_NTL_ERR_FIRST1_OFF }, { "NTL1.REGS.CERR_FIRST1", NPU2_BLOCK_NTL1, NPU2_NTL_ERR_FIRST1_OFF }, { "NTL0.REGS.CERR_FIRST2", NPU2_BLOCK_NTL0, NPU2_NTL_ERR_FIRST2_OFF }, { "NTL1.REGS.CERR_FIRST2", NPU2_BLOCK_NTL1, NPU2_NTL_ERR_FIRST2_OFF }, }; static npu2_scom_dump_t npu2_scom_dump_ocapi[] = { { "OTL0.MISC.C_ERR_RPT_HOLD0", NPU2_BLOCK_OTL0, NPU2_OTL_ERR_RPT_HOLD0 }, { "OTL1.MISC.C_ERR_RPT_HOLD0", NPU2_BLOCK_OTL1, NPU2_OTL_ERR_RPT_HOLD0 }, { "OTL0.MISC.OTL_REM0", NPU2_BLOCK_OTL0, NPU2_OTL_RAS_ERR_MSG0 }, { "OTL1.MISC.OTL_REM0", NPU2_BLOCK_OTL1, NPU2_OTL_RAS_ERR_MSG0 }, { "OTL0.MISC.ERROR_SIG_RXI", NPU2_BLOCK_OTL0, NPU2_OTL_RXI_ERR_SIG }, { "OTL1.MISC.ERROR_SIG_RXI", NPU2_BLOCK_OTL1, NPU2_OTL_RXI_ERR_SIG }, { "OTL0.MISC.ERROR_SIG_RXO", NPU2_BLOCK_OTL0, NPU2_OTL_RXO_ERR_SIG }, { "OTL1.MISC.ERROR_SIG_RXO", NPU2_BLOCK_OTL1, NPU2_OTL_RXO_ERR_SIG }, { "OTL0.MISC.C_ERR_RPT_HOLD1", NPU2_BLOCK_OTL0, NPU2_OTL_ERR_RPT_HOLD1 }, { "OTL1.MISC.C_ERR_RPT_HOLD1", NPU2_BLOCK_OTL1, NPU2_OTL_ERR_RPT_HOLD1 }, }; static void print_one_npu_reg(struct npu2 *npu, npu2_scom_dump_t *scom, int stack) { uint64_t reg, val; reg = NPU2_REG_OFFSET(stack, scom->block, scom->offset); val = npu2_scom_read(npu->chip_id, npu->xscom_base, reg, NPU2_MISC_DA_LEN_8B); prlog(PR_ERR, "NPU[%d] STCK%d.%s 0x%llx = 0x%016llx\n", npu->chip_id, stack - 4, scom->name, reg, val); } /* same as above, but for direct access registers */ static void print_one_reg(int chip_id, int brick_index, uint64_t reg_addr, const char *reg_name) { uint64_t val; xscom_read(chip_id, reg_addr, &val); prlog(PR_ERR, "NPU[%d] %s brick %d 0x%llx = 0x%016llx\n", chip_id, reg_name, brick_index, reg_addr, val); } static void show_nvlink_regs(struct npu2 *npu, int brick_index) { uint32_t stack, ntl; int i; stack = NPU2_STACK_STCK_0 + brick_index / 2; ntl = NPU2_BLOCK_NTL0 + (brick_index % 2) * 2; for (i = 0; i < ARRAY_SIZE(npu2_scom_dump_nvlink); i++) { if (npu2_scom_dump_nvlink[i].block == ntl) print_one_npu_reg(npu, &npu2_scom_dump_nvlink[i], stack); } } static void show_opencapi_regs(struct npu2 *npu, int brick_index) { uint32_t stack, otl; int i; stack = NPU2_STACK_STCK_0 + brick_index / 2; otl = NPU2_BLOCK_OTL0 + (brick_index % 2); /* NPU registers */ for (i = 0; i < ARRAY_SIZE(npu2_scom_dump_ocapi); i++) { if (npu2_scom_dump_ocapi[i].block == otl) print_one_npu_reg(npu, &npu2_scom_dump_ocapi[i], stack); } /* Fabric registers */ print_one_reg(npu->chip_id, brick_index, OB_ODL_STATUS(brick_index), "ODL status"); print_one_reg(npu->chip_id, brick_index, OB_ODL_TRAINING_STATUS(brick_index), "ODL training status"); print_one_reg(npu->chip_id, brick_index, OB_ODL_ENDPOINT_INFO(brick_index), "ODL endpoint info"); } static void show_all_regs(struct npu2 *npu, int brick_index) { int i, stack, stack_min, stack_max; uint64_t fir_val, mask_val, fir_addr, mask_addr; struct npu2_dev *dev; npu2_scom_dump_t scom_reg; if (brick_index != -1) { stack_min = stack_max = NPU2_STACK_STCK_0 + brick_index / 2; } else { stack_min = NPU2_STACK_STCK_0; stack_max = NPU2_STACK_STCK_2; /* Avoid dumping unused stacks for opencapi on Lagrange */ if (npu->total_devices == 2) stack_min = stack_max = NPU2_STACK_STCK_1; } /* NPU FIRs */ for (i = 0; i < NPU2_TOTAL_FIR_REGISTERS; i++) { fir_addr = NPU2_FIR_REGISTER_0 + i * NPU2_FIR_OFFSET; mask_addr = fir_addr + NPU2_FIR_MASK_OFFSET; xscom_read(npu->chip_id, fir_addr, &fir_val); xscom_read(npu->chip_id, mask_addr, &mask_val); prlog(PR_ERR, "NPU[%d] FIR%d = 0x%016llx (mask 0x%016llx => 0x%016llx)\n", npu->chip_id, i, fir_val, mask_val, fir_val & ~mask_val); } /* NPU global, per-stack registers */ for (i = 0; i < ARRAY_SIZE(npu2_scom_dump_global); i++) { for (stack = stack_min; stack <= stack_max; stack++) print_one_npu_reg(npu, &npu2_scom_dump_global[i], stack); } /* * NPU global registers, stack independent * We have only one for now, so dump it directly */ scom_reg.name = "XTS.REG.ERR_HOLD"; scom_reg.block = NPU2_BLOCK_XTS; scom_reg.offset = 0; print_one_npu_reg(npu, &scom_reg, NPU2_STACK_MISC); /* nvlink- or opencapi-specific registers */ for (i = 0; i < npu->total_devices; i++) { dev = &npu->devices[i]; if (brick_index == -1 || dev->brick_index == brick_index) { if (dev->type == NPU2_DEV_TYPE_NVLINK) show_nvlink_regs(npu, dev->brick_index); else if (dev->type == NPU2_DEV_TYPE_OPENCAPI) show_opencapi_regs(npu, dev->brick_index); } } } void npu2_dump_scoms(int chip_id) { struct npu2 *npu; struct phb *phb; struct npu2_dev *dev; /* * Look for the npu2 structure for that chip ID. We can access it * through the array of phbs, looking for a nvlink or opencapi * phb. We can have several entries, but they all point * to the same npu2 structure */ for_each_phb(phb) { npu = NULL; if (phb->phb_type == phb_type_npu_v2) { npu = phb_to_npu2_nvlink(phb); } else if (phb->phb_type == phb_type_npu_v2_opencapi) { dev = phb_to_npu2_dev_ocapi(phb); npu = dev->npu; } if (npu && npu->chip_id == chip_id) { show_all_regs(npu, -1 /* all bricks */); break; } } } static uint64_t npu2_ipi_attributes(struct irq_source *is __unused, uint32_t isn __unused) { struct npu2 *p = is->data; uint32_t idx = isn - p->base_lsi; if ((idx == 18) || (idx >= 27 && idx <= 34)) /* * level 18: TCE Interrupt - used to detect a frozen PE (nvlink) * level 27-30: OTL interrupt (opencapi) * level 31-34: XSL interrupt (opencapi) */ return IRQ_ATTR_TARGET_OPAL | IRQ_ATTR_TARGET_RARE | IRQ_ATTR_TYPE_MSI; else return IRQ_ATTR_TARGET_LINUX; } static char *npu2_ipi_name(struct irq_source *is, uint32_t isn) { struct npu2 *p = is->data; uint32_t idx = isn - p->base_lsi; const char *name; switch (idx) { case 0: name = "NDL 0 Stall Event (brick 0)"; break; case 1: name = "NDL 0 No-Stall Event (brick 0)"; break; case 2: name = "NDL 1 Stall Event (brick 1)"; break; case 3: name = "NDL 1 No-Stall Event (brick 1)"; break; case 4: name = "NDL 2 Stall Event (brick 2)"; break; case 5: name = "NDL 2 No-Stall Event (brick 2)"; break; case 6: name = "NDL 5 Stall Event (brick 3)"; break; case 7: name = "NDL 5 No-Stall Event (brick 3)"; break; case 8: name = "NDL 4 Stall Event (brick 4)"; break; case 9: name = "NDL 4 No-Stall Event (brick 4)"; break; case 10: name = "NDL 3 Stall Event (brick 5)"; break; case 11: name = "NDL 3 No-Stall Event (brick 5)"; break; case 12: name = "NTL 0 Event"; break; case 13: name = "NTL 1 Event"; break; case 14: name = "NTL 2 Event"; break; case 15: name = "NTL 3 Event"; break; case 16: name = "NTL 4 Event"; break; case 17: name = "NTL 5 Event"; break; case 18: name = "TCE Event"; break; case 19: name = "ATS Event"; break; case 20: name = "CQ Event"; break; case 21: name = "MISC Event"; break; case 22: name = "NMMU Local Xstop"; break; case 23: name = "Translate Fail (brick 2)"; break; case 24: name = "Translate Fail (brick 3)"; break; case 25: name = "Translate Fail (brick 4)"; break; case 26: name = "Translate Fail (brick 5)"; break; case 27: name = "OTL Event (brick 2)"; break; case 28: name = "OTL Event (brick 3)"; break; case 29: name = "OTL Event (brick 4)"; break; case 30: name = "OTL Event (brick 5)"; break; case 31: name = "XSL Event (brick 2)"; break; case 32: name = "XSL Event (brick 3)"; break; case 33: name = "XSL Event (brick 4)"; break; case 34: name = "XSL Event (brick 5)"; break; default: name = "Unknown"; } return strdup(name); } static void npu2_err_interrupt(struct irq_source *is, uint32_t isn) { struct npu2 *p = is->data; uint32_t idx = isn - p->base_lsi; char *irq_name; int brick; switch (idx) { case 18: opal_update_pending_evt(OPAL_EVENT_PCI_ERROR, OPAL_EVENT_PCI_ERROR); break; case 27 ... 34: /* opencapi only */ brick = 2 + ((idx - 27) % 4); irq_name = npu2_ipi_name(is, isn); prlog(PR_ERR, "NPU[%d] received error interrupt '%s'\n", p->chip_id, irq_name); free(irq_name); show_all_regs(p, brick); opal_update_pending_evt(OPAL_EVENT_PCI_ERROR, OPAL_EVENT_PCI_ERROR); break; default: prerror("OPAL received unknown NPU2 interrupt %d\n", idx); return; } } static const struct irq_source_ops npu2_ipi_ops = { .interrupt = npu2_err_interrupt, .attributes = npu2_ipi_attributes, .name = npu2_ipi_name, }; static void setup_irqs(struct npu2 *p) { uint64_t reg, val; void *tp; p->base_lsi = xive_alloc_ipi_irqs(p->chip_id, NPU2_N_DL_IRQS, NPU2_N_DL_IRQS_ALIGN); if (p->base_lsi == XIVE_IRQ_ERROR) { prlog(PR_ERR, "NPU: Failed to allocate interrupt sources\n"); return; } xive_register_ipi_source(p->base_lsi, NPU2_N_DL_IRQS, p, &npu2_ipi_ops); /* Set IPI configuration */ reg = NPU2_REG_OFFSET(NPU2_STACK_MISC, NPU2_BLOCK_MISC, NPU2_MISC_CFG); val = npu2_read(p, reg); val = SETFIELD(NPU2_MISC_CFG_IPI_PS, val, NPU2_MISC_CFG_IPI_PS_64K); val = SETFIELD(NPU2_MISC_CFG_IPI_OS, val, NPU2_MISC_CFG_IPI_OS_AIX); npu2_write(p, reg, val); /* Set IRQ base */ reg = NPU2_REG_OFFSET(NPU2_STACK_MISC, NPU2_BLOCK_MISC, NPU2_MISC_IRQ_BASE); tp = xive_get_trigger_port(p->base_lsi); val = ((uint64_t)tp) << NPU2_IRQ_BASE_SHIFT; npu2_write(p, reg, val); } static bool _i2c_presence_detect(struct npu2_dev *dev) { uint8_t state, data; int rc; rc = i2c_request_send(dev->npu->i2c_port_id_ocapi, platform.ocapi->i2c_presence_addr, SMBUS_READ, 0, 1, &state, 1, 120); if (rc) { OCAPIERR(dev, "error detecting link presence: %d\n", rc); return true; /* assume link exists */ } OCAPIDBG(dev, "I2C presence detect: 0x%x\n", state); switch (dev->link_index) { case 2: data = platform.ocapi->i2c_presence_brick2; break; case 3: data = platform.ocapi->i2c_presence_brick3; break; case 4: data = platform.ocapi->i2c_presence_brick4; break; case 5: data = platform.ocapi->i2c_presence_brick5; break; default: OCAPIERR(dev, "presence detection on invalid link\n"); return true; } /* Presence detect bits are active low */ return !(state & data); } /* * A default presence detection implementation for platforms like ZZ and Zaius * that don't implement their own. Assumes all devices found will be OpenCAPI. */ void npu2_i2c_presence_detect(struct npu2 *npu) { struct npu2_dev *dev; assert(platform.ocapi); for (int i = 0; i < npu->total_devices; i++) { dev = &npu->devices[i]; if (_i2c_presence_detect(dev)) dev->type = NPU2_DEV_TYPE_OPENCAPI; else dev->type = NPU2_DEV_TYPE_UNKNOWN; } } static struct npu2 *setup_npu(struct dt_node *dn) { struct npu2 *npu; struct npu2_dev *dev; struct dt_node *np; uint32_t num_links; char port_name[17]; void *npumem; char *path; int gcid; struct proc_chip *chip; int i = 0; /* Retrieve chip ID */ path = dt_get_path(dn); gcid = dt_get_chip_id(dn); chip = get_chip(gcid); assert(chip); num_links = dt_prop_get_u32(dn, "ibm,npu-links"); npumem = zalloc(sizeof(struct npu2) + num_links * sizeof(struct npu2_dev)); assert(npumem); npu = npumem; npu->dt_node = dn; npu->index = dt_prop_get_u32(dn, "ibm,npu-index"); npu->chip_id = gcid; npu->xscom_base = dt_get_address(dn, 0, NULL); npu->phb_index = dt_prop_get_u32(dn, "ibm,phb-index"); init_lock(&npu->i2c_lock); npu->i2c_pin_mode = ~0; // input mode by default npu->i2c_pin_wr_state = ~0; // reset is active low if (platform.ocapi) { /* Find I2C port for handling device presence/reset */ snprintf(port_name, sizeof(port_name), "p8_%08x_e%dp%d", gcid, platform.ocapi->i2c_engine, platform.ocapi->i2c_port); prlog(PR_DEBUG, "NPU: Looking for I2C port %s\n", port_name); dt_for_each_compatible(dt_root, np, "ibm,power9-i2c-port") { if (streq(port_name, dt_prop_get(np, "ibm,port-name"))) { npu->i2c_port_id_ocapi = dt_prop_get_u32(np, "ibm,opal-id"); break; } } if (!npu->i2c_port_id_ocapi) { prlog(PR_ERR, "NPU: Couldn't find I2C port %s\n", port_name); goto failed; } } npu->devices = npumem + sizeof(struct npu2); dt_for_each_compatible(dn, np, "ibm,npu-link") { assert(i < num_links); dev = &npu->devices[i]; dev->link_index = dt_prop_get_u32(np, "ibm,npu-link-index"); /* May be overridden by platform presence detection */ dev->brick_index = dev->link_index; /* Will be overridden by presence detection */ dev->type = NPU2_DEV_TYPE_UNKNOWN; dev->npu = npu; dev->dt_node = np; dev->pl_xscom_base = dt_prop_get_u64(np, "ibm,npu-phy"); dev->lane_mask = dt_prop_get_u32(np, "ibm,npu-lane-mask"); dev->link_speed = dt_prop_get_u64(np, "ibm,link-speed"); i++; }; npu->total_devices = i; prlog(PR_INFO, "NPU: Chip %d Found NPU2#%d (%d links) at %s\n", npu->chip_id, npu->index, npu->total_devices, path); prlog(PR_INFO, " SCOM Base: %08llx\n", npu->xscom_base); free(path); return npu; failed: prlog(PR_ERR, "NPU: Chip %d NPU setup failed\n", gcid); free(path); free(npu); return NULL; } static void setup_devices(struct npu2 *npu) { bool nvlink_detected = false, ocapi_detected = false; struct npu2_dev *dev; /* * TODO: In future, we'll do brick configuration here to support mixed * setups. */ for (int i = 0; i < npu->total_devices; i++) { dev = &npu->devices[i]; switch (dev->type) { case NPU2_DEV_TYPE_NVLINK: nvlink_detected = true; dt_add_property_strings(dev->dt_node, "ibm,npu-link-type", "nvlink"); break; case NPU2_DEV_TYPE_OPENCAPI: ocapi_detected = true; dt_add_property_strings(dev->dt_node, "ibm,npu-link-type", "opencapi"); break; default: prlog(PR_INFO, "NPU: Link %d device not present\n", npu->devices[i].link_index); dt_add_property_strings(dev->dt_node, "ibm,npu-link-type", "unknown"); } } if (nvlink_detected && ocapi_detected) { prlog(PR_ERR, "NPU: NVLink and OpenCAPI devices on same chip not supported, aborting NPU init\n"); return; } setup_irqs(npu); if (nvlink_detected) npu2_nvlink_init_npu(npu); else if (ocapi_detected) npu2_opencapi_init_npu(npu); } void probe_npu2(void) { struct proc_chip *chip = next_chip(NULL); struct npu2 *npu; struct dt_node *np; const char *zcal; /* npu2 only */ if (!dt_find_compatible_node(dt_root, NULL, "ibm,power9-npu")) return; /* Abort if we're running on POWER9C DD1 (P9N DD1 is not supported) */ if (chip && chip->type == PROC_CHIP_P9_CUMULUS && (chip->ec_level & 0xf0) == 0x10) { prlog(PR_INFO, "NPU2: DD1 not supported\n"); return; } /* Check for a zcal override */ zcal = nvram_query_dangerous("nv_zcal_override"); if (zcal) { nv_zcal_nominal = atoi(zcal); prlog(PR_WARNING, "NPU2: Using ZCAL impedance override = %d\n", nv_zcal_nominal); } if (!platform.npu2_device_detect) { prlog(PR_INFO, "NPU: Platform does not support NPU\n"); return; } dt_for_each_compatible(dt_root, np, "ibm,power9-npu") { npu = setup_npu(np); if (!npu) continue; platform.npu2_device_detect(npu); setup_devices(npu); } }