// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2025-2026, NVIDIA CORPORATION. All rights reserved. */ #include #include #include #include #include #include #include "mc.h" #include "tegra264-bwmgr.h" /* * MC Client entries are sorted in the increasing order of the * override and security register offsets. */ static const struct tegra_mc_client tegra264_mc_clients[] = { { .id = TEGRA264_MEMORY_CLIENT_HDAR, .name = "hdar", .bpmp_id = TEGRA264_BWMGR_HDA, .type = TEGRA_ICC_ISO_AUDIO, }, { .id = TEGRA264_MEMORY_CLIENT_HDAW, .name = "hdaw", .bpmp_id = TEGRA264_BWMGR_HDA, .type = TEGRA_ICC_ISO_AUDIO, }, { .id = TEGRA264_MEMORY_CLIENT_MGBE0R, .name = "mgbe0r", .bpmp_id = TEGRA264_BWMGR_EQOS, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_MGBE0W, .name = "mgbe0w", .bpmp_id = TEGRA264_BWMGR_EQOS, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_MGBE1R, .name = "mgbe1r", .bpmp_id = TEGRA264_BWMGR_EQOS, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_MGBE1W, .name = "mgbe1w", .bpmp_id = TEGRA264_BWMGR_EQOS, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_SDMMC0R, .name = "sdmmc0r", .bpmp_id = TEGRA264_BWMGR_SDMMC_1, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_SDMMC0W, .name = "sdmmc0w", .bpmp_id = TEGRA264_BWMGR_SDMMC_1, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_VICR, .name = "vicr", .bpmp_id = TEGRA264_BWMGR_VIC, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_VICW, .name = "vicw", .bpmp_id = TEGRA264_BWMGR_VIC, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_APER, .name = "aper", .bpmp_id = TEGRA264_BWMGR_APE, .type = TEGRA_ICC_ISO_AUDIO, }, { .id = TEGRA264_MEMORY_CLIENT_APEW, .name = "apew", .bpmp_id = TEGRA264_BWMGR_APE, .type = TEGRA_ICC_ISO_AUDIO, }, { .id = TEGRA264_MEMORY_CLIENT_APEDMAR, .name = "apedmar", .bpmp_id = TEGRA264_BWMGR_APEDMA, .type = TEGRA_ICC_ISO_AUDIO, }, { .id = TEGRA264_MEMORY_CLIENT_APEDMAW, .name = "apedmaw", .bpmp_id = TEGRA264_BWMGR_APEDMA, .type = TEGRA_ICC_ISO_AUDIO, }, { .id = TEGRA264_MEMORY_CLIENT_VIFALCONR, .name = "vifalconr", .bpmp_id = TEGRA264_BWMGR_VIFAL, .type = TEGRA_ICC_ISO_VIFAL, }, { .id = TEGRA264_MEMORY_CLIENT_VIFALCONW, .name = "vifalconw", .bpmp_id = TEGRA264_BWMGR_VIFAL, .type = TEGRA_ICC_ISO_VIFAL, }, { .id = TEGRA264_MEMORY_CLIENT_RCER, .name = "rcer", .bpmp_id = TEGRA264_BWMGR_RCE, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_RCEW, .name = "rcew", .bpmp_id = TEGRA264_BWMGR_RCE, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE0W, .name = "pcie0w", .bpmp_id = TEGRA264_BWMGR_PCIE_0, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE1R, .name = "pcie1r", .bpmp_id = TEGRA264_BWMGR_PCIE_1, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE1W, .name = "pcie1w", .bpmp_id = TEGRA264_BWMGR_PCIE_1, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE2AR, .name = "pcie2ar", .bpmp_id = TEGRA264_BWMGR_PCIE_2, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE2AW, .name = "pcie2aw", .bpmp_id = TEGRA264_BWMGR_PCIE_2, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE3R, .name = "pcie3r", .bpmp_id = TEGRA264_BWMGR_PCIE_3, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE3W, .name = "pcie3w", .bpmp_id = TEGRA264_BWMGR_PCIE_3, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE4R, .name = "pcie4r", .bpmp_id = TEGRA264_BWMGR_PCIE_4, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE4W, .name = "pcie4w", .bpmp_id = TEGRA264_BWMGR_PCIE_4, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE5R, .name = "pcie5r", .bpmp_id = TEGRA264_BWMGR_PCIE_5, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_PCIE5W, .name = "pcie5w", .bpmp_id = TEGRA264_BWMGR_PCIE_5, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_GPUR02MC, .name = "gpur02mc", .bpmp_id = TEGRA264_BWMGR_GPU, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_GPUW02MC, .name = "gpuw02mc", .bpmp_id = TEGRA264_BWMGR_GPU, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_NVDECSRD2MC, .name = "nvdecsrd2mc", .bpmp_id = TEGRA264_BWMGR_NVDEC, .type = TEGRA_ICC_NISO, }, { .id = TEGRA264_MEMORY_CLIENT_NVDECSWR2MC, .name = "nvdecswr2mc", .bpmp_id = TEGRA264_BWMGR_NVDEC, .type = TEGRA_ICC_NISO, }, }; static const char *const tegra264_hub_error_names[32] = { [0] = "coalescer error", [1] = "SMMU BYPASS ALLOW error", [2] = "Illegal tbugrp_id error", [3] = "Malformed MSI request error", [4] = "Read response with poison bit error", [5] = "Restricted access violation error", [6] = "Reserved PA error", }; static const char *const tegra264_mc_error_names[4] = { [1] = "EMEM decode error", [2] = "TrustZone violation", [3] = "Carveout violation", }; static const char *const tegra264_rt_error_names[16] = { [1] = "DECERR_PARTIAL_POPULATED", [2] = "DECERR_SMMU_BYPASS", [3] = "DECERR_INVALID_MMIO", [4] = "DECERR_INVALID_GIC_MSI", [5] = "DECERR_ATOMIC_SYSRAM", [9] = "DECERR_REMOTE_REQ_PRE_BOOT", [10] = "DECERR_ISO_OVER_C2C", [11] = "DECERR_UNSUPPORTED_SBS_OPCODE", [12] = "DECERR_SBS_REQ_OVER_SISO_LL", }; /* * MC instance aperture mapping for hubc registers */ static const int mc_hubc_aperture_number[5] = { 7, 8, 9, 10, 11 }; /* * tegra264_mc_icc_set() - Pass MC client info to the BPMP-FW * @src: ICC node for Memory Controller's (MC) Client * @dst: ICC node for Memory Controller (MC) * * Passing the current request info from the MC to the BPMP-FW where * LA and PTSA registers are accessed and the final EMC freq is set * based on client_id, type, latency and bandwidth. * icc_set_bw() makes set_bw calls for both MC and EMC providers in * sequence. Both the calls are protected by 'mutex_lock(&icc_lock)'. * So, the data passed won't be updated by concurrent set calls from * other clients. */ static int tegra264_mc_icc_set(struct icc_node *src, struct icc_node *dst) { struct tegra_mc *mc = icc_provider_to_tegra_mc(dst->provider); struct mrq_bwmgr_int_request bwmgr_req = { 0 }; struct mrq_bwmgr_int_response bwmgr_resp = { 0 }; const struct tegra_mc_client *pclient = src->data; struct tegra_bpmp_message msg; int ret; /* * Same Src and Dst node will happen during boot from icc_node_add(). * This can be used to pre-initialize and set bandwidth for all clients * before their drivers are loaded. We are skipping this case as for us, * the pre-initialization already happened in Bootloader(MB2) and BPMP-FW. */ if (src->id == dst->id) return 0; if (!mc->bwmgr_mrq_supported) return 0; if (!mc->bpmp) { dev_err(mc->dev, "BPMP reference NULL\n"); return -ENOENT; } if (pclient->type == TEGRA_ICC_NISO) bwmgr_req.bwmgr_calc_set_req.niso_bw = src->avg_bw; else bwmgr_req.bwmgr_calc_set_req.iso_bw = src->avg_bw; bwmgr_req.bwmgr_calc_set_req.client_id = pclient->bpmp_id; bwmgr_req.cmd = CMD_BWMGR_INT_CALC_AND_SET; bwmgr_req.bwmgr_calc_set_req.mc_floor = src->peak_bw; bwmgr_req.bwmgr_calc_set_req.floor_unit = BWMGR_INT_UNIT_KBPS; memset(&msg, 0, sizeof(msg)); msg.mrq = MRQ_BWMGR_INT; msg.tx.data = &bwmgr_req; msg.tx.size = sizeof(bwmgr_req); msg.rx.data = &bwmgr_resp; msg.rx.size = sizeof(bwmgr_resp); ret = tegra_bpmp_transfer(mc->bpmp, &msg); if (ret < 0) { dev_err(mc->dev, "BPMP transfer failed: %d\n", ret); goto error; } if (msg.rx.ret < 0) { pr_err("failed to set bandwidth for %u: %d\n", bwmgr_req.bwmgr_calc_set_req.client_id, msg.rx.ret); ret = -EINVAL; } error: return ret; } static int tegra264_mc_icc_aggregate(struct icc_node *node, u32 tag, u32 avg_bw, u32 peak_bw, u32 *agg_avg, u32 *agg_peak) { struct icc_provider *p = node->provider; struct tegra_mc *mc = icc_provider_to_tegra_mc(p); if (!mc->bwmgr_mrq_supported) return 0; *agg_avg += avg_bw; *agg_peak = max(*agg_peak, peak_bw); return 0; } static int tegra264_mc_icc_get_init_bw(struct icc_node *node, u32 *avg, u32 *peak) { *avg = 0; *peak = 0; return 0; } static void mcf_log_fault(struct tegra_mc *mc, u32 channel, unsigned long mcf_ch_intstatus) { unsigned int bit; for_each_set_bit(bit, &mcf_ch_intstatus, 32) { const char *client = "unknown", *desc = "NA"; u32 status_reg, status1_reg = 0, addr_reg, addr_hi_reg = 0, err_type_mask = 0; u32 value, client_id, i, addr_hi_shift = 0, addr_hi_mask = 0, status1; u32 mc_rw_bit = MC_ERR_STATUS_RW, mc_sec_bit = MC_ERR_STATUS_SECURITY; phys_addr_t addr = 0; u8 type; switch (BIT(bit)) { case MC_INT_DECERR_EMEM: case MC_INT_SECURITY_VIOLATION: status_reg = mc->soc->regs->err_status; addr_reg = mc->soc->regs->err_add; addr_hi_reg = mc->soc->regs->err_add_hi; err_type_mask = mc->soc->mc_err_status_type_mask; break; case MC_INT_DECERR_VPR: status_reg = mc->soc->regs->err_vpr_status; addr_reg = mc->soc->regs->err_vpr_add; addr_hi_shift = MC_ERR_STATUS_ADR_HI_SHIFT; addr_hi_mask = mc->soc->mc_addr_hi_mask; break; case MC_INT_SECERR_SEC: status_reg = mc->soc->regs->err_sec_status; addr_reg = mc->soc->regs->err_sec_add; addr_hi_shift = MC_ERR_STATUS_ADR_HI_SHIFT; addr_hi_mask = mc->soc->mc_addr_hi_mask; break; case MC_INT_DECERR_MTS: status_reg = mc->soc->regs->err_mts_status; addr_reg = mc->soc->regs->err_mts_add; addr_hi_shift = MC_ERR_STATUS_ADR_HI_SHIFT; addr_hi_mask = mc->soc->mc_addr_hi_mask; break; case MC_INT_DECERR_GENERALIZED_CARVEOUT: status_reg = mc->soc->regs->err_gen_co_status; status1_reg = MC_ERR_GENERALIZED_CARVEOUT_STATUS_1_0; addr_reg = mc->soc->regs->err_gen_co_add; addr_hi_shift = MC_ERR_STATUS_GSC_ADR_HI_SHIFT; addr_hi_mask = MC_ERR_STATUS_GSC_ADR_HI_MASK; break; case MC_INT_DECERR_ROUTE_SANITY: case MC_INT_DECERR_ROUTE_SANITY_GIC_MSI: status_reg = mc->soc->regs->err_route_status; addr_reg = mc->soc->regs->err_route_add; addr_hi_shift = MC_ERR_STATUS_RT_ADR_HI_SHIFT; addr_hi_mask = mc->soc->mc_addr_hi_mask; mc_sec_bit = MC_ERR_ROUTE_SANITY_SEC; mc_rw_bit = MC_ERR_ROUTE_SANITY_RW; err_type_mask = MC_ERR_STATUS_RT_TYPE_MASK; break; default: dev_err_ratelimited(mc->dev, "Incorrect MC interrupt mask\n"); return; } value = mc_ch_readl(mc, channel, status_reg); if (addr_hi_reg) { addr = mc_ch_readl(mc, channel, addr_hi_reg); } else { if (!status1_reg) { addr = ((value >> addr_hi_shift) & addr_hi_mask); } else { status1 = mc_ch_readl(mc, channel, status1_reg); addr = ((status1 >> addr_hi_shift) & addr_hi_mask); } } addr <<= 32; addr |= mc_ch_readl(mc, channel, addr_reg); client_id = value & mc->soc->client_id_mask; for (i = 0; i < mc->soc->num_clients; i++) { if (mc->soc->clients[i].id == client_id) { client = mc->soc->clients[i].name; break; } } if (err_type_mask == MC_ERR_STATUS_RT_TYPE_MASK) { type = (value & err_type_mask) >> MC_ERR_STATUS_RT_TYPE_SHIFT; desc = tegra264_rt_error_names[type]; } else if (err_type_mask) { type = (value & err_type_mask) >> MC_ERR_STATUS_TYPE_SHIFT; desc = tegra264_mc_error_names[type]; } dev_err_ratelimited(mc->dev, "%s: %s %s @%pa: %s (%s)\n", client, value & mc_sec_bit ? "secure" : "non-secure", value & mc_rw_bit ? "write" : "read", &addr, tegra_mc_status_names[bit] ?: "unknown", desc); if (status1_reg) dev_err_ratelimited(mc->dev, "gsc_apr_id=%u gsc_co_apr_id=%u\n", ((status1 >> ERR_GENERALIZED_APERTURE_ID_SHIFT) & ERR_GENERALIZED_APERTURE_ID_MASK), ((status1 >> ERR_GENERALIZED_CARVEOUT_APERTURE_ID_SHIFT) & ERR_GENERALIZED_CARVEOUT_APERTURE_ID_MASK)); } /* clear interrupts */ mc_ch_writel(mc, channel, mcf_ch_intstatus, MCF_INTSTATUS_0); } static irqreturn_t handle_mcf_irq(int irq, void *data) { struct tegra_mc *mc = data; unsigned long common_intstat, intstatus; u32 slice; /* Read MCF_COMMON_INTSTATUS0_0_0 from MCB block */ common_intstat = mc_ch_readl(mc, MC_BROADCAST_CHANNEL, MCF_COMMON_INTSTATUS0_0_0); if (common_intstat == 0) { dev_warn(mc->dev, "No interrupt in MCF\n"); return IRQ_NONE; } for_each_set_bit(slice, &common_intstat, 32) { /* Find out the slice number on which interrupt occurred */ if (slice > 4) { dev_err(mc->dev, "Slice index out of bounds: %u\n", slice); return IRQ_NONE; } intstatus = mc_ch_readl(mc, slice, MCF_INTSTATUS_0); if (intstatus != 0) mcf_log_fault(mc, slice, intstatus); } return IRQ_HANDLED; } static void hub_log_fault(struct tegra_mc *mc, u32 hub, unsigned long hub_intstat) { unsigned int bit; for_each_set_bit(bit, &hub_intstat, 32) { const char *client = "unknown"; u32 client_id, status_reg, value, i; phys_addr_t addr = 0; switch (BIT(bit)) { case MSS_HUB_COALESCER_ERR_INTMASK: status_reg = MSS_HUB_COALESCE_ERR_STATUS_0; addr = mc_ch_readl(mc, hub, MSS_HUB_COALESCE_ERR_ADR_HI_0); addr <<= 32; addr |= mc_ch_readl(mc, hub, MSS_HUB_COALESCE_ERR_ADR_0); break; case MSS_HUB_SMMU_BYPASS_ALLOW_ERR_INTMASK: status_reg = MSS_HUB_SMMU_BYPASS_ALLOW_ERR_STATUS_0; break; case MSS_HUB_ILLEGAL_TBUGRP_ID_INTMASK: status_reg = MSS_HUB_ILLEGAL_TBUGRP_ID_ERR_STATUS_0; break; case MSS_HUB_MSI_ERR_INTMASK: status_reg = MSS_HUB_MSI_ERR_STATUS_0; break; case MSS_HUB_POISON_RSP_INTMASK: status_reg = MSS_HUB_POISON_RSP_STATUS_0; break; case MSS_HUB_RESTRICTED_ACCESS_ERR_INTMASK: status_reg = MSS_HUB_RESTRICTED_ACCESS_ERR_STATUS_0; break; case MSS_HUB_RESERVED_PA_ERR_INTMASK: status_reg = MSS_HUB_RESERVED_PA_ERR_STATUS_0; break; default: dev_err_ratelimited(mc->dev, "Incorrect HUB interrupt mask\n"); return; } value = mc_ch_readl(mc, hub, status_reg); client_id = value & mc->soc->client_id_mask; for (i = 0; i < mc->soc->num_clients; i++) { if (mc->soc->clients[i].id == client_id) { client = mc->soc->clients[i].name; break; } } dev_err_ratelimited(mc->dev, "%s: @%pa: %s status: 0x%x\n", client, &addr, tegra264_hub_error_names[bit] ?: "unknown", value); } /* clear interrupts */ mc_ch_writel(mc, hub, hub_intstat, MSS_HUB_INTRSTATUS_0); } static irqreturn_t handle_hub_irq(int irq, void *data, int mc_hubc_aperture_number) { struct tegra_mc *mc = data; u32 global_intstat; unsigned long hub_interrupt, intstat, hub; /* Read MSS_HUB_GLOBAL_INTSTATUS_0 from mc_hubc_aperture_number block */ global_intstat = mc_ch_readl(mc, mc_hubc_aperture_number, MSS_HUB_GLOBAL_INTSTATUS_0); if (global_intstat == 0) { dev_warn(mc->dev, "No interrupt in HUB/HUBC\n"); return IRQ_NONE; } /* Handle interrupt from hubc */ if (global_intstat & MSS_HUBC_INTR) { /* Read MSS_HUB_HUBC_INTSTATUS_0 from block mc_hubc_aperture_number */ intstat = mc_ch_readl(mc, mc_hubc_aperture_number, MSS_HUB_HUBC_INTSTATUS_0); if (intstat != 0) { dev_err_ratelimited(mc->dev, "Scrubber operation status: 0x%lx\n", intstat); /* Clear hubc interrupt */ mc_ch_writel(mc, mc_hubc_aperture_number, intstat, MSS_HUB_HUBC_INTSTATUS_0); } } hub_interrupt = (global_intstat & MSS_HUB_GLOBAL_MASK) >> MSS_HUB_GLOBAL_SHIFT; /* Handle interrupt from hub */ for_each_set_bit(hub, &hub_interrupt, 32) { /* Read MSS_HUB_INTRSTATUS_0 from block MCi */ intstat = mc_ch_readl(mc, hub, MSS_HUB_INTRSTATUS_0); if (intstat != 0) hub_log_fault(mc, hub, intstat); } /* Clear global interrupt status register */ mc_ch_writel(mc, mc_hubc_aperture_number, global_intstat, MSS_HUB_GLOBAL_INTSTATUS_0); return IRQ_HANDLED; } static irqreturn_t handle_disp_hub_irq(int irq, void *data) { return handle_hub_irq(irq, data, mc_hubc_aperture_number[0]); } static irqreturn_t handle_system_hub_irq(int irq, void *data) { return handle_hub_irq(irq, data, mc_hubc_aperture_number[1]); } static irqreturn_t handle_vision_hub_irq(int irq, void *data) { return handle_hub_irq(irq, data, mc_hubc_aperture_number[2]); } static irqreturn_t handle_uphy_hub_irq(int irq, void *data) { return handle_hub_irq(irq, data, mc_hubc_aperture_number[3]); } static irqreturn_t handle_top_hub_irq(int irq, void *data) { return handle_hub_irq(irq, data, mc_hubc_aperture_number[4]); } static irqreturn_t handle_generic_irq(struct tegra_mc *mc, unsigned long intstat_reg) { u32 intstat, i; /* Iterate over all MC blocks to read INTSTATUS */ for (i = 0; i < mc->num_channels; i++) { intstat = mc_ch_readl(mc, i, intstat_reg); if (intstat) { dev_err_ratelimited(mc->dev, "channel: %i status: 0x%x\n", i, intstat); /* Clear interrupt */ mc_ch_writel(mc, i, intstat, intstat_reg); } } return IRQ_HANDLED; } static irqreturn_t handle_sbs_irq(int irq, void *data) { return handle_generic_irq((struct tegra_mc *)data, MSS_SBS_INTSTATUS_0); } static irqreturn_t handle_channel_irq(int irq, void *data) { return handle_generic_irq((struct tegra_mc *)data, MC_CH_INTSTATUS_0); } static const irq_handler_t tegra264_mc_irq_handlers[8] = { handle_mcf_irq, handle_disp_hub_irq, handle_vision_hub_irq, handle_system_hub_irq, handle_uphy_hub_irq, handle_top_hub_irq, handle_sbs_irq, handle_channel_irq }; static const struct tegra_mc_icc_ops tegra264_mc_icc_ops = { .xlate = tegra_mc_icc_xlate, .aggregate = tegra264_mc_icc_aggregate, .get_bw = tegra264_mc_icc_get_init_bw, .set = tegra264_mc_icc_set, }; static const struct tegra_mc_regs tegra264_mc_regs = { .cfg_channel_enable = 0x8870, .err_status = 0xbc00, .err_add = 0xbc04, .err_add_hi = 0xbc08, .err_vpr_status = 0xbc20, .err_vpr_add = 0xbc24, .err_sec_status = 0xbc3c, .err_sec_add = 0xbc40, .err_mts_status = 0xbc5c, .err_mts_add = 0xbc60, .err_gen_co_status = 0xbc78, .err_gen_co_add = 0xbc7c, .err_route_status = 0xbc64, .err_route_add = 0xbc68, }; static const struct tegra_mc_intmask tegra264_mc_intmasks[] = { { .reg = MCF_INTMASK_0, .mask = MC_INT_DECERR_ROUTE_SANITY_GIC_MSI | MC_INT_DECERR_ROUTE_SANITY | MC_INT_DECERR_GENERALIZED_CARVEOUT | MC_INT_DECERR_MTS | MC_INT_SECERR_SEC | MC_INT_DECERR_VPR | MC_INT_SECURITY_VIOLATION | MC_INT_DECERR_EMEM, }, { .reg = MCF_INTPRIORITY_0, .mask = MC_INT_DECERR_ROUTE_SANITY_GIC_MSI | MC_INT_DECERR_ROUTE_SANITY | MC_INT_DECERR_GENERALIZED_CARVEOUT | MC_INT_DECERR_MTS | MC_INT_SECERR_SEC | MC_INT_DECERR_VPR | MC_INT_SECURITY_VIOLATION | MC_INT_DECERR_EMEM, }, { .reg = MSS_HUB_INTRMASK_0, .mask = MSS_HUB_COALESCER_ERR_INTMASK | MSS_HUB_SMMU_BYPASS_ALLOW_ERR_INTMASK | MSS_HUB_ILLEGAL_TBUGRP_ID_INTMASK | MSS_HUB_MSI_ERR_INTMASK | MSS_HUB_POISON_RSP_INTMASK | MSS_HUB_RESTRICTED_ACCESS_ERR_INTMASK | MSS_HUB_RESERVED_PA_ERR_INTMASK, }, { .reg = MSS_HUB_INTRPRIORITY_0, .mask = MSS_HUB_COALESCER_ERR_INTMASK | MSS_HUB_SMMU_BYPASS_ALLOW_ERR_INTMASK | MSS_HUB_ILLEGAL_TBUGRP_ID_INTMASK | MSS_HUB_MSI_ERR_INTMASK | MSS_HUB_POISON_RSP_INTMASK | MSS_HUB_RESTRICTED_ACCESS_ERR_INTMASK | MSS_HUB_RESERVED_PA_ERR_INTMASK, }, { .reg = MSS_HUB_HUBC_INTMASK_0, .mask = MSS_HUB_HUBC_SCRUB_DONE_INTMASK, }, { .reg = MSS_HUB_HUBC_INTPRIORITY_0, .mask = MSS_HUB_HUBC_SCRUB_DONE_INTMASK, }, { .reg = MSS_SBS_INTMASK_0, .mask = MSS_SBS_FILL_FIFO_ISO_OVERFLOW_INTMASK | MSS_SBS_FILL_FIFO_SISO_OVERFLOW_INTMASK | MSS_SBS_FILL_FIFO_NISO_OVERFLOW_INTMASK, }, { .reg = MC_CH_INTMASK_0, .mask = WCAM_ERR_INTMASK, } }; const struct tegra_mc_soc tegra264_mc_soc = { .num_clients = ARRAY_SIZE(tegra264_mc_clients), .clients = tegra264_mc_clients, .num_address_bits = 40, .num_channels = 16, .client_id_mask = 0x1ff, .intmasks = tegra264_mc_intmasks, .num_intmasks = ARRAY_SIZE(tegra264_mc_intmasks), .has_addr_hi_reg = true, .ops = &tegra186_mc_ops, .icc_ops = &tegra264_mc_icc_ops, .ch_intmask = 0x0000ff00, .global_intstatus_channel_shift = 8, /* * Additionally, there are lite carveouts but those are not currently * supported. */ .num_carveouts = 32, .mc_addr_hi_mask = 0xff, .mc_err_status_type_mask = (0x3 << 28), .regs = &tegra264_mc_regs, .handle_irq = tegra264_mc_irq_handlers, .num_interrupts = ARRAY_SIZE(tegra264_mc_irq_handlers), };