// SPDX-License-Identifier: GPL-2.0 /* * Copyright 2016-2019 HabanaLabs, Ltd. * All Rights Reserved. */ #include "goyaP.h" #include "include/goya/goya_coresight.h" #include "include/goya/asic_reg/goya_regs.h" #include "include/goya/asic_reg/goya_masks.h" #include #include #define GOYA_PLDM_CORESIGHT_TIMEOUT_USEC (CORESIGHT_TIMEOUT_USEC * 100) #define SPMU_SECTION_SIZE DMA_CH_0_CS_SPMU_MAX_OFFSET #define SPMU_EVENT_TYPES_OFFSET 0x400 #define SPMU_MAX_COUNTERS 6 static u64 debug_stm_regs[GOYA_STM_LAST + 1] = { [GOYA_STM_CPU] = mmCPU_STM_BASE, [GOYA_STM_DMA_CH_0_CS] = mmDMA_CH_0_CS_STM_BASE, [GOYA_STM_DMA_CH_1_CS] = mmDMA_CH_1_CS_STM_BASE, [GOYA_STM_DMA_CH_2_CS] = mmDMA_CH_2_CS_STM_BASE, [GOYA_STM_DMA_CH_3_CS] = mmDMA_CH_3_CS_STM_BASE, [GOYA_STM_DMA_CH_4_CS] = mmDMA_CH_4_CS_STM_BASE, [GOYA_STM_DMA_MACRO_CS] = mmDMA_MACRO_CS_STM_BASE, [GOYA_STM_MME1_SBA] = mmMME1_SBA_STM_BASE, [GOYA_STM_MME3_SBB] = mmMME3_SBB_STM_BASE, [GOYA_STM_MME4_WACS2] = mmMME4_WACS2_STM_BASE, [GOYA_STM_MME4_WACS] = mmMME4_WACS_STM_BASE, [GOYA_STM_MMU_CS] = mmMMU_CS_STM_BASE, [GOYA_STM_PCIE] = mmPCIE_STM_BASE, [GOYA_STM_PSOC] = mmPSOC_STM_BASE, [GOYA_STM_TPC0_EML] = mmTPC0_EML_STM_BASE, [GOYA_STM_TPC1_EML] = mmTPC1_EML_STM_BASE, [GOYA_STM_TPC2_EML] = mmTPC2_EML_STM_BASE, [GOYA_STM_TPC3_EML] = mmTPC3_EML_STM_BASE, [GOYA_STM_TPC4_EML] = mmTPC4_EML_STM_BASE, [GOYA_STM_TPC5_EML] = mmTPC5_EML_STM_BASE, [GOYA_STM_TPC6_EML] = mmTPC6_EML_STM_BASE, [GOYA_STM_TPC7_EML] = mmTPC7_EML_STM_BASE }; static u64 debug_etf_regs[GOYA_ETF_LAST + 1] = { [GOYA_ETF_CPU_0] = mmCPU_ETF_0_BASE, [GOYA_ETF_CPU_1] = mmCPU_ETF_1_BASE, [GOYA_ETF_CPU_TRACE] = mmCPU_ETF_TRACE_BASE, [GOYA_ETF_DMA_CH_0_CS] = mmDMA_CH_0_CS_ETF_BASE, [GOYA_ETF_DMA_CH_1_CS] = mmDMA_CH_1_CS_ETF_BASE, [GOYA_ETF_DMA_CH_2_CS] = mmDMA_CH_2_CS_ETF_BASE, [GOYA_ETF_DMA_CH_3_CS] = mmDMA_CH_3_CS_ETF_BASE, [GOYA_ETF_DMA_CH_4_CS] = mmDMA_CH_4_CS_ETF_BASE, [GOYA_ETF_DMA_MACRO_CS] = mmDMA_MACRO_CS_ETF_BASE, [GOYA_ETF_MME1_SBA] = mmMME1_SBA_ETF_BASE, [GOYA_ETF_MME3_SBB] = mmMME3_SBB_ETF_BASE, [GOYA_ETF_MME4_WACS2] = mmMME4_WACS2_ETF_BASE, [GOYA_ETF_MME4_WACS] = mmMME4_WACS_ETF_BASE, [GOYA_ETF_MMU_CS] = mmMMU_CS_ETF_BASE, [GOYA_ETF_PCIE] = mmPCIE_ETF_BASE, [GOYA_ETF_PSOC] = mmPSOC_ETF_BASE, [GOYA_ETF_TPC0_EML] = mmTPC0_EML_ETF_BASE, [GOYA_ETF_TPC1_EML] = mmTPC1_EML_ETF_BASE, [GOYA_ETF_TPC2_EML] = mmTPC2_EML_ETF_BASE, [GOYA_ETF_TPC3_EML] = mmTPC3_EML_ETF_BASE, [GOYA_ETF_TPC4_EML] = mmTPC4_EML_ETF_BASE, [GOYA_ETF_TPC5_EML] = mmTPC5_EML_ETF_BASE, [GOYA_ETF_TPC6_EML] = mmTPC6_EML_ETF_BASE, [GOYA_ETF_TPC7_EML] = mmTPC7_EML_ETF_BASE }; static u64 debug_funnel_regs[GOYA_FUNNEL_LAST + 1] = { [GOYA_FUNNEL_CPU] = mmCPU_FUNNEL_BASE, [GOYA_FUNNEL_DMA_CH_6_1] = mmDMA_CH_FUNNEL_6_1_BASE, [GOYA_FUNNEL_DMA_MACRO_3_1] = mmDMA_MACRO_FUNNEL_3_1_BASE, [GOYA_FUNNEL_MME0_RTR] = mmMME0_RTR_FUNNEL_BASE, [GOYA_FUNNEL_MME1_RTR] = mmMME1_RTR_FUNNEL_BASE, [GOYA_FUNNEL_MME2_RTR] = mmMME2_RTR_FUNNEL_BASE, [GOYA_FUNNEL_MME3_RTR] = mmMME3_RTR_FUNNEL_BASE, [GOYA_FUNNEL_MME4_RTR] = mmMME4_RTR_FUNNEL_BASE, [GOYA_FUNNEL_MME5_RTR] = mmMME5_RTR_FUNNEL_BASE, [GOYA_FUNNEL_PCIE] = mmPCIE_FUNNEL_BASE, [GOYA_FUNNEL_PSOC] = mmPSOC_FUNNEL_BASE, [GOYA_FUNNEL_TPC0_EML] = mmTPC0_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC1_EML] = mmTPC1_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC1_RTR] = mmTPC1_RTR_FUNNEL_BASE, [GOYA_FUNNEL_TPC2_EML] = mmTPC2_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC2_RTR] = mmTPC2_RTR_FUNNEL_BASE, [GOYA_FUNNEL_TPC3_EML] = mmTPC3_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC3_RTR] = mmTPC3_RTR_FUNNEL_BASE, [GOYA_FUNNEL_TPC4_EML] = mmTPC4_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC4_RTR] = mmTPC4_RTR_FUNNEL_BASE, [GOYA_FUNNEL_TPC5_EML] = mmTPC5_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC5_RTR] = mmTPC5_RTR_FUNNEL_BASE, [GOYA_FUNNEL_TPC6_EML] = mmTPC6_EML_FUNNEL_BASE, [GOYA_FUNNEL_TPC6_RTR] = mmTPC6_RTR_FUNNEL_BASE, [GOYA_FUNNEL_TPC7_EML] = mmTPC7_EML_FUNNEL_BASE }; static u64 debug_bmon_regs[GOYA_BMON_LAST + 1] = { [GOYA_BMON_CPU_RD] = mmCPU_RD_BMON_BASE, [GOYA_BMON_CPU_WR] = mmCPU_WR_BMON_BASE, [GOYA_BMON_DMA_CH_0_0] = mmDMA_CH_0_BMON_0_BASE, [GOYA_BMON_DMA_CH_0_1] = mmDMA_CH_0_BMON_1_BASE, [GOYA_BMON_DMA_CH_1_0] = mmDMA_CH_1_BMON_0_BASE, [GOYA_BMON_DMA_CH_1_1] = mmDMA_CH_1_BMON_1_BASE, [GOYA_BMON_DMA_CH_2_0] = mmDMA_CH_2_BMON_0_BASE, [GOYA_BMON_DMA_CH_2_1] = mmDMA_CH_2_BMON_1_BASE, [GOYA_BMON_DMA_CH_3_0] = mmDMA_CH_3_BMON_0_BASE, [GOYA_BMON_DMA_CH_3_1] = mmDMA_CH_3_BMON_1_BASE, [GOYA_BMON_DMA_CH_4_0] = mmDMA_CH_4_BMON_0_BASE, [GOYA_BMON_DMA_CH_4_1] = mmDMA_CH_4_BMON_1_BASE, [GOYA_BMON_DMA_MACRO_0] = mmDMA_MACRO_BMON_0_BASE, [GOYA_BMON_DMA_MACRO_1] = mmDMA_MACRO_BMON_1_BASE, [GOYA_BMON_DMA_MACRO_2] = mmDMA_MACRO_BMON_2_BASE, [GOYA_BMON_DMA_MACRO_3] = mmDMA_MACRO_BMON_3_BASE, [GOYA_BMON_DMA_MACRO_4] = mmDMA_MACRO_BMON_4_BASE, [GOYA_BMON_DMA_MACRO_5] = mmDMA_MACRO_BMON_5_BASE, [GOYA_BMON_DMA_MACRO_6] = mmDMA_MACRO_BMON_6_BASE, [GOYA_BMON_DMA_MACRO_7] = mmDMA_MACRO_BMON_7_BASE, [GOYA_BMON_MME1_SBA_0] = mmMME1_SBA_BMON0_BASE, [GOYA_BMON_MME1_SBA_1] = mmMME1_SBA_BMON1_BASE, [GOYA_BMON_MME3_SBB_0] = mmMME3_SBB_BMON0_BASE, [GOYA_BMON_MME3_SBB_1] = mmMME3_SBB_BMON1_BASE, [GOYA_BMON_MME4_WACS2_0] = mmMME4_WACS2_BMON0_BASE, [GOYA_BMON_MME4_WACS2_1] = mmMME4_WACS2_BMON1_BASE, [GOYA_BMON_MME4_WACS2_2] = mmMME4_WACS2_BMON2_BASE, [GOYA_BMON_MME4_WACS_0] = mmMME4_WACS_BMON0_BASE, [GOYA_BMON_MME4_WACS_1] = mmMME4_WACS_BMON1_BASE, [GOYA_BMON_MME4_WACS_2] = mmMME4_WACS_BMON2_BASE, [GOYA_BMON_MME4_WACS_3] = mmMME4_WACS_BMON3_BASE, [GOYA_BMON_MME4_WACS_4] = mmMME4_WACS_BMON4_BASE, [GOYA_BMON_MME4_WACS_5] = mmMME4_WACS_BMON5_BASE, [GOYA_BMON_MME4_WACS_6] = mmMME4_WACS_BMON6_BASE, [GOYA_BMON_MMU_0] = mmMMU_BMON_0_BASE, [GOYA_BMON_MMU_1] = mmMMU_BMON_1_BASE, [GOYA_BMON_PCIE_MSTR_RD] = mmPCIE_BMON_MSTR_RD_BASE, [GOYA_BMON_PCIE_MSTR_WR] = mmPCIE_BMON_MSTR_WR_BASE, [GOYA_BMON_PCIE_SLV_RD] = mmPCIE_BMON_SLV_RD_BASE, [GOYA_BMON_PCIE_SLV_WR] = mmPCIE_BMON_SLV_WR_BASE, [GOYA_BMON_TPC0_EML_0] = mmTPC0_EML_BUSMON_0_BASE, [GOYA_BMON_TPC0_EML_1] = mmTPC0_EML_BUSMON_1_BASE, [GOYA_BMON_TPC0_EML_2] = mmTPC0_EML_BUSMON_2_BASE, [GOYA_BMON_TPC0_EML_3] = mmTPC0_EML_BUSMON_3_BASE, [GOYA_BMON_TPC1_EML_0] = mmTPC1_EML_BUSMON_0_BASE, [GOYA_BMON_TPC1_EML_1] = mmTPC1_EML_BUSMON_1_BASE, [GOYA_BMON_TPC1_EML_2] = mmTPC1_EML_BUSMON_2_BASE, [GOYA_BMON_TPC1_EML_3] = mmTPC1_EML_BUSMON_3_BASE, [GOYA_BMON_TPC2_EML_0] = mmTPC2_EML_BUSMON_0_BASE, [GOYA_BMON_TPC2_EML_1] = mmTPC2_EML_BUSMON_1_BASE, [GOYA_BMON_TPC2_EML_2] = mmTPC2_EML_BUSMON_2_BASE, [GOYA_BMON_TPC2_EML_3] = mmTPC2_EML_BUSMON_3_BASE, [GOYA_BMON_TPC3_EML_0] = mmTPC3_EML_BUSMON_0_BASE, [GOYA_BMON_TPC3_EML_1] = mmTPC3_EML_BUSMON_1_BASE, [GOYA_BMON_TPC3_EML_2] = mmTPC3_EML_BUSMON_2_BASE, [GOYA_BMON_TPC3_EML_3] = mmTPC3_EML_BUSMON_3_BASE, [GOYA_BMON_TPC4_EML_0] = mmTPC4_EML_BUSMON_0_BASE, [GOYA_BMON_TPC4_EML_1] = mmTPC4_EML_BUSMON_1_BASE, [GOYA_BMON_TPC4_EML_2] = mmTPC4_EML_BUSMON_2_BASE, [GOYA_BMON_TPC4_EML_3] = mmTPC4_EML_BUSMON_3_BASE, [GOYA_BMON_TPC5_EML_0] = mmTPC5_EML_BUSMON_0_BASE, [GOYA_BMON_TPC5_EML_1] = mmTPC5_EML_BUSMON_1_BASE, [GOYA_BMON_TPC5_EML_2] = mmTPC5_EML_BUSMON_2_BASE, [GOYA_BMON_TPC5_EML_3] = mmTPC5_EML_BUSMON_3_BASE, [GOYA_BMON_TPC6_EML_0] = mmTPC6_EML_BUSMON_0_BASE, [GOYA_BMON_TPC6_EML_1] = mmTPC6_EML_BUSMON_1_BASE, [GOYA_BMON_TPC6_EML_2] = mmTPC6_EML_BUSMON_2_BASE, [GOYA_BMON_TPC6_EML_3] = mmTPC6_EML_BUSMON_3_BASE, [GOYA_BMON_TPC7_EML_0] = mmTPC7_EML_BUSMON_0_BASE, [GOYA_BMON_TPC7_EML_1] = mmTPC7_EML_BUSMON_1_BASE, [GOYA_BMON_TPC7_EML_2] = mmTPC7_EML_BUSMON_2_BASE, [GOYA_BMON_TPC7_EML_3] = mmTPC7_EML_BUSMON_3_BASE }; static u64 debug_spmu_regs[GOYA_SPMU_LAST + 1] = { [GOYA_SPMU_DMA_CH_0_CS] = mmDMA_CH_0_CS_SPMU_BASE, [GOYA_SPMU_DMA_CH_1_CS] = mmDMA_CH_1_CS_SPMU_BASE, [GOYA_SPMU_DMA_CH_2_CS] = mmDMA_CH_2_CS_SPMU_BASE, [GOYA_SPMU_DMA_CH_3_CS] = mmDMA_CH_3_CS_SPMU_BASE, [GOYA_SPMU_DMA_CH_4_CS] = mmDMA_CH_4_CS_SPMU_BASE, [GOYA_SPMU_DMA_MACRO_CS] = mmDMA_MACRO_CS_SPMU_BASE, [GOYA_SPMU_MME1_SBA] = mmMME1_SBA_SPMU_BASE, [GOYA_SPMU_MME3_SBB] = mmMME3_SBB_SPMU_BASE, [GOYA_SPMU_MME4_WACS2] = mmMME4_WACS2_SPMU_BASE, [GOYA_SPMU_MME4_WACS] = mmMME4_WACS_SPMU_BASE, [GOYA_SPMU_MMU_CS] = mmMMU_CS_SPMU_BASE, [GOYA_SPMU_PCIE] = mmPCIE_SPMU_BASE, [GOYA_SPMU_TPC0_EML] = mmTPC0_EML_SPMU_BASE, [GOYA_SPMU_TPC1_EML] = mmTPC1_EML_SPMU_BASE, [GOYA_SPMU_TPC2_EML] = mmTPC2_EML_SPMU_BASE, [GOYA_SPMU_TPC3_EML] = mmTPC3_EML_SPMU_BASE, [GOYA_SPMU_TPC4_EML] = mmTPC4_EML_SPMU_BASE, [GOYA_SPMU_TPC5_EML] = mmTPC5_EML_SPMU_BASE, [GOYA_SPMU_TPC6_EML] = mmTPC6_EML_SPMU_BASE, [GOYA_SPMU_TPC7_EML] = mmTPC7_EML_SPMU_BASE }; static int goya_coresight_timeout(struct hl_device *hdev, u64 addr, int position, bool up) { int rc; u32 val, timeout_usec; if (hdev->pldm) timeout_usec = GOYA_PLDM_CORESIGHT_TIMEOUT_USEC; else timeout_usec = CORESIGHT_TIMEOUT_USEC; rc = hl_poll_timeout( hdev, addr, val, up ? val & BIT(position) : !(val & BIT(position)), 1000, timeout_usec); if (rc) { dev_err(hdev->dev, "Timeout while waiting for coresight, addr: 0x%llx, position: %d, up: %d\n", addr, position, up); return -EFAULT; } return 0; } static int goya_config_stm(struct hl_device *hdev, struct hl_debug_params *params) { struct hl_debug_params_stm *input; u64 base_reg; int rc; if (params->reg_idx >= ARRAY_SIZE(debug_stm_regs)) { dev_err(hdev->dev, "Invalid register index in STM\n"); return -EINVAL; } base_reg = debug_stm_regs[params->reg_idx] - CFG_BASE; WREG32(base_reg + 0xFB0, CORESIGHT_UNLOCK); if (params->enable) { input = params->input; if (!input) return -EINVAL; WREG32(base_reg + 0xE80, 0x80004); WREG32(base_reg + 0xD64, 7); WREG32(base_reg + 0xD60, 0); WREG32(base_reg + 0xD00, lower_32_bits(input->he_mask)); WREG32(base_reg + 0xD20, lower_32_bits(input->sp_mask)); WREG32(base_reg + 0xD60, 1); WREG32(base_reg + 0xD00, upper_32_bits(input->he_mask)); WREG32(base_reg + 0xD20, upper_32_bits(input->sp_mask)); WREG32(base_reg + 0xE70, 0x10); WREG32(base_reg + 0xE60, 0); WREG32(base_reg + 0xE64, 0x420000); WREG32(base_reg + 0xE00, 0xFFFFFFFF); WREG32(base_reg + 0xE20, 0xFFFFFFFF); WREG32(base_reg + 0xEF4, input->id); WREG32(base_reg + 0xDF4, 0x80); WREG32(base_reg + 0xE8C, input->frequency); WREG32(base_reg + 0xE90, 0x7FF); WREG32(base_reg + 0xE80, 0x27 | (input->id << 16)); } else { WREG32(base_reg + 0xE80, 4); WREG32(base_reg + 0xD64, 0); WREG32(base_reg + 0xD60, 1); WREG32(base_reg + 0xD00, 0); WREG32(base_reg + 0xD20, 0); WREG32(base_reg + 0xD60, 0); WREG32(base_reg + 0xE20, 0); WREG32(base_reg + 0xE00, 0); WREG32(base_reg + 0xDF4, 0x80); WREG32(base_reg + 0xE70, 0); WREG32(base_reg + 0xE60, 0); WREG32(base_reg + 0xE64, 0); WREG32(base_reg + 0xE8C, 0); rc = goya_coresight_timeout(hdev, base_reg + 0xE80, 23, false); if (rc) { dev_err(hdev->dev, "Failed to disable STM on timeout, error %d\n", rc); return rc; } WREG32(base_reg + 0xE80, 4); } return 0; } static int goya_config_etf(struct hl_device *hdev, struct hl_debug_params *params) { struct hl_debug_params_etf *input; u64 base_reg; u32 val; int rc; if (params->reg_idx >= ARRAY_SIZE(debug_etf_regs)) { dev_err(hdev->dev, "Invalid register index in ETF\n"); return -EINVAL; } base_reg = debug_etf_regs[params->reg_idx] - CFG_BASE; WREG32(base_reg + 0xFB0, CORESIGHT_UNLOCK); val = RREG32(base_reg + 0x304); val |= 0x1000; WREG32(base_reg + 0x304, val); val |= 0x40; WREG32(base_reg + 0x304, val); rc = goya_coresight_timeout(hdev, base_reg + 0x304, 6, false); if (rc) { dev_err(hdev->dev, "Failed to %s ETF on timeout, error %d\n", params->enable ? "enable" : "disable", rc); return rc; } rc = goya_coresight_timeout(hdev, base_reg + 0xC, 2, true); if (rc) { dev_err(hdev->dev, "Failed to %s ETF on timeout, error %d\n", params->enable ? "enable" : "disable", rc); return rc; } WREG32(base_reg + 0x20, 0); if (params->enable) { input = params->input; if (!input) return -EINVAL; WREG32(base_reg + 0x34, 0x3FFC); WREG32(base_reg + 0x28, input->sink_mode); WREG32(base_reg + 0x304, 0x4001); WREG32(base_reg + 0x308, 0xA); WREG32(base_reg + 0x20, 1); } else { WREG32(base_reg + 0x34, 0); WREG32(base_reg + 0x28, 0); WREG32(base_reg + 0x304, 0); } return 0; } static int goya_etr_validate_address(struct hl_device *hdev, u64 addr, u32 size) { struct asic_fixed_properties *prop = &hdev->asic_prop; u64 range_start, range_end; if (hdev->mmu_enable) { range_start = prop->dmmu.start_addr; range_end = prop->dmmu.end_addr; } else { range_start = prop->dram_user_base_address; range_end = prop->dram_end_address; } return hl_mem_area_inside_range(addr, size, range_start, range_end); } static int goya_config_etr(struct hl_device *hdev, struct hl_debug_params *params) { struct hl_debug_params_etr *input; u32 val; int rc; WREG32(mmPSOC_ETR_LAR, CORESIGHT_UNLOCK); val = RREG32(mmPSOC_ETR_FFCR); val |= 0x1000; WREG32(mmPSOC_ETR_FFCR, val); val |= 0x40; WREG32(mmPSOC_ETR_FFCR, val); rc = goya_coresight_timeout(hdev, mmPSOC_ETR_FFCR, 6, false); if (rc) { dev_err(hdev->dev, "Failed to %s ETR on timeout, error %d\n", params->enable ? "enable" : "disable", rc); return rc; } rc = goya_coresight_timeout(hdev, mmPSOC_ETR_STS, 2, true); if (rc) { dev_err(hdev->dev, "Failed to %s ETR on timeout, error %d\n", params->enable ? "enable" : "disable", rc); return rc; } WREG32(mmPSOC_ETR_CTL, 0); if (params->enable) { input = params->input; if (!input) return -EINVAL; if (input->buffer_size == 0) { dev_err(hdev->dev, "ETR buffer size should be bigger than 0\n"); return -EINVAL; } if (!goya_etr_validate_address(hdev, input->buffer_address, input->buffer_size)) { dev_err(hdev->dev, "buffer address is not valid\n"); return -EINVAL; } WREG32(mmPSOC_ETR_BUFWM, 0x3FFC); WREG32(mmPSOC_ETR_RSZ, input->buffer_size); WREG32(mmPSOC_ETR_MODE, input->sink_mode); WREG32(mmPSOC_ETR_AXICTL, 0x700 | PSOC_ETR_AXICTL_PROTCTRLBIT1_SHIFT); WREG32(mmPSOC_ETR_DBALO, lower_32_bits(input->buffer_address)); WREG32(mmPSOC_ETR_DBAHI, upper_32_bits(input->buffer_address)); WREG32(mmPSOC_ETR_FFCR, 3); WREG32(mmPSOC_ETR_PSCR, 0xA); WREG32(mmPSOC_ETR_CTL, 1); } else { WREG32(mmPSOC_ETR_BUFWM, 0); WREG32(mmPSOC_ETR_RSZ, 0x400); WREG32(mmPSOC_ETR_DBALO, 0); WREG32(mmPSOC_ETR_DBAHI, 0); WREG32(mmPSOC_ETR_PSCR, 0); WREG32(mmPSOC_ETR_MODE, 0); WREG32(mmPSOC_ETR_FFCR, 0); if (params->output_size >= sizeof(u64)) { u32 rwp, rwphi; /* * The trace buffer address is 40 bits wide. The end of * the buffer is set in the RWP register (lower 32 * bits), and in the RWPHI register (upper 8 bits). */ rwp = RREG32(mmPSOC_ETR_RWP); rwphi = RREG32(mmPSOC_ETR_RWPHI) & 0xff; *(u64 *) params->output = ((u64) rwphi << 32) | rwp; } } return 0; } static int goya_config_funnel(struct hl_device *hdev, struct hl_debug_params *params) { u64 base_reg; if (params->reg_idx >= ARRAY_SIZE(debug_funnel_regs)) { dev_err(hdev->dev, "Invalid register index in FUNNEL\n"); return -EINVAL; } base_reg = debug_funnel_regs[params->reg_idx] - CFG_BASE; WREG32(base_reg + 0xFB0, CORESIGHT_UNLOCK); WREG32(base_reg, params->enable ? 0x33F : 0); return 0; } static int goya_config_bmon(struct hl_device *hdev, struct hl_debug_params *params) { struct hl_debug_params_bmon *input; u64 base_reg; u32 pcie_base = 0; if (params->reg_idx >= ARRAY_SIZE(debug_bmon_regs)) { dev_err(hdev->dev, "Invalid register index in BMON\n"); return -EINVAL; } base_reg = debug_bmon_regs[params->reg_idx] - CFG_BASE; WREG32(base_reg + 0x104, 1); if (params->enable) { input = params->input; if (!input) return -EINVAL; WREG32(base_reg + 0x200, lower_32_bits(input->start_addr0)); WREG32(base_reg + 0x204, upper_32_bits(input->start_addr0)); WREG32(base_reg + 0x208, lower_32_bits(input->addr_mask0)); WREG32(base_reg + 0x20C, upper_32_bits(input->addr_mask0)); WREG32(base_reg + 0x240, lower_32_bits(input->start_addr1)); WREG32(base_reg + 0x244, upper_32_bits(input->start_addr1)); WREG32(base_reg + 0x248, lower_32_bits(input->addr_mask1)); WREG32(base_reg + 0x24C, upper_32_bits(input->addr_mask1)); WREG32(base_reg + 0x224, 0); WREG32(base_reg + 0x234, 0); WREG32(base_reg + 0x30C, input->bw_win); WREG32(base_reg + 0x308, input->win_capture); /* PCIE IF BMON bug WA */ if (params->reg_idx != GOYA_BMON_PCIE_MSTR_RD && params->reg_idx != GOYA_BMON_PCIE_MSTR_WR && params->reg_idx != GOYA_BMON_PCIE_SLV_RD && params->reg_idx != GOYA_BMON_PCIE_SLV_WR) pcie_base = 0xA000000; WREG32(base_reg + 0x700, pcie_base | 0xB00 | (input->id << 12)); WREG32(base_reg + 0x708, pcie_base | 0xA00 | (input->id << 12)); WREG32(base_reg + 0x70C, pcie_base | 0xC00 | (input->id << 12)); WREG32(base_reg + 0x100, 0x11); WREG32(base_reg + 0x304, 0x1); } else { WREG32(base_reg + 0x200, 0); WREG32(base_reg + 0x204, 0); WREG32(base_reg + 0x208, 0xFFFFFFFF); WREG32(base_reg + 0x20C, 0xFFFFFFFF); WREG32(base_reg + 0x240, 0); WREG32(base_reg + 0x244, 0); WREG32(base_reg + 0x248, 0xFFFFFFFF); WREG32(base_reg + 0x24C, 0xFFFFFFFF); WREG32(base_reg + 0x224, 0xFFFFFFFF); WREG32(base_reg + 0x234, 0x1070F); WREG32(base_reg + 0x30C, 0); WREG32(base_reg + 0x308, 0xFFFF); WREG32(base_reg + 0x700, 0xA000B00); WREG32(base_reg + 0x708, 0xA000A00); WREG32(base_reg + 0x70C, 0xA000C00); WREG32(base_reg + 0x100, 1); WREG32(base_reg + 0x304, 0); WREG32(base_reg + 0x104, 0); } return 0; } static int goya_config_spmu(struct hl_device *hdev, struct hl_debug_params *params) { u64 base_reg; struct hl_debug_params_spmu *input = params->input; u64 *output; u32 output_arr_len; u32 events_num; u32 overflow_idx; u32 cycle_cnt_idx; int i; if (params->reg_idx >= ARRAY_SIZE(debug_spmu_regs)) { dev_err(hdev->dev, "Invalid register index in SPMU\n"); return -EINVAL; } base_reg = debug_spmu_regs[params->reg_idx] - CFG_BASE; if (params->enable) { input = params->input; if (!input) return -EINVAL; if (input->event_types_num < 3) { dev_err(hdev->dev, "not enough event types values for SPMU enable\n"); return -EINVAL; } if (input->event_types_num > SPMU_MAX_COUNTERS) { dev_err(hdev->dev, "too many event types values for SPMU enable\n"); return -EINVAL; } WREG32(base_reg + 0xE04, 0x41013046); WREG32(base_reg + 0xE04, 0x41013040); for (i = 0 ; i < input->event_types_num ; i++) WREG32(base_reg + SPMU_EVENT_TYPES_OFFSET + i * 4, input->event_types[i]); WREG32(base_reg + 0xE04, 0x41013041); WREG32(base_reg + 0xC00, 0x8000003F); } else { output = params->output; output_arr_len = params->output_size / 8; events_num = output_arr_len - 2; overflow_idx = output_arr_len - 2; cycle_cnt_idx = output_arr_len - 1; if (!output) return -EINVAL; if (output_arr_len < 3) { dev_err(hdev->dev, "not enough values for SPMU disable\n"); return -EINVAL; } if (events_num > SPMU_MAX_COUNTERS) { dev_err(hdev->dev, "too many events values for SPMU disable\n"); return -EINVAL; } WREG32(base_reg + 0xE04, 0x41013040); for (i = 0 ; i < events_num ; i++) output[i] = RREG32(base_reg + i * 8); output[overflow_idx] = RREG32(base_reg + 0xCC0); output[cycle_cnt_idx] = RREG32(base_reg + 0xFC); output[cycle_cnt_idx] <<= 32; output[cycle_cnt_idx] |= RREG32(base_reg + 0xF8); WREG32(base_reg + 0xCC0, 0); } return 0; } int goya_debug_coresight(struct hl_device *hdev, void *data) { struct hl_debug_params *params = data; u32 val; int rc = 0; switch (params->op) { case HL_DEBUG_OP_STM: rc = goya_config_stm(hdev, params); break; case HL_DEBUG_OP_ETF: rc = goya_config_etf(hdev, params); break; case HL_DEBUG_OP_ETR: rc = goya_config_etr(hdev, params); break; case HL_DEBUG_OP_FUNNEL: rc = goya_config_funnel(hdev, params); break; case HL_DEBUG_OP_BMON: rc = goya_config_bmon(hdev, params); break; case HL_DEBUG_OP_SPMU: rc = goya_config_spmu(hdev, params); break; case HL_DEBUG_OP_TIMESTAMP: /* Do nothing as this opcode is deprecated */ break; default: dev_err(hdev->dev, "Unknown coresight id %d\n", params->op); return -EINVAL; } /* Perform read from the device to flush all configuration */ val = RREG32(mmPCIE_DBI_DEVICE_ID_VENDOR_ID_REG); return rc; } void goya_halt_coresight(struct hl_device *hdev) { struct hl_debug_params params = {}; int i, rc; for (i = GOYA_ETF_FIRST ; i <= GOYA_ETF_LAST ; i++) { params.reg_idx = i; rc = goya_config_etf(hdev, ¶ms); if (rc) dev_err(hdev->dev, "halt ETF failed, %d/%d\n", rc, i); } rc = goya_config_etr(hdev, ¶ms); if (rc) dev_err(hdev->dev, "halt ETR failed, %d\n", rc); }