Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Quan Nguyen | 2538 | 100.00% | 3 | 100.00% |
Total | 2538 | 3 |
// SPDX-License-Identifier: GPL-2.0-only /* * Ampere Computing SoC's SMpro Error Monitoring Driver * * Copyright (c) 2022, Ampere Computing LLC * */ #include <linux/mod_devicetable.h> #include <linux/module.h> #include <linux/platform_device.h> #include <linux/regmap.h> /* GPI RAS Error Registers */ #define GPI_RAS_ERR 0x7E /* Core and L2C Error Registers */ #define CORE_CE_ERR_CNT 0x80 #define CORE_CE_ERR_LEN 0x81 #define CORE_CE_ERR_DATA 0x82 #define CORE_UE_ERR_CNT 0x83 #define CORE_UE_ERR_LEN 0x84 #define CORE_UE_ERR_DATA 0x85 /* Memory Error Registers */ #define MEM_CE_ERR_CNT 0x90 #define MEM_CE_ERR_LEN 0x91 #define MEM_CE_ERR_DATA 0x92 #define MEM_UE_ERR_CNT 0x93 #define MEM_UE_ERR_LEN 0x94 #define MEM_UE_ERR_DATA 0x95 /* RAS Error/Warning Registers */ #define ERR_SMPRO_TYPE 0xA0 #define ERR_PMPRO_TYPE 0xA1 #define ERR_SMPRO_INFO_LO 0xA2 #define ERR_SMPRO_INFO_HI 0xA3 #define ERR_SMPRO_DATA_LO 0xA4 #define ERR_SMPRO_DATA_HI 0xA5 #define WARN_SMPRO_INFO_LO 0xAA #define WARN_SMPRO_INFO_HI 0xAB #define ERR_PMPRO_INFO_LO 0xA6 #define ERR_PMPRO_INFO_HI 0xA7 #define ERR_PMPRO_DATA_LO 0xA8 #define ERR_PMPRO_DATA_HI 0xA9 #define WARN_PMPRO_INFO_LO 0xAC #define WARN_PMPRO_INFO_HI 0xAD /* Boot Stage Register */ #define BOOTSTAGE 0xB0 #define DIMM_SYNDROME_SEL 0xB4 #define DIMM_SYNDROME_ERR 0xB5 #define DIMM_SYNDROME_STAGE 4 /* PCIE Error Registers */ #define PCIE_CE_ERR_CNT 0xC0 #define PCIE_CE_ERR_LEN 0xC1 #define PCIE_CE_ERR_DATA 0xC2 #define PCIE_UE_ERR_CNT 0xC3 #define PCIE_UE_ERR_LEN 0xC4 #define PCIE_UE_ERR_DATA 0xC5 /* Other Error Registers */ #define OTHER_CE_ERR_CNT 0xD0 #define OTHER_CE_ERR_LEN 0xD1 #define OTHER_CE_ERR_DATA 0xD2 #define OTHER_UE_ERR_CNT 0xD8 #define OTHER_UE_ERR_LEN 0xD9 #define OTHER_UE_ERR_DATA 0xDA /* Event Data Registers */ #define VRD_WARN_FAULT_EVENT_DATA 0x78 #define VRD_HOT_EVENT_DATA 0x79 #define DIMM_HOT_EVENT_DATA 0x7A #define DIMM_2X_REFRESH_EVENT_DATA 0x96 #define MAX_READ_BLOCK_LENGTH 48 #define RAS_SMPRO_ERR 0 #define RAS_PMPRO_ERR 1 enum RAS_48BYTES_ERR_TYPES { CORE_CE_ERR, CORE_UE_ERR, MEM_CE_ERR, MEM_UE_ERR, PCIE_CE_ERR, PCIE_UE_ERR, OTHER_CE_ERR, OTHER_UE_ERR, NUM_48BYTES_ERR_TYPE, }; struct smpro_error_hdr { u8 count; /* Number of the RAS errors */ u8 len; /* Number of data bytes */ u8 data; /* Start of 48-byte data */ u8 max_cnt; /* Max num of errors */ }; /* * Included Address of registers to get Count, Length of data and Data * of the 48 bytes error data */ static struct smpro_error_hdr smpro_error_table[] = { [CORE_CE_ERR] = { .count = CORE_CE_ERR_CNT, .len = CORE_CE_ERR_LEN, .data = CORE_CE_ERR_DATA, .max_cnt = 32 }, [CORE_UE_ERR] = { .count = CORE_UE_ERR_CNT, .len = CORE_UE_ERR_LEN, .data = CORE_UE_ERR_DATA, .max_cnt = 32 }, [MEM_CE_ERR] = { .count = MEM_CE_ERR_CNT, .len = MEM_CE_ERR_LEN, .data = MEM_CE_ERR_DATA, .max_cnt = 16 }, [MEM_UE_ERR] = { .count = MEM_UE_ERR_CNT, .len = MEM_UE_ERR_LEN, .data = MEM_UE_ERR_DATA, .max_cnt = 16 }, [PCIE_CE_ERR] = { .count = PCIE_CE_ERR_CNT, .len = PCIE_CE_ERR_LEN, .data = PCIE_CE_ERR_DATA, .max_cnt = 96 }, [PCIE_UE_ERR] = { .count = PCIE_UE_ERR_CNT, .len = PCIE_UE_ERR_LEN, .data = PCIE_UE_ERR_DATA, .max_cnt = 96 }, [OTHER_CE_ERR] = { .count = OTHER_CE_ERR_CNT, .len = OTHER_CE_ERR_LEN, .data = OTHER_CE_ERR_DATA, .max_cnt = 8 }, [OTHER_UE_ERR] = { .count = OTHER_UE_ERR_CNT, .len = OTHER_UE_ERR_LEN, .data = OTHER_UE_ERR_DATA, .max_cnt = 8 }, }; /* * List of SCP registers which are used to get * one type of RAS Internal errors. */ struct smpro_int_error_hdr { u8 type; u8 info_l; u8 info_h; u8 data_l; u8 data_h; u8 warn_l; u8 warn_h; }; static struct smpro_int_error_hdr list_smpro_int_error_hdr[] = { [RAS_SMPRO_ERR] = { .type = ERR_SMPRO_TYPE, .info_l = ERR_SMPRO_INFO_LO, .info_h = ERR_SMPRO_INFO_HI, .data_l = ERR_SMPRO_DATA_LO, .data_h = ERR_SMPRO_DATA_HI, .warn_l = WARN_SMPRO_INFO_LO, .warn_h = WARN_SMPRO_INFO_HI, }, [RAS_PMPRO_ERR] = { .type = ERR_PMPRO_TYPE, .info_l = ERR_PMPRO_INFO_LO, .info_h = ERR_PMPRO_INFO_HI, .data_l = ERR_PMPRO_DATA_LO, .data_h = ERR_PMPRO_DATA_HI, .warn_l = WARN_PMPRO_INFO_LO, .warn_h = WARN_PMPRO_INFO_HI, }, }; struct smpro_errmon { struct regmap *regmap; }; enum EVENT_TYPES { VRD_WARN_FAULT_EVENT, VRD_HOT_EVENT, DIMM_HOT_EVENT, DIMM_2X_REFRESH_EVENT, NUM_EVENTS_TYPE, }; /* Included Address of event source and data registers */ static u8 smpro_event_table[NUM_EVENTS_TYPE] = { VRD_WARN_FAULT_EVENT_DATA, VRD_HOT_EVENT_DATA, DIMM_HOT_EVENT_DATA, DIMM_2X_REFRESH_EVENT_DATA, }; static ssize_t smpro_event_data_read(struct device *dev, struct device_attribute *da, char *buf, int channel) { struct smpro_errmon *errmon = dev_get_drvdata(dev); s32 event_data; int ret; ret = regmap_read(errmon->regmap, smpro_event_table[channel], &event_data); if (ret) return ret; /* Clear event after read */ if (event_data != 0) regmap_write(errmon->regmap, smpro_event_table[channel], event_data); return sysfs_emit(buf, "%04x\n", event_data); } static ssize_t smpro_overflow_data_read(struct device *dev, struct device_attribute *da, char *buf, int channel) { struct smpro_errmon *errmon = dev_get_drvdata(dev); struct smpro_error_hdr *err_info; s32 err_count; int ret; err_info = &smpro_error_table[channel]; ret = regmap_read(errmon->regmap, err_info->count, &err_count); if (ret) return ret; /* Bit 8 indicates the overflow status */ return sysfs_emit(buf, "%d\n", (err_count & BIT(8)) ? 1 : 0); } static ssize_t smpro_error_data_read(struct device *dev, struct device_attribute *da, char *buf, int channel) { struct smpro_errmon *errmon = dev_get_drvdata(dev); unsigned char err_data[MAX_READ_BLOCK_LENGTH]; struct smpro_error_hdr *err_info; s32 err_count, err_length; int ret; err_info = &smpro_error_table[channel]; ret = regmap_read(errmon->regmap, err_info->count, &err_count); /* Error count is the low byte */ err_count &= 0xff; if (ret || !err_count || err_count > err_info->max_cnt) return ret; ret = regmap_read(errmon->regmap, err_info->len, &err_length); if (ret || err_length <= 0) return ret; if (err_length > MAX_READ_BLOCK_LENGTH) err_length = MAX_READ_BLOCK_LENGTH; memset(err_data, 0x00, MAX_READ_BLOCK_LENGTH); ret = regmap_noinc_read(errmon->regmap, err_info->data, err_data, err_length); if (ret < 0) return ret; /* clear the error */ ret = regmap_write(errmon->regmap, err_info->count, 0x100); if (ret) return ret; /* * The output of Core/Memory/PCIe/Others UE/CE errors follows the format * specified in section 5.8.1 CE/UE Error Data record in * Altra SOC BMC Interface specification. */ return sysfs_emit(buf, "%*phN\n", MAX_READ_BLOCK_LENGTH, err_data); } /* * Output format: * <4-byte hex value of error info><4-byte hex value of error extensive data> * Where: * + error info : The error information * + error data : Extensive data (32 bits) * Reference to section 5.10 RAS Internal Error Register Definition in * Altra SOC BMC Interface specification */ static ssize_t smpro_internal_err_read(struct device *dev, struct device_attribute *da, char *buf, int channel) { struct smpro_errmon *errmon = dev_get_drvdata(dev); struct smpro_int_error_hdr *err_info; unsigned int err[4] = { 0 }; unsigned int err_type; unsigned int val; int ret; /* read error status */ ret = regmap_read(errmon->regmap, GPI_RAS_ERR, &val); if (ret) return ret; if ((channel == RAS_SMPRO_ERR && !(val & BIT(0))) || (channel == RAS_PMPRO_ERR && !(val & BIT(1)))) return 0; err_info = &list_smpro_int_error_hdr[channel]; ret = regmap_read(errmon->regmap, err_info->type, &val); if (ret) return ret; err_type = (val & BIT(1)) ? BIT(1) : (val & BIT(2)) ? BIT(2) : 0; if (!err_type) return 0; ret = regmap_read(errmon->regmap, err_info->info_l, err + 1); if (ret) return ret; ret = regmap_read(errmon->regmap, err_info->info_h, err); if (ret) return ret; if (err_type & BIT(2)) { /* Error with data type */ ret = regmap_read(errmon->regmap, err_info->data_l, err + 3); if (ret) return ret; ret = regmap_read(errmon->regmap, err_info->data_h, err + 2); if (ret) return ret; } /* clear the read errors */ ret = regmap_write(errmon->regmap, err_info->type, err_type); if (ret) return ret; return sysfs_emit(buf, "%*phN\n", (int)sizeof(err), err); } /* * Output format: * <4-byte hex value of warining info> * Reference to section 5.10 RAS Internal Error Register Definition in * Altra SOC BMC Interface specification */ static ssize_t smpro_internal_warn_read(struct device *dev, struct device_attribute *da, char *buf, int channel) { struct smpro_errmon *errmon = dev_get_drvdata(dev); struct smpro_int_error_hdr *err_info; unsigned int warn[2] = { 0 }; unsigned int val; int ret; /* read error status */ ret = regmap_read(errmon->regmap, GPI_RAS_ERR, &val); if (ret) return ret; if ((channel == RAS_SMPRO_ERR && !(val & BIT(0))) || (channel == RAS_PMPRO_ERR && !(val & BIT(1)))) return 0; err_info = &list_smpro_int_error_hdr[channel]; ret = regmap_read(errmon->regmap, err_info->type, &val); if (ret) return ret; if (!(val & BIT(0))) return 0; ret = regmap_read(errmon->regmap, err_info->warn_l, warn + 1); if (ret) return ret; ret = regmap_read(errmon->regmap, err_info->warn_h, warn); if (ret) return ret; /* clear the warning */ ret = regmap_write(errmon->regmap, err_info->type, BIT(0)); if (ret) return ret; return sysfs_emit(buf, "%*phN\n", (int)sizeof(warn), warn); } #define ERROR_OVERFLOW_RO(_error, _index) \ static ssize_t overflow_##_error##_show(struct device *dev, \ struct device_attribute *da, \ char *buf) \ { \ return smpro_overflow_data_read(dev, da, buf, _index); \ } \ static DEVICE_ATTR_RO(overflow_##_error) ERROR_OVERFLOW_RO(core_ce, CORE_CE_ERR); ERROR_OVERFLOW_RO(core_ue, CORE_UE_ERR); ERROR_OVERFLOW_RO(mem_ce, MEM_CE_ERR); ERROR_OVERFLOW_RO(mem_ue, MEM_UE_ERR); ERROR_OVERFLOW_RO(pcie_ce, PCIE_CE_ERR); ERROR_OVERFLOW_RO(pcie_ue, PCIE_UE_ERR); ERROR_OVERFLOW_RO(other_ce, OTHER_CE_ERR); ERROR_OVERFLOW_RO(other_ue, OTHER_UE_ERR); #define ERROR_RO(_error, _index) \ static ssize_t error_##_error##_show(struct device *dev, \ struct device_attribute *da, \ char *buf) \ { \ return smpro_error_data_read(dev, da, buf, _index); \ } \ static DEVICE_ATTR_RO(error_##_error) ERROR_RO(core_ce, CORE_CE_ERR); ERROR_RO(core_ue, CORE_UE_ERR); ERROR_RO(mem_ce, MEM_CE_ERR); ERROR_RO(mem_ue, MEM_UE_ERR); ERROR_RO(pcie_ce, PCIE_CE_ERR); ERROR_RO(pcie_ue, PCIE_UE_ERR); ERROR_RO(other_ce, OTHER_CE_ERR); ERROR_RO(other_ue, OTHER_UE_ERR); static ssize_t error_smpro_show(struct device *dev, struct device_attribute *da, char *buf) { return smpro_internal_err_read(dev, da, buf, RAS_SMPRO_ERR); } static DEVICE_ATTR_RO(error_smpro); static ssize_t error_pmpro_show(struct device *dev, struct device_attribute *da, char *buf) { return smpro_internal_err_read(dev, da, buf, RAS_PMPRO_ERR); } static DEVICE_ATTR_RO(error_pmpro); static ssize_t warn_smpro_show(struct device *dev, struct device_attribute *da, char *buf) { return smpro_internal_warn_read(dev, da, buf, RAS_SMPRO_ERR); } static DEVICE_ATTR_RO(warn_smpro); static ssize_t warn_pmpro_show(struct device *dev, struct device_attribute *da, char *buf) { return smpro_internal_warn_read(dev, da, buf, RAS_PMPRO_ERR); } static DEVICE_ATTR_RO(warn_pmpro); #define EVENT_RO(_event, _index) \ static ssize_t event_##_event##_show(struct device *dev, \ struct device_attribute *da, \ char *buf) \ { \ return smpro_event_data_read(dev, da, buf, _index); \ } \ static DEVICE_ATTR_RO(event_##_event) EVENT_RO(vrd_warn_fault, VRD_WARN_FAULT_EVENT); EVENT_RO(vrd_hot, VRD_HOT_EVENT); EVENT_RO(dimm_hot, DIMM_HOT_EVENT); EVENT_RO(dimm_2x_refresh, DIMM_2X_REFRESH_EVENT); static ssize_t smpro_dimm_syndrome_read(struct device *dev, struct device_attribute *da, char *buf, unsigned int slot) { struct smpro_errmon *errmon = dev_get_drvdata(dev); unsigned int data; int ret; ret = regmap_read(errmon->regmap, BOOTSTAGE, &data); if (ret) return ret; /* check for valid stage */ data = (data >> 8) & 0xff; if (data != DIMM_SYNDROME_STAGE) return ret; /* Write the slot ID to retrieve Error Syndrome */ ret = regmap_write(errmon->regmap, DIMM_SYNDROME_SEL, slot); if (ret) return ret; /* Read the Syndrome error */ ret = regmap_read(errmon->regmap, DIMM_SYNDROME_ERR, &data); if (ret || !data) return ret; return sysfs_emit(buf, "%04x\n", data); } #define EVENT_DIMM_SYNDROME(_slot) \ static ssize_t event_dimm##_slot##_syndrome_show(struct device *dev, \ struct device_attribute *da, \ char *buf) \ { \ return smpro_dimm_syndrome_read(dev, da, buf, _slot); \ } \ static DEVICE_ATTR_RO(event_dimm##_slot##_syndrome) EVENT_DIMM_SYNDROME(0); EVENT_DIMM_SYNDROME(1); EVENT_DIMM_SYNDROME(2); EVENT_DIMM_SYNDROME(3); EVENT_DIMM_SYNDROME(4); EVENT_DIMM_SYNDROME(5); EVENT_DIMM_SYNDROME(6); EVENT_DIMM_SYNDROME(7); EVENT_DIMM_SYNDROME(8); EVENT_DIMM_SYNDROME(9); EVENT_DIMM_SYNDROME(10); EVENT_DIMM_SYNDROME(11); EVENT_DIMM_SYNDROME(12); EVENT_DIMM_SYNDROME(13); EVENT_DIMM_SYNDROME(14); EVENT_DIMM_SYNDROME(15); static struct attribute *smpro_errmon_attrs[] = { &dev_attr_overflow_core_ce.attr, &dev_attr_overflow_core_ue.attr, &dev_attr_overflow_mem_ce.attr, &dev_attr_overflow_mem_ue.attr, &dev_attr_overflow_pcie_ce.attr, &dev_attr_overflow_pcie_ue.attr, &dev_attr_overflow_other_ce.attr, &dev_attr_overflow_other_ue.attr, &dev_attr_error_core_ce.attr, &dev_attr_error_core_ue.attr, &dev_attr_error_mem_ce.attr, &dev_attr_error_mem_ue.attr, &dev_attr_error_pcie_ce.attr, &dev_attr_error_pcie_ue.attr, &dev_attr_error_other_ce.attr, &dev_attr_error_other_ue.attr, &dev_attr_error_smpro.attr, &dev_attr_error_pmpro.attr, &dev_attr_warn_smpro.attr, &dev_attr_warn_pmpro.attr, &dev_attr_event_vrd_warn_fault.attr, &dev_attr_event_vrd_hot.attr, &dev_attr_event_dimm_hot.attr, &dev_attr_event_dimm_2x_refresh.attr, &dev_attr_event_dimm0_syndrome.attr, &dev_attr_event_dimm1_syndrome.attr, &dev_attr_event_dimm2_syndrome.attr, &dev_attr_event_dimm3_syndrome.attr, &dev_attr_event_dimm4_syndrome.attr, &dev_attr_event_dimm5_syndrome.attr, &dev_attr_event_dimm6_syndrome.attr, &dev_attr_event_dimm7_syndrome.attr, &dev_attr_event_dimm8_syndrome.attr, &dev_attr_event_dimm9_syndrome.attr, &dev_attr_event_dimm10_syndrome.attr, &dev_attr_event_dimm11_syndrome.attr, &dev_attr_event_dimm12_syndrome.attr, &dev_attr_event_dimm13_syndrome.attr, &dev_attr_event_dimm14_syndrome.attr, &dev_attr_event_dimm15_syndrome.attr, NULL }; ATTRIBUTE_GROUPS(smpro_errmon); static int smpro_errmon_probe(struct platform_device *pdev) { struct smpro_errmon *errmon; errmon = devm_kzalloc(&pdev->dev, sizeof(struct smpro_errmon), GFP_KERNEL); if (!errmon) return -ENOMEM; platform_set_drvdata(pdev, errmon); errmon->regmap = dev_get_regmap(pdev->dev.parent, NULL); if (!errmon->regmap) return -ENODEV; return 0; } static struct platform_driver smpro_errmon_driver = { .probe = smpro_errmon_probe, .driver = { .name = "smpro-errmon", .dev_groups = smpro_errmon_groups, }, }; module_platform_driver(smpro_errmon_driver); MODULE_AUTHOR("Tung Nguyen <tung.nguyen@amperecomputing.com>"); MODULE_AUTHOR("Thinh Pham <thinh.pham@amperecomputing.com>"); MODULE_AUTHOR("Hoang Nguyen <hnguyen@amperecomputing.com>"); MODULE_AUTHOR("Thu Nguyen <thu@os.amperecomputing.com>"); MODULE_AUTHOR("Quan Nguyen <quan@os.amperecomputing.com>"); MODULE_DESCRIPTION("Ampere Altra SMpro driver"); MODULE_LICENSE("GPL");
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