/* * Copyright (c) 2017 Jean-Paul Etienne * Copyright (c) 2023 Meta * Contributors: 2018 Antmicro * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT sifive_plic_1_0_0 /** * @brief Platform Level Interrupt Controller (PLIC) driver * for RISC-V processors */ #include #include "sw_isr_common.h" #include #include #include #include #include #include #include #include #include #define PLIC_BASE_ADDR(n) DT_INST_REG_ADDR(n) /* * These registers' offset are defined in the RISCV PLIC specs, see: * https://github.com/riscv/riscv-plic-spec */ #define CONTEXT_BASE 0x200000 #define CONTEXT_SIZE 0x1000 #define CONTEXT_THRESHOLD 0x00 #define CONTEXT_CLAIM 0x04 #define CONTEXT_ENABLE_BASE 0x2000 #define CONTEXT_ENABLE_SIZE 0x80 /* * Trigger type is mentioned, but not defined in the RISCV PLIC specs. * However, it is defined and supported by at least the Andes & Telink datasheet, and supported * in Linux's SiFive PLIC driver */ #define PLIC_TRIG_LEVEL ((uint32_t)0) #define PLIC_TRIG_EDGE ((uint32_t)1) #define PLIC_DRV_HAS_COMPAT(compat) \ DT_NODE_HAS_COMPAT(DT_COMPAT_GET_ANY_STATUS_OKAY(DT_DRV_COMPAT), compat) #if PLIC_DRV_HAS_COMPAT(andestech_nceplic100) #define PLIC_SUPPORTS_TRIG_TYPE 1 #define PLIC_REG_TRIG_TYPE_WIDTH 1 #define PLIC_REG_TRIG_TYPE_OFFSET 0x1080 #else /* Trigger-type not supported */ #define PLIC_REG_TRIG_TYPE_WIDTH 0 #endif /* PLIC registers are 32-bit memory-mapped */ #define PLIC_REG_SIZE 32 #define PLIC_REG_MASK BIT_MASK(LOG2(PLIC_REG_SIZE)) #ifdef CONFIG_TEST_INTC_PLIC #define INTC_PLIC_STATIC #else #define INTC_PLIC_STATIC static inline #endif typedef void (*riscv_plic_irq_config_func_t)(void); struct plic_config { mem_addr_t prio; mem_addr_t irq_en; mem_addr_t reg; mem_addr_t trig; uint32_t max_prio; uint32_t num_irqs; riscv_plic_irq_config_func_t irq_config_func; struct _isr_table_entry *isr_table; }; struct plic_stats { uint16_t *const irq_count; const int irq_count_len; }; struct plic_data { struct plic_stats stats; }; static uint32_t save_irq; static const struct device *save_dev; INTC_PLIC_STATIC uint32_t local_irq_to_reg_index(uint32_t local_irq) { return local_irq >> LOG2(PLIC_REG_SIZE); } INTC_PLIC_STATIC uint32_t local_irq_to_reg_offset(uint32_t local_irq) { return local_irq_to_reg_index(local_irq) * sizeof(uint32_t); } static inline uint32_t get_plic_enabled_size(const struct device *dev) { const struct plic_config *config = dev->config; return local_irq_to_reg_index(config->num_irqs) + 1; } static inline uint32_t get_first_context(uint32_t hartid) { return hartid == 0 ? 0 : (hartid * 2) - 1; } static inline mem_addr_t get_context_en_addr(const struct device *dev, uint32_t cpu_num) { const struct plic_config *config = dev->config; uint32_t hartid; /* * We want to return the irq_en address for the context of given hart. * If hartid is 0, we return the devices irq_en property, job done. If it is * greater than zero, we assume that there are two context's associated with * each hart: M mode enable, followed by S mode enable. We return the M mode * enable address. */ #if CONFIG_SMP hartid = _kernel.cpus[cpu_num].arch.hartid; #else hartid = arch_proc_id(); #endif return config->irq_en + get_first_context(hartid) * CONTEXT_ENABLE_SIZE; } static inline mem_addr_t get_claim_complete_addr(const struct device *dev) { const struct plic_config *config = dev->config; /* * We want to return the claim complete addr for the hart's context. * We are making a few assumptions here: * 1. for hart 0, return the first context claim complete. * 2. for any other hart, we assume they have two privileged mode contexts * which are contiguous, where the m mode context is first. * We return the m mode context. */ return config->reg + get_first_context(arch_proc_id()) * CONTEXT_SIZE + CONTEXT_CLAIM; } static inline mem_addr_t get_threshold_priority_addr(const struct device *dev, uint32_t cpu_num) { const struct plic_config *config = dev->config; uint32_t hartid; #if CONFIG_SMP hartid = _kernel.cpus[cpu_num].arch.hartid; #else hartid = arch_proc_id(); #endif return config->reg + (get_first_context(hartid) * CONTEXT_SIZE); } /** * @brief Determine the PLIC device from the IRQ * * @param irq IRQ number * * @return PLIC device of that IRQ */ static inline const struct device *get_plic_dev_from_irq(uint32_t irq) { #ifdef CONFIG_DYNAMIC_INTERRUPTS return z_get_sw_isr_device_from_irq(irq); #else return DEVICE_DT_INST_GET(0); #endif } /** * @brief Return the value of the trigger type register for the IRQ * * In the event edge irq is enable this will return the trigger * value of the irq. In the event edge irq is not supported this * routine will return 0 * * @param dev PLIC-instance device * @param local_irq PLIC-instance IRQ number to add to the trigger * * @return Trigger type register value if PLIC supports trigger type, PLIC_TRIG_LEVEL otherwise */ static uint32_t __maybe_unused riscv_plic_irq_trig_val(const struct device *dev, uint32_t local_irq) { if (!IS_ENABLED(PLIC_SUPPORTS_TRIG_TYPE)) { return PLIC_TRIG_LEVEL; } const struct plic_config *config = dev->config; mem_addr_t trig_addr = config->trig + local_irq_to_reg_offset(local_irq); uint32_t offset = local_irq * PLIC_REG_TRIG_TYPE_WIDTH; return sys_read32(trig_addr) & GENMASK(offset + PLIC_REG_TRIG_TYPE_WIDTH - 1, offset); } static void plic_irq_enable_set_state(uint32_t irq, bool enable) { const struct device *dev = get_plic_dev_from_irq(irq); const uint32_t local_irq = irq_from_level_2(irq); for (uint32_t cpu_num = 0; cpu_num < arch_num_cpus(); cpu_num++) { mem_addr_t en_addr = get_context_en_addr(dev, cpu_num) + local_irq_to_reg_offset(local_irq); uint32_t en_value; uint32_t key; key = irq_lock(); en_value = sys_read32(en_addr); WRITE_BIT(en_value, local_irq & PLIC_REG_MASK, enable); sys_write32(en_value, en_addr); irq_unlock(key); } } /** * @brief Enable a riscv PLIC-specific interrupt line * * This routine enables a RISCV PLIC-specific interrupt line. * riscv_plic_irq_enable is called by RISCV_PRIVILEGED * arch_irq_enable function to enable external interrupts for * IRQS level == 2, whenever CONFIG_RISCV_HAS_PLIC variable is set. * * @param irq IRQ number to enable */ void riscv_plic_irq_enable(uint32_t irq) { plic_irq_enable_set_state(irq, true); } /** * @brief Disable a riscv PLIC-specific interrupt line * * This routine disables a RISCV PLIC-specific interrupt line. * riscv_plic_irq_disable is called by RISCV_PRIVILEGED * arch_irq_disable function to disable external interrupts, for * IRQS level == 2, whenever CONFIG_RISCV_HAS_PLIC variable is set. * * @param irq IRQ number to disable */ void riscv_plic_irq_disable(uint32_t irq) { plic_irq_enable_set_state(irq, false); } /** * @brief Check if a riscv PLIC-specific interrupt line is enabled * * This routine checks if a RISCV PLIC-specific interrupt line is enabled. * @param irq IRQ number to check * * @return 1 or 0 */ int riscv_plic_irq_is_enabled(uint32_t irq) { const struct device *dev = get_plic_dev_from_irq(irq); const struct plic_config *config = dev->config; const uint32_t local_irq = irq_from_level_2(irq); mem_addr_t en_addr = config->irq_en + local_irq_to_reg_offset(local_irq); uint32_t en_value; en_value = sys_read32(en_addr); en_value &= BIT(local_irq & PLIC_REG_MASK); return !!en_value; } /** * @brief Set priority of a riscv PLIC-specific interrupt line * * This routine set the priority of a RISCV PLIC-specific interrupt line. * riscv_plic_irq_set_prio is called by riscv arch_irq_priority_set to set * the priority of an interrupt whenever CONFIG_RISCV_HAS_PLIC variable is set. * * @param irq IRQ number for which to set priority * @param priority Priority of IRQ to set to */ void riscv_plic_set_priority(uint32_t irq, uint32_t priority) { const struct device *dev = get_plic_dev_from_irq(irq); const struct plic_config *config = dev->config; const uint32_t local_irq = irq_from_level_2(irq); mem_addr_t prio_addr = config->prio + (local_irq * sizeof(uint32_t)); if (priority > config->max_prio) { priority = config->max_prio; } sys_write32(priority, prio_addr); } /** * @brief Get riscv PLIC-specific interrupt line causing an interrupt * * This routine returns the RISCV PLIC-specific interrupt line causing an * interrupt. * * @param dev Optional device pointer to get the interrupt line's controller * * @return PLIC-specific interrupt line causing an interrupt. */ unsigned int riscv_plic_get_irq(void) { return save_irq; } const struct device *riscv_plic_get_dev(void) { return save_dev; } static void plic_irq_handler(const struct device *dev) { const struct plic_config *config = dev->config; mem_addr_t claim_complete_addr = get_claim_complete_addr(dev); struct _isr_table_entry *ite; uint32_t __maybe_unused trig_val; /* Get the IRQ number generating the interrupt */ const uint32_t local_irq = sys_read32(claim_complete_addr); #ifdef CONFIG_PLIC_SHELL const struct plic_data *data = dev->data; struct plic_stats stat = data->stats; /* Cap the count at __UINT16_MAX__ */ if (stat.irq_count[local_irq] != __UINT16_MAX__) { stat.irq_count[local_irq]++; } #endif /* CONFIG_PLIC_SHELL */ /* * Save IRQ in save_irq. To be used, if need be, by * subsequent handlers registered in the _sw_isr_table table, * as IRQ number held by the claim_complete register is * cleared upon read. */ save_irq = local_irq; save_dev = dev; /* * If the IRQ is out of range, call z_irq_spurious. * A call to z_irq_spurious will not return. */ if (local_irq == 0U || local_irq >= config->num_irqs) { z_irq_spurious(NULL); } #if PLIC_DRV_HAS_COMPAT(andestech_nceplic100) trig_val = riscv_plic_irq_trig_val(dev, local_irq); /* * Edge-triggered interrupts on Andes NCEPLIC100 have to be acknowledged first before * getting handled so that we don't miss on the next edge-triggered interrupt. */ if (trig_val == PLIC_TRIG_EDGE) { sys_write32(local_irq, claim_complete_addr); } #endif /* Call the corresponding IRQ handler in _sw_isr_table */ ite = &config->isr_table[local_irq]; ite->isr(ite->arg); /* * Write to claim_complete register to indicate to * PLIC controller that the IRQ has been handled * for level triggered interrupts. */ #if PLIC_DRV_HAS_COMPAT(andestech_nceplic100) /* For NCEPLIC100, handle only if level-triggered */ if (trig_val == PLIC_TRIG_LEVEL) { sys_write32(local_irq, claim_complete_addr); } #else sys_write32(local_irq, claim_complete_addr); #endif } /** * @brief Initialize the Platform Level Interrupt Controller * * @param dev PLIC device struct * * @retval 0 on success. */ static int plic_init(const struct device *dev) { const struct plic_config *config = dev->config; mem_addr_t en_addr, thres_prio_addr; mem_addr_t prio_addr = config->prio; /* Iterate through each of the contexts, HART + PRIV */ for (uint32_t cpu_num = 0; cpu_num < arch_num_cpus(); cpu_num++) { en_addr = get_context_en_addr(dev, cpu_num); thres_prio_addr = get_threshold_priority_addr(dev, cpu_num); /* Ensure that all interrupts are disabled initially */ for (uint32_t i = 0; i < get_plic_enabled_size(dev); i++) { sys_write32(0U, en_addr + (i * sizeof(uint32_t))); } /* Set threshold priority to 0 */ sys_write32(0U, thres_prio_addr); } /* Set priority of each interrupt line to 0 initially */ for (uint32_t i = 0; i < config->num_irqs; i++) { sys_write32(0U, prio_addr + (i * sizeof(uint32_t))); } /* Configure IRQ for PLIC driver */ config->irq_config_func(); return 0; } #ifdef CONFIG_PLIC_SHELL static inline int parse_device(const struct shell *sh, size_t argc, char *argv[], const struct device **plic) { ARG_UNUSED(argc); *plic = device_get_binding(argv[1]); if (*plic == NULL) { shell_error(sh, "PLIC device (%s) not found!\n", argv[1]); return -ENODEV; } return 0; } static int cmd_get_stats(const struct shell *sh, size_t argc, char *argv[]) { const struct device *dev; int ret = parse_device(sh, argc, argv, &dev); uint16_t min_hit = 0; if (ret != 0) { return ret; } const struct plic_config *config = dev->config; const struct plic_data *data = dev->data; struct plic_stats stat = data->stats; if (argc > 2) { min_hit = (uint16_t)atoi(argv[2]); shell_print(sh, "IRQ line with > %d hits:", min_hit); } shell_print(sh, " IRQ Hits\tISR(ARG)"); for (int i = 0; i < stat.irq_count_len; i++) { if (stat.irq_count[i] > min_hit) { #ifdef CONFIG_SYMTAB const char *name = symtab_find_symbol_name((uintptr_t)config->isr_table[i].isr, NULL); shell_print(sh, " %4d %10d\t%s(%p)", i, stat.irq_count[i], name, config->isr_table[i].arg); #else shell_print(sh, " %4d %10d\t%p(%p)", i, stat.irq_count[i], (void *)config->isr_table[i].isr, config->isr_table[i].arg); #endif /* CONFIG_SYMTAB */ } } shell_print(sh, ""); return 0; } static int cmd_clear_stats(const struct shell *sh, size_t argc, char *argv[]) { const struct device *dev; int ret = parse_device(sh, argc, argv, &dev); if (ret != 0) { return ret; } const struct plic_data *data = dev->data; struct plic_stats stat = data->stats; memset(stat.irq_count, 0, stat.irq_count_len * sizeof(uint16_t)); shell_print(sh, "Cleared stats of %s.\n", dev->name); return 0; } /* Device name autocompletion support */ static void device_name_get(size_t idx, struct shell_static_entry *entry) { const struct device *dev = shell_device_lookup(idx, NULL); entry->syntax = (dev != NULL) ? dev->name : NULL; entry->handler = NULL; entry->help = NULL; entry->subcmd = NULL; } SHELL_DYNAMIC_CMD_CREATE(dsub_device_name, device_name_get); SHELL_STATIC_SUBCMD_SET_CREATE(plic_stats_cmds, SHELL_CMD_ARG(get, &dsub_device_name, "Read PLIC's stats.\n" "Usage: plic stats get [minimum hits]", cmd_get_stats, 2, 1), SHELL_CMD_ARG(clear, &dsub_device_name, "Reset PLIC's stats.\n" "Usage: plic stats clear ", cmd_clear_stats, 2, 0), SHELL_SUBCMD_SET_END ); SHELL_STATIC_SUBCMD_SET_CREATE(plic_cmds, SHELL_CMD_ARG(stats, &plic_stats_cmds, "PLIC stats", NULL, 3, 0), SHELL_SUBCMD_SET_END ); static int cmd_plic(const struct shell *sh, size_t argc, char **argv) { shell_error(sh, "%s:unknown parameter: %s", argv[0], argv[1]); return -EINVAL; } SHELL_CMD_ARG_REGISTER(plic, &plic_cmds, "PLIC shell commands", cmd_plic, 2, 0); #define PLIC_MIN_IRQ_NUM(n) MIN(DT_INST_PROP(n, riscv_ndev), CONFIG_MAX_IRQ_PER_AGGREGATOR) #define PLIC_INTC_IRQ_COUNT_BUF_DEFINE(n) \ static uint16_t local_irq_count_##n[PLIC_MIN_IRQ_NUM(n)]; #define PLIC_INTC_DATA_INIT(n) \ PLIC_INTC_IRQ_COUNT_BUF_DEFINE(n); \ static struct plic_data plic_data_##n = { \ .stats = { \ .irq_count = local_irq_count_##n, \ .irq_count_len = PLIC_MIN_IRQ_NUM(n), \ }, \ }; #define PLIC_INTC_DATA(n) &plic_data_##n #else #define PLIC_INTC_DATA_INIT(...) #define PLIC_INTC_DATA(n) (NULL) #endif #define PLIC_INTC_IRQ_FUNC_DECLARE(n) static void plic_irq_config_func_##n(void) #define PLIC_INTC_IRQ_FUNC_DEFINE(n) \ static void plic_irq_config_func_##n(void) \ { \ IRQ_CONNECT(DT_INST_IRQN(n), 0, plic_irq_handler, DEVICE_DT_INST_GET(n), 0); \ irq_enable(DT_INST_IRQN(n)); \ } #define PLIC_INTC_CONFIG_INIT(n) \ PLIC_INTC_IRQ_FUNC_DECLARE(n); \ static const struct plic_config plic_config_##n = { \ .prio = PLIC_BASE_ADDR(n), \ .irq_en = PLIC_BASE_ADDR(n) + CONTEXT_ENABLE_BASE, \ .reg = PLIC_BASE_ADDR(n) + CONTEXT_BASE, \ IF_ENABLED(PLIC_SUPPORTS_TRIG_TYPE, \ (.trig = PLIC_BASE_ADDR(n) + PLIC_REG_TRIG_TYPE_OFFSET,)) \ .max_prio = DT_INST_PROP(n, riscv_max_priority), \ .num_irqs = DT_INST_PROP(n, riscv_ndev), \ .irq_config_func = plic_irq_config_func_##n, \ .isr_table = &_sw_isr_table[INTC_INST_ISR_TBL_OFFSET(n)], \ }; \ PLIC_INTC_IRQ_FUNC_DEFINE(n) #define PLIC_INTC_DEVICE_INIT(n) \ IRQ_PARENT_ENTRY_DEFINE( \ plic##n, DEVICE_DT_INST_GET(n), DT_INST_IRQN(n), \ INTC_INST_ISR_TBL_OFFSET(n), \ DT_INST_INTC_GET_AGGREGATOR_LEVEL(n)); \ PLIC_INTC_CONFIG_INIT(n) \ PLIC_INTC_DATA_INIT(n) \ DEVICE_DT_INST_DEFINE(n, &plic_init, NULL, \ PLIC_INTC_DATA(n), &plic_config_##n, \ PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY, \ NULL); DT_INST_FOREACH_STATUS_OKAY(PLIC_INTC_DEVICE_INIT)