/* * Copyright (c) 2018 Foundries.io * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT openisa_rv32m1_intmux /** * @file * @brief RV32M1 INTMUX (interrupt multiplexer) driver * * This driver provides support for level 2 interrupts on the RV32M1 * SoC using the INTMUX peripheral. * * Each of the RI5CY and ZERO-RISCY cores has an INTMUX peripheral; * INTMUX0 is wired to the RI5CY event unit interrupt table, while * INTMUX1 is used with ZERO-RISCY. * * For this reason, only a single intmux device is declared here. The * dtsi for each core needs to set up the intmux device and any * associated IRQ numbers to work with this driver. */ #include #include #include #include #include #include #include #include /* * CHn_VEC registers are offset by a value that is convenient if * you're dealing with a Cortex-M NVIC vector table; we're not, so it * needs to be subtracted out to get a useful value. */ #define VECN_OFFSET 48U struct rv32m1_intmux_config { INTMUX_Type *regs; const struct device *clock_dev; clock_control_subsys_t clock_subsys; struct _isr_table_entry *isr_base; }; #define DEV_CFG(dev) \ ((struct rv32m1_intmux_config *)(dev->config)) #define DEV_REGS(dev) (DEV_CFG(dev)->regs) /* * API */ static void rv32m1_intmux_irq_enable(const struct device *dev, uint32_t irq) { INTMUX_Type *regs = DEV_REGS(dev); uint32_t channel = rv32m1_intmux_channel(irq); uint32_t line = rv32m1_intmux_line(irq); regs->CHANNEL[channel].CHn_IER_31_0 |= BIT(line); } static void rv32m1_intmux_irq_disable(const struct device *dev, uint32_t irq) { INTMUX_Type *regs = DEV_REGS(dev); uint32_t channel = rv32m1_intmux_channel(irq); uint32_t line = rv32m1_intmux_line(irq); regs->CHANNEL[channel].CHn_IER_31_0 &= ~BIT(line); } static uint32_t rv32m1_intmux_get_state(const struct device *dev) { INTMUX_Type *regs = DEV_REGS(dev); size_t i; for (i = 0; i < INTMUX_CHn_IER_31_0_COUNT; i++) { if (regs->CHANNEL[i].CHn_IER_31_0) { return 1; } } return 0; } static int rv32m1_intmux_get_line_state(const struct device *dev, unsigned int irq) { INTMUX_Type *regs = DEV_REGS(dev); uint32_t channel = rv32m1_intmux_channel(irq); uint32_t line = rv32m1_intmux_line(irq); if ((regs->CHANNEL[channel].CHn_IER_31_0 & BIT(line)) != 0) { return 1; } return 0; } /* * IRQ handling. */ #define ISR_ENTRY(channel, line) \ ((channel) * CONFIG_MAX_IRQ_PER_AGGREGATOR + line) static void rv32m1_intmux_isr(const void *arg) { const struct device *dev = DEVICE_DT_INST_GET(0); INTMUX_Type *regs = DEV_REGS(dev); uint32_t channel = POINTER_TO_UINT(arg); uint32_t line = (regs->CHANNEL[channel].CHn_VEC >> 2); struct _isr_table_entry *isr_base = DEV_CFG(dev)->isr_base; struct _isr_table_entry *entry; /* * Make sure the vector is valid, there is a note of page 1243~1244 * of chapter 36 INTMUX of RV32M1 RM, * Note: Unlike the NVIC, the INTMUX does not latch pending source * interrupts. This means that the INTMUX output channel ISRs must * check for and handle a 0 value of the CHn_VEC register to * account for spurious interrupts. */ if (line < VECN_OFFSET) { return; } entry = &isr_base[ISR_ENTRY(channel, (line - VECN_OFFSET))]; entry->isr(entry->arg); } /* * Instance and initialization */ static const struct irq_next_level_api rv32m1_intmux_apis = { .intr_enable = rv32m1_intmux_irq_enable, .intr_disable = rv32m1_intmux_irq_disable, .intr_get_state = rv32m1_intmux_get_state, .intr_get_line_state = rv32m1_intmux_get_line_state, }; static const struct rv32m1_intmux_config rv32m1_intmux_cfg = { .regs = (INTMUX_Type *)DT_INST_REG_ADDR(0), .clock_dev = DEVICE_DT_GET(DT_INST_CLOCKS_CTLR(0)), .clock_subsys = UINT_TO_POINTER(DT_INST_CLOCKS_CELL(0, name)), .isr_base = &_sw_isr_table[CONFIG_2ND_LVL_ISR_TBL_OFFSET], }; static int rv32m1_intmux_init(const struct device *dev) { const struct rv32m1_intmux_config *config = DEV_CFG(dev); INTMUX_Type *regs = DEV_REGS(dev); size_t i; /* Enable INTMUX clock. */ clock_control_on(config->clock_dev, config->clock_subsys); /* * Reset all channels, not just the ones we're configured to * support. We don't want to continue to take level 2 IRQs * enabled by bootloaders, for example. */ for (i = 0; i < INTMUX_CHn_CSR_COUNT; i++) { regs->CHANNEL[i].CHn_CSR |= INTMUX_CHn_CSR_RST_MASK; } /* Connect and enable level 1 (channel) interrupts. */ #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_0 IRQ_CONNECT(INTMUX_CH0_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(0), 0); irq_enable(INTMUX_CH0_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_1 IRQ_CONNECT(INTMUX_CH1_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(1), 0); irq_enable(INTMUX_CH1_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_2 IRQ_CONNECT(INTMUX_CH2_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(2), 0); irq_enable(INTMUX_CH2_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_3 IRQ_CONNECT(INTMUX_CH3_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(3), 0); irq_enable(INTMUX_CH3_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_4 IRQ_CONNECT(INTMUX_CH4_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(4), 0); irq_enable(INTMUX_CH4_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_5 IRQ_CONNECT(INTMUX_CH5_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(5), 0); irq_enable(INTMUX_CH5_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_6 IRQ_CONNECT(INTMUX_CH6_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(6), 0); irq_enable(INTMUX_CH6_IRQ); #endif #ifdef CONFIG_RV32M1_INTMUX_CHANNEL_7 IRQ_CONNECT(INTMUX_CH7_IRQ, 0, rv32m1_intmux_isr, UINT_TO_POINTER(7), 0); irq_enable(INTMUX_CH7_IRQ); #endif return 0; } DEVICE_DT_INST_DEFINE(0, &rv32m1_intmux_init, NULL, NULL, &rv32m1_intmux_cfg, PRE_KERNEL_1, CONFIG_RV32M1_INTMUX_INIT_PRIORITY, &rv32m1_intmux_apis);