/* * Copyright (c) 2023 Antmicro * * SPDX-License-Identifier: Apache-2.0 */ #define DT_DRV_COMPAT renesas_rzt2m_gpio #include #include #include #include #include #include #include #include #include #include static const struct device *const ns_portnf_md_dev = DEVICE_DT_GET(DT_NODELABEL(ns_portnf_md)); #define PMm_OFFSET 0x200 #define PMCm_OFFSET 0x400 #define PFCm_OFFSET 0x600 #define PINm_OFFSET 0x800 #define DRCTLm_OFFSET 0xa00 #define PMm_SIZE 0x2 #define DRCTLm_SIZE 0x8 #define PFCm_SIZE 0x4 /* config defines in include/zephyr/dt-bindings/gpio/renesas-rzt2m-gpio.h */ #define DRIVE_SHIFT 0 #define SCHMITT_TRIGGER_SHIFT 4 #define SLEW_RATE_SHIFT 5 #define PULL_SHIFT 2 #define PULL_NONE (0 << PULL_SHIFT) #define PULL_UP (1 << PULL_SHIFT) #define PULL_DOWN (2 << PULL_SHIFT) #define INT_INVERT 0 #define INT_FALLING_EDGE 1 #define INT_RISING_EDGE 2 #define INT_BOTH_EDGE 3 #define IRQ_COUNT 16 #define NS_IRQ_COUNT 14 #define MAX_PORT_SIZE 8 #define RZT2M_GPIO_VALUE_IDENTITY(i, _) i struct rzt2m_gpio_config { struct gpio_driver_config common; uint8_t pin_irqs[MAX_PORT_SIZE]; uint8_t *port_nsr; uint8_t *ptadr; uint8_t port; }; struct rzt2m_gpio_data { struct gpio_driver_data common; sys_slist_t cb; }; struct rzt2m_gpio_irq_slot { const struct device *dev; uint8_t pin; }; struct rzt2m_gpio_common_data { struct rzt2m_gpio_irq_slot irq_registered_ports[IRQ_COUNT]; }; static struct rzt2m_gpio_common_data rzt2m_gpio_common_data_inst; static void rzt2m_gpio_unlock(void) { rzt2m_unlock_prcrn(PRCRN_PRC1 | PRCRN_PRC2); rzt2m_unlock_prcrs(PRCRS_GPIO); } static void rzt2m_gpio_lock(void) { rzt2m_lock_prcrn(PRCRN_PRC1 | PRCRN_PRC2); rzt2m_lock_prcrs(PRCRS_GPIO); } /* Port m output data store */ static volatile uint8_t *rzt2m_gpio_get_p_reg(const struct device *dev) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint8_t *)(config->port_nsr + config->port); } /* Port m input data store */ static volatile uint8_t *rzt2m_gpio_get_pin_reg(const struct device *dev) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint8_t *)(config->port_nsr + PINm_OFFSET + config->port); } /* Port m mode register */ static volatile uint16_t *rzt2m_gpio_get_pm_reg(const struct device *dev) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint16_t *)(config->port_nsr + PMm_OFFSET + PMm_SIZE * config->port); } /* IO Buffer m function switching register */ static volatile uint64_t *rzt2m_gpio_get_drctl_reg(const struct device *dev) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint64_t *)(config->port_nsr + DRCTLm_OFFSET + DRCTLm_SIZE * config->port); } /* Port m region select register */ static volatile uint8_t *rzt2m_gpio_get_rselp_reg(const struct device *dev) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint8_t *)(config->ptadr + config->port); } /* Port m mode control register */ static volatile uint8_t *rzt2m_gpio_get_pmc_reg(const struct device *dev, uint8_t port) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint8_t *)(config->port_nsr + PMCm_OFFSET + port); } /* Port m function control register */ static volatile uint32_t *rzt2m_gpio_get_pfc_reg(const struct device *dev, uint8_t port) { const struct rzt2m_gpio_config *config = dev->config; return (volatile uint32_t *)(config->port_nsr + PFCm_OFFSET + PFCm_SIZE * port); } static int rzt2m_gpio_init(const struct device *dev) { rzt2m_gpio_unlock(); volatile uint8_t *rselp_reg = rzt2m_gpio_get_rselp_reg(dev); *rselp_reg = 0xFF; rzt2m_gpio_lock(); return 0; } static int rzt2m_gpio_get_raw(const struct device *dev, gpio_port_value_t *value) { rzt2m_gpio_unlock(); volatile uint8_t *pin_reg = rzt2m_gpio_get_pin_reg(dev); *value = *pin_reg; rzt2m_gpio_lock(); return 0; } static int rzt2m_port_set_masked_raw(const struct device *dev, gpio_port_pins_t mask, gpio_port_value_t value) { rzt2m_gpio_unlock(); volatile uint8_t *p_reg = rzt2m_gpio_get_p_reg(dev); *p_reg = (*p_reg & ~mask) | (value & mask); rzt2m_gpio_lock(); return 0; } static int rzt2m_port_set_bits_raw(const struct device *dev, gpio_port_pins_t pins) { rzt2m_gpio_unlock(); volatile uint8_t *p_reg = rzt2m_gpio_get_p_reg(dev); *p_reg |= pins; rzt2m_gpio_lock(); return 0; } static int rzt2m_port_clear_bits_raw(const struct device *dev, gpio_port_pins_t pins) { rzt2m_gpio_unlock(); volatile uint8_t *p_reg = rzt2m_gpio_get_p_reg(dev); *p_reg &= ~pins; rzt2m_gpio_lock(); return 0; } static int rzt2m_gpio_toggle(const struct device *dev, gpio_port_pins_t pins) { rzt2m_gpio_unlock(); volatile uint8_t *p_reg = rzt2m_gpio_get_p_reg(dev); *p_reg ^= pins; rzt2m_gpio_lock(); return 0; } static int rzt2m_gpio_configure(const struct device *dev, gpio_pin_t pin, gpio_flags_t flags) { volatile uint16_t *pm_reg = rzt2m_gpio_get_pm_reg(dev); volatile uint64_t *drctl_reg = rzt2m_gpio_get_drctl_reg(dev); rzt2m_gpio_unlock(); WRITE_BIT(*pm_reg, pin * 2, flags & GPIO_INPUT); WRITE_BIT(*pm_reg, pin * 2 + 1, flags & GPIO_OUTPUT); if (flags & GPIO_OUTPUT) { if (flags & GPIO_OUTPUT_INIT_LOW) { rzt2m_port_clear_bits_raw(dev, 1 << pin); } else if (flags & GPIO_OUTPUT_INIT_HIGH) { rzt2m_port_set_bits_raw(dev, 1 << pin); } } if (flags & GPIO_PULL_UP && flags & GPIO_PULL_DOWN) { rzt2m_gpio_lock(); return -EINVAL; } uint8_t drctl_pin_config = 0; if (flags & GPIO_PULL_UP) { drctl_pin_config |= PULL_UP; } else if (flags & GPIO_PULL_DOWN) { drctl_pin_config |= PULL_DOWN; } else { drctl_pin_config |= PULL_NONE; } drctl_pin_config |= (flags & RZT2M_GPIO_DRIVE_MASK) >> (RZT2M_GPIO_DRIVE_OFFSET - DRIVE_SHIFT); drctl_pin_config |= (flags & RZT2M_GPIO_SCHMITT_TRIGGER_MASK) >> (RZT2M_GPIO_SCHMITT_TRIGGER_OFFSET - SCHMITT_TRIGGER_SHIFT); drctl_pin_config |= (flags & RZT2M_GPIO_SLEW_RATE_MASK) >> (RZT2M_GPIO_SLEW_RATE_OFFSET - SLEW_RATE_SHIFT); uint64_t drctl_pin_value = *drctl_reg & ~(0xFFULL << (pin * 8)); *drctl_reg = drctl_pin_value | ((uint64_t)drctl_pin_config << (pin * 8)); rzt2m_gpio_lock(); return 0; } static int rzt2m_gpio_get_pin_irq(const struct device *dev, gpio_pin_t pin) { const struct rzt2m_gpio_config *config = dev->config; if (pin >= MAX_PORT_SIZE) { return -1; } return config->pin_irqs[pin] - 1; } static bool rzt2m_gpio_is_irq_used_by_other_pin(const struct device *dev, gpio_pin_t pin, uint8_t irq) { if (irq >= IRQ_COUNT) { return false; } if (rzt2m_gpio_common_data_inst.irq_registered_ports[irq].dev == NULL) { return false; } if (rzt2m_gpio_common_data_inst.irq_registered_ports[irq].dev != dev) { return true; } return rzt2m_gpio_common_data_inst.irq_registered_ports[irq].pin != pin; } static void rzt2m_gpio_isr(uint8_t *irq_n) { const struct device *dev = rzt2m_gpio_common_data_inst.irq_registered_ports[*irq_n].dev; if (dev) { struct rzt2m_gpio_data *data = dev->data; int irq_pin = rzt2m_gpio_common_data_inst.irq_registered_ports[*irq_n].pin; if (irq_pin >= 0) { gpio_fire_callbacks(&data->cb, dev, 1 << irq_pin); } } } static int rzt2m_gpio_pin_interrupt_configure(const struct device *dev, gpio_pin_t pin, enum gpio_int_mode mode, enum gpio_int_trig trig) { const struct rzt2m_gpio_config *config = dev->config; volatile uint8_t *pmc_reg = rzt2m_gpio_get_pmc_reg(dev, config->port); volatile uint32_t *pfc_reg = rzt2m_gpio_get_pfc_reg(dev, config->port); uint32_t ns_portnf_md_val = 0; syscon_read_reg(ns_portnf_md_dev, 0, &ns_portnf_md_val); /* level interrupts are not supported */ if (mode == GPIO_INT_MODE_LEVEL) { return -ENOTSUP; } uint8_t irq = rzt2m_gpio_get_pin_irq(dev, pin); bool irq_used_by_other = rzt2m_gpio_is_irq_used_by_other_pin(dev, pin, irq); if (irq < 0) { return -ENOTSUP; } /* secure range - currently not supported*/ if (irq >= NS_IRQ_COUNT) { return -ENOSYS; } if (mode == GPIO_INT_MODE_DISABLED) { rzt2m_gpio_unlock(); WRITE_BIT(*pmc_reg, pin, 0); /* check if selected pin is using irq line to avoid unregistering other pin irq * handler */ if (!irq_used_by_other) { rzt2m_gpio_common_data_inst.irq_registered_ports[irq].dev = NULL; } rzt2m_gpio_lock(); return 0; } /* the irq line is used by another pin */ if (irq_used_by_other) { return -EBUSY; } uint8_t md_mode = 0x0; switch (trig) { case GPIO_INT_TRIG_LOW: md_mode = INT_FALLING_EDGE; break; case GPIO_INT_TRIG_HIGH: md_mode = INT_RISING_EDGE; break; case GPIO_INT_TRIG_BOTH: md_mode = INT_BOTH_EDGE; break; default: return -EINVAL; } rzt2m_gpio_unlock(); uint32_t mdx_mask = ~((uint32_t)0b11 << irq); /* description of interrupt type has length of 2 bits */ ns_portnf_md_val = (ns_portnf_md_val & mdx_mask) | (md_mode << irq); syscon_write_reg(ns_portnf_md_dev, 0, ns_portnf_md_val); /* set interrupt type */ WRITE_BIT(*pmc_reg, pin, 1); /* enable special function on selected pin */ /* in case of every pin on every port irq function number is 0 */ *pfc_reg &= ~((uint32_t)0b1111 << pin * 4); /* register handling interrupt in isr for selected port and pin */ rzt2m_gpio_common_data_inst.irq_registered_ports[irq].dev = dev; rzt2m_gpio_common_data_inst.irq_registered_ports[irq].pin = pin; rzt2m_gpio_lock(); return 0; } static int rzt2m_gpio_manage_callback(const struct device *dev, struct gpio_callback *cb, bool set) { struct rzt2m_gpio_data *data = dev->data; return gpio_manage_callback(&data->cb, cb, set); } static const struct gpio_driver_api rzt2m_gpio_driver_api = { .pin_configure = rzt2m_gpio_configure, .port_get_raw = rzt2m_gpio_get_raw, .port_set_masked_raw = rzt2m_port_set_masked_raw, .port_set_bits_raw = rzt2m_port_set_bits_raw, .port_clear_bits_raw = rzt2m_port_clear_bits_raw, .port_toggle_bits = rzt2m_gpio_toggle, .pin_interrupt_configure = rzt2m_gpio_pin_interrupt_configure, .manage_callback = rzt2m_gpio_manage_callback}; #define RZT2M_INIT_IRQ(irq_n) \ IRQ_CONNECT(DT_IRQ_BY_IDX(DT_INST(0, renesas_rzt2m_gpio_common), irq_n, irq), \ DT_IRQ_BY_IDX(DT_INST(0, renesas_rzt2m_gpio_common), irq_n, priority), \ rzt2m_gpio_isr, &n[irq_n], \ DT_IRQ_BY_IDX(DT_INST(0, renesas_rzt2m_gpio_common), irq_n, flags)) \ irq_enable(DT_IRQ_BY_IDX(DT_INST(0, renesas_rzt2m_gpio_common), irq_n, irq)); static int rzt2m_gpio_common_init(const struct device *dev) { struct rzt2m_gpio_common_data *data = dev->data; static uint8_t n[IRQ_COUNT]; for (int i = 0; i < ARRAY_SIZE(n); i++) { n[i] = i; data->irq_registered_ports[i].dev = NULL; } FOR_EACH(RZT2M_INIT_IRQ, (), LISTIFY(NS_IRQ_COUNT, RZT2M_GPIO_VALUE_IDENTITY, (,))) return 0; } DEVICE_DT_DEFINE(DT_INST(0, renesas_rzt2m_gpio_common), rzt2m_gpio_common_init, NULL, &rzt2m_gpio_common_data_inst, NULL, PRE_KERNEL_1, CONFIG_GPIO_INIT_PRIORITY, NULL); #define VALUE_2X(i, _) UTIL_X2(i) #define PIN_IRQ_INITIALIZER(idx, inst) \ COND_CODE_1(DT_INST_PROP_HAS_IDX(inst, irqs, idx), \ ([DT_INST_PROP_BY_IDX(inst, irqs, idx)] = \ DT_INST_PROP_BY_IDX(inst, irqs, UTIL_INC(idx)) + 1,), \ ()) #define PORT_IRQS_INITIALIZER(inst) \ FOR_EACH_FIXED_ARG(PIN_IRQ_INITIALIZER, (), inst, \ LISTIFY(DT_INST_PROP_LEN_OR(inst, irqs, 0), VALUE_2X, (,))) #define RZT2M_GPIO_DEFINE(inst) \ static struct rzt2m_gpio_data rzt2m_gpio_data##inst; \ static struct rzt2m_gpio_config rzt2m_gpio_config##inst = { \ .port_nsr = (uint8_t *)DT_REG_ADDR_BY_NAME(DT_INST_GPARENT(inst), port_nsr), \ .ptadr = (uint8_t *)DT_REG_ADDR_BY_NAME(DT_INST_GPARENT(inst), ptadr), \ .port = DT_INST_REG_ADDR(inst), \ .pin_irqs = {PORT_IRQS_INITIALIZER(inst)}, \ .common = {.port_pin_mask = GPIO_PORT_PIN_MASK_FROM_DT_INST(inst)}}; \ DEVICE_DT_INST_DEFINE(inst, rzt2m_gpio_init, NULL, &rzt2m_gpio_data##inst, \ &rzt2m_gpio_config##inst, PRE_KERNEL_1, CONFIG_GPIO_INIT_PRIORITY, \ &rzt2m_gpio_driver_api); DT_INST_FOREACH_STATUS_OKAY(RZT2M_GPIO_DEFINE)