drivers/interrupt_controller/intc_mchp_ecia_xec.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2021 Microchip Technology Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @brief Driver for External interrupt controller in Microchip XEC devices
  *
  * Driver is currently implemented to support MEC172x ECIA GIRQs
  */

 #define DT_DRV_COMPAT microchip_xec_ecia

 #include <zephyr/arch/cpu.h>
 #include <zephyr/arch/arm/aarch32/cortex_m/cmsis.h>
 #include <zephyr/device.h>
 #include <soc.h>
 #include <zephyr/sys/__assert.h>
 #include <zephyr/drivers/clock_control/mchp_xec_clock_control.h>
 #include <zephyr/drivers/interrupt_controller/intc_mchp_xec_ecia.h>
 #include <zephyr/dt-bindings/interrupt-controller/mchp-xec-ecia.h>

 /* defined at the SoC layer */
 #define MCHP_FIRST_GIRQ			MCHP_FIRST_GIRQ_NOS
 #define MCHP_LAST_GIRQ			MCHP_LAST_GIRQ_NOS
 #define MCHP_XEC_DIRECT_CAPABLE		MCHP_ECIA_DIRECT_BITMAP

 #define GIRQ_ID_TO_BITPOS(id) ((id) + 8)

 /*
  * MEC SoC's have one and only one instance of ECIA. GIRQ8 register are located
  * at the beginning of the ECIA block.
  */
 #define ECIA_XEC_REG_BASE						\
 	((struct ecia_regs *)(DT_REG_ADDR(DT_NODELABEL(ecia))))

 #define ECS_XEC_REG_BASE						\
 	((struct ecs_regs *)(DT_REG_ADDR(DT_NODELABEL(ecs))))

 #define PCR_XEC_REG_BASE						\
 	((struct pcr_regs *)(DT_REG_ADDR(DT_NODELABEL(pcr))))

 #define ECIA_XEC_PCR_REG_IDX	DT_INST_CLOCKS_CELL(0, regidx)
 #define ECIA_XEC_PCR_BITPOS	DT_INST_CLOCKS_CELL(0, bitpos)

 #define ECIA_XEC_PCR_INFO						\
 	MCHP_XEC_PCR_SCR_ENCODE(DT_INST_CLOCKS_CELL(0, regidx),		\
 				DT_INST_CLOCKS_CELL(0, bitpos))

 struct xec_girq_config {
 	uintptr_t base;
 	uint8_t girq_id;
 	uint8_t num_srcs;
 	uint8_t sources[32];
 };

 struct xec_ecia_config {
 	uintptr_t ecia_base;
 	struct mchp_xec_pcr_clk_ctrl clk_ctrl;
 	const struct device *girq_node_handles[32];
 };

 struct xec_girq_src_data {
 	mchp_xec_ecia_callback_t cb;
 	void *data;
 };

 #define DEV_ECIA_CFG(ecia_dev) \
 	((const struct xec_ecia_config *const)(ecia_dev)->config)

 #define DEV_GIRQ_CFG(girq_dev) \
 	((const struct xec_girq_config *const)(girq_dev)->config)

 #define DEV_GIRQ_DATA(girq_dev) \
 	((struct xec_girq_src_data *const)(girq_dev)->data)

 /*
  * Enable/disable specified GIRQ's aggregated output. Aggregated output is the
  * bit-wise or of all the GIRQ's result bits.
  */
 void mchp_xec_ecia_girq_aggr_en(uint8_t girq_num, uint8_t enable)
 {
 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	if (enable) {
 		regs->BLK_EN_SET = BIT(girq_num);
 	} else {
 		regs->BLK_EN_CLR = BIT(girq_num);
 	}
 }

 void mchp_xec_ecia_girq_src_clr(uint8_t girq_num, uint8_t src_bit_pos)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to clear */
 	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].SRC = BIT(src_bit_pos);
 }

 void mchp_xec_ecia_girq_src_en(uint8_t girq_num, uint8_t src_bit_pos)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to set */
 	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_SET = BIT(src_bit_pos);
 }

 void mchp_xec_ecia_girq_src_dis(uint8_t girq_num, uint8_t src_bit_pos)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to clear */
 	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_CLR = BIT(src_bit_pos);
 }

 void mchp_xec_ecia_girq_src_clr_bitmap(uint8_t girq_num, uint32_t bitmap)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to clear */
 	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].SRC = bitmap;
 }

 void mchp_xec_ecia_girq_src_en_bitmap(uint8_t girq_num, uint32_t bitmap)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to clear */
 	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_SET = bitmap;
 }

 void mchp_xec_ecia_girq_src_dis_bitmap(uint8_t girq_num, uint32_t bitmap)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to clear */
 	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_CLR = bitmap;
 }

 /*
  * Return read-only GIRQ result register. Result is bit-wise and of source
  * and enable registers.
  */
 uint32_t mchp_xec_ecia_girq_result(uint8_t girq_num)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return 0U;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	return regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].RESULT;
 }

 /* Clear NVIC pending given the external NVIC input number (zero based) */
 void mchp_xec_ecia_nvic_clr_pend(uint32_t nvic_num)
 {
 	if (nvic_num >= ((SCnSCB->ICTR + 1) * 32)) {
 		return;
 	}

 	NVIC_ClearPendingIRQ(nvic_num);
 }

 /* API taking input encoded with MCHP_XEC_ECIA(g, gb, na, nd) macro */

 void mchp_xec_ecia_info_girq_aggr_en(int ecia_info, uint8_t enable)
 {
 	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);

 	mchp_xec_ecia_girq_aggr_en(girq_num, enable);
 }

 void mchp_xec_ecia_info_girq_src_clr(int ecia_info)
 {
 	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);
 	uint8_t bitpos = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	mchp_xec_ecia_girq_src_clr(girq_num, bitpos);
 }

 void mchp_xec_ecia_info_girq_src_en(int ecia_info)
 {
 	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);
 	uint8_t bitpos = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	mchp_xec_ecia_girq_src_en(girq_num, bitpos);
 }

 void mchp_xec_ecia_info_girq_src_dis(int ecia_info)
 {
 	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);
 	uint8_t bitpos = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	mchp_xec_ecia_girq_src_dis(girq_num, bitpos);
 }

 uint32_t mchp_xec_ecia_info_girq_result(int ecia_info)
 {
 	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);

 	return mchp_xec_ecia_girq_result(girq_num);
 }

 /*
  * Clear NVIC pending status given GIRQ source information encoded by macro
  * MCHP_XEC_ECIA. For aggregated only sources the encoding sets direct NVIC
  * number equal to aggregated NVIC number.
  */
 void mchp_xec_ecia_info_nvic_clr_pend(int ecia_info)
 {
 	uint8_t nvic_num = MCHP_XEC_ECIA_NVIC_DIRECT(ecia_info);

 	mchp_xec_ecia_nvic_clr_pend(nvic_num);
 }

 /**
  * @brief enable GIRQn interrupt for specific source
  *
  * @param girq is the GIRQ number (8 - 26)
  * @param src is the interrupt source in the GIRQ (0 - 31)
  */
 int mchp_xec_ecia_enable(int girq, int src)
 {
 	if ((girq < MCHP_FIRST_GIRQ) || (girq > MCHP_LAST_GIRQ) ||
 	    (src < 0) || (src > 31)) {
 		return -EINVAL;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to set */
 	regs->GIRQ[girq - MCHP_FIRST_GIRQ].EN_SET = BIT(src);

 	return 0;
 }

 /**
  * @brief enable EXTI interrupt for specific line specified by parameter
  * encoded with MCHP_XEC_ECIA macro.
  *
  * @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
  */
 int mchp_xec_ecia_info_enable(int ecia_info)
 {
 	uint8_t girq = (uint8_t)MCHP_XEC_ECIA_GIRQ(ecia_info);
 	uint8_t src = (uint8_t)MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	return mchp_xec_ecia_enable(girq, src);
 }

 /**
  * @brief disable EXTI interrupt for specific line
  *
  * @param girq is the GIRQ number (8 - 26)
  * @param src is the interrupt source in the GIRQ (0 - 31)
  */
 int mchp_xec_ecia_disable(int girq, int src)
 {
 	if ((girq < MCHP_FIRST_GIRQ) || (girq > MCHP_LAST_GIRQ) ||
 	    (src < 0) || (src > 31)) {
 		return -EINVAL;
 	}

 	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

 	/* write 1 to clear */
 	regs->GIRQ[girq - MCHP_FIRST_GIRQ].EN_CLR = BIT(src);

 	return 0;
 }

 /**
  * @brief disable EXTI interrupt for specific line specified by parameter
  * encoded with MCHP_XEC_ECIA macro.
  *
  * @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
  */
 int mchp_xec_ecia_info_disable(int ecia_info)
 {
 	uint8_t girq = (uint8_t)MCHP_XEC_ECIA_GIRQ(ecia_info);
 	uint8_t src = (uint8_t)MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	return mchp_xec_ecia_disable(girq, src);
 }

 /* forward reference */
 static const struct device *get_girq_dev(int girq_num);

 /**
  * @brief set GIRQn interrupt source callback
  *
  * @param dev_girq is the GIRQn device handle
  * @param src is the interrupt source in the GIRQ (0 - 31)
  * @param cb user callback
  * @param data user data
  */
 int mchp_xec_ecia_set_callback_by_dev(const struct device *dev_girq, int src,
 				      mchp_xec_ecia_callback_t cb, void *data)
 {
 	if ((dev_girq == NULL) || (src < 0) || (src > 31)) {
 		return -EINVAL;
 	}

 	const struct xec_girq_config *const cfg = DEV_GIRQ_CFG(dev_girq);
 	struct xec_girq_src_data *girq_data = DEV_GIRQ_DATA(dev_girq);

 	/* source exists in this GIRQ? */
 	if (!(cfg->sources[src] & BIT(7))) {
 		return -EINVAL;
 	}

 	/* obtain the callback array index for the source */
 	int idx = (int)(cfg->sources[src] & ~BIT(7));

 	girq_data[idx].cb = cb;
 	girq_data[idx].data = data;

 	return 0;
 }

 /**
  * @brief set GIRQn interrupt source callback
  *
  * @param girq is the GIRQ number (8 - 26)
  * @param src is the interrupt source in the GIRQ (0 - 31)
  * @param cb user callback
  * @param data user data
  */
 int mchp_xec_ecia_set_callback(int girq_num, int src,
 			       mchp_xec_ecia_callback_t cb, void *data)
 {
 	const struct device *dev = get_girq_dev(girq_num);

 	return mchp_xec_ecia_set_callback_by_dev(dev, src, cb, data);
 }

 /**
  * @brief set GIRQn interrupt source callback
  *
  * @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
  * @param cb user callback
  * @param data user data
  */
 int mchp_xec_ecia_info_set_callback(int ecia_info, mchp_xec_ecia_callback_t cb,
 				    void *data)
 {
 	const struct device *dev = get_girq_dev(MCHP_XEC_ECIA_GIRQ(ecia_info));
 	uint8_t src = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	return mchp_xec_ecia_set_callback_by_dev(dev, src, cb, data);
 }

 /**
  * @brief unset GIRQn interrupt source callback by device handle
  *
  * @param dev_girq is the GIRQn device handle
  * @param src is the interrupt source in the GIRQ (0 - 31)
  */
 int mchp_ecia_unset_callback_by_dev(const struct device *dev_girq, int src)
 {
 	if ((dev_girq == NULL) || (src < 0) || (src > 31)) {
 		return -EINVAL;
 	}

 	const struct xec_girq_config *const cfg = DEV_GIRQ_CFG(dev_girq);
 	struct xec_girq_src_data *girq_data = DEV_GIRQ_DATA(dev_girq);

 	/* source exists in this GIRQ? */
 	if (!(cfg->sources[src] & BIT(7))) {
 		return -EINVAL;
 	}

 	/* obtain the callback array index for the source */
 	int idx = (int)(cfg->sources[src] & ~BIT(7));

 	girq_data[idx].cb = NULL;
 	girq_data[idx].data = NULL;

 	return 0;
 }

 /**
  * @brief unset GIRQn interrupt source callback
  *
  * @param girq is the GIRQ number (8 - 26)
  * @param src is the interrupt source in the GIRQ (0 - 31)
  */
 int mchp_ecia_unset_callback(int girq_num, int src)
 {
 	const struct device *dev = get_girq_dev(girq_num);

 	return mchp_ecia_unset_callback_by_dev(dev, src);
 }

 /**
  * @brief unset GIRQn interrupt source callback
  *
  * @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
  */
 int mchp_ecia_info_unset_callback(int ecia_info)
 {
 	const struct device *dev = get_girq_dev(MCHP_XEC_ECIA_GIRQ(ecia_info));
 	uint8_t src = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

 	return mchp_ecia_unset_callback_by_dev(dev, src);
 }


 /*
  * Create a build time flag to know if any aggregated GIRQ has been enabled.
  * We make use of DT FOREACH macro to check GIRQ node status.
  * Enabling a GIRQ node (status = "okay") implies you want it used in
  * aggregated mode. Note, GIRQ 8-12, 24-26 are aggregated only by HW design.
  * If a GIRQ node is disabled(status = "disabled") and is direct capable the
  * other driver/application may use IRQ_CONNECT, irq_enable, and the helper
  * functions in this driver to set/clear GIRQ enable bits and status.
  * Leaving a node disabled also allows another driver/application to take over
  * aggregation by managing the GIRQ itself.
  */
 #define XEC_CHK_REQ_AGGR(n) DT_NODE_HAS_STATUS(n, okay) |

 #define XEC_ECIA_REQUIRE_AGGR_ISR					\
 	(								\
 	DT_FOREACH_CHILD(DT_NODELABEL(ecia), XEC_CHK_REQ_AGGR) \
 	0)

 /* static const uint32_t xec_chk_req = (XEC_ECIA_REQUIRE_AGGR_ISR); */

 #if XEC_ECIA_REQUIRE_AGGR_ISR
 /*
  * Generic ISR for aggregated GIRQ's.
  * GIRQ source(status) bits are latched (R/W1C). The peripheral status
  * connected to the GIRQ source bit must be cleared first by the callback
  * and this routine will clear the GIRQ source bit. If a callback was not
  * registered for a source the enable will also be cleared to prevent
  * interrupt storms.
  * NOTE: dev_girq is a pointer to a GIRQ child device instance.
  */
 static void xec_girq_isr(const struct device *dev_girq)
 {
 	const struct xec_girq_config *const cfg = DEV_GIRQ_CFG(dev_girq);
 	struct xec_girq_src_data *data = DEV_GIRQ_DATA(dev_girq);
 	struct girq_regs *girq = (struct girq_regs *)cfg->base;
 	int girq_id = GIRQ_ID_TO_BITPOS(cfg->girq_id);
 	uint32_t idx = 0;
 	uint32_t result = girq->RESULT;

 	for (int i = 0; result && i < 32; i++) {
 		uint8_t bitpos = 31 - (__builtin_clz(result) & 0x1f);

 		/* is it an implemented source? */
 		if (cfg->sources[bitpos] & BIT(7)) {
 			/* yes, get the index by removing bit[7] flag */
 			idx = (uint32_t)cfg->sources[bitpos] & ~BIT(7);
 			/* callback registered? */
 			if (data[idx].cb) {
 				data[idx].cb(girq_id, bitpos, data[idx].data);
 			} else { /* no callback, clear the enable */
 				girq->EN_CLR = BIT(bitpos);
 			}
 		} else { /* paranoia, we should not get here... */
 			girq->EN_CLR = BIT(bitpos);
 		}

 		/* clear GIRQ latched status */
 		girq->SRC = BIT(bitpos);
 		result &= ~BIT(bitpos);
 	}
 }
 #endif

 /**
  * @brief initialize XEC ECIA driver
  * NOTE: GIRQ22 is special used for waking the PLL from deep sleep when a
  * peripheral receives data from an external entity (eSPI, I2C, etc). Once
  * the data transfer is complete the system re-enters deep sleep unless the
  * peripheral was configured to wake CPU after reception of data or event.
  * GIRQ22 aggregated output and sources are not connected to the NVIC.
  * We enable GIRQ22 aggregated output to ensure clock asynchronous wake
  * functionality is operational.
  */
 static int xec_ecia_init(const struct device *dev)
 {
 	const struct xec_ecia_config *cfg =
 		(const struct xec_ecia_config *const) (dev->config);
 	const struct device *const clk_dev = DEVICE_DT_GET(DT_NODELABEL(pcr));
 	struct ecs_regs *const ecs = ECS_XEC_REG_BASE;
 	struct ecia_regs *const ecia = (struct ecia_regs *)cfg->ecia_base;
 	uint32_t n = 0, nr = 0;
 	int ret;

 	ret = clock_control_on(clk_dev,
 			       (clock_control_subsys_t *)&cfg->clk_ctrl);
 	if (ret < 0) {
 		return ret;
 	}

 	/* Enable all direct NVIC connections */
 	ecs->INTR_CTRL |= BIT(0);

 	/* gate off all aggregated outputs */
 	ecia->BLK_EN_CLR = UINT32_MAX;

 	/* connect aggregated only GIRQs to NVIC */
 	ecia->BLK_EN_SET = MCHP_ECIA_AGGR_BITMAP;

 	/* Clear all GIRQn source enables */
 	for (n = 0; n < MCHP_GIRQS; n++) {
 		ecia->GIRQ[n].EN_CLR = UINT32_MAX;
 	}

 	/* Clear all external NVIC enables and pending status */
 	nr = SCnSCB->ICTR;
 	for (n = 0u; n <= nr; n++) {
 		NVIC->ICER[n] = UINT32_MAX;
 		NVIC->ICPR[n] = UINT32_MAX;
 	}

 	/* ecia->BLK_ACTIVE = xec_chk_req; */

 	return 0;
 }

 /* xec_config_girq_xxx.sources[] entries from GIRQ node */
 #define XEC_GIRQ_SOURCES2(node_id, prop, idx)				\
 	.sources[DT_PROP_BY_IDX(node_id, prop, idx)] =			\
 		((uint8_t)(idx) | BIT(7)),

 /* Parameter n is a child node-id */
 #define GIRQ_XEC_DEVICE(n)						\
 	static int xec_girq_init_##n(const struct device *dev);		\
 									\
 	static struct xec_girq_src_data					\
 		xec_data_girq_##n[DT_PROP_LEN(n, sources)];		\
 									\
 	static const struct xec_girq_config xec_config_girq_##n = {	\
 		.base = DT_REG_ADDR(n),					\
 		.girq_id = DT_PROP(n, girq_id),				\
 		.num_srcs = DT_PROP_LEN(n, sources),			\
 		DT_FOREACH_PROP_ELEM(n, sources, XEC_GIRQ_SOURCES2)	\
 	};								\
 									\
 	DEVICE_DT_DEFINE(n, xec_girq_init_##n,				\
 		 NULL, &xec_data_girq_##n, &xec_config_girq_##n,	\
 		 PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY,		\
 		 NULL);							\
 									\
 	static int xec_girq_init_##n(const struct device *dev)		\
 	{								\
 		mchp_xec_ecia_girq_aggr_en(				\
 			GIRQ_ID_TO_BITPOS(DT_PROP(n, girq_id)), 1);	\
 									\
 		IRQ_CONNECT(DT_IRQN(n),					\
 			    DT_IRQ(n, priority),			\
 			    xec_girq_isr,				\
 			    DEVICE_DT_GET(n), 0);			\
 									\
 		irq_enable(DT_IRQN(n));					\
 									\
 		return 0;						\
 	}

 /*
  * iterate over each enabled child node of ECIA
  * Enable means property status = "okay"
  */
 DT_FOREACH_CHILD_STATUS_OKAY(DT_NODELABEL(ecia), GIRQ_XEC_DEVICE)

 /* n = GIRQ node id */
 #define XEC_GIRQ_HANDLE(n)					\
 	.girq_node_handles[DT_PROP(n, girq_id)] = (DEVICE_DT_GET(n)),

 static const struct xec_ecia_config xec_config_ecia = {
 	.ecia_base = DT_REG_ADDR(DT_NODELABEL(ecia)),
 	.clk_ctrl = {
 		.pcr_info = ECIA_XEC_PCR_INFO,
 	},
 	DT_FOREACH_CHILD_STATUS_OKAY(DT_NODELABEL(ecia), XEC_GIRQ_HANDLE)
 };

 DEVICE_DT_DEFINE(DT_NODELABEL(ecia), xec_ecia_init,
 		 NULL, NULL, &xec_config_ecia,
 		 PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY,
 		 NULL);

 /* look up GIRQ node handle from ECIA configuration */
 static const struct device *get_girq_dev(int girq_num)
 {
 	if ((girq_num < MCHP_FIRST_GIRQ) || (girq_num > MCHP_LAST_GIRQ)) {
 		return NULL;
 	}

 	/* safe to convert to zero based index */
 	girq_num -= MCHP_FIRST_GIRQ;

 	return xec_config_ecia.girq_node_handles[girq_num];
 }
	/*
	* Copyright (c) 2021 Microchip Technology Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @brief Driver for External interrupt controller in Microchip XEC devices
	*
	* Driver is currently implemented to support MEC172x ECIA GIRQs
	*/

	#define DT_DRV_COMPAT microchip_xec_ecia

	#include <zephyr/arch/cpu.h>
	#include <zephyr/arch/arm/aarch32/cortex_m/cmsis.h>
	#include <zephyr/device.h>
	#include <soc.h>
	#include <zephyr/sys/__assert.h>
	#include <zephyr/drivers/clock_control/mchp_xec_clock_control.h>
	#include <zephyr/drivers/interrupt_controller/intc_mchp_xec_ecia.h>
	#include <zephyr/dt-bindings/interrupt-controller/mchp-xec-ecia.h>

	/* defined at the SoC layer */
	#define MCHP_FIRST_GIRQ MCHP_FIRST_GIRQ_NOS
	#define MCHP_LAST_GIRQ MCHP_LAST_GIRQ_NOS
	#define MCHP_XEC_DIRECT_CAPABLE MCHP_ECIA_DIRECT_BITMAP

	#define GIRQ_ID_TO_BITPOS(id) ((id) + 8)

	/*
	* MEC SoC's have one and only one instance of ECIA. GIRQ8 register are located
	* at the beginning of the ECIA block.
	*/
	#define ECIA_XEC_REG_BASE \
	((struct ecia_regs *)(DT_REG_ADDR(DT_NODELABEL(ecia))))

	#define ECS_XEC_REG_BASE \
	((struct ecs_regs *)(DT_REG_ADDR(DT_NODELABEL(ecs))))

	#define PCR_XEC_REG_BASE \
	((struct pcr_regs *)(DT_REG_ADDR(DT_NODELABEL(pcr))))

	#define ECIA_XEC_PCR_REG_IDX DT_INST_CLOCKS_CELL(0, regidx)
	#define ECIA_XEC_PCR_BITPOS DT_INST_CLOCKS_CELL(0, bitpos)

	#define ECIA_XEC_PCR_INFO \
	MCHP_XEC_PCR_SCR_ENCODE(DT_INST_CLOCKS_CELL(0, regidx), \
	DT_INST_CLOCKS_CELL(0, bitpos))

	struct xec_girq_config {
	uintptr_t base;
	uint8_t girq_id;
	uint8_t num_srcs;
	uint8_t sources[32];
	};

	struct xec_ecia_config {
	uintptr_t ecia_base;
	struct mchp_xec_pcr_clk_ctrl clk_ctrl;
	const struct device *girq_node_handles[32];
	};

	struct xec_girq_src_data {
	mchp_xec_ecia_callback_t cb;
	void *data;
	};

	#define DEV_ECIA_CFG(ecia_dev) \
	((const struct xec_ecia_config *const)(ecia_dev)->config)

	#define DEV_GIRQ_CFG(girq_dev) \
	((const struct xec_girq_config *const)(girq_dev)->config)

	#define DEV_GIRQ_DATA(girq_dev) \
	((struct xec_girq_src_data *const)(girq_dev)->data)

	/*
	* Enable/disable specified GIRQ's aggregated output. Aggregated output is the
	* bit-wise or of all the GIRQ's result bits.
	*/
	void mchp_xec_ecia_girq_aggr_en(uint8_t girq_num, uint8_t enable)
	{
	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	if (enable) {
	regs->BLK_EN_SET = BIT(girq_num);
	} else {
	regs->BLK_EN_CLR = BIT(girq_num);
	}
	}

	void mchp_xec_ecia_girq_src_clr(uint8_t girq_num, uint8_t src_bit_pos)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to clear */
	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].SRC = BIT(src_bit_pos);
	}

	void mchp_xec_ecia_girq_src_en(uint8_t girq_num, uint8_t src_bit_pos)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to set */
	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_SET = BIT(src_bit_pos);
	}

	void mchp_xec_ecia_girq_src_dis(uint8_t girq_num, uint8_t src_bit_pos)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to clear */
	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_CLR = BIT(src_bit_pos);
	}

	void mchp_xec_ecia_girq_src_clr_bitmap(uint8_t girq_num, uint32_t bitmap)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to clear */
	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].SRC = bitmap;
	}

	void mchp_xec_ecia_girq_src_en_bitmap(uint8_t girq_num, uint32_t bitmap)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to clear */
	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_SET = bitmap;
	}

	void mchp_xec_ecia_girq_src_dis_bitmap(uint8_t girq_num, uint32_t bitmap)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to clear */
	regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].EN_CLR = bitmap;
	}

	/*
	* Return read-only GIRQ result register. Result is bit-wise and of source
	* and enable registers.
	*/
	uint32_t mchp_xec_ecia_girq_result(uint8_t girq_num)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return 0U;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	return regs->GIRQ[girq_num - MCHP_FIRST_GIRQ].RESULT;
	}

	/* Clear NVIC pending given the external NVIC input number (zero based) */
	void mchp_xec_ecia_nvic_clr_pend(uint32_t nvic_num)
	{
	if (nvic_num >= ((SCnSCB->ICTR + 1) * 32)) {
	return;
	}

	NVIC_ClearPendingIRQ(nvic_num);
	}

	/* API taking input encoded with MCHP_XEC_ECIA(g, gb, na, nd) macro */

	void mchp_xec_ecia_info_girq_aggr_en(int ecia_info, uint8_t enable)
	{
	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);

	mchp_xec_ecia_girq_aggr_en(girq_num, enable);
	}

	void mchp_xec_ecia_info_girq_src_clr(int ecia_info)
	{
	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);
	uint8_t bitpos = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	mchp_xec_ecia_girq_src_clr(girq_num, bitpos);
	}

	void mchp_xec_ecia_info_girq_src_en(int ecia_info)
	{
	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);
	uint8_t bitpos = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	mchp_xec_ecia_girq_src_en(girq_num, bitpos);
	}

	void mchp_xec_ecia_info_girq_src_dis(int ecia_info)
	{
	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);
	uint8_t bitpos = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	mchp_xec_ecia_girq_src_dis(girq_num, bitpos);
	}

	uint32_t mchp_xec_ecia_info_girq_result(int ecia_info)
	{
	uint8_t girq_num = MCHP_XEC_ECIA_GIRQ(ecia_info);

	return mchp_xec_ecia_girq_result(girq_num);
	}

	/*
	* Clear NVIC pending status given GIRQ source information encoded by macro
	* MCHP_XEC_ECIA. For aggregated only sources the encoding sets direct NVIC
	* number equal to aggregated NVIC number.
	*/
	void mchp_xec_ecia_info_nvic_clr_pend(int ecia_info)
	{
	uint8_t nvic_num = MCHP_XEC_ECIA_NVIC_DIRECT(ecia_info);

	mchp_xec_ecia_nvic_clr_pend(nvic_num);
	}

	/**
	* @brief enable GIRQn interrupt for specific source
	*
	* @param girq is the GIRQ number (8 - 26)
	* @param src is the interrupt source in the GIRQ (0 - 31)
	*/
	int mchp_xec_ecia_enable(int girq, int src)
	{
	if ((girq < MCHP_FIRST_GIRQ) \|\| (girq > MCHP_LAST_GIRQ) \|\|
	(src < 0) \|\| (src > 31)) {
	return -EINVAL;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to set */
	regs->GIRQ[girq - MCHP_FIRST_GIRQ].EN_SET = BIT(src);

	return 0;
	}

	/**
	* @brief enable EXTI interrupt for specific line specified by parameter
	* encoded with MCHP_XEC_ECIA macro.
	*
	* @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
	*/
	int mchp_xec_ecia_info_enable(int ecia_info)
	{
	uint8_t girq = (uint8_t)MCHP_XEC_ECIA_GIRQ(ecia_info);
	uint8_t src = (uint8_t)MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	return mchp_xec_ecia_enable(girq, src);
	}

	/**
	* @brief disable EXTI interrupt for specific line
	*
	* @param girq is the GIRQ number (8 - 26)
	* @param src is the interrupt source in the GIRQ (0 - 31)
	*/
	int mchp_xec_ecia_disable(int girq, int src)
	{
	if ((girq < MCHP_FIRST_GIRQ) \|\| (girq > MCHP_LAST_GIRQ) \|\|
	(src < 0) \|\| (src > 31)) {
	return -EINVAL;
	}

	struct ecia_regs *regs = ECIA_XEC_REG_BASE;

	/* write 1 to clear */
	regs->GIRQ[girq - MCHP_FIRST_GIRQ].EN_CLR = BIT(src);

	return 0;
	}

	/**
	* @brief disable EXTI interrupt for specific line specified by parameter
	* encoded with MCHP_XEC_ECIA macro.
	*
	* @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
	*/
	int mchp_xec_ecia_info_disable(int ecia_info)
	{
	uint8_t girq = (uint8_t)MCHP_XEC_ECIA_GIRQ(ecia_info);
	uint8_t src = (uint8_t)MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	return mchp_xec_ecia_disable(girq, src);
	}

	/* forward reference */
	static const struct device *get_girq_dev(int girq_num);

	/**
	* @brief set GIRQn interrupt source callback
	*
	* @param dev_girq is the GIRQn device handle
	* @param src is the interrupt source in the GIRQ (0 - 31)
	* @param cb user callback
	* @param data user data
	*/
	int mchp_xec_ecia_set_callback_by_dev(const struct device *dev_girq, int src,
	mchp_xec_ecia_callback_t cb, void *data)
	{
	if ((dev_girq == NULL) \|\| (src < 0) \|\| (src > 31)) {
	return -EINVAL;
	}

	const struct xec_girq_config *const cfg = DEV_GIRQ_CFG(dev_girq);
	struct xec_girq_src_data *girq_data = DEV_GIRQ_DATA(dev_girq);

	/* source exists in this GIRQ? */
	if (!(cfg->sources[src] & BIT(7))) {
	return -EINVAL;
	}

	/* obtain the callback array index for the source */
	int idx = (int)(cfg->sources[src] & ~BIT(7));

	girq_data[idx].cb = cb;
	girq_data[idx].data = data;

	return 0;
	}

	/**
	* @brief set GIRQn interrupt source callback
	*
	* @param girq is the GIRQ number (8 - 26)
	* @param src is the interrupt source in the GIRQ (0 - 31)
	* @param cb user callback
	* @param data user data
	*/
	int mchp_xec_ecia_set_callback(int girq_num, int src,
	mchp_xec_ecia_callback_t cb, void *data)
	{
	const struct device *dev = get_girq_dev(girq_num);

	return mchp_xec_ecia_set_callback_by_dev(dev, src, cb, data);
	}

	/**
	* @brief set GIRQn interrupt source callback
	*
	* @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
	* @param cb user callback
	* @param data user data
	*/
	int mchp_xec_ecia_info_set_callback(int ecia_info, mchp_xec_ecia_callback_t cb,
	void *data)
	{
	const struct device *dev = get_girq_dev(MCHP_XEC_ECIA_GIRQ(ecia_info));
	uint8_t src = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	return mchp_xec_ecia_set_callback_by_dev(dev, src, cb, data);
	}

	/**
	* @brief unset GIRQn interrupt source callback by device handle
	*
	* @param dev_girq is the GIRQn device handle
	* @param src is the interrupt source in the GIRQ (0 - 31)
	*/
	int mchp_ecia_unset_callback_by_dev(const struct device *dev_girq, int src)
	{
	if ((dev_girq == NULL) \|\| (src < 0) \|\| (src > 31)) {
	return -EINVAL;
	}

	const struct xec_girq_config *const cfg = DEV_GIRQ_CFG(dev_girq);
	struct xec_girq_src_data *girq_data = DEV_GIRQ_DATA(dev_girq);

	/* source exists in this GIRQ? */
	if (!(cfg->sources[src] & BIT(7))) {
	return -EINVAL;
	}

	/* obtain the callback array index for the source */
	int idx = (int)(cfg->sources[src] & ~BIT(7));

	girq_data[idx].cb = NULL;
	girq_data[idx].data = NULL;

	return 0;
	}

	/**
	* @brief unset GIRQn interrupt source callback
	*
	* @param girq is the GIRQ number (8 - 26)
	* @param src is the interrupt source in the GIRQ (0 - 31)
	*/
	int mchp_ecia_unset_callback(int girq_num, int src)
	{
	const struct device *dev = get_girq_dev(girq_num);

	return mchp_ecia_unset_callback_by_dev(dev, src);
	}

	/**
	* @brief unset GIRQn interrupt source callback
	*
	* @param ecia_info is GIRQ connection encoded with MCHP_XEC_ECIA
	*/
	int mchp_ecia_info_unset_callback(int ecia_info)
	{
	const struct device *dev = get_girq_dev(MCHP_XEC_ECIA_GIRQ(ecia_info));
	uint8_t src = MCHP_XEC_ECIA_GIRQ_POS(ecia_info);

	return mchp_ecia_unset_callback_by_dev(dev, src);
	}


	/*
	* Create a build time flag to know if any aggregated GIRQ has been enabled.
	* We make use of DT FOREACH macro to check GIRQ node status.
	* Enabling a GIRQ node (status = "okay") implies you want it used in
	* aggregated mode. Note, GIRQ 8-12, 24-26 are aggregated only by HW design.
	* If a GIRQ node is disabled(status = "disabled") and is direct capable the
	* other driver/application may use IRQ_CONNECT, irq_enable, and the helper
	* functions in this driver to set/clear GIRQ enable bits and status.
	* Leaving a node disabled also allows another driver/application to take over
	* aggregation by managing the GIRQ itself.
	*/
	#define XEC_CHK_REQ_AGGR(n) DT_NODE_HAS_STATUS(n, okay) \|

	#define XEC_ECIA_REQUIRE_AGGR_ISR \
	( \
	DT_FOREACH_CHILD(DT_NODELABEL(ecia), XEC_CHK_REQ_AGGR) \
	0)

	/* static const uint32_t xec_chk_req = (XEC_ECIA_REQUIRE_AGGR_ISR); */

	#if XEC_ECIA_REQUIRE_AGGR_ISR
	/*
	* Generic ISR for aggregated GIRQ's.
	* GIRQ source(status) bits are latched (R/W1C). The peripheral status
	* connected to the GIRQ source bit must be cleared first by the callback
	* and this routine will clear the GIRQ source bit. If a callback was not
	* registered for a source the enable will also be cleared to prevent
	* interrupt storms.
	* NOTE: dev_girq is a pointer to a GIRQ child device instance.
	*/
	static void xec_girq_isr(const struct device *dev_girq)
	{
	const struct xec_girq_config *const cfg = DEV_GIRQ_CFG(dev_girq);
	struct xec_girq_src_data *data = DEV_GIRQ_DATA(dev_girq);
	struct girq_regs girq = (struct girq_regs )cfg->base;
	int girq_id = GIRQ_ID_TO_BITPOS(cfg->girq_id);
	uint32_t idx = 0;
	uint32_t result = girq->RESULT;

	for (int i = 0; result && i < 32; i++) {
	uint8_t bitpos = 31 - (__builtin_clz(result) & 0x1f);

	/* is it an implemented source? */
	if (cfg->sources[bitpos] & BIT(7)) {
	/* yes, get the index by removing bit[7] flag */
	idx = (uint32_t)cfg->sources[bitpos] & ~BIT(7);
	/* callback registered? */
	if (data[idx].cb) {
	data[idx].cb(girq_id, bitpos, data[idx].data);
	} else { /* no callback, clear the enable */
	girq->EN_CLR = BIT(bitpos);
	}
	} else { /* paranoia, we should not get here... */
	girq->EN_CLR = BIT(bitpos);
	}

	/* clear GIRQ latched status */
	girq->SRC = BIT(bitpos);
	result &= ~BIT(bitpos);
	}
	}
	#endif

	/**
	* @brief initialize XEC ECIA driver
	* NOTE: GIRQ22 is special used for waking the PLL from deep sleep when a
	* peripheral receives data from an external entity (eSPI, I2C, etc). Once
	* the data transfer is complete the system re-enters deep sleep unless the
	* peripheral was configured to wake CPU after reception of data or event.
	* GIRQ22 aggregated output and sources are not connected to the NVIC.
	* We enable GIRQ22 aggregated output to ensure clock asynchronous wake
	* functionality is operational.
	*/
	static int xec_ecia_init(const struct device *dev)
	{
	const struct xec_ecia_config *cfg =
	(const struct xec_ecia_config *const) (dev->config);
	const struct device *const clk_dev = DEVICE_DT_GET(DT_NODELABEL(pcr));
	struct ecs_regs *const ecs = ECS_XEC_REG_BASE;
	struct ecia_regs const ecia = (struct ecia_regs )cfg->ecia_base;
	uint32_t n = 0, nr = 0;
	int ret;

	ret = clock_control_on(clk_dev,
	(clock_control_subsys_t *)&cfg->clk_ctrl);
	if (ret < 0) {
	return ret;
	}

	/* Enable all direct NVIC connections */
	ecs->INTR_CTRL \|= BIT(0);

	/* gate off all aggregated outputs */
	ecia->BLK_EN_CLR = UINT32_MAX;

	/* connect aggregated only GIRQs to NVIC */
	ecia->BLK_EN_SET = MCHP_ECIA_AGGR_BITMAP;

	/* Clear all GIRQn source enables */
	for (n = 0; n < MCHP_GIRQS; n++) {
	ecia->GIRQ[n].EN_CLR = UINT32_MAX;
	}

	/* Clear all external NVIC enables and pending status */
	nr = SCnSCB->ICTR;
	for (n = 0u; n <= nr; n++) {
	NVIC->ICER[n] = UINT32_MAX;
	NVIC->ICPR[n] = UINT32_MAX;
	}

	/* ecia->BLK_ACTIVE = xec_chk_req; */

	return 0;
	}

	/* xec_config_girq_xxx.sources[] entries from GIRQ node */
	#define XEC_GIRQ_SOURCES2(node_id, prop, idx) \
	.sources[DT_PROP_BY_IDX(node_id, prop, idx)] = \
	((uint8_t)(idx) \| BIT(7)),

	/* Parameter n is a child node-id */
	#define GIRQ_XEC_DEVICE(n) \
	static int xec_girq_init_##n(const struct device *dev); \
	\
	static struct xec_girq_src_data \
	xec_data_girq_##n[DT_PROP_LEN(n, sources)]; \
	\
	static const struct xec_girq_config xec_config_girq_##n = { \
	.base = DT_REG_ADDR(n), \
	.girq_id = DT_PROP(n, girq_id), \
	.num_srcs = DT_PROP_LEN(n, sources), \
	DT_FOREACH_PROP_ELEM(n, sources, XEC_GIRQ_SOURCES2) \
	}; \
	\
	DEVICE_DT_DEFINE(n, xec_girq_init_##n, \
	NULL, &xec_data_girq_##n, &xec_config_girq_##n, \
	PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY, \
	NULL); \
	\
	static int xec_girq_init_##n(const struct device *dev) \
	{ \
	mchp_xec_ecia_girq_aggr_en( \
	GIRQ_ID_TO_BITPOS(DT_PROP(n, girq_id)), 1); \
	\
	IRQ_CONNECT(DT_IRQN(n), \
	DT_IRQ(n, priority), \
	xec_girq_isr, \
	DEVICE_DT_GET(n), 0); \
	\
	irq_enable(DT_IRQN(n)); \
	\
	return 0; \
	}

	/*
	* iterate over each enabled child node of ECIA
	* Enable means property status = "okay"
	*/
	DT_FOREACH_CHILD_STATUS_OKAY(DT_NODELABEL(ecia), GIRQ_XEC_DEVICE)

	/* n = GIRQ node id */
	#define XEC_GIRQ_HANDLE(n) \
	.girq_node_handles[DT_PROP(n, girq_id)] = (DEVICE_DT_GET(n)),

	static const struct xec_ecia_config xec_config_ecia = {
	.ecia_base = DT_REG_ADDR(DT_NODELABEL(ecia)),
	.clk_ctrl = {
	.pcr_info = ECIA_XEC_PCR_INFO,
	},
	DT_FOREACH_CHILD_STATUS_OKAY(DT_NODELABEL(ecia), XEC_GIRQ_HANDLE)
	};

	DEVICE_DT_DEFINE(DT_NODELABEL(ecia), xec_ecia_init,
	NULL, NULL, &xec_config_ecia,
	PRE_KERNEL_1, CONFIG_INTC_INIT_PRIORITY,
	NULL);

	/* look up GIRQ node handle from ECIA configuration */
	static const struct device *get_girq_dev(int girq_num)
	{
	if ((girq_num < MCHP_FIRST_GIRQ) \|\| (girq_num > MCHP_LAST_GIRQ)) {
	return NULL;
	}

	/* safe to convert to zero based index */
	girq_num -= MCHP_FIRST_GIRQ;

	return xec_config_ecia.girq_node_handles[girq_num];
	}