drivers/watchdog/wdt_dw.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /* SPDX-License-Identifier: Apache-2.0 */
 /*
  * Copyright (c) 2023 Intel Corporation
  *
  * Author: Adrian Warecki <adrian.warecki@intel.com>
  */

 #ifndef ZEPHYR_DRIVERS_WATCHDOG_WDT_DW_H_
 #define ZEPHYR_DRIVERS_WATCHDOG_WDT_DW_H_

 #include <zephyr/sys/util.h>

 /**
  * @file
  * @brief Synopsys Designware Watchdog driver
  *
  * The DW_apb_wdt is an APB slave peripheral that can be used to prevent system lockup that may be
  * caused by conflicting parts or programs in an SoC. This component can be configured, synthesized,
  * and programmed based on user-defined options.
  *
  * The generated interrupt is passed to an interrupt controller. The generated reset is passed to a
  * reset controller, which in turn generates a reset for the components in the system. The WDT may
  * be reset independently to the other components.
  *
  * For more information about the specific IP capability, please refer to the DesignWare DW_apb_wdt
  * Databook.
  */

 /*
  * Control Register
  */
 #define WDT_CR				0x0

 /*
  * WDT enable
  */
 #define WDT_CR_WDT_EN			BIT(0)

 /* Watchdog timer disabled
  */
 #define WDT_EN_DISABLED			0x0

 /* Watchdog timer enabled
  */
 #define WDT_EN_ENABLED			0x1

 /*
  * Response mode
  */
 #define WDT_CR_RMOD			BIT(1)

 /* Generate a system reset
  */
 #define RMOD_RESET			0x0

 /* First generate an interrupt and even if it is cleared
  * by the time a second timeout occurs then generate a system reset
  */
 #define RMOD_INTERRUPT			0x1

 /*
  * Reset pulse length
  */
 #define WDT_CR_RPL			GENMASK(4, 2)

 #define RPL_PCLK_CYCLES2		0x0 /* 2 pclk cycles */
 #define RPL_PCLK_CYCLES4		0x1 /* 4 pclk cycles */
 #define RPL_PCLK_CYCLES8		0x2 /* 8 pclk cycles */
 #define RPL_PCLK_CYCLES16		0x3 /* 16 pclk cycles */
 #define RPL_PCLK_CYCLES32		0x4 /* 32 pclk cycles */
 #define RPL_PCLK_CYCLES64		0x5 /* 64 pclk cycles */
 #define RPL_PCLK_CYCLES128		0x6 /* 128 pclk cycles */
 #define RPL_PCLK_CYCLES256		0x7 /* 256 pclk cycles */

 /*
  * Redundant R/W bit.
  */
 #define WDT_CR_NO_NAME			BIT(5)


 /*
  * Timeout Range Register
  */
 #define WDT_TORR			0x4

 #define TORR_USER0_OR_64K		0x0 /* Time out of WDT_USER_TOP_0 or 64K Clocks */
 #define TORR_USER1_OR_128K		0x1 /* Time out of WDT_USER_TOP_1 or 128K Clocks */
 #define TORR_USER2_OR_256K		0x2 /* Time out of WDT_USER_TOP_2 or 256K Clocks */
 #define TORR_USER3_OR_512K		0x3 /* Time out of WDT_USER_TOP_3 or 512K Clocks */
 #define TORR_USER4_OR_1M		0x4 /* Time out of WDT_USER_TOP_4 or 1M Clocks */
 #define TORR_USER5_OR_2M		0x5 /* Time out of WDT_USER_TOP_5 or 2M Clocks */
 #define TORR_USER6_OR_4M		0x6 /* Time out of WDT_USER_TOP_6 or 4M Clocks */
 #define TORR_USER7_OR_8M		0x7 /* Time out of WDT_USER_TOP_7 or 8M Clocks */
 #define TORR_USER8_OR_16M		0x8 /* Time out of WDT_USER_TOP_8 or 16M Clocks */
 #define TORR_USER9_OR_32M		0x9 /* Time out of WDT_USER_TOP_9 or 32M Clocks */
 #define TORR_USER10_OR_64M		0xa /* Time out of WDT_USER_TOP_10 or 64M Clocks */
 #define TORR_USER11_OR_128M		0xb /* Time out of WDT_USER_TOP_11 or 128M Clocks */
 #define TORR_USER12_OR_256M		0xc /* Time out of WDT_USER_TOP_12 or 256M Clocks */
 #define TORR_USER13_OR_512M		0xd /* Time out of WDT_USER_TOP_13 or 512M Clocks */
 #define TORR_USER14_OR_1G		0xe /* Time out of WDT_USER_TOP_14 or 1G Clocks */
 #define TORR_USER15_OR_2G		0xf /* Time out of WDT_USER_TOP_15 or 2G Clocks */

 /*
  * Timeout period
  */
 #define WDT_TORR_TOP			GENMASK(3, 0)

 /*
  * Timeout period for initialization
  */
 #define WDT_TORR_TOP_INIT		GENMASK(7, 4)


 /*
  * Current Counter Value Register.
  * bits WDT_CNT_WIDTH - 1 to 0
  */
 #define WDT_CCVR			0x8

 /*
  * Counter Restart Register
  */
 #define WDT_CRR				0xc
 #define WDT_CRR_MASK			GENMASK(7, 0)

 /*
  * Watchdog timer restart command
  */
 #define WDT_CRR_RESTART_KEY		0x76


 /*
  * Interrupt Status Register
  */
 #define WDT_STAT			0x10
 #define WDT_STAT_MASK			BIT(0)


 /*
  * Interrupt Clear Register
  */
 #define WDT_EOI				0x14
 #define WDT_EOI_MASK			BIT(0)


 /*
  * WDT Protection level register
  */
 #define WDT_PROT_LEVEL			0x1c
 #define WDT_PROT_LEVEL_MASK		GENMASK(2, 0)


 /*
  * Component Parameters Register 5
  * Upper limit of Timeout Period parameters
  */
 #define WDT_COMP_PARAM_5		0xe4
 #define CP_WDT_USER_TOP_MAX		WDT_COMP_PARAM_5


 /*
  * Component Parameters Register 4
  * Upper limit of Initial Timeout Period parameters
  */
 #define WDT_COMP_PARAM_4		0xe8
 #define CP_WDT_USER_TOP_INIT_MAX	WDT_COMP_PARAM_4

 /*
  * Component Parameters Register 3
  * The value of this register is derived from the WDT_TOP_RST core Consultant parameter.
  */
 #define WDT_COMP_PARAM_3		0xec
 #define CD_WDT_TOP_RST			WDT_COMP_PARAM_3


 /*
  * Component Parameters Register 2
  * The value of this register is derived from the WDT_CNT_RST core Consultant parameter.
  */
 #define WDT_COMP_PARAM_2		0xf0
 #define CP_WDT_CNT_RST			WDT_COMP_PARAM_2


 /*
  * Component Parameters Register 1
  */
 #define WDT_COMP_PARAM_1		0xf4

 /*
  * The Watchdog Timer counter width.
  */
 #define WDT_CNT_WIDTH			GENMASK(28, 24)

 /*
  * Describes the initial timeout period that is available directly after reset. It controls the
  * reset value of the register. If WDT_HC_TOP is 1, then the default initial time period is the
  * only possible period.
  */
 #define WDT_DFLT_TOP_INIT		GENMASK(23, 20)

 /*
  * Selects the timeout period that is available directly after reset. It controls the reset value
  * of the register. If WDT_HC_TOP is set to 1, then the default timeout period is the only possible
  * timeout period. Can choose one of 16 values.
  */
 #define WDT_DFLT_TOP			GENMASK(19, 16)

 /*
  * The reset pulse length that is available directly after reset.
  */
 #define WDT_DFLT_RPL			GENMASK(12, 10)

 /*
  * Width of the APB Data Bus to which this component is attached.
  */
 #define APB_DATA_WIDTH			GENMASK(9, 8)

 /*
  * APB data width is 8 bits
  */
 #define APB_8BITS			0x0

 /*
  * APB data width is 16 bits
  */
 #define APB_16BITS			0x1

 /*
  * APB data width is 32 bits
  */
 #define APB_32BITS			0x2

 /*
  * Configures the peripheral to have a pause enable signal (pause) on the interface that can be used
  * to freeze the watchdog counter during pause mode.
  */
 #define WDT_PAUSE			BIT(7)

 /*
  * When this parameter is set to 1, timeout period range is fixed. The range increments by the power
  * of 2 from 2^16 to 2^(WDT_CNT_WIDTH-1). When this parameter is set to 0, the user must define the
  * timeout period range (2^8 to 2^(WDT_CNT_WIDTH)-1) using the WDT_USER_TOP_(i) parameter.
  */
 #define WDT_USE_FIX_TOP			BIT(6)

 /*
  * When set to 1, the selected timeout period(s)
  */
 #define WDT_HC_TOP			BIT(5)

 /*
  * Configures the reset pulse length to be hard coded.
  */
 #define WDT_HC_RPL			BIT(4)

 /*
  * Configures the output response mode to be hard coded.
  */
 #define WDT_HC_RMOD			BIT(3)

 /*
  * When set to 1, includes a second timeout period that is used for initialization prior to the
  * first kick.
  */
 #define WDT_DUAL_TOP			BIT(2)

 /*
  * Describes the output response mode that is available directly after reset. Indicates the output
  * response the WDT gives if a zero count is reached; that is, a system reset if equals 0 and
  * an interrupt followed by a system reset, if equals 1. If WDT_HC_RMOD is 1, then default response
  * mode is the only possible output response mode.
  */
 #define WDT_DFLT_RMOD			BIT(1)

 /*
  * Configures the WDT to be enabled from reset. If this setting is 1, the WDT is always enabled and
  * a write to the WDT_EN field (bit 0) of the Watchdog Timer Control Register (WDT_CR) to disable
  * it has no effect.
  */
 #define WDT_ALWAYS_EN			BIT(0)


 /*
  * Component Version Register
  * ASCII value for each number in the version, followed by *.
  * For example, 32_30_31_2A represents the version 2.01*.
  */
 #define WDT_COMP_VERSION		0xf8


 /*
  * Component Type Register
  * Designware Component Type number = 0x44_57_01_20.
  * This assigned unique hex value is constant, and is derived from the two ASCII letters "DW"
  * followed by a 16-bit unsigned number.
  */
 #define WDT_COMP_TYPE			0xfc
 #define WDT_COMP_TYPE_VALUE		0x44570120

 /**
  * @brief Enable watchdog
  *
  * @param base Device base address.
  */
 static inline void dw_wdt_enable(const uint32_t base)
 {
 	uint32_t control = sys_read32(base + WDT_CR);

 	control |= WDT_CR_WDT_EN;
 	sys_write32(control, base + WDT_CR);
 }

 /**
  * @brief Set response mode.
  *
  * Selects whether watchdog should generate interrupt on the first timeout (true) or reset system
  * (false)
  *
  * @param base Device base address.
  * @param mode Response mode.
  *		false = Generate a system reset,
  *		true = First generate an interrupt and even if it is cleared by the time a second
  *		       timeout occurs then generate a system reset
  */
 static inline void dw_wdt_response_mode_set(const uint32_t base, const bool mode)
 {
 	uint32_t control = sys_read32(base + WDT_CR);

 	if (mode)
 		control |= WDT_CR_RMOD;
 	else
 		control &= ~WDT_CR_RMOD;

 	sys_write32(control, base + WDT_CR);
 }

 /**
  * @brief Set reset pulse length.
  *
  * @param base Device base address.
  * @param pclk_cycles Reset pulse length selector (2 to 256 pclk cycles)
  */
 static inline void dw_wdt_reset_pulse_length_set(const uint32_t base, const uint32_t pclk_cycles)
 {
 	uint32_t control = sys_read32(base + WDT_CR);

 	control &= ~WDT_CR_RPL;
 	control |= FIELD_PREP(WDT_CR_RPL, pclk_cycles);

 	sys_write32(control, base + WDT_CR);
 }

 /**
  * @brief Set timeout period.
  *
  * @param base Device base address.
  * @param timeout_period Timeout period value selector
  */
 static inline void dw_wdt_timeout_period_set(const uint32_t base, const uint32_t timeout_period)
 {
 	uint32_t timeout = sys_read32(base + WDT_TORR);

 	timeout &= ~WDT_TORR_TOP;
 	timeout |= FIELD_PREP(WDT_TORR_TOP, timeout_period);
 	sys_write32(timeout, base + WDT_TORR);
 }

 /**
  * @brief Get actual timeout period range.
  *
  * @param base Device base address.
  * @return Actual timeout period range
  */
 static inline uint32_t dw_wdt_timeout_period_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_TORR_TOP, sys_read32(base + WDT_TORR));
 }

 /**
  * @brief Timeout period for initialization.
  *
  * @param base Device base address.
  * @param timeout_period Timeout period value selector
  */
 static inline void dw_wdt_timeout_period_init_set(const uint32_t base,
 						  const uint32_t timeout_period)
 {
 	uint32_t timeout = sys_read32(base + WDT_TORR);

 	timeout &= ~WDT_TORR_TOP_INIT;
 	timeout |= FIELD_PREP(WDT_TORR_TOP_INIT, timeout_period);
 	sys_write32(timeout, base + WDT_TORR);
 }

 /**
  * @brief Get WDT Current Counter Value Register.
  *
  * @param base Device base address.
  * @param wdt_counter_width Watchdog Timer counter width
  * @return The current value of the internal counter
  */
 static inline uint32_t dw_wdt_current_counter_value_register_get(const uint32_t base,
 								 uint32_t wdt_counter_width)
 {
 	uint32_t current_counter_value = sys_read32(base + WDT_CCVR);

 	current_counter_value &= (1 << (wdt_counter_width - 1));
 	return current_counter_value;
 }

 /**
  * @brief Counter Restart
  *
  * Restart the WDT counter. A restart also clears the WDT interrupt.
  *
  * @param base Device base address.
  */
 static inline void dw_wdt_counter_restart(const uint32_t base)
 {
 	sys_write32(WDT_CRR_RESTART_KEY, base + WDT_CRR);
 }

 /**
  * @brief Get Interrupt status
  *
  * @param base Device base address.
  * @return 0x0 (INACTIVE): Interrupt is inactive,
  *	   0x1 (ACTIVE): Interrupt is active regardless of polarity
  */
 static inline uint32_t dw_wdt_interrupt_status_register_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_STAT) & 1;
 }

 /**
  * @brief Clears the watchdog interrupt.
  *
  * This can be used to clear the interrupt without restarting the watchdog counter.
  *
  * @param base Device base address.
  */
 static inline void dw_wdt_clear_interrupt(const uint32_t base)
 {
 	sys_read32(base + WDT_EOI);
 }

 /**
  * @brief Gets the upper limit of Timeout Period parameters.
  *
  * @param base Device base address.
  * @return Upper limit of Timeout Period parameters.
  */
 static inline uint32_t dw_wdt_user_top_max_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_COMP_PARAM_5);
 }

 /**
  * @brief Gets the Upper limit of Initial Timeout Period parameters.
  *
  * @param base Device base address.
  * @return Upper limit of Initial Timeout Period parameters.
  */
 static inline uint32_t dw_wdt_user_top_init_max_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_COMP_PARAM_4);
 }

 /**
  * @brief Get the default value of the timeout range that is selected after reset.
  *
  * @param base Device base address.
  * @return Default timeout range after reset
  */
 static inline uint32_t dw_wdt_timeout_period_rst_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_COMP_PARAM_3);
 }

 /**
  * @brief Get the default value of the timeout counter that is set after reset.
  *
  * @param base Device base address.
  * @return Default timeout counter value
  */
 static inline uint32_t dw_wdt_cnt_rst_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_COMP_PARAM_2);
 }

 /**
  * @brief Get the Watchdog timer counter width.
  *
  * @param base Device base address.
  * @return Width of the counter register
  */
 static inline uint32_t dw_wdt_cnt_width_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_CNT_WIDTH, sys_read32(base + WDT_COMP_PARAM_1)) + 16;
 }

 /**
  * @brief Describes the initial timeout period that is available directly after reset.
  *
  * It controls the reset value of the register. If WDT_HC_TOP is 1, then the default initial time
  * period is the only possible period.
  *
  * @param base Device base address.
  * @return Initial timeout period
  */
 static inline uint32_t dw_wdt_dflt_timeout_period_init_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_DFLT_TOP_INIT, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Get default timeout period
  *
  * Selects the timeout period that is available directly after reset. It controls the reset value
  * of the register. If WDT_HC_TOP is set to 1, then the default timeout period is the only possible
  * timeout period. Can choose one of 16 values.
  *
  * @param base Device base address.
  * @return Default timeout period
  */
 static inline uint32_t dw_wdt_dflt_timeout_period_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_DFLT_TOP, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief The reset pulse length that is available directly after reset.
  *
  * @param base Device base address.
  * @return Reset pulse length
  */
 static inline uint32_t dw_wdt_dflt_rpl_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_DFLT_RPL, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Width of the APB Data Bus to which this component is attached.
  *
  * @param base Device base address.
  * @return APB data width
  *	   0x0 (APB_8BITS): APB data width is 8 bits
  *	   0x1 (APB_16BITS): APB data width is 16 bits
  *	   0x2 (APB_32BITS): APB data width is 32 bits
  */
 static inline uint32_t dw_wdt_apb_data_width_get(const uint32_t base)
 {
 	return FIELD_GET(APB_DATA_WIDTH, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Get configuration status of a pause signal
  *
  * Check the peripheral is configured to have a pause enable signal (pause) on the interface that
  * can be used to freeze the watchdog counter during pause mode.
  *
  * @param base Device base address.
  * @return 0x0 (DISABLED): Pause enable signal is non existent
  *	   0x1 (ENABLED): Pause enable signal is included
  */
 static inline uint32_t dw_wdt_pause_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_PAUSE, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Get fixed period status
  *
  * When this parameter is set to 1, timeout period range is fixed. The range increments by the power
  * of 2 from 2^16 to 2^(WDT_CNT_WIDTH-1). When this parameter is set to 0, the user must define the
  * timeout period range (2^8 to 2^(WDT_CNT_WIDTH)-1) using the WDT_USER_TOP_(i) parameter.
  *
  * @param base Device base address.
  * @return 0x0 (USERDEFINED): User must define timeout values
  *	   0x1 (PREDEFINED): Use predefined timeout values
  */
 static inline uint32_t dw_wdt_use_fix_timeout_period_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_USE_FIX_TOP, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Checks if period is hardcoded
  *
  * When set to 1, the selected timeout period(s) is set to be hard coded.
  *
  * @param base Device base address.
  * @return 0x0 (PROGRAMMABLE): Timeout period is programmable
  *	   0x1 (HARDCODED): Timeout period is hard coded
  */
 static inline uint32_t dw_wdt_hc_timeout_period_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_HC_TOP, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Checks if reset pulse length is hardcoded.
  *
  * @param base Device base address.
  * @return 0x0 (PROGRAMMABLE): Reset pulse length is programmable
  *	   0x1 (HARDCODED): Reset pulse length is hardcoded
  */
 static inline uint32_t dw_wdt_hc_reset_pulse_length_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_HC_RPL, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Checks if the output response mode is hardcoded.
  *
  * @param base Device base address.
  * @return 0x0 (PROGRAMMABLE): Output response mode is programmable
  *	   0x1 (HARDCODED): Output response mode is hard coded
  */
 static inline uint32_t dw_wdt_hc_response_mode_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_HC_RMOD, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Checks if a second timeout period if supported.
  *
  * When set to 1, includes a second timeout period that is used for initialization prior to the
  * first kick.
  *
  * @param base Device base address.
  * @return 0x0 (DISABLED): Second timeout period is not present
  *	   0x1 (ENABLED): Second timeout period is present
  */
 static inline uint32_t dw_wdt_dual_timeout_period_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_DUAL_TOP, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Get default response mode
  *
  * Describes the output response mode that is available directly after reset. Indicates the output
  * response the WDT gives if a zero count is reached; that is, a system reset if equals 0 and an
  * interrupt followed by a system reset, if equals 1. If WDT_HC_RMOD is 1, then default response
  * mode is the only possible output response mode.
  *
  * @param base Device base address.
  * @return 0x0 (DISABLED): System reset only
  *	   0x1 (ENABLED): Interrupt and system reset
  */
 static inline uint32_t dw_wdt_dflt_response_mode_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_DFLT_RMOD, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief Checks if watchdog is enabled from reset
  *
  * If this setting is 1, the WDT is always enabled and a write to the WDT_EN field (bit 0) of the
  * Watchdog Timer Control Register (WDT_CR) to disable it has no effect.
  *
  * @param base Device base address.
  * @return 0x0 (DISABLED): Watchdog timer disabled on reset
  *	   0x1 (ENABLED): Watchdog timer enabled on reset
  */
 static inline uint32_t dw_wdt_always_en_get(const uint32_t base)
 {
 	return FIELD_GET(WDT_ALWAYS_EN, sys_read32(base + WDT_COMP_PARAM_1));
 }

 /**
  * @brief ASCII value for each number in the version
  *
  * For example, 32_30_31_2A represents the version 2.01s
  *
  * @param base Device base address.
  * @return Component version code
  */
 static inline uint32_t dw_wdt_comp_version_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_COMP_VERSION);
 }

 /**
  * @brief Get Component Type
  *
  * @param base Device base address.
  * @return Components type code
  */
 static inline uint32_t dw_wdt_comp_type_get(const uint32_t base)
 {
 	return sys_read32(base + WDT_COMP_TYPE);
 }

 #endif /* !ZEPHYR_DRIVERS_WATCHDOG_WDT_DW_H_ */
	/* SPDX-License-Identifier: Apache-2.0 */
	/*
	* Copyright (c) 2023 Intel Corporation
	*
	* Author: Adrian Warecki <adrian.warecki@intel.com>
	*/

	#ifndef ZEPHYR_DRIVERS_WATCHDOG_WDT_DW_H_
	#define ZEPHYR_DRIVERS_WATCHDOG_WDT_DW_H_

	#include <zephyr/sys/util.h>

	/**
	* @file
	* @brief Synopsys Designware Watchdog driver
	*
	* The DW_apb_wdt is an APB slave peripheral that can be used to prevent system lockup that may be
	* caused by conflicting parts or programs in an SoC. This component can be configured, synthesized,
	* and programmed based on user-defined options.
	*
	* The generated interrupt is passed to an interrupt controller. The generated reset is passed to a
	* reset controller, which in turn generates a reset for the components in the system. The WDT may
	* be reset independently to the other components.
	*
	* For more information about the specific IP capability, please refer to the DesignWare DW_apb_wdt
	* Databook.
	*/

	/*
	* Control Register
	*/
	#define WDT_CR 0x0

	/*
	* WDT enable
	*/
	#define WDT_CR_WDT_EN BIT(0)

	/* Watchdog timer disabled
	*/
	#define WDT_EN_DISABLED 0x0

	/* Watchdog timer enabled
	*/
	#define WDT_EN_ENABLED 0x1

	/*
	* Response mode
	*/
	#define WDT_CR_RMOD BIT(1)

	/* Generate a system reset
	*/
	#define RMOD_RESET 0x0

	/* First generate an interrupt and even if it is cleared
	* by the time a second timeout occurs then generate a system reset
	*/
	#define RMOD_INTERRUPT 0x1

	/*
	* Reset pulse length
	*/
	#define WDT_CR_RPL GENMASK(4, 2)

	#define RPL_PCLK_CYCLES2 0x0 /* 2 pclk cycles */
	#define RPL_PCLK_CYCLES4 0x1 /* 4 pclk cycles */
	#define RPL_PCLK_CYCLES8 0x2 /* 8 pclk cycles */
	#define RPL_PCLK_CYCLES16 0x3 /* 16 pclk cycles */
	#define RPL_PCLK_CYCLES32 0x4 /* 32 pclk cycles */
	#define RPL_PCLK_CYCLES64 0x5 /* 64 pclk cycles */
	#define RPL_PCLK_CYCLES128 0x6 /* 128 pclk cycles */
	#define RPL_PCLK_CYCLES256 0x7 /* 256 pclk cycles */

	/*
	* Redundant R/W bit.
	*/
	#define WDT_CR_NO_NAME BIT(5)


	/*
	* Timeout Range Register
	*/
	#define WDT_TORR 0x4

	#define TORR_USER0_OR_64K 0x0 /* Time out of WDT_USER_TOP_0 or 64K Clocks */
	#define TORR_USER1_OR_128K 0x1 /* Time out of WDT_USER_TOP_1 or 128K Clocks */
	#define TORR_USER2_OR_256K 0x2 /* Time out of WDT_USER_TOP_2 or 256K Clocks */
	#define TORR_USER3_OR_512K 0x3 /* Time out of WDT_USER_TOP_3 or 512K Clocks */
	#define TORR_USER4_OR_1M 0x4 /* Time out of WDT_USER_TOP_4 or 1M Clocks */
	#define TORR_USER5_OR_2M 0x5 /* Time out of WDT_USER_TOP_5 or 2M Clocks */
	#define TORR_USER6_OR_4M 0x6 /* Time out of WDT_USER_TOP_6 or 4M Clocks */
	#define TORR_USER7_OR_8M 0x7 /* Time out of WDT_USER_TOP_7 or 8M Clocks */
	#define TORR_USER8_OR_16M 0x8 /* Time out of WDT_USER_TOP_8 or 16M Clocks */
	#define TORR_USER9_OR_32M 0x9 /* Time out of WDT_USER_TOP_9 or 32M Clocks */
	#define TORR_USER10_OR_64M 0xa /* Time out of WDT_USER_TOP_10 or 64M Clocks */
	#define TORR_USER11_OR_128M 0xb /* Time out of WDT_USER_TOP_11 or 128M Clocks */
	#define TORR_USER12_OR_256M 0xc /* Time out of WDT_USER_TOP_12 or 256M Clocks */
	#define TORR_USER13_OR_512M 0xd /* Time out of WDT_USER_TOP_13 or 512M Clocks */
	#define TORR_USER14_OR_1G 0xe /* Time out of WDT_USER_TOP_14 or 1G Clocks */
	#define TORR_USER15_OR_2G 0xf /* Time out of WDT_USER_TOP_15 or 2G Clocks */

	/*
	* Timeout period
	*/
	#define WDT_TORR_TOP GENMASK(3, 0)

	/*
	* Timeout period for initialization
	*/
	#define WDT_TORR_TOP_INIT GENMASK(7, 4)


	/*
	* Current Counter Value Register.
	* bits WDT_CNT_WIDTH - 1 to 0
	*/
	#define WDT_CCVR 0x8

	/*
	* Counter Restart Register
	*/
	#define WDT_CRR 0xc
	#define WDT_CRR_MASK GENMASK(7, 0)

	/*
	* Watchdog timer restart command
	*/
	#define WDT_CRR_RESTART_KEY 0x76


	/*
	* Interrupt Status Register
	*/
	#define WDT_STAT 0x10
	#define WDT_STAT_MASK BIT(0)


	/*
	* Interrupt Clear Register
	*/
	#define WDT_EOI 0x14
	#define WDT_EOI_MASK BIT(0)


	/*
	* WDT Protection level register
	*/
	#define WDT_PROT_LEVEL 0x1c
	#define WDT_PROT_LEVEL_MASK GENMASK(2, 0)


	/*
	* Component Parameters Register 5
	* Upper limit of Timeout Period parameters
	*/
	#define WDT_COMP_PARAM_5 0xe4
	#define CP_WDT_USER_TOP_MAX WDT_COMP_PARAM_5


	/*
	* Component Parameters Register 4
	* Upper limit of Initial Timeout Period parameters
	*/
	#define WDT_COMP_PARAM_4 0xe8
	#define CP_WDT_USER_TOP_INIT_MAX WDT_COMP_PARAM_4

	/*
	* Component Parameters Register 3
	* The value of this register is derived from the WDT_TOP_RST core Consultant parameter.
	*/
	#define WDT_COMP_PARAM_3 0xec
	#define CD_WDT_TOP_RST WDT_COMP_PARAM_3


	/*
	* Component Parameters Register 2
	* The value of this register is derived from the WDT_CNT_RST core Consultant parameter.
	*/
	#define WDT_COMP_PARAM_2 0xf0
	#define CP_WDT_CNT_RST WDT_COMP_PARAM_2


	/*
	* Component Parameters Register 1
	*/
	#define WDT_COMP_PARAM_1 0xf4

	/*
	* The Watchdog Timer counter width.
	*/
	#define WDT_CNT_WIDTH GENMASK(28, 24)

	/*
	* Describes the initial timeout period that is available directly after reset. It controls the
	* reset value of the register. If WDT_HC_TOP is 1, then the default initial time period is the
	* only possible period.
	*/
	#define WDT_DFLT_TOP_INIT GENMASK(23, 20)

	/*
	* Selects the timeout period that is available directly after reset. It controls the reset value
	* of the register. If WDT_HC_TOP is set to 1, then the default timeout period is the only possible
	* timeout period. Can choose one of 16 values.
	*/
	#define WDT_DFLT_TOP GENMASK(19, 16)

	/*
	* The reset pulse length that is available directly after reset.
	*/
	#define WDT_DFLT_RPL GENMASK(12, 10)

	/*
	* Width of the APB Data Bus to which this component is attached.
	*/
	#define APB_DATA_WIDTH GENMASK(9, 8)

	/*
	* APB data width is 8 bits
	*/
	#define APB_8BITS 0x0

	/*
	* APB data width is 16 bits
	*/
	#define APB_16BITS 0x1

	/*
	* APB data width is 32 bits
	*/
	#define APB_32BITS 0x2

	/*
	* Configures the peripheral to have a pause enable signal (pause) on the interface that can be used
	* to freeze the watchdog counter during pause mode.
	*/
	#define WDT_PAUSE BIT(7)

	/*
	* When this parameter is set to 1, timeout period range is fixed. The range increments by the power
	* of 2 from 2^16 to 2^(WDT_CNT_WIDTH-1). When this parameter is set to 0, the user must define the
	* timeout period range (2^8 to 2^(WDT_CNT_WIDTH)-1) using the WDT_USER_TOP_(i) parameter.
	*/
	#define WDT_USE_FIX_TOP BIT(6)

	/*
	* When set to 1, the selected timeout period(s)
	*/
	#define WDT_HC_TOP BIT(5)

	/*
	* Configures the reset pulse length to be hard coded.
	*/
	#define WDT_HC_RPL BIT(4)

	/*
	* Configures the output response mode to be hard coded.
	*/
	#define WDT_HC_RMOD BIT(3)

	/*
	* When set to 1, includes a second timeout period that is used for initialization prior to the
	* first kick.
	*/
	#define WDT_DUAL_TOP BIT(2)

	/*
	* Describes the output response mode that is available directly after reset. Indicates the output
	* response the WDT gives if a zero count is reached; that is, a system reset if equals 0 and
	* an interrupt followed by a system reset, if equals 1. If WDT_HC_RMOD is 1, then default response
	* mode is the only possible output response mode.
	*/
	#define WDT_DFLT_RMOD BIT(1)

	/*
	* Configures the WDT to be enabled from reset. If this setting is 1, the WDT is always enabled and
	* a write to the WDT_EN field (bit 0) of the Watchdog Timer Control Register (WDT_CR) to disable
	* it has no effect.
	*/
	#define WDT_ALWAYS_EN BIT(0)


	/*
	* Component Version Register
	* ASCII value for each number in the version, followed by *.
	* For example, 32_30_31_2A represents the version 2.01*.
	*/
	#define WDT_COMP_VERSION 0xf8


	/*
	* Component Type Register
	* Designware Component Type number = 0x44_57_01_20.
	* This assigned unique hex value is constant, and is derived from the two ASCII letters "DW"
	* followed by a 16-bit unsigned number.
	*/
	#define WDT_COMP_TYPE 0xfc
	#define WDT_COMP_TYPE_VALUE 0x44570120

	/**
	* @brief Enable watchdog
	*
	* @param base Device base address.
	*/
	static inline void dw_wdt_enable(const uint32_t base)
	{
	uint32_t control = sys_read32(base + WDT_CR);

	control \|= WDT_CR_WDT_EN;
	sys_write32(control, base + WDT_CR);
	}

	/**
	* @brief Set response mode.
	*
	* Selects whether watchdog should generate interrupt on the first timeout (true) or reset system
	* (false)
	*
	* @param base Device base address.
	* @param mode Response mode.
	* false = Generate a system reset,
	* true = First generate an interrupt and even if it is cleared by the time a second
	* timeout occurs then generate a system reset
	*/
	static inline void dw_wdt_response_mode_set(const uint32_t base, const bool mode)
	{
	uint32_t control = sys_read32(base + WDT_CR);

	if (mode)
	control \|= WDT_CR_RMOD;
	else
	control &= ~WDT_CR_RMOD;

	sys_write32(control, base + WDT_CR);
	}

	/**
	* @brief Set reset pulse length.
	*
	* @param base Device base address.
	* @param pclk_cycles Reset pulse length selector (2 to 256 pclk cycles)
	*/
	static inline void dw_wdt_reset_pulse_length_set(const uint32_t base, const uint32_t pclk_cycles)
	{
	uint32_t control = sys_read32(base + WDT_CR);

	control &= ~WDT_CR_RPL;
	control \|= FIELD_PREP(WDT_CR_RPL, pclk_cycles);

	sys_write32(control, base + WDT_CR);
	}

	/**
	* @brief Set timeout period.
	*
	* @param base Device base address.
	* @param timeout_period Timeout period value selector
	*/
	static inline void dw_wdt_timeout_period_set(const uint32_t base, const uint32_t timeout_period)
	{
	uint32_t timeout = sys_read32(base + WDT_TORR);

	timeout &= ~WDT_TORR_TOP;
	timeout \|= FIELD_PREP(WDT_TORR_TOP, timeout_period);
	sys_write32(timeout, base + WDT_TORR);
	}

	/**
	* @brief Get actual timeout period range.
	*
	* @param base Device base address.
	* @return Actual timeout period range
	*/
	static inline uint32_t dw_wdt_timeout_period_get(const uint32_t base)
	{
	return FIELD_GET(WDT_TORR_TOP, sys_read32(base + WDT_TORR));
	}

	/**
	* @brief Timeout period for initialization.
	*
	* @param base Device base address.
	* @param timeout_period Timeout period value selector
	*/
	static inline void dw_wdt_timeout_period_init_set(const uint32_t base,
	const uint32_t timeout_period)
	{
	uint32_t timeout = sys_read32(base + WDT_TORR);

	timeout &= ~WDT_TORR_TOP_INIT;
	timeout \|= FIELD_PREP(WDT_TORR_TOP_INIT, timeout_period);
	sys_write32(timeout, base + WDT_TORR);
	}

	/**
	* @brief Get WDT Current Counter Value Register.
	*
	* @param base Device base address.
	* @param wdt_counter_width Watchdog Timer counter width
	* @return The current value of the internal counter
	*/
	static inline uint32_t dw_wdt_current_counter_value_register_get(const uint32_t base,
	uint32_t wdt_counter_width)
	{
	uint32_t current_counter_value = sys_read32(base + WDT_CCVR);

	current_counter_value &= (1 << (wdt_counter_width - 1));
	return current_counter_value;
	}

	/**
	* @brief Counter Restart
	*
	* Restart the WDT counter. A restart also clears the WDT interrupt.
	*
	* @param base Device base address.
	*/
	static inline void dw_wdt_counter_restart(const uint32_t base)
	{
	sys_write32(WDT_CRR_RESTART_KEY, base + WDT_CRR);
	}

	/**
	* @brief Get Interrupt status
	*
	* @param base Device base address.
	* @return 0x0 (INACTIVE): Interrupt is inactive,
	* 0x1 (ACTIVE): Interrupt is active regardless of polarity
	*/
	static inline uint32_t dw_wdt_interrupt_status_register_get(const uint32_t base)
	{
	return sys_read32(base + WDT_STAT) & 1;
	}

	/**
	* @brief Clears the watchdog interrupt.
	*
	* This can be used to clear the interrupt without restarting the watchdog counter.
	*
	* @param base Device base address.
	*/
	static inline void dw_wdt_clear_interrupt(const uint32_t base)
	{
	sys_read32(base + WDT_EOI);
	}

	/**
	* @brief Gets the upper limit of Timeout Period parameters.
	*
	* @param base Device base address.
	* @return Upper limit of Timeout Period parameters.
	*/
	static inline uint32_t dw_wdt_user_top_max_get(const uint32_t base)
	{
	return sys_read32(base + WDT_COMP_PARAM_5);
	}

	/**
	* @brief Gets the Upper limit of Initial Timeout Period parameters.
	*
	* @param base Device base address.
	* @return Upper limit of Initial Timeout Period parameters.
	*/
	static inline uint32_t dw_wdt_user_top_init_max_get(const uint32_t base)
	{
	return sys_read32(base + WDT_COMP_PARAM_4);
	}

	/**
	* @brief Get the default value of the timeout range that is selected after reset.
	*
	* @param base Device base address.
	* @return Default timeout range after reset
	*/
	static inline uint32_t dw_wdt_timeout_period_rst_get(const uint32_t base)
	{
	return sys_read32(base + WDT_COMP_PARAM_3);
	}

	/**
	* @brief Get the default value of the timeout counter that is set after reset.
	*
	* @param base Device base address.
	* @return Default timeout counter value
	*/
	static inline uint32_t dw_wdt_cnt_rst_get(const uint32_t base)
	{
	return sys_read32(base + WDT_COMP_PARAM_2);
	}

	/**
	* @brief Get the Watchdog timer counter width.
	*
	* @param base Device base address.
	* @return Width of the counter register
	*/
	static inline uint32_t dw_wdt_cnt_width_get(const uint32_t base)
	{
	return FIELD_GET(WDT_CNT_WIDTH, sys_read32(base + WDT_COMP_PARAM_1)) + 16;
	}

	/**
	* @brief Describes the initial timeout period that is available directly after reset.
	*
	* It controls the reset value of the register. If WDT_HC_TOP is 1, then the default initial time
	* period is the only possible period.
	*
	* @param base Device base address.
	* @return Initial timeout period
	*/
	static inline uint32_t dw_wdt_dflt_timeout_period_init_get(const uint32_t base)
	{
	return FIELD_GET(WDT_DFLT_TOP_INIT, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Get default timeout period
	*
	* Selects the timeout period that is available directly after reset. It controls the reset value
	* of the register. If WDT_HC_TOP is set to 1, then the default timeout period is the only possible
	* timeout period. Can choose one of 16 values.
	*
	* @param base Device base address.
	* @return Default timeout period
	*/
	static inline uint32_t dw_wdt_dflt_timeout_period_get(const uint32_t base)
	{
	return FIELD_GET(WDT_DFLT_TOP, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief The reset pulse length that is available directly after reset.
	*
	* @param base Device base address.
	* @return Reset pulse length
	*/
	static inline uint32_t dw_wdt_dflt_rpl_get(const uint32_t base)
	{
	return FIELD_GET(WDT_DFLT_RPL, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Width of the APB Data Bus to which this component is attached.
	*
	* @param base Device base address.
	* @return APB data width
	* 0x0 (APB_8BITS): APB data width is 8 bits
	* 0x1 (APB_16BITS): APB data width is 16 bits
	* 0x2 (APB_32BITS): APB data width is 32 bits
	*/
	static inline uint32_t dw_wdt_apb_data_width_get(const uint32_t base)
	{
	return FIELD_GET(APB_DATA_WIDTH, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Get configuration status of a pause signal
	*
	* Check the peripheral is configured to have a pause enable signal (pause) on the interface that
	* can be used to freeze the watchdog counter during pause mode.
	*
	* @param base Device base address.
	* @return 0x0 (DISABLED): Pause enable signal is non existent
	* 0x1 (ENABLED): Pause enable signal is included
	*/
	static inline uint32_t dw_wdt_pause_get(const uint32_t base)
	{
	return FIELD_GET(WDT_PAUSE, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Get fixed period status
	*
	* When this parameter is set to 1, timeout period range is fixed. The range increments by the power
	* of 2 from 2^16 to 2^(WDT_CNT_WIDTH-1). When this parameter is set to 0, the user must define the
	* timeout period range (2^8 to 2^(WDT_CNT_WIDTH)-1) using the WDT_USER_TOP_(i) parameter.
	*
	* @param base Device base address.
	* @return 0x0 (USERDEFINED): User must define timeout values
	* 0x1 (PREDEFINED): Use predefined timeout values
	*/
	static inline uint32_t dw_wdt_use_fix_timeout_period_get(const uint32_t base)
	{
	return FIELD_GET(WDT_USE_FIX_TOP, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Checks if period is hardcoded
	*
	* When set to 1, the selected timeout period(s) is set to be hard coded.
	*
	* @param base Device base address.
	* @return 0x0 (PROGRAMMABLE): Timeout period is programmable
	* 0x1 (HARDCODED): Timeout period is hard coded
	*/
	static inline uint32_t dw_wdt_hc_timeout_period_get(const uint32_t base)
	{
	return FIELD_GET(WDT_HC_TOP, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Checks if reset pulse length is hardcoded.
	*
	* @param base Device base address.
	* @return 0x0 (PROGRAMMABLE): Reset pulse length is programmable
	* 0x1 (HARDCODED): Reset pulse length is hardcoded
	*/
	static inline uint32_t dw_wdt_hc_reset_pulse_length_get(const uint32_t base)
	{
	return FIELD_GET(WDT_HC_RPL, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Checks if the output response mode is hardcoded.
	*
	* @param base Device base address.
	* @return 0x0 (PROGRAMMABLE): Output response mode is programmable
	* 0x1 (HARDCODED): Output response mode is hard coded
	*/
	static inline uint32_t dw_wdt_hc_response_mode_get(const uint32_t base)
	{
	return FIELD_GET(WDT_HC_RMOD, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Checks if a second timeout period if supported.
	*
	* When set to 1, includes a second timeout period that is used for initialization prior to the
	* first kick.
	*
	* @param base Device base address.
	* @return 0x0 (DISABLED): Second timeout period is not present
	* 0x1 (ENABLED): Second timeout period is present
	*/
	static inline uint32_t dw_wdt_dual_timeout_period_get(const uint32_t base)
	{
	return FIELD_GET(WDT_DUAL_TOP, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Get default response mode
	*
	* Describes the output response mode that is available directly after reset. Indicates the output
	* response the WDT gives if a zero count is reached; that is, a system reset if equals 0 and an
	* interrupt followed by a system reset, if equals 1. If WDT_HC_RMOD is 1, then default response
	* mode is the only possible output response mode.
	*
	* @param base Device base address.
	* @return 0x0 (DISABLED): System reset only
	* 0x1 (ENABLED): Interrupt and system reset
	*/
	static inline uint32_t dw_wdt_dflt_response_mode_get(const uint32_t base)
	{
	return FIELD_GET(WDT_DFLT_RMOD, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief Checks if watchdog is enabled from reset
	*
	* If this setting is 1, the WDT is always enabled and a write to the WDT_EN field (bit 0) of the
	* Watchdog Timer Control Register (WDT_CR) to disable it has no effect.
	*
	* @param base Device base address.
	* @return 0x0 (DISABLED): Watchdog timer disabled on reset
	* 0x1 (ENABLED): Watchdog timer enabled on reset
	*/
	static inline uint32_t dw_wdt_always_en_get(const uint32_t base)
	{
	return FIELD_GET(WDT_ALWAYS_EN, sys_read32(base + WDT_COMP_PARAM_1));
	}

	/**
	* @brief ASCII value for each number in the version
	*
	* For example, 32_30_31_2A represents the version 2.01s
	*
	* @param base Device base address.
	* @return Component version code
	*/
	static inline uint32_t dw_wdt_comp_version_get(const uint32_t base)
	{
	return sys_read32(base + WDT_COMP_VERSION);
	}

	/**
	* @brief Get Component Type
	*
	* @param base Device base address.
	* @return Components type code
	*/
	static inline uint32_t dw_wdt_comp_type_get(const uint32_t base)
	{
	return sys_read32(base + WDT_COMP_TYPE);
	}

	#endif /* !ZEPHYR_DRIVERS_WATCHDOG_WDT_DW_H_ */