include/DAP_config.h - third_party/github/raspberrypi/debugprobe - Git at Google

 /*
  * Copyright (c) 2013-2021 ARM Limited. All rights reserved.
  *
  * SPDX-License-Identifier: Apache-2.0
  *
  * Licensed under the Apache License, Version 2.0 (the License); you may
  * not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  * www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an AS IS BASIS, WITHOUT
  * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  * ----------------------------------------------------------------------
  *
  * $Date:        16. June 2021
  * $Revision:    V2.1.0
  *
  * Project:      CMSIS-DAP Configuration
  * Title:        DAP_config.h CMSIS-DAP Configuration File (Template)
  *
  *---------------------------------------------------------------------------*/

 #ifndef __DAP_CONFIG_H__
 #define __DAP_CONFIG_H__


 //**************************************************************************************************
 /**
 \defgroup DAP_Config_Debug_gr CMSIS-DAP Debug Unit Information
 \ingroup DAP_ConfigIO_gr
 @{
 Provides definitions about the hardware and configuration of the Debug Unit.

 This information includes:
  - Definition of Cortex-M processor parameters used in CMSIS-DAP Debug Unit.
  - Debug Unit Identification strings (Vendor, Product, Serial Number).
  - Debug Unit communication packet size.
  - Debug Access Port supported modes and settings (JTAG/SWD and SWO).
  - Optional information about a connected Target Device (for Evaluation Boards).
 */
 #include <pico/stdlib.h>
 #include <hardware/clocks.h>
 #include <hardware/gpio.h>

 #include "cmsis_compiler.h"
 #include "probe_config.h"
 #include "probe.h"

 /// Processor Clock of the Cortex-M MCU used in the Debug Unit.
 /// This value is used to calculate the SWD/JTAG clock speed.
 /* Debugprobe uses PIO for clock generation, so return the current system clock. */
 #define CPU_CLOCK               clock_get_hz(clk_sys)

 /// Number of processor cycles for I/O Port write operations.
 /// This value is used to calculate the SWD/JTAG clock speed that is generated with I/O
 /// Port write operations in the Debug Unit by a Cortex-M MCU. Most Cortex-M processors
 /// require 2 processor cycles for a I/O Port Write operation.  If the Debug Unit uses
 /// a Cortex-M0+ processor with high-speed peripheral I/O only 1 processor cycle might be
 /// required.
 #define IO_PORT_WRITE_CYCLES    1U              ///< I/O Cycles: 2=default, 1=Cortex-M0+ fast I/0.
 #define DELAY_SLOW_CYCLES 1U // We don't differentiate between fast/slow, we've got a 16-bit divisor for that

 /// Indicate that Serial Wire Debug (SWD) communication mode is available at the Debug Access Port.
 /// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
 #define DAP_SWD                 1               ///< SWD Mode:  1 = available, 0 = not available.

 /// Indicate that JTAG communication mode is available at the Debug Port.
 /// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
 #define DAP_JTAG                0               ///< JTAG Mode: 1 = available, 0 = not available.

 /// Configure maximum number of JTAG devices on the scan chain connected to the Debug Access Port.
 /// This setting impacts the RAM requirements of the Debug Unit. Valid range is 1 .. 255.
 #define DAP_JTAG_DEV_CNT        8U              ///< Maximum number of JTAG devices on scan chain.

 /// Default communication mode on the Debug Access Port.
 /// Used for the command \ref DAP_Connect when Port Default mode is selected.
 #define DAP_DEFAULT_PORT        1U              ///< Default JTAG/SWJ Port Mode: 1 = SWD, 2 = JTAG.

 /// Default communication speed on the Debug Access Port for SWD and JTAG mode.
 /// Used to initialize the default SWD/JTAG clock frequency.
 /// The command \ref DAP_SWJ_Clock can be used to overwrite this default setting.
 #define DAP_DEFAULT_SWJ_CLOCK   1000000U        ///< Default SWD/JTAG clock frequency in Hz.

 /// Maximum Package Size for Command and Response data.
 /// This configuration settings is used to optimize the communication performance with the
 /// debugger and depends on the USB peripheral. Typical vales are 64 for Full-speed USB HID or WinUSB,
 /// 1024 for High-speed USB HID and 512 for High-speed USB WinUSB.
 #define DAP_PACKET_SIZE         64U            ///< Specifies Packet Size in bytes.

 /// Maximum Package Buffers for Command and Response data.
 /// This configuration settings is used to optimize the communication performance with the
 /// debugger and depends on the USB peripheral. For devices with limited RAM or USB buffer the
 /// setting can be reduced (valid range is 1 .. 255).
 #define DAP_PACKET_COUNT        2U              ///< Specifies number of packets buffered.

 /// Indicate that UART Serial Wire Output (SWO) trace is available.
 /// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
 #define SWO_UART                0               ///< SWO UART:  1 = available, 0 = not available.

 /// USART Driver instance number for the UART SWO.
 #define SWO_UART_DRIVER         0               ///< USART Driver instance number (Driver_USART#).

 /// Maximum SWO UART Baudrate.
 #define SWO_UART_MAX_BAUDRATE   10000000U       ///< SWO UART Maximum Baudrate in Hz.

 /// Indicate that Manchester Serial Wire Output (SWO) trace is available.
 /// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
 #define SWO_MANCHESTER          0               ///< SWO Manchester:  1 = available, 0 = not available.

 /// SWO Trace Buffer Size.
 #define SWO_BUFFER_SIZE         4096U           ///< SWO Trace Buffer Size in bytes (must be 2^n).

 /// SWO Streaming Trace.
 #define SWO_STREAM              0               ///< SWO Streaming Trace: 1 = available, 0 = not available.

 /// Clock frequency of the Test Domain Timer. Timer value is returned with \ref TIMESTAMP_GET.
 #define TIMESTAMP_CLOCK         1000000U      ///< Timestamp clock in Hz (0 = timestamps not supported).

 /// Indicate that UART Communication Port is available.
 /// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
 #define DAP_UART                0               ///< DAP UART:  1 = available, 0 = not available.

 /// USART Driver instance number for the UART Communication Port.
 #define DAP_UART_DRIVER         0               ///< USART Driver instance number (Driver_USART#).

 /// UART Receive Buffer Size.
 #define DAP_UART_RX_BUFFER_SIZE 1024U           ///< Uart Receive Buffer Size in bytes (must be 2^n).

 /// UART Transmit Buffer Size.
 #define DAP_UART_TX_BUFFER_SIZE 1024U           ///< Uart Transmit Buffer Size in bytes (must be 2^n).

 /// Indicate that UART Communication via USB COM Port is available.
 /// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
 #define DAP_UART_USB_COM_PORT   0               ///< USB COM Port:  1 = available, 0 = not available.

 /// Debug Unit is connected to fixed Target Device.
 /// The Debug Unit may be part of an evaluation board and always connected to a fixed
 /// known device. In this case a Device Vendor, Device Name, Board Vendor and Board Name strings
 /// are stored and may be used by the debugger or IDE to configure device parameters.
 #define TARGET_FIXED            0               ///< Target: 1 = known, 0 = unknown;

 #define TARGET_DEVICE_VENDOR    "Arm"           ///< String indicating the Silicon Vendor
 #define TARGET_DEVICE_NAME      "Cortex-M"      ///< String indicating the Target Device
 #define TARGET_BOARD_VENDOR     "Arm"           ///< String indicating the Board Vendor
 #define TARGET_BOARD_NAME       "Arm board"     ///< String indicating the Board Name

 #if TARGET_FIXED != 0
 #include <string.h>
 static const char TargetDeviceVendor [] = TARGET_DEVICE_VENDOR;
 static const char TargetDeviceName   [] = TARGET_DEVICE_NAME;
 static const char TargetBoardVendor  [] = TARGET_BOARD_VENDOR;
 static const char TargetBoardName    [] = TARGET_BOARD_NAME;
 #endif

 /** Get Vendor Name string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetVendorString (char *str) {
   (void)str;
   return (0U);
 }

 /** Get Product Name string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetProductString (char *str) {
   (void)str;
   return (0U);
 }

 /** Get Serial Number string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetSerNumString (char *str) {
   (void)str;
   return (0U);
 }

 /** Get Target Device Vendor string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetTargetDeviceVendorString (char *str) {
 #if TARGET_FIXED != 0
   uint8_t len;

   strcpy(str, TargetDeviceVendor);
   len = (uint8_t)(strlen(TargetDeviceVendor) + 1U);
   return (len);
 #else
   (void)str;
   return (0U);
 #endif
 }

 /** Get Target Device Name string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetTargetDeviceNameString (char *str) {
 #if TARGET_FIXED != 0
   uint8_t len;

   strcpy(str, TargetDeviceName);
   len = (uint8_t)(strlen(TargetDeviceName) + 1U);
   return (len);
 #else
   (void)str;
   return (0U);
 #endif
 }

 /** Get Target Board Vendor string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetTargetBoardVendorString (char *str) {
 #if TARGET_FIXED != 0
   uint8_t len;

   strcpy(str, TargetBoardVendor);
   len = (uint8_t)(strlen(TargetBoardVendor) + 1U);
   return (len);
 #else
   (void)str;
   return (0U);
 #endif
 }

 /** Get Target Board Name string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetTargetBoardNameString (char *str) {
 #if TARGET_FIXED != 0
   uint8_t len;

   strcpy(str, TargetBoardName);
   len = (uint8_t)(strlen(TargetBoardName) + 1U);
   return (len);
 #else
   (void)str;
   return (0U);
 #endif
 }

 /** Get Product Firmware Version string.
 \param str Pointer to buffer to store the string (max 60 characters).
 \return String length (including terminating NULL character) or 0 (no string).
 */
 __STATIC_INLINE uint8_t DAP_GetProductFirmwareVersionString (char *str) {
   (void)str;
   return (0U);
 }

 ///@}


 //**************************************************************************************************
 /**
 \defgroup DAP_Config_PortIO_gr CMSIS-DAP Hardware I/O Pin Access
 \ingroup DAP_ConfigIO_gr
 @{

 Standard I/O Pins of the CMSIS-DAP Hardware Debug Port support standard JTAG mode
 and Serial Wire Debug (SWD) mode. In SWD mode only 2 pins are required to implement the debug
 interface of a device. The following I/O Pins are provided:

 JTAG I/O Pin                 | SWD I/O Pin          | CMSIS-DAP Hardware pin mode
 ---------------------------- | -------------------- | ---------------------------------------------
 TCK: Test Clock              | SWCLK: Clock         | Output Push/Pull
 TMS: Test Mode Select        | SWDIO: Data I/O      | Output Push/Pull; Input (for receiving data)
 TDI: Test Data Input         |                      | Output Push/Pull
 TDO: Test Data Output        |                      | Input
 nTRST: Test Reset (optional) |                      | Output Open Drain with pull-up resistor
 nRESET: Device Reset         | nRESET: Device Reset | Output Open Drain with pull-up resistor


 DAP Hardware I/O Pin Access Functions
 -------------------------------------
 The various I/O Pins are accessed by functions that implement the Read, Write, Set, or Clear to
 these I/O Pins.

 For the SWDIO I/O Pin there are additional functions that are called in SWD I/O mode only.
 This functions are provided to achieve faster I/O that is possible with some advanced GPIO
 peripherals that can independently write/read a single I/O pin without affecting any other pins
 of the same I/O port. The following SWDIO I/O Pin functions are provided:
  - \ref PIN_SWDIO_OUT_ENABLE to enable the output mode from the DAP hardware.
  - \ref PIN_SWDIO_OUT_DISABLE to enable the input mode to the DAP hardware.
  - \ref PIN_SWDIO_IN to read from the SWDIO I/O pin with utmost possible speed.
  - \ref PIN_SWDIO_OUT to write to the SWDIO I/O pin with utmost possible speed.
 */


 // Configure DAP I/O pins ------------------------------

 /** Setup JTAG I/O pins: TCK, TMS, TDI, TDO, nTRST, and nRESET.
 Configures the DAP Hardware I/O pins for JTAG mode:
  - TCK, TMS, TDI, nTRST, nRESET to output mode and set to high level.
  - TDO to input mode.
 */
 __STATIC_INLINE void PORT_JTAG_SETUP (void) {
   ;
 }

 /** Setup SWD I/O pins: SWCLK, SWDIO, and nRESET.
 Configures the DAP Hardware I/O pins for Serial Wire Debug (SWD) mode:
  - SWCLK, SWDIO, nRESET to output mode and set to default high level.
  - TDI, nTRST to HighZ mode (pins are unused in SWD mode).
 */
 // hack - zap our "stop doing divides everywhere" cache
 extern volatile uint32_t cached_delay;
 __STATIC_INLINE void PORT_SWD_SETUP (void) {
   probe_init();
   cached_delay = 0;
 }

 /** Disable JTAG/SWD I/O Pins.
 Disables the DAP Hardware I/O pins which configures:
  - TCK/SWCLK, TMS/SWDIO, TDI, TDO, nTRST, nRESET to High-Z mode.
 */
 __STATIC_INLINE void PORT_OFF (void) {
   probe_deinit();
 }


 // SWCLK/TCK I/O pin -------------------------------------

 /** SWCLK/TCK I/O pin: Get Input.
 \return Current status of the SWCLK/TCK DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_SWCLK_TCK_IN  (void) {
   return (0U);
 }

 /** SWCLK/TCK I/O pin: Set Output to High.
 Set the SWCLK/TCK DAP hardware I/O pin to high level.
 */
 __STATIC_FORCEINLINE void     PIN_SWCLK_TCK_SET (void) {
   ;
 }

 /** SWCLK/TCK I/O pin: Set Output to Low.
 Set the SWCLK/TCK DAP hardware I/O pin to low level.
 */
 __STATIC_FORCEINLINE void     PIN_SWCLK_TCK_CLR (void) {
   ;
 }


 // SWDIO/TMS Pin I/O --------------------------------------

 /** SWDIO/TMS I/O pin: Get Input.
 \return Current status of the SWDIO/TMS DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_SWDIO_TMS_IN  (void) {
   return (0U);
 }

 /** SWDIO/TMS I/O pin: Set Output to High.
 Set the SWDIO/TMS DAP hardware I/O pin to high level.
 */
 __STATIC_FORCEINLINE void     PIN_SWDIO_TMS_SET (void) {
   ;
 }

 /** SWDIO/TMS I/O pin: Set Output to Low.
 Set the SWDIO/TMS DAP hardware I/O pin to low level.
 */
 __STATIC_FORCEINLINE void     PIN_SWDIO_TMS_CLR (void) {
   ;
 }

 /** SWDIO I/O pin: Get Input (used in SWD mode only).
 \return Current status of the SWDIO DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_SWDIO_IN      (void) {
   return (0U);
 }

 /** SWDIO I/O pin: Set Output (used in SWD mode only).
 \param bit Output value for the SWDIO DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE void     PIN_SWDIO_OUT     (uint32_t bit) {
   ;
 }

 /** SWDIO I/O pin: Switch to Output mode (used in SWD mode only).
 Configure the SWDIO DAP hardware I/O pin to output mode. This function is
 called prior \ref PIN_SWDIO_OUT function calls.
 */
 __STATIC_FORCEINLINE void     PIN_SWDIO_OUT_ENABLE  (void) {
   probe_write_mode();
 }

 /** SWDIO I/O pin: Switch to Input mode (used in SWD mode only).
 Configure the SWDIO DAP hardware I/O pin to input mode. This function is
 called prior \ref PIN_SWDIO_IN function calls.
 */
 __STATIC_FORCEINLINE void     PIN_SWDIO_OUT_DISABLE (void) {
   probe_read_mode();
 }


 // TDI Pin I/O ---------------------------------------------

 /** TDI I/O pin: Get Input.
 \return Current status of the TDI DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_TDI_IN  (void) {
   return (0U);
 }

 /** TDI I/O pin: Set Output.
 \param bit Output value for the TDI DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE void     PIN_TDI_OUT (uint32_t bit) {
   ;
 }


 // TDO Pin I/O ---------------------------------------------

 /** TDO I/O pin: Get Input.
 \return Current status of the TDO DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_TDO_IN  (void) {
   return (0U);
 }


 // nTRST Pin I/O -------------------------------------------

 /** nTRST I/O pin: Get Input.
 \return Current status of the nTRST DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_nTRST_IN   (void) {
   return (0U);
 }

 /** nTRST I/O pin: Set Output.
 \param bit JTAG TRST Test Reset pin status:
            - 0: issue a JTAG TRST Test Reset.
            - 1: release JTAG TRST Test Reset.
 */
 __STATIC_FORCEINLINE void     PIN_nTRST_OUT  (uint32_t bit) {
   ;
 }

 // nRESET Pin I/O------------------------------------------

 /** nRESET I/O pin: Get Input.
 \return Current status of the nRESET DAP hardware I/O pin.
 */
 __STATIC_FORCEINLINE uint32_t PIN_nRESET_IN  (void) {
 #ifdef PROBE_PIN_RESET
   return probe_reset_level();
 #else
   return (0U);
 #endif
 }

 /** nRESET I/O pin: Set Output.
 \param bit target device hardware reset pin status:
            - 0: issue a device hardware reset.
            - 1: release device hardware reset.
 */
 __STATIC_FORCEINLINE void     PIN_nRESET_OUT (uint32_t bit) {
 #ifdef PROBE_PIN_RESET
   probe_assert_reset(!!bit);
 #else
   (void) bit;
 #endif
 }

 ///@}


 //**************************************************************************************************
 /**
 \defgroup DAP_Config_LEDs_gr CMSIS-DAP Hardware Status LEDs
 \ingroup DAP_ConfigIO_gr
 @{

 CMSIS-DAP Hardware may provide LEDs that indicate the status of the CMSIS-DAP Debug Unit.

 It is recommended to provide the following LEDs for status indication:
  - Connect LED: is active when the DAP hardware is connected to a debugger.
  - Running LED: is active when the debugger has put the target device into running state.
 */

 /** Debug Unit: Set status of Connected LED.
 \param bit status of the Connect LED.
            - 1: Connect LED ON: debugger is connected to CMSIS-DAP Debug Unit.
            - 0: Connect LED OFF: debugger is not connected to CMSIS-DAP Debug Unit.
 */
 __STATIC_INLINE void LED_CONNECTED_OUT (uint32_t bit) {
 #ifdef PROBE_DAP_CONNECTED_LED
   gpio_put(PROBE_DAP_CONNECTED_LED, bit);
 #endif
 }

 /** Debug Unit: Set status Target Running LED.
 \param bit status of the Target Running LED.
            - 1: Target Running LED ON: program execution in target started.
            - 0: Target Running LED OFF: program execution in target stopped.
 */
 __STATIC_INLINE void LED_RUNNING_OUT (uint32_t bit) {
 #ifdef PROBE_DAP_RUNNING_LED
   gpio_put(PROBE_DAP_RUNNING_LED, bit);
 #endif
 }

 ///@}


 //**************************************************************************************************
 /**
 \defgroup DAP_Config_Timestamp_gr CMSIS-DAP Timestamp
 \ingroup DAP_ConfigIO_gr
 @{
 Access function for Test Domain Timer.

 The value of the Test Domain Timer in the Debug Unit is returned by the function \ref TIMESTAMP_GET. By
 default, the DWT timer is used.  The frequency of this timer is configured with \ref TIMESTAMP_CLOCK.

 */

 /** Get timestamp of Test Domain Timer.
 \return Current timestamp value.
 */
 __STATIC_INLINE uint32_t TIMESTAMP_GET (void) {
   return time_us_32();
 }

 ///@}


 //**************************************************************************************************
 /**
 \defgroup DAP_Config_Initialization_gr CMSIS-DAP Initialization
 \ingroup DAP_ConfigIO_gr
 @{

 CMSIS-DAP Hardware I/O and LED Pins are initialized with the function \ref DAP_SETUP.
 */

 /** Setup of the Debug Unit I/O pins and LEDs (called when Debug Unit is initialized).
 This function performs the initialization of the CMSIS-DAP Hardware I/O Pins and the
 Status LEDs. In detail the operation of Hardware I/O and LED pins are enabled and set:
  - I/O clock system enabled.
  - all I/O pins: input buffer enabled, output pins are set to HighZ mode.
  - for nTRST, nRESET a weak pull-up (if available) is enabled.
  - LED output pins are enabled and LEDs are turned off.
 */
 __STATIC_INLINE void DAP_SETUP (void) {
 // We synchronously setup probe IOs when the respective PIO program is loaded - not at start of day

 #ifdef PROBE_DAP_CONNECTED_LED
     gpio_init(PROBE_DAP_CONNECTED_LED);
     gpio_set_dir(PROBE_DAP_CONNECTED_LED, GPIO_OUT);
 #endif
 #ifdef PROBE_DAP_RUNNING_LED
     gpio_init(PROBE_DAP_RUNNING_LED);
     gpio_set_dir(PROBE_DAP_RUNNING_LED, GPIO_OUT);
 #endif
 }

 /** Reset Target Device with custom specific I/O pin or command sequence.
 This function allows the optional implementation of a device specific reset sequence.
 It is called when the command \ref DAP_ResetTarget and is for example required
 when a device needs a time-critical unlock sequence that enables the debug port.
 \return 0 = no device specific reset sequence is implemented.\n
         1 = a device specific reset sequence is implemented.
 */
 __STATIC_INLINE uint8_t RESET_TARGET (void) {
   return (0U);             // change to '1' when a device reset sequence is implemented
 }

 ///@}


 #endif /* __DAP_CONFIG_H__ */
	/*
	* Copyright (c) 2013-2021 ARM Limited. All rights reserved.
	*
	* SPDX-License-Identifier: Apache-2.0
	*
	* Licensed under the Apache License, Version 2.0 (the License); you may
	* not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an AS IS BASIS, WITHOUT
	* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	* ----------------------------------------------------------------------
	*
	* $Date: 16. June 2021
	* $Revision: V2.1.0
	*
	* Project: CMSIS-DAP Configuration
	* Title: DAP_config.h CMSIS-DAP Configuration File (Template)
	*
	---------------------------------------------------------------------------/

	#ifndef __DAP_CONFIG_H__
	#define __DAP_CONFIG_H__


	//**************************************************************************************************
	/**
	\defgroup DAP_Config_Debug_gr CMSIS-DAP Debug Unit Information
	\ingroup DAP_ConfigIO_gr
	@{
	Provides definitions about the hardware and configuration of the Debug Unit.

	This information includes:
	- Definition of Cortex-M processor parameters used in CMSIS-DAP Debug Unit.
	- Debug Unit Identification strings (Vendor, Product, Serial Number).
	- Debug Unit communication packet size.
	- Debug Access Port supported modes and settings (JTAG/SWD and SWO).
	- Optional information about a connected Target Device (for Evaluation Boards).
	*/
	#include <pico/stdlib.h>
	#include <hardware/clocks.h>
	#include <hardware/gpio.h>

	#include "cmsis_compiler.h"
	#include "probe_config.h"
	#include "probe.h"

	/// Processor Clock of the Cortex-M MCU used in the Debug Unit.
	/// This value is used to calculate the SWD/JTAG clock speed.
	/* Debugprobe uses PIO for clock generation, so return the current system clock. */
	#define CPU_CLOCK clock_get_hz(clk_sys)

	/// Number of processor cycles for I/O Port write operations.
	/// This value is used to calculate the SWD/JTAG clock speed that is generated with I/O
	/// Port write operations in the Debug Unit by a Cortex-M MCU. Most Cortex-M processors
	/// require 2 processor cycles for a I/O Port Write operation. If the Debug Unit uses
	/// a Cortex-M0+ processor with high-speed peripheral I/O only 1 processor cycle might be
	/// required.
	#define IO_PORT_WRITE_CYCLES 1U ///< I/O Cycles: 2=default, 1=Cortex-M0+ fast I/0.
	#define DELAY_SLOW_CYCLES 1U // We don't differentiate between fast/slow, we've got a 16-bit divisor for that

	/// Indicate that Serial Wire Debug (SWD) communication mode is available at the Debug Access Port.
	/// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
	#define DAP_SWD 1 ///< SWD Mode: 1 = available, 0 = not available.

	/// Indicate that JTAG communication mode is available at the Debug Port.
	/// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
	#define DAP_JTAG 0 ///< JTAG Mode: 1 = available, 0 = not available.

	/// Configure maximum number of JTAG devices on the scan chain connected to the Debug Access Port.
	/// This setting impacts the RAM requirements of the Debug Unit. Valid range is 1 .. 255.
	#define DAP_JTAG_DEV_CNT 8U ///< Maximum number of JTAG devices on scan chain.

	/// Default communication mode on the Debug Access Port.
	/// Used for the command \ref DAP_Connect when Port Default mode is selected.
	#define DAP_DEFAULT_PORT 1U ///< Default JTAG/SWJ Port Mode: 1 = SWD, 2 = JTAG.

	/// Default communication speed on the Debug Access Port for SWD and JTAG mode.
	/// Used to initialize the default SWD/JTAG clock frequency.
	/// The command \ref DAP_SWJ_Clock can be used to overwrite this default setting.
	#define DAP_DEFAULT_SWJ_CLOCK 1000000U ///< Default SWD/JTAG clock frequency in Hz.

	/// Maximum Package Size for Command and Response data.
	/// This configuration settings is used to optimize the communication performance with the
	/// debugger and depends on the USB peripheral. Typical vales are 64 for Full-speed USB HID or WinUSB,
	/// 1024 for High-speed USB HID and 512 for High-speed USB WinUSB.
	#define DAP_PACKET_SIZE 64U ///< Specifies Packet Size in bytes.

	/// Maximum Package Buffers for Command and Response data.
	/// This configuration settings is used to optimize the communication performance with the
	/// debugger and depends on the USB peripheral. For devices with limited RAM or USB buffer the
	/// setting can be reduced (valid range is 1 .. 255).
	#define DAP_PACKET_COUNT 2U ///< Specifies number of packets buffered.

	/// Indicate that UART Serial Wire Output (SWO) trace is available.
	/// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
	#define SWO_UART 0 ///< SWO UART: 1 = available, 0 = not available.

	/// USART Driver instance number for the UART SWO.
	#define SWO_UART_DRIVER 0 ///< USART Driver instance number (Driver_USART#).

	/// Maximum SWO UART Baudrate.
	#define SWO_UART_MAX_BAUDRATE 10000000U ///< SWO UART Maximum Baudrate in Hz.

	/// Indicate that Manchester Serial Wire Output (SWO) trace is available.
	/// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
	#define SWO_MANCHESTER 0 ///< SWO Manchester: 1 = available, 0 = not available.

	/// SWO Trace Buffer Size.
	#define SWO_BUFFER_SIZE 4096U ///< SWO Trace Buffer Size in bytes (must be 2^n).

	/// SWO Streaming Trace.
	#define SWO_STREAM 0 ///< SWO Streaming Trace: 1 = available, 0 = not available.

	/// Clock frequency of the Test Domain Timer. Timer value is returned with \ref TIMESTAMP_GET.
	#define TIMESTAMP_CLOCK 1000000U ///< Timestamp clock in Hz (0 = timestamps not supported).

	/// Indicate that UART Communication Port is available.
	/// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
	#define DAP_UART 0 ///< DAP UART: 1 = available, 0 = not available.

	/// USART Driver instance number for the UART Communication Port.
	#define DAP_UART_DRIVER 0 ///< USART Driver instance number (Driver_USART#).

	/// UART Receive Buffer Size.
	#define DAP_UART_RX_BUFFER_SIZE 1024U ///< Uart Receive Buffer Size in bytes (must be 2^n).

	/// UART Transmit Buffer Size.
	#define DAP_UART_TX_BUFFER_SIZE 1024U ///< Uart Transmit Buffer Size in bytes (must be 2^n).

	/// Indicate that UART Communication via USB COM Port is available.
	/// This information is returned by the command \ref DAP_Info as part of <b>Capabilities</b>.
	#define DAP_UART_USB_COM_PORT 0 ///< USB COM Port: 1 = available, 0 = not available.

	/// Debug Unit is connected to fixed Target Device.
	/// The Debug Unit may be part of an evaluation board and always connected to a fixed
	/// known device. In this case a Device Vendor, Device Name, Board Vendor and Board Name strings
	/// are stored and may be used by the debugger or IDE to configure device parameters.
	#define TARGET_FIXED 0 ///< Target: 1 = known, 0 = unknown;

	#define TARGET_DEVICE_VENDOR "Arm" ///< String indicating the Silicon Vendor
	#define TARGET_DEVICE_NAME "Cortex-M" ///< String indicating the Target Device
	#define TARGET_BOARD_VENDOR "Arm" ///< String indicating the Board Vendor
	#define TARGET_BOARD_NAME "Arm board" ///< String indicating the Board Name

	#if TARGET_FIXED != 0
	#include <string.h>
	static const char TargetDeviceVendor [] = TARGET_DEVICE_VENDOR;
	static const char TargetDeviceName [] = TARGET_DEVICE_NAME;
	static const char TargetBoardVendor [] = TARGET_BOARD_VENDOR;
	static const char TargetBoardName [] = TARGET_BOARD_NAME;
	#endif

	/** Get Vendor Name string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetVendorString (char *str) {
	(void)str;
	return (0U);
	}

	/** Get Product Name string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetProductString (char *str) {
	(void)str;
	return (0U);
	}

	/** Get Serial Number string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetSerNumString (char *str) {
	(void)str;
	return (0U);
	}

	/** Get Target Device Vendor string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetTargetDeviceVendorString (char *str) {
	#if TARGET_FIXED != 0
	uint8_t len;

	strcpy(str, TargetDeviceVendor);
	len = (uint8_t)(strlen(TargetDeviceVendor) + 1U);
	return (len);
	#else
	(void)str;
	return (0U);
	#endif
	}

	/** Get Target Device Name string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetTargetDeviceNameString (char *str) {
	#if TARGET_FIXED != 0
	uint8_t len;

	strcpy(str, TargetDeviceName);
	len = (uint8_t)(strlen(TargetDeviceName) + 1U);
	return (len);
	#else
	(void)str;
	return (0U);
	#endif
	}

	/** Get Target Board Vendor string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetTargetBoardVendorString (char *str) {
	#if TARGET_FIXED != 0
	uint8_t len;

	strcpy(str, TargetBoardVendor);
	len = (uint8_t)(strlen(TargetBoardVendor) + 1U);
	return (len);
	#else
	(void)str;
	return (0U);
	#endif
	}

	/** Get Target Board Name string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetTargetBoardNameString (char *str) {
	#if TARGET_FIXED != 0
	uint8_t len;

	strcpy(str, TargetBoardName);
	len = (uint8_t)(strlen(TargetBoardName) + 1U);
	return (len);
	#else
	(void)str;
	return (0U);
	#endif
	}

	/** Get Product Firmware Version string.
	\param str Pointer to buffer to store the string (max 60 characters).
	\return String length (including terminating NULL character) or 0 (no string).
	*/
	__STATIC_INLINE uint8_t DAP_GetProductFirmwareVersionString (char *str) {
	(void)str;
	return (0U);
	}

	///@}


	//**************************************************************************************************
	/**
	\defgroup DAP_Config_PortIO_gr CMSIS-DAP Hardware I/O Pin Access
	\ingroup DAP_ConfigIO_gr
	@{

	Standard I/O Pins of the CMSIS-DAP Hardware Debug Port support standard JTAG mode
	and Serial Wire Debug (SWD) mode. In SWD mode only 2 pins are required to implement the debug
	interface of a device. The following I/O Pins are provided:

	JTAG I/O Pin \| SWD I/O Pin \| CMSIS-DAP Hardware pin mode
	---------------------------- \| -------------------- \| ---------------------------------------------
	TCK: Test Clock \| SWCLK: Clock \| Output Push/Pull
	TMS: Test Mode Select \| SWDIO: Data I/O \| Output Push/Pull; Input (for receiving data)
	TDI: Test Data Input \| \| Output Push/Pull
	TDO: Test Data Output \| \| Input
	nTRST: Test Reset (optional) \| \| Output Open Drain with pull-up resistor
	nRESET: Device Reset \| nRESET: Device Reset \| Output Open Drain with pull-up resistor


	DAP Hardware I/O Pin Access Functions
	-------------------------------------
	The various I/O Pins are accessed by functions that implement the Read, Write, Set, or Clear to
	these I/O Pins.

	For the SWDIO I/O Pin there are additional functions that are called in SWD I/O mode only.
	This functions are provided to achieve faster I/O that is possible with some advanced GPIO
	peripherals that can independently write/read a single I/O pin without affecting any other pins
	of the same I/O port. The following SWDIO I/O Pin functions are provided:
	- \ref PIN_SWDIO_OUT_ENABLE to enable the output mode from the DAP hardware.
	- \ref PIN_SWDIO_OUT_DISABLE to enable the input mode to the DAP hardware.
	- \ref PIN_SWDIO_IN to read from the SWDIO I/O pin with utmost possible speed.
	- \ref PIN_SWDIO_OUT to write to the SWDIO I/O pin with utmost possible speed.
	*/


	// Configure DAP I/O pins ------------------------------

	/** Setup JTAG I/O pins: TCK, TMS, TDI, TDO, nTRST, and nRESET.
	Configures the DAP Hardware I/O pins for JTAG mode:
	- TCK, TMS, TDI, nTRST, nRESET to output mode and set to high level.
	- TDO to input mode.
	*/
	__STATIC_INLINE void PORT_JTAG_SETUP (void) {
	;
	}

	/** Setup SWD I/O pins: SWCLK, SWDIO, and nRESET.
	Configures the DAP Hardware I/O pins for Serial Wire Debug (SWD) mode:
	- SWCLK, SWDIO, nRESET to output mode and set to default high level.
	- TDI, nTRST to HighZ mode (pins are unused in SWD mode).
	*/
	// hack - zap our "stop doing divides everywhere" cache
	extern volatile uint32_t cached_delay;
	__STATIC_INLINE void PORT_SWD_SETUP (void) {
	probe_init();
	cached_delay = 0;
	}

	/** Disable JTAG/SWD I/O Pins.
	Disables the DAP Hardware I/O pins which configures:
	- TCK/SWCLK, TMS/SWDIO, TDI, TDO, nTRST, nRESET to High-Z mode.
	*/
	__STATIC_INLINE void PORT_OFF (void) {
	probe_deinit();
	}


	// SWCLK/TCK I/O pin -------------------------------------

	/** SWCLK/TCK I/O pin: Get Input.
	\return Current status of the SWCLK/TCK DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_SWCLK_TCK_IN (void) {
	return (0U);
	}

	/** SWCLK/TCK I/O pin: Set Output to High.
	Set the SWCLK/TCK DAP hardware I/O pin to high level.
	*/
	__STATIC_FORCEINLINE void PIN_SWCLK_TCK_SET (void) {
	;
	}

	/** SWCLK/TCK I/O pin: Set Output to Low.
	Set the SWCLK/TCK DAP hardware I/O pin to low level.
	*/
	__STATIC_FORCEINLINE void PIN_SWCLK_TCK_CLR (void) {
	;
	}


	// SWDIO/TMS Pin I/O --------------------------------------

	/** SWDIO/TMS I/O pin: Get Input.
	\return Current status of the SWDIO/TMS DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_SWDIO_TMS_IN (void) {
	return (0U);
	}

	/** SWDIO/TMS I/O pin: Set Output to High.
	Set the SWDIO/TMS DAP hardware I/O pin to high level.
	*/
	__STATIC_FORCEINLINE void PIN_SWDIO_TMS_SET (void) {
	;
	}

	/** SWDIO/TMS I/O pin: Set Output to Low.
	Set the SWDIO/TMS DAP hardware I/O pin to low level.
	*/
	__STATIC_FORCEINLINE void PIN_SWDIO_TMS_CLR (void) {
	;
	}

	/** SWDIO I/O pin: Get Input (used in SWD mode only).
	\return Current status of the SWDIO DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_SWDIO_IN (void) {
	return (0U);
	}

	/** SWDIO I/O pin: Set Output (used in SWD mode only).
	\param bit Output value for the SWDIO DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE void PIN_SWDIO_OUT (uint32_t bit) {
	;
	}

	/** SWDIO I/O pin: Switch to Output mode (used in SWD mode only).
	Configure the SWDIO DAP hardware I/O pin to output mode. This function is
	called prior \ref PIN_SWDIO_OUT function calls.
	*/
	__STATIC_FORCEINLINE void PIN_SWDIO_OUT_ENABLE (void) {
	probe_write_mode();
	}

	/** SWDIO I/O pin: Switch to Input mode (used in SWD mode only).
	Configure the SWDIO DAP hardware I/O pin to input mode. This function is
	called prior \ref PIN_SWDIO_IN function calls.
	*/
	__STATIC_FORCEINLINE void PIN_SWDIO_OUT_DISABLE (void) {
	probe_read_mode();
	}


	// TDI Pin I/O ---------------------------------------------

	/** TDI I/O pin: Get Input.
	\return Current status of the TDI DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_TDI_IN (void) {
	return (0U);
	}

	/** TDI I/O pin: Set Output.
	\param bit Output value for the TDI DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE void PIN_TDI_OUT (uint32_t bit) {
	;
	}


	// TDO Pin I/O ---------------------------------------------

	/** TDO I/O pin: Get Input.
	\return Current status of the TDO DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_TDO_IN (void) {
	return (0U);
	}


	// nTRST Pin I/O -------------------------------------------

	/** nTRST I/O pin: Get Input.
	\return Current status of the nTRST DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_nTRST_IN (void) {
	return (0U);
	}

	/** nTRST I/O pin: Set Output.
	\param bit JTAG TRST Test Reset pin status:
	- 0: issue a JTAG TRST Test Reset.
	- 1: release JTAG TRST Test Reset.
	*/
	__STATIC_FORCEINLINE void PIN_nTRST_OUT (uint32_t bit) {
	;
	}

	// nRESET Pin I/O------------------------------------------

	/** nRESET I/O pin: Get Input.
	\return Current status of the nRESET DAP hardware I/O pin.
	*/
	__STATIC_FORCEINLINE uint32_t PIN_nRESET_IN (void) {
	#ifdef PROBE_PIN_RESET
	return probe_reset_level();
	#else
	return (0U);
	#endif
	}

	/** nRESET I/O pin: Set Output.
	\param bit target device hardware reset pin status:
	- 0: issue a device hardware reset.
	- 1: release device hardware reset.
	*/
	__STATIC_FORCEINLINE void PIN_nRESET_OUT (uint32_t bit) {
	#ifdef PROBE_PIN_RESET
	probe_assert_reset(!!bit);
	#else
	(void) bit;
	#endif
	}

	///@}


	//**************************************************************************************************
	/**
	\defgroup DAP_Config_LEDs_gr CMSIS-DAP Hardware Status LEDs
	\ingroup DAP_ConfigIO_gr
	@{

	CMSIS-DAP Hardware may provide LEDs that indicate the status of the CMSIS-DAP Debug Unit.

	It is recommended to provide the following LEDs for status indication:
	- Connect LED: is active when the DAP hardware is connected to a debugger.
	- Running LED: is active when the debugger has put the target device into running state.
	*/

	/** Debug Unit: Set status of Connected LED.
	\param bit status of the Connect LED.
	- 1: Connect LED ON: debugger is connected to CMSIS-DAP Debug Unit.
	- 0: Connect LED OFF: debugger is not connected to CMSIS-DAP Debug Unit.
	*/
	__STATIC_INLINE void LED_CONNECTED_OUT (uint32_t bit) {
	#ifdef PROBE_DAP_CONNECTED_LED
	gpio_put(PROBE_DAP_CONNECTED_LED, bit);
	#endif
	}

	/** Debug Unit: Set status Target Running LED.
	\param bit status of the Target Running LED.
	- 1: Target Running LED ON: program execution in target started.
	- 0: Target Running LED OFF: program execution in target stopped.
	*/
	__STATIC_INLINE void LED_RUNNING_OUT (uint32_t bit) {
	#ifdef PROBE_DAP_RUNNING_LED
	gpio_put(PROBE_DAP_RUNNING_LED, bit);
	#endif
	}

	///@}


	//**************************************************************************************************
	/**
	\defgroup DAP_Config_Timestamp_gr CMSIS-DAP Timestamp
	\ingroup DAP_ConfigIO_gr
	@{
	Access function for Test Domain Timer.

	The value of the Test Domain Timer in the Debug Unit is returned by the function \ref TIMESTAMP_GET. By
	default, the DWT timer is used. The frequency of this timer is configured with \ref TIMESTAMP_CLOCK.

	*/

	/** Get timestamp of Test Domain Timer.
	\return Current timestamp value.
	*/
	__STATIC_INLINE uint32_t TIMESTAMP_GET (void) {
	return time_us_32();
	}

	///@}


	//**************************************************************************************************
	/**
	\defgroup DAP_Config_Initialization_gr CMSIS-DAP Initialization
	\ingroup DAP_ConfigIO_gr
	@{

	CMSIS-DAP Hardware I/O and LED Pins are initialized with the function \ref DAP_SETUP.
	*/

	/** Setup of the Debug Unit I/O pins and LEDs (called when Debug Unit is initialized).
	This function performs the initialization of the CMSIS-DAP Hardware I/O Pins and the
	Status LEDs. In detail the operation of Hardware I/O and LED pins are enabled and set:
	- I/O clock system enabled.
	- all I/O pins: input buffer enabled, output pins are set to HighZ mode.
	- for nTRST, nRESET a weak pull-up (if available) is enabled.
	- LED output pins are enabled and LEDs are turned off.
	*/
	__STATIC_INLINE void DAP_SETUP (void) {
	// We synchronously setup probe IOs when the respective PIO program is loaded - not at start of day

	#ifdef PROBE_DAP_CONNECTED_LED
	gpio_init(PROBE_DAP_CONNECTED_LED);
	gpio_set_dir(PROBE_DAP_CONNECTED_LED, GPIO_OUT);
	#endif
	#ifdef PROBE_DAP_RUNNING_LED
	gpio_init(PROBE_DAP_RUNNING_LED);
	gpio_set_dir(PROBE_DAP_RUNNING_LED, GPIO_OUT);
	#endif
	}

	/** Reset Target Device with custom specific I/O pin or command sequence.
	This function allows the optional implementation of a device specific reset sequence.
	It is called when the command \ref DAP_ResetTarget and is for example required
	when a device needs a time-critical unlock sequence that enables the debug port.
	\return 0 = no device specific reset sequence is implemented.\n
	1 = a device specific reset sequence is implemented.
	*/
	__STATIC_INLINE uint8_t RESET_TARGET (void) {
	return (0U); // change to '1' when a device reset sequence is implemented
	}

	///@}


	#endif /* __DAP_CONFIG_H__ */