/* ** ################################################################### ** Compilers: Keil ARM C/C++ Compiler ** Freescale C/C++ for Embedded ARM ** GNU C Compiler ** IAR ANSI C/C++ Compiler for ARM ** ** Reference manual: K22P121M120SF7RM, Rev. 1, March 24, 2014 ** Version: rev. 2.5, 2014-05-06 ** Build: b140604 ** ** Abstract: ** Extension to the CMSIS register access layer header. ** ** Copyright (c) 2014 Freescale Semiconductor, Inc. ** All rights reserved. ** ** Redistribution and use in source and binary forms, with or without modification, ** are permitted provided that the following conditions are met: ** ** o Redistributions of source code must retain the above copyright notice, this list ** of conditions and the following disclaimer. ** ** o Redistributions in binary form must reproduce the above copyright notice, this ** list of conditions and the following disclaimer in the documentation and/or ** other materials provided with the distribution. ** ** o Neither the name of Freescale Semiconductor, Inc. nor the names of its ** contributors may be used to endorse or promote products derived from this ** software without specific prior written permission. ** ** THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ** ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED ** WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE ** DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ** ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES ** (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; ** LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ** ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS ** SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ** ** http: www.freescale.com ** mail: support@freescale.com ** ** Revisions: ** - rev. 1.0 (2013-07-23) ** Initial version. ** - rev. 1.1 (2013-09-17) ** RM rev. 0.4 update. ** - rev. 2.0 (2013-10-29) ** Register accessor macros added to the memory map. ** Symbols for Processor Expert memory map compatibility added to the memory map. ** Startup file for gcc has been updated according to CMSIS 3.2. ** System initialization updated. ** - rev. 2.1 (2013-10-30) ** Definition of BITBAND macros updated to support peripherals with 32-bit acces disabled. ** - rev. 2.2 (2013-12-20) ** Update according to reference manual rev. 0.6, ** - rev. 2.3 (2014-01-13) ** Update according to reference manual rev. 0.61, ** - rev. 2.4 (2014-02-10) ** The declaration of clock configurations has been moved to separate header file system_MK22F51212.h ** - rev. 2.5 (2014-05-06) ** Update according to reference manual rev. 1.0, ** Update of system and startup files. ** Module access macro module_BASES replaced by module_BASE_PTRS. ** ** ################################################################### */ /* * WARNING! DO NOT EDIT THIS FILE DIRECTLY! * * This file was generated automatically and any changes may be lost. */ #ifndef __HW_FTFA_REGISTERS_H__ #define __HW_FTFA_REGISTERS_H__ #include "MK22F51212.h" #include "fsl_bitaccess.h" /* * MK22F51212 FTFA * * Flash Memory Interface * * Registers defined in this header file: * - HW_FTFA_FSTAT - Flash Status Register * - HW_FTFA_FCNFG - Flash Configuration Register * - HW_FTFA_FSEC - Flash Security Register * - HW_FTFA_FOPT - Flash Option Register * - HW_FTFA_FCCOB3 - Flash Common Command Object Registers * - HW_FTFA_FCCOB2 - Flash Common Command Object Registers * - HW_FTFA_FCCOB1 - Flash Common Command Object Registers * - HW_FTFA_FCCOB0 - Flash Common Command Object Registers * - HW_FTFA_FCCOB7 - Flash Common Command Object Registers * - HW_FTFA_FCCOB6 - Flash Common Command Object Registers * - HW_FTFA_FCCOB5 - Flash Common Command Object Registers * - HW_FTFA_FCCOB4 - Flash Common Command Object Registers * - HW_FTFA_FCCOBB - Flash Common Command Object Registers * - HW_FTFA_FCCOBA - Flash Common Command Object Registers * - HW_FTFA_FCCOB9 - Flash Common Command Object Registers * - HW_FTFA_FCCOB8 - Flash Common Command Object Registers * - HW_FTFA_FPROT3 - Program Flash Protection Registers * - HW_FTFA_FPROT2 - Program Flash Protection Registers * - HW_FTFA_FPROT1 - Program Flash Protection Registers * - HW_FTFA_FPROT0 - Program Flash Protection Registers * - HW_FTFA_XACCH3 - Execute-only Access Registers * - HW_FTFA_XACCH2 - Execute-only Access Registers * - HW_FTFA_XACCH1 - Execute-only Access Registers * - HW_FTFA_XACCH0 - Execute-only Access Registers * - HW_FTFA_XACCL3 - Execute-only Access Registers * - HW_FTFA_XACCL2 - Execute-only Access Registers * - HW_FTFA_XACCL1 - Execute-only Access Registers * - HW_FTFA_XACCL0 - Execute-only Access Registers * - HW_FTFA_SACCH3 - Supervisor-only Access Registers * - HW_FTFA_SACCH2 - Supervisor-only Access Registers * - HW_FTFA_SACCH1 - Supervisor-only Access Registers * - HW_FTFA_SACCH0 - Supervisor-only Access Registers * - HW_FTFA_SACCL3 - Supervisor-only Access Registers * - HW_FTFA_SACCL2 - Supervisor-only Access Registers * - HW_FTFA_SACCL1 - Supervisor-only Access Registers * - HW_FTFA_SACCL0 - Supervisor-only Access Registers * - HW_FTFA_FACSS - Flash Access Segment Size Register * - HW_FTFA_FACSN - Flash Access Segment Number Register * * - hw_ftfa_t - Struct containing all module registers. */ #define HW_FTFA_INSTANCE_COUNT (1U) /*!< Number of instances of the FTFA module. */ /******************************************************************************* * HW_FTFA_FSTAT - Flash Status Register ******************************************************************************/ /*! * @brief HW_FTFA_FSTAT - Flash Status Register (RW) * * Reset value: 0x00U * * The FSTAT register reports the operational status of the flash memory module. * The CCIF, RDCOLERR, ACCERR, and FPVIOL bits are readable and writable. The * MGSTAT0 bit is read only. The unassigned bits read 0 and are not writable. When * set, the Access Error (ACCERR) and Flash Protection Violation (FPVIOL) bits in * this register prevent the launch of any more commands until the flag is * cleared (by writing a one to it). */ typedef union _hw_ftfa_fstat { uint8_t U; struct _hw_ftfa_fstat_bitfields { uint8_t MGSTAT0 : 1; /*!< [0] Memory Controller Command Completion * Status Flag */ uint8_t RESERVED0 : 3; /*!< [3:1] */ uint8_t FPVIOL : 1; /*!< [4] Flash Protection Violation Flag */ uint8_t ACCERR : 1; /*!< [5] Flash Access Error Flag */ uint8_t RDCOLERR : 1; /*!< [6] Flash Read Collision Error Flag */ uint8_t CCIF : 1; /*!< [7] Command Complete Interrupt Flag */ } B; } hw_ftfa_fstat_t; /*! * @name Constants and macros for entire FTFA_FSTAT register */ /*@{*/ #define HW_FTFA_FSTAT_ADDR(x) ((x) + 0x0U) #define HW_FTFA_FSTAT(x) (*(__IO hw_ftfa_fstat_t *) HW_FTFA_FSTAT_ADDR(x)) #define HW_FTFA_FSTAT_RD(x) (HW_FTFA_FSTAT(x).U) #define HW_FTFA_FSTAT_WR(x, v) (HW_FTFA_FSTAT(x).U = (v)) #define HW_FTFA_FSTAT_SET(x, v) (HW_FTFA_FSTAT_WR(x, HW_FTFA_FSTAT_RD(x) | (v))) #define HW_FTFA_FSTAT_CLR(x, v) (HW_FTFA_FSTAT_WR(x, HW_FTFA_FSTAT_RD(x) & ~(v))) #define HW_FTFA_FSTAT_TOG(x, v) (HW_FTFA_FSTAT_WR(x, HW_FTFA_FSTAT_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FSTAT bitfields */ /*! * @name Register FTFA_FSTAT, field MGSTAT0[0] (RO) * * The MGSTAT0 status flag is set if an error is detected during execution of a * flash command or during the flash reset sequence. As a status flag, this field * cannot (and need not) be cleared by the user like the other error flags in * this register. The value of the MGSTAT0 bit for "command-N" is valid only at the * end of the "command-N" execution when CCIF=1 and before the next command has * been launched. At some point during the execution of "command-N+1," the * previous result is discarded and any previous error is cleared. */ /*@{*/ #define BP_FTFA_FSTAT_MGSTAT0 (0U) /*!< Bit position for FTFA_FSTAT_MGSTAT0. */ #define BM_FTFA_FSTAT_MGSTAT0 (0x01U) /*!< Bit mask for FTFA_FSTAT_MGSTAT0. */ #define BS_FTFA_FSTAT_MGSTAT0 (1U) /*!< Bit field size in bits for FTFA_FSTAT_MGSTAT0. */ /*! @brief Read current value of the FTFA_FSTAT_MGSTAT0 field. */ #define BR_FTFA_FSTAT_MGSTAT0(x) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_MGSTAT0)) /*@}*/ /*! * @name Register FTFA_FSTAT, field FPVIOL[4] (W1C) * * Indicates an attempt was made to program or erase an address in a protected * area of program flash memory during a command write sequence . While FPVIOL is * set, the CCIF flag cannot be cleared to launch a command. The FPVIOL bit is * cleared by writing a 1 to it. Writing a 0 to the FPVIOL bit has no effect. * * Values: * - 0 - No protection violation detected * - 1 - Protection violation detected */ /*@{*/ #define BP_FTFA_FSTAT_FPVIOL (4U) /*!< Bit position for FTFA_FSTAT_FPVIOL. */ #define BM_FTFA_FSTAT_FPVIOL (0x10U) /*!< Bit mask for FTFA_FSTAT_FPVIOL. */ #define BS_FTFA_FSTAT_FPVIOL (1U) /*!< Bit field size in bits for FTFA_FSTAT_FPVIOL. */ /*! @brief Read current value of the FTFA_FSTAT_FPVIOL field. */ #define BR_FTFA_FSTAT_FPVIOL(x) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_FPVIOL)) /*! @brief Format value for bitfield FTFA_FSTAT_FPVIOL. */ #define BF_FTFA_FSTAT_FPVIOL(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FSTAT_FPVIOL) & BM_FTFA_FSTAT_FPVIOL) /*! @brief Set the FPVIOL field to a new value. */ #define BW_FTFA_FSTAT_FPVIOL(x, v) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_FPVIOL) = (v)) /*@}*/ /*! * @name Register FTFA_FSTAT, field ACCERR[5] (W1C) * * Indicates an illegal access has occurred to a flash memory resource caused by * a violation of the command write sequence or issuing an illegal flash * command. While ACCERR is set, the CCIF flag cannot be cleared to launch a command. * The ACCERR bit is cleared by writing a 1 to it. Writing a 0 to the ACCERR bit * has no effect. * * Values: * - 0 - No access error detected * - 1 - Access error detected */ /*@{*/ #define BP_FTFA_FSTAT_ACCERR (5U) /*!< Bit position for FTFA_FSTAT_ACCERR. */ #define BM_FTFA_FSTAT_ACCERR (0x20U) /*!< Bit mask for FTFA_FSTAT_ACCERR. */ #define BS_FTFA_FSTAT_ACCERR (1U) /*!< Bit field size in bits for FTFA_FSTAT_ACCERR. */ /*! @brief Read current value of the FTFA_FSTAT_ACCERR field. */ #define BR_FTFA_FSTAT_ACCERR(x) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_ACCERR)) /*! @brief Format value for bitfield FTFA_FSTAT_ACCERR. */ #define BF_FTFA_FSTAT_ACCERR(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FSTAT_ACCERR) & BM_FTFA_FSTAT_ACCERR) /*! @brief Set the ACCERR field to a new value. */ #define BW_FTFA_FSTAT_ACCERR(x, v) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_ACCERR) = (v)) /*@}*/ /*! * @name Register FTFA_FSTAT, field RDCOLERR[6] (W1C) * * Indicates that the MCU attempted a read from a flash memory resource that was * being manipulated by a flash command (CCIF=0). Any simultaneous access is * detected as a collision error by the block arbitration logic. The read data in * this case cannot be guaranteed. The RDCOLERR bit is cleared by writing a 1 to * it. Writing a 0 to RDCOLERR has no effect. * * Values: * - 0 - No collision error detected * - 1 - Collision error detected */ /*@{*/ #define BP_FTFA_FSTAT_RDCOLERR (6U) /*!< Bit position for FTFA_FSTAT_RDCOLERR. */ #define BM_FTFA_FSTAT_RDCOLERR (0x40U) /*!< Bit mask for FTFA_FSTAT_RDCOLERR. */ #define BS_FTFA_FSTAT_RDCOLERR (1U) /*!< Bit field size in bits for FTFA_FSTAT_RDCOLERR. */ /*! @brief Read current value of the FTFA_FSTAT_RDCOLERR field. */ #define BR_FTFA_FSTAT_RDCOLERR(x) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_RDCOLERR)) /*! @brief Format value for bitfield FTFA_FSTAT_RDCOLERR. */ #define BF_FTFA_FSTAT_RDCOLERR(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FSTAT_RDCOLERR) & BM_FTFA_FSTAT_RDCOLERR) /*! @brief Set the RDCOLERR field to a new value. */ #define BW_FTFA_FSTAT_RDCOLERR(x, v) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_RDCOLERR) = (v)) /*@}*/ /*! * @name Register FTFA_FSTAT, field CCIF[7] (W1C) * * Indicates that a flash command has completed. The CCIF flag is cleared by * writing a 1 to CCIF to launch a command, and CCIF stays low until command * completion or command violation. CCIF is reset to 0 but is set to 1 by the memory * controller at the end of the reset initialization sequence. Depending on how * quickly the read occurs after reset release, the user may or may not see the 0 * hardware reset value. * * Values: * - 0 - Flash command in progress * - 1 - Flash command has completed */ /*@{*/ #define BP_FTFA_FSTAT_CCIF (7U) /*!< Bit position for FTFA_FSTAT_CCIF. */ #define BM_FTFA_FSTAT_CCIF (0x80U) /*!< Bit mask for FTFA_FSTAT_CCIF. */ #define BS_FTFA_FSTAT_CCIF (1U) /*!< Bit field size in bits for FTFA_FSTAT_CCIF. */ /*! @brief Read current value of the FTFA_FSTAT_CCIF field. */ #define BR_FTFA_FSTAT_CCIF(x) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_CCIF)) /*! @brief Format value for bitfield FTFA_FSTAT_CCIF. */ #define BF_FTFA_FSTAT_CCIF(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FSTAT_CCIF) & BM_FTFA_FSTAT_CCIF) /*! @brief Set the CCIF field to a new value. */ #define BW_FTFA_FSTAT_CCIF(x, v) (BITBAND_ACCESS8(HW_FTFA_FSTAT_ADDR(x), BP_FTFA_FSTAT_CCIF) = (v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCNFG - Flash Configuration Register ******************************************************************************/ /*! * @brief HW_FTFA_FCNFG - Flash Configuration Register (RW) * * Reset value: 0x00U * * This register provides information on the current functional state of the * flash memory module. The erase control bits (ERSAREQ and ERSSUSP) have write * restrictions. The unassigned bits read as noted and are not writable. */ typedef union _hw_ftfa_fcnfg { uint8_t U; struct _hw_ftfa_fcnfg_bitfields { uint8_t RESERVED0 : 4; /*!< [3:0] */ uint8_t ERSSUSP : 1; /*!< [4] Erase Suspend */ uint8_t ERSAREQ : 1; /*!< [5] Erase All Request */ uint8_t RDCOLLIE : 1; /*!< [6] Read Collision Error Interrupt Enable * */ uint8_t CCIE : 1; /*!< [7] Command Complete Interrupt Enable */ } B; } hw_ftfa_fcnfg_t; /*! * @name Constants and macros for entire FTFA_FCNFG register */ /*@{*/ #define HW_FTFA_FCNFG_ADDR(x) ((x) + 0x1U) #define HW_FTFA_FCNFG(x) (*(__IO hw_ftfa_fcnfg_t *) HW_FTFA_FCNFG_ADDR(x)) #define HW_FTFA_FCNFG_RD(x) (HW_FTFA_FCNFG(x).U) #define HW_FTFA_FCNFG_WR(x, v) (HW_FTFA_FCNFG(x).U = (v)) #define HW_FTFA_FCNFG_SET(x, v) (HW_FTFA_FCNFG_WR(x, HW_FTFA_FCNFG_RD(x) | (v))) #define HW_FTFA_FCNFG_CLR(x, v) (HW_FTFA_FCNFG_WR(x, HW_FTFA_FCNFG_RD(x) & ~(v))) #define HW_FTFA_FCNFG_TOG(x, v) (HW_FTFA_FCNFG_WR(x, HW_FTFA_FCNFG_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCNFG bitfields */ /*! * @name Register FTFA_FCNFG, field ERSSUSP[4] (RW) * * Allows the user to suspend (interrupt) the Erase Flash Sector command while * it is executing. * * Values: * - 0 - No suspend requested * - 1 - Suspend the current Erase Flash Sector command execution. */ /*@{*/ #define BP_FTFA_FCNFG_ERSSUSP (4U) /*!< Bit position for FTFA_FCNFG_ERSSUSP. */ #define BM_FTFA_FCNFG_ERSSUSP (0x10U) /*!< Bit mask for FTFA_FCNFG_ERSSUSP. */ #define BS_FTFA_FCNFG_ERSSUSP (1U) /*!< Bit field size in bits for FTFA_FCNFG_ERSSUSP. */ /*! @brief Read current value of the FTFA_FCNFG_ERSSUSP field. */ #define BR_FTFA_FCNFG_ERSSUSP(x) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_ERSSUSP)) /*! @brief Format value for bitfield FTFA_FCNFG_ERSSUSP. */ #define BF_FTFA_FCNFG_ERSSUSP(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCNFG_ERSSUSP) & BM_FTFA_FCNFG_ERSSUSP) /*! @brief Set the ERSSUSP field to a new value. */ #define BW_FTFA_FCNFG_ERSSUSP(x, v) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_ERSSUSP) = (v)) /*@}*/ /*! * @name Register FTFA_FCNFG, field ERSAREQ[5] (RO) * * Issues a request to the memory controller to execute the Erase All Blocks * command and release security. ERSAREQ is not directly writable but is under * indirect user control. Refer to the device's Chip Configuration details on how to * request this command. ERSAREQ sets when an erase all request is triggered * external to the flash memory module and CCIF is set (no command is currently being * executed). ERSAREQ is cleared by the flash memory module when the operation * completes. * * Values: * - 0 - No request or request complete * - 1 - Request to: run the Erase All Blocks command, verify the erased state, * program the security byte in the Flash Configuration Field to the unsecure * state, and release MCU security by setting the FSEC[SEC] field to the * unsecure state. */ /*@{*/ #define BP_FTFA_FCNFG_ERSAREQ (5U) /*!< Bit position for FTFA_FCNFG_ERSAREQ. */ #define BM_FTFA_FCNFG_ERSAREQ (0x20U) /*!< Bit mask for FTFA_FCNFG_ERSAREQ. */ #define BS_FTFA_FCNFG_ERSAREQ (1U) /*!< Bit field size in bits for FTFA_FCNFG_ERSAREQ. */ /*! @brief Read current value of the FTFA_FCNFG_ERSAREQ field. */ #define BR_FTFA_FCNFG_ERSAREQ(x) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_ERSAREQ)) /*@}*/ /*! * @name Register FTFA_FCNFG, field RDCOLLIE[6] (RW) * * Controls interrupt generation when a flash memory read collision error occurs. * * Values: * - 0 - Read collision error interrupt disabled * - 1 - Read collision error interrupt enabled. An interrupt request is * generated whenever a flash memory read collision error is detected (see the * description of FSTAT[RDCOLERR]). */ /*@{*/ #define BP_FTFA_FCNFG_RDCOLLIE (6U) /*!< Bit position for FTFA_FCNFG_RDCOLLIE. */ #define BM_FTFA_FCNFG_RDCOLLIE (0x40U) /*!< Bit mask for FTFA_FCNFG_RDCOLLIE. */ #define BS_FTFA_FCNFG_RDCOLLIE (1U) /*!< Bit field size in bits for FTFA_FCNFG_RDCOLLIE. */ /*! @brief Read current value of the FTFA_FCNFG_RDCOLLIE field. */ #define BR_FTFA_FCNFG_RDCOLLIE(x) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_RDCOLLIE)) /*! @brief Format value for bitfield FTFA_FCNFG_RDCOLLIE. */ #define BF_FTFA_FCNFG_RDCOLLIE(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCNFG_RDCOLLIE) & BM_FTFA_FCNFG_RDCOLLIE) /*! @brief Set the RDCOLLIE field to a new value. */ #define BW_FTFA_FCNFG_RDCOLLIE(x, v) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_RDCOLLIE) = (v)) /*@}*/ /*! * @name Register FTFA_FCNFG, field CCIE[7] (RW) * * Controls interrupt generation when a flash command completes. * * Values: * - 0 - Command complete interrupt disabled * - 1 - Command complete interrupt enabled. An interrupt request is generated * whenever the FSTAT[CCIF] flag is set. */ /*@{*/ #define BP_FTFA_FCNFG_CCIE (7U) /*!< Bit position for FTFA_FCNFG_CCIE. */ #define BM_FTFA_FCNFG_CCIE (0x80U) /*!< Bit mask for FTFA_FCNFG_CCIE. */ #define BS_FTFA_FCNFG_CCIE (1U) /*!< Bit field size in bits for FTFA_FCNFG_CCIE. */ /*! @brief Read current value of the FTFA_FCNFG_CCIE field. */ #define BR_FTFA_FCNFG_CCIE(x) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_CCIE)) /*! @brief Format value for bitfield FTFA_FCNFG_CCIE. */ #define BF_FTFA_FCNFG_CCIE(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCNFG_CCIE) & BM_FTFA_FCNFG_CCIE) /*! @brief Set the CCIE field to a new value. */ #define BW_FTFA_FCNFG_CCIE(x, v) (BITBAND_ACCESS8(HW_FTFA_FCNFG_ADDR(x), BP_FTFA_FCNFG_CCIE) = (v)) /*@}*/ /******************************************************************************* * HW_FTFA_FSEC - Flash Security Register ******************************************************************************/ /*! * @brief HW_FTFA_FSEC - Flash Security Register (RO) * * Reset value: 0x00U * * This read-only register holds all bits associated with the security of the * MCU and flash memory module. During the reset sequence, the register is loaded * with the contents of the flash security byte in the Flash Configuration Field * located in program flash memory. The flash basis for the values is signified by * X in the reset value. */ typedef union _hw_ftfa_fsec { uint8_t U; struct _hw_ftfa_fsec_bitfields { uint8_t SEC : 2; /*!< [1:0] Flash Security */ uint8_t FSLACC : 2; /*!< [3:2] Freescale Failure Analysis Access Code * */ uint8_t MEEN : 2; /*!< [5:4] Mass Erase Enable Bits */ uint8_t KEYEN : 2; /*!< [7:6] Backdoor Key Security Enable */ } B; } hw_ftfa_fsec_t; /*! * @name Constants and macros for entire FTFA_FSEC register */ /*@{*/ #define HW_FTFA_FSEC_ADDR(x) ((x) + 0x2U) #define HW_FTFA_FSEC(x) (*(__I hw_ftfa_fsec_t *) HW_FTFA_FSEC_ADDR(x)) #define HW_FTFA_FSEC_RD(x) (HW_FTFA_FSEC(x).U) /*@}*/ /* * Constants & macros for individual FTFA_FSEC bitfields */ /*! * @name Register FTFA_FSEC, field SEC[1:0] (RO) * * Defines the security state of the MCU. In the secure state, the MCU limits * access to flash memory module resources. The limitations are defined per device * and are detailed in the Chip Configuration details. If the flash memory module * is unsecured using backdoor key access, SEC is forced to 10b. * * Values: * - 00 - MCU security status is secure. * - 01 - MCU security status is secure. * - 10 - MCU security status is unsecure. (The standard shipping condition of * the flash memory module is unsecure.) * - 11 - MCU security status is secure. */ /*@{*/ #define BP_FTFA_FSEC_SEC (0U) /*!< Bit position for FTFA_FSEC_SEC. */ #define BM_FTFA_FSEC_SEC (0x03U) /*!< Bit mask for FTFA_FSEC_SEC. */ #define BS_FTFA_FSEC_SEC (2U) /*!< Bit field size in bits for FTFA_FSEC_SEC. */ /*! @brief Read current value of the FTFA_FSEC_SEC field. */ #define BR_FTFA_FSEC_SEC(x) (HW_FTFA_FSEC(x).B.SEC) /*@}*/ /*! * @name Register FTFA_FSEC, field FSLACC[3:2] (RO) * * Enables or disables access to the flash memory contents during returned part * failure analysis at Freescale. When SEC is secure and FSLACC is denied, access * to the program flash contents is denied and any failure analysis performed by * Freescale factory test must begin with a full erase to unsecure the part. * When access is granted (SEC is unsecure, or SEC is secure and FSLACC is granted), * Freescale factory testing has visibility of the current flash contents. The * state of the FSLACC bits is only relevant when SEC is set to secure. When SEC * is set to unsecure, the FSLACC setting does not matter. * * Values: * - 00 - Freescale factory access granted * - 01 - Freescale factory access denied * - 10 - Freescale factory access denied * - 11 - Freescale factory access granted */ /*@{*/ #define BP_FTFA_FSEC_FSLACC (2U) /*!< Bit position for FTFA_FSEC_FSLACC. */ #define BM_FTFA_FSEC_FSLACC (0x0CU) /*!< Bit mask for FTFA_FSEC_FSLACC. */ #define BS_FTFA_FSEC_FSLACC (2U) /*!< Bit field size in bits for FTFA_FSEC_FSLACC. */ /*! @brief Read current value of the FTFA_FSEC_FSLACC field. */ #define BR_FTFA_FSEC_FSLACC(x) (HW_FTFA_FSEC(x).B.FSLACC) /*@}*/ /*! * @name Register FTFA_FSEC, field MEEN[5:4] (RO) * * Enables and disables mass erase capability of the flash memory module. The * state of this field is relevant only when SEC is set to secure outside of NVM * Normal Mode. When SEC is set to unsecure, the MEEN setting does not matter. * * Values: * - 00 - Mass erase is enabled * - 01 - Mass erase is enabled * - 10 - Mass erase is disabled * - 11 - Mass erase is enabled */ /*@{*/ #define BP_FTFA_FSEC_MEEN (4U) /*!< Bit position for FTFA_FSEC_MEEN. */ #define BM_FTFA_FSEC_MEEN (0x30U) /*!< Bit mask for FTFA_FSEC_MEEN. */ #define BS_FTFA_FSEC_MEEN (2U) /*!< Bit field size in bits for FTFA_FSEC_MEEN. */ /*! @brief Read current value of the FTFA_FSEC_MEEN field. */ #define BR_FTFA_FSEC_MEEN(x) (HW_FTFA_FSEC(x).B.MEEN) /*@}*/ /*! * @name Register FTFA_FSEC, field KEYEN[7:6] (RO) * * Enables or disables backdoor key access to the flash memory module. * * Values: * - 00 - Backdoor key access disabled * - 01 - Backdoor key access disabled (preferred KEYEN state to disable * backdoor key access) * - 10 - Backdoor key access enabled * - 11 - Backdoor key access disabled */ /*@{*/ #define BP_FTFA_FSEC_KEYEN (6U) /*!< Bit position for FTFA_FSEC_KEYEN. */ #define BM_FTFA_FSEC_KEYEN (0xC0U) /*!< Bit mask for FTFA_FSEC_KEYEN. */ #define BS_FTFA_FSEC_KEYEN (2U) /*!< Bit field size in bits for FTFA_FSEC_KEYEN. */ /*! @brief Read current value of the FTFA_FSEC_KEYEN field. */ #define BR_FTFA_FSEC_KEYEN(x) (HW_FTFA_FSEC(x).B.KEYEN) /*@}*/ /******************************************************************************* * HW_FTFA_FOPT - Flash Option Register ******************************************************************************/ /*! * @brief HW_FTFA_FOPT - Flash Option Register (RO) * * Reset value: 0x00U * * The flash option register allows the MCU to customize its operations by * examining the state of these read-only bits, which are loaded from NVM at reset. * The function of the bits is defined in the device's Chip Configuration details. * All bits in the register are read-only . During the reset sequence, the * register is loaded from the flash nonvolatile option byte in the Flash Configuration * Field located in program flash memory. The flash basis for the values is * signified by X in the reset value. However, the register is written to 0xFF if the * contents of the flash nonvolatile option byte are 0x00. */ typedef union _hw_ftfa_fopt { uint8_t U; struct _hw_ftfa_fopt_bitfields { uint8_t OPT : 8; /*!< [7:0] Nonvolatile Option */ } B; } hw_ftfa_fopt_t; /*! * @name Constants and macros for entire FTFA_FOPT register */ /*@{*/ #define HW_FTFA_FOPT_ADDR(x) ((x) + 0x3U) #define HW_FTFA_FOPT(x) (*(__I hw_ftfa_fopt_t *) HW_FTFA_FOPT_ADDR(x)) #define HW_FTFA_FOPT_RD(x) (HW_FTFA_FOPT(x).U) /*@}*/ /* * Constants & macros for individual FTFA_FOPT bitfields */ /*! * @name Register FTFA_FOPT, field OPT[7:0] (RO) * * These bits are loaded from flash to this register at reset. Refer to the * device's Chip Configuration details for the definition and use of these bits. */ /*@{*/ #define BP_FTFA_FOPT_OPT (0U) /*!< Bit position for FTFA_FOPT_OPT. */ #define BM_FTFA_FOPT_OPT (0xFFU) /*!< Bit mask for FTFA_FOPT_OPT. */ #define BS_FTFA_FOPT_OPT (8U) /*!< Bit field size in bits for FTFA_FOPT_OPT. */ /*! @brief Read current value of the FTFA_FOPT_OPT field. */ #define BR_FTFA_FOPT_OPT(x) (HW_FTFA_FOPT(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB3 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB3 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob3 { uint8_t U; struct _hw_ftfa_fccob3_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob3_t; /*! * @name Constants and macros for entire FTFA_FCCOB3 register */ /*@{*/ #define HW_FTFA_FCCOB3_ADDR(x) ((x) + 0x4U) #define HW_FTFA_FCCOB3(x) (*(__IO hw_ftfa_fccob3_t *) HW_FTFA_FCCOB3_ADDR(x)) #define HW_FTFA_FCCOB3_RD(x) (HW_FTFA_FCCOB3(x).U) #define HW_FTFA_FCCOB3_WR(x, v) (HW_FTFA_FCCOB3(x).U = (v)) #define HW_FTFA_FCCOB3_SET(x, v) (HW_FTFA_FCCOB3_WR(x, HW_FTFA_FCCOB3_RD(x) | (v))) #define HW_FTFA_FCCOB3_CLR(x, v) (HW_FTFA_FCCOB3_WR(x, HW_FTFA_FCCOB3_RD(x) & ~(v))) #define HW_FTFA_FCCOB3_TOG(x, v) (HW_FTFA_FCCOB3_WR(x, HW_FTFA_FCCOB3_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB3 bitfields */ /*! * @name Register FTFA_FCCOB3, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB3_CCOBn (0U) /*!< Bit position for FTFA_FCCOB3_CCOBn. */ #define BM_FTFA_FCCOB3_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB3_CCOBn. */ #define BS_FTFA_FCCOB3_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB3_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB3_CCOBn field. */ #define BR_FTFA_FCCOB3_CCOBn(x) (HW_FTFA_FCCOB3(x).U) /*! @brief Format value for bitfield FTFA_FCCOB3_CCOBn. */ #define BF_FTFA_FCCOB3_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB3_CCOBn) & BM_FTFA_FCCOB3_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB3_CCOBn(x, v) (HW_FTFA_FCCOB3_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB2 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB2 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob2 { uint8_t U; struct _hw_ftfa_fccob2_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob2_t; /*! * @name Constants and macros for entire FTFA_FCCOB2 register */ /*@{*/ #define HW_FTFA_FCCOB2_ADDR(x) ((x) + 0x5U) #define HW_FTFA_FCCOB2(x) (*(__IO hw_ftfa_fccob2_t *) HW_FTFA_FCCOB2_ADDR(x)) #define HW_FTFA_FCCOB2_RD(x) (HW_FTFA_FCCOB2(x).U) #define HW_FTFA_FCCOB2_WR(x, v) (HW_FTFA_FCCOB2(x).U = (v)) #define HW_FTFA_FCCOB2_SET(x, v) (HW_FTFA_FCCOB2_WR(x, HW_FTFA_FCCOB2_RD(x) | (v))) #define HW_FTFA_FCCOB2_CLR(x, v) (HW_FTFA_FCCOB2_WR(x, HW_FTFA_FCCOB2_RD(x) & ~(v))) #define HW_FTFA_FCCOB2_TOG(x, v) (HW_FTFA_FCCOB2_WR(x, HW_FTFA_FCCOB2_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB2 bitfields */ /*! * @name Register FTFA_FCCOB2, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB2_CCOBn (0U) /*!< Bit position for FTFA_FCCOB2_CCOBn. */ #define BM_FTFA_FCCOB2_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB2_CCOBn. */ #define BS_FTFA_FCCOB2_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB2_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB2_CCOBn field. */ #define BR_FTFA_FCCOB2_CCOBn(x) (HW_FTFA_FCCOB2(x).U) /*! @brief Format value for bitfield FTFA_FCCOB2_CCOBn. */ #define BF_FTFA_FCCOB2_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB2_CCOBn) & BM_FTFA_FCCOB2_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB2_CCOBn(x, v) (HW_FTFA_FCCOB2_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB1 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB1 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob1 { uint8_t U; struct _hw_ftfa_fccob1_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob1_t; /*! * @name Constants and macros for entire FTFA_FCCOB1 register */ /*@{*/ #define HW_FTFA_FCCOB1_ADDR(x) ((x) + 0x6U) #define HW_FTFA_FCCOB1(x) (*(__IO hw_ftfa_fccob1_t *) HW_FTFA_FCCOB1_ADDR(x)) #define HW_FTFA_FCCOB1_RD(x) (HW_FTFA_FCCOB1(x).U) #define HW_FTFA_FCCOB1_WR(x, v) (HW_FTFA_FCCOB1(x).U = (v)) #define HW_FTFA_FCCOB1_SET(x, v) (HW_FTFA_FCCOB1_WR(x, HW_FTFA_FCCOB1_RD(x) | (v))) #define HW_FTFA_FCCOB1_CLR(x, v) (HW_FTFA_FCCOB1_WR(x, HW_FTFA_FCCOB1_RD(x) & ~(v))) #define HW_FTFA_FCCOB1_TOG(x, v) (HW_FTFA_FCCOB1_WR(x, HW_FTFA_FCCOB1_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB1 bitfields */ /*! * @name Register FTFA_FCCOB1, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB1_CCOBn (0U) /*!< Bit position for FTFA_FCCOB1_CCOBn. */ #define BM_FTFA_FCCOB1_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB1_CCOBn. */ #define BS_FTFA_FCCOB1_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB1_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB1_CCOBn field. */ #define BR_FTFA_FCCOB1_CCOBn(x) (HW_FTFA_FCCOB1(x).U) /*! @brief Format value for bitfield FTFA_FCCOB1_CCOBn. */ #define BF_FTFA_FCCOB1_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB1_CCOBn) & BM_FTFA_FCCOB1_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB1_CCOBn(x, v) (HW_FTFA_FCCOB1_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB0 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB0 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob0 { uint8_t U; struct _hw_ftfa_fccob0_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob0_t; /*! * @name Constants and macros for entire FTFA_FCCOB0 register */ /*@{*/ #define HW_FTFA_FCCOB0_ADDR(x) ((x) + 0x7U) #define HW_FTFA_FCCOB0(x) (*(__IO hw_ftfa_fccob0_t *) HW_FTFA_FCCOB0_ADDR(x)) #define HW_FTFA_FCCOB0_RD(x) (HW_FTFA_FCCOB0(x).U) #define HW_FTFA_FCCOB0_WR(x, v) (HW_FTFA_FCCOB0(x).U = (v)) #define HW_FTFA_FCCOB0_SET(x, v) (HW_FTFA_FCCOB0_WR(x, HW_FTFA_FCCOB0_RD(x) | (v))) #define HW_FTFA_FCCOB0_CLR(x, v) (HW_FTFA_FCCOB0_WR(x, HW_FTFA_FCCOB0_RD(x) & ~(v))) #define HW_FTFA_FCCOB0_TOG(x, v) (HW_FTFA_FCCOB0_WR(x, HW_FTFA_FCCOB0_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB0 bitfields */ /*! * @name Register FTFA_FCCOB0, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB0_CCOBn (0U) /*!< Bit position for FTFA_FCCOB0_CCOBn. */ #define BM_FTFA_FCCOB0_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB0_CCOBn. */ #define BS_FTFA_FCCOB0_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB0_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB0_CCOBn field. */ #define BR_FTFA_FCCOB0_CCOBn(x) (HW_FTFA_FCCOB0(x).U) /*! @brief Format value for bitfield FTFA_FCCOB0_CCOBn. */ #define BF_FTFA_FCCOB0_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB0_CCOBn) & BM_FTFA_FCCOB0_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB0_CCOBn(x, v) (HW_FTFA_FCCOB0_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB7 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB7 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob7 { uint8_t U; struct _hw_ftfa_fccob7_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob7_t; /*! * @name Constants and macros for entire FTFA_FCCOB7 register */ /*@{*/ #define HW_FTFA_FCCOB7_ADDR(x) ((x) + 0x8U) #define HW_FTFA_FCCOB7(x) (*(__IO hw_ftfa_fccob7_t *) HW_FTFA_FCCOB7_ADDR(x)) #define HW_FTFA_FCCOB7_RD(x) (HW_FTFA_FCCOB7(x).U) #define HW_FTFA_FCCOB7_WR(x, v) (HW_FTFA_FCCOB7(x).U = (v)) #define HW_FTFA_FCCOB7_SET(x, v) (HW_FTFA_FCCOB7_WR(x, HW_FTFA_FCCOB7_RD(x) | (v))) #define HW_FTFA_FCCOB7_CLR(x, v) (HW_FTFA_FCCOB7_WR(x, HW_FTFA_FCCOB7_RD(x) & ~(v))) #define HW_FTFA_FCCOB7_TOG(x, v) (HW_FTFA_FCCOB7_WR(x, HW_FTFA_FCCOB7_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB7 bitfields */ /*! * @name Register FTFA_FCCOB7, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB7_CCOBn (0U) /*!< Bit position for FTFA_FCCOB7_CCOBn. */ #define BM_FTFA_FCCOB7_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB7_CCOBn. */ #define BS_FTFA_FCCOB7_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB7_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB7_CCOBn field. */ #define BR_FTFA_FCCOB7_CCOBn(x) (HW_FTFA_FCCOB7(x).U) /*! @brief Format value for bitfield FTFA_FCCOB7_CCOBn. */ #define BF_FTFA_FCCOB7_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB7_CCOBn) & BM_FTFA_FCCOB7_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB7_CCOBn(x, v) (HW_FTFA_FCCOB7_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB6 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB6 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob6 { uint8_t U; struct _hw_ftfa_fccob6_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob6_t; /*! * @name Constants and macros for entire FTFA_FCCOB6 register */ /*@{*/ #define HW_FTFA_FCCOB6_ADDR(x) ((x) + 0x9U) #define HW_FTFA_FCCOB6(x) (*(__IO hw_ftfa_fccob6_t *) HW_FTFA_FCCOB6_ADDR(x)) #define HW_FTFA_FCCOB6_RD(x) (HW_FTFA_FCCOB6(x).U) #define HW_FTFA_FCCOB6_WR(x, v) (HW_FTFA_FCCOB6(x).U = (v)) #define HW_FTFA_FCCOB6_SET(x, v) (HW_FTFA_FCCOB6_WR(x, HW_FTFA_FCCOB6_RD(x) | (v))) #define HW_FTFA_FCCOB6_CLR(x, v) (HW_FTFA_FCCOB6_WR(x, HW_FTFA_FCCOB6_RD(x) & ~(v))) #define HW_FTFA_FCCOB6_TOG(x, v) (HW_FTFA_FCCOB6_WR(x, HW_FTFA_FCCOB6_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB6 bitfields */ /*! * @name Register FTFA_FCCOB6, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB6_CCOBn (0U) /*!< Bit position for FTFA_FCCOB6_CCOBn. */ #define BM_FTFA_FCCOB6_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB6_CCOBn. */ #define BS_FTFA_FCCOB6_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB6_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB6_CCOBn field. */ #define BR_FTFA_FCCOB6_CCOBn(x) (HW_FTFA_FCCOB6(x).U) /*! @brief Format value for bitfield FTFA_FCCOB6_CCOBn. */ #define BF_FTFA_FCCOB6_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB6_CCOBn) & BM_FTFA_FCCOB6_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB6_CCOBn(x, v) (HW_FTFA_FCCOB6_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB5 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB5 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob5 { uint8_t U; struct _hw_ftfa_fccob5_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob5_t; /*! * @name Constants and macros for entire FTFA_FCCOB5 register */ /*@{*/ #define HW_FTFA_FCCOB5_ADDR(x) ((x) + 0xAU) #define HW_FTFA_FCCOB5(x) (*(__IO hw_ftfa_fccob5_t *) HW_FTFA_FCCOB5_ADDR(x)) #define HW_FTFA_FCCOB5_RD(x) (HW_FTFA_FCCOB5(x).U) #define HW_FTFA_FCCOB5_WR(x, v) (HW_FTFA_FCCOB5(x).U = (v)) #define HW_FTFA_FCCOB5_SET(x, v) (HW_FTFA_FCCOB5_WR(x, HW_FTFA_FCCOB5_RD(x) | (v))) #define HW_FTFA_FCCOB5_CLR(x, v) (HW_FTFA_FCCOB5_WR(x, HW_FTFA_FCCOB5_RD(x) & ~(v))) #define HW_FTFA_FCCOB5_TOG(x, v) (HW_FTFA_FCCOB5_WR(x, HW_FTFA_FCCOB5_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB5 bitfields */ /*! * @name Register FTFA_FCCOB5, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB5_CCOBn (0U) /*!< Bit position for FTFA_FCCOB5_CCOBn. */ #define BM_FTFA_FCCOB5_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB5_CCOBn. */ #define BS_FTFA_FCCOB5_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB5_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB5_CCOBn field. */ #define BR_FTFA_FCCOB5_CCOBn(x) (HW_FTFA_FCCOB5(x).U) /*! @brief Format value for bitfield FTFA_FCCOB5_CCOBn. */ #define BF_FTFA_FCCOB5_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB5_CCOBn) & BM_FTFA_FCCOB5_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB5_CCOBn(x, v) (HW_FTFA_FCCOB5_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB4 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB4 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob4 { uint8_t U; struct _hw_ftfa_fccob4_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob4_t; /*! * @name Constants and macros for entire FTFA_FCCOB4 register */ /*@{*/ #define HW_FTFA_FCCOB4_ADDR(x) ((x) + 0xBU) #define HW_FTFA_FCCOB4(x) (*(__IO hw_ftfa_fccob4_t *) HW_FTFA_FCCOB4_ADDR(x)) #define HW_FTFA_FCCOB4_RD(x) (HW_FTFA_FCCOB4(x).U) #define HW_FTFA_FCCOB4_WR(x, v) (HW_FTFA_FCCOB4(x).U = (v)) #define HW_FTFA_FCCOB4_SET(x, v) (HW_FTFA_FCCOB4_WR(x, HW_FTFA_FCCOB4_RD(x) | (v))) #define HW_FTFA_FCCOB4_CLR(x, v) (HW_FTFA_FCCOB4_WR(x, HW_FTFA_FCCOB4_RD(x) & ~(v))) #define HW_FTFA_FCCOB4_TOG(x, v) (HW_FTFA_FCCOB4_WR(x, HW_FTFA_FCCOB4_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB4 bitfields */ /*! * @name Register FTFA_FCCOB4, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB4_CCOBn (0U) /*!< Bit position for FTFA_FCCOB4_CCOBn. */ #define BM_FTFA_FCCOB4_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB4_CCOBn. */ #define BS_FTFA_FCCOB4_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB4_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB4_CCOBn field. */ #define BR_FTFA_FCCOB4_CCOBn(x) (HW_FTFA_FCCOB4(x).U) /*! @brief Format value for bitfield FTFA_FCCOB4_CCOBn. */ #define BF_FTFA_FCCOB4_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB4_CCOBn) & BM_FTFA_FCCOB4_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB4_CCOBn(x, v) (HW_FTFA_FCCOB4_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOBB - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOBB - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccobb { uint8_t U; struct _hw_ftfa_fccobb_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccobb_t; /*! * @name Constants and macros for entire FTFA_FCCOBB register */ /*@{*/ #define HW_FTFA_FCCOBB_ADDR(x) ((x) + 0xCU) #define HW_FTFA_FCCOBB(x) (*(__IO hw_ftfa_fccobb_t *) HW_FTFA_FCCOBB_ADDR(x)) #define HW_FTFA_FCCOBB_RD(x) (HW_FTFA_FCCOBB(x).U) #define HW_FTFA_FCCOBB_WR(x, v) (HW_FTFA_FCCOBB(x).U = (v)) #define HW_FTFA_FCCOBB_SET(x, v) (HW_FTFA_FCCOBB_WR(x, HW_FTFA_FCCOBB_RD(x) | (v))) #define HW_FTFA_FCCOBB_CLR(x, v) (HW_FTFA_FCCOBB_WR(x, HW_FTFA_FCCOBB_RD(x) & ~(v))) #define HW_FTFA_FCCOBB_TOG(x, v) (HW_FTFA_FCCOBB_WR(x, HW_FTFA_FCCOBB_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOBB bitfields */ /*! * @name Register FTFA_FCCOBB, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOBB_CCOBn (0U) /*!< Bit position for FTFA_FCCOBB_CCOBn. */ #define BM_FTFA_FCCOBB_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOBB_CCOBn. */ #define BS_FTFA_FCCOBB_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOBB_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOBB_CCOBn field. */ #define BR_FTFA_FCCOBB_CCOBn(x) (HW_FTFA_FCCOBB(x).U) /*! @brief Format value for bitfield FTFA_FCCOBB_CCOBn. */ #define BF_FTFA_FCCOBB_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOBB_CCOBn) & BM_FTFA_FCCOBB_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOBB_CCOBn(x, v) (HW_FTFA_FCCOBB_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOBA - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOBA - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccoba { uint8_t U; struct _hw_ftfa_fccoba_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccoba_t; /*! * @name Constants and macros for entire FTFA_FCCOBA register */ /*@{*/ #define HW_FTFA_FCCOBA_ADDR(x) ((x) + 0xDU) #define HW_FTFA_FCCOBA(x) (*(__IO hw_ftfa_fccoba_t *) HW_FTFA_FCCOBA_ADDR(x)) #define HW_FTFA_FCCOBA_RD(x) (HW_FTFA_FCCOBA(x).U) #define HW_FTFA_FCCOBA_WR(x, v) (HW_FTFA_FCCOBA(x).U = (v)) #define HW_FTFA_FCCOBA_SET(x, v) (HW_FTFA_FCCOBA_WR(x, HW_FTFA_FCCOBA_RD(x) | (v))) #define HW_FTFA_FCCOBA_CLR(x, v) (HW_FTFA_FCCOBA_WR(x, HW_FTFA_FCCOBA_RD(x) & ~(v))) #define HW_FTFA_FCCOBA_TOG(x, v) (HW_FTFA_FCCOBA_WR(x, HW_FTFA_FCCOBA_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOBA bitfields */ /*! * @name Register FTFA_FCCOBA, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOBA_CCOBn (0U) /*!< Bit position for FTFA_FCCOBA_CCOBn. */ #define BM_FTFA_FCCOBA_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOBA_CCOBn. */ #define BS_FTFA_FCCOBA_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOBA_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOBA_CCOBn field. */ #define BR_FTFA_FCCOBA_CCOBn(x) (HW_FTFA_FCCOBA(x).U) /*! @brief Format value for bitfield FTFA_FCCOBA_CCOBn. */ #define BF_FTFA_FCCOBA_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOBA_CCOBn) & BM_FTFA_FCCOBA_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOBA_CCOBn(x, v) (HW_FTFA_FCCOBA_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB9 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB9 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob9 { uint8_t U; struct _hw_ftfa_fccob9_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob9_t; /*! * @name Constants and macros for entire FTFA_FCCOB9 register */ /*@{*/ #define HW_FTFA_FCCOB9_ADDR(x) ((x) + 0xEU) #define HW_FTFA_FCCOB9(x) (*(__IO hw_ftfa_fccob9_t *) HW_FTFA_FCCOB9_ADDR(x)) #define HW_FTFA_FCCOB9_RD(x) (HW_FTFA_FCCOB9(x).U) #define HW_FTFA_FCCOB9_WR(x, v) (HW_FTFA_FCCOB9(x).U = (v)) #define HW_FTFA_FCCOB9_SET(x, v) (HW_FTFA_FCCOB9_WR(x, HW_FTFA_FCCOB9_RD(x) | (v))) #define HW_FTFA_FCCOB9_CLR(x, v) (HW_FTFA_FCCOB9_WR(x, HW_FTFA_FCCOB9_RD(x) & ~(v))) #define HW_FTFA_FCCOB9_TOG(x, v) (HW_FTFA_FCCOB9_WR(x, HW_FTFA_FCCOB9_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB9 bitfields */ /*! * @name Register FTFA_FCCOB9, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB9_CCOBn (0U) /*!< Bit position for FTFA_FCCOB9_CCOBn. */ #define BM_FTFA_FCCOB9_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB9_CCOBn. */ #define BS_FTFA_FCCOB9_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB9_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB9_CCOBn field. */ #define BR_FTFA_FCCOB9_CCOBn(x) (HW_FTFA_FCCOB9(x).U) /*! @brief Format value for bitfield FTFA_FCCOB9_CCOBn. */ #define BF_FTFA_FCCOB9_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB9_CCOBn) & BM_FTFA_FCCOB9_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB9_CCOBn(x, v) (HW_FTFA_FCCOB9_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FCCOB8 - Flash Common Command Object Registers ******************************************************************************/ /*! * @brief HW_FTFA_FCCOB8 - Flash Common Command Object Registers (RW) * * Reset value: 0x00U * * The FCCOB register group provides 12 bytes for command codes and parameters. * The individual bytes within the set append a 0-B hex identifier to the FCCOB * register name: FCCOB0, FCCOB1, ..., FCCOBB. */ typedef union _hw_ftfa_fccob8 { uint8_t U; struct _hw_ftfa_fccob8_bitfields { uint8_t CCOBn : 8; /*!< [7:0] */ } B; } hw_ftfa_fccob8_t; /*! * @name Constants and macros for entire FTFA_FCCOB8 register */ /*@{*/ #define HW_FTFA_FCCOB8_ADDR(x) ((x) + 0xFU) #define HW_FTFA_FCCOB8(x) (*(__IO hw_ftfa_fccob8_t *) HW_FTFA_FCCOB8_ADDR(x)) #define HW_FTFA_FCCOB8_RD(x) (HW_FTFA_FCCOB8(x).U) #define HW_FTFA_FCCOB8_WR(x, v) (HW_FTFA_FCCOB8(x).U = (v)) #define HW_FTFA_FCCOB8_SET(x, v) (HW_FTFA_FCCOB8_WR(x, HW_FTFA_FCCOB8_RD(x) | (v))) #define HW_FTFA_FCCOB8_CLR(x, v) (HW_FTFA_FCCOB8_WR(x, HW_FTFA_FCCOB8_RD(x) & ~(v))) #define HW_FTFA_FCCOB8_TOG(x, v) (HW_FTFA_FCCOB8_WR(x, HW_FTFA_FCCOB8_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FCCOB8 bitfields */ /*! * @name Register FTFA_FCCOB8, field CCOBn[7:0] (RW) * * The FCCOB register provides a command code and relevant parameters to the * memory controller. The individual registers that compose the FCCOB data set can * be written in any order, but you must provide all needed values, which vary * from command to command. First, set up all required FCCOB fields and then * initiate the command's execution by writing a 1 to the FSTAT[CCIF] bit. This clears * the CCIF bit, which locks all FCCOB parameter fields and they cannot be changed * by the user until the command completes (CCIF returns to 1). No command * buffering or queueing is provided; the next command can be loaded only after the * current command completes. Some commands return information to the FCCOB * registers. Any values returned to FCCOB are available for reading after the * FSTAT[CCIF] flag returns to 1 by the memory controller. The following table shows a * generic flash command format. The first FCCOB register, FCCOB0, always contains * the command code. This 8-bit value defines the command to be executed. The * command code is followed by the parameters required for this specific flash * command, typically an address and/or data values. The command parameter table is * written in terms of FCCOB Number (which is equivalent to the byte number). This * number is a reference to the FCCOB register name and is not the register * address. FCCOB Number Typical Command Parameter Contents [7:0] 0 FCMD (a code that * defines the flash command) 1 Flash address [23:16] 2 Flash address [15:8] 3 * Flash address [7:0] 4 Data Byte 0 5 Data Byte 1 6 Data Byte 2 7 Data Byte 3 8 * Data Byte 4 9 Data Byte 5 A Data Byte 6 B Data Byte 7 FCCOB Endianness : The * FCCOB register group uses a big endian addressing convention. For all command * parameter fields larger than 1 byte, the most significant data resides in the * lowest FCCOB register number. */ /*@{*/ #define BP_FTFA_FCCOB8_CCOBn (0U) /*!< Bit position for FTFA_FCCOB8_CCOBn. */ #define BM_FTFA_FCCOB8_CCOBn (0xFFU) /*!< Bit mask for FTFA_FCCOB8_CCOBn. */ #define BS_FTFA_FCCOB8_CCOBn (8U) /*!< Bit field size in bits for FTFA_FCCOB8_CCOBn. */ /*! @brief Read current value of the FTFA_FCCOB8_CCOBn field. */ #define BR_FTFA_FCCOB8_CCOBn(x) (HW_FTFA_FCCOB8(x).U) /*! @brief Format value for bitfield FTFA_FCCOB8_CCOBn. */ #define BF_FTFA_FCCOB8_CCOBn(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FCCOB8_CCOBn) & BM_FTFA_FCCOB8_CCOBn) /*! @brief Set the CCOBn field to a new value. */ #define BW_FTFA_FCCOB8_CCOBn(x, v) (HW_FTFA_FCCOB8_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FPROT3 - Program Flash Protection Registers ******************************************************************************/ /*! * @brief HW_FTFA_FPROT3 - Program Flash Protection Registers (RW) * * Reset value: 0x00U * * The FPROT registers define which logical program flash regions are protected * from program and erase operations. Protected flash regions cannot have their * content changed; that is, these regions cannot be programmed and cannot be * erased by any flash command. Unprotected regions can be changed by program and * erase operations. The four FPROT registers allow up to 32 protectable regions. * Each bit protects a 1/32 region of the program flash memory except for memory * configurations with less than 32 KB of program flash where each assigned bit * protects 1 KB . For configurations with 24 KB of program flash memory or less, * FPROT0 is not used. For configurations with 16 KB of program flash memory or * less, FPROT1 is not used. For configurations with 8 KB of program flash memory, * FPROT2 is not used. The bitfields are defined in each register as follows: * Program flash protection register Program flash protection bits FPROT0 PROT[31:24] * FPROT1 PROT[23:16] FPROT2 PROT[15:8] FPROT3 PROT[7:0] During the reset * sequence, the FPROT registers are loaded with the contents of the program flash * protection bytes in the Flash Configuration Field as indicated in the following * table. Program flash protection register Flash Configuration Field offset * address FPROT0 0x000B FPROT1 0x000A FPROT2 0x0009 FPROT3 0x0008 To change the * program flash protection that is loaded during the reset sequence, unprotect the * sector of program flash memory that contains the Flash Configuration Field. Then, * reprogram the program flash protection byte. */ typedef union _hw_ftfa_fprot3 { uint8_t U; struct _hw_ftfa_fprot3_bitfields { uint8_t PROT : 8; /*!< [7:0] Program Flash Region Protect */ } B; } hw_ftfa_fprot3_t; /*! * @name Constants and macros for entire FTFA_FPROT3 register */ /*@{*/ #define HW_FTFA_FPROT3_ADDR(x) ((x) + 0x10U) #define HW_FTFA_FPROT3(x) (*(__IO hw_ftfa_fprot3_t *) HW_FTFA_FPROT3_ADDR(x)) #define HW_FTFA_FPROT3_RD(x) (HW_FTFA_FPROT3(x).U) #define HW_FTFA_FPROT3_WR(x, v) (HW_FTFA_FPROT3(x).U = (v)) #define HW_FTFA_FPROT3_SET(x, v) (HW_FTFA_FPROT3_WR(x, HW_FTFA_FPROT3_RD(x) | (v))) #define HW_FTFA_FPROT3_CLR(x, v) (HW_FTFA_FPROT3_WR(x, HW_FTFA_FPROT3_RD(x) & ~(v))) #define HW_FTFA_FPROT3_TOG(x, v) (HW_FTFA_FPROT3_WR(x, HW_FTFA_FPROT3_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FPROT3 bitfields */ /*! * @name Register FTFA_FPROT3, field PROT[7:0] (RW) * * Each program flash region can be protected from program and erase operations * by setting the associated PROT bit. In NVM Normal mode: The protection can * only be increased, meaning that currently unprotected memory can be protected, * but currently protected memory cannot be unprotected. Since unprotected regions * are marked with a 1 and protected regions use a 0, only writes changing 1s to * 0s are accepted. This 1-to-0 transition check is performed on a bit-by-bit * basis. Those FPROT bits with 1-to-0 transitions are accepted while all bits with * 0-to-1 transitions are ignored. In NVM Special mode: All bits of FPROT are * writable without restriction. Unprotected areas can be protected and protected * areas can be unprotected. The user must never write to any FPROT register while * a command is running (CCIF=0). Trying to alter data in any protected area in * the program flash memory results in a protection violation error and sets the * FSTAT[FPVIOL] bit. A full block erase of a program flash block is not possible * if it contains any protected region. Each bit in the 32-bit protection * register represents 1/32 of the total program flash except for configurations where * program flash memory is less than 32 KB. For configurations with less than 32 * KB of program flash memory, each assigned bit represents 1 KB. * * Values: * - 0 - Program flash region is protected. * - 1 - Program flash region is not protected */ /*@{*/ #define BP_FTFA_FPROT3_PROT (0U) /*!< Bit position for FTFA_FPROT3_PROT. */ #define BM_FTFA_FPROT3_PROT (0xFFU) /*!< Bit mask for FTFA_FPROT3_PROT. */ #define BS_FTFA_FPROT3_PROT (8U) /*!< Bit field size in bits for FTFA_FPROT3_PROT. */ /*! @brief Read current value of the FTFA_FPROT3_PROT field. */ #define BR_FTFA_FPROT3_PROT(x) (HW_FTFA_FPROT3(x).U) /*! @brief Format value for bitfield FTFA_FPROT3_PROT. */ #define BF_FTFA_FPROT3_PROT(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FPROT3_PROT) & BM_FTFA_FPROT3_PROT) /*! @brief Set the PROT field to a new value. */ #define BW_FTFA_FPROT3_PROT(x, v) (HW_FTFA_FPROT3_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FPROT2 - Program Flash Protection Registers ******************************************************************************/ /*! * @brief HW_FTFA_FPROT2 - Program Flash Protection Registers (RW) * * Reset value: 0x00U * * The FPROT registers define which logical program flash regions are protected * from program and erase operations. Protected flash regions cannot have their * content changed; that is, these regions cannot be programmed and cannot be * erased by any flash command. Unprotected regions can be changed by program and * erase operations. The four FPROT registers allow up to 32 protectable regions. * Each bit protects a 1/32 region of the program flash memory except for memory * configurations with less than 32 KB of program flash where each assigned bit * protects 1 KB . For configurations with 24 KB of program flash memory or less, * FPROT0 is not used. For configurations with 16 KB of program flash memory or * less, FPROT1 is not used. For configurations with 8 KB of program flash memory, * FPROT2 is not used. The bitfields are defined in each register as follows: * Program flash protection register Program flash protection bits FPROT0 PROT[31:24] * FPROT1 PROT[23:16] FPROT2 PROT[15:8] FPROT3 PROT[7:0] During the reset * sequence, the FPROT registers are loaded with the contents of the program flash * protection bytes in the Flash Configuration Field as indicated in the following * table. Program flash protection register Flash Configuration Field offset * address FPROT0 0x000B FPROT1 0x000A FPROT2 0x0009 FPROT3 0x0008 To change the * program flash protection that is loaded during the reset sequence, unprotect the * sector of program flash memory that contains the Flash Configuration Field. Then, * reprogram the program flash protection byte. */ typedef union _hw_ftfa_fprot2 { uint8_t U; struct _hw_ftfa_fprot2_bitfields { uint8_t PROT : 8; /*!< [7:0] Program Flash Region Protect */ } B; } hw_ftfa_fprot2_t; /*! * @name Constants and macros for entire FTFA_FPROT2 register */ /*@{*/ #define HW_FTFA_FPROT2_ADDR(x) ((x) + 0x11U) #define HW_FTFA_FPROT2(x) (*(__IO hw_ftfa_fprot2_t *) HW_FTFA_FPROT2_ADDR(x)) #define HW_FTFA_FPROT2_RD(x) (HW_FTFA_FPROT2(x).U) #define HW_FTFA_FPROT2_WR(x, v) (HW_FTFA_FPROT2(x).U = (v)) #define HW_FTFA_FPROT2_SET(x, v) (HW_FTFA_FPROT2_WR(x, HW_FTFA_FPROT2_RD(x) | (v))) #define HW_FTFA_FPROT2_CLR(x, v) (HW_FTFA_FPROT2_WR(x, HW_FTFA_FPROT2_RD(x) & ~(v))) #define HW_FTFA_FPROT2_TOG(x, v) (HW_FTFA_FPROT2_WR(x, HW_FTFA_FPROT2_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FPROT2 bitfields */ /*! * @name Register FTFA_FPROT2, field PROT[7:0] (RW) * * Each program flash region can be protected from program and erase operations * by setting the associated PROT bit. In NVM Normal mode: The protection can * only be increased, meaning that currently unprotected memory can be protected, * but currently protected memory cannot be unprotected. Since unprotected regions * are marked with a 1 and protected regions use a 0, only writes changing 1s to * 0s are accepted. This 1-to-0 transition check is performed on a bit-by-bit * basis. Those FPROT bits with 1-to-0 transitions are accepted while all bits with * 0-to-1 transitions are ignored. In NVM Special mode: All bits of FPROT are * writable without restriction. Unprotected areas can be protected and protected * areas can be unprotected. The user must never write to any FPROT register while * a command is running (CCIF=0). Trying to alter data in any protected area in * the program flash memory results in a protection violation error and sets the * FSTAT[FPVIOL] bit. A full block erase of a program flash block is not possible * if it contains any protected region. Each bit in the 32-bit protection * register represents 1/32 of the total program flash except for configurations where * program flash memory is less than 32 KB. For configurations with less than 32 * KB of program flash memory, each assigned bit represents 1 KB. * * Values: * - 0 - Program flash region is protected. * - 1 - Program flash region is not protected */ /*@{*/ #define BP_FTFA_FPROT2_PROT (0U) /*!< Bit position for FTFA_FPROT2_PROT. */ #define BM_FTFA_FPROT2_PROT (0xFFU) /*!< Bit mask for FTFA_FPROT2_PROT. */ #define BS_FTFA_FPROT2_PROT (8U) /*!< Bit field size in bits for FTFA_FPROT2_PROT. */ /*! @brief Read current value of the FTFA_FPROT2_PROT field. */ #define BR_FTFA_FPROT2_PROT(x) (HW_FTFA_FPROT2(x).U) /*! @brief Format value for bitfield FTFA_FPROT2_PROT. */ #define BF_FTFA_FPROT2_PROT(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FPROT2_PROT) & BM_FTFA_FPROT2_PROT) /*! @brief Set the PROT field to a new value. */ #define BW_FTFA_FPROT2_PROT(x, v) (HW_FTFA_FPROT2_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FPROT1 - Program Flash Protection Registers ******************************************************************************/ /*! * @brief HW_FTFA_FPROT1 - Program Flash Protection Registers (RW) * * Reset value: 0x00U * * The FPROT registers define which logical program flash regions are protected * from program and erase operations. Protected flash regions cannot have their * content changed; that is, these regions cannot be programmed and cannot be * erased by any flash command. Unprotected regions can be changed by program and * erase operations. The four FPROT registers allow up to 32 protectable regions. * Each bit protects a 1/32 region of the program flash memory except for memory * configurations with less than 32 KB of program flash where each assigned bit * protects 1 KB . For configurations with 24 KB of program flash memory or less, * FPROT0 is not used. For configurations with 16 KB of program flash memory or * less, FPROT1 is not used. For configurations with 8 KB of program flash memory, * FPROT2 is not used. The bitfields are defined in each register as follows: * Program flash protection register Program flash protection bits FPROT0 PROT[31:24] * FPROT1 PROT[23:16] FPROT2 PROT[15:8] FPROT3 PROT[7:0] During the reset * sequence, the FPROT registers are loaded with the contents of the program flash * protection bytes in the Flash Configuration Field as indicated in the following * table. Program flash protection register Flash Configuration Field offset * address FPROT0 0x000B FPROT1 0x000A FPROT2 0x0009 FPROT3 0x0008 To change the * program flash protection that is loaded during the reset sequence, unprotect the * sector of program flash memory that contains the Flash Configuration Field. Then, * reprogram the program flash protection byte. */ typedef union _hw_ftfa_fprot1 { uint8_t U; struct _hw_ftfa_fprot1_bitfields { uint8_t PROT : 8; /*!< [7:0] Program Flash Region Protect */ } B; } hw_ftfa_fprot1_t; /*! * @name Constants and macros for entire FTFA_FPROT1 register */ /*@{*/ #define HW_FTFA_FPROT1_ADDR(x) ((x) + 0x12U) #define HW_FTFA_FPROT1(x) (*(__IO hw_ftfa_fprot1_t *) HW_FTFA_FPROT1_ADDR(x)) #define HW_FTFA_FPROT1_RD(x) (HW_FTFA_FPROT1(x).U) #define HW_FTFA_FPROT1_WR(x, v) (HW_FTFA_FPROT1(x).U = (v)) #define HW_FTFA_FPROT1_SET(x, v) (HW_FTFA_FPROT1_WR(x, HW_FTFA_FPROT1_RD(x) | (v))) #define HW_FTFA_FPROT1_CLR(x, v) (HW_FTFA_FPROT1_WR(x, HW_FTFA_FPROT1_RD(x) & ~(v))) #define HW_FTFA_FPROT1_TOG(x, v) (HW_FTFA_FPROT1_WR(x, HW_FTFA_FPROT1_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FPROT1 bitfields */ /*! * @name Register FTFA_FPROT1, field PROT[7:0] (RW) * * Each program flash region can be protected from program and erase operations * by setting the associated PROT bit. In NVM Normal mode: The protection can * only be increased, meaning that currently unprotected memory can be protected, * but currently protected memory cannot be unprotected. Since unprotected regions * are marked with a 1 and protected regions use a 0, only writes changing 1s to * 0s are accepted. This 1-to-0 transition check is performed on a bit-by-bit * basis. Those FPROT bits with 1-to-0 transitions are accepted while all bits with * 0-to-1 transitions are ignored. In NVM Special mode: All bits of FPROT are * writable without restriction. Unprotected areas can be protected and protected * areas can be unprotected. The user must never write to any FPROT register while * a command is running (CCIF=0). Trying to alter data in any protected area in * the program flash memory results in a protection violation error and sets the * FSTAT[FPVIOL] bit. A full block erase of a program flash block is not possible * if it contains any protected region. Each bit in the 32-bit protection * register represents 1/32 of the total program flash except for configurations where * program flash memory is less than 32 KB. For configurations with less than 32 * KB of program flash memory, each assigned bit represents 1 KB. * * Values: * - 0 - Program flash region is protected. * - 1 - Program flash region is not protected */ /*@{*/ #define BP_FTFA_FPROT1_PROT (0U) /*!< Bit position for FTFA_FPROT1_PROT. */ #define BM_FTFA_FPROT1_PROT (0xFFU) /*!< Bit mask for FTFA_FPROT1_PROT. */ #define BS_FTFA_FPROT1_PROT (8U) /*!< Bit field size in bits for FTFA_FPROT1_PROT. */ /*! @brief Read current value of the FTFA_FPROT1_PROT field. */ #define BR_FTFA_FPROT1_PROT(x) (HW_FTFA_FPROT1(x).U) /*! @brief Format value for bitfield FTFA_FPROT1_PROT. */ #define BF_FTFA_FPROT1_PROT(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FPROT1_PROT) & BM_FTFA_FPROT1_PROT) /*! @brief Set the PROT field to a new value. */ #define BW_FTFA_FPROT1_PROT(x, v) (HW_FTFA_FPROT1_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_FPROT0 - Program Flash Protection Registers ******************************************************************************/ /*! * @brief HW_FTFA_FPROT0 - Program Flash Protection Registers (RW) * * Reset value: 0x00U * * The FPROT registers define which logical program flash regions are protected * from program and erase operations. Protected flash regions cannot have their * content changed; that is, these regions cannot be programmed and cannot be * erased by any flash command. Unprotected regions can be changed by program and * erase operations. The four FPROT registers allow up to 32 protectable regions. * Each bit protects a 1/32 region of the program flash memory except for memory * configurations with less than 32 KB of program flash where each assigned bit * protects 1 KB . For configurations with 24 KB of program flash memory or less, * FPROT0 is not used. For configurations with 16 KB of program flash memory or * less, FPROT1 is not used. For configurations with 8 KB of program flash memory, * FPROT2 is not used. The bitfields are defined in each register as follows: * Program flash protection register Program flash protection bits FPROT0 PROT[31:24] * FPROT1 PROT[23:16] FPROT2 PROT[15:8] FPROT3 PROT[7:0] During the reset * sequence, the FPROT registers are loaded with the contents of the program flash * protection bytes in the Flash Configuration Field as indicated in the following * table. Program flash protection register Flash Configuration Field offset * address FPROT0 0x000B FPROT1 0x000A FPROT2 0x0009 FPROT3 0x0008 To change the * program flash protection that is loaded during the reset sequence, unprotect the * sector of program flash memory that contains the Flash Configuration Field. Then, * reprogram the program flash protection byte. */ typedef union _hw_ftfa_fprot0 { uint8_t U; struct _hw_ftfa_fprot0_bitfields { uint8_t PROT : 8; /*!< [7:0] Program Flash Region Protect */ } B; } hw_ftfa_fprot0_t; /*! * @name Constants and macros for entire FTFA_FPROT0 register */ /*@{*/ #define HW_FTFA_FPROT0_ADDR(x) ((x) + 0x13U) #define HW_FTFA_FPROT0(x) (*(__IO hw_ftfa_fprot0_t *) HW_FTFA_FPROT0_ADDR(x)) #define HW_FTFA_FPROT0_RD(x) (HW_FTFA_FPROT0(x).U) #define HW_FTFA_FPROT0_WR(x, v) (HW_FTFA_FPROT0(x).U = (v)) #define HW_FTFA_FPROT0_SET(x, v) (HW_FTFA_FPROT0_WR(x, HW_FTFA_FPROT0_RD(x) | (v))) #define HW_FTFA_FPROT0_CLR(x, v) (HW_FTFA_FPROT0_WR(x, HW_FTFA_FPROT0_RD(x) & ~(v))) #define HW_FTFA_FPROT0_TOG(x, v) (HW_FTFA_FPROT0_WR(x, HW_FTFA_FPROT0_RD(x) ^ (v))) /*@}*/ /* * Constants & macros for individual FTFA_FPROT0 bitfields */ /*! * @name Register FTFA_FPROT0, field PROT[7:0] (RW) * * Each program flash region can be protected from program and erase operations * by setting the associated PROT bit. In NVM Normal mode: The protection can * only be increased, meaning that currently unprotected memory can be protected, * but currently protected memory cannot be unprotected. Since unprotected regions * are marked with a 1 and protected regions use a 0, only writes changing 1s to * 0s are accepted. This 1-to-0 transition check is performed on a bit-by-bit * basis. Those FPROT bits with 1-to-0 transitions are accepted while all bits with * 0-to-1 transitions are ignored. In NVM Special mode: All bits of FPROT are * writable without restriction. Unprotected areas can be protected and protected * areas can be unprotected. The user must never write to any FPROT register while * a command is running (CCIF=0). Trying to alter data in any protected area in * the program flash memory results in a protection violation error and sets the * FSTAT[FPVIOL] bit. A full block erase of a program flash block is not possible * if it contains any protected region. Each bit in the 32-bit protection * register represents 1/32 of the total program flash except for configurations where * program flash memory is less than 32 KB. For configurations with less than 32 * KB of program flash memory, each assigned bit represents 1 KB. * * Values: * - 0 - Program flash region is protected. * - 1 - Program flash region is not protected */ /*@{*/ #define BP_FTFA_FPROT0_PROT (0U) /*!< Bit position for FTFA_FPROT0_PROT. */ #define BM_FTFA_FPROT0_PROT (0xFFU) /*!< Bit mask for FTFA_FPROT0_PROT. */ #define BS_FTFA_FPROT0_PROT (8U) /*!< Bit field size in bits for FTFA_FPROT0_PROT. */ /*! @brief Read current value of the FTFA_FPROT0_PROT field. */ #define BR_FTFA_FPROT0_PROT(x) (HW_FTFA_FPROT0(x).U) /*! @brief Format value for bitfield FTFA_FPROT0_PROT. */ #define BF_FTFA_FPROT0_PROT(v) ((uint8_t)((uint8_t)(v) << BP_FTFA_FPROT0_PROT) & BM_FTFA_FPROT0_PROT) /*! @brief Set the PROT field to a new value. */ #define BW_FTFA_FPROT0_PROT(x, v) (HW_FTFA_FPROT0_WR(x, v)) /*@}*/ /******************************************************************************* * HW_FTFA_XACCH3 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCH3 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xacch3 { uint8_t U; struct _hw_ftfa_xacch3_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xacch3_t; /*! * @name Constants and macros for entire FTFA_XACCH3 register */ /*@{*/ #define HW_FTFA_XACCH3_ADDR(x) ((x) + 0x18U) #define HW_FTFA_XACCH3(x) (*(__I hw_ftfa_xacch3_t *) HW_FTFA_XACCH3_ADDR(x)) #define HW_FTFA_XACCH3_RD(x) (HW_FTFA_XACCH3(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCH3 bitfields */ /*! * @name Register FTFA_XACCH3, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCH3_XA (0U) /*!< Bit position for FTFA_XACCH3_XA. */ #define BM_FTFA_XACCH3_XA (0xFFU) /*!< Bit mask for FTFA_XACCH3_XA. */ #define BS_FTFA_XACCH3_XA (8U) /*!< Bit field size in bits for FTFA_XACCH3_XA. */ /*! @brief Read current value of the FTFA_XACCH3_XA field. */ #define BR_FTFA_XACCH3_XA(x) (HW_FTFA_XACCH3(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCH2 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCH2 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xacch2 { uint8_t U; struct _hw_ftfa_xacch2_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xacch2_t; /*! * @name Constants and macros for entire FTFA_XACCH2 register */ /*@{*/ #define HW_FTFA_XACCH2_ADDR(x) ((x) + 0x19U) #define HW_FTFA_XACCH2(x) (*(__I hw_ftfa_xacch2_t *) HW_FTFA_XACCH2_ADDR(x)) #define HW_FTFA_XACCH2_RD(x) (HW_FTFA_XACCH2(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCH2 bitfields */ /*! * @name Register FTFA_XACCH2, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCH2_XA (0U) /*!< Bit position for FTFA_XACCH2_XA. */ #define BM_FTFA_XACCH2_XA (0xFFU) /*!< Bit mask for FTFA_XACCH2_XA. */ #define BS_FTFA_XACCH2_XA (8U) /*!< Bit field size in bits for FTFA_XACCH2_XA. */ /*! @brief Read current value of the FTFA_XACCH2_XA field. */ #define BR_FTFA_XACCH2_XA(x) (HW_FTFA_XACCH2(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCH1 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCH1 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xacch1 { uint8_t U; struct _hw_ftfa_xacch1_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xacch1_t; /*! * @name Constants and macros for entire FTFA_XACCH1 register */ /*@{*/ #define HW_FTFA_XACCH1_ADDR(x) ((x) + 0x1AU) #define HW_FTFA_XACCH1(x) (*(__I hw_ftfa_xacch1_t *) HW_FTFA_XACCH1_ADDR(x)) #define HW_FTFA_XACCH1_RD(x) (HW_FTFA_XACCH1(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCH1 bitfields */ /*! * @name Register FTFA_XACCH1, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCH1_XA (0U) /*!< Bit position for FTFA_XACCH1_XA. */ #define BM_FTFA_XACCH1_XA (0xFFU) /*!< Bit mask for FTFA_XACCH1_XA. */ #define BS_FTFA_XACCH1_XA (8U) /*!< Bit field size in bits for FTFA_XACCH1_XA. */ /*! @brief Read current value of the FTFA_XACCH1_XA field. */ #define BR_FTFA_XACCH1_XA(x) (HW_FTFA_XACCH1(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCH0 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCH0 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xacch0 { uint8_t U; struct _hw_ftfa_xacch0_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xacch0_t; /*! * @name Constants and macros for entire FTFA_XACCH0 register */ /*@{*/ #define HW_FTFA_XACCH0_ADDR(x) ((x) + 0x1BU) #define HW_FTFA_XACCH0(x) (*(__I hw_ftfa_xacch0_t *) HW_FTFA_XACCH0_ADDR(x)) #define HW_FTFA_XACCH0_RD(x) (HW_FTFA_XACCH0(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCH0 bitfields */ /*! * @name Register FTFA_XACCH0, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCH0_XA (0U) /*!< Bit position for FTFA_XACCH0_XA. */ #define BM_FTFA_XACCH0_XA (0xFFU) /*!< Bit mask for FTFA_XACCH0_XA. */ #define BS_FTFA_XACCH0_XA (8U) /*!< Bit field size in bits for FTFA_XACCH0_XA. */ /*! @brief Read current value of the FTFA_XACCH0_XA field. */ #define BR_FTFA_XACCH0_XA(x) (HW_FTFA_XACCH0(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCL3 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCL3 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xaccl3 { uint8_t U; struct _hw_ftfa_xaccl3_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xaccl3_t; /*! * @name Constants and macros for entire FTFA_XACCL3 register */ /*@{*/ #define HW_FTFA_XACCL3_ADDR(x) ((x) + 0x1CU) #define HW_FTFA_XACCL3(x) (*(__I hw_ftfa_xaccl3_t *) HW_FTFA_XACCL3_ADDR(x)) #define HW_FTFA_XACCL3_RD(x) (HW_FTFA_XACCL3(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCL3 bitfields */ /*! * @name Register FTFA_XACCL3, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCL3_XA (0U) /*!< Bit position for FTFA_XACCL3_XA. */ #define BM_FTFA_XACCL3_XA (0xFFU) /*!< Bit mask for FTFA_XACCL3_XA. */ #define BS_FTFA_XACCL3_XA (8U) /*!< Bit field size in bits for FTFA_XACCL3_XA. */ /*! @brief Read current value of the FTFA_XACCL3_XA field. */ #define BR_FTFA_XACCL3_XA(x) (HW_FTFA_XACCL3(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCL2 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCL2 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xaccl2 { uint8_t U; struct _hw_ftfa_xaccl2_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xaccl2_t; /*! * @name Constants and macros for entire FTFA_XACCL2 register */ /*@{*/ #define HW_FTFA_XACCL2_ADDR(x) ((x) + 0x1DU) #define HW_FTFA_XACCL2(x) (*(__I hw_ftfa_xaccl2_t *) HW_FTFA_XACCL2_ADDR(x)) #define HW_FTFA_XACCL2_RD(x) (HW_FTFA_XACCL2(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCL2 bitfields */ /*! * @name Register FTFA_XACCL2, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCL2_XA (0U) /*!< Bit position for FTFA_XACCL2_XA. */ #define BM_FTFA_XACCL2_XA (0xFFU) /*!< Bit mask for FTFA_XACCL2_XA. */ #define BS_FTFA_XACCL2_XA (8U) /*!< Bit field size in bits for FTFA_XACCL2_XA. */ /*! @brief Read current value of the FTFA_XACCL2_XA field. */ #define BR_FTFA_XACCL2_XA(x) (HW_FTFA_XACCL2(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCL1 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCL1 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xaccl1 { uint8_t U; struct _hw_ftfa_xaccl1_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xaccl1_t; /*! * @name Constants and macros for entire FTFA_XACCL1 register */ /*@{*/ #define HW_FTFA_XACCL1_ADDR(x) ((x) + 0x1EU) #define HW_FTFA_XACCL1(x) (*(__I hw_ftfa_xaccl1_t *) HW_FTFA_XACCL1_ADDR(x)) #define HW_FTFA_XACCL1_RD(x) (HW_FTFA_XACCL1(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCL1 bitfields */ /*! * @name Register FTFA_XACCL1, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCL1_XA (0U) /*!< Bit position for FTFA_XACCL1_XA. */ #define BM_FTFA_XACCL1_XA (0xFFU) /*!< Bit mask for FTFA_XACCL1_XA. */ #define BS_FTFA_XACCL1_XA (8U) /*!< Bit field size in bits for FTFA_XACCL1_XA. */ /*! @brief Read current value of the FTFA_XACCL1_XA field. */ #define BR_FTFA_XACCL1_XA(x) (HW_FTFA_XACCL1(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_XACCL0 - Execute-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_XACCL0 - Execute-only Access Registers (RO) * * Reset value: 0x00U * * The XACC registers define which logical program flash segments are restricted * to data read or execute only or both data and instruction fetches. The eight * XACC registers allow up to 64 restricted segments of equal memory size. * Execute-only access register Program flash execute-only access bits XACCH0 XA[63:56] * XACCH1 XA[55:48] XACCH2 XA[47:40] XACCH3 XA[39:32] XACCL0 XA[31:24] XACCL1 * XA[23:16] XACCL2 XA[15:8] XACCL3 XA[7:0] During the reset sequence, the XACC * registers are loaded with the logical AND of Program Flash IFR addresses A and B * as indicated in the following table. Execute-only access register Program * Flash IFR address A Program Flash IFR address B XACCH0 0xA3 0xAB XACCH1 0xA2 0xAA * XACCH2 0xA1 0xA9 XACCH3 0xA0 0xA8 XACCL0 0xA7 0xAF XACCL1 0xA6 0xAE XACCL2 * 0xA5 0xAD XACCL3 0xA4 0xAC Use the Program Once command to program the * execute-only access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_xaccl0 { uint8_t U; struct _hw_ftfa_xaccl0_bitfields { uint8_t XA : 8; /*!< [7:0] Execute-only access control */ } B; } hw_ftfa_xaccl0_t; /*! * @name Constants and macros for entire FTFA_XACCL0 register */ /*@{*/ #define HW_FTFA_XACCL0_ADDR(x) ((x) + 0x1FU) #define HW_FTFA_XACCL0(x) (*(__I hw_ftfa_xaccl0_t *) HW_FTFA_XACCL0_ADDR(x)) #define HW_FTFA_XACCL0_RD(x) (HW_FTFA_XACCL0(x).U) /*@}*/ /* * Constants & macros for individual FTFA_XACCL0 bitfields */ /*! * @name Register FTFA_XACCL0, field XA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in execute mode only (as an * instruction fetch) * - 1 - Associated segment is accessible as data or in execute mode */ /*@{*/ #define BP_FTFA_XACCL0_XA (0U) /*!< Bit position for FTFA_XACCL0_XA. */ #define BM_FTFA_XACCL0_XA (0xFFU) /*!< Bit mask for FTFA_XACCL0_XA. */ #define BS_FTFA_XACCL0_XA (8U) /*!< Bit field size in bits for FTFA_XACCL0_XA. */ /*! @brief Read current value of the FTFA_XACCL0_XA field. */ #define BR_FTFA_XACCL0_XA(x) (HW_FTFA_XACCL0(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCH3 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCH3 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_sacch3 { uint8_t U; struct _hw_ftfa_sacch3_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_sacch3_t; /*! * @name Constants and macros for entire FTFA_SACCH3 register */ /*@{*/ #define HW_FTFA_SACCH3_ADDR(x) ((x) + 0x20U) #define HW_FTFA_SACCH3(x) (*(__I hw_ftfa_sacch3_t *) HW_FTFA_SACCH3_ADDR(x)) #define HW_FTFA_SACCH3_RD(x) (HW_FTFA_SACCH3(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCH3 bitfields */ /*! * @name Register FTFA_SACCH3, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCH3_SA (0U) /*!< Bit position for FTFA_SACCH3_SA. */ #define BM_FTFA_SACCH3_SA (0xFFU) /*!< Bit mask for FTFA_SACCH3_SA. */ #define BS_FTFA_SACCH3_SA (8U) /*!< Bit field size in bits for FTFA_SACCH3_SA. */ /*! @brief Read current value of the FTFA_SACCH3_SA field. */ #define BR_FTFA_SACCH3_SA(x) (HW_FTFA_SACCH3(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCH2 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCH2 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_sacch2 { uint8_t U; struct _hw_ftfa_sacch2_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_sacch2_t; /*! * @name Constants and macros for entire FTFA_SACCH2 register */ /*@{*/ #define HW_FTFA_SACCH2_ADDR(x) ((x) + 0x21U) #define HW_FTFA_SACCH2(x) (*(__I hw_ftfa_sacch2_t *) HW_FTFA_SACCH2_ADDR(x)) #define HW_FTFA_SACCH2_RD(x) (HW_FTFA_SACCH2(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCH2 bitfields */ /*! * @name Register FTFA_SACCH2, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCH2_SA (0U) /*!< Bit position for FTFA_SACCH2_SA. */ #define BM_FTFA_SACCH2_SA (0xFFU) /*!< Bit mask for FTFA_SACCH2_SA. */ #define BS_FTFA_SACCH2_SA (8U) /*!< Bit field size in bits for FTFA_SACCH2_SA. */ /*! @brief Read current value of the FTFA_SACCH2_SA field. */ #define BR_FTFA_SACCH2_SA(x) (HW_FTFA_SACCH2(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCH1 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCH1 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_sacch1 { uint8_t U; struct _hw_ftfa_sacch1_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_sacch1_t; /*! * @name Constants and macros for entire FTFA_SACCH1 register */ /*@{*/ #define HW_FTFA_SACCH1_ADDR(x) ((x) + 0x22U) #define HW_FTFA_SACCH1(x) (*(__I hw_ftfa_sacch1_t *) HW_FTFA_SACCH1_ADDR(x)) #define HW_FTFA_SACCH1_RD(x) (HW_FTFA_SACCH1(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCH1 bitfields */ /*! * @name Register FTFA_SACCH1, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCH1_SA (0U) /*!< Bit position for FTFA_SACCH1_SA. */ #define BM_FTFA_SACCH1_SA (0xFFU) /*!< Bit mask for FTFA_SACCH1_SA. */ #define BS_FTFA_SACCH1_SA (8U) /*!< Bit field size in bits for FTFA_SACCH1_SA. */ /*! @brief Read current value of the FTFA_SACCH1_SA field. */ #define BR_FTFA_SACCH1_SA(x) (HW_FTFA_SACCH1(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCH0 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCH0 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_sacch0 { uint8_t U; struct _hw_ftfa_sacch0_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_sacch0_t; /*! * @name Constants and macros for entire FTFA_SACCH0 register */ /*@{*/ #define HW_FTFA_SACCH0_ADDR(x) ((x) + 0x23U) #define HW_FTFA_SACCH0(x) (*(__I hw_ftfa_sacch0_t *) HW_FTFA_SACCH0_ADDR(x)) #define HW_FTFA_SACCH0_RD(x) (HW_FTFA_SACCH0(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCH0 bitfields */ /*! * @name Register FTFA_SACCH0, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCH0_SA (0U) /*!< Bit position for FTFA_SACCH0_SA. */ #define BM_FTFA_SACCH0_SA (0xFFU) /*!< Bit mask for FTFA_SACCH0_SA. */ #define BS_FTFA_SACCH0_SA (8U) /*!< Bit field size in bits for FTFA_SACCH0_SA. */ /*! @brief Read current value of the FTFA_SACCH0_SA field. */ #define BR_FTFA_SACCH0_SA(x) (HW_FTFA_SACCH0(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCL3 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCL3 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_saccl3 { uint8_t U; struct _hw_ftfa_saccl3_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_saccl3_t; /*! * @name Constants and macros for entire FTFA_SACCL3 register */ /*@{*/ #define HW_FTFA_SACCL3_ADDR(x) ((x) + 0x24U) #define HW_FTFA_SACCL3(x) (*(__I hw_ftfa_saccl3_t *) HW_FTFA_SACCL3_ADDR(x)) #define HW_FTFA_SACCL3_RD(x) (HW_FTFA_SACCL3(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCL3 bitfields */ /*! * @name Register FTFA_SACCL3, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCL3_SA (0U) /*!< Bit position for FTFA_SACCL3_SA. */ #define BM_FTFA_SACCL3_SA (0xFFU) /*!< Bit mask for FTFA_SACCL3_SA. */ #define BS_FTFA_SACCL3_SA (8U) /*!< Bit field size in bits for FTFA_SACCL3_SA. */ /*! @brief Read current value of the FTFA_SACCL3_SA field. */ #define BR_FTFA_SACCL3_SA(x) (HW_FTFA_SACCL3(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCL2 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCL2 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_saccl2 { uint8_t U; struct _hw_ftfa_saccl2_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_saccl2_t; /*! * @name Constants and macros for entire FTFA_SACCL2 register */ /*@{*/ #define HW_FTFA_SACCL2_ADDR(x) ((x) + 0x25U) #define HW_FTFA_SACCL2(x) (*(__I hw_ftfa_saccl2_t *) HW_FTFA_SACCL2_ADDR(x)) #define HW_FTFA_SACCL2_RD(x) (HW_FTFA_SACCL2(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCL2 bitfields */ /*! * @name Register FTFA_SACCL2, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCL2_SA (0U) /*!< Bit position for FTFA_SACCL2_SA. */ #define BM_FTFA_SACCL2_SA (0xFFU) /*!< Bit mask for FTFA_SACCL2_SA. */ #define BS_FTFA_SACCL2_SA (8U) /*!< Bit field size in bits for FTFA_SACCL2_SA. */ /*! @brief Read current value of the FTFA_SACCL2_SA field. */ #define BR_FTFA_SACCL2_SA(x) (HW_FTFA_SACCL2(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCL1 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCL1 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_saccl1 { uint8_t U; struct _hw_ftfa_saccl1_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_saccl1_t; /*! * @name Constants and macros for entire FTFA_SACCL1 register */ /*@{*/ #define HW_FTFA_SACCL1_ADDR(x) ((x) + 0x26U) #define HW_FTFA_SACCL1(x) (*(__I hw_ftfa_saccl1_t *) HW_FTFA_SACCL1_ADDR(x)) #define HW_FTFA_SACCL1_RD(x) (HW_FTFA_SACCL1(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCL1 bitfields */ /*! * @name Register FTFA_SACCL1, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCL1_SA (0U) /*!< Bit position for FTFA_SACCL1_SA. */ #define BM_FTFA_SACCL1_SA (0xFFU) /*!< Bit mask for FTFA_SACCL1_SA. */ #define BS_FTFA_SACCL1_SA (8U) /*!< Bit field size in bits for FTFA_SACCL1_SA. */ /*! @brief Read current value of the FTFA_SACCL1_SA field. */ #define BR_FTFA_SACCL1_SA(x) (HW_FTFA_SACCL1(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_SACCL0 - Supervisor-only Access Registers ******************************************************************************/ /*! * @brief HW_FTFA_SACCL0 - Supervisor-only Access Registers (RO) * * Reset value: 0x00U * * The SACC registers define which logical program flash segments are restricted * to supervisor only or user and supervisor access. The eight SACC registers * allow up to 64 restricted segments of equal memory size. Supervisor-only access * register Program flash supervisor-only access bits SACCH0 SA[63:56] SACCH1 * SA[55:48] SACCH2 SA[47:40] SACCH3 SA[39:32] SACCL0 SA[31:24] SACCL1 SA[23:16] * SACCL2 SA[15:8] SACCL3 SA[7:0] During the reset sequence, the SACC registers are * loaded with the logical AND of Program Flash IFR addresses A and B as * indicated in the following table. Supervisor-only access register Program Flash IFR * address A Program Flash IFR address B SACCH0 0xB3 0xBB SACCH1 0xB2 0xBA SACCH2 * 0xB1 0xB9 SACCH3 0xB0 0xB8 SACCL0 0xB7 0xBF SACCL1 0xB6 0xBE SACCL2 0xB5 0xBD * SACCL3 0xB4 0xBC Use the Program Once command to program the supervisor-only * access control fields that are loaded during the reset sequence. */ typedef union _hw_ftfa_saccl0 { uint8_t U; struct _hw_ftfa_saccl0_bitfields { uint8_t SA : 8; /*!< [7:0] Supervisor-only access control */ } B; } hw_ftfa_saccl0_t; /*! * @name Constants and macros for entire FTFA_SACCL0 register */ /*@{*/ #define HW_FTFA_SACCL0_ADDR(x) ((x) + 0x27U) #define HW_FTFA_SACCL0(x) (*(__I hw_ftfa_saccl0_t *) HW_FTFA_SACCL0_ADDR(x)) #define HW_FTFA_SACCL0_RD(x) (HW_FTFA_SACCL0(x).U) /*@}*/ /* * Constants & macros for individual FTFA_SACCL0 bitfields */ /*! * @name Register FTFA_SACCL0, field SA[7:0] (RO) * * Values: * - 0 - Associated segment is accessible in supervisor mode only * - 1 - Associated segment is accessible in user or supervisor mode */ /*@{*/ #define BP_FTFA_SACCL0_SA (0U) /*!< Bit position for FTFA_SACCL0_SA. */ #define BM_FTFA_SACCL0_SA (0xFFU) /*!< Bit mask for FTFA_SACCL0_SA. */ #define BS_FTFA_SACCL0_SA (8U) /*!< Bit field size in bits for FTFA_SACCL0_SA. */ /*! @brief Read current value of the FTFA_SACCL0_SA field. */ #define BR_FTFA_SACCL0_SA(x) (HW_FTFA_SACCL0(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_FACSS - Flash Access Segment Size Register ******************************************************************************/ /*! * @brief HW_FTFA_FACSS - Flash Access Segment Size Register (RO) * * Reset value: 0x00U * * The flash access segment size register determines which bits in the address * are used to index into the SACC and XACC bitmaps to get the appropriate * permission flags. All bits in the register are read-only. The contents of this * register are loaded during the reset sequence. */ typedef union _hw_ftfa_facss { uint8_t U; struct _hw_ftfa_facss_bitfields { uint8_t SGSIZE : 8; /*!< [7:0] Segment Size */ } B; } hw_ftfa_facss_t; /*! * @name Constants and macros for entire FTFA_FACSS register */ /*@{*/ #define HW_FTFA_FACSS_ADDR(x) ((x) + 0x28U) #define HW_FTFA_FACSS(x) (*(__I hw_ftfa_facss_t *) HW_FTFA_FACSS_ADDR(x)) #define HW_FTFA_FACSS_RD(x) (HW_FTFA_FACSS(x).U) /*@}*/ /* * Constants & macros for individual FTFA_FACSS bitfields */ /*! * @name Register FTFA_FACSS, field SGSIZE[7:0] (RO) * * The segment size is a fixed value based on the available program flash size * divided by NUMSG. Program Flash Size Segment Size Segment Size Encoding 64 * KBytes 2 KBytes 0x3 128 KBytes 4 KBytes 0x4 160 KBytes 4 KBytes 0x4 256 KBytes 4 * KBytes 0x4 512 KBytes 8 KBytes 0x5 */ /*@{*/ #define BP_FTFA_FACSS_SGSIZE (0U) /*!< Bit position for FTFA_FACSS_SGSIZE. */ #define BM_FTFA_FACSS_SGSIZE (0xFFU) /*!< Bit mask for FTFA_FACSS_SGSIZE. */ #define BS_FTFA_FACSS_SGSIZE (8U) /*!< Bit field size in bits for FTFA_FACSS_SGSIZE. */ /*! @brief Read current value of the FTFA_FACSS_SGSIZE field. */ #define BR_FTFA_FACSS_SGSIZE(x) (HW_FTFA_FACSS(x).U) /*@}*/ /******************************************************************************* * HW_FTFA_FACSN - Flash Access Segment Number Register ******************************************************************************/ /*! * @brief HW_FTFA_FACSN - Flash Access Segment Number Register (RO) * * Reset value: 0x00U * * The flash access segment number register provides the number of program flash * segments that are available for XACC and SACC permissions. All bits in the * register are read-only. The contents of this register are loaded during the * reset sequence. */ typedef union _hw_ftfa_facsn { uint8_t U; struct _hw_ftfa_facsn_bitfields { uint8_t NUMSG : 8; /*!< [7:0] Number of Segments Indicator */ } B; } hw_ftfa_facsn_t; /*! * @name Constants and macros for entire FTFA_FACSN register */ /*@{*/ #define HW_FTFA_FACSN_ADDR(x) ((x) + 0x2BU) #define HW_FTFA_FACSN(x) (*(__I hw_ftfa_facsn_t *) HW_FTFA_FACSN_ADDR(x)) #define HW_FTFA_FACSN_RD(x) (HW_FTFA_FACSN(x).U) /*@}*/ /* * Constants & macros for individual FTFA_FACSN bitfields */ /*! * @name Register FTFA_FACSN, field NUMSG[7:0] (RO) * * The NUMSG field indicates the number of equal-sized segments in the program * flash. * * Values: * - 100000 - Program flash memory is divided into 32 segments (64 Kbytes, 128 * Kbytes) * - 101000 - Program flash memory is divided into 40 segments (160 Kbytes) * - 1000000 - Program flash memory is divided into 64 segments (256 Kbytes, 512 * Kbytes) */ /*@{*/ #define BP_FTFA_FACSN_NUMSG (0U) /*!< Bit position for FTFA_FACSN_NUMSG. */ #define BM_FTFA_FACSN_NUMSG (0xFFU) /*!< Bit mask for FTFA_FACSN_NUMSG. */ #define BS_FTFA_FACSN_NUMSG (8U) /*!< Bit field size in bits for FTFA_FACSN_NUMSG. */ /*! @brief Read current value of the FTFA_FACSN_NUMSG field. */ #define BR_FTFA_FACSN_NUMSG(x) (HW_FTFA_FACSN(x).U) /*@}*/ /******************************************************************************* * hw_ftfa_t - module struct ******************************************************************************/ /*! * @brief All FTFA module registers. */ #pragma pack(1) typedef struct _hw_ftfa { __IO hw_ftfa_fstat_t FSTAT; /*!< [0x0] Flash Status Register */ __IO hw_ftfa_fcnfg_t FCNFG; /*!< [0x1] Flash Configuration Register */ __I hw_ftfa_fsec_t FSEC; /*!< [0x2] Flash Security Register */ __I hw_ftfa_fopt_t FOPT; /*!< [0x3] Flash Option Register */ __IO hw_ftfa_fccob3_t FCCOB3; /*!< [0x4] Flash Common Command Object Registers */ __IO hw_ftfa_fccob2_t FCCOB2; /*!< [0x5] Flash Common Command Object Registers */ __IO hw_ftfa_fccob1_t FCCOB1; /*!< [0x6] Flash Common Command Object Registers */ __IO hw_ftfa_fccob0_t FCCOB0; /*!< [0x7] Flash Common Command Object Registers */ __IO hw_ftfa_fccob7_t FCCOB7; /*!< [0x8] Flash Common Command Object Registers */ __IO hw_ftfa_fccob6_t FCCOB6; /*!< [0x9] Flash Common Command Object Registers */ __IO hw_ftfa_fccob5_t FCCOB5; /*!< [0xA] Flash Common Command Object Registers */ __IO hw_ftfa_fccob4_t FCCOB4; /*!< [0xB] Flash Common Command Object Registers */ __IO hw_ftfa_fccobb_t FCCOBB; /*!< [0xC] Flash Common Command Object Registers */ __IO hw_ftfa_fccoba_t FCCOBA; /*!< [0xD] Flash Common Command Object Registers */ __IO hw_ftfa_fccob9_t FCCOB9; /*!< [0xE] Flash Common Command Object Registers */ __IO hw_ftfa_fccob8_t FCCOB8; /*!< [0xF] Flash Common Command Object Registers */ __IO hw_ftfa_fprot3_t FPROT3; /*!< [0x10] Program Flash Protection Registers */ __IO hw_ftfa_fprot2_t FPROT2; /*!< [0x11] Program Flash Protection Registers */ __IO hw_ftfa_fprot1_t FPROT1; /*!< [0x12] Program Flash Protection Registers */ __IO hw_ftfa_fprot0_t FPROT0; /*!< [0x13] Program Flash Protection Registers */ uint8_t _reserved0[4]; __I hw_ftfa_xacch3_t XACCH3; /*!< [0x18] Execute-only Access Registers */ __I hw_ftfa_xacch2_t XACCH2; /*!< [0x19] Execute-only Access Registers */ __I hw_ftfa_xacch1_t XACCH1; /*!< [0x1A] Execute-only Access Registers */ __I hw_ftfa_xacch0_t XACCH0; /*!< [0x1B] Execute-only Access Registers */ __I hw_ftfa_xaccl3_t XACCL3; /*!< [0x1C] Execute-only Access Registers */ __I hw_ftfa_xaccl2_t XACCL2; /*!< [0x1D] Execute-only Access Registers */ __I hw_ftfa_xaccl1_t XACCL1; /*!< [0x1E] Execute-only Access Registers */ __I hw_ftfa_xaccl0_t XACCL0; /*!< [0x1F] Execute-only Access Registers */ __I hw_ftfa_sacch3_t SACCH3; /*!< [0x20] Supervisor-only Access Registers */ __I hw_ftfa_sacch2_t SACCH2; /*!< [0x21] Supervisor-only Access Registers */ __I hw_ftfa_sacch1_t SACCH1; /*!< [0x22] Supervisor-only Access Registers */ __I hw_ftfa_sacch0_t SACCH0; /*!< [0x23] Supervisor-only Access Registers */ __I hw_ftfa_saccl3_t SACCL3; /*!< [0x24] Supervisor-only Access Registers */ __I hw_ftfa_saccl2_t SACCL2; /*!< [0x25] Supervisor-only Access Registers */ __I hw_ftfa_saccl1_t SACCL1; /*!< [0x26] Supervisor-only Access Registers */ __I hw_ftfa_saccl0_t SACCL0; /*!< [0x27] Supervisor-only Access Registers */ __I hw_ftfa_facss_t FACSS; /*!< [0x28] Flash Access Segment Size Register */ uint8_t _reserved1[2]; __I hw_ftfa_facsn_t FACSN; /*!< [0x2B] Flash Access Segment Number Register */ } hw_ftfa_t; #pragma pack() /*! @brief Macro to access all FTFA registers. */ /*! @param x FTFA module instance base address. */ /*! @return Reference (not a pointer) to the registers struct. To get a pointer to the struct, * use the '&' operator, like &HW_FTFA(FTFA_BASE). */ #define HW_FTFA(x) (*(hw_ftfa_t *)(x)) #endif /* __HW_FTFA_REGISTERS_H__ */ /* EOF */