/* * Copyright (c) 2014, Freescale Semiconductor, Inc. * All rights reserved. * * THIS SOFTWARE IS PROVIDED BY FREESCALE "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 FREESCALE 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. */ /* * WARNING! DO NOT EDIT THIS FILE DIRECTLY! * * This file was generated automatically and any changes may be lost. */ #ifndef __HW_FMC_REGISTERS_H__ #define __HW_FMC_REGISTERS_H__ #include "regs.h" /* * MK64F12 FMC * * Flash Memory Controller * * Registers defined in this header file: * - HW_FMC_PFAPR - Flash Access Protection Register * - HW_FMC_PFB0CR - Flash Bank 0 Control Register * - HW_FMC_PFB1CR - Flash Bank 1 Control Register * - HW_FMC_TAGVDW0Sn - Cache Tag Storage * - HW_FMC_TAGVDW1Sn - Cache Tag Storage * - HW_FMC_TAGVDW2Sn - Cache Tag Storage * - HW_FMC_TAGVDW3Sn - Cache Tag Storage * - HW_FMC_DATAW0SnU - Cache Data Storage (upper word) * - HW_FMC_DATAW0SnL - Cache Data Storage (lower word) * - HW_FMC_DATAW1SnU - Cache Data Storage (upper word) * - HW_FMC_DATAW1SnL - Cache Data Storage (lower word) * - HW_FMC_DATAW2SnU - Cache Data Storage (upper word) * - HW_FMC_DATAW2SnL - Cache Data Storage (lower word) * - HW_FMC_DATAW3SnU - Cache Data Storage (upper word) * - HW_FMC_DATAW3SnL - Cache Data Storage (lower word) * * - hw_fmc_t - Struct containing all module registers. */ //! @name Module base addresses //@{ #ifndef REGS_FMC_BASE #define HW_FMC_INSTANCE_COUNT (1U) //!< Number of instances of the FMC module. #define REGS_FMC_BASE (0x4001F000U) //!< Base address for FMC. #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_PFAPR - Flash Access Protection Register //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_PFAPR - Flash Access Protection Register (RW) * * Reset value: 0x00F8003FU */ typedef union _hw_fmc_pfapr { uint32_t U; struct _hw_fmc_pfapr_bitfields { uint32_t M0AP : 2; //!< [1:0] Master 0 Access Protection uint32_t M1AP : 2; //!< [3:2] Master 1 Access Protection uint32_t M2AP : 2; //!< [5:4] Master 2 Access Protection uint32_t M3AP : 2; //!< [7:6] Master 3 Access Protection uint32_t M4AP : 2; //!< [9:8] Master 4 Access Protection uint32_t M5AP : 2; //!< [11:10] Master 5 Access Protection uint32_t M6AP : 2; //!< [13:12] Master 6 Access Protection uint32_t M7AP : 2; //!< [15:14] Master 7 Access Protection uint32_t M0PFD : 1; //!< [16] Master 0 Prefetch Disable uint32_t M1PFD : 1; //!< [17] Master 1 Prefetch Disable uint32_t M2PFD : 1; //!< [18] Master 2 Prefetch Disable uint32_t M3PFD : 1; //!< [19] Master 3 Prefetch Disable uint32_t M4PFD : 1; //!< [20] Master 4 Prefetch Disable uint32_t M5PFD : 1; //!< [21] Master 5 Prefetch Disable uint32_t M6PFD : 1; //!< [22] Master 6 Prefetch Disable uint32_t M7PFD : 1; //!< [23] Master 7 Prefetch Disable uint32_t RESERVED0 : 8; //!< [31:24] } B; } hw_fmc_pfapr_t; #endif /*! * @name Constants and macros for entire FMC_PFAPR register */ //@{ #define HW_FMC_PFAPR_ADDR (REGS_FMC_BASE + 0x0U) #ifndef __LANGUAGE_ASM__ #define HW_FMC_PFAPR (*(__IO hw_fmc_pfapr_t *) HW_FMC_PFAPR_ADDR) #define HW_FMC_PFAPR_RD() (HW_FMC_PFAPR.U) #define HW_FMC_PFAPR_WR(v) (HW_FMC_PFAPR.U = (v)) #define HW_FMC_PFAPR_SET(v) (HW_FMC_PFAPR_WR(HW_FMC_PFAPR_RD() | (v))) #define HW_FMC_PFAPR_CLR(v) (HW_FMC_PFAPR_WR(HW_FMC_PFAPR_RD() & ~(v))) #define HW_FMC_PFAPR_TOG(v) (HW_FMC_PFAPR_WR(HW_FMC_PFAPR_RD() ^ (v))) #endif //@} /* * Constants & macros for individual FMC_PFAPR bitfields */ /*! * @name Register FMC_PFAPR, field M0AP[1:0] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M0AP (0U) //!< Bit position for FMC_PFAPR_M0AP. #define BM_FMC_PFAPR_M0AP (0x00000003U) //!< Bit mask for FMC_PFAPR_M0AP. #define BS_FMC_PFAPR_M0AP (2U) //!< Bit field size in bits for FMC_PFAPR_M0AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M0AP field. #define BR_FMC_PFAPR_M0AP (HW_FMC_PFAPR.B.M0AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M0AP. #define BF_FMC_PFAPR_M0AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M0AP), uint32_t) & BM_FMC_PFAPR_M0AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M0AP field to a new value. #define BW_FMC_PFAPR_M0AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M0AP) | BF_FMC_PFAPR_M0AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M1AP[3:2] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M1AP (2U) //!< Bit position for FMC_PFAPR_M1AP. #define BM_FMC_PFAPR_M1AP (0x0000000CU) //!< Bit mask for FMC_PFAPR_M1AP. #define BS_FMC_PFAPR_M1AP (2U) //!< Bit field size in bits for FMC_PFAPR_M1AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M1AP field. #define BR_FMC_PFAPR_M1AP (HW_FMC_PFAPR.B.M1AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M1AP. #define BF_FMC_PFAPR_M1AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M1AP), uint32_t) & BM_FMC_PFAPR_M1AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M1AP field to a new value. #define BW_FMC_PFAPR_M1AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M1AP) | BF_FMC_PFAPR_M1AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M2AP[5:4] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M2AP (4U) //!< Bit position for FMC_PFAPR_M2AP. #define BM_FMC_PFAPR_M2AP (0x00000030U) //!< Bit mask for FMC_PFAPR_M2AP. #define BS_FMC_PFAPR_M2AP (2U) //!< Bit field size in bits for FMC_PFAPR_M2AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M2AP field. #define BR_FMC_PFAPR_M2AP (HW_FMC_PFAPR.B.M2AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M2AP. #define BF_FMC_PFAPR_M2AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M2AP), uint32_t) & BM_FMC_PFAPR_M2AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M2AP field to a new value. #define BW_FMC_PFAPR_M2AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M2AP) | BF_FMC_PFAPR_M2AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M3AP[7:6] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M3AP (6U) //!< Bit position for FMC_PFAPR_M3AP. #define BM_FMC_PFAPR_M3AP (0x000000C0U) //!< Bit mask for FMC_PFAPR_M3AP. #define BS_FMC_PFAPR_M3AP (2U) //!< Bit field size in bits for FMC_PFAPR_M3AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M3AP field. #define BR_FMC_PFAPR_M3AP (HW_FMC_PFAPR.B.M3AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M3AP. #define BF_FMC_PFAPR_M3AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M3AP), uint32_t) & BM_FMC_PFAPR_M3AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M3AP field to a new value. #define BW_FMC_PFAPR_M3AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M3AP) | BF_FMC_PFAPR_M3AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M4AP[9:8] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M4AP (8U) //!< Bit position for FMC_PFAPR_M4AP. #define BM_FMC_PFAPR_M4AP (0x00000300U) //!< Bit mask for FMC_PFAPR_M4AP. #define BS_FMC_PFAPR_M4AP (2U) //!< Bit field size in bits for FMC_PFAPR_M4AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M4AP field. #define BR_FMC_PFAPR_M4AP (HW_FMC_PFAPR.B.M4AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M4AP. #define BF_FMC_PFAPR_M4AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M4AP), uint32_t) & BM_FMC_PFAPR_M4AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M4AP field to a new value. #define BW_FMC_PFAPR_M4AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M4AP) | BF_FMC_PFAPR_M4AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M5AP[11:10] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M5AP (10U) //!< Bit position for FMC_PFAPR_M5AP. #define BM_FMC_PFAPR_M5AP (0x00000C00U) //!< Bit mask for FMC_PFAPR_M5AP. #define BS_FMC_PFAPR_M5AP (2U) //!< Bit field size in bits for FMC_PFAPR_M5AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M5AP field. #define BR_FMC_PFAPR_M5AP (HW_FMC_PFAPR.B.M5AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M5AP. #define BF_FMC_PFAPR_M5AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M5AP), uint32_t) & BM_FMC_PFAPR_M5AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M5AP field to a new value. #define BW_FMC_PFAPR_M5AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M5AP) | BF_FMC_PFAPR_M5AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M6AP[13:12] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master * - 01 - Only read accesses may be performed by this master * - 10 - Only write accesses may be performed by this master * - 11 - Both read and write accesses may be performed by this master */ //@{ #define BP_FMC_PFAPR_M6AP (12U) //!< Bit position for FMC_PFAPR_M6AP. #define BM_FMC_PFAPR_M6AP (0x00003000U) //!< Bit mask for FMC_PFAPR_M6AP. #define BS_FMC_PFAPR_M6AP (2U) //!< Bit field size in bits for FMC_PFAPR_M6AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M6AP field. #define BR_FMC_PFAPR_M6AP (HW_FMC_PFAPR.B.M6AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M6AP. #define BF_FMC_PFAPR_M6AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M6AP), uint32_t) & BM_FMC_PFAPR_M6AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M6AP field to a new value. #define BW_FMC_PFAPR_M6AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M6AP) | BF_FMC_PFAPR_M6AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M7AP[15:14] (RW) * * This field controls whether read and write access to the flash are allowed * based on the logical master number of the requesting crossbar switch master. * * Values: * - 00 - No access may be performed by this master. * - 01 - Only read accesses may be performed by this master. * - 10 - Only write accesses may be performed by this master. * - 11 - Both read and write accesses may be performed by this master. */ //@{ #define BP_FMC_PFAPR_M7AP (14U) //!< Bit position for FMC_PFAPR_M7AP. #define BM_FMC_PFAPR_M7AP (0x0000C000U) //!< Bit mask for FMC_PFAPR_M7AP. #define BS_FMC_PFAPR_M7AP (2U) //!< Bit field size in bits for FMC_PFAPR_M7AP. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M7AP field. #define BR_FMC_PFAPR_M7AP (HW_FMC_PFAPR.B.M7AP) #endif //! @brief Format value for bitfield FMC_PFAPR_M7AP. #define BF_FMC_PFAPR_M7AP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M7AP), uint32_t) & BM_FMC_PFAPR_M7AP) #ifndef __LANGUAGE_ASM__ //! @brief Set the M7AP field to a new value. #define BW_FMC_PFAPR_M7AP(v) (HW_FMC_PFAPR_WR((HW_FMC_PFAPR_RD() & ~BM_FMC_PFAPR_M7AP) | BF_FMC_PFAPR_M7AP(v))) #endif //@} /*! * @name Register FMC_PFAPR, field M0PFD[16] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M0PFD (16U) //!< Bit position for FMC_PFAPR_M0PFD. #define BM_FMC_PFAPR_M0PFD (0x00010000U) //!< Bit mask for FMC_PFAPR_M0PFD. #define BS_FMC_PFAPR_M0PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M0PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M0PFD field. #define BR_FMC_PFAPR_M0PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M0PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M0PFD. #define BF_FMC_PFAPR_M0PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M0PFD), uint32_t) & BM_FMC_PFAPR_M0PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M0PFD field to a new value. #define BW_FMC_PFAPR_M0PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M0PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M1PFD[17] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M1PFD (17U) //!< Bit position for FMC_PFAPR_M1PFD. #define BM_FMC_PFAPR_M1PFD (0x00020000U) //!< Bit mask for FMC_PFAPR_M1PFD. #define BS_FMC_PFAPR_M1PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M1PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M1PFD field. #define BR_FMC_PFAPR_M1PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M1PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M1PFD. #define BF_FMC_PFAPR_M1PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M1PFD), uint32_t) & BM_FMC_PFAPR_M1PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M1PFD field to a new value. #define BW_FMC_PFAPR_M1PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M1PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M2PFD[18] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M2PFD (18U) //!< Bit position for FMC_PFAPR_M2PFD. #define BM_FMC_PFAPR_M2PFD (0x00040000U) //!< Bit mask for FMC_PFAPR_M2PFD. #define BS_FMC_PFAPR_M2PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M2PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M2PFD field. #define BR_FMC_PFAPR_M2PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M2PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M2PFD. #define BF_FMC_PFAPR_M2PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M2PFD), uint32_t) & BM_FMC_PFAPR_M2PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M2PFD field to a new value. #define BW_FMC_PFAPR_M2PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M2PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M3PFD[19] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M3PFD (19U) //!< Bit position for FMC_PFAPR_M3PFD. #define BM_FMC_PFAPR_M3PFD (0x00080000U) //!< Bit mask for FMC_PFAPR_M3PFD. #define BS_FMC_PFAPR_M3PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M3PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M3PFD field. #define BR_FMC_PFAPR_M3PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M3PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M3PFD. #define BF_FMC_PFAPR_M3PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M3PFD), uint32_t) & BM_FMC_PFAPR_M3PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M3PFD field to a new value. #define BW_FMC_PFAPR_M3PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M3PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M4PFD[20] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M4PFD (20U) //!< Bit position for FMC_PFAPR_M4PFD. #define BM_FMC_PFAPR_M4PFD (0x00100000U) //!< Bit mask for FMC_PFAPR_M4PFD. #define BS_FMC_PFAPR_M4PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M4PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M4PFD field. #define BR_FMC_PFAPR_M4PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M4PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M4PFD. #define BF_FMC_PFAPR_M4PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M4PFD), uint32_t) & BM_FMC_PFAPR_M4PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M4PFD field to a new value. #define BW_FMC_PFAPR_M4PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M4PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M5PFD[21] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M5PFD (21U) //!< Bit position for FMC_PFAPR_M5PFD. #define BM_FMC_PFAPR_M5PFD (0x00200000U) //!< Bit mask for FMC_PFAPR_M5PFD. #define BS_FMC_PFAPR_M5PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M5PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M5PFD field. #define BR_FMC_PFAPR_M5PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M5PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M5PFD. #define BF_FMC_PFAPR_M5PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M5PFD), uint32_t) & BM_FMC_PFAPR_M5PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M5PFD field to a new value. #define BW_FMC_PFAPR_M5PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M5PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M6PFD[22] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M6PFD (22U) //!< Bit position for FMC_PFAPR_M6PFD. #define BM_FMC_PFAPR_M6PFD (0x00400000U) //!< Bit mask for FMC_PFAPR_M6PFD. #define BS_FMC_PFAPR_M6PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M6PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M6PFD field. #define BR_FMC_PFAPR_M6PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M6PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M6PFD. #define BF_FMC_PFAPR_M6PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M6PFD), uint32_t) & BM_FMC_PFAPR_M6PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M6PFD field to a new value. #define BW_FMC_PFAPR_M6PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M6PFD) = (v)) #endif //@} /*! * @name Register FMC_PFAPR, field M7PFD[23] (RW) * * These bits control whether prefetching is enabled based on the logical number * of the requesting crossbar switch master. This field is further qualified by * the PFBnCR[BxDPE,BxIPE] bits. * * Values: * - 0 - Prefetching for this master is enabled. * - 1 - Prefetching for this master is disabled. */ //@{ #define BP_FMC_PFAPR_M7PFD (23U) //!< Bit position for FMC_PFAPR_M7PFD. #define BM_FMC_PFAPR_M7PFD (0x00800000U) //!< Bit mask for FMC_PFAPR_M7PFD. #define BS_FMC_PFAPR_M7PFD (1U) //!< Bit field size in bits for FMC_PFAPR_M7PFD. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFAPR_M7PFD field. #define BR_FMC_PFAPR_M7PFD (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M7PFD)) #endif //! @brief Format value for bitfield FMC_PFAPR_M7PFD. #define BF_FMC_PFAPR_M7PFD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFAPR_M7PFD), uint32_t) & BM_FMC_PFAPR_M7PFD) #ifndef __LANGUAGE_ASM__ //! @brief Set the M7PFD field to a new value. #define BW_FMC_PFAPR_M7PFD(v) (BITBAND_ACCESS32(HW_FMC_PFAPR_ADDR, BP_FMC_PFAPR_M7PFD) = (v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_PFB0CR - Flash Bank 0 Control Register //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_PFB0CR - Flash Bank 0 Control Register (RW) * * Reset value: 0x3004001FU */ typedef union _hw_fmc_pfb0cr { uint32_t U; struct _hw_fmc_pfb0cr_bitfields { uint32_t B0SEBE : 1; //!< [0] Bank 0 Single Entry Buffer Enable uint32_t B0IPE : 1; //!< [1] Bank 0 Instruction Prefetch Enable uint32_t B0DPE : 1; //!< [2] Bank 0 Data Prefetch Enable uint32_t B0ICE : 1; //!< [3] Bank 0 Instruction Cache Enable uint32_t B0DCE : 1; //!< [4] Bank 0 Data Cache Enable uint32_t CRCb : 3; //!< [7:5] Cache Replacement Control uint32_t RESERVED0 : 9; //!< [16:8] uint32_t B0MW : 2; //!< [18:17] Bank 0 Memory Width uint32_t S_B_INV : 1; //!< [19] Invalidate Prefetch Speculation Buffer uint32_t CINV_WAY : 4; //!< [23:20] Cache Invalidate Way x uint32_t CLCK_WAY : 4; //!< [27:24] Cache Lock Way x uint32_t B0RWSC : 4; //!< [31:28] Bank 0 Read Wait State Control } B; } hw_fmc_pfb0cr_t; #endif /*! * @name Constants and macros for entire FMC_PFB0CR register */ //@{ #define HW_FMC_PFB0CR_ADDR (REGS_FMC_BASE + 0x4U) #ifndef __LANGUAGE_ASM__ #define HW_FMC_PFB0CR (*(__IO hw_fmc_pfb0cr_t *) HW_FMC_PFB0CR_ADDR) #define HW_FMC_PFB0CR_RD() (HW_FMC_PFB0CR.U) #define HW_FMC_PFB0CR_WR(v) (HW_FMC_PFB0CR.U = (v)) #define HW_FMC_PFB0CR_SET(v) (HW_FMC_PFB0CR_WR(HW_FMC_PFB0CR_RD() | (v))) #define HW_FMC_PFB0CR_CLR(v) (HW_FMC_PFB0CR_WR(HW_FMC_PFB0CR_RD() & ~(v))) #define HW_FMC_PFB0CR_TOG(v) (HW_FMC_PFB0CR_WR(HW_FMC_PFB0CR_RD() ^ (v))) #endif //@} /* * Constants & macros for individual FMC_PFB0CR bitfields */ /*! * @name Register FMC_PFB0CR, field B0SEBE[0] (RW) * * This bit controls whether the single entry page buffer is enabled in response * to flash read accesses. Its operation is independent from bank 1's cache. A * high-to-low transition of this enable forces the page buffer to be invalidated. * * Values: * - 0 - Single entry buffer is disabled. * - 1 - Single entry buffer is enabled. */ //@{ #define BP_FMC_PFB0CR_B0SEBE (0U) //!< Bit position for FMC_PFB0CR_B0SEBE. #define BM_FMC_PFB0CR_B0SEBE (0x00000001U) //!< Bit mask for FMC_PFB0CR_B0SEBE. #define BS_FMC_PFB0CR_B0SEBE (1U) //!< Bit field size in bits for FMC_PFB0CR_B0SEBE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0SEBE field. #define BR_FMC_PFB0CR_B0SEBE (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0SEBE)) #endif //! @brief Format value for bitfield FMC_PFB0CR_B0SEBE. #define BF_FMC_PFB0CR_B0SEBE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_B0SEBE), uint32_t) & BM_FMC_PFB0CR_B0SEBE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B0SEBE field to a new value. #define BW_FMC_PFB0CR_B0SEBE(v) (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0SEBE) = (v)) #endif //@} /*! * @name Register FMC_PFB0CR, field B0IPE[1] (RW) * * This bit controls whether prefetches (or speculative accesses) are initiated * in response to instruction fetches. * * Values: * - 0 - Do not prefetch in response to instruction fetches. * - 1 - Enable prefetches in response to instruction fetches. */ //@{ #define BP_FMC_PFB0CR_B0IPE (1U) //!< Bit position for FMC_PFB0CR_B0IPE. #define BM_FMC_PFB0CR_B0IPE (0x00000002U) //!< Bit mask for FMC_PFB0CR_B0IPE. #define BS_FMC_PFB0CR_B0IPE (1U) //!< Bit field size in bits for FMC_PFB0CR_B0IPE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0IPE field. #define BR_FMC_PFB0CR_B0IPE (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0IPE)) #endif //! @brief Format value for bitfield FMC_PFB0CR_B0IPE. #define BF_FMC_PFB0CR_B0IPE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_B0IPE), uint32_t) & BM_FMC_PFB0CR_B0IPE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B0IPE field to a new value. #define BW_FMC_PFB0CR_B0IPE(v) (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0IPE) = (v)) #endif //@} /*! * @name Register FMC_PFB0CR, field B0DPE[2] (RW) * * This bit controls whether prefetches (or speculative accesses) are initiated * in response to data references. * * Values: * - 0 - Do not prefetch in response to data references. * - 1 - Enable prefetches in response to data references. */ //@{ #define BP_FMC_PFB0CR_B0DPE (2U) //!< Bit position for FMC_PFB0CR_B0DPE. #define BM_FMC_PFB0CR_B0DPE (0x00000004U) //!< Bit mask for FMC_PFB0CR_B0DPE. #define BS_FMC_PFB0CR_B0DPE (1U) //!< Bit field size in bits for FMC_PFB0CR_B0DPE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0DPE field. #define BR_FMC_PFB0CR_B0DPE (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0DPE)) #endif //! @brief Format value for bitfield FMC_PFB0CR_B0DPE. #define BF_FMC_PFB0CR_B0DPE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_B0DPE), uint32_t) & BM_FMC_PFB0CR_B0DPE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B0DPE field to a new value. #define BW_FMC_PFB0CR_B0DPE(v) (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0DPE) = (v)) #endif //@} /*! * @name Register FMC_PFB0CR, field B0ICE[3] (RW) * * This bit controls whether instruction fetches are loaded into the cache. * * Values: * - 0 - Do not cache instruction fetches. * - 1 - Cache instruction fetches. */ //@{ #define BP_FMC_PFB0CR_B0ICE (3U) //!< Bit position for FMC_PFB0CR_B0ICE. #define BM_FMC_PFB0CR_B0ICE (0x00000008U) //!< Bit mask for FMC_PFB0CR_B0ICE. #define BS_FMC_PFB0CR_B0ICE (1U) //!< Bit field size in bits for FMC_PFB0CR_B0ICE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0ICE field. #define BR_FMC_PFB0CR_B0ICE (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0ICE)) #endif //! @brief Format value for bitfield FMC_PFB0CR_B0ICE. #define BF_FMC_PFB0CR_B0ICE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_B0ICE), uint32_t) & BM_FMC_PFB0CR_B0ICE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B0ICE field to a new value. #define BW_FMC_PFB0CR_B0ICE(v) (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0ICE) = (v)) #endif //@} /*! * @name Register FMC_PFB0CR, field B0DCE[4] (RW) * * This bit controls whether data references are loaded into the cache. * * Values: * - 0 - Do not cache data references. * - 1 - Cache data references. */ //@{ #define BP_FMC_PFB0CR_B0DCE (4U) //!< Bit position for FMC_PFB0CR_B0DCE. #define BM_FMC_PFB0CR_B0DCE (0x00000010U) //!< Bit mask for FMC_PFB0CR_B0DCE. #define BS_FMC_PFB0CR_B0DCE (1U) //!< Bit field size in bits for FMC_PFB0CR_B0DCE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0DCE field. #define BR_FMC_PFB0CR_B0DCE (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0DCE)) #endif //! @brief Format value for bitfield FMC_PFB0CR_B0DCE. #define BF_FMC_PFB0CR_B0DCE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_B0DCE), uint32_t) & BM_FMC_PFB0CR_B0DCE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B0DCE field to a new value. #define BW_FMC_PFB0CR_B0DCE(v) (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_B0DCE) = (v)) #endif //@} /*! * @name Register FMC_PFB0CR, field CRC[7:5] (RW) * * This 3-bit field defines the replacement algorithm for accesses that are * cached. * * Values: * - 000 - LRU replacement algorithm per set across all four ways * - 001 - Reserved * - 010 - Independent LRU with ways [0-1] for ifetches, [2-3] for data * - 011 - Independent LRU with ways [0-2] for ifetches, [3] for data * - 1xx - Reserved */ //@{ #define BP_FMC_PFB0CR_CRC (5U) //!< Bit position for FMC_PFB0CR_CRC. #define BM_FMC_PFB0CR_CRC (0x000000E0U) //!< Bit mask for FMC_PFB0CR_CRC. #define BS_FMC_PFB0CR_CRC (3U) //!< Bit field size in bits for FMC_PFB0CR_CRC. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_CRC field. #define BR_FMC_PFB0CR_CRC (HW_FMC_PFB0CR.B.CRC) #endif //! @brief Format value for bitfield FMC_PFB0CR_CRC. #define BF_FMC_PFB0CR_CRC(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_CRC), uint32_t) & BM_FMC_PFB0CR_CRC) #ifndef __LANGUAGE_ASM__ //! @brief Set the CRC field to a new value. #define BW_FMC_PFB0CR_CRC(v) (HW_FMC_PFB0CR_WR((HW_FMC_PFB0CR_RD() & ~BM_FMC_PFB0CR_CRC) | BF_FMC_PFB0CR_CRC(v))) #endif //@} /*! * @name Register FMC_PFB0CR, field B0MW[18:17] (RO) * * This read-only field defines the width of the bank 0 memory. * * Values: * - 00 - 32 bits * - 01 - 64 bits * - 10 - 128 bits * - 11 - Reserved */ //@{ #define BP_FMC_PFB0CR_B0MW (17U) //!< Bit position for FMC_PFB0CR_B0MW. #define BM_FMC_PFB0CR_B0MW (0x00060000U) //!< Bit mask for FMC_PFB0CR_B0MW. #define BS_FMC_PFB0CR_B0MW (2U) //!< Bit field size in bits for FMC_PFB0CR_B0MW. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0MW field. #define BR_FMC_PFB0CR_B0MW (HW_FMC_PFB0CR.B.B0MW) #endif //@} /*! * @name Register FMC_PFB0CR, field S_B_INV[19] (WORZ) * * This bit determines if the FMC's prefetch speculation buffer and the single * entry page buffer are to be invalidated (cleared). When this bit is written, * the speculation buffer and single entry buffer are immediately cleared. This bit * always reads as zero. * * Values: * - 0 - Speculation buffer and single entry buffer are not affected. * - 1 - Invalidate (clear) speculation buffer and single entry buffer. */ //@{ #define BP_FMC_PFB0CR_S_B_INV (19U) //!< Bit position for FMC_PFB0CR_S_B_INV. #define BM_FMC_PFB0CR_S_B_INV (0x00080000U) //!< Bit mask for FMC_PFB0CR_S_B_INV. #define BS_FMC_PFB0CR_S_B_INV (1U) //!< Bit field size in bits for FMC_PFB0CR_S_B_INV. //! @brief Format value for bitfield FMC_PFB0CR_S_B_INV. #define BF_FMC_PFB0CR_S_B_INV(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_S_B_INV), uint32_t) & BM_FMC_PFB0CR_S_B_INV) #ifndef __LANGUAGE_ASM__ //! @brief Set the S_B_INV field to a new value. #define BW_FMC_PFB0CR_S_B_INV(v) (BITBAND_ACCESS32(HW_FMC_PFB0CR_ADDR, BP_FMC_PFB0CR_S_B_INV) = (v)) #endif //@} /*! * @name Register FMC_PFB0CR, field CINV_WAY[23:20] (WORZ) * * These bits determine if the given cache way is to be invalidated (cleared). * When a bit within this field is written, the corresponding cache way is * immediately invalidated: the way's tag, data, and valid contents are cleared. This * field always reads as zero. Cache invalidation takes precedence over locking. * The cache is invalidated by system reset. System software is required to * maintain memory coherency when any segment of the flash memory is programmed or * erased. Accordingly, cache invalidations must occur after a programming or erase * event is completed and before the new memory image is accessed. The bit setting * definitions are for each bit in the field. * * Values: * - 0 - No cache way invalidation for the corresponding cache * - 1 - Invalidate cache way for the corresponding cache: clear the tag, data, * and vld bits of ways selected */ //@{ #define BP_FMC_PFB0CR_CINV_WAY (20U) //!< Bit position for FMC_PFB0CR_CINV_WAY. #define BM_FMC_PFB0CR_CINV_WAY (0x00F00000U) //!< Bit mask for FMC_PFB0CR_CINV_WAY. #define BS_FMC_PFB0CR_CINV_WAY (4U) //!< Bit field size in bits for FMC_PFB0CR_CINV_WAY. //! @brief Format value for bitfield FMC_PFB0CR_CINV_WAY. #define BF_FMC_PFB0CR_CINV_WAY(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_CINV_WAY), uint32_t) & BM_FMC_PFB0CR_CINV_WAY) #ifndef __LANGUAGE_ASM__ //! @brief Set the CINV_WAY field to a new value. #define BW_FMC_PFB0CR_CINV_WAY(v) (HW_FMC_PFB0CR_WR((HW_FMC_PFB0CR_RD() & ~BM_FMC_PFB0CR_CINV_WAY) | BF_FMC_PFB0CR_CINV_WAY(v))) #endif //@} /*! * @name Register FMC_PFB0CR, field CLCK_WAY[27:24] (RW) * * These bits determine if the given cache way is locked such that its contents * will not be displaced by future misses. The bit setting definitions are for * each bit in the field. * * Values: * - 0 - Cache way is unlocked and may be displaced * - 1 - Cache way is locked and its contents are not displaced */ //@{ #define BP_FMC_PFB0CR_CLCK_WAY (24U) //!< Bit position for FMC_PFB0CR_CLCK_WAY. #define BM_FMC_PFB0CR_CLCK_WAY (0x0F000000U) //!< Bit mask for FMC_PFB0CR_CLCK_WAY. #define BS_FMC_PFB0CR_CLCK_WAY (4U) //!< Bit field size in bits for FMC_PFB0CR_CLCK_WAY. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_CLCK_WAY field. #define BR_FMC_PFB0CR_CLCK_WAY (HW_FMC_PFB0CR.B.CLCK_WAY) #endif //! @brief Format value for bitfield FMC_PFB0CR_CLCK_WAY. #define BF_FMC_PFB0CR_CLCK_WAY(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB0CR_CLCK_WAY), uint32_t) & BM_FMC_PFB0CR_CLCK_WAY) #ifndef __LANGUAGE_ASM__ //! @brief Set the CLCK_WAY field to a new value. #define BW_FMC_PFB0CR_CLCK_WAY(v) (HW_FMC_PFB0CR_WR((HW_FMC_PFB0CR_RD() & ~BM_FMC_PFB0CR_CLCK_WAY) | BF_FMC_PFB0CR_CLCK_WAY(v))) #endif //@} /*! * @name Register FMC_PFB0CR, field B0RWSC[31:28] (RO) * * This read-only field defines the number of wait states required to access the * bank 0 flash memory. The relationship between the read access time of the * flash array (expressed in system clock cycles) and RWSC is defined as: Access * time of flash array [system clocks] = RWSC + 1 The FMC automatically calculates * this value based on the ratio of the system clock speed to the flash clock * speed. For example, when this ratio is 4:1, the field's value is 3h. */ //@{ #define BP_FMC_PFB0CR_B0RWSC (28U) //!< Bit position for FMC_PFB0CR_B0RWSC. #define BM_FMC_PFB0CR_B0RWSC (0xF0000000U) //!< Bit mask for FMC_PFB0CR_B0RWSC. #define BS_FMC_PFB0CR_B0RWSC (4U) //!< Bit field size in bits for FMC_PFB0CR_B0RWSC. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB0CR_B0RWSC field. #define BR_FMC_PFB0CR_B0RWSC (HW_FMC_PFB0CR.B.B0RWSC) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_PFB1CR - Flash Bank 1 Control Register //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_PFB1CR - Flash Bank 1 Control Register (RW) * * Reset value: 0x3004001FU * * This register has a format similar to that for PFB0CR, except it controls the * operation of flash bank 1, and the "global" cache control fields are empty. */ typedef union _hw_fmc_pfb1cr { uint32_t U; struct _hw_fmc_pfb1cr_bitfields { uint32_t B1SEBE : 1; //!< [0] Bank 1 Single Entry Buffer Enable uint32_t B1IPE : 1; //!< [1] Bank 1 Instruction Prefetch Enable uint32_t B1DPE : 1; //!< [2] Bank 1 Data Prefetch Enable uint32_t B1ICE : 1; //!< [3] Bank 1 Instruction Cache Enable uint32_t B1DCE : 1; //!< [4] Bank 1 Data Cache Enable uint32_t RESERVED0 : 12; //!< [16:5] uint32_t B1MW : 2; //!< [18:17] Bank 1 Memory Width uint32_t RESERVED1 : 9; //!< [27:19] uint32_t B1RWSC : 4; //!< [31:28] Bank 1 Read Wait State Control } B; } hw_fmc_pfb1cr_t; #endif /*! * @name Constants and macros for entire FMC_PFB1CR register */ //@{ #define HW_FMC_PFB1CR_ADDR (REGS_FMC_BASE + 0x8U) #ifndef __LANGUAGE_ASM__ #define HW_FMC_PFB1CR (*(__IO hw_fmc_pfb1cr_t *) HW_FMC_PFB1CR_ADDR) #define HW_FMC_PFB1CR_RD() (HW_FMC_PFB1CR.U) #define HW_FMC_PFB1CR_WR(v) (HW_FMC_PFB1CR.U = (v)) #define HW_FMC_PFB1CR_SET(v) (HW_FMC_PFB1CR_WR(HW_FMC_PFB1CR_RD() | (v))) #define HW_FMC_PFB1CR_CLR(v) (HW_FMC_PFB1CR_WR(HW_FMC_PFB1CR_RD() & ~(v))) #define HW_FMC_PFB1CR_TOG(v) (HW_FMC_PFB1CR_WR(HW_FMC_PFB1CR_RD() ^ (v))) #endif //@} /* * Constants & macros for individual FMC_PFB1CR bitfields */ /*! * @name Register FMC_PFB1CR, field B1SEBE[0] (RW) * * This bit controls whether the single entry buffer is enabled in response to * flash read accesses. Its operation is independent from bank 0's cache. A * high-to-low transition of this enable forces the page buffer to be invalidated. * * Values: * - 0 - Single entry buffer is disabled. * - 1 - Single entry buffer is enabled. */ //@{ #define BP_FMC_PFB1CR_B1SEBE (0U) //!< Bit position for FMC_PFB1CR_B1SEBE. #define BM_FMC_PFB1CR_B1SEBE (0x00000001U) //!< Bit mask for FMC_PFB1CR_B1SEBE. #define BS_FMC_PFB1CR_B1SEBE (1U) //!< Bit field size in bits for FMC_PFB1CR_B1SEBE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1SEBE field. #define BR_FMC_PFB1CR_B1SEBE (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1SEBE)) #endif //! @brief Format value for bitfield FMC_PFB1CR_B1SEBE. #define BF_FMC_PFB1CR_B1SEBE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB1CR_B1SEBE), uint32_t) & BM_FMC_PFB1CR_B1SEBE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B1SEBE field to a new value. #define BW_FMC_PFB1CR_B1SEBE(v) (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1SEBE) = (v)) #endif //@} /*! * @name Register FMC_PFB1CR, field B1IPE[1] (RW) * * This bit controls whether prefetches (or speculative accesses) are initiated * in response to instruction fetches. * * Values: * - 0 - Do not prefetch in response to instruction fetches. * - 1 - Enable prefetches in response to instruction fetches. */ //@{ #define BP_FMC_PFB1CR_B1IPE (1U) //!< Bit position for FMC_PFB1CR_B1IPE. #define BM_FMC_PFB1CR_B1IPE (0x00000002U) //!< Bit mask for FMC_PFB1CR_B1IPE. #define BS_FMC_PFB1CR_B1IPE (1U) //!< Bit field size in bits for FMC_PFB1CR_B1IPE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1IPE field. #define BR_FMC_PFB1CR_B1IPE (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1IPE)) #endif //! @brief Format value for bitfield FMC_PFB1CR_B1IPE. #define BF_FMC_PFB1CR_B1IPE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB1CR_B1IPE), uint32_t) & BM_FMC_PFB1CR_B1IPE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B1IPE field to a new value. #define BW_FMC_PFB1CR_B1IPE(v) (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1IPE) = (v)) #endif //@} /*! * @name Register FMC_PFB1CR, field B1DPE[2] (RW) * * This bit controls whether prefetches (or speculative accesses) are initiated * in response to data references. * * Values: * - 0 - Do not prefetch in response to data references. * - 1 - Enable prefetches in response to data references. */ //@{ #define BP_FMC_PFB1CR_B1DPE (2U) //!< Bit position for FMC_PFB1CR_B1DPE. #define BM_FMC_PFB1CR_B1DPE (0x00000004U) //!< Bit mask for FMC_PFB1CR_B1DPE. #define BS_FMC_PFB1CR_B1DPE (1U) //!< Bit field size in bits for FMC_PFB1CR_B1DPE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1DPE field. #define BR_FMC_PFB1CR_B1DPE (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1DPE)) #endif //! @brief Format value for bitfield FMC_PFB1CR_B1DPE. #define BF_FMC_PFB1CR_B1DPE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB1CR_B1DPE), uint32_t) & BM_FMC_PFB1CR_B1DPE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B1DPE field to a new value. #define BW_FMC_PFB1CR_B1DPE(v) (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1DPE) = (v)) #endif //@} /*! * @name Register FMC_PFB1CR, field B1ICE[3] (RW) * * This bit controls whether instruction fetches are loaded into the cache. * * Values: * - 0 - Do not cache instruction fetches. * - 1 - Cache instruction fetches. */ //@{ #define BP_FMC_PFB1CR_B1ICE (3U) //!< Bit position for FMC_PFB1CR_B1ICE. #define BM_FMC_PFB1CR_B1ICE (0x00000008U) //!< Bit mask for FMC_PFB1CR_B1ICE. #define BS_FMC_PFB1CR_B1ICE (1U) //!< Bit field size in bits for FMC_PFB1CR_B1ICE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1ICE field. #define BR_FMC_PFB1CR_B1ICE (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1ICE)) #endif //! @brief Format value for bitfield FMC_PFB1CR_B1ICE. #define BF_FMC_PFB1CR_B1ICE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB1CR_B1ICE), uint32_t) & BM_FMC_PFB1CR_B1ICE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B1ICE field to a new value. #define BW_FMC_PFB1CR_B1ICE(v) (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1ICE) = (v)) #endif //@} /*! * @name Register FMC_PFB1CR, field B1DCE[4] (RW) * * This bit controls whether data references are loaded into the cache. * * Values: * - 0 - Do not cache data references. * - 1 - Cache data references. */ //@{ #define BP_FMC_PFB1CR_B1DCE (4U) //!< Bit position for FMC_PFB1CR_B1DCE. #define BM_FMC_PFB1CR_B1DCE (0x00000010U) //!< Bit mask for FMC_PFB1CR_B1DCE. #define BS_FMC_PFB1CR_B1DCE (1U) //!< Bit field size in bits for FMC_PFB1CR_B1DCE. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1DCE field. #define BR_FMC_PFB1CR_B1DCE (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1DCE)) #endif //! @brief Format value for bitfield FMC_PFB1CR_B1DCE. #define BF_FMC_PFB1CR_B1DCE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_PFB1CR_B1DCE), uint32_t) & BM_FMC_PFB1CR_B1DCE) #ifndef __LANGUAGE_ASM__ //! @brief Set the B1DCE field to a new value. #define BW_FMC_PFB1CR_B1DCE(v) (BITBAND_ACCESS32(HW_FMC_PFB1CR_ADDR, BP_FMC_PFB1CR_B1DCE) = (v)) #endif //@} /*! * @name Register FMC_PFB1CR, field B1MW[18:17] (RO) * * This read-only field defines the width of the bank 1 memory. * * Values: * - 00 - 32 bits * - 01 - 64 bits * - 10 - 128 bits * - 11 - Reserved */ //@{ #define BP_FMC_PFB1CR_B1MW (17U) //!< Bit position for FMC_PFB1CR_B1MW. #define BM_FMC_PFB1CR_B1MW (0x00060000U) //!< Bit mask for FMC_PFB1CR_B1MW. #define BS_FMC_PFB1CR_B1MW (2U) //!< Bit field size in bits for FMC_PFB1CR_B1MW. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1MW field. #define BR_FMC_PFB1CR_B1MW (HW_FMC_PFB1CR.B.B1MW) #endif //@} /*! * @name Register FMC_PFB1CR, field B1RWSC[31:28] (RO) * * This read-only field defines the number of wait states required to access the * bank 1 flash memory. The relationship between the read access time of the * flash array (expressed in system clock cycles) and RWSC is defined as: Access * time of flash array [system clocks] = RWSC + 1 The FMC automatically calculates * this value based on the ratio of the system clock speed to the flash clock * speed. For example, when this ratio is 4:1, the field's value is 3h. */ //@{ #define BP_FMC_PFB1CR_B1RWSC (28U) //!< Bit position for FMC_PFB1CR_B1RWSC. #define BM_FMC_PFB1CR_B1RWSC (0xF0000000U) //!< Bit mask for FMC_PFB1CR_B1RWSC. #define BS_FMC_PFB1CR_B1RWSC (4U) //!< Bit field size in bits for FMC_PFB1CR_B1RWSC. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_PFB1CR_B1RWSC field. #define BR_FMC_PFB1CR_B1RWSC (HW_FMC_PFB1CR.B.B1RWSC) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_TAGVDW0Sn - Cache Tag Storage //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_TAGVDW0Sn - Cache Tag Storage (RW) * * Reset value: 0x00000000U * * The cache is a 4-way, set-associative cache with 4 sets. The ways are * numbered 0-3 and the sets are numbered 0-3. In TAGVDWxSy, x denotes the way, and y * denotes the set. This section represents tag/vld information for all sets in the * indicated way. */ typedef union _hw_fmc_tagvdw0sn { uint32_t U; struct _hw_fmc_tagvdw0sn_bitfields { uint32_t valid : 1; //!< [0] 1-bit valid for cache entry uint32_t RESERVED0 : 4; //!< [4:1] uint32_t tag : 14; //!< [18:5] 14-bit tag for cache entry uint32_t RESERVED1 : 13; //!< [31:19] } B; } hw_fmc_tagvdw0sn_t; #endif /*! * @name Constants and macros for entire FMC_TAGVDW0Sn register */ //@{ #define HW_FMC_TAGVDW0Sn_COUNT (4U) #define HW_FMC_TAGVDW0Sn_ADDR(n) (REGS_FMC_BASE + 0x100U + (0x4U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_TAGVDW0Sn(n) (*(__IO hw_fmc_tagvdw0sn_t *) HW_FMC_TAGVDW0Sn_ADDR(n)) #define HW_FMC_TAGVDW0Sn_RD(n) (HW_FMC_TAGVDW0Sn(n).U) #define HW_FMC_TAGVDW0Sn_WR(n, v) (HW_FMC_TAGVDW0Sn(n).U = (v)) #define HW_FMC_TAGVDW0Sn_SET(n, v) (HW_FMC_TAGVDW0Sn_WR(n, HW_FMC_TAGVDW0Sn_RD(n) | (v))) #define HW_FMC_TAGVDW0Sn_CLR(n, v) (HW_FMC_TAGVDW0Sn_WR(n, HW_FMC_TAGVDW0Sn_RD(n) & ~(v))) #define HW_FMC_TAGVDW0Sn_TOG(n, v) (HW_FMC_TAGVDW0Sn_WR(n, HW_FMC_TAGVDW0Sn_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_TAGVDW0Sn bitfields */ /*! * @name Register FMC_TAGVDW0Sn, field valid[0] (RW) */ //@{ #define BP_FMC_TAGVDW0Sn_valid (0U) //!< Bit position for FMC_TAGVDW0Sn_valid. #define BM_FMC_TAGVDW0Sn_valid (0x00000001U) //!< Bit mask for FMC_TAGVDW0Sn_valid. #define BS_FMC_TAGVDW0Sn_valid (1U) //!< Bit field size in bits for FMC_TAGVDW0Sn_valid. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW0Sn_valid field. #define BR_FMC_TAGVDW0Sn_valid(n) (BITBAND_ACCESS32(HW_FMC_TAGVDW0Sn_ADDR(n), BP_FMC_TAGVDW0Sn_valid)) #endif //! @brief Format value for bitfield FMC_TAGVDW0Sn_valid. #define BF_FMC_TAGVDW0Sn_valid(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW0Sn_valid), uint32_t) & BM_FMC_TAGVDW0Sn_valid) #ifndef __LANGUAGE_ASM__ //! @brief Set the valid field to a new value. #define BW_FMC_TAGVDW0Sn_valid(n, v) (BITBAND_ACCESS32(HW_FMC_TAGVDW0Sn_ADDR(n), BP_FMC_TAGVDW0Sn_valid) = (v)) #endif //@} /*! * @name Register FMC_TAGVDW0Sn, field tag[18:5] (RW) */ //@{ #define BP_FMC_TAGVDW0Sn_tag (5U) //!< Bit position for FMC_TAGVDW0Sn_tag. #define BM_FMC_TAGVDW0Sn_tag (0x0007FFE0U) //!< Bit mask for FMC_TAGVDW0Sn_tag. #define BS_FMC_TAGVDW0Sn_tag (14U) //!< Bit field size in bits for FMC_TAGVDW0Sn_tag. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW0Sn_tag field. #define BR_FMC_TAGVDW0Sn_tag(n) (HW_FMC_TAGVDW0Sn(n).B.tag) #endif //! @brief Format value for bitfield FMC_TAGVDW0Sn_tag. #define BF_FMC_TAGVDW0Sn_tag(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW0Sn_tag), uint32_t) & BM_FMC_TAGVDW0Sn_tag) #ifndef __LANGUAGE_ASM__ //! @brief Set the tag field to a new value. #define BW_FMC_TAGVDW0Sn_tag(n, v) (HW_FMC_TAGVDW0Sn_WR(n, (HW_FMC_TAGVDW0Sn_RD(n) & ~BM_FMC_TAGVDW0Sn_tag) | BF_FMC_TAGVDW0Sn_tag(v))) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_TAGVDW1Sn - Cache Tag Storage //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_TAGVDW1Sn - Cache Tag Storage (RW) * * Reset value: 0x00000000U * * The cache is a 4-way, set-associative cache with 4 sets. The ways are * numbered 0-3 and the sets are numbered 0-3. In TAGVDWxSy, x denotes the way, and y * denotes the set. This section represents tag/vld information for all sets in the * indicated way. */ typedef union _hw_fmc_tagvdw1sn { uint32_t U; struct _hw_fmc_tagvdw1sn_bitfields { uint32_t valid : 1; //!< [0] 1-bit valid for cache entry uint32_t RESERVED0 : 4; //!< [4:1] uint32_t tag : 14; //!< [18:5] 14-bit tag for cache entry uint32_t RESERVED1 : 13; //!< [31:19] } B; } hw_fmc_tagvdw1sn_t; #endif /*! * @name Constants and macros for entire FMC_TAGVDW1Sn register */ //@{ #define HW_FMC_TAGVDW1Sn_COUNT (4U) #define HW_FMC_TAGVDW1Sn_ADDR(n) (REGS_FMC_BASE + 0x110U + (0x4U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_TAGVDW1Sn(n) (*(__IO hw_fmc_tagvdw1sn_t *) HW_FMC_TAGVDW1Sn_ADDR(n)) #define HW_FMC_TAGVDW1Sn_RD(n) (HW_FMC_TAGVDW1Sn(n).U) #define HW_FMC_TAGVDW1Sn_WR(n, v) (HW_FMC_TAGVDW1Sn(n).U = (v)) #define HW_FMC_TAGVDW1Sn_SET(n, v) (HW_FMC_TAGVDW1Sn_WR(n, HW_FMC_TAGVDW1Sn_RD(n) | (v))) #define HW_FMC_TAGVDW1Sn_CLR(n, v) (HW_FMC_TAGVDW1Sn_WR(n, HW_FMC_TAGVDW1Sn_RD(n) & ~(v))) #define HW_FMC_TAGVDW1Sn_TOG(n, v) (HW_FMC_TAGVDW1Sn_WR(n, HW_FMC_TAGVDW1Sn_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_TAGVDW1Sn bitfields */ /*! * @name Register FMC_TAGVDW1Sn, field valid[0] (RW) */ //@{ #define BP_FMC_TAGVDW1Sn_valid (0U) //!< Bit position for FMC_TAGVDW1Sn_valid. #define BM_FMC_TAGVDW1Sn_valid (0x00000001U) //!< Bit mask for FMC_TAGVDW1Sn_valid. #define BS_FMC_TAGVDW1Sn_valid (1U) //!< Bit field size in bits for FMC_TAGVDW1Sn_valid. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW1Sn_valid field. #define BR_FMC_TAGVDW1Sn_valid(n) (BITBAND_ACCESS32(HW_FMC_TAGVDW1Sn_ADDR(n), BP_FMC_TAGVDW1Sn_valid)) #endif //! @brief Format value for bitfield FMC_TAGVDW1Sn_valid. #define BF_FMC_TAGVDW1Sn_valid(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW1Sn_valid), uint32_t) & BM_FMC_TAGVDW1Sn_valid) #ifndef __LANGUAGE_ASM__ //! @brief Set the valid field to a new value. #define BW_FMC_TAGVDW1Sn_valid(n, v) (BITBAND_ACCESS32(HW_FMC_TAGVDW1Sn_ADDR(n), BP_FMC_TAGVDW1Sn_valid) = (v)) #endif //@} /*! * @name Register FMC_TAGVDW1Sn, field tag[18:5] (RW) */ //@{ #define BP_FMC_TAGVDW1Sn_tag (5U) //!< Bit position for FMC_TAGVDW1Sn_tag. #define BM_FMC_TAGVDW1Sn_tag (0x0007FFE0U) //!< Bit mask for FMC_TAGVDW1Sn_tag. #define BS_FMC_TAGVDW1Sn_tag (14U) //!< Bit field size in bits for FMC_TAGVDW1Sn_tag. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW1Sn_tag field. #define BR_FMC_TAGVDW1Sn_tag(n) (HW_FMC_TAGVDW1Sn(n).B.tag) #endif //! @brief Format value for bitfield FMC_TAGVDW1Sn_tag. #define BF_FMC_TAGVDW1Sn_tag(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW1Sn_tag), uint32_t) & BM_FMC_TAGVDW1Sn_tag) #ifndef __LANGUAGE_ASM__ //! @brief Set the tag field to a new value. #define BW_FMC_TAGVDW1Sn_tag(n, v) (HW_FMC_TAGVDW1Sn_WR(n, (HW_FMC_TAGVDW1Sn_RD(n) & ~BM_FMC_TAGVDW1Sn_tag) | BF_FMC_TAGVDW1Sn_tag(v))) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_TAGVDW2Sn - Cache Tag Storage //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_TAGVDW2Sn - Cache Tag Storage (RW) * * Reset value: 0x00000000U * * The cache is a 4-way, set-associative cache with 4 sets. The ways are * numbered 0-3 and the sets are numbered 0-3. In TAGVDWxSy, x denotes the way, and y * denotes the set. This section represents tag/vld information for all sets in the * indicated way. */ typedef union _hw_fmc_tagvdw2sn { uint32_t U; struct _hw_fmc_tagvdw2sn_bitfields { uint32_t valid : 1; //!< [0] 1-bit valid for cache entry uint32_t RESERVED0 : 4; //!< [4:1] uint32_t tag : 14; //!< [18:5] 14-bit tag for cache entry uint32_t RESERVED1 : 13; //!< [31:19] } B; } hw_fmc_tagvdw2sn_t; #endif /*! * @name Constants and macros for entire FMC_TAGVDW2Sn register */ //@{ #define HW_FMC_TAGVDW2Sn_COUNT (4U) #define HW_FMC_TAGVDW2Sn_ADDR(n) (REGS_FMC_BASE + 0x120U + (0x4U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_TAGVDW2Sn(n) (*(__IO hw_fmc_tagvdw2sn_t *) HW_FMC_TAGVDW2Sn_ADDR(n)) #define HW_FMC_TAGVDW2Sn_RD(n) (HW_FMC_TAGVDW2Sn(n).U) #define HW_FMC_TAGVDW2Sn_WR(n, v) (HW_FMC_TAGVDW2Sn(n).U = (v)) #define HW_FMC_TAGVDW2Sn_SET(n, v) (HW_FMC_TAGVDW2Sn_WR(n, HW_FMC_TAGVDW2Sn_RD(n) | (v))) #define HW_FMC_TAGVDW2Sn_CLR(n, v) (HW_FMC_TAGVDW2Sn_WR(n, HW_FMC_TAGVDW2Sn_RD(n) & ~(v))) #define HW_FMC_TAGVDW2Sn_TOG(n, v) (HW_FMC_TAGVDW2Sn_WR(n, HW_FMC_TAGVDW2Sn_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_TAGVDW2Sn bitfields */ /*! * @name Register FMC_TAGVDW2Sn, field valid[0] (RW) */ //@{ #define BP_FMC_TAGVDW2Sn_valid (0U) //!< Bit position for FMC_TAGVDW2Sn_valid. #define BM_FMC_TAGVDW2Sn_valid (0x00000001U) //!< Bit mask for FMC_TAGVDW2Sn_valid. #define BS_FMC_TAGVDW2Sn_valid (1U) //!< Bit field size in bits for FMC_TAGVDW2Sn_valid. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW2Sn_valid field. #define BR_FMC_TAGVDW2Sn_valid(n) (BITBAND_ACCESS32(HW_FMC_TAGVDW2Sn_ADDR(n), BP_FMC_TAGVDW2Sn_valid)) #endif //! @brief Format value for bitfield FMC_TAGVDW2Sn_valid. #define BF_FMC_TAGVDW2Sn_valid(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW2Sn_valid), uint32_t) & BM_FMC_TAGVDW2Sn_valid) #ifndef __LANGUAGE_ASM__ //! @brief Set the valid field to a new value. #define BW_FMC_TAGVDW2Sn_valid(n, v) (BITBAND_ACCESS32(HW_FMC_TAGVDW2Sn_ADDR(n), BP_FMC_TAGVDW2Sn_valid) = (v)) #endif //@} /*! * @name Register FMC_TAGVDW2Sn, field tag[18:5] (RW) */ //@{ #define BP_FMC_TAGVDW2Sn_tag (5U) //!< Bit position for FMC_TAGVDW2Sn_tag. #define BM_FMC_TAGVDW2Sn_tag (0x0007FFE0U) //!< Bit mask for FMC_TAGVDW2Sn_tag. #define BS_FMC_TAGVDW2Sn_tag (14U) //!< Bit field size in bits for FMC_TAGVDW2Sn_tag. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW2Sn_tag field. #define BR_FMC_TAGVDW2Sn_tag(n) (HW_FMC_TAGVDW2Sn(n).B.tag) #endif //! @brief Format value for bitfield FMC_TAGVDW2Sn_tag. #define BF_FMC_TAGVDW2Sn_tag(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW2Sn_tag), uint32_t) & BM_FMC_TAGVDW2Sn_tag) #ifndef __LANGUAGE_ASM__ //! @brief Set the tag field to a new value. #define BW_FMC_TAGVDW2Sn_tag(n, v) (HW_FMC_TAGVDW2Sn_WR(n, (HW_FMC_TAGVDW2Sn_RD(n) & ~BM_FMC_TAGVDW2Sn_tag) | BF_FMC_TAGVDW2Sn_tag(v))) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_TAGVDW3Sn - Cache Tag Storage //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_TAGVDW3Sn - Cache Tag Storage (RW) * * Reset value: 0x00000000U * * The cache is a 4-way, set-associative cache with 4 sets. The ways are * numbered 0-3 and the sets are numbered 0-3. In TAGVDWxSy, x denotes the way, and y * denotes the set. This section represents tag/vld information for all sets in the * indicated way. */ typedef union _hw_fmc_tagvdw3sn { uint32_t U; struct _hw_fmc_tagvdw3sn_bitfields { uint32_t valid : 1; //!< [0] 1-bit valid for cache entry uint32_t RESERVED0 : 4; //!< [4:1] uint32_t tag : 14; //!< [18:5] 14-bit tag for cache entry uint32_t RESERVED1 : 13; //!< [31:19] } B; } hw_fmc_tagvdw3sn_t; #endif /*! * @name Constants and macros for entire FMC_TAGVDW3Sn register */ //@{ #define HW_FMC_TAGVDW3Sn_COUNT (4U) #define HW_FMC_TAGVDW3Sn_ADDR(n) (REGS_FMC_BASE + 0x130U + (0x4U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_TAGVDW3Sn(n) (*(__IO hw_fmc_tagvdw3sn_t *) HW_FMC_TAGVDW3Sn_ADDR(n)) #define HW_FMC_TAGVDW3Sn_RD(n) (HW_FMC_TAGVDW3Sn(n).U) #define HW_FMC_TAGVDW3Sn_WR(n, v) (HW_FMC_TAGVDW3Sn(n).U = (v)) #define HW_FMC_TAGVDW3Sn_SET(n, v) (HW_FMC_TAGVDW3Sn_WR(n, HW_FMC_TAGVDW3Sn_RD(n) | (v))) #define HW_FMC_TAGVDW3Sn_CLR(n, v) (HW_FMC_TAGVDW3Sn_WR(n, HW_FMC_TAGVDW3Sn_RD(n) & ~(v))) #define HW_FMC_TAGVDW3Sn_TOG(n, v) (HW_FMC_TAGVDW3Sn_WR(n, HW_FMC_TAGVDW3Sn_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_TAGVDW3Sn bitfields */ /*! * @name Register FMC_TAGVDW3Sn, field valid[0] (RW) */ //@{ #define BP_FMC_TAGVDW3Sn_valid (0U) //!< Bit position for FMC_TAGVDW3Sn_valid. #define BM_FMC_TAGVDW3Sn_valid (0x00000001U) //!< Bit mask for FMC_TAGVDW3Sn_valid. #define BS_FMC_TAGVDW3Sn_valid (1U) //!< Bit field size in bits for FMC_TAGVDW3Sn_valid. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW3Sn_valid field. #define BR_FMC_TAGVDW3Sn_valid(n) (BITBAND_ACCESS32(HW_FMC_TAGVDW3Sn_ADDR(n), BP_FMC_TAGVDW3Sn_valid)) #endif //! @brief Format value for bitfield FMC_TAGVDW3Sn_valid. #define BF_FMC_TAGVDW3Sn_valid(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW3Sn_valid), uint32_t) & BM_FMC_TAGVDW3Sn_valid) #ifndef __LANGUAGE_ASM__ //! @brief Set the valid field to a new value. #define BW_FMC_TAGVDW3Sn_valid(n, v) (BITBAND_ACCESS32(HW_FMC_TAGVDW3Sn_ADDR(n), BP_FMC_TAGVDW3Sn_valid) = (v)) #endif //@} /*! * @name Register FMC_TAGVDW3Sn, field tag[18:5] (RW) */ //@{ #define BP_FMC_TAGVDW3Sn_tag (5U) //!< Bit position for FMC_TAGVDW3Sn_tag. #define BM_FMC_TAGVDW3Sn_tag (0x0007FFE0U) //!< Bit mask for FMC_TAGVDW3Sn_tag. #define BS_FMC_TAGVDW3Sn_tag (14U) //!< Bit field size in bits for FMC_TAGVDW3Sn_tag. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_TAGVDW3Sn_tag field. #define BR_FMC_TAGVDW3Sn_tag(n) (HW_FMC_TAGVDW3Sn(n).B.tag) #endif //! @brief Format value for bitfield FMC_TAGVDW3Sn_tag. #define BF_FMC_TAGVDW3Sn_tag(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_TAGVDW3Sn_tag), uint32_t) & BM_FMC_TAGVDW3Sn_tag) #ifndef __LANGUAGE_ASM__ //! @brief Set the tag field to a new value. #define BW_FMC_TAGVDW3Sn_tag(n, v) (HW_FMC_TAGVDW3Sn_WR(n, (HW_FMC_TAGVDW3Sn_RD(n) & ~BM_FMC_TAGVDW3Sn_tag) | BF_FMC_TAGVDW3Sn_tag(v))) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW0SnU - Cache Data Storage (upper word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW0SnU - Cache Data Storage (upper word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the upper word (bits * [63:32]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw0snu { uint32_t U; struct _hw_fmc_dataw0snu_bitfields { uint32_t data : 32; //!< [31:0] Bits [63:32] of data entry } B; } hw_fmc_dataw0snu_t; #endif /*! * @name Constants and macros for entire FMC_DATAW0SnU register */ //@{ #define HW_FMC_DATAW0SnU_COUNT (4U) #define HW_FMC_DATAW0SnU_ADDR(n) (REGS_FMC_BASE + 0x200U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW0SnU(n) (*(__IO hw_fmc_dataw0snu_t *) HW_FMC_DATAW0SnU_ADDR(n)) #define HW_FMC_DATAW0SnU_RD(n) (HW_FMC_DATAW0SnU(n).U) #define HW_FMC_DATAW0SnU_WR(n, v) (HW_FMC_DATAW0SnU(n).U = (v)) #define HW_FMC_DATAW0SnU_SET(n, v) (HW_FMC_DATAW0SnU_WR(n, HW_FMC_DATAW0SnU_RD(n) | (v))) #define HW_FMC_DATAW0SnU_CLR(n, v) (HW_FMC_DATAW0SnU_WR(n, HW_FMC_DATAW0SnU_RD(n) & ~(v))) #define HW_FMC_DATAW0SnU_TOG(n, v) (HW_FMC_DATAW0SnU_WR(n, HW_FMC_DATAW0SnU_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW0SnU bitfields */ /*! * @name Register FMC_DATAW0SnU, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW0SnU_data (0U) //!< Bit position for FMC_DATAW0SnU_data. #define BM_FMC_DATAW0SnU_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW0SnU_data. #define BS_FMC_DATAW0SnU_data (32U) //!< Bit field size in bits for FMC_DATAW0SnU_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW0SnU_data field. #define BR_FMC_DATAW0SnU_data(n) (HW_FMC_DATAW0SnU(n).U) #endif //! @brief Format value for bitfield FMC_DATAW0SnU_data. #define BF_FMC_DATAW0SnU_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW0SnU_data), uint32_t) & BM_FMC_DATAW0SnU_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW0SnU_data(n, v) (HW_FMC_DATAW0SnU_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW0SnL - Cache Data Storage (lower word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW0SnL - Cache Data Storage (lower word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the lower word (bits * [31:0]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw0snl { uint32_t U; struct _hw_fmc_dataw0snl_bitfields { uint32_t data : 32; //!< [31:0] Bits [31:0] of data entry } B; } hw_fmc_dataw0snl_t; #endif /*! * @name Constants and macros for entire FMC_DATAW0SnL register */ //@{ #define HW_FMC_DATAW0SnL_COUNT (4U) #define HW_FMC_DATAW0SnL_ADDR(n) (REGS_FMC_BASE + 0x204U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW0SnL(n) (*(__IO hw_fmc_dataw0snl_t *) HW_FMC_DATAW0SnL_ADDR(n)) #define HW_FMC_DATAW0SnL_RD(n) (HW_FMC_DATAW0SnL(n).U) #define HW_FMC_DATAW0SnL_WR(n, v) (HW_FMC_DATAW0SnL(n).U = (v)) #define HW_FMC_DATAW0SnL_SET(n, v) (HW_FMC_DATAW0SnL_WR(n, HW_FMC_DATAW0SnL_RD(n) | (v))) #define HW_FMC_DATAW0SnL_CLR(n, v) (HW_FMC_DATAW0SnL_WR(n, HW_FMC_DATAW0SnL_RD(n) & ~(v))) #define HW_FMC_DATAW0SnL_TOG(n, v) (HW_FMC_DATAW0SnL_WR(n, HW_FMC_DATAW0SnL_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW0SnL bitfields */ /*! * @name Register FMC_DATAW0SnL, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW0SnL_data (0U) //!< Bit position for FMC_DATAW0SnL_data. #define BM_FMC_DATAW0SnL_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW0SnL_data. #define BS_FMC_DATAW0SnL_data (32U) //!< Bit field size in bits for FMC_DATAW0SnL_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW0SnL_data field. #define BR_FMC_DATAW0SnL_data(n) (HW_FMC_DATAW0SnL(n).U) #endif //! @brief Format value for bitfield FMC_DATAW0SnL_data. #define BF_FMC_DATAW0SnL_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW0SnL_data), uint32_t) & BM_FMC_DATAW0SnL_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW0SnL_data(n, v) (HW_FMC_DATAW0SnL_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW1SnU - Cache Data Storage (upper word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW1SnU - Cache Data Storage (upper word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the upper word (bits * [63:32]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw1snu { uint32_t U; struct _hw_fmc_dataw1snu_bitfields { uint32_t data : 32; //!< [31:0] Bits [63:32] of data entry } B; } hw_fmc_dataw1snu_t; #endif /*! * @name Constants and macros for entire FMC_DATAW1SnU register */ //@{ #define HW_FMC_DATAW1SnU_COUNT (4U) #define HW_FMC_DATAW1SnU_ADDR(n) (REGS_FMC_BASE + 0x220U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW1SnU(n) (*(__IO hw_fmc_dataw1snu_t *) HW_FMC_DATAW1SnU_ADDR(n)) #define HW_FMC_DATAW1SnU_RD(n) (HW_FMC_DATAW1SnU(n).U) #define HW_FMC_DATAW1SnU_WR(n, v) (HW_FMC_DATAW1SnU(n).U = (v)) #define HW_FMC_DATAW1SnU_SET(n, v) (HW_FMC_DATAW1SnU_WR(n, HW_FMC_DATAW1SnU_RD(n) | (v))) #define HW_FMC_DATAW1SnU_CLR(n, v) (HW_FMC_DATAW1SnU_WR(n, HW_FMC_DATAW1SnU_RD(n) & ~(v))) #define HW_FMC_DATAW1SnU_TOG(n, v) (HW_FMC_DATAW1SnU_WR(n, HW_FMC_DATAW1SnU_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW1SnU bitfields */ /*! * @name Register FMC_DATAW1SnU, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW1SnU_data (0U) //!< Bit position for FMC_DATAW1SnU_data. #define BM_FMC_DATAW1SnU_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW1SnU_data. #define BS_FMC_DATAW1SnU_data (32U) //!< Bit field size in bits for FMC_DATAW1SnU_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW1SnU_data field. #define BR_FMC_DATAW1SnU_data(n) (HW_FMC_DATAW1SnU(n).U) #endif //! @brief Format value for bitfield FMC_DATAW1SnU_data. #define BF_FMC_DATAW1SnU_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW1SnU_data), uint32_t) & BM_FMC_DATAW1SnU_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW1SnU_data(n, v) (HW_FMC_DATAW1SnU_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW1SnL - Cache Data Storage (lower word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW1SnL - Cache Data Storage (lower word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the lower word (bits * [31:0]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw1snl { uint32_t U; struct _hw_fmc_dataw1snl_bitfields { uint32_t data : 32; //!< [31:0] Bits [31:0] of data entry } B; } hw_fmc_dataw1snl_t; #endif /*! * @name Constants and macros for entire FMC_DATAW1SnL register */ //@{ #define HW_FMC_DATAW1SnL_COUNT (4U) #define HW_FMC_DATAW1SnL_ADDR(n) (REGS_FMC_BASE + 0x224U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW1SnL(n) (*(__IO hw_fmc_dataw1snl_t *) HW_FMC_DATAW1SnL_ADDR(n)) #define HW_FMC_DATAW1SnL_RD(n) (HW_FMC_DATAW1SnL(n).U) #define HW_FMC_DATAW1SnL_WR(n, v) (HW_FMC_DATAW1SnL(n).U = (v)) #define HW_FMC_DATAW1SnL_SET(n, v) (HW_FMC_DATAW1SnL_WR(n, HW_FMC_DATAW1SnL_RD(n) | (v))) #define HW_FMC_DATAW1SnL_CLR(n, v) (HW_FMC_DATAW1SnL_WR(n, HW_FMC_DATAW1SnL_RD(n) & ~(v))) #define HW_FMC_DATAW1SnL_TOG(n, v) (HW_FMC_DATAW1SnL_WR(n, HW_FMC_DATAW1SnL_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW1SnL bitfields */ /*! * @name Register FMC_DATAW1SnL, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW1SnL_data (0U) //!< Bit position for FMC_DATAW1SnL_data. #define BM_FMC_DATAW1SnL_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW1SnL_data. #define BS_FMC_DATAW1SnL_data (32U) //!< Bit field size in bits for FMC_DATAW1SnL_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW1SnL_data field. #define BR_FMC_DATAW1SnL_data(n) (HW_FMC_DATAW1SnL(n).U) #endif //! @brief Format value for bitfield FMC_DATAW1SnL_data. #define BF_FMC_DATAW1SnL_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW1SnL_data), uint32_t) & BM_FMC_DATAW1SnL_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW1SnL_data(n, v) (HW_FMC_DATAW1SnL_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW2SnU - Cache Data Storage (upper word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW2SnU - Cache Data Storage (upper word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the upper word (bits * [63:32]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw2snu { uint32_t U; struct _hw_fmc_dataw2snu_bitfields { uint32_t data : 32; //!< [31:0] Bits [63:32] of data entry } B; } hw_fmc_dataw2snu_t; #endif /*! * @name Constants and macros for entire FMC_DATAW2SnU register */ //@{ #define HW_FMC_DATAW2SnU_COUNT (4U) #define HW_FMC_DATAW2SnU_ADDR(n) (REGS_FMC_BASE + 0x240U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW2SnU(n) (*(__IO hw_fmc_dataw2snu_t *) HW_FMC_DATAW2SnU_ADDR(n)) #define HW_FMC_DATAW2SnU_RD(n) (HW_FMC_DATAW2SnU(n).U) #define HW_FMC_DATAW2SnU_WR(n, v) (HW_FMC_DATAW2SnU(n).U = (v)) #define HW_FMC_DATAW2SnU_SET(n, v) (HW_FMC_DATAW2SnU_WR(n, HW_FMC_DATAW2SnU_RD(n) | (v))) #define HW_FMC_DATAW2SnU_CLR(n, v) (HW_FMC_DATAW2SnU_WR(n, HW_FMC_DATAW2SnU_RD(n) & ~(v))) #define HW_FMC_DATAW2SnU_TOG(n, v) (HW_FMC_DATAW2SnU_WR(n, HW_FMC_DATAW2SnU_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW2SnU bitfields */ /*! * @name Register FMC_DATAW2SnU, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW2SnU_data (0U) //!< Bit position for FMC_DATAW2SnU_data. #define BM_FMC_DATAW2SnU_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW2SnU_data. #define BS_FMC_DATAW2SnU_data (32U) //!< Bit field size in bits for FMC_DATAW2SnU_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW2SnU_data field. #define BR_FMC_DATAW2SnU_data(n) (HW_FMC_DATAW2SnU(n).U) #endif //! @brief Format value for bitfield FMC_DATAW2SnU_data. #define BF_FMC_DATAW2SnU_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW2SnU_data), uint32_t) & BM_FMC_DATAW2SnU_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW2SnU_data(n, v) (HW_FMC_DATAW2SnU_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW2SnL - Cache Data Storage (lower word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW2SnL - Cache Data Storage (lower word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the lower word (bits * [31:0]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw2snl { uint32_t U; struct _hw_fmc_dataw2snl_bitfields { uint32_t data : 32; //!< [31:0] Bits [31:0] of data entry } B; } hw_fmc_dataw2snl_t; #endif /*! * @name Constants and macros for entire FMC_DATAW2SnL register */ //@{ #define HW_FMC_DATAW2SnL_COUNT (4U) #define HW_FMC_DATAW2SnL_ADDR(n) (REGS_FMC_BASE + 0x244U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW2SnL(n) (*(__IO hw_fmc_dataw2snl_t *) HW_FMC_DATAW2SnL_ADDR(n)) #define HW_FMC_DATAW2SnL_RD(n) (HW_FMC_DATAW2SnL(n).U) #define HW_FMC_DATAW2SnL_WR(n, v) (HW_FMC_DATAW2SnL(n).U = (v)) #define HW_FMC_DATAW2SnL_SET(n, v) (HW_FMC_DATAW2SnL_WR(n, HW_FMC_DATAW2SnL_RD(n) | (v))) #define HW_FMC_DATAW2SnL_CLR(n, v) (HW_FMC_DATAW2SnL_WR(n, HW_FMC_DATAW2SnL_RD(n) & ~(v))) #define HW_FMC_DATAW2SnL_TOG(n, v) (HW_FMC_DATAW2SnL_WR(n, HW_FMC_DATAW2SnL_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW2SnL bitfields */ /*! * @name Register FMC_DATAW2SnL, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW2SnL_data (0U) //!< Bit position for FMC_DATAW2SnL_data. #define BM_FMC_DATAW2SnL_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW2SnL_data. #define BS_FMC_DATAW2SnL_data (32U) //!< Bit field size in bits for FMC_DATAW2SnL_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW2SnL_data field. #define BR_FMC_DATAW2SnL_data(n) (HW_FMC_DATAW2SnL(n).U) #endif //! @brief Format value for bitfield FMC_DATAW2SnL_data. #define BF_FMC_DATAW2SnL_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW2SnL_data), uint32_t) & BM_FMC_DATAW2SnL_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW2SnL_data(n, v) (HW_FMC_DATAW2SnL_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW3SnU - Cache Data Storage (upper word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW3SnU - Cache Data Storage (upper word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the upper word (bits * [63:32]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw3snu { uint32_t U; struct _hw_fmc_dataw3snu_bitfields { uint32_t data : 32; //!< [31:0] Bits [63:32] of data entry } B; } hw_fmc_dataw3snu_t; #endif /*! * @name Constants and macros for entire FMC_DATAW3SnU register */ //@{ #define HW_FMC_DATAW3SnU_COUNT (4U) #define HW_FMC_DATAW3SnU_ADDR(n) (REGS_FMC_BASE + 0x260U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW3SnU(n) (*(__IO hw_fmc_dataw3snu_t *) HW_FMC_DATAW3SnU_ADDR(n)) #define HW_FMC_DATAW3SnU_RD(n) (HW_FMC_DATAW3SnU(n).U) #define HW_FMC_DATAW3SnU_WR(n, v) (HW_FMC_DATAW3SnU(n).U = (v)) #define HW_FMC_DATAW3SnU_SET(n, v) (HW_FMC_DATAW3SnU_WR(n, HW_FMC_DATAW3SnU_RD(n) | (v))) #define HW_FMC_DATAW3SnU_CLR(n, v) (HW_FMC_DATAW3SnU_WR(n, HW_FMC_DATAW3SnU_RD(n) & ~(v))) #define HW_FMC_DATAW3SnU_TOG(n, v) (HW_FMC_DATAW3SnU_WR(n, HW_FMC_DATAW3SnU_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW3SnU bitfields */ /*! * @name Register FMC_DATAW3SnU, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW3SnU_data (0U) //!< Bit position for FMC_DATAW3SnU_data. #define BM_FMC_DATAW3SnU_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW3SnU_data. #define BS_FMC_DATAW3SnU_data (32U) //!< Bit field size in bits for FMC_DATAW3SnU_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW3SnU_data field. #define BR_FMC_DATAW3SnU_data(n) (HW_FMC_DATAW3SnU(n).U) #endif //! @brief Format value for bitfield FMC_DATAW3SnU_data. #define BF_FMC_DATAW3SnU_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW3SnU_data), uint32_t) & BM_FMC_DATAW3SnU_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW3SnU_data(n, v) (HW_FMC_DATAW3SnU_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // HW_FMC_DATAW3SnL - Cache Data Storage (lower word) //------------------------------------------------------------------------------------------- #ifndef __LANGUAGE_ASM__ /*! * @brief HW_FMC_DATAW3SnL - Cache Data Storage (lower word) (RW) * * Reset value: 0x00000000U * * The cache of 64-bit entries is a 4-way, set-associative cache with 4 sets. * The ways are numbered 0-3 and the sets are numbered 0-3. In DATAWxSyU and * DATAWxSyL, x denotes the way, y denotes the set, and U and L represent upper and * lower word, respectively. This section represents data for the lower word (bits * [31:0]) of all sets in the indicated way. */ typedef union _hw_fmc_dataw3snl { uint32_t U; struct _hw_fmc_dataw3snl_bitfields { uint32_t data : 32; //!< [31:0] Bits [31:0] of data entry } B; } hw_fmc_dataw3snl_t; #endif /*! * @name Constants and macros for entire FMC_DATAW3SnL register */ //@{ #define HW_FMC_DATAW3SnL_COUNT (4U) #define HW_FMC_DATAW3SnL_ADDR(n) (REGS_FMC_BASE + 0x264U + (0x8U * n)) #ifndef __LANGUAGE_ASM__ #define HW_FMC_DATAW3SnL(n) (*(__IO hw_fmc_dataw3snl_t *) HW_FMC_DATAW3SnL_ADDR(n)) #define HW_FMC_DATAW3SnL_RD(n) (HW_FMC_DATAW3SnL(n).U) #define HW_FMC_DATAW3SnL_WR(n, v) (HW_FMC_DATAW3SnL(n).U = (v)) #define HW_FMC_DATAW3SnL_SET(n, v) (HW_FMC_DATAW3SnL_WR(n, HW_FMC_DATAW3SnL_RD(n) | (v))) #define HW_FMC_DATAW3SnL_CLR(n, v) (HW_FMC_DATAW3SnL_WR(n, HW_FMC_DATAW3SnL_RD(n) & ~(v))) #define HW_FMC_DATAW3SnL_TOG(n, v) (HW_FMC_DATAW3SnL_WR(n, HW_FMC_DATAW3SnL_RD(n) ^ (v))) #endif //@} /* * Constants & macros for individual FMC_DATAW3SnL bitfields */ /*! * @name Register FMC_DATAW3SnL, field data[31:0] (RW) */ //@{ #define BP_FMC_DATAW3SnL_data (0U) //!< Bit position for FMC_DATAW3SnL_data. #define BM_FMC_DATAW3SnL_data (0xFFFFFFFFU) //!< Bit mask for FMC_DATAW3SnL_data. #define BS_FMC_DATAW3SnL_data (32U) //!< Bit field size in bits for FMC_DATAW3SnL_data. #ifndef __LANGUAGE_ASM__ //! @brief Read current value of the FMC_DATAW3SnL_data field. #define BR_FMC_DATAW3SnL_data(n) (HW_FMC_DATAW3SnL(n).U) #endif //! @brief Format value for bitfield FMC_DATAW3SnL_data. #define BF_FMC_DATAW3SnL_data(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_FMC_DATAW3SnL_data), uint32_t) & BM_FMC_DATAW3SnL_data) #ifndef __LANGUAGE_ASM__ //! @brief Set the data field to a new value. #define BW_FMC_DATAW3SnL_data(n, v) (HW_FMC_DATAW3SnL_WR(n, v)) #endif //@} //------------------------------------------------------------------------------------------- // hw_fmc_t - module struct //------------------------------------------------------------------------------------------- /*! * @brief All FMC module registers. */ #ifndef __LANGUAGE_ASM__ #pragma pack(1) typedef struct _hw_fmc { __IO hw_fmc_pfapr_t PFAPR; //!< [0x0] Flash Access Protection Register __IO hw_fmc_pfb0cr_t PFB0CR; //!< [0x4] Flash Bank 0 Control Register __IO hw_fmc_pfb1cr_t PFB1CR; //!< [0x8] Flash Bank 1 Control Register uint8_t _reserved0[244]; __IO hw_fmc_tagvdw0sn_t TAGVDW0Sn[4]; //!< [0x100] Cache Tag Storage __IO hw_fmc_tagvdw1sn_t TAGVDW1Sn[4]; //!< [0x110] Cache Tag Storage __IO hw_fmc_tagvdw2sn_t TAGVDW2Sn[4]; //!< [0x120] Cache Tag Storage __IO hw_fmc_tagvdw3sn_t TAGVDW3Sn[4]; //!< [0x130] Cache Tag Storage uint8_t _reserved1[192]; struct { __IO hw_fmc_dataw0snu_t DATAW0SnU; //!< [0x200] Cache Data Storage (upper word) __IO hw_fmc_dataw0snl_t DATAW0SnL; //!< [0x204] Cache Data Storage (lower word) } DATAW0Sn[4]; struct { __IO hw_fmc_dataw1snu_t DATAW1SnU; //!< [0x220] Cache Data Storage (upper word) __IO hw_fmc_dataw1snl_t DATAW1SnL; //!< [0x224] Cache Data Storage (lower word) } DATAW1Sn[4]; struct { __IO hw_fmc_dataw2snu_t DATAW2SnU; //!< [0x240] Cache Data Storage (upper word) __IO hw_fmc_dataw2snl_t DATAW2SnL; //!< [0x244] Cache Data Storage (lower word) } DATAW2Sn[4]; struct { __IO hw_fmc_dataw3snu_t DATAW3SnU; //!< [0x260] Cache Data Storage (upper word) __IO hw_fmc_dataw3snl_t DATAW3SnL; //!< [0x264] Cache Data Storage (lower word) } DATAW3Sn[4]; } hw_fmc_t; #pragma pack() //! @brief Macro to access all FMC registers. //! @return Reference (not a pointer) to the registers struct. To get a pointer to the struct, //! use the '&' operator, like &HW_FMC. #define HW_FMC (*(hw_fmc_t *) REGS_FMC_BASE) #endif #endif // __HW_FMC_REGISTERS_H__ // v22/130726/0.9 // EOF