Fork of mbed-dev build 137, last build before FAT file system appears to be broken. Also reduced HSE timeout time in STM4XX HAL
Fork of mbed-dev by
cmsis/core_ca_mmu.h
- Committer:
- kkado
- Date:
- 2017-06-20
- Revision:
- 167:356ef919c855
- Parent:
- 149:156823d33999
File content as of revision 167:356ef919c855:
;/**************************************************************************//** ; * @file core_ca_mmu.h ; * @brief MMU Startup File for A9_MP Device Series ; * @version V1.01 ; * @date 10 Sept 2014 ; * ; * @note ; * ; ******************************************************************************/ ;/* Copyright (c) 2012-2014 ARM LIMITED ; ; All rights reserved. ; Redistribution and use in source and binary forms, with or without ; modification, are permitted provided that the following conditions are met: ; - Redistributions of source code must retain the above copyright ; notice, this list of conditions and the following disclaimer. ; - 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. ; - Neither the name of ARM 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 COPYRIGHT HOLDERS AND 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. ; ---------------------------------------------------------------------------*/ #ifdef __cplusplus extern "C" { #endif #ifndef _MMU_FUNC_H #define _MMU_FUNC_H #define SECTION_DESCRIPTOR (0x2) #define SECTION_MASK (0xFFFFFFFC) #define SECTION_TEXCB_MASK (0xFFFF8FF3) #define SECTION_B_SHIFT (2) #define SECTION_C_SHIFT (3) #define SECTION_TEX0_SHIFT (12) #define SECTION_TEX1_SHIFT (13) #define SECTION_TEX2_SHIFT (14) #define SECTION_XN_MASK (0xFFFFFFEF) #define SECTION_XN_SHIFT (4) #define SECTION_DOMAIN_MASK (0xFFFFFE1F) #define SECTION_DOMAIN_SHIFT (5) #define SECTION_P_MASK (0xFFFFFDFF) #define SECTION_P_SHIFT (9) #define SECTION_AP_MASK (0xFFFF73FF) #define SECTION_AP_SHIFT (10) #define SECTION_AP2_SHIFT (15) #define SECTION_S_MASK (0xFFFEFFFF) #define SECTION_S_SHIFT (16) #define SECTION_NG_MASK (0xFFFDFFFF) #define SECTION_NG_SHIFT (17) #define SECTION_NS_MASK (0xFFF7FFFF) #define SECTION_NS_SHIFT (19) #define PAGE_L1_DESCRIPTOR (0x1) #define PAGE_L1_MASK (0xFFFFFFFC) #define PAGE_L2_4K_DESC (0x2) #define PAGE_L2_4K_MASK (0xFFFFFFFD) #define PAGE_L2_64K_DESC (0x1) #define PAGE_L2_64K_MASK (0xFFFFFFFC) #define PAGE_4K_TEXCB_MASK (0xFFFFFE33) #define PAGE_4K_B_SHIFT (2) #define PAGE_4K_C_SHIFT (3) #define PAGE_4K_TEX0_SHIFT (6) #define PAGE_4K_TEX1_SHIFT (7) #define PAGE_4K_TEX2_SHIFT (8) #define PAGE_64K_TEXCB_MASK (0xFFFF8FF3) #define PAGE_64K_B_SHIFT (2) #define PAGE_64K_C_SHIFT (3) #define PAGE_64K_TEX0_SHIFT (12) #define PAGE_64K_TEX1_SHIFT (13) #define PAGE_64K_TEX2_SHIFT (14) #define PAGE_TEXCB_MASK (0xFFFF8FF3) #define PAGE_B_SHIFT (2) #define PAGE_C_SHIFT (3) #define PAGE_TEX_SHIFT (12) #define PAGE_XN_4K_MASK (0xFFFFFFFE) #define PAGE_XN_4K_SHIFT (0) #define PAGE_XN_64K_MASK (0xFFFF7FFF) #define PAGE_XN_64K_SHIFT (15) #define PAGE_DOMAIN_MASK (0xFFFFFE1F) #define PAGE_DOMAIN_SHIFT (5) #define PAGE_P_MASK (0xFFFFFDFF) #define PAGE_P_SHIFT (9) #define PAGE_AP_MASK (0xFFFFFDCF) #define PAGE_AP_SHIFT (4) #define PAGE_AP2_SHIFT (9) #define PAGE_S_MASK (0xFFFFFBFF) #define PAGE_S_SHIFT (10) #define PAGE_NG_MASK (0xFFFFF7FF) #define PAGE_NG_SHIFT (11) #define PAGE_NS_MASK (0xFFFFFFF7) #define PAGE_NS_SHIFT (3) #define OFFSET_1M (0x00100000) #define OFFSET_64K (0x00010000) #define OFFSET_4K (0x00001000) #define DESCRIPTOR_FAULT (0x00000000) /* ########################### MMU Function Access ########################### */ /** \ingroup MMU_FunctionInterface \defgroup MMU_Functions MMU Functions Interface @{ */ /* Attributes enumerations */ /* Region size attributes */ typedef enum { SECTION, PAGE_4k, PAGE_64k, } mmu_region_size_Type; /* Region type attributes */ typedef enum { NORMAL, DEVICE, SHARED_DEVICE, NON_SHARED_DEVICE, STRONGLY_ORDERED } mmu_memory_Type; /* Region cacheability attributes */ typedef enum { NON_CACHEABLE, WB_WA, WT, WB_NO_WA, } mmu_cacheability_Type; /* Region parity check attributes */ typedef enum { ECC_DISABLED, ECC_ENABLED, } mmu_ecc_check_Type; /* Region execution attributes */ typedef enum { EXECUTE, NON_EXECUTE, } mmu_execute_Type; /* Region global attributes */ typedef enum { GLOBAL, NON_GLOBAL, } mmu_global_Type; /* Region shareability attributes */ typedef enum { NON_SHARED, SHARED, } mmu_shared_Type; /* Region security attributes */ typedef enum { SECURE, NON_SECURE, } mmu_secure_Type; /* Region access attributes */ typedef enum { NO_ACCESS, RW, READ, } mmu_access_Type; /* Memory Region definition */ typedef struct RegionStruct { mmu_region_size_Type rg_t; mmu_memory_Type mem_t; uint8_t domain; mmu_cacheability_Type inner_norm_t; mmu_cacheability_Type outer_norm_t; mmu_ecc_check_Type e_t; mmu_execute_Type xn_t; mmu_global_Type g_t; mmu_secure_Type sec_t; mmu_access_Type priv_t; mmu_access_Type user_t; mmu_shared_Type sh_t; } mmu_region_attributes_Type; /** \brief Set section execution-never attribute The function sets section execution-never attribute \param [out] descriptor_l1 L1 descriptor. \param [in] xn Section execution-never attribute : EXECUTE , NON_EXECUTE. \return 0 */ __STATIC_INLINE int __xn_section(uint32_t *descriptor_l1, mmu_execute_Type xn) { *descriptor_l1 &= SECTION_XN_MASK; *descriptor_l1 |= ((xn & 0x1) << SECTION_XN_SHIFT); return 0; } /** \brief Set section domain The function sets section domain \param [out] descriptor_l1 L1 descriptor. \param [in] domain Section domain \return 0 */ __STATIC_INLINE int __domain_section(uint32_t *descriptor_l1, uint8_t domain) { *descriptor_l1 &= SECTION_DOMAIN_MASK; *descriptor_l1 |= ((domain & 0xF) << SECTION_DOMAIN_SHIFT); return 0; } /** \brief Set section parity check The function sets section parity check \param [out] descriptor_l1 L1 descriptor. \param [in] p_bit Parity check: ECC_DISABLED, ECC_ENABLED \return 0 */ __STATIC_INLINE int __p_section(uint32_t *descriptor_l1, mmu_ecc_check_Type p_bit) { *descriptor_l1 &= SECTION_P_MASK; *descriptor_l1 |= ((p_bit & 0x1) << SECTION_P_SHIFT); return 0; } /** \brief Set section access privileges The function sets section access privileges \param [out] descriptor_l1 L1 descriptor. \param [in] user User Level Access: NO_ACCESS, RW, READ \param [in] priv Privilege Level Access: NO_ACCESS, RW, READ \param [in] afe Access flag enable \return 0 */ __STATIC_INLINE int __ap_section(uint32_t *descriptor_l1, mmu_access_Type user, mmu_access_Type priv, uint32_t afe) { uint32_t ap = 0; if (afe == 0) { //full access if ((priv == NO_ACCESS) && (user == NO_ACCESS)) { ap = 0x0; } else if ((priv == RW) && (user == NO_ACCESS)) { ap = 0x1; } else if ((priv == RW) && (user == READ)) { ap = 0x2; } else if ((priv == RW) && (user == RW)) { ap = 0x3; } else if ((priv == READ) && (user == NO_ACCESS)) { ap = 0x5; } else if ((priv == READ) && (user == READ)) { ap = 0x7; } } else { //Simplified access if ((priv == RW) && (user == NO_ACCESS)) { ap = 0x1; } else if ((priv == RW) && (user == RW)) { ap = 0x3; } else if ((priv == READ) && (user == NO_ACCESS)) { ap = 0x5; } else if ((priv == READ) && (user == READ)) { ap = 0x7; } } *descriptor_l1 &= SECTION_AP_MASK; *descriptor_l1 |= (ap & 0x3) << SECTION_AP_SHIFT; *descriptor_l1 |= ((ap & 0x4)>>2) << SECTION_AP2_SHIFT; return 0; } /** \brief Set section shareability The function sets section shareability \param [out] descriptor_l1 L1 descriptor. \param [in] s_bit Section shareability: NON_SHARED, SHARED \return 0 */ __STATIC_INLINE int __shared_section(uint32_t *descriptor_l1, mmu_shared_Type s_bit) { *descriptor_l1 &= SECTION_S_MASK; *descriptor_l1 |= ((s_bit & 0x1) << SECTION_S_SHIFT); return 0; } /** \brief Set section Global attribute The function sets section Global attribute \param [out] descriptor_l1 L1 descriptor. \param [in] g_bit Section attribute: GLOBAL, NON_GLOBAL \return 0 */ __STATIC_INLINE int __global_section(uint32_t *descriptor_l1, mmu_global_Type g_bit) { *descriptor_l1 &= SECTION_NG_MASK; *descriptor_l1 |= ((g_bit & 0x1) << SECTION_NG_SHIFT); return 0; } /** \brief Set section Security attribute The function sets section Global attribute \param [out] descriptor_l1 L1 descriptor. \param [in] s_bit Section Security attribute: SECURE, NON_SECURE \return 0 */ __STATIC_INLINE int __secure_section(uint32_t *descriptor_l1, mmu_secure_Type s_bit) { *descriptor_l1 &= SECTION_NS_MASK; *descriptor_l1 |= ((s_bit & 0x1) << SECTION_NS_SHIFT); return 0; } /* Page 4k or 64k */ /** \brief Set 4k/64k page execution-never attribute The function sets 4k/64k page execution-never attribute \param [out] descriptor_l2 L2 descriptor. \param [in] xn Page execution-never attribute : EXECUTE , NON_EXECUTE. \param [in] page Page size: PAGE_4k, PAGE_64k, \return 0 */ __STATIC_INLINE int __xn_page(uint32_t *descriptor_l2, mmu_execute_Type xn, mmu_region_size_Type page) { if (page == PAGE_4k) { *descriptor_l2 &= PAGE_XN_4K_MASK; *descriptor_l2 |= ((xn & 0x1) << PAGE_XN_4K_SHIFT); } else { *descriptor_l2 &= PAGE_XN_64K_MASK; *descriptor_l2 |= ((xn & 0x1) << PAGE_XN_64K_SHIFT); } return 0; } /** \brief Set 4k/64k page domain The function sets 4k/64k page domain \param [out] descriptor_l1 L1 descriptor. \param [in] domain Page domain \return 0 */ __STATIC_INLINE int __domain_page(uint32_t *descriptor_l1, uint8_t domain) { *descriptor_l1 &= PAGE_DOMAIN_MASK; *descriptor_l1 |= ((domain & 0xf) << PAGE_DOMAIN_SHIFT); return 0; } /** \brief Set 4k/64k page parity check The function sets 4k/64k page parity check \param [out] descriptor_l1 L1 descriptor. \param [in] p_bit Parity check: ECC_DISABLED, ECC_ENABLED \return 0 */ __STATIC_INLINE int __p_page(uint32_t *descriptor_l1, mmu_ecc_check_Type p_bit) { *descriptor_l1 &= SECTION_P_MASK; *descriptor_l1 |= ((p_bit & 0x1) << SECTION_P_SHIFT); return 0; } /** \brief Set 4k/64k page access privileges The function sets 4k/64k page access privileges \param [out] descriptor_l2 L2 descriptor. \param [in] user User Level Access: NO_ACCESS, RW, READ \param [in] priv Privilege Level Access: NO_ACCESS, RW, READ \param [in] afe Access flag enable \return 0 */ __STATIC_INLINE int __ap_page(uint32_t *descriptor_l2, mmu_access_Type user, mmu_access_Type priv, uint32_t afe) { uint32_t ap = 0; if (afe == 0) { //full access if ((priv == NO_ACCESS) && (user == NO_ACCESS)) { ap = 0x0; } else if ((priv == RW) && (user == NO_ACCESS)) { ap = 0x1; } else if ((priv == RW) && (user == READ)) { ap = 0x2; } else if ((priv == RW) && (user == RW)) { ap = 0x3; } else if ((priv == READ) && (user == NO_ACCESS)) { ap = 0x5; } else if ((priv == READ) && (user == READ)) { ap = 0x6; } } else { //Simplified access if ((priv == RW) && (user == NO_ACCESS)) { ap = 0x1; } else if ((priv == RW) && (user == RW)) { ap = 0x3; } else if ((priv == READ) && (user == NO_ACCESS)) { ap = 0x5; } else if ((priv == READ) && (user == READ)) { ap = 0x7; } } *descriptor_l2 &= PAGE_AP_MASK; *descriptor_l2 |= (ap & 0x3) << PAGE_AP_SHIFT; *descriptor_l2 |= ((ap & 0x4)>>2) << PAGE_AP2_SHIFT; return 0; } /** \brief Set 4k/64k page shareability The function sets 4k/64k page shareability \param [out] descriptor_l2 L2 descriptor. \param [in] s_bit 4k/64k page shareability: NON_SHARED, SHARED \return 0 */ __STATIC_INLINE int __shared_page(uint32_t *descriptor_l2, mmu_shared_Type s_bit) { *descriptor_l2 &= PAGE_S_MASK; *descriptor_l2 |= ((s_bit & 0x1) << PAGE_S_SHIFT); return 0; } /** \brief Set 4k/64k page Global attribute The function sets 4k/64k page Global attribute \param [out] descriptor_l2 L2 descriptor. \param [in] g_bit 4k/64k page attribute: GLOBAL, NON_GLOBAL \return 0 */ __STATIC_INLINE int __global_page(uint32_t *descriptor_l2, mmu_global_Type g_bit) { *descriptor_l2 &= PAGE_NG_MASK; *descriptor_l2 |= ((g_bit & 0x1) << PAGE_NG_SHIFT); return 0; } /** \brief Set 4k/64k page Security attribute The function sets 4k/64k page Global attribute \param [out] descriptor_l1 L1 descriptor. \param [in] s_bit 4k/64k page Security attribute: SECURE, NON_SECURE \return 0 */ __STATIC_INLINE int __secure_page(uint32_t *descriptor_l1, mmu_secure_Type s_bit) { *descriptor_l1 &= PAGE_NS_MASK; *descriptor_l1 |= ((s_bit & 0x1) << PAGE_NS_SHIFT); return 0; } /** \brief Set Section memory attributes The function sets section memory attributes \param [out] descriptor_l1 L1 descriptor. \param [in] mem Section memory type: NORMAL, DEVICE, SHARED_DEVICE, NON_SHARED_DEVICE, STRONGLY_ORDERED \param [in] outer Outer cacheability: NON_CACHEABLE, WB_WA, WT, WB_NO_WA, \param [in] inner Inner cacheability: NON_CACHEABLE, WB_WA, WT, WB_NO_WA, \return 0 */ __STATIC_INLINE int __memory_section(uint32_t *descriptor_l1, mmu_memory_Type mem, mmu_cacheability_Type outer, mmu_cacheability_Type inner) { *descriptor_l1 &= SECTION_TEXCB_MASK; if (STRONGLY_ORDERED == mem) { return 0; } else if (SHARED_DEVICE == mem) { *descriptor_l1 |= (1 << SECTION_B_SHIFT); } else if (NON_SHARED_DEVICE == mem) { *descriptor_l1 |= (1 << SECTION_TEX1_SHIFT); } else if (NORMAL == mem) { *descriptor_l1 |= 1 << SECTION_TEX2_SHIFT; switch(inner) { case NON_CACHEABLE: break; case WB_WA: *descriptor_l1 |= (1 << SECTION_B_SHIFT); break; case WT: *descriptor_l1 |= 1 << SECTION_C_SHIFT; break; case WB_NO_WA: *descriptor_l1 |= (1 << SECTION_B_SHIFT) | (1 << SECTION_C_SHIFT); break; } switch(outer) { case NON_CACHEABLE: break; case WB_WA: *descriptor_l1 |= (1 << SECTION_TEX0_SHIFT); break; case WT: *descriptor_l1 |= 1 << SECTION_TEX1_SHIFT; break; case WB_NO_WA: *descriptor_l1 |= (1 << SECTION_TEX0_SHIFT) | (1 << SECTION_TEX0_SHIFT); break; } } return 0; } /** \brief Set 4k/64k page memory attributes The function sets 4k/64k page memory attributes \param [out] descriptor_l2 L2 descriptor. \param [in] mem 4k/64k page memory type: NORMAL, DEVICE, SHARED_DEVICE, NON_SHARED_DEVICE, STRONGLY_ORDERED \param [in] outer Outer cacheability: NON_CACHEABLE, WB_WA, WT, WB_NO_WA, \param [in] inner Inner cacheability: NON_CACHEABLE, WB_WA, WT, WB_NO_WA, \return 0 */ __STATIC_INLINE int __memory_page(uint32_t *descriptor_l2, mmu_memory_Type mem, mmu_cacheability_Type outer, mmu_cacheability_Type inner, mmu_region_size_Type page) { *descriptor_l2 &= PAGE_4K_TEXCB_MASK; if (page == PAGE_64k) { //same as section __memory_section(descriptor_l2, mem, outer, inner); } else { if (STRONGLY_ORDERED == mem) { return 0; } else if (SHARED_DEVICE == mem) { *descriptor_l2 |= (1 << PAGE_4K_B_SHIFT); } else if (NON_SHARED_DEVICE == mem) { *descriptor_l2 |= (1 << PAGE_4K_TEX1_SHIFT); } else if (NORMAL == mem) { *descriptor_l2 |= 1 << PAGE_4K_TEX2_SHIFT; switch(inner) { case NON_CACHEABLE: break; case WB_WA: *descriptor_l2 |= (1 << PAGE_4K_B_SHIFT); break; case WT: *descriptor_l2 |= 1 << PAGE_4K_C_SHIFT; break; case WB_NO_WA: *descriptor_l2 |= (1 << PAGE_4K_B_SHIFT) | (1 << PAGE_4K_C_SHIFT); break; } switch(outer) { case NON_CACHEABLE: break; case WB_WA: *descriptor_l2 |= (1 << PAGE_4K_TEX0_SHIFT); break; case WT: *descriptor_l2 |= 1 << PAGE_4K_TEX1_SHIFT; break; case WB_NO_WA: *descriptor_l2 |= (1 << PAGE_4K_TEX0_SHIFT) | (1 << PAGE_4K_TEX0_SHIFT); break; } } } return 0; } /** \brief Create a L1 section descriptor The function creates a section descriptor. Assumptions: - 16MB super sections not supported - TEX remap disabled, so memory type and attributes are described directly by bits in the descriptor - Functions always return 0 \param [out] descriptor L1 descriptor \param [out] descriptor2 L2 descriptor \param [in] reg Section attributes \return 0 */ __STATIC_INLINE int __get_section_descriptor(uint32_t *descriptor, mmu_region_attributes_Type reg) { *descriptor = 0; __memory_section(descriptor, reg.mem_t, reg.outer_norm_t, reg.inner_norm_t); __xn_section(descriptor,reg.xn_t); __domain_section(descriptor, reg.domain); __p_section(descriptor, reg.e_t); __ap_section(descriptor, reg.priv_t, reg.user_t, 1); __shared_section(descriptor,reg.sh_t); __global_section(descriptor,reg.g_t); __secure_section(descriptor,reg.sec_t); *descriptor &= SECTION_MASK; *descriptor |= SECTION_DESCRIPTOR; return 0; } /** \brief Create a L1 and L2 4k/64k page descriptor The function creates a 4k/64k page descriptor. Assumptions: - TEX remap disabled, so memory type and attributes are described directly by bits in the descriptor - Functions always return 0 \param [out] descriptor L1 descriptor \param [out] descriptor2 L2 descriptor \param [in] reg 4k/64k page attributes \return 0 */ __STATIC_INLINE int __get_page_descriptor(uint32_t *descriptor, uint32_t *descriptor2, mmu_region_attributes_Type reg) { *descriptor = 0; *descriptor2 = 0; switch (reg.rg_t) { case PAGE_4k: __memory_page(descriptor2, reg.mem_t, reg.outer_norm_t, reg.inner_norm_t, PAGE_4k); __xn_page(descriptor2, reg.xn_t, PAGE_4k); __domain_page(descriptor, reg.domain); __p_page(descriptor, reg.e_t); __ap_page(descriptor2, reg.priv_t, reg.user_t, 1); __shared_page(descriptor2,reg.sh_t); __global_page(descriptor2,reg.g_t); __secure_page(descriptor,reg.sec_t); *descriptor &= PAGE_L1_MASK; *descriptor |= PAGE_L1_DESCRIPTOR; *descriptor2 &= PAGE_L2_4K_MASK; *descriptor2 |= PAGE_L2_4K_DESC; break; case PAGE_64k: __memory_page(descriptor2, reg.mem_t, reg.outer_norm_t, reg.inner_norm_t, PAGE_64k); __xn_page(descriptor2, reg.xn_t, PAGE_64k); __domain_page(descriptor, reg.domain); __p_page(descriptor, reg.e_t); __ap_page(descriptor2, reg.priv_t, reg.user_t, 1); __shared_page(descriptor2,reg.sh_t); __global_page(descriptor2,reg.g_t); __secure_page(descriptor,reg.sec_t); *descriptor &= PAGE_L1_MASK; *descriptor |= PAGE_L1_DESCRIPTOR; *descriptor2 &= PAGE_L2_64K_MASK; *descriptor2 |= PAGE_L2_64K_DESC; break; case SECTION: //error break; } return 0; } /** \brief Create a 1MB Section \param [in] ttb Translation table base address \param [in] base_address Section base address \param [in] count Number of sections to create \param [in] descriptor_l1 L1 descriptor (region attributes) */ __STATIC_INLINE void __TTSection(uint32_t *ttb, uint32_t base_address, uint32_t count, uint32_t descriptor_l1) { uint32_t offset; uint32_t entry; uint32_t i; offset = base_address >> 20; entry = (base_address & 0xFFF00000) | descriptor_l1; //4 bytes aligned ttb = ttb + offset; for (i = 0; i < count; i++ ) { //4 bytes aligned *ttb++ = entry; entry += OFFSET_1M; } } /** \brief Create a 4k page entry \param [in] ttb L1 table base address \param [in] base_address 4k base address \param [in] count Number of 4k pages to create \param [in] descriptor_l1 L1 descriptor (region attributes) \param [in] ttb_l2 L2 table base address \param [in] descriptor_l2 L2 descriptor (region attributes) */ __STATIC_INLINE void __TTPage_4k(uint32_t *ttb, uint32_t base_address, uint32_t count, uint32_t descriptor_l1, uint32_t *ttb_l2, uint32_t descriptor_l2 ) { uint32_t offset, offset2; uint32_t entry, entry2; uint32_t i; offset = base_address >> 20; entry = ((int)ttb_l2 & 0xFFFFFC00) | descriptor_l1; //4 bytes aligned ttb += offset; //create l1_entry *ttb = entry; offset2 = (base_address & 0xff000) >> 12; ttb_l2 += offset2; entry2 = (base_address & 0xFFFFF000) | descriptor_l2; for (i = 0; i < count; i++ ) { //4 bytes aligned *ttb_l2++ = entry2; entry2 += OFFSET_4K; } } /** \brief Create a 64k page entry \param [in] ttb L1 table base address \param [in] base_address 64k base address \param [in] count Number of 64k pages to create \param [in] descriptor_l1 L1 descriptor (region attributes) \param [in] ttb_l2 L2 table base address \param [in] descriptor_l2 L2 descriptor (region attributes) */ __STATIC_INLINE void __TTPage_64k(uint32_t *ttb, uint32_t base_address, uint32_t count, uint32_t descriptor_l1, uint32_t *ttb_l2, uint32_t descriptor_l2 ) { uint32_t offset, offset2; uint32_t entry, entry2; uint32_t i,j; offset = base_address >> 20; entry = ((int)ttb_l2 & 0xFFFFFC00) | descriptor_l1; //4 bytes aligned ttb += offset; //create l1_entry *ttb = entry; offset2 = (base_address & 0xff000) >> 12; ttb_l2 += offset2; entry2 = (base_address & 0xFFFF0000) | descriptor_l2; for (i = 0; i < count; i++ ) { //create 16 entries for (j = 0; j < 16; j++) //4 bytes aligned *ttb_l2++ = entry2; entry2 += OFFSET_64K; } } /*@} end of MMU_Functions */ #endif #ifdef __cplusplus } #endif