Nothing Special
Modification of Mbed-dev library for LQFP48 package microcontrollers: STM32F103C8 (STM32F103C8T6) and STM32F103CB (STM32F103CBT6) (Bluepill boards, Maple mini etc. )
Fork of
mbed-STM32F103C8_org
by 
Nothing Special
Library for STM32F103C8 (Bluepill boards etc.).
Use this instead of mbed library.
This library allows the size of the code in the FLASH up to 128kB. Therefore, code also runs on microcontrollers STM32F103CB (eg. Maple mini).
But in the case of STM32F103C8, check the size of the resulting code would not exceed 64kB.
To compile a program with this library, use NUCLEO-F103RB as the target name. !
Changes:
- Corrected initialization of the HSE + crystal clock (mbed permanent bug), allowing the use of on-board xtal (8MHz).(1)
- Additionally, it also set USB clock (48Mhz).(2)
- Definitions of pins and peripherals adjusted to LQFP48 case.
- Board led LED1 is now PC_13 (3)
- USER_BUTTON is now PC_14 (4)
Now the library is complete rebuilt based on mbed-dev v160 (and not yet fully tested).
notes
(1) - In case 8MHz xtal on board, CPU frequency is 72MHz. Without xtal is 64MHz.
(2) - Using the USB interface is only possible if STM32 is clocking by on-board 8MHz xtal or external clock signal 8MHz on the OSC_IN pin.
(3) - On Bluepill board led operation is reversed, i.e. 0 - led on, 1 - led off.
(4) - Bluepill board has no real user button
Information
After export to SW4STM (AC6):
- add line
#include "mbed_config.h"in files Serial.h and RawSerial.h - in project properties change
Optimisation LeveltoOptimise for size (-Os)
cmsis/core_ca_mmu.h
- Committer:
- mega64
- Date:
- 2017-04-27
- Revision:
- 148:8b0b02bf146f
- Parent:
- 146:03e976389d16
File content as of revision 148:8b0b02bf146f:
;/**************************************************************************//**
; * @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