鸿蒙轻内核A核源码分析系列五 虚实映射（4）

7、Flag标签属性

在学习函数LOS_ArchMmuMap()代码时，我们已经了解了虚拟内存如何映射到物理内存，在映射的时候，可以通过UINT 32 flags参数定一些标签属性信息。本节，我们具体了解下内存标签属性信息。先了解下MMU标签属性，然后看看映射内存区间时的映射虚实信息，最后了解下属性信息转换函数。

7.1 MMU标签属性

在映射的时候，对于内存页可以指定一些内存属性，比如权限、内存类型、缓存策略等等。更多信息参考ARM官网资料《ARM® Cortex™-A Series Version: 4.0 Programmer’s Guide》，我们只快速摘录些关键信息。L1页表项的格式如下图所示，其中Type extension (TEX), Shareable (S), Access Permission (AP, APX)、 Cacheable (C)、 Bufferable (B)位表示内存属性信息。在arch/arm/arm/include/los_mmu_descriptor_v6.h文件中定义了MMU L1页表内存属性相关的宏，如下。

/* TEX CB */
#define MMU_DESCRIPTOR_L1_TEX_SHIFT                             12 /* type extension field shift */
#define MMU_DESCRIPTOR_L1_TEX(x)                                /
((x) << MMU_DESCRIPTOR_L1_TEX_SHIFT) /* type extension */
#define MMU_DESCRIPTOR_L1_TYPE_STRONGLY_ORDERED                 /
(MMU_DESCRIPTOR_L1_TEX(MMU_DESCRIPTOR_TEX_0) | MMU_DESCRIPTOR_NON_CACHEABLE)
#define MMU_DESCRIPTOR_L1_TYPE_NORMAL_NOCACHE                   /
(MMU_DESCRIPTOR_L1_TEX(MMU_DESCRIPTOR_TEX_1) | MMU_DESCRIPTOR_NON_CACHEABLE)
#define MMU_DESCRIPTOR_L1_TYPE_DEVICE_SHARED                    /
(MMU_DESCRIPTOR_L1_TEX(MMU_DESCRIPTOR_TEX_0) | MMU_DESCRIPTOR_WRITE_BACK_ALLOCATE)
#define MMU_DESCRIPTOR_L1_TYPE_DEVICE_NON_SHARED                /
(MMU_DESCRIPTOR_L1_TEX(MMU_DESCRIPTOR_TEX_2) | MMU_DESCRIPTOR_NON_CACHEABLE)
#define MMU_DESCRIPTOR_L1_TYPE_NORMAL_WRITE_BACK_ALLOCATE       /
(MMU_DESCRIPTOR_L1_TEX(MMU_DESCRIPTOR_TEX_1) | MMU_DESCRIPTOR_WRITE_BACK_NO_ALLOCATE)
#define MMU_DESCRIPTOR_L1_TEX_TYPE_MASK                         /
(MMU_DESCRIPTOR_L1_TEX(MMU_DESCRIPTOR_TEX_MASK) | MMU_DESCRIPTOR_WRITE_BACK_NO_ALLOCATE)
#define MMU_DESCRIPTOR_L1_AP2_SHIFT                             15
#define MMU_DESCRIPTOR_L1_AP2(x)                                ((x) << MMU_DESCRIPTOR_L1_AP2_SHIFT)
#define MMU_DESCRIPTOR_L1_AP2_0                                 (MMU_DESCRIPTOR_L1_AP2(0))
#define MMU_DESCRIPTOR_L1_AP2_1                                 (MMU_DESCRIPTOR_L1_AP2(1))
#define MMU_DESCRIPTOR_L1_AP01_SHIFT                            10
#define MMU_DESCRIPTOR_L1_AP01(x)                               ((x) << MMU_DESCRIPTOR_L1_AP01_SHIFT)
#define MMU_DESCRIPTOR_L1_AP01_0                                (MMU_DESCRIPTOR_L1_AP01(0))
#define MMU_DESCRIPTOR_L1_AP01_1                                (MMU_DESCRIPTOR_L1_AP01(1))
#define MMU_DESCRIPTOR_L1_AP01_3                                (MMU_DESCRIPTOR_L1_AP01(3))
#define MMU_DESCRIPTOR_L1_AP_P_NA_U_NA                          (MMU_DESCRIPTOR_L1_AP2_0 | MMU_DESCRIPTOR_L1_AP01_0)
#define MMU_DESCRIPTOR_L1_AP_P_RW_U_RW                          (MMU_DESCRIPTOR_L1_AP2_0 | MMU_DESCRIPTOR_L1_AP01_3)
#define MMU_DESCRIPTOR_L1_AP_P_RW_U_NA                          (MMU_DESCRIPTOR_L1_AP2_0 | MMU_DESCRIPTOR_L1_AP01_1)
#define MMU_DESCRIPTOR_L1_AP_P_RO_U_RO                          (MMU_DESCRIPTOR_L1_AP2_1 | MMU_DESCRIPTOR_L1_AP01_3)
#define MMU_DESCRIPTOR_L1_AP_P_RO_U_NA                          (MMU_DESCRIPTOR_L1_AP2_1 | MMU_DESCRIPTOR_L1_AP01_1)
#define MMU_DESCRIPTOR_L1_AP_MASK                               (MMU_DESCRIPTOR_L1_AP2_1 | MMU_DESCRIPTOR_L1_AP01_3)

L2页表项的格式如下图所示。在arch/arm/arm/include/los_mmu_descriptor_v6.h文件中定义了MMU L2页表内存属性相关的宏，如下。

#define MMU_DESCRIPTOR_L2_TEX_SHIFT                             6 /* type extension field shift */
#define MMU_DESCRIPTOR_L2_TEX(x)                                /
((x) << MMU_DESCRIPTOR_L2_TEX_SHIFT) /* type extension */
#define MMU_DESCRIPTOR_L2_TYPE_STRONGLY_ORDERED                 /
(MMU_DESCRIPTOR_L2_TEX(MMU_DESCRIPTOR_TEX_0) | MMU_DESCRIPTOR_NON_CACHEABLE)
#define MMU_DESCRIPTOR_L2_TYPE_NORMAL_NOCACHE                   /
(MMU_DESCRIPTOR_L2_TEX(MMU_DESCRIPTOR_TEX_1) | MMU_DESCRIPTOR_NON_CACHEABLE)
#define MMU_DESCRIPTOR_L2_TYPE_DEVICE_SHARED                    /
(MMU_DESCRIPTOR_L2_TEX(MMU_DESCRIPTOR_TEX_0) | MMU_DESCRIPTOR_WRITE_BACK_ALLOCATE)
#define MMU_DESCRIPTOR_L2_TYPE_DEVICE_NON_SHARED                /
(MMU_DESCRIPTOR_L2_TEX(MMU_DESCRIPTOR_TEX_2) | MMU_DESCRIPTOR_NON_CACHEABLE)
#define MMU_DESCRIPTOR_L2_TYPE_NORMAL_WRITE_BACK_ALLOCATE       /
(MMU_DESCRIPTOR_L2_TEX(MMU_DESCRIPTOR_TEX_1) | MMU_DESCRIPTOR_WRITE_BACK_NO_ALLOCATE)
#define MMU_DESCRIPTOR_L2_TEX_TYPE_MASK                         /
(MMU_DESCRIPTOR_L2_TEX(MMU_DESCRIPTOR_TEX_MASK) | MMU_DESCRIPTOR_WRITE_BACK_NO_ALLOCATE)
#define MMU_DESCRIPTOR_L2_AP2_SHIFT                             9
#define MMU_DESCRIPTOR_L2_AP2(x)                                ((x) << MMU_DESCRIPTOR_L2_AP2_SHIFT)
#define MMU_DESCRIPTOR_L2_AP2_0                                 (MMU_DESCRIPTOR_L2_AP2(0))
#define MMU_DESCRIPTOR_L2_AP2_1                                 (MMU_DESCRIPTOR_L2_AP2(1))
#define MMU_DESCRIPTOR_L2_AP01_SHIFT                            4
#define MMU_DESCRIPTOR_L2_AP01(x)                               ((x) << MMU_DESCRIPTOR_L2_AP01_SHIFT)
#define MMU_DESCRIPTOR_L2_AP01_0                                (MMU_DESCRIPTOR_L2_AP01(0))
#define MMU_DESCRIPTOR_L2_AP01_1                                (MMU_DESCRIPTOR_L2_AP01(1))
#define MMU_DESCRIPTOR_L2_AP01_3                                (MMU_DESCRIPTOR_L2_AP01(3))
#define MMU_DESCRIPTOR_L2_AP_P_NA_U_NA                          (MMU_DESCRIPTOR_L2_AP2_0 | MMU_DESCRIPTOR_L2_AP01_0)
#define MMU_DESCRIPTOR_L2_AP_P_RW_U_RW                          (MMU_DESCRIPTOR_L2_AP2_0 | MMU_DESCRIPTOR_L2_AP01_3)
#define MMU_DESCRIPTOR_L2_AP_P_RW_U_NA                          (MMU_DESCRIPTOR_L2_AP2_0 | MMU_DESCRIPTOR_L2_AP01_1)
#define MMU_DESCRIPTOR_L2_AP_P_RO_U_RO                          (MMU_DESCRIPTOR_L2_AP2_1 | MMU_DESCRIPTOR_L2_AP01_3)
#define MMU_DESCRIPTOR_L2_AP_P_RO_U_NA                          (MMU_DESCRIPTOR_L2_AP2_1 | MMU_DESCRIPTOR_L2_AP01_1)
#define MMU_DESCRIPTOR_L2_AP_MASK                               (MMU_DESCRIPTOR_L2_AP2_1 | MMU_DESCRIPTOR_L2_AP01_3)

7.2 映射地址区间标签属性

kernel/base/include/los_vm_map.h文件中定义地址区间映射标签属性信息。标签属性信息主要分为4类，如图所示。前2位用于标记释放缓存设备，2-5位用于标记权限信息，6-8位用于标记共享私有等信息，9-19位用于标记stack、heap、data、text、bss、vsdo、mmap、shm、fixed、fixed_noreplace等属性信息。20-23位暂未使用，高8位被共享内存SHM使用。

/* the high 8 bits(24~31) should reserved, shm will use it */
#define     VM_MAP_REGION_FLAG_CACHED               (0<<0)
#define     VM_MAP_REGION_FLAG_UNCACHED             (1<<0)
#define     VM_MAP_REGION_FLAG_UNCACHED_DEVICE      (2<<0) /* only exists on some arches, otherwise UNCACHED */
#define     VM_MAP_REGION_FLAG_STRONGLY_ORDERED     (3<<0) /* only exists on some arches, otherwise UNCACHED */
#define     VM_MAP_REGION_FLAG_CACHE_MASK           (3<<0)
#define     VM_MAP_REGION_FLAG_PERM_USER            (1<<2)
#define     VM_MAP_REGION_FLAG_PERM_READ            (1<<3)
#define     VM_MAP_REGION_FLAG_PERM_WRITE           (1<<4)
#define     VM_MAP_REGION_FLAG_PERM_EXECUTE         (1<<5)
#define     VM_MAP_REGION_FLAG_PROT_MASK            (0xF<<2)
#define     VM_MAP_REGION_FLAG_NS                   (1<<6) /* NON-SECURE */
#define     VM_MAP_REGION_FLAG_SHARED               (1<<7)
#define     VM_MAP_REGION_FLAG_PRIVATE              (1<<8)
#define     VM_MAP_REGION_FLAG_FLAG_MASK            (3<<7)
#define     VM_MAP_REGION_FLAG_STACK                (1<<9)
#define     VM_MAP_REGION_FLAG_HEAP                 (1<<10)
#define     VM_MAP_REGION_FLAG_DATA                 (1<<11)
#define     VM_MAP_REGION_FLAG_TEXT                 (1<<12)
#define     VM_MAP_REGION_FLAG_BSS                  (1<<13)
#define     VM_MAP_REGION_FLAG_VDSO                 (1<<14)
#define     VM_MAP_REGION_FLAG_MMAP                 (1<<15)
#define     VM_MAP_REGION_FLAG_SHM                  (1<<16)
#define     VM_MAP_REGION_FLAG_FIXED                (1<<17)
#define     VM_MAP_REGION_FLAG_FIXED_NOREPLACE      (1<<18)
#define     VM_MAP_REGION_FLAG_INVALID              (1<<19) /* indicates that flags are not specified */

7.3 标签转换操作

7.3.1 OsCvtProtFlagsToRegionFlags函数

函数OsCvtProtFlagsToRegionFlags()把保护属性转换为虚拟内存区间标签属性，该函数在系统调用、共享内存等模块会使用。参数unsigned long prot中的保护标签属性如PROT_READ、MAP_SHARED等等，定义在文件third_party/musl/porting/liteos_a/kernel/include/sys/mman.h。

STATIC INLINE UINT32 OsCvtProtFlagsToRegionFlags(unsigned long prot, unsigned long flags)
{
UINT32 regionFlags = 0;
regionFlags |= VM_MAP_REGION_FLAG_PERM_USER;
regionFlags |= (prot & PROT_READ) ? VM_MAP_REGION_FLAG_PERM_READ : 0;
regionFlags |= (prot & PROT_WRITE) ? (VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE) : 0;
regionFlags |= (prot & PROT_EXEC) ? (VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_EXECUTE) : 0;
regionFlags |= (flags & MAP_SHARED) ? VM_MAP_REGION_FLAG_SHARED : 0;
regionFlags |= (flags & MAP_PRIVATE) ? VM_MAP_REGION_FLAG_PRIVATE : 0;
regionFlags |= (flags & MAP_FIXED) ? VM_MAP_REGION_FLAG_FIXED : 0;
regionFlags |= (flags & MAP_FIXED_NOREPLACE) ? VM_MAP_REGION_FLAG_FIXED_NOREPLACE : 0;
return regionFlags;
}

7.3.2 OsCvtSecFlagsToAttrs函数和OsCvtSecAttsToFlags函数

OsCvtSecFlagsToAttrs函数用于把内存区域映射标签属性转换为L1 Section类型页表项的MMU标签属性。该函数又分为2个函数，分别是⑴处的OsCvtSecCacheFlagsToMMUFlags()函数和⑵处的OsCvtSecAccessFlagsToMMUFlags()函数。OsCvtSecCacheFlagsToMMUFlags()函数主要判断内存映射区域的低2位缓存标签属性的转换。OsCvtSecAccessFlagsToMMUFlags()函数用于映射标签属性的2-4位访问权限部分的转换。代码比较简单不再赘述。

⑶处的函数OsCvtSecAttsToFlags()是上述函数OsCvtSecFlagsToAttrs的逆过程，用于把L1 Section类型页表项的MMU标签属性转换为内存区域映射标签属性。自行阅读代码，不再逐行分析。

⑴  STATIC UINT32 OsCvtSecCacheFlagsToMMUFlags(UINT32 flags)
{
UINT32 mmuFlags = 0;
switch (flags & VM_MAP_REGION_FLAG_CACHE_MASK) {
case VM_MAP_REGION_FLAG_CACHED:
mmuFlags |= MMU_DESCRIPTOR_L1_TYPE_NORMAL_WRITE_BACK_ALLOCATE;
#ifdef LOSCFG_KERNEL_SMP
mmuFlags |= MMU_DESCRIPTOR_L1_SECTION_SHAREABLE;
#endif
break;
case VM_MAP_REGION_FLAG_STRONGLY_ORDERED:
mmuFlags |= MMU_DESCRIPTOR_L1_TYPE_STRONGLY_ORDERED;
break;
case VM_MAP_REGION_FLAG_UNCACHED:
mmuFlags |= MMU_DESCRIPTOR_L1_TYPE_NORMAL_NOCACHE;
break;
case VM_MAP_REGION_FLAG_UNCACHED_DEVICE:
mmuFlags |= MMU_DESCRIPTOR_L1_TYPE_DEVICE_SHARED;
break;
default:
return LOS_ERRNO_VM_INVALID_ARGS;
}
return mmuFlags;
}
⑵  STATIC UINT32 OsCvtSecAccessFlagsToMMUFlags(UINT32 flags)
{
UINT32 mmuFlags = 0;
switch (flags & (VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE)) {
case 0:
mmuFlags |= MMU_DESCRIPTOR_L1_AP_P_NA_U_NA;
break;
case VM_MAP_REGION_FLAG_PERM_READ:
case VM_MAP_REGION_FLAG_PERM_USER:
mmuFlags |= MMU_DESCRIPTOR_L1_AP_P_RO_U_NA;
break;
case VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_READ:
mmuFlags |= MMU_DESCRIPTOR_L1_AP_P_RO_U_RO;
break;
case VM_MAP_REGION_FLAG_PERM_WRITE:
case VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE:
mmuFlags |= MMU_DESCRIPTOR_L1_AP_P_RW_U_NA;
break;
case VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_WRITE:
case VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE:
mmuFlags |= MMU_DESCRIPTOR_L1_AP_P_RW_U_RW;
break;
default:
break;
}
return mmuFlags;
}
/* convert user level mmu flags to L1 descriptors flags */
STATIC UINT32 OsCvtSecFlagsToAttrs(UINT32 flags)
{
UINT32 mmuFlags;
mmuFlags = OsCvtSecCacheFlagsToMMUFlags(flags);
if (mmuFlags == LOS_ERRNO_VM_INVALID_ARGS) {
return mmuFlags;
}
mmuFlags |= MMU_DESCRIPTOR_L1_SMALL_DOMAIN_CLIENT;
mmuFlags |= OsCvtSecAccessFlagsToMMUFlags(flags);
if (!(flags & VM_MAP_REGION_FLAG_PERM_EXECUTE)) {
mmuFlags |= MMU_DESCRIPTOR_L1_SECTION_XN;
}
if (flags & VM_MAP_REGION_FLAG_NS) {
mmuFlags |= MMU_DESCRIPTOR_L1_SECTION_NON_SECURE;
}
if (flags & VM_MAP_REGION_FLAG_PERM_USER) {
mmuFlags |= MMU_DESCRIPTOR_L1_SECTION_NON_GLOBAL;
}
return mmuFlags;
}
⑶  STATIC VOID OsCvtSecAttsToFlags(PTE_T l1Entry, UINT32 *flags)
{
*flags = 0;
if (l1Entry & MMU_DESCRIPTOR_L1_SECTION_NON_SECURE) {
*flags |= VM_MAP_REGION_FLAG_NS;
}
switch (l1Entry & MMU_DESCRIPTOR_L1_TEX_TYPE_MASK) {
case MMU_DESCRIPTOR_L1_TYPE_STRONGLY_ORDERED:
*flags |= VM_MAP_REGION_FLAG_STRONGLY_ORDERED;
break;
case MMU_DESCRIPTOR_L1_TYPE_NORMAL_NOCACHE:
*flags |= VM_MAP_REGION_FLAG_UNCACHED;
break;
case MMU_DESCRIPTOR_L1_TYPE_DEVICE_SHARED:
case MMU_DESCRIPTOR_L1_TYPE_DEVICE_NON_SHARED:
*flags |= VM_MAP_REGION_FLAG_UNCACHED_DEVICE;
break;
default:
break;
}
*flags |= VM_MAP_REGION_FLAG_PERM_READ;
switch (l1Entry & MMU_DESCRIPTOR_L1_AP_MASK) {
case MMU_DESCRIPTOR_L1_AP_P_RO_U_NA:
break;
case MMU_DESCRIPTOR_L1_AP_P_RW_U_NA:
*flags |= VM_MAP_REGION_FLAG_PERM_WRITE;
break;
case MMU_DESCRIPTOR_L1_AP_P_RO_U_RO:
*flags |= VM_MAP_REGION_FLAG_PERM_USER;
break;
case MMU_DESCRIPTOR_L1_AP_P_RW_U_RW:
*flags |= VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_WRITE;
break;
default:
break;
}
if (!(l1Entry & MMU_DESCRIPTOR_L1_SECTION_XN)) {
*flags |= VM_MAP_REGION_FLAG_PERM_EXECUTE;
}
}

7.3.3 OsCvtPte2FlagsToAttrs函数和OsCvtPte2AttsToFlags函数

和上一小节非常类似，上节是L1 Section类型页表项MMU属性和内存区域标签属性的相互转换，本节的2个函数是L2页表项MMU属性和内存区域标签属性的相互转换。函数OsCvtPte2FlagsToAttrs()把内存区域映射标签属性转换为L2页表项MMU属性，又分为2个函数，分别是⑴处的函数OsCvtPte2CacheFlagsToMMUFlags()和⑵处的OsCvtPte2AccessFlagsToMMUFlags()。OsCvtPte2CacheFlagsToMMUFlags()函数主要判断内存映射区域的低2位缓存标签属性的转换。OsCvtPte2AccessFlagsToMMUFlags()函数用于映射标签属性的2-4位访问权限部分的转换。代码比较简单不再赘述。

⑶处的函数OsCvtPte2AttsToFlags()是上述函数OsCvtPte2FlagsToAttrs的逆过程，用于把L2页表项的MMU标签属性转换为内存区域映射标签属性。自行阅读代码，不再逐行分析。

⑴  STATIC UINT32 OsCvtPte2CacheFlagsToMMUFlags(UINT32 flags)
{
UINT32 mmuFlags = 0;
switch (flags & VM_MAP_REGION_FLAG_CACHE_MASK) {
case VM_MAP_REGION_FLAG_CACHED:
#ifdef LOSCFG_KERNEL_SMP
mmuFlags |= MMU_DESCRIPTOR_L2_SHAREABLE;
#endif
mmuFlags |= MMU_DESCRIPTOR_L2_TYPE_NORMAL_WRITE_BACK_ALLOCATE;
break;
case VM_MAP_REGION_FLAG_STRONGLY_ORDERED:
mmuFlags |= MMU_DESCRIPTOR_L2_TYPE_STRONGLY_ORDERED;
break;
case VM_MAP_REGION_FLAG_UNCACHED:
mmuFlags |= MMU_DESCRIPTOR_L2_TYPE_NORMAL_NOCACHE;
break;
case VM_MAP_REGION_FLAG_UNCACHED_DEVICE:
mmuFlags |= MMU_DESCRIPTOR_L2_TYPE_DEVICE_SHARED;
break;
default:
return LOS_ERRNO_VM_INVALID_ARGS;
}
return mmuFlags;
}
⑵  STATIC UINT32 OsCvtPte2AccessFlagsToMMUFlags(UINT32 flags)
{
UINT32 mmuFlags = 0;
switch (flags & (VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE)) {
case 0:
mmuFlags |= MMU_DESCRIPTOR_L1_AP_P_NA_U_NA;
break;
case VM_MAP_REGION_FLAG_PERM_READ:
case VM_MAP_REGION_FLAG_PERM_USER:
mmuFlags |= MMU_DESCRIPTOR_L2_AP_P_RO_U_NA;
break;
case VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_READ:
mmuFlags |= MMU_DESCRIPTOR_L2_AP_P_RO_U_RO;
break;
case VM_MAP_REGION_FLAG_PERM_WRITE:
case VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE:
mmuFlags |= MMU_DESCRIPTOR_L2_AP_P_RW_U_NA;
break;
case VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_WRITE:
case VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_READ | VM_MAP_REGION_FLAG_PERM_WRITE:
mmuFlags |= MMU_DESCRIPTOR_L2_AP_P_RW_U_RW;
break;
default:
break;
}
return mmuFlags;
}
/* convert user level mmu flags to L2 descriptors flags */
STATIC UINT32 OsCvtPte2FlagsToAttrs(UINT32 flags)
{
UINT32 mmuFlags;
mmuFlags = OsCvtPte2CacheFlagsToMMUFlags(flags);
if (mmuFlags == LOS_ERRNO_VM_INVALID_ARGS) {
return mmuFlags;
}
mmuFlags |= OsCvtPte2AccessFlagsToMMUFlags(flags);
if (!(flags & VM_MAP_REGION_FLAG_PERM_EXECUTE)) {
mmuFlags |= MMU_DESCRIPTOR_L2_TYPE_SMALL_PAGE_XN;
} else {
mmuFlags |= MMU_DESCRIPTOR_L2_TYPE_SMALL_PAGE;
}
if (flags & VM_MAP_REGION_FLAG_PERM_USER) {
mmuFlags |= MMU_DESCRIPTOR_L2_NON_GLOBAL;
}
return mmuFlags;
}
⑶  STATIC VOID OsCvtPte2AttsToFlags(PTE_T l1Entry, PTE_T l2Entry, UINT32 *flags)
{
*flags = 0;
/* NS flag is only present on L1 entry */
if (l1Entry & MMU_DESCRIPTOR_L1_PAGETABLE_NON_SECURE) {
*flags |= VM_MAP_REGION_FLAG_NS;
}
switch (l2Entry & MMU_DESCRIPTOR_L2_TEX_TYPE_MASK) {
case MMU_DESCRIPTOR_L2_TYPE_STRONGLY_ORDERED:
*flags |= VM_MAP_REGION_FLAG_STRONGLY_ORDERED;
break;
case MMU_DESCRIPTOR_L2_TYPE_NORMAL_NOCACHE:
*flags |= VM_MAP_REGION_FLAG_UNCACHED;
break;
case MMU_DESCRIPTOR_L2_TYPE_DEVICE_SHARED:
case MMU_DESCRIPTOR_L2_TYPE_DEVICE_NON_SHARED:
*flags |= VM_MAP_REGION_FLAG_UNCACHED_DEVICE;
break;
default:
break;
}
*flags |= VM_MAP_REGION_FLAG_PERM_READ;
switch (l2Entry & MMU_DESCRIPTOR_L2_AP_MASK) {
case MMU_DESCRIPTOR_L2_AP_P_RO_U_NA:
break;
case MMU_DESCRIPTOR_L2_AP_P_RW_U_NA:
*flags |= VM_MAP_REGION_FLAG_PERM_WRITE;
break;
case MMU_DESCRIPTOR_L2_AP_P_RO_U_RO:
*flags |= VM_MAP_REGION_FLAG_PERM_USER;
break;
case MMU_DESCRIPTOR_L2_AP_P_RW_U_RW:
*flags |= VM_MAP_REGION_FLAG_PERM_USER | VM_MAP_REGION_FLAG_PERM_WRITE;
break;
default:
break;
}
if ((l2Entry & MMU_DESCRIPTOR_L2_TYPE_MASK) != MMU_DESCRIPTOR_L2_TYPE_SMALL_PAGE_XN) {
*flags |= VM_MAP_REGION_FLAG_PERM_EXECUTE;
}
}