FreeCalypso > hg > fc-magnetite
view src/gpf2/osl/os_mem_fl.c @ 671:5f00e9afd5d9
removing clutter: INIT_blob provision
The lost init.c source was reconstructed from init.obj in 2017; prior
to that reconstruction we were compiling main.lib from partial source:
using the init module in blob form with various binary patches, but
recompiling create_RVtasks.c from source so we could change RiViera SWE
configuration.
We've been using the fully reconstructed version of init.c since 2017,
and now the old INIT_blob provision (which is not used by any config)
is just extra noise in our targets/*.conf files. This commit removes
all bits related to this provision, reducing clutter and making it
easier to add new targets.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Fri, 29 May 2020 02:36:39 +0000 |
parents | 2e73bbc0648e |
children |
line wrap: on
line source
/* * This C module is a reconstruction based on the disassembly of * os_mem.obj in frame_na7_db_fl.lib from the Leonardo package. */ /* set of included headers from COFF symtab: */ #include <stdio.h> #include <string.h> #include "nucleus.h" #include "typedefs.h" #include "os.h" #include "gdi.h" #include "os_types.h" #include "os_glob.h" extern T_OS_PART_GRP_TABLE_ENTRY PartGrpTable[]; extern T_OS_MEM_POOL_TABLE_ENTRY MemPoolTable[]; extern T_OS_POOL_BORDER PoolBorder[]; OS_HANDLE os_ext_pool_handle; OS_HANDLE os_int_pool_handle; static USHORT NumOfMemoryPools; static NU_SEMAPHORE MemSemCB; static NU_MEMORY_POOL mem_pool_head; GLOBAL LONG os_SetPoolHandles(OS_HANDLE ext_pool_handle, OS_HANDLE int_pool_handle) { os_ext_pool_handle = ext_pool_handle; os_int_pool_handle = int_pool_handle; return(OS_OK); } static int os_GetPartitionPoolEntry(USHORT Index, T_OS_PART_POOL **pool) { static T_OS_PART_POOL *part_pool; static int grp_hndl; switch (Index) { case FIRST_ENTRY: grp_hndl = 0; *pool = part_pool = PartGrpTable[0].grp_head; return(OS_OK); case NEXT_ENTRY: if (part_pool->next) { *pool = part_pool = part_pool->next; return(OS_OK); } grp_hndl++; if (PartGrpTable[grp_hndl].grp_head) { *pool = part_pool = PartGrpTable[grp_hndl].grp_head; return(OS_OK); } else return(OS_ERROR); default: return(OS_ERROR); } } GLOBAL LONG os_PartitionInformation(USHORT Handle, char *Buffer) { T_OS_PART_POOL *pool; OPTION SuspendType; UNSIGNED PoolSize; UNSIGNED PartitionSize; UNSIGNED Available; UNSIGNED Waiting; UNSIGNED Allocated; VOID *pStartAddress; NU_TASK *First; CHAR Name[NU_MAX_NAME]; if (os_GetPartitionPoolEntry(Handle, &pool) == OS_ERROR) return(OS_ERROR); if (NU_Partition_Pool_Information(&pool->pcb, Name, &pStartAddress, &PoolSize, &PartitionSize, &Available, &Allocated, &SuspendType, &Waiting, &First) != NU_SUCCESS) return(OS_ERROR); sprintf(Buffer, "Name:%s Addr:%lx PoolSize:%ld PartSize:%ld Free:%ld Used:%ld", Name, (UNSIGNED) pStartAddress, PoolSize, PartitionSize, Available, Allocated); return(OS_OK); } static int os_GetMemoryPoolEntry(USHORT Index, OS_HANDLE *Handle) { static USHORT Idx; switch (Index) { case FIRST_ENTRY: Idx = 0; break; case NEXT_ENTRY: Idx++; break; default: Idx = Index; } if (Idx == NumOfMemoryPools) return(OS_ERROR); *Handle = Idx; return(OS_OK); } GLOBAL LONG os_MemoryInformation(USHORT Index, char *Buffer) { OS_HANDLE Handle; OPTION SuspendType; UNSIGNED Size, Min, Available, Waiting; VOID *pStartAddress; NU_TASK *First; CHAR Name[NU_MAX_NAME]; if (os_GetMemoryPoolEntry(Index, &Handle) == OS_ERROR) return(OS_ERROR); if (NU_Memory_Pool_Information(MemPoolTable[Handle].pcb, Name, &pStartAddress, &Size, &Min, &Available, &SuspendType, &Waiting, &First) != NU_SUCCESS) return(OS_ERROR); sprintf(Buffer, "Heapname:%s Addr:%lx Size:%ld Min:%ld Free:%ld Suspend:%d", Name, (UNSIGNED) pStartAddress, Size, Min, Available, SuspendType); return(OS_OK); } GLOBAL LONG os_MemInit(void) { USHORT i; if (NU_Create_Semaphore(&MemSemCB, "MEMSEM", 1, NU_PRIORITY) != NU_SUCCESS) return(OS_ERROR); for (i = 0; i <= MaxPoolGroups; i++) { PoolBorder[i].Start = (char *)0xFFFFFFFF; PoolBorder[i].End = (char *)0; PartGrpTable[i].grp_head = 0; PartGrpTable[i].name[0] = 0; } MemPoolTable[0].pcb = &mem_pool_head; return(OS_OK); } void os_InitPartitionCheck(T_OS_PART_POOL *pool) { unsigned **Buffer, offset; USHORT i, k; NU_Allocate_Memory(MemPoolTable[0].pcb, (VOID **) &Buffer, pool->pcb.pm_available * sizeof(unsigned *), NU_NO_SUSPEND); offset = pool->pcb.pm_partition_size / sizeof(unsigned) - 1; for (i = 0; ; i++) { if (NU_Allocate_Partition(&pool->pcb, (VOID **)(Buffer + i), NU_NO_SUSPEND) != NU_SUCCESS) break; Buffer[i][offset] = GUARD_PATTERN; } for (k = 0; k < i; k++) if (NU_Deallocate_Partition(Buffer[k]) != NU_SUCCESS) break; NU_Deallocate_Memory(Buffer); } GLOBAL const ULONG * os_GetPrimpoolCB(int grp, int id) { T_OS_PART_POOL *pool; int i; pool = PartGrpTable[grp].grp_head; if (!pool) return(0); if (id < 0) return(0); for (i = 0; i < id; i++) { pool = pool->next; if (!pool) return(0); } return (const ULONG *) &pool->pcb; } GLOBAL LONG os_GetPartitionPoolStatus(ULONG size, OS_HANDLE gr_hndl, USHORT *m_free, USHORT *m_alloc) { T_OS_PART_POOL *pool; UNSIGNED dummy, allocated, available; CHAR Name[NU_MAX_NAME]; for (pool = PartGrpTable[gr_hndl].grp_head; pool; pool = pool->next) { if (!size) break; if (size > pool->size) continue; if (NU_Partition_Pool_Information(&pool->pcb, Name, (VOID **)&dummy, &dummy, &dummy, &available, &allocated, (OPTION *)&dummy, &dummy, (NU_TASK **)&dummy) != NU_SUCCESS) break; *m_alloc = allocated; *m_free = available; return(OS_OK); } *m_alloc = 0; *m_free = 0; return(OS_ERROR); } GLOBAL LONG os_GetPartitionGroupHandle(OS_HANDLE Caller, char *Name, OS_HANDLE *GroupHandle) { int i; for (i = 0; i <= MaxPoolGroups; i++) { if (!PartGrpTable[i].grp_head) continue; if (strncmp(Name, PartGrpTable[i].name, RESOURCE_NAMELEN-1)) continue; *GroupHandle = i; return(OS_OK); } return(OS_ERROR); } GLOBAL LONG os_DeallocateMemory(OS_HANDLE TaskHandle, T_VOID_STRUCT *Buffer) { if (NU_Deallocate_Memory(Buffer) == NU_SUCCESS) return(OS_OK); else return(OS_ERROR); } GLOBAL LONG os_AllocateMemory(OS_HANDLE TaskHandle, T_VOID_STRUCT **Buffer, ULONG Size, ULONG Suspend, OS_HANDLE PoolHandle) { int ret, sts; if (Suspend == 0xFFFFFFFF) Suspend = 1; ret = OS_OK; for (;;) { sts = NU_Allocate_Memory(MemPoolTable[PoolHandle].pcb, (VOID **) Buffer, Size, Suspend); switch (sts) { case NU_SUCCESS: return(ret); case NU_INVALID_SUSPEND: Suspend = 0; continue; case NU_NO_MEMORY: case NU_TIMEOUT: if (Suspend == 1) { Suspend = 0xFFFFFFFF; ret = OS_WAITED; continue; } else { *Buffer = 0; return(OS_TIMEOUT); } default: /* * Disassembly reveals that the original code * has an endless loop here, the equivalent * of continue. My guess is that they simply * forgot the default case, and so control * falls onto the closing brace of the switch * and then onto the closing brace of the for * loop. But I prefer better error handling, * hence the present addition. - Space Falcon */ *Buffer = 0; return(OS_ERROR); } } } GLOBAL LONG os_CreatePartitionPool(OS_HANDLE TaskHandle, char *GroupName, void *Addr, USHORT Num, ULONG Size, OS_HANDLE *GroupHandle) { STATUS sts; T_OS_PART_POOL *part_group_head, *opool, *npool; USHORT part_group; USHORT i, j; char PoolName[8], *cp; sts = NU_Obtain_Semaphore(&MemSemCB, NU_SUSPEND); j = 0; part_group_head = 0; for (i = 0; i <= MaxPoolGroups; i++) { if (!PartGrpTable[i].grp_head || !PartGrpTable[i].name[0]) break; if (!strncmp(GroupName, PartGrpTable[i].name, RESOURCE_NAMELEN - 1)) { part_group_head = PartGrpTable[i].grp_head; opool = part_group_head; j++; while (opool->next) { opool = opool->next; j++; } break; } } /* * This error check logic has been modified from the original * faithful reconstruction by Space Falcon. In the original code * if MaxPoolGroups had been reached and the for loop above * never broke, the code would proceed to overwrite pool #0 * instead of catching the error. */ if (i > MaxPoolGroups) { release_sem_return_err: if (sts == NU_SUCCESS) NU_Release_Semaphore(&MemSemCB); return(OS_ERROR); } part_group = i; if (!part_group_head) { strncpy(PartGrpTable[part_group].name, GroupName, RESOURCE_NAMELEN); PartGrpTable[part_group].name[RESOURCE_NAMELEN-1] = 0; } if (os_AllocateMemory(OS_NOTASK, (T_VOID_STRUCT **) &npool, sizeof(T_OS_PART_POOL), OS_NO_SUSPEND, os_ext_pool_handle) != OS_OK) goto release_sem_return_err; sprintf(PoolName, "POOL%1d%1d", part_group + 1, j); Size &= ~3; npool->pool_mem = Addr; #if 0 /* * FreeCalypso: in our first-attempt gcc-built firmwares we needed to * bzero the PM_PCB before calling NU_Create_Partition_Pool() to * prevent the possibility of Nucleus error checker failing the call * because the signature word happens to be there already. The issue * arose because we were using "raw" memory sections that weren't * zeroed out on boot like standard .bss, but in TI's original * architecture everything is zeroed out on boot, so we don't need * this additional zeroing here. */ bzero(&npool->pcb, sizeof(NU_PARTITION_POOL)); #endif if (NU_Create_Partition_Pool(&npool->pcb, PoolName, npool->pool_mem, POOL_SIZE(Num, Size), Size + 4, NU_FIFO) != NU_SUCCESS) goto release_sem_return_err; if (!part_group_head) PartGrpTable[part_group].grp_head = npool; else opool->next = npool; npool->size = Size; npool->next = 0; *GroupHandle = part_group; cp = (char *) npool->pool_mem; if (PoolBorder[part_group].Start >= cp) PoolBorder[part_group].Start = cp; cp += POOL_SIZE(Num, Size); if (PoolBorder[part_group].End < cp) PoolBorder[part_group].End = cp; os_InitPartitionCheck(npool); if (sts == NU_SUCCESS) NU_Release_Semaphore(&MemSemCB); return(OS_OK); } GLOBAL LONG os_CreatePartitionPool_fixed_pool_size(OS_HANDLE TaskHandle, char *GroupName, void *Addr, USHORT PoolSize, ULONG PartSize, OS_HANDLE *GroupHandle, ULONG *NumCreated) { USHORT num; num = PoolSize / (PartSize + PT_CHKOVERHEAD + PT_OVERHEAD); *NumCreated = num; return os_CreatePartitionPool(TaskHandle, GroupName, Addr, num, PartSize, GroupHandle); } GLOBAL LONG os_CreateMemoryPool(OS_HANDLE TaskHandle, char *Name, void *Addr, ULONG PoolSize, OS_HANDLE *PoolHandle) { STATUS sts; USHORT i; sts = NU_Obtain_Semaphore(&MemSemCB, NU_SUSPEND); for (i = 0; i < NumOfMemoryPools; i++) if (!strncmp(Name, MemPoolTable[i].name, RESOURCE_NAMELEN-1)) { *PoolHandle = i; if (sts == NU_SUCCESS) NU_Release_Semaphore(&MemSemCB); return(OS_OK); } if (i >= MaxMemoryPools) { release_sem_return_err: if (sts == NU_SUCCESS) NU_Release_Semaphore(&MemSemCB); return(OS_ERROR); } if (i) { if (os_AllocateMemory(OS_NOTASK, (T_VOID_STRUCT **) &MemPoolTable[i].pcb, sizeof(NU_MEMORY_POOL), OS_NO_SUSPEND, os_ext_pool_handle) != OS_OK) goto release_sem_return_err; #if 0 /* * FreeCalypso: in our first-attempt gcc-built firmwares we * needed to bzero the DM_PCB before calling * NU_Create_Memory_Pool() to prevent the possibility of * Nucleus error checker failing the call because the signature * word happens to be there already. The issue arose because * we were using "raw" memory sections that weren't zeroed out * on boot like standard .bss, but in TI's original architecture * everything is zeroed out on boot, so we don't need this * additional zeroing here. */ bzero(MemPoolTable[i].pcb, sizeof(NU_MEMORY_POOL)); #endif } if (NU_Create_Memory_Pool(MemPoolTable[i].pcb, Name, Addr, PoolSize, 4, NU_FIFO) != NU_SUCCESS) goto release_sem_return_err; strncpy(MemPoolTable[i].name, Name, RESOURCE_NAMELEN); MemPoolTable[i].name[RESOURCE_NAMELEN-1] = 0; *PoolHandle = i; NumOfMemoryPools++; if (sts == NU_SUCCESS) NU_Release_Semaphore(&MemSemCB); return(OS_OK); }