FreeCalypso > hg > fc-magnetite
view src/gpf2/osl/os_mem_ir.c @ 673:62a5285e014a
Lorekeeping: allow tpudrv-leonardo.lib on Leonardo/Tango
Back in 2015 the Mother's idea was to produce a FreeCalypso development
board that would be a clone of TI Leonardo, including the original
quadband RFFE; one major additional stipulation was that this board
needed to be able to run original unmodified TCS211-20070608 firmware
with all blobs intact, with only minimal binary patches to main.lib
and tpudrv.lib. The necessary patched libs were produced at that time
in the tcs211-patches repository.
That plan was changed and we produced FCDEV3B instead, with Openmoko's
triband RFFE instead of Leonardo quadband, but when FC Magnetite started
in 2016, a TPUDRV_blob= provision was still made, allowing the possibility
of patching OM's tpudrv.lib for a restored Leonardo RFFE.
Now in 2020 we have FC Tango which is essentially a verbatim clone of
Leonardo core, including the original quadband RFFE. We have also
deblobbed our firmware so much that we have absolutely no real need
for a blob version of tpudrv.lib - but I thought it would be neat to put
the ancient TPUDRV_blob= mechanism (classic config) to its originally
intended use, just for the heck of it.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Fri, 29 May 2020 03:55:36 +0000 |
parents | e9bdc8184d50 |
children |
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/* * This C module is a reconstruction based on the disassembly of * os_mem.obj in frame_na7_db_ir.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_POOL_BORDER PoolBorder[]; GLOBAL LONG os_is_valid_partition(T_VOID_STRUCT *Buffer) { int i; for (i = 0; i <= MaxPoolGroups; i++) { if (PoolBorder[i].End == 0) return(OS_ERROR); if ((char *)Buffer < PoolBorder[i].Start) continue; if ((char *)Buffer >= PoolBorder[i].End) continue; return(OS_OK); } return(OS_ERROR); } GLOBAL LONG os_PartitionCheck(ULONG *ptr) { PM_HEADER *phdr; PM_PCB *pool; phdr = (PM_HEADER *)(ptr - 2); if (phdr->pm_next_available) return(OS_PARTITION_FREE); pool = phdr->pm_partition_pool; if (ptr[(pool->pm_partition_size - 4) >> 2] == GUARD_PATTERN) return(OS_OK); else return(OS_PARTITION_GUARD_PATTERN_DESTROYED); } GLOBAL LONG os_DeallocatePartition(OS_HANDLE TaskHandle, T_VOID_STRUCT *Buffer) { if (os_is_valid_partition(Buffer) != OS_OK) return(OS_ERROR); if (NU_Deallocate_Partition(Buffer) != NU_SUCCESS) return(OS_ERROR); return(OS_OK); } GLOBAL LONG os_AllocatePartition(OS_HANDLE TaskHandle, T_VOID_STRUCT **Buffer, ULONG Size, ULONG Suspend, OS_HANDLE GroupHandle) { T_OS_PART_POOL *pool, *requested_pool; ULONG nu_suspend; STATUS sts; int ret; for (pool = PartGrpTable[GroupHandle].grp_head; pool; pool = pool->next) if (Size <= pool->size) break; if (!pool) return(OS_ERROR); requested_pool = pool; ret = OS_OK; nu_suspend = NU_NO_SUSPEND; try_alloc: sts = NU_Allocate_Partition(&pool->pcb, (VOID **) Buffer, nu_suspend); switch (sts) { case NU_SUCCESS: return(ret); case NU_TIMEOUT: case NU_INVALID_SUSPEND: *Buffer = 0; return(OS_TIMEOUT); case NU_NO_PARTITION: pool = pool->next; if (pool) { ret = OS_ALLOCATED_BIGGER; goto try_alloc; } pool = requested_pool; if (Suspend) { nu_suspend = Suspend; ret = OS_WAITED; goto try_alloc; } return(OS_TIMEOUT); default: *Buffer = 0; return(OS_ERROR); } }