FreeCalypso > hg > fc-tourmaline
view src/gpf/frame/cust_os/osx.c @ 75:8697f358f505
backlight rework: Condat light driver accepts levels
The present change is another intermediate step on the path toward
new FreeCalypso backlight handling. At this intermediate step the
Condat light driver accepts 0-255 backlight levels driven by MFW,
and puts them out on PWL on Luna development boards. At the same
time on C139 it is now possible to turn on the display backlight
with or without the keypad bl - the lsb of the 0-255 backlight level
controls the keypad bl.
MFW presently drives only 0 and 255 backlight levels, thus there is
no visible behavioral change yet - but the plan for subsequent stages
of this backlight rework is to add a dimmed backlight state
(no keypad bl on C139) during active calls.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Sat, 24 Oct 2020 20:44:04 +0000 |
| parents | 4e78acac3d88 |
| children |
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/* * This C module is a reconstruction based on the disassembly of * osx.obj in osx_na7_db.lib from the Leonardo package. */ /* reconstructed set of included headers from COFF symtab: */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include "typedefs.h" #include "vsi.h" #include "cust_os.h" int osx_config = 2; int _caller; T_OSX_REGISTER _osx_registry[MAX_OSX_QUEUE]; void int_osx_send_sig(int caller, unsigned long opc, void *signal_ptr, int queue_handle) { T_QMSG Message; int status; TRACE_ASSERT(queue_handle != 0); Message.MsgType = MSG_SIGNAL; Message.Msg.Signal.SigOPC = opc; Message.Msg.Signal.SigBuffer = signal_ptr; Message.Msg.Signal.SigLen = sizeof(xSignalHeaderRec); status = vsi_c_send(caller, queue_handle, &Message FILE_LINE_MACRO); TRACE_ASSERT(status == VSI_OK); } void osx_send_sig(unsigned long opc, void *signal_ptr, T_ENUM_OS_QUEUE queue_type) { int caller, queue_handle; caller = _osx_registry[queue_type].caller; queue_handle = _osx_registry[queue_type].queue_handle; TRACE_ASSERT(queue_handle != 0); int_osx_send_sig(caller, opc, signal_ptr, queue_handle); } void int_osx_free_prim(int caller, xSignalHeaderRec *prim_ptr) { vsi_c_free(caller, (T_VOID_STRUCT **) &prim_ptr FILE_LINE_MACRO); } void int_osx_send_prim(int caller, xSignalHeaderRec *prim_ptr, int queue_handle) { T_QMSG Message; int status; if (osx_config & 1 && prim_ptr->SignalCode == 0x7D) { vsi_c_free(caller, (T_VOID_STRUCT **) &prim_ptr FILE_LINE_MACRO); return; } TRACE_ASSERT(queue_handle != 0); Message.MsgType = MSG_PRIMITIVE; Message.Msg.Primitive.Prim = (T_VOID_STRUCT *) prim_ptr; Message.Msg.Primitive.PrimLen = sizeof(xSignalHeaderRec); status = vsi_c_send(caller, queue_handle, &Message FILE_LINE_MACRO); TRACE_ASSERT(status == VSI_OK); } void osx_send_prim(xSignalHeaderRec *prim_ptr, T_ENUM_OS_QUEUE queue_type) { int_osx_send_prim(_osx_registry[queue_type].caller, prim_ptr, _osx_registry[queue_type].queue_handle); } xSignalHeaderRec * int_osx_receive_prim(int caller, int queue_handle) { T_QMSG Message; unsigned opc; xSignalHeaderRec *message; int status; TRACE_ASSERT(queue_handle != OSX_ERROR); for (;;) { status = vsi_c_await(caller, queue_handle, &Message, 0xFFFFFFFF); TRACE_ASSERT(status == VSI_OK); /* * Disassembly reveals that the original code expects * the received message to be a primitive, rather than * a signal or a timeout. If one of the latter comes * in, the original code would go haywire. Hence the * following TRACE_ASSERT is a FreeCalypso addition. */ TRACE_ASSERT(Message.MsgType == MSG_PRIMITIVE); message = (xSignalHeaderRec *) Message.Msg.Primitive.Prim; opc = message->SignalCode & 0xFFFF; if (opc == 11 && osx_config & 2) message->SigP = *(DummyStruct **)(message + 1); else message->SigP = (DummyStruct *)(message + 1); if (opc != 0x8000) return(message); vsi_c_primitive(caller, message); } } xSignalHeaderRec * osx_receive_prim(T_ENUM_OS_QUEUE queue_type) { return int_osx_receive_prim(_osx_registry[queue_type].caller, _osx_registry[queue_type].queue_handle); } void osx_free_prim(xSignalHeaderRec *prim_ptr) { vsi_c_free(_caller, (T_VOID_STRUCT **) &prim_ptr FILE_LINE_MACRO); } void int_osx_free_mem(int caller, void *mem_ptr) { int status; TRACE_ASSERT(mem_ptr != 0); status = D_FREE(mem_ptr); TRACE_ASSERT(status == VSI_OK); } void osx_free_mem(void *mem_ptr) { int_osx_free_mem(_caller, mem_ptr); } xSignalHeaderRec * int_osx_alloc_prim(int caller, unsigned long len, int pool_group_handle) { xSignalHeaderRec *prim_ptr; prim_ptr = (xSignalHeaderRec *) vsi_c_new(caller, (len & 0xFFFF) + sizeof(xSignalHeaderRec), 0 FILE_LINE_MACRO); /* This check is a FreeCalypso addition */ TRACE_ASSERT(prim_ptr != 0); prim_ptr->SigP = (DummyStruct *)(prim_ptr + 1); return(prim_ptr); } xSignalHeaderRec * osx_alloc_prim(unsigned long len) { xSignalHeaderRec *prim_ptr; prim_ptr = (xSignalHeaderRec *) vsi_c_new(_caller, (len & 0xFFFF) + sizeof(xSignalHeaderRec), 0 FILE_LINE_MACRO); /* This check is a FreeCalypso addition */ TRACE_ASSERT(prim_ptr != 0); prim_ptr->SigP = (DummyStruct *)(prim_ptr + 1); return(prim_ptr); } void * int_osx_alloc_mem(int caller, unsigned long len) { void *mem_ptr; DMALLOC(mem_ptr, len); TRACE_ASSERT(mem_ptr != 0); return(mem_ptr); } void * osx_alloc_mem(unsigned long len) { return int_osx_alloc_mem(_caller, len); } int _osx_open(int caller, unsigned short queue_type, int queue_handle) { if (!queue_type && !queue_handle) { _caller = caller; return(OSX_ERROR); } if (queue_type >= MAX_OSX_QUEUE) return(OSX_ERROR); if (_osx_registry[queue_type].queue_handle != queue_handle && _osx_registry[queue_type].queue_handle != -1) return(OSX_ERROR); _osx_registry[queue_type].queue_handle = queue_handle; _osx_registry[queue_type].caller = caller; return(OSX_OK); } void _osx_init(void) { USHORT i; for (i = 0; i < MAX_OSX_QUEUE; i++) _osx_registry[i].queue_handle = -1; } int _osx_config(const char *config) { if (!strcmp(config, L1S_TRACE_DISABLE)) { osx_config |= 1; return(OSX_OK); } if (!strcmp(config, L1S_TRACE_ENABLE)) { osx_config &= ~1; return(OSX_OK); } if (!strcmp(config, NO_SPECIAL_MPHC_RXLEV_REQ)) { osx_config &= ~2; return(OSX_OK); } return(OSX_ERROR); }