FreeCalypso > hg > fc-magnetite
view src/ui3/bmi/mmiBlkResources.c @ 629:3231dd9b38c1
armio.c: make GPIOs 8 & 13 outputs driving 1 on all "classic" targets
Calypso GPIOs 8 & 13 are pinmuxed with MCUEN1 & MCUEN2, respectively,
and on powerup these pins are MCUEN, i.e., outputs driving 1. TI's code
for C-Sample and earlier turns them into GPIOs configured as outputs also
driving 1 - so far, so good - but TI's code for BOARD 41 (which covers
D-Sample, Leonardo and all real world Calypso devices derived from the
latter) switches them from MCUEN to GPIOs, but then leaves them as inputs.
Given that the hardware powerup state of these two pins is outputs driving 1,
every Calypso board design MUST be compatible with such driving; typically
these GPIO signals will be either unused and unconnected or connected as
outputs driving some peripheral. Turning these pins into GPIO inputs will
result in floating inputs on every reasonably-wired board, thus I am
convinced that this configuration is nothing but a bug on the part of
whoever wrote this code at TI.
This floating input bug had already been fixed earlier for GTA modem and
FCDEV3B targets; the present change makes the fix unconditional for all
"classic" targets. The newly affected targets are D-Sample, Leonardo,
Tango and GTM900.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Thu, 02 Jan 2020 05:38:26 +0000 |
| parents | 6a4d9f47793e |
| children |
line wrap: on
line source
/******************************************************************************* CONDAT (UK) ******************************************************************************** This software product is the property of Condat (UK) Ltd and may not be disclosed to any third party without the express permission of the owner. ******************************************************************************** $Project name: Basic MMI $Project code: BMI (6349) $Module: PhoneBook $File: MmiBlkResources.c $Revision: 1.0 $Author: Condat(UK) $Date: 25/10/00 ******************************************************************************** Description: This modules provides, in conjunction with the MmiBlkManager module, the resource management facilities for the MMI. ******************************************************************************** $History: MmiBlkResources.c 25/10/00 Original Condat(UK) BMI version. $End *******************************************************************************/ /******************************************************************************* Include Files *******************************************************************************/ #define ENTITY_MFW /* includes */ #include <string.h> #include <stdio.h> #include <stdlib.h> #if defined (NEW_FRAME) #include "typedefs.h" #include "vsi.h" #include "pei.h" #include "custom.h" #include "gsm.h" #else #include "STDDEFS.H" #include "custom.h" #include "gsm.h" #include "vsi.h" #endif // #include <malloc.h> #include "MmiBlkResources.h" /******************************************************************************* Local Structures *******************************************************************************/ /* Define the control structures used to implement the block resource manager */ #define RESOURCE_MANAGER_KEY 0x00BABE02L #define RESOURCE_SEARCH_LIMIT 4 typedef struct _tBlkEntry_ { tBlkId BlkId; tBlkHandle BlkHandle; } tBlkEntry, *pBlkEntry; typedef struct _tBlkControl_ { long int BlkKey; tBlkHandle BlkBase; int BlkLength; pBlkEntry BlkStartPtr; tBlkHandle BlkMinAddress; tBlkHandle BlkMaxAddress; } tBlkControl, *pBlkControl; /******************************************************************************* Private Routines *******************************************************************************/ /******************************************************************************* $Function: ValidBlockResource $Description: Verifies that the resource indicated by the handle is a valid resource. $Returns: 0 If invalid, non-zero if valid. $Arguments: BlkRsrc, handle of resource *******************************************************************************/ static int ValidBlockResource( tBlkHandle BlkRsrc ) { pBlkControl BlkControl = (pBlkControl) BlkRsrc; /* Check for non-NULL handle */ if ( BlkControl == NULL ) return 0; /* Check key has been set up correctly */ return ( BlkControl->BlkKey == RESOURCE_MANAGER_KEY ); } /******************************************************************************* Public Routines *******************************************************************************/ /******************************************************************************* $Function: mmibr_Initialise $Description: The initialisation routine must be called as part of the startup phase of the system, it will allocate working space for the block handler if required, and will initialise any structures required to maintain the corect operation of the functions. This routine must be called prior to invocation of any other block resource function $Returns: Handle to a resource block, NULL if unsuccessful $Arguments: BlkBase, Base address of the block of data relating to the resource NumEntries, number of entries associated with the resource *******************************************************************************/ tBlkHandle mmibr_Initialise( tBlkHandle BlkBase, int NumEntries ) { pBlkControl Blk; int i; /* As part of the initialisation process, we need to allocate a block of memory in which to store the control information associated with this block resource manager */ if ( ( Blk = (pBlkControl) ALLOC_MEMORY( sizeof(tBlkControl) ) ) != NULL ) { /* Store the things we know straight off */ Blk->BlkKey = RESOURCE_MANAGER_KEY; Blk->BlkBase = BlkBase; Blk->BlkLength = NumEntries; Blk->BlkStartPtr = (pBlkEntry) BlkBase; /* In order to detect memory allocations, we scan the list of known entries, storing the maximum and minimum addresses in the list. This scan allows us to detect when allocated memory is being returned, since the address will be outside the contiguous memory block we are managing. */ Blk->BlkMinAddress = Blk->BlkMaxAddress = BlkBase; for ( i = 0; i < NumEntries; i++ ) { if ( Blk->BlkMaxAddress < Blk->BlkStartPtr[i].BlkHandle ) Blk->BlkMaxAddress = Blk->BlkStartPtr[i].BlkHandle; } } return Blk; } /******************************************************************************* $Function: mmibr_ShutDown $Description: The shutdown function can be called to free any allocations set up by the Initialise routine. In a running system this is unlikely to be called unless a catastrophic error has occurred and the system needs to be restarted. $Returns: none. $Arguments: Pointer to a block resource handle (ie ptr to ptr) *******************************************************************************/ void mmibr_ShutDown( tBlkHandle *BlkRsrc ) { /* Only allow the resource manager to be shutdown if the provided handle is consistent */ if ( ValidBlockResource( *BlkRsrc ) ) { free( *BlkRsrc ); *BlkRsrc = NULL; } } /******************************************************************************* $Function: mmibr_Fetch $Description: We will adopt a mechanism where each block of data being provided will need to be returned to the block resource manager when it is no longer being used, this will provide an orthogonal approach when dealing with data coming from either ROM or dynamically allocated memory. $Returns: pointer to resource, NULL if unsuccessful $Arguments: BlkRsrc, resource handle created by mmibr_Initialise Id, identifier of the resource to be returned *******************************************************************************/ tBlkHandle mmibr_Fetch( tBlkHandle BlkRsrc, tBlkId Id ) { int Start, End, Search; tBlkId CurrentId; tBlkHandle SearchPtr; /* convert the handle and verify it's valid */ pBlkControl BlkControl = (pBlkControl) BlkRsrc; if ( ! ValidBlockResource( BlkRsrc ) ) return NULL; /* When locating a specific entry, we need to search the list of ids for one matching the input value. Since the Ids will be organised as an ordered list, very important that bit, we can perform a simple binary search to locate the items. */ Start = 0; End = BlkControl->BlkLength - 1; SearchPtr = NULL; do { /* grab the entry midway between the current start and end */ Search = Start + ((End - Start) >> 1); CurrentId = BlkControl->BlkStartPtr[Search].BlkId; /* Binary chop the search space */ if ( CurrentId == Id ) { /* Found a match, grab handle and terminate search */ SearchPtr = BlkControl->BlkStartPtr[Search].BlkHandle; Start = End; } else if ( CurrentId > Id ) { /* Not got a match, but it's not in the top half so move the End pointer down */ End = Search; } else { /* Not got a match, but it's not in the bottom half so move the Start pointer up */ Start = Search; } /* when we get down to the last three or four entries, just search linearly to solve it, this is generally quicker for a small number of entries than continuing the binary chop */ if ( ( End - Start ) < RESOURCE_SEARCH_LIMIT ) { /* search quickly through the possibles */ for ( Search = Start; Search <= End; Search++ ) if ( Id == BlkControl->BlkStartPtr[Search].BlkId ) SearchPtr = BlkControl->BlkStartPtr[Search].BlkHandle; /* And terminate the binary chop */ Start = End; } } while ( Start != End ); return SearchPtr; } /******************************************************************************* End of File *******************************************************************************/