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view src/gpf2/osl/os_mem_ir.c @ 629:3231dd9b38c1

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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 e9bdc8184d50
children
line wrap: on
line source

/*
 * 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);
	}
}