view src/g23m-aci/gdd_dio/gdd_dio_if.c @ 221:5bf097aeaad7

LLS: when turning off all LEDs on boot, skip LED-C Having LLS turn off LED-A and LED-B on boot is normally unnecessary (they should already be off in Iota), but it is harmless, hence this logic is kept for robustness. However, having LLS read-modify-write the BCICTL2 register (to turn off LED-C) creates a potential race condition with FCHG writes to this register, especially in the case when baseband switch-on is caused by VCHG and charging is expected to start right away. Furthermore, control of the charging LED itself (on those hw targets that have it) is the responsibility of the FCHG SWE, hence LLS should leave it alone.
author Mychaela Falconia <falcon@freecalypso.org>
date Mon, 26 Apr 2021 21:55:13 +0000
parents fa8dc04885d8
children
line wrap: on
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/* 
+-----------------------------------------------------------------------------
|  Project :
|  Modul   :
+-----------------------------------------------------------------------------
|  Copyright 2004 Texas Instruments Berlin, AG
|                 All rights reserved.
|
|                 This file is confidential and a trade secret of Texas
|                 Instruments Berlin, AG
|                 The receipt of or possession of this file does not convey
|                 any rights to reproduce or disclose its contents or to
|                 manufacture, use, or sell anything it may describe, in
|                 whole, or in part, without the specific written consent of
|                 Texas Instruments Berlin, AG.
+-----------------------------------------------------------------------------
|  Purpose :  Implementation of the GDD interface with DIOv4 
+-----------------------------------------------------------------------------
*/

#define GDD_DIO_IF_C

/*==== INCLUDES =============================================================*/

#include <string.h>
#include <stdlib.h>
#include <stddef.h>
#include "typedefs.h"
#include "pcm.h"
#include "vsi.h"
#include "custom.h"
#include "gsm.h"
#include "pei.h"

#include "gdd.h"
#include "gdd_dio_data.h"
#include "gdd_dio.h"

#include "gdd_dio_con_mgr.h"
#include "gdd_dio_queue.h"

#include "gdd_dio_dtxf.h"
#include "gdd_dio_drxf.h"


/*==== CONSTANTS ============================================================*/

/*==== TYPES ================================================================*/

/*==== PROTOTYPES ===========================================================*/

/*==== GLOBAL VARS ==========================================================*/

/*==== LOCAL VARS ===========================================================*/

/*==== LOCAL FUNCTIONS=======================================================*/

/*==== EXPORTED FUNCTIONS====================================================*/

/** gdd_init_dio - see header "gdd.h" for comment and description */

GDD_RESULT gdd_init_dio
(
 T_GDD_INST_ID     inst,
 void *            mem,
 U16               num_con
 )
{
  T_GDD_DIO_DATA * gdd_dio_data;
  
  TRACE_FUNCTION("[GDD] gdd_init_dio()");
  
  /* Check params */
  if(inst < GDD_INST_BAT || inst >= GDD_NUM_INSTS)
  {
    TRACE_ERROR("[GDD] Instance id out of bounds");
    return GDD_INVALID_PARAMS;
  }
  
  gdd_dio_data = &gdd_dio_data_base[inst];
  
  if(gdd_dio_init_flag[inst])
  {
    TRACE_ERROR("[GDD] Attempted to call gdd_init_dio() twice for same instance");
    return GDD_ALREADY_INITIALIZED;
  }
  
  if(num_con < 1 || num_con > gdd_dio_data->max_con)
  {
    TRACE_ERROR("[GDD] Number of connections out of bounds");
    return GDD_INVALID_PARAMS;
  }
  
  if(mem)
  {
    gdd_dio_data->con_arr = mem;
    gdd_dio_data->con_arr_mem_allocated = FALSE;
  }
  else
  {
    gdd_dio_data->con_arr = 0;
    MALLOC(gdd_dio_data->con_arr, GDD_DIO_SIZEOF_CONDATA * num_con);
    if(gdd_dio_data->con_arr EQ 0)
    {
      TRACE_ERROR("[GDD] memory allocation failed");
      return GDD_NO_MEMORY;
    }
    
    gdd_dio_data->con_arr_mem_allocated = TRUE;
  }
  
  gdd_dio_data->max_con = num_con;
  
  /* Initialize the connection manager */
  gdd_dio_con_mgr_init(gdd_dio_data);
  
  gdd_dio_init_flag[inst] = TRUE;
  
  return GDD_OK;
}


/** gdd_deinit  - see header "gdd.h" for comment and description*/
GDD_RESULT gdd_deinit_dio
(
 T_GDD_INST_ID     inst
 )
{
  T_GDD_DIO_DATA * gdd_dio_data = 0;
  
  TRACE_FUNCTION("[GDD] gdd_deinit_dio()");
  
  if(inst < GDD_INST_BAT || inst >= GDD_NUM_INSTS)
  {
    TRACE_ERROR("[GDD] instance id out of bounds");
    return GDD_INVALID_PARAMS;
  }
  
  gdd_dio_data = &gdd_dio_data_base[inst];
  
  
  /* If we allocated our own memory, free it. */
  if(gdd_dio_data->con_arr_mem_allocated EQ FALSE)
  {
    MFREE(gdd_dio_data->con_arr);
    gdd_dio_data->con_arr = 0;
    gdd_dio_data->con_arr_mem_allocated = FALSE;
  }
  
  gdd_dio_init_flag[inst] = FALSE;
  
  return GDD_OK;
}


/** gdd_connect - see header "gdd.h" for comment and description */
GDD_RESULT gdd_connect_dio
(
 T_GDD_INST_ID     inst,
 T_GDD_CON_HANDLE * con_handle,
 const T_GDD_CAP * cap,
 T_GDD_RECEIVE_DATA_CB rcv_cb,
 T_GDD_SIGNAL_CB   sig_cb
 )
{
  T_GDD_DIO_DATA * gdd_dio_data;
  
  TRACE_FUNCTION("[GDD] gdd_connect_dio()");
  
  /**
  * Do the necessary checks.
  */
  
  if(inst < GDD_INST_BAT || inst >= GDD_NUM_INSTS)
  {
    TRACE_ERROR("[GDD] instance id out of bounds");
    return GDD_INVALID_PARAMS;
  }
  
  gdd_dio_data = &gdd_dio_data_base[inst];
  
  if (gdd_dio_data->ker.state NEQ GDD_DIO_KER_READY)
  {
    TRACE_ERROR("[GDD] DIO driver not initialized");
    return DRV_INTERNAL_ERROR;
  }  
  
  /* Check if we are already initialized. If we not, we do it ourselfs! */
  /* This is specific to the DIO implementation of GDD */ 
  if(gdd_dio_init_flag[inst] EQ FALSE)
  {
    gdd_init_dio(inst, 0, gdd_dio_data->max_con);
  }
  
  if(con_handle EQ 0)
  {
    TRACE_ERROR("[GDD] Connection handle pointer cannot be 0");
    return GDD_INVALID_PARAMS;
  }
  
  if(cap EQ 0)
  {
    TRACE_ERROR("[GDD] Capabilities pointer cannot be 0");
    return GDD_INVALID_PARAMS;
  }
  
  if(rcv_cb EQ 0 || sig_cb EQ 0)
  {
    TRACE_ERROR("[GDD] Callback function pointer cannot be 0");
    return GDD_INVALID_PARAMS;
  }
  
  /**
  * We are ready to create the DIO connection
  */
  return gdd_dio_con_mgr_new(gdd_dio_data, con_handle, cap, rcv_cb, sig_cb);
}

/** gdd_disconnect - see header "gdd.h" for comment and description */
GDD_RESULT gdd_disconnect_dio
(
 T_GDD_CON_HANDLE  con_handle
 )
{
  if(con_handle EQ 0)
  {
    TRACE_ERROR("[GDD] Connection handle cannot be 0");
    return GDD_INVALID_PARAMS;
  }
  
  /*
  * Inform the connection manager
  */
  return gdd_dio_con_mgr_close(con_handle);
}


/** gdd_get_send_buffer - see header "gdd.h" for comment and description */
GDD_RESULT gdd_get_send_buffer_dio
(
 T_GDD_CON_HANDLE  con_handle,
 T_GDD_BUF **      buf,
 U16               data_size
 )
{
  TRACE_USER_CLASS(TC_FUNC_DATA_FLOW, "[GDD] gdd_get_send_buffer_dio()");
  
  if(con_handle EQ 0)
  {
    TRACE_ERROR("[GDD] Connection handle cannot be 0");
    return GDD_INVALID_PARAMS;
  }
  if(buf EQ NULL)
  {
    TRACE_ERROR("[GDD] buf cannot be NULL");
    return GDD_INVALID_PARAMS;
  }
  
  return gdd_dio_dtx_get_send_buffer(con_handle, buf, data_size);
}


/** gdd_send_data - see header "gdd.h" for comment and description */
GDD_RESULT gdd_send_data_dio
(
 T_GDD_CON_HANDLE  con_handle,
 T_GDD_BUF *       buf
 )
{
  TRACE_USER_CLASS(TC_FUNC_DATA_FLOW, "[GDD] gdd_send_data_dio()");
  
  if(con_handle EQ 0)
  {
    TRACE_ERROR("[GDD] Connection handle cannot be 0");
    return GDD_INVALID_PARAMS;
  }
  if(buf EQ NULL)
  {
    TRACE_ERROR("[GDD] buf cannot be NULL");
    return GDD_INVALID_PARAMS;
  }
  
  return gdd_dio_dtx_send_buffer(con_handle, buf);
}


/** gdd_signal_ready_rcv - see header "gdd.h" for comment and description */
void gdd_signal_ready_rcv_dio( T_GDD_CON_HANDLE  con_handle )
{
  TRACE_FUNCTION("[GDD] gdd_signal_ready_rcv_dio()");
  
  if(con_handle NEQ 0)
  {
    return;
  }
  
  gdd_dio_drx_ready_to_rcv(con_handle);
}


/** Exported function table for DIO implementation of GDD */
T_GDD_FUNC gdd_func_dio =
{
  gdd_init_dio,
  gdd_deinit_dio,
  gdd_connect_dio,
  gdd_disconnect_dio,
  gdd_get_send_buffer_dio,
  gdd_send_data_dio,
  gdd_signal_ready_rcv_dio
};


/*==== EXPORTED HELPER FUNCTIONS=============================================*/

S32 gdd_write_buf_with_pid(const U8 * src_buf,
                           U16 src_size,
                           T_GDD_BUF * dest_buf,
                           U8 protocol_id)
{
  int idx_seg;
  int remaining;

  /* Check that we have more than one segment and that the first one
     is the PID segment which. */
  TRACE_ASSERT(dest_buf->c_segment > 1);
  TRACE_ASSERT(dest_buf->ptr_gdd_segment[0].c_data EQ GDD_DIO_PID_SEG_SIZE);

  if( dest_buf->c_segment < 2 ||
      dest_buf->ptr_gdd_segment[0].c_data NEQ GDD_DIO_PID_SEG_SIZE )
  {
    return -1;
  }

  /* Set the protocol ID, which is carried in the first buffer segment */
  /* Note: the DTI2 interface in the stack uses only 8 bits for the p_id. */
  dest_buf->ptr_gdd_segment[0].ptr_data[0] = 0x0;/* not used, see note above */
  dest_buf->ptr_gdd_segment[0].ptr_data[1] = protocol_id;


  remaining = src_size;

  for(idx_seg=1; idx_seg<dest_buf->c_segment; ++idx_seg)
  {
    T_GDD_SEGMENT * seg = &(dest_buf->ptr_gdd_segment[idx_seg]);
    int bytes_to_copy = remaining < seg->c_data ? remaining : seg->c_data;

    memcpy(seg->ptr_data, src_buf + src_size - remaining, bytes_to_copy);
    remaining -= bytes_to_copy;
    if(remaining EQ 0) 
      break;
  }

  dest_buf->length = src_size - remaining + GDD_DIO_PID_SEG_SIZE;
  return remaining;
}

#define DTI_PID_IP (0x21)  /* simple ip packet (IPv4) */

S32 gdd_write_buf(const U8 * src_buf, U16 src_size, T_GDD_BUF * dest_buf)
{
  return gdd_write_buf_with_pid(src_buf, src_size, dest_buf, DTI_PID_IP);
}

S32 gdd_read_buf(const T_GDD_BUF * src_buf, U8 * dest_buf, U16 dest_size)
{
  int idx_seg;
  int remaining;

  /* Check that we have more than one segment and that the first one
     is the PID segment which. */

  TRACE_ASSERT(src_buf->c_segment > 1);
  TRACE_ASSERT(src_buf->ptr_gdd_segment[0].c_data EQ GDD_DIO_PID_SEG_SIZE);
  if( src_buf->c_segment < 2 ||
      src_buf->ptr_gdd_segment[0].c_data NEQ GDD_DIO_PID_SEG_SIZE )
  {
    return -1;
  }
  
  remaining = src_buf->length - GDD_DIO_PID_SEG_SIZE;
  if(remaining > dest_size)
  {
    remaining = dest_size;
  } 

  for(idx_seg=1; idx_seg<src_buf->c_segment; ++idx_seg)
  {
    T_GDD_SEGMENT * seg = &(src_buf->ptr_gdd_segment[idx_seg]);
    int bytes_to_copy = remaining < seg->c_data ? remaining : seg->c_data;
    
    memcpy(dest_buf + dest_size - remaining, seg->ptr_data, bytes_to_copy);
    remaining -= bytes_to_copy;
    if(remaining EQ 0)
      break;
  }

  return remaining;
}