view src/cs/services/mks/mks_functions.c @ 205:81f5c4ca1fb3

mmiDialogs.c: make dialog_info() static The function in question was first declared as static, then defined as non-static, which should be considered invalid C. Given that this function is not referenced from any other modules and appears to have been intended as static, make it so.
author Mychaela Falconia <falcon@freecalypso.org>
date Tue, 06 Apr 2021 01:28:52 +0000
parents 4e78acac3d88
children
line wrap: on
line source

/**
 * @file   mks_functions.c
 *
 * Implementation of MKS functions.
 *
 * @author   Laurent Sollier (l-sollier@ti.com)
 * @version 0.1
 */

/*
 * History:
 *
 *   Date          Author       Modification
 *  ----------------------------------------
 *  11/16/2001     L Sollier    Create
 *
 *
 * (C) Copyright 2001 by Texas Instruments Incorporated, All Rights Reserved
 */

#include "mks/mks_i.h"
#include "mks/mks_api.h"
#include "mks/mks_env.h"

#include "kpd/kpd_api.h"

#include "rvm/rvm_use_id_list.h"
#include "rv/rv_general.h"

#include <string.h>


/* This value is set in the T_KEY_SEQUENCE_INFOS structure when post-sequence is on going */
#define POST_SEQUENCE_COMPLETED 0x10

/** This structure defines  */
typedef struct {  char name[KPD_MAX_CHAR_NAME+1];
                  T_KPD_VIRTUAL_KEY_ID sequence_key[MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE];
                  UINT8 nb_key_of_sequence;
                  UINT8 completion_type;
                  UINT8 nb_key_for_post_sequence;
                  UINT8 nb_key_sent_for_post_sequence;
                  T_RV_RETURN return_path;
               } T_KEY_SEQUENCE_INFOS;




/** Definition of the different magic key sequence.
 * Note that the magic key sequence is defined by a KPD_KEY_NULL key Id.
 */
static T_KEY_SEQUENCE_INFOS* key_sequence_table[MKS_NB_MAX_OF_KEY_SEQUENCE] = {0};

/* Subscriber Id for keypad driver */
static T_KPD_SUBSCRIBER subscriber_id;

/* Number of key sequence registered */
static UINT8 nb_key_sequence = 0;

/* Key pressed history */
static T_KPD_VIRTUAL_KEY_ID key_history[MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE];


/** External declaration */
extern T_MKS_ENV_CTRL_BLK* mks_env_ctrl_blk;

/**
 * @name Functions implementation
 *
 */
/*@{*/


/**
 * function: mks_add_key_sequence_i
 */
T_RV_RET mks_add_key_sequence_i(T_MKS_INFOS_KEY_SEQUENCE_MSG* infos_key_sequence_p)
{
   UINT8 i;
   T_RVF_MB_STATUS mb_status;
   T_RV_RET ret = RV_OK;
   T_MKS_INFOS_KEY_SEQUENCE* infos_p = &(infos_key_sequence_p->key_sequence_infos);

   if (nb_key_sequence < MKS_NB_MAX_OF_KEY_SEQUENCE)
   {
      /* Reserve memory for message */
      mb_status = rvf_get_buf (mks_env_ctrl_blk->prim_id, sizeof(T_KEY_SEQUENCE_INFOS), (void **) &key_sequence_table[nb_key_sequence]);   

      if (mb_status != RVF_RED) /* Memory allocation success */
      {
         /* Fill the structure */
         for (i = 0; i < infos_p->nb_key_of_sequence; i++)
            key_sequence_table[nb_key_sequence]->sequence_key[i] = infos_p->key_id[i];

         key_sequence_table[nb_key_sequence]->nb_key_of_sequence = infos_p->nb_key_of_sequence;
         key_sequence_table[nb_key_sequence]->completion_type = infos_p->completion_type;
         key_sequence_table[nb_key_sequence]->return_path = infos_p->return_path;
         key_sequence_table[nb_key_sequence]->nb_key_for_post_sequence = infos_p->nb_key_for_post_sequence;
         infos_p->name[KPD_MAX_CHAR_NAME] = 0;
         strcpy(key_sequence_table[nb_key_sequence]->name, infos_p->name);

         key_sequence_table[nb_key_sequence]->nb_key_sent_for_post_sequence = 0;

         /* Update number of key sequence */
         nb_key_sequence++;

         ret = RV_OK;
      }
      else
      {
         MKS_SEND_TRACE("MKS: Memory allocation error", RV_TRACE_LEVEL_ERROR);
         ret = RV_MEMORY_ERR;
      }
   }
   else
   {
      /* Maximum of magic key sequence registered*/
      ret = RV_INTERNAL_ERR;
   }

   return ret;
}

/**
 * function: mks_remove_key_sequence_i
 *
 */
T_RV_RET mks_remove_key_sequence_i(T_MKS_REMOVE_KEY_SEQUENCE_MSG* remove_key_sequence_p)
{
   UINT8 i;

   for (i = 0; i < nb_key_sequence; i++)
   {
      /* Compare name of the key sequence */
      if ( !(strcmp(key_sequence_table[i]->name, remove_key_sequence_p->name)) )
      {
         /* Free memory used for the key sequence */
         rvf_free_buf(key_sequence_table[i]);
         nb_key_sequence--;

         /* Sort out the table of key sequence */
         key_sequence_table[i] = key_sequence_table[nb_key_sequence];
         key_sequence_table[nb_key_sequence] = 0;
         break;
      }
   }

   return RV_OK;
}

/**
 * function: mks_check_key_sequence
 */
void mks_check_key_sequence(T_KPD_KEY_EVENT_MSG* key_event_p)
{
   UINT8 i,j, nb_key_of_sequence;
   BOOL key_sequence_completed = TRUE;

   /* Stop timer */
   rvf_stop_timer(RVF_TIMER_0);

   /* Update key pressed history */
   for (i = 0; i < MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE-1; i++)
      key_history[i] = key_history[i+1];

   key_history[MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE-1] = key_event_p->key_info.virtual_key_id;

   /* Check each key sequence */
   for (i = 0; i < nb_key_sequence; i++)
   {
      if (!(key_sequence_table[i]->completion_type & POST_SEQUENCE_COMPLETED))
      {
         /* Verify if magic key sequence is completed */
         nb_key_of_sequence = key_sequence_table[i]->nb_key_of_sequence;
         for (j = 0; j < nb_key_of_sequence; j++)
         {
            if (key_sequence_table[i]->sequence_key[nb_key_of_sequence-j-1] != key_history[MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE-j-1])
            {
               key_sequence_completed = FALSE;
               break;
            }
         }
         if (key_sequence_completed == TRUE)
         {
            if (key_sequence_table[i]->completion_type == MKS_SEQUENCE_COMPLETED)
            {
               /* Process sequence completed */
               mks_send_key_sequence_completed_msg(MKS_SEQUENCE_COMPLETED,
                                                   KPD_KEY_NULL,
                                                   key_sequence_table[i]->return_path,
                                                   key_sequence_table[i]->name);
            }
            else
            {
               /* Store info that post-sequence is on going */
               key_sequence_table[i]->completion_type |= POST_SEQUENCE_COMPLETED;
            }
         }
         else
            key_sequence_completed = TRUE;
      }
      else
      {
         /* Notify that magic key sequence is completed */
         mks_send_key_sequence_completed_msg(MKS_POST_SEQUENCE,
                                             key_event_p->key_info.virtual_key_id,
                                             key_sequence_table[i]->return_path,
                                             key_sequence_table[i]->name);

         key_sequence_table[i]->nb_key_sent_for_post_sequence++;

         if (key_sequence_table[i]->nb_key_sent_for_post_sequence == key_sequence_table[i]->nb_key_for_post_sequence)
         {
            key_sequence_table[i]->nb_key_sent_for_post_sequence = 0;
            key_sequence_table[i]->completion_type &= ~POST_SEQUENCE_COMPLETED;
         }
      }
   }

   rvf_start_timer(RVF_TIMER_0, RVF_MS_TO_TICKS(MKS_TIME_RESET_KEY_SEQUENCE), FALSE);
}



/**
 * function: mks_send_key_sequence_completed_msg
 */
void mks_send_key_sequence_completed_msg(UINT8 completion_level,
                                         T_KPD_VIRTUAL_KEY_ID key_id,
                                         T_RV_RETURN return_path,
                                         char* name)
{
   T_MKS_SEQUENCE_COMPLETED_MSG* msg_sequence_completed = 0;
   T_RVF_MB_STATUS mb_status;

   /* Reserve memory for message */
   mb_status = rvf_get_buf (mks_env_ctrl_blk->prim_id, sizeof(T_MKS_SEQUENCE_COMPLETED_MSG), (void **) &msg_sequence_completed);   

   if (mb_status != RVF_RED) /* Memory allocation success */
   {
      /* Fill the message */
      msg_sequence_completed->hdr.msg_id = MKS_SEQUENCE_COMPLETED_MSG;
      strcpy(msg_sequence_completed->name, name);
      msg_sequence_completed->completion_type = completion_level;
      msg_sequence_completed->key_pressed = key_id;

      /* Send message to the client */
      if (return_path.callback_func != 0)
      {
         return_path.callback_func((void*) msg_sequence_completed);
         rvf_free_buf(msg_sequence_completed);
      }
      else
      {
         rvf_send_msg(return_path.addr_id, msg_sequence_completed);
      }
   }
   else
   {
      MKS_SEND_TRACE("MKS: Memory allocation error", RV_TRACE_LEVEL_ERROR);
   }
}


/**
 * function: mks_reset_sequence
 */
void mks_reset_sequence(void)
{
   UINT8 i;

   for (i = 0; i < MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE; i++)
      key_history[i] = KPD_KEY_NULL;
}


/**
 * function: mks_initialize_swe
 */
void mks_initialize_swe(void)
{
   T_RV_RET ret;
   T_KPD_VIRTUAL_KEY_TABLE notified_keys;
   T_RV_RETURN return_path;
   UINT8 i;

   /* Initialize key pressed history structure */
   for (i = 0; i < MKS_NB_MAX_OF_KEY_IN_KEY_SEQUENCE; i++)
      key_history[i] = KPD_KEY_NULL;

   /* Subscription to the keypad */
   return_path.addr_id = mks_env_ctrl_blk->addr_id;
   return_path.callback_func = 0;
   notified_keys.nb_notified_keys = KPD_NB_PHYSICAL_KEYS;
   ret = kpd_subscribe (&subscriber_id, KPD_DEFAULT_MODE, &notified_keys, return_path);

   if (ret != RV_OK)
   {
      MKS_SEND_TRACE("MKS: Unable to subscribe to the keypad", RV_TRACE_LEVEL_DEBUG_HIGH);
   }
}


/**
 * function: mks_stop_swe
 */
void mks_stop_swe(void)
{
   T_RV_RET ret;

   /* Unsubscribe to the keypad */
   ret = kpd_unsubscribe(&subscriber_id);

   if (ret != RV_OK)
   {
      MKS_SEND_TRACE("MKS: Unsubscription error", RV_TRACE_LEVEL_DEBUG_HIGH);
   }
}


/*@}*/