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#include <kernel/func.h>

#include <kernel/kern.h>

#include <stdlib.h>

#include <stdio.h>

#include "string.h"

#include "drivers/udpip.h"

#include "tftp.h"

#include "endn.h"

/*  */

#include "sem/sem/sem.h"

char local_ip_addr[20];

char host_ip_addr[20];

/* The value is incremented when assigning a new port address to a new

 * connection.

 */

int port_counter;

/* The fixed IP/port (=69) to submit the connection requesting */

UDP_ADDR connection_request;

TFTP_MODEL model[MAX_CONCURRENT_STREAM];

sem_t *model_sem[MAX_CONCURRENT_STREAM];

TFTP_BUFFER buffer[MAX_CONCURRENT_STREAM];

//QUEUE queue[MAX_CONCURRENT_STREAM];

sem_t *buffer_sem[MAX_CONCURRENT_STREAM];

WORD tftp_get_data(TFTP_PACKET *pkt, BYTE *data, int n) {

        memcpy(data, pkt->u.data.data, n);

        return(pkt->u.data.block);

}

int tftp_get_ack_block(TFTP_PACKET *pkt) {

        return(pkt->u.ack.block);

}

int tftp_get_error(TFTP_PACKET *pkt, char *errmsg) {

        strcpy(errmsg, pkt->u.err.errmsg);

        return(pkt->u.err.errcode);

}

/* Returns the packet opcode.

 */

int tftp_get_opcode(TFTP_PACKET *pkt) {

  WORD tmp;

  tmp = pkt->opcode;

  SWAP_SHORT(tmp);    /* Swap endian!! */

  return(tmp);

}

int tftp_fill_request(TFTP_PACKET *pkt, WORD opcode, const BYTE *filename, const BYTE *mode) {

  int i, j;

  pkt->opcode = opcode;                         /* Put the opcode in the right struct field */

  SWAP_SHORT(pkt->opcode);    /* Swap endian!! */

        /* Reset the filename field */

  memset(pkt->u.request.filename, 0, sizeof(pkt->u.request.filename));

        /* Concats the containing filename and mode NULL terminatd strings in the filename field */

  for (i = 0; i < strlen(filename); i++)

     pkt->u.request.filename[i] = filename[i];

  pkt->u.request.filename[i] = '\0';

  for (j = 0, i = i + 1; j < strlen(mode); i++, j++)

     pkt->u.request.filename[i] = mode[j];

  pkt->u.request.filename[i] = '\0';

  return(0);

}

int tftp_fill_data(TFTP_PACKET *pkt, WORD nblock, BYTE *rawdata, WORD datasize) {

        if (datasize > TFTP_DATA_SIZE) { return(1); }   /* Overflow checking */

        pkt->opcode = TFTP_DATA;        /* Put the DATA opcode in the opcode field */

        SWAP_SHORT(pkt->opcode);  /* Swap endian!! */

  pkt->u.data.block = nblock;

  SWAP_SHORT(pkt->u.data.block); /* Swap endian!! */

  memcpy(pkt->u.data.data, rawdata, datasize);  /* ??? Maybe some data manipulation required!!! */

  return(0);

}

int tftp_fill_ack(TFTP_PACKET *pkt, WORD nblock) {

        pkt->opcode = TFTP_ACK;         /* Put the ACK opcode in the opcode field */

        SWAP_SHORT(pkt->opcode);  /* Swap endian!! */

  pkt->u.ack.block = nblock;

        return(0);

}

void tftp_reset_handle(int h) {

        model[h].status = TFTP_NOT_CONNECTED;

  model[h].errcode = TFTP_NO_ERROR;

  model[h].handle = -1;

  model[h].sender_pid = -1;

  model[h].receiver_pid = -1;

        model[h].nblock = 0;

        model[h].waiting_ack = 0;

        model[h].timestamp = 0;

        model[h].timeout = TFTP_DEFAULT_TIMEOUT;

        model[h].ntimeout = TFTP_DEFAULT_TIMEOUT_NUMBER;

        buffer[h].data = NULL;

        buffer[h].size = 0;

        buffer[h].nbytes = 0;

        model_sem[h] = NULL;

        buffer_sem[h] = NULL;

}

int tftp_init() {

  int i;

  for (i = 0; i < MAX_CONCURRENT_STREAM; i++) {

    tftp_reset_handle(i);

  }

  port_counter = 0;

  return(0);

}

int tftp_net_start(char *local_ip, char *host_ip, int init_net) {

  struct net_model m = net_base;

  int netval;

        /* Save IPs locally */

  strcpy(local_ip_addr, local_ip);

  strcpy(host_ip_addr, host_ip);

  netval = 0;

  if (init_net) {

    net_setmode(m, TXTASK);                     /* We want a task for TX mutual exclusion */

    net_setudpip(m, local_ip,"255.255.255.255");        /* We use UDP/IP stack */

    /* OK: let's start the NetLib! */

    netval = net_init(&m);

  }

  return(netval);

}

int tftp_setup_timeout(int h, int sec) {

  if (model[h].handle != TFTP_NOT_CONNECTED) return(-1);

  model[h].timeout = sec * 1000000;

  return(0);

}

int tftp_set_timeout_numbers(int h, int n) {

  if (model[h].handle != TFTP_NOT_CONNECTED) return(-1);

  model[h].ntimeout = n;

  return(0);

}

int tftp_open(char *fname) {

  int i;

  /* Finds the first free connection slot */

  for (i = 0; i < MAX_CONCURRENT_STREAM; i++)

     if (model[i].status == TFTP_NOT_CONNECTED) break;

  if (i >= MAX_CONCURRENT_STREAM) return(-1);   /* No connection slots available */

  model[i].handle = i;                                                  /* Handle = index in the struct array */

  strcpy(model[i].filename, fname);     /* Save filename into struct */

        model[i].status = TFTP_OPEN;              /* Connection opened */

  sem_init(model_sem[i], 0, 1);

  return(i);

}

TASK upload_sender(int id) {

  TFTP_PACKET pkt;

  char data[TFTP_DATA_SIZE];

  int mystatus;

  int i, n;

  i = 0;

  while(1) {

    sem_wait(model_sem[id]);

    if (model[id].waiting_ack) {   /* and status != error ??? */

      if (sys_gettime(NULL) - model[id].timestamp >= model[id].timeout) {   /* ??? check it!!! */

        if (!model[id].ntimeout) {

          model[id].status = TFTP_ERR;

          model[id].errcode = TFTP_ERR_TIMEOUT;

          sem_post(model_sem[id]);

        } else {

          model[id].ntimeout--;

          model[id].timestamp = sys_gettime(NULL);

          sem_post(model_sem[id]);

                                        udp_sendto(model[id].socket, (char*)(&model[id].last_sent), sizeof(TFTP_PACKET), &model[id].host);

        }

      } else {

        sem_post(model_sem[id]);

      }

    } else {

      mystatus = model[id].status;

      sem_post(model_sem[id]);

      switch (mystatus) {

        case TFTP_ACTIVE : {

          /* Doesn't use mutex 'cause uses "static" model fields */

          tftp_fill_request(&pkt, TFTP_WRITE_REQUEST, model[id].filename, TFTP_OCTET_MODE);

          udp_sendto(model[id].socket, (char*)(&pkt), sizeof(TFTP_PACKET), &connection_request);

                                memcpy(&model[id].last_sent, &pkt, sizeof(TFTP_PACKET));                /* Save the last sent packet for retransmission */

          sem_wait(model_sem[id]);

          if (model[id].status != TFTP_ERR)

            model[id].status = TFTP_CONNECTION_REQUESTING;

          else {

            sem_post(model_sem[id]);

            break;

          }

          model[id].waiting_ack = 1;

          model[id].timestamp = sys_gettime(NULL);

          sem_post(model_sem[id]);

          break;

        }

        case TFTP_CONNECTION_REQUESTING : {

        }

        case TFTP_STREAMING : {

          if (tftp_usedbuffer(id) >= TFTP_DATA_SIZE) {

            n = tftp_get(id, data, TFTP_DATA_SIZE);

            tftp_fill_data(&pkt, model[id].nblock, data, n);

            udp_sendto(model[id].socket, (char*)(&pkt), sizeof(TFTP_PACKET), &model[id].host);

                                memcpy(&model[id].last_sent, &pkt, sizeof(TFTP_PACKET));                /* Save the last sent packet for retransmission */

            sem_wait(model_sem[id]);

            model[id].waiting_ack = 1;

            model[id].timestamp = sys_gettime(NULL);

            sem_post(model_sem[id]);

          }

          break;

        }

        case TFTP_FLUSHING : {

                n = tftp_usedbuffer(id);

          if (n >= TFTP_DATA_SIZE) {

            /* Get data for a full data packet */

            n = tftp_get(id, data, TFTP_DATA_SIZE);

            tftp_fill_data(&pkt, model[id].nblock, data, n);

            udp_sendto(model[id].socket, (char*)(&pkt), sizeof(TFTP_PACKET), &model[id].host);

                                memcpy(&model[id].last_sent, &pkt, sizeof(TFTP_PACKET));                /* Save the last sent packet for retransmission */

            sem_wait(model_sem[id]);

            model[id].waiting_ack = 1;

            model[id].timestamp = sys_gettime(NULL);

            sem_post(model_sem[id]);

          } else {

            /* Get remaining data from buffer */

            n = tftp_get(id, data, n);

            tftp_fill_data(&pkt, model[id].nblock, data, n);

            /* Sending 4 extra bytes for opcode and block number!! */

            udp_sendto(model[id].socket, (char*)(&pkt), sizeof(n + 4), &model[id].host);

                                                /* Don't wait for ack!! Maybe will be implemented later... */

            task_kill(model[id].receiver_pid);

            /* ..... */

            task_abort(NULL);

          }

          break;

        }

        case TFTP_ERROR : {

          break;

        }

      }

    }

    task_testcancel();

                task_endcycle();

  }

  return(0);

}

/* This non real-time task reads UDP packets with ACK from the network

 */

TASK upload_receiver(int id) {

  char msg[200];

  int mystatus;

  int n;

  int i;

  WORD opcode;

  TFTP_PACKET pkt;

  UDP_ADDR server;

  i = 0;

  while (1) {

    sem_wait(model_sem[id]);

    mystatus = model[id].status;

    sem_post(model_sem[id]);

    if (mystatus != TFTP_ERR) {

      n = udp_recvfrom(model[id].socket, &pkt, &server);

      opcode = tftp_get_opcode(&pkt);

      if (opcode == TFTP_ERROR) {

        n = tftp_get_error(&pkt, msg);   // re-use n: not too orthodox...

        sem_wait(model_sem[id]);

        model[id].status = TFTP_ERR;

        model[id].errcode = n;

        strcpy(model[id].errmsg, msg);

        sem_post(model_sem[id]);

      } else {

        switch (mystatus) {

          case TFTP_NOT_CONNECTED : {

            // discard the packet... set error??

            break;

          }

          case TFTP_CONNECTION_REQUESTING : {

            sem_wait(model_sem[id]);

            memcpy(&model[id].host, &server, sizeof(model[id].host));

            model[id].waiting_ack = 0;

            model[id].status = TFTP_STREAMING;

            model[id].nblock++;

            sem_post(model_sem[id]);

            break;

          }

          case TFTP_STREAMING : {

            // check the nblock on the arrived packet

            sem_wait(model_sem[id]);

            model[id].waiting_ack = 0;

            model[id].nblock++;

            sem_post(model_sem[id]);

            break;

          }

        }

      }

    }

    i++;

  }

  return(0);

}

int tftp_upload(int i, unsigned long buffsize, sem_t *mtx) {

  SOFT_TASK_MODEL soft_m;

  NRT_TASK_MODEL nrt_m;

  if ((buffer_sem[i] = mtx) == NULL) return(-3);                                                                        /* ??? check assignment!!! */

  if ((buffer[i].size = buffsize) > MAX_BUFFER_SIZE) return(-2);        /* Buffer size too large */

  if ((buffer[i].data = malloc(buffsize)) == NULL) return(-4);          /* Buffer allocation error */

  buffer[i].nbytes = 0;

  /* Create a socket for transmission */

  ip_str2addr(local_ip_addr, &(model[i].local.s_addr));

  model[i].local.s_port = BASE_PORT + port_counter;     /* Different port for each connection */

  port_counter++;

  ip_str2addr(host_ip_addr, &(connection_request.s_addr));

  connection_request.s_port = 69;   /* It is fixed for the connection request */

        model[i].socket = udp_bind(&model[i].local, NULL);

  /* First we set the sender's task properties... */

  soft_task_default_model(soft_m);

  soft_task_def_level(soft_m, 0);

  soft_task_def_arg(soft_m, (void *)(i));

  soft_task_def_group(soft_m, i);

  soft_task_def_periodic(soft_m);

  soft_task_def_wcet(soft_m, TFTP_UPLOAD_SENDER_WCET);

  soft_task_def_period(soft_m, TFTP_UPLOAD_SENDER_PERIOD);

  soft_task_def_met(soft_m, TFTP_UPLOAD_SENDER_MET);

  model[i].sender_pid = task_create("upload_sender", upload_sender, &soft_m, NULL);

  if (model[i].sender_pid == -1) {

     free(buffer[i].data);

     tftp_reset_handle(i);

     return(-5);

  }

  nrt_task_default_model(nrt_m);        /* Start the receiver task... */

  nrt_task_def_arg(nrt_m, (void *)(i));

  if ((model[i].receiver_pid = task_create("upload_receiver", upload_receiver, &nrt_m, NULL)) == NIL) {

     free(buffer[i].data);

     tftp_reset_handle(i);

     return(-6);

  }

        model[i].status = TFTP_ACTIVE;          /* Connection active */

  if (task_activate(model[i].sender_pid) == -1) {

     free(buffer[i].data);

     tftp_reset_handle(i);

     return(-7);

  }

  if (task_activate(model[i].receiver_pid) == -1) {

     free(buffer[i].data);   // Maybe not correct... sys_panic() may be better

     tftp_reset_handle(i);

     return(-8);

  }

  return(0);

}

int tftp_download(int i, unsigned long buffsize, sem_t *mtx) {

  return(0);

}

int tftp_close(int h, int hardness) {

  TFTP_PACKET pkt;

        if (hardness == TFTP_STOP_NOW) {

    task_kill(model[h].sender_pid);

        task_kill(model[h].receiver_pid);

    tftp_fill_data(&pkt, model[h].nblock, NULL, 0);

    udp_sendto(model[h].socket, (char*)(&pkt), 4, &model[h].host);

    tftp_reset_handle(h);

    free(buffer[h].data);

    sem_destroy(buffer_sem[h]);

    sem_destroy(model_sem[h]);

  } else {

        sem_wait(model_sem[h]);

    model[h].status = TFTP_FLUSHING;

        sem_post(model_sem[h]);

  }

        return(0);

}

int tftp_put(int h, BYTE *rawdata, WORD n) {

        sem_wait(buffer_sem[h]);

        /* Buffer overflow checking */

  if (buffer[h].nbytes + n > buffer[h].size) {  /* Maybe ">"??? */

                sem_post(buffer_sem[h]);

                return(1);

  }

        /* Check this carefully!!! */

        memcpy(buffer[h].data + buffer[h].nbytes, rawdata, n);

        buffer[h].nbytes += n;

  sem_post(buffer_sem[h]);

  return(0);

}

int tftp_get(int h, BYTE *rawdata, WORD n) {

//  cprintf("get mutex %d - use %d\n", buffer_sem[h]->mutexlevel, buffer_sem[h]->use);

        sem_wait(buffer_sem[h]);

        if (buffer[h].nbytes < 1) return(0);

  if (buffer[h].nbytes < n) n = buffer[h].nbytes;

        /* Check this carefully!!! */

        memcpy(rawdata, buffer[h].data, n);                                                     /* Export data to calling function */

        memcpy(buffer[h].data, buffer[h].data + n, n);  /* Shift data into buffer */

        buffer[h].nbytes -= n;

  sem_post(buffer_sem[h]);

        return(n);

}

int tftp_getbuffersize(int h) {

        return(buffer[h].size);         /* We on't use the mutex 'cause the size is read-only */

}

int tftp_usedbuffer(int h) {

        int n;

//  cprintf("used mutex %d - use %d\n", buffer_sem[h]->mutexlevel, buffer_sem[h]->use);

        sem_wait(buffer_sem[h]);

        n = buffer[h].nbytes;

        sem_post(buffer_sem[h]);

        return(n);

}

int tftp_freebuffer(int h) {

        int n;

        sem_wait(buffer_sem[h]);

        n = buffer[h].size - buffer[h].nbytes;

        sem_post(buffer_sem[h]);

        return(n);

}

int tftp_status(int h) {

        int n;

        sem_wait(model_sem[h]);

        n = model[h].status;

        sem_post(model_sem[h]);

        return(n);

}

///////////////////////////////////////////////////////////////////////////

int debug_setbuffer(int h, int size) {

  if ((buffer[h].data = malloc(size)) == NULL) return(-1);              /* Buffer allocation error */

  buffer[h].size = size;

  buffer[h].nbytes = 0;

  return(0);

}

void debug_freebuffer(int h) {

  free(buffer[h].data);         /* Buffer allocation error */

  buffer[h].size = 0;

  buffer[h].nbytes = 0;

}