path: root/kaffeine/src/input/dvb/lib/libdvben50221/en50221_app_ca.c

/*
    en50221 encoder An implementation for libdvb
    an implementation for the en50221 transport layer

    Copyright (C) 2004, 2005 Manu Abraham (manu@kromtek.com)
    Copyright (C) 2005 Julian Scheel (julian at jusst dot de)
    Copyright (C) 2006 Andrew de Quincey (adq_dvb@lidskialf.net)

    This library is free software; you can redistribute it and/or modify
    it under the terms of the GNU Lesser General Public License as
    published by the Free Software Foundation; either version 2.1 of
    the License, or (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU Lesser General Public License for more details.

    You should have received a copy of the GNU Lesser General Public
    License along with this library; if not, write to the Free Software
    Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301 USA
*/

#include <string.h>
#include <libdvbmisc/dvbmisc.h>
#include <pthread.h>
#include <libucsi/mpeg/descriptor.h>
#include "en50221_app_ca.h"
#include "asn_1.h"

// tags supported by this resource
#define TAG_CA_INFO_ENQUIRY     0x9f8030
#define TAG_CA_INFO             0x9f8031
#define TAG_CA_PMT              0x9f8032
#define TAG_CA_PMT_REPLY        0x9f8033

struct en50221_app_ca_private {
    struct en50221_app_send_functions *funcs;

    en50221_app_ca_info_callback ca_info_callback;
    void *ca_info_callback_arg;

    en50221_app_ca_pmt_reply_callback ca_pmt_reply_callback;
    void *ca_pmt_reply_callback_arg;

    pthread_mutex_t lock;
};

struct ca_pmt_descriptor {
    uint8_t *descriptor;
    uint16_t length;

    struct ca_pmt_descriptor *next;
};

struct ca_pmt_stream {
    uint8_t stream_type;
    uint16_t pid;
    struct ca_pmt_descriptor *descriptors;
    uint32_t descriptors_length;
    uint32_t descriptors_count;

    struct ca_pmt_stream *next;
};

static int en50221_ca_extract_pmt_descriptors(struct mpeg_pmt_section *pmt, struct ca_pmt_descriptor **outdescriptors);
static int en50221_ca_extract_streams(struct mpeg_pmt_section *pmt, struct ca_pmt_stream **outstreams);
static void en50221_ca_try_move_pmt_descriptors(struct ca_pmt_descriptor **pmt_descriptors,
                                                struct ca_pmt_stream **pmt_streams);
static uint32_t en50221_ca_calculate_length(struct ca_pmt_descriptor *pmt_descriptors,
                                            uint32_t *pmt_descriptors_length,
                                            struct ca_pmt_stream *pmt_streams);
static int en50221_app_ca_parse_info(struct en50221_app_ca_private *private,
                                      uint8_t slot_id, uint16_t session_number,
                                      uint8_t *data, uint32_t data_length);
static int en50221_app_ca_parse_reply(struct en50221_app_ca_private *private,
                                       uint8_t slot_id, uint16_t session_number,
                                       uint8_t *data, uint32_t data_length);



en50221_app_ca en50221_app_ca_create(struct en50221_app_send_functions *funcs)
{
    struct en50221_app_ca_private *private = NULL;

    // create structure and set it up
    private = malloc(sizeof(struct en50221_app_ca_private));
    if (private == NULL) {
        return NULL;
    }
    private->funcs = funcs;
    private->ca_info_callback = NULL;
    private->ca_pmt_reply_callback = NULL;

    pthread_mutex_init(&private->lock, NULL);

    // done
    return private;
}

void en50221_app_ca_destroy(en50221_app_ca ca)
{
    struct en50221_app_ca_private *private = (struct en50221_app_ca_private *) ca;

    pthread_mutex_destroy(&private->lock);
    free(private);
}

void en50221_app_ca_register_info_callback(en50221_app_ca ca,
                                           en50221_app_ca_info_callback callback, void *arg)
{
    struct en50221_app_ca_private *private = (struct en50221_app_ca_private *) ca;

    pthread_mutex_lock(&private->lock);
    private->ca_info_callback = callback;
    private->ca_info_callback_arg = arg;
    pthread_mutex_unlock(&private->lock);
}

void en50221_app_ca_register_pmt_reply_callback(en50221_app_ca ca,
                                                en50221_app_ca_pmt_reply_callback callback, void *arg)
{
    struct en50221_app_ca_private *private = (struct en50221_app_ca_private *) ca;

    pthread_mutex_lock(&private->lock);
    private->ca_pmt_reply_callback = callback;
    private->ca_pmt_reply_callback_arg = arg;
    pthread_mutex_unlock(&private->lock);
}

int en50221_app_ca_info_enq(en50221_app_ca ca,
                            uint16_t session_number)
{
    struct en50221_app_ca_private *private = (struct en50221_app_ca_private *) ca;
    uint8_t data[4];

    data[0] = (TAG_CA_INFO_ENQUIRY >> 16) & 0xFF;
    data[1] = (TAG_CA_INFO_ENQUIRY >> 8) & 0xFF;
    data[2] = TAG_CA_INFO_ENQUIRY & 0xFF;
    data[3] = 0;
    return private->funcs->send_data(private->funcs->arg, session_number, data, 4);
}

int en50221_app_ca_pmt(en50221_app_ca ca,
                       uint16_t session_number,
                       uint8_t *ca_pmt,
                       uint32_t ca_pmt_length)
{
    struct en50221_app_ca_private *private = (struct en50221_app_ca_private *) ca;
    uint8_t buf[10];

    // set up the tag
    buf[0] = (TAG_CA_PMT >> 16) & 0xFF;
    buf[1] = (TAG_CA_PMT >> 8) & 0xFF;
    buf[2] = TAG_CA_PMT & 0xFF;

    // encode the length field
    int length_field_len;
    if ((length_field_len = asn_1_encode(ca_pmt_length, buf+3, 3)) < 0) {
        return -1;
    }

    // build the iovecs
    struct iovec iov[2];
    iov[0].iov_base = buf;
    iov[0].iov_len = 3+length_field_len;
    iov[1].iov_base = ca_pmt;
    iov[1].iov_len = ca_pmt_length;

    // create the data and send it
    return private->funcs->send_datav(private->funcs->arg, session_number, iov, 2);
}

int en50221_app_ca_message(en50221_app_ca ca,
                           uint8_t slot_id,
                           uint16_t session_number,
                           uint32_t resource_id,
                           uint8_t *data, uint32_t data_length)
{
    struct en50221_app_ca_private *private = (struct en50221_app_ca_private *) ca;
    (void)resource_id;

    // get the tag
    if (data_length < 3) {
        print(LOG_LEVEL, ERROR, 1, "Received short data\n");
        return -1;
    }
    uint32_t tag = (data[0] << 16) | (data[1] << 8) | data[2];

    switch(tag)
    {
        case TAG_CA_INFO:
            return en50221_app_ca_parse_info(private, slot_id, session_number, data+3, data_length-3);
        case TAG_CA_PMT_REPLY:
            return en50221_app_ca_parse_reply(private, slot_id, session_number, data+3, data_length-3);
    }

    print(LOG_LEVEL, ERROR, 1, "Received unexpected tag %x\n", tag);
    return -1;
}

int en50221_ca_format_pmt(struct mpeg_pmt_section *pmt, uint8_t *data, uint32_t data_length,
                          int move_ca_descriptors,
                          uint8_t ca_pmt_list_management, uint8_t ca_pmt_cmd_id)
{
    struct ca_pmt_descriptor *pmt_descriptors = NULL;
    uint32_t pmt_descriptors_length = 0;
    struct ca_pmt_stream *pmt_streams = NULL;
    uint32_t total_required_length = 0;
    struct ca_pmt_descriptor *cur_d;
    struct ca_pmt_stream *cur_s;
    int result = -1;

    // extract the descriptors and streams
    if (en50221_ca_extract_pmt_descriptors(pmt, &pmt_descriptors))
        goto cleanup;
    if (en50221_ca_extract_streams(pmt, &pmt_streams))
        goto cleanup;

    // try and merge them if we have no PMT descriptors
    if ((pmt_descriptors == NULL) && move_ca_descriptors) {
        en50221_ca_try_move_pmt_descriptors(&pmt_descriptors, &pmt_streams);
    }

    // calculate the length of all descriptors/streams and the total length required
    total_required_length = en50221_ca_calculate_length(pmt_descriptors, &pmt_descriptors_length, pmt_streams);

    // ensure we were supplied with enough data
    if (total_required_length > data_length) {
        goto cleanup;
    }

    // format the start of the PMT
    uint32_t data_pos = 0;
    data[data_pos++] = ca_pmt_list_management;
    data[data_pos++] = mpeg_pmt_section_program_number(pmt) >> 8;
    data[data_pos++] = mpeg_pmt_section_program_number(pmt);
    data[data_pos++] = (pmt->head.version_number << 1) | pmt->head.current_next_indicator;
    data[data_pos++] = (pmt_descriptors_length >> 8) & 0x0f;
    data[data_pos++] = pmt_descriptors_length;

    // append the PMT descriptors
    if (pmt_descriptors_length) {
        data[data_pos++] = ca_pmt_cmd_id;
        struct ca_pmt_descriptor *cur_d = pmt_descriptors;
        while(cur_d) {
            memcpy(data+data_pos, cur_d->descriptor, cur_d->length);
            data_pos += cur_d->length;
            cur_d = cur_d->next;
        }
    }

    // now, append the streams
    cur_s = pmt_streams;
    while(cur_s) {
        data[data_pos++] = cur_s->stream_type;
        data[data_pos++] = (cur_s->pid >> 8) & 0x1f;
        data[data_pos++] = cur_s->pid;
        data[data_pos++] = (cur_s->descriptors_length >> 8) & 0x0f;
        data[data_pos++] = cur_s->descriptors_length;

        // append the stream descriptors
        if (cur_s->descriptors_length) {
            data[data_pos++] = ca_pmt_cmd_id;
            struct ca_pmt_descriptor *cur_d = cur_s->descriptors;
            while(cur_d) {
                memcpy(data+data_pos, cur_d->descriptor, cur_d->length);
                data_pos += cur_d->length;
                cur_d = cur_d->next;
            }
        }
        cur_s = cur_s->next;
    }
    result = data_pos;


cleanup:
    // free the PMT descriptors
    cur_d = pmt_descriptors;
    while(cur_d) {
        struct ca_pmt_descriptor *next = cur_d->next;
        free(cur_d);
        cur_d = next;
    }

    // free the streams
    cur_s = pmt_streams;
    while(cur_s) {
        struct ca_pmt_stream *next_s = cur_s->next;

        // free the stream descriptors
        cur_d = cur_s->descriptors;
        while(cur_d) {
            struct ca_pmt_descriptor *next_d = cur_d->next;
            free(cur_d);
            cur_d = next_d;
        }

        free(cur_s);
        cur_s = next_s;
    }
    return result;
}







static int en50221_ca_extract_pmt_descriptors(struct mpeg_pmt_section *pmt, struct ca_pmt_descriptor **outdescriptors)
{
    struct ca_pmt_descriptor *descriptors = NULL;
    struct ca_pmt_descriptor *descriptors_tail = NULL;
    struct ca_pmt_descriptor *cur_d;

    struct descriptor *cur_descriptor;
    mpeg_pmt_section_descriptors_for_each(pmt, cur_descriptor) {
        if (cur_descriptor->tag == dtag_mpeg_ca) {
            // create a new structure for this one
            struct ca_pmt_descriptor *new_d = malloc(sizeof(struct ca_pmt_descriptor));
            if (new_d == NULL) {
                goto error_exit;
            }
            new_d->descriptor = (uint8_t*) cur_descriptor;
            new_d->length = cur_descriptor->len+2;
            new_d->next = NULL;

            // append it to the list
            if (descriptors == NULL) {
                descriptors = new_d;
            } else {
                descriptors_tail->next = new_d;
            }
            descriptors_tail = new_d;
        }
    }
    *outdescriptors = descriptors;
    return 0;

error_exit:
    cur_d = descriptors;
    while(cur_d) {
        struct ca_pmt_descriptor *next = cur_d->next;
        free(cur_d);
        cur_d = next;
    }
    return -1;
}

static int en50221_ca_extract_streams(struct mpeg_pmt_section *pmt, struct ca_pmt_stream **outstreams)
{
    struct ca_pmt_stream *streams = NULL;
    struct ca_pmt_stream *streams_tail = NULL;
    struct mpeg_pmt_stream *cur_stream;
    struct descriptor *cur_descriptor;
    struct ca_pmt_stream *cur_s;

    mpeg_pmt_section_streams_for_each(pmt, cur_stream) {
        struct ca_pmt_descriptor *descriptors_tail = NULL;

        // create a new structure
        struct ca_pmt_stream *new_s = malloc(sizeof(struct ca_pmt_stream));
        if (new_s == NULL) {
            goto exit_cleanup;
        }
        new_s->stream_type = cur_stream->stream_type;
        new_s->pid = cur_stream->pid;
        new_s->descriptors = NULL;
        new_s->next = NULL;
        new_s->descriptors_count = 0;

        // append it to the list
        if (streams == NULL) {
            streams = new_s;
        } else {
            streams_tail->next = new_s;
        }
        streams_tail = new_s;

        // now process the descriptors
        mpeg_pmt_stream_descriptors_for_each(cur_stream, cur_descriptor) {
            if (cur_descriptor->tag == dtag_mpeg_ca) {
               // create a new structure
                struct ca_pmt_descriptor *new_d = malloc(sizeof(struct ca_pmt_descriptor));
                if (new_d == NULL) {
                    goto exit_cleanup;
                }
                new_d->descriptor = (uint8_t*) cur_descriptor;
                new_d->length = cur_descriptor->len+2;
                new_d->next = NULL;

                // append it to the list
                if (new_s->descriptors == NULL) {
                    new_s->descriptors = new_d;
                } else {
                    descriptors_tail->next = new_d;
                }
                descriptors_tail = new_d;
                new_s->descriptors_count++;
            }
        }
    }
    *outstreams = streams;
    return 0;

exit_cleanup:
    // free the streams
    cur_s = streams;
    while(cur_s) {
        struct ca_pmt_stream *next_s = cur_s->next;

        // free the stream descriptors
        struct ca_pmt_descriptor *cur_d = cur_s->descriptors;
        while(cur_d) {
            struct ca_pmt_descriptor *next_d = cur_d->next;
            free(cur_d);
            cur_d = next_d;
        }

        free(cur_s);
        cur_s = next_s;
    }
    return -1;
}

static void en50221_ca_try_move_pmt_descriptors(struct ca_pmt_descriptor **pmt_descriptors,
        struct ca_pmt_stream **pmt_streams)
{
    // get the first stream
    struct ca_pmt_stream *first_stream = *pmt_streams;
    if (first_stream == NULL)
        return;

    // Check that all the other streams with CA descriptors have exactly the same CA descriptors
    struct ca_pmt_stream *cur_stream = first_stream->next;
    while(cur_stream) {
        // if there are differing numbers of descriptors, exit right now
        if (cur_stream->descriptors_count != first_stream->descriptors_count)
            return;

        // now verify the descriptors match
        struct ca_pmt_descriptor *cur_descriptor = cur_stream->descriptors;
        struct ca_pmt_descriptor *first_cur_descriptor = first_stream->descriptors;
        while(cur_descriptor) {
            // check the descriptors are the same length
            if (cur_descriptor->length != first_cur_descriptor->length)
                return;

            // check their contents match
            if (memcmp(cur_descriptor->descriptor, first_cur_descriptor->descriptor, cur_descriptor->length)) {
                return;
            }

            // move to next
            cur_descriptor = cur_descriptor->next;
            first_cur_descriptor = first_cur_descriptor->next;
        }

        // move to next
        cur_stream = cur_stream->next;
    }

    // if we end up here, all descriptors in all streams matched

    // hook the first stream's descriptors into the PMT's
    *pmt_descriptors = first_stream->descriptors;
    first_stream->descriptors = NULL;
    first_stream->descriptors_count = 0;

    // now free up all the descriptors in the other streams
    cur_stream = first_stream->next;
    while(cur_stream) {
        struct ca_pmt_descriptor *cur_descriptor = cur_stream->descriptors;
        while(cur_descriptor) {
            struct ca_pmt_descriptor *next = cur_descriptor->next;
            free(cur_descriptor);
            cur_descriptor=next;
        }
        cur_stream->descriptors = NULL;
        cur_stream->descriptors_count = 0;
        cur_stream = cur_stream->next;
    }
}

static uint32_t en50221_ca_calculate_length(struct ca_pmt_descriptor *pmt_descriptors,
                                            uint32_t *pmt_descriptors_length,
                                            struct ca_pmt_stream *pmt_streams)
{
    uint32_t total_required_length = 6; // header
    struct ca_pmt_stream *cur_s;

    // calcuate the PMT descriptors length
    (*pmt_descriptors_length) = 0;
    struct ca_pmt_descriptor *cur_d = pmt_descriptors;
    while(cur_d) {
        (*pmt_descriptors_length) += cur_d->length;
        cur_d = cur_d->next;
    }

    // add on 1 byte for the ca_pmt_cmd_id if we have some descriptors.
    if (*pmt_descriptors_length)
        (*pmt_descriptors_length)++;

    // update the total required length
    total_required_length += *pmt_descriptors_length;

    // calculate the length of descriptors in the streams
    cur_s = pmt_streams;
    while(cur_s) {
        // calculate the size of descriptors in this stream
        cur_s->descriptors_length = 0;
        cur_d = cur_s->descriptors;
        while(cur_d) {
            cur_s->descriptors_length += cur_d->length;
            cur_d = cur_d->next;
        }

        // add on 1 byte for the ca_pmt_cmd_id if we have some descriptors.
        if (cur_s->descriptors_length)
            cur_s->descriptors_length++;

        // update the total required length;
        total_required_length += 5 + cur_s->descriptors_length;

        cur_s = cur_s->next;
    }

    // done
    return total_required_length;
}

static int en50221_app_ca_parse_info(struct en50221_app_ca_private *private,
                                      uint8_t slot_id, uint16_t session_number,
                                      uint8_t *data, uint32_t data_length)
{
    // first of all, decode the length field
    uint16_t asn_data_length;
    int length_field_len;
    if ((length_field_len = asn_1_decode(&asn_data_length, data, data_length)) < 0) {
        print(LOG_LEVEL, ERROR, 1, "ASN.1 decode error\n");
        return -1;
    }

    // check it
    if (asn_data_length > (data_length-length_field_len)) {
        print(LOG_LEVEL, ERROR, 1, "Received short data\n");
        return -1;
    }
    data+=length_field_len;

    // parse
    uint32_t ca_id_count = asn_data_length / 2;

    // byteswap the IDs
    uint16_t *ids = (uint16_t*) data;
    uint32_t i;
    for(i=0; i<ca_id_count; i++) {
        bswap16(data);
        data+=2;
    }

    // tell the app
    pthread_mutex_lock(&private->lock);
    en50221_app_ca_info_callback cb = private->ca_info_callback;
    void *cb_arg = private->ca_info_callback_arg;
    pthread_mutex_unlock(&private->lock);
    if (cb) {
        return cb(cb_arg, slot_id, session_number, ca_id_count, ids);
    }
    return 0;
}

static int en50221_app_ca_parse_reply(struct en50221_app_ca_private *private,
                                       uint8_t slot_id, uint16_t session_number,
                                       uint8_t *data, uint32_t data_length)
{
    // first of all, decode the length field
    uint16_t asn_data_length;
    int length_field_len;
    if ((length_field_len = asn_1_decode(&asn_data_length, data, data_length)) < 0) {
        print(LOG_LEVEL, ERROR, 1, "ASN.1 decode error\n");
        return -1;
    }

    // check it
    if (asn_data_length < 4) {
        print(LOG_LEVEL, ERROR, 1, "Received short data\n");
        return -1;
    }
    if (asn_data_length > (data_length-length_field_len)) {
        print(LOG_LEVEL, ERROR, 1, "Received short data\n");
        return -1;
    }
    data += length_field_len;
    data_length -= length_field_len;

    // process the reply table to fix endian issues
    uint32_t pos = 4;
    bswap16(data);
    while(pos < asn_data_length) {
        bswap16(data+pos);
        pos+= 3;
    }

    // tell the app
    pthread_mutex_lock(&private->lock);
    en50221_app_ca_pmt_reply_callback cb = private->ca_pmt_reply_callback;
    void *cb_arg = private->ca_pmt_reply_callback_arg;
    pthread_mutex_unlock(&private->lock);
    if (cb) {
        return cb(cb_arg, slot_id, session_number, (struct en50221_app_pmt_reply*) data, asn_data_length);
    }
    return 0;
}