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module-emulator.c
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module-emulator.c
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#define MODULE_LOG_PREFIX "emu"
#include "globals.h"
#ifdef WITH_EMU
#include "module-emulator-osemu.h"
#include "module-emulator-streamserver.h"
#include "module-emulator-biss.h"
#include "module-emulator-irdeto.h"
#include "module-emulator-powervu.h"
#include "oscam-conf-chk.h"
#include "oscam-config.h"
#include "oscam-reader.h"
#include "oscam-string.h"
/*
* Readers in OSCam consist of 2 basic parts.
* The hardware or the device part. This is where physical smart cards are inserted
* and made available to OSCam.
* The software or the emulation part. This is where the actual card reading is done,
* including ecm and emm processing (i.e emulation of the various cryptosystems).
* In the Emu reader, the device part has no meaning, but we have to create it in
* order to be compatible with OSCam's reader structure.
*/
/*
* Create the Emu "emulation" part. This is of type s_cardsystem.
* Similar structures are found in the main sources folder (files reader-xxxxxx.c)
* for every cryptosystem supported by OSCam.
* Here we read keys from our virtual card (aka the SoftCam.Key file) and we inform
* OSCam about them. This is done with the emu_card_info() function. Keep in mind
* that Emu holds all its keys to separate structures for faster access.
* In addition, ECM and EMM requests are processed here, with the emu_do_ecm() and
* emu_do_emm() functions.
*/
#define CS_OK 1
#define CS_ERROR 0
extern char cs_confdir[128];
static int8_t emu_key_data_mutex_init = 0;
pthread_mutex_t emu_key_data_mutex;
static void set_hexserial_to_version(struct s_reader *rdr)
{
char cVersion[32];
uint32_t version = EMU_VERSION;
uint8_t hversion[2];
memset(hversion, 0, 2);
snprintf(cVersion, sizeof(cVersion), "%04d", version);
char_to_bin(hversion, cVersion, 4);
rdr->hexserial[3] = hversion[0];
rdr->hexserial[4] = hversion[1];
}
static void set_prids(struct s_reader *rdr)
{
int32_t i, j;
rdr->nprov = 0;
for (i = 0; (i < rdr->emu_auproviders.nfilts) && (rdr->nprov < CS_MAXPROV); i++)
{
for (j = 0; (j < rdr->emu_auproviders.filts[i].nprids) && (rdr->nprov < CS_MAXPROV); j++)
{
i2b_buf(4, rdr->emu_auproviders.filts[i].prids[j], rdr->prid[i]);
rdr->nprov++;
}
}
}
static void emu_add_entitlement(struct s_reader *rdr, uint16_t caid, uint32_t provid, uint8_t *key, char *keyName, uint32_t keyLength, uint8_t isData)
{
if (!rdr->ll_entitlements)
{
rdr->ll_entitlements = ll_create("ll_entitlements");
}
S_ENTITLEMENT *item;
if (cs_malloc(&item, sizeof(S_ENTITLEMENT)))
{
// fill item
item->caid = caid;
item->provid = provid;
item->id = 0;
item->class = 0;
item->start = 0;
item->end = 2147472000;
item->type = 0;
item->isKey = 1;
memcpy(item->name, keyName, 8);
item->key = key;
item->keyLength = keyLength;
item->isData = isData;
// add item
ll_append(rdr->ll_entitlements, item);
}
}
static void refresh_entitlements(struct s_reader *rdr)
{
uint32_t i;
uint16_t caid;
KeyData *tmpKeyData;
LL_ITER itr;
biss2_rsa_key_t *item;
cs_clear_entitlement(rdr);
for (i = 0; i < StreamKeys.keyCount; i++)
{
emu_add_entitlement(rdr, b2i(2, StreamKeys.EmuKeys[i].key), StreamKeys.EmuKeys[i].provider, StreamKeys.EmuKeys[i].key,
StreamKeys.EmuKeys[i].keyName, StreamKeys.EmuKeys[i].keyLength, 1);
}
for (i = 0; i < ViKeys.keyCount; i++)
{
emu_add_entitlement(rdr, 0x0500, ViKeys.EmuKeys[i].provider, ViKeys.EmuKeys[i].key,
ViKeys.EmuKeys[i].keyName, ViKeys.EmuKeys[i].keyLength, 0);
}
for (i = 0; i < IrdetoKeys.keyCount; i++)
{
tmpKeyData = &IrdetoKeys.EmuKeys[i];
do
{
emu_add_entitlement(rdr, tmpKeyData->provider >> 8, tmpKeyData->provider & 0xFF,
tmpKeyData->key, tmpKeyData->keyName, tmpKeyData->keyLength, 0);
tmpKeyData = tmpKeyData->nextKey;
}
while (tmpKeyData != NULL);
}
for (i = 0; i < CwKeys.keyCount; i++)
{
emu_add_entitlement(rdr, CwKeys.EmuKeys[i].provider >> 8, CwKeys.EmuKeys[i].provider & 0xFF,
CwKeys.EmuKeys[i].key, CwKeys.EmuKeys[i].keyName, CwKeys.EmuKeys[i].keyLength, 0);
}
for (i = 0; i < PowervuKeys.keyCount; i++)
{
emu_add_entitlement(rdr, 0x0E00, PowervuKeys.EmuKeys[i].provider, PowervuKeys.EmuKeys[i].key,
PowervuKeys.EmuKeys[i].keyName, PowervuKeys.EmuKeys[i].keyLength, 0);
}
for (i = 0; i < TandbergKeys.keyCount; i++)
{
emu_add_entitlement(rdr, 0x1010, TandbergKeys.EmuKeys[i].provider, TandbergKeys.EmuKeys[i].key,
TandbergKeys.EmuKeys[i].keyName, TandbergKeys.EmuKeys[i].keyLength, 0);
}
for (i = 0; i < NagraKeys.keyCount; i++)
{
emu_add_entitlement(rdr, 0x1801, NagraKeys.EmuKeys[i].provider, NagraKeys.EmuKeys[i].key,
NagraKeys.EmuKeys[i].keyName, NagraKeys.EmuKeys[i].keyLength, 0);
}
// Session words for BISS1 mode 1/E (caid 2600) and BISS2 mode 1/E (caid 2602)
for (i = 0; i < BissSWs.keyCount; i++)
{
caid = (BissSWs.EmuKeys[i].keyLength == 8) ? 0x2600 : 0x2602;
emu_add_entitlement(rdr, caid, BissSWs.EmuKeys[i].provider, BissSWs.EmuKeys[i].key,
BissSWs.EmuKeys[i].keyName, BissSWs.EmuKeys[i].keyLength, 0);
}
// Session keys (ECM keys) for BISS2 mode CA
for (i = 0; i < Biss2Keys.keyCount; i++)
{
emu_add_entitlement(rdr, 0x2610, Biss2Keys.EmuKeys[i].provider, Biss2Keys.EmuKeys[i].key,
Biss2Keys.EmuKeys[i].keyName, Biss2Keys.EmuKeys[i].keyLength, 0);
}
// RSA keys (EMM keys) for BISS2 mode CA
itr = ll_iter_create(rdr->ll_biss2_rsa_keys);
while ((item = ll_iter_next(&itr)))
{
emu_add_entitlement(rdr, 0x2610, 0, item->ekid, "RSAPRI", 8, 0);
}
}
static int32_t emu_do_ecm(struct s_reader *rdr, const ECM_REQUEST *er, struct s_ecm_answer *ea)
{
if (!emu_process_ecm(rdr, er, ea->cw, &ea->cw_ex))
{
return CS_OK;
}
return CS_ERROR;
}
static int32_t emu_do_emm(struct s_reader *rdr, EMM_PACKET *emm)
{
uint32_t keysAdded = 0;
if (emm->emmlen < 3)
{
return CS_ERROR;
}
if (SCT_LEN(emm->emm) > emm->emmlen)
{
return CS_ERROR;
}
if (!emu_process_emm(rdr, b2i(2, emm->caid), emm->emm, &keysAdded))
{
if (keysAdded > 0)
{
refresh_entitlements(rdr);
}
return CS_OK;
}
return CS_ERROR;
}
static int32_t emu_card_info(struct s_reader *rdr)
{
SAFE_MUTEX_LOCK(&emu_key_data_mutex);
// Delete keys from Emu's memory
emu_clear_keydata();
// Delete BISS2 mode CA RSA keys
ll_destroy_data(&rdr->ll_biss2_rsa_keys);
// Read keys built in the OSCam-Emu binary
emu_read_keymemory(rdr);
// Read keys from SoftCam.Key file
emu_set_keyfile_path(cs_confdir);
if (!emu_read_keyfile(rdr, cs_confdir))
{
if (emu_read_keyfile(rdr, "/var/keys/"))
{
emu_set_keyfile_path("/var/keys/");
}
}
// Read BISS2 mode CA RSA keys from PEM files
biss_read_pem(rdr, BISS2_MAX_RSA_KEYS);
cs_log("Total keys in memory: W:%d V:%d N:%d I:%d F:%d G:%d P:%d T:%d A:%d",
CwKeys.keyCount, ViKeys.keyCount, NagraKeys.keyCount, IrdetoKeys.keyCount,
BissSWs.keyCount, Biss2Keys.keyCount, PowervuKeys.keyCount, TandbergKeys.keyCount,
StreamKeys.keyCount);
// Inform OSCam about all available keys.
// This is used for listing the "entitlements" in the webif's reader page.
refresh_entitlements(rdr);
SAFE_MUTEX_UNLOCK(&emu_key_data_mutex);
set_prids(rdr);
set_hexserial_to_version(rdr);
return CS_OK;
}
/*
static int32_t emu_card_init(struct s_reader *UNUSED(rdr), struct s_ATR *UNUSED(atr))
{
return CS_ERROR;
}
*/
int32_t emu_get_via3_emm_type(EMM_PACKET *ep, struct s_reader *rdr)
{
uint32_t provid = 0;
if(ep->emm[3] == 0x90 && ep->emm[4] == 0x03)
{
provid = b2i(3, ep->emm + 5);
provid &= 0xFFFFF0;
i2b_buf(4, provid, ep->provid);
}
switch (ep->emm[0])
{
case 0x88:
ep->type = UNIQUE;
memset(ep->hexserial, 0, 8);
memcpy(ep->hexserial, ep->emm + 4, 4);
rdr_log_dbg(rdr, D_EMM, "UNIQUE");
return 1;
case 0x8A:
case 0x8B:
ep->type = GLOBAL;
rdr_log_dbg(rdr, D_EMM, "GLOBAL");
return 1;
case 0x8C:
case 0x8D:
ep->type = SHARED;
rdr_log_dbg(rdr, D_EMM, "SHARED (part)");
// We need those packets to pass otherwise we would never
// be able to complete EMM reassembly
return 1;
case 0x8E:
ep->type = SHARED;
rdr_log_dbg(rdr, D_EMM, "SHARED");
memset(ep->hexserial, 0, 8);
memcpy(ep->hexserial, ep->emm + 3, 3);
return 1;
default:
ep->type = UNKNOWN;
rdr_log_dbg(rdr, D_EMM, "UNKNOWN");
return 1;
}
}
int32_t emu_get_ird2_emm_type(EMM_PACKET *ep, struct s_reader *rdr)
{
int32_t l = (ep->emm[3] & 0x07);
int32_t base = (ep->emm[3] >> 3);
char dumprdrserial[l * 3], dumpemmserial[l * 3];
switch (l)
{
case 0:
// global emm, 0 bytes addressed
ep->type = GLOBAL;
rdr_log_dbg(rdr, D_EMM, "GLOBAL base = %02x", base);
return 1;
case 2:
// shared emm, 2 bytes addressed
ep->type = SHARED;
memset(ep->hexserial, 0, 8);
memcpy(ep->hexserial, ep->emm + 4, l);
cs_hexdump(1, rdr->hexserial, l, dumprdrserial, sizeof(dumprdrserial));
cs_hexdump(1, ep->hexserial, l, dumpemmserial, sizeof(dumpemmserial));
rdr_log_dbg_sensitive(rdr, D_EMM, "SHARED l = %d ep = {%s} rdr = {%s} base = %02x",
l, dumpemmserial, dumprdrserial, base);
return 1;
case 3:
// unique emm, 3 bytes addressed
ep->type = UNIQUE;
memset(ep->hexserial, 0, 8);
memcpy(ep->hexserial, ep->emm + 4, l);
cs_hexdump(1, rdr->hexserial, l, dumprdrserial, sizeof(dumprdrserial));
cs_hexdump(1, ep->hexserial, l, dumpemmserial, sizeof(dumpemmserial));
rdr_log_dbg_sensitive(rdr, D_EMM, "UNIQUE l = %d ep = {%s} rdr = {%s} base = %02x",
l, dumpemmserial, dumprdrserial, base);
return 1;
default:
ep->type = UNKNOWN;
rdr_log_dbg(rdr, D_EMM, "UNKNOWN");
return 1;
}
}
int32_t emu_get_pvu_emm_type(EMM_PACKET *ep, struct s_reader *rdr)
{
if (ep->emm[0] == 0x82)
{
ep->type = UNIQUE;
memset(ep->hexserial, 0, 8);
memcpy(ep->hexserial, ep->emm + 12, 4);
}
else
{
ep->type = UNKNOWN;
rdr_log_dbg(rdr, D_EMM, "UNKNOWN");
}
return 1;
}
int32_t emu_get_tan_emm_type(EMM_PACKET *ep, struct s_reader *rdr)
{
if (ep->emm[0] == 0x82 || ep->emm[0] == 0x83)
{
ep->type = GLOBAL;
}
else
{
ep->type = UNKNOWN;
rdr_log_dbg(rdr, D_EMM, "UNKNOWN");
}
return 1;
}
int32_t emu_get_biss_emm_type(EMM_PACKET *ep, struct s_reader *rdr)
{
switch (ep->emm[0])
{
case 0x81: // Spec say this is for EMM, but oscam (and all other crypto systems) use it for ECM
case 0x82:
case 0x83:
case 0x84:
case 0x85:
case 0x86:
case 0x87:
case 0x88:
case 0x89:
case 0x8A:
case 0x8B:
case 0x8C:
case 0x8D:
case 0x8E:
case 0x8F:
ep->type = GLOBAL;
return 1;
default:
ep->type = UNKNOWN;
rdr_log_dbg(rdr, D_EMM, "UNKNOWN");
return 1;
}
}
static int32_t emu_get_emm_type(struct emm_packet_t *ep, struct s_reader *rdr)
{
uint16_t caid = b2i(2, ep->caid);
if (caid_is_viaccess(caid)) return emu_get_via3_emm_type(ep, rdr);
if (caid_is_irdeto(caid)) return emu_get_ird2_emm_type(ep, rdr);
if (caid_is_powervu(caid)) return emu_get_pvu_emm_type(ep, rdr);
if (caid_is_director(caid)) return emu_get_tan_emm_type(ep, rdr);
if (caid_is_biss_dynamic(caid)) return emu_get_biss_emm_type(ep, rdr);
return CS_ERROR;
}
FILTER *get_emu_prids_for_caid(struct s_reader *rdr, uint16_t caid)
{
int32_t i;
for (i = 0; i < rdr->emu_auproviders.nfilts; i++)
{
if (caid == rdr->emu_auproviders.filts[i].caid)
{
return &rdr->emu_auproviders.filts[i];
}
}
return NULL;
}
static int32_t emu_get_via3_emm_filter(struct s_reader *UNUSED(rdr), struct s_csystem_emm_filter **emm_filters, unsigned int *filter_count, uint16_t UNUSED(caid), uint32_t UNUSED(provid))
{
if (*emm_filters == NULL)
{
const unsigned int max_filter_count = 1;
if (!cs_malloc(emm_filters, max_filter_count * sizeof(struct s_csystem_emm_filter)))
{
return CS_ERROR;
}
struct s_csystem_emm_filter *filters = *emm_filters;
*filter_count = 0;
int32_t idx = 0;
filters[idx].type = EMM_GLOBAL;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x8A;
filters[idx].mask[0] = 0xFE;
filters[idx].filter[3] = 0x80;
filters[idx].mask[3] = 0x80;
idx++;
*filter_count = idx;
}
return CS_OK;
}
static int32_t emu_get_ird2_emm_filter(struct s_reader *rdr, struct s_csystem_emm_filter **emm_filters, unsigned int *filter_count, uint16_t caid, uint32_t UNUSED(provid))
{
uint8_t hexserial[3], prid[4];
FILTER *emu_provids;
int8_t have_provid = 0, have_serial = 0;
int32_t i;
SAFE_MUTEX_LOCK(&emu_key_data_mutex);
if(irdeto2_get_hexserial(caid, hexserial))
{
have_serial = 1;
}
SAFE_MUTEX_UNLOCK(&emu_key_data_mutex);
emu_provids = get_emu_prids_for_caid(rdr, caid);
if (emu_provids != NULL && emu_provids->nprids > 0)
{
have_provid = 1;
}
if (*emm_filters == NULL)
{
const unsigned int max_filter_count = have_serial + (2 * (have_provid ? emu_provids->nprids : 0));
if (!cs_malloc(emm_filters, max_filter_count * sizeof(struct s_csystem_emm_filter)))
{
return CS_ERROR;
}
struct s_csystem_emm_filter *filters = *emm_filters;
*filter_count = 0;
unsigned int idx = 0;
if (have_serial)
{
filters[idx].type = EMM_UNIQUE;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x82;
filters[idx].mask[0] = 0xFF;
filters[idx].filter[1] = 0xFB;
filters[idx].mask[1] = 0x07;
memcpy(&filters[idx].filter[2], hexserial, 3);
memset(&filters[idx].mask[2], 0xFF, 3);
idx++;
}
for (i = 0; have_provid && i < emu_provids->nprids; i++)
{
i2b_buf(4, emu_provids->prids[i], prid);
filters[idx].type = EMM_UNIQUE;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x82;
filters[idx].mask[0] = 0xFF;
filters[idx].filter[1] = 0xFB;
filters[idx].mask[1] = 0x07;
memcpy(&filters[idx].filter[2], &prid[1], 3);
memset(&filters[idx].mask[2], 0xFF, 3);
idx++;
filters[idx].type = EMM_SHARED;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x82;
filters[idx].mask[0] = 0xFF;
filters[idx].filter[1] = 0xFA;
filters[idx].mask[1] = 0x07;
memcpy(&filters[idx].filter[2], &prid[1], 2);
memset(&filters[idx].mask[2], 0xFF, 2);
idx++;
}
*filter_count = idx;
}
return CS_OK;
}
static int32_t emu_get_pvu_emm_filter(struct s_csystem_emm_filter **emm_filters, unsigned int *filter_count,
uint16_t caid, uint16_t srvid, uint16_t tsid, uint16_t onid, uint32_t ens)
{
uint8_t hexserials[32][4];
uint32_t i, count = 0;
SAFE_MUTEX_LOCK(&emu_key_data_mutex);
count = powervu_get_hexserials_new(hexserials, 32, caid, tsid, onid, ens);
if (count == 0)
{
count = powervu_get_hexserials(hexserials, 32, srvid);
if (count == 0)
{
SAFE_MUTEX_UNLOCK(&emu_key_data_mutex);
return CS_ERROR;
}
}
SAFE_MUTEX_UNLOCK(&emu_key_data_mutex);
if (*emm_filters == NULL)
{
const unsigned int max_filter_count = count;
if (!cs_malloc(emm_filters, max_filter_count * sizeof(struct s_csystem_emm_filter)))
{
return CS_ERROR;
}
struct s_csystem_emm_filter *filters = *emm_filters;
*filter_count = 0;
int32_t idx = 0;
for (i = 0; i < count; i++)
{
filters[idx].type = EMM_UNIQUE;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x82;
filters[idx].filter[10] = hexserials[i][0];
filters[idx].filter[11] = hexserials[i][1];
filters[idx].filter[12] = hexserials[i][2];
filters[idx].filter[13] = hexserials[i][3];
filters[idx].mask[0] = 0xFF;
filters[idx].mask[10] = 0xFF;
filters[idx].mask[11] = 0xFF;
filters[idx].mask[12] = 0xFF;
filters[idx].mask[13] = 0xFF;
idx++;
}
*filter_count = idx;
}
return CS_OK;
}
static int32_t emu_get_tan_emm_filter(struct s_reader *UNUSED(rdr), struct s_csystem_emm_filter **emm_filters, unsigned int *filter_count, uint16_t UNUSED(caid), uint32_t UNUSED(provid))
{
if (*emm_filters == NULL)
{
const unsigned int max_filter_count = 2;
uint8_t buf[8];
if (!emu_find_key('T', 0x40, 0, "MK", buf, 8, 0, 0, 0, NULL) &&
!emu_find_key('T', 0x40, 0, "MK01", buf, 8, 0, 0, 0, NULL))
{
return CS_ERROR;
}
if (!cs_malloc(emm_filters, max_filter_count * sizeof(struct s_csystem_emm_filter)))
{
return CS_ERROR;
}
struct s_csystem_emm_filter *filters = *emm_filters;
*filter_count = 0;
int32_t idx = 0;
filters[idx].type = EMM_GLOBAL;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x82;
filters[idx].mask[0] = 0xFF;
idx++;
filters[idx].type = EMM_GLOBAL;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x83;
filters[idx].mask[0] = 0xFF;
idx++;
*filter_count = idx;
}
return CS_OK;
}
static int32_t emu_get_biss_emm_filter(struct s_reader *UNUSED(rdr), struct s_csystem_emm_filter **emm_filters, unsigned int *filter_count, uint16_t UNUSED(caid), uint32_t UNUSED(provid))
{
if (*emm_filters == NULL)
{
const unsigned int max_filter_count = 15;
if (!cs_malloc(emm_filters, max_filter_count * sizeof(struct s_csystem_emm_filter)))
{
return CS_ERROR;
}
struct s_csystem_emm_filter *filters = *emm_filters;
*filter_count = 0;
int32_t idx = 0;
uint8_t i;
for (i = 0; i < max_filter_count; i++)
{
filters[idx].type = EMM_GLOBAL;
filters[idx].enabled = 1;
filters[idx].filter[0] = 0x81 + i; // What about table 0x81?
filters[idx].mask[0] = 0xFF;
idx++;
*filter_count = idx;
}
}
return CS_OK;
}
static int32_t emu_get_emm_filter(struct s_reader *UNUSED(rdr), struct s_csystem_emm_filter **UNUSED(emm_filters), unsigned int *UNUSED(filter_count))
{
return CS_ERROR;
}
static int32_t emu_get_emm_filter_adv(struct s_reader *rdr, struct s_csystem_emm_filter **emm_filters, unsigned int *filter_count,
uint16_t caid, uint32_t provid, uint16_t srvid, uint16_t tsid, uint16_t onid, uint32_t ens)
{
if (caid_is_viaccess(caid)) return emu_get_via3_emm_filter(rdr, emm_filters, filter_count, caid, provid);
if (caid_is_irdeto(caid)) return emu_get_ird2_emm_filter(rdr, emm_filters, filter_count, caid, provid);
if (caid_is_powervu(caid)) return emu_get_pvu_emm_filter(emm_filters, filter_count, caid, srvid, tsid, onid, ens);
if (caid_is_director(caid)) return emu_get_tan_emm_filter(rdr, emm_filters, filter_count, caid, provid);
if (caid_is_biss_dynamic(caid)) return emu_get_biss_emm_filter(rdr, emm_filters, filter_count, caid, provid);
return CS_ERROR;
}
const struct s_cardsystem reader_emu =
{
.desc = "emu",
.caids = (uint16_t[]){ 0x05, 0x06, 0x0D, 0x0E, 0x10, 0x18, 0x26, 0 },
.do_ecm = emu_do_ecm,
.do_emm = emu_do_emm,
.card_info = emu_card_info,
//.card_init = emu_card_init, // apparently this is not needed at all
.get_emm_type = emu_get_emm_type,
.get_emm_filter = emu_get_emm_filter, // needed to pass checks
.get_emm_filter_adv = emu_get_emm_filter_adv,
};
/*
* Create the Emu virtual "device" part. This is of type s_cardreader.
* Similar structures are found in the csctapi (Card System Card Terminal API)
* folder for every IFD (InterFace Device), aka smart card reader.
* Since we have no hardware to initialize, we start our Stream Relay server
* with the emu_reader_init() function.
* At Emu shutdown, we remove keys from memory with the emu_close() function.
*/
#define CR_OK 0
#define CR_ERROR 1
static int32_t emu_reader_init(struct s_reader *UNUSED(reader))
{
int32_t i;
char authtmp[128];
if (cfg.emu_stream_relay_enabled && (stream_server_thread_init == 0))
{
stream_server_thread_init = 1;
SAFE_MUTEX_INIT(&emu_fixed_key_srvid_mutex, NULL);
for (i = 0; i < EMU_STREAM_SERVER_MAX_CONNECTIONS; i++)
{
SAFE_MUTEX_INIT(&emu_fixed_key_data_mutex[i], NULL);
ll_emu_stream_delayed_keys[i] = ll_create("ll_emu_stream_delayed_keys");
memset(&emu_fixed_key_data[i], 0, sizeof(emu_stream_client_key_data));
}
start_thread("stream_key_delayer", stream_key_delayer, NULL, NULL, 1, 1);
cs_log("Stream key delayer initialized");
cs_strncpy(emu_stream_source_host, cfg.emu_stream_source_host, sizeof(emu_stream_source_host));
emu_stream_source_port = cfg.emu_stream_source_port;
emu_stream_relay_port = cfg.emu_stream_relay_port;
emu_stream_emm_enabled = cfg.emu_stream_emm_enabled;
if (cfg.emu_stream_source_auth_user && cfg.emu_stream_source_auth_password)
{
snprintf(authtmp, sizeof(authtmp), "%s:%s", cfg.emu_stream_source_auth_user, cfg.emu_stream_source_auth_password);
b64encode(authtmp, strlen(authtmp), &emu_stream_source_auth);
}
else
{
NULLFREE(emu_stream_source_auth);
}
start_thread("stream_server", stream_server, NULL, NULL, 1, 1);
cs_log("Stream relay server initialized");
}
// Initialize mutex for exclusive access to key database and key file
if (!emu_key_data_mutex_init)
{
SAFE_MUTEX_INIT(&emu_key_data_mutex, NULL);
emu_key_data_mutex_init = 1;
}
return CR_OK;
}
static int32_t emu_close(struct s_reader *UNUSED(reader))
{
cs_log("Reader is shutting down");
// Delete keys from Emu's memory
SAFE_MUTEX_LOCK(&emu_key_data_mutex);
emu_clear_keydata();
SAFE_MUTEX_UNLOCK(&emu_key_data_mutex);
return CR_OK;
}
static int32_t emu_get_status(struct s_reader *UNUSED(reader), int32_t *in) { *in = 1; return CR_OK; }
static int32_t emu_activate(struct s_reader *UNUSED(reader), struct s_ATR *UNUSED(atr)) { return CR_OK; }
static int32_t emu_transmit(struct s_reader *UNUSED(reader), uint8_t *UNUSED(buffer), uint32_t UNUSED(size), uint32_t UNUSED(expectedlen), uint32_t UNUSED(delay), uint32_t UNUSED(timeout)) { return CR_OK; }
static int32_t emu_receive(struct s_reader *UNUSED(reader), uint8_t *UNUSED(buffer), uint32_t UNUSED(size), uint32_t UNUSED(delay), uint32_t UNUSED(timeout)) { return CR_OK; }
static int32_t emu_write_settings(struct s_reader *UNUSED(reader), struct s_cardreader_settings *UNUSED(s)) { return CR_OK; }
static int32_t emu_card_write(struct s_reader *UNUSED(pcsc_reader), const uint8_t *UNUSED(buf), uint8_t *UNUSED(cta_res), uint16_t *UNUSED(cta_lr), int32_t UNUSED(l)) { return CR_OK; }
static int32_t emu_set_protocol(struct s_reader *UNUSED(rdr), uint8_t *UNUSED(params), uint32_t *UNUSED(length), uint32_t UNUSED(len_request)) { return CR_OK; }
const struct s_cardreader cardreader_emu =
{
.desc = "emu",
.typ = R_EMU,
.skip_extra_atr_parsing = 1,
.reader_init = emu_reader_init,
.get_status = emu_get_status,
.activate = emu_activate,
.transmit = emu_transmit,
.receive = emu_receive,
.close = emu_close,
.write_settings = emu_write_settings,
.card_write = emu_card_write,
.set_protocol = emu_set_protocol,
};
void add_emu_reader(void)
{
// This function is called inside oscam.c and creates an emu [reader] with default
// settings in oscam.server file. If an emu [reader] already exists, it uses that.
LL_ITER itr;
struct s_reader *rdr;
int8_t haveEmuReader = 0;
char emuName[] = "emulator";
char *ctab, *ftab, *emu_auproviders, *disablecrccws_only_for;
// Check if emu [reader] entry already exists in oscam.server file and get it
itr = ll_iter_create(configured_readers);
while ((rdr = ll_iter_next(&itr)))
{
if (rdr->typ == R_EMU)
{
haveEmuReader = 1;
break;
}
}
rdr = NULL;
// If there's no emu [reader] in oscam.server, create one with default settings
if (!haveEmuReader)
{
if (!cs_malloc(&rdr, sizeof(struct s_reader)))
{
return;
}
reader_set_defaults(rdr);
rdr->enable = 1;
rdr->typ = R_EMU;
cs_strncpy(rdr->label, emuName, sizeof(emuName));
cs_strncpy(rdr->device, emuName, sizeof(emuName));
// CAIDs
ctab = strdup("0500,0604,0E00,1010,1801,2600,2602,2610");
chk_caidtab(ctab, &rdr->ctab);
NULLFREE(ctab);
// Idents
ftab = strdup("0500:000000,007400,007800,021110,023800;"
"0604:000000;"
"0E00:000000;"
"1010:000000;"
"1801:000000,001101,002111,007301;"
"2600:000000;"
"2602:000000;"
"2610:000000;"
);
chk_ftab(ftab, &rdr->ftab);
NULLFREE(ftab);
// AU providers
emu_auproviders = strdup("0604:010200;0E00:000000;1010:000000;2610:000000;");
chk_ftab(emu_auproviders, &rdr->emu_auproviders);
NULLFREE(emu_auproviders);
// EMM cache
rdr->cachemm = 2;
rdr->rewritemm = 1;
rdr->logemm = 2;
rdr->deviceemm = 1;
// User group
rdr->grp = 0x1ULL;
// Add the "device" part to our emu reader
rdr->crdr = &cardreader_emu;
// Disable CW checksum test for PowerVu
disablecrccws_only_for = strdup("0E00:000000");
chk_ftab(disablecrccws_only_for, &rdr->disablecrccws_only_for);
NULLFREE(disablecrccws_only_for);
reader_fixups_fn(rdr);
ll_append(configured_readers, rdr);
}
// Set DVB Api delayer option
#ifdef HAVE_DVBAPI
if (cfg.dvbapi_enabled && cfg.dvbapi_delayer < 60)
{
cfg.dvbapi_delayer = 60;
}
#endif
cs_log("OSCam-Emu version %d", EMU_VERSION);
}
#endif // WITH_EMU