/**
** @brief
** ROM/SRAM/FlashPage Write Access Timing
*/
static void
s3c4510_bus_write( bus_t *bus, uint32_t adr, uint32_t data )
{
/* see Figure 4-21 in [1] */
part_t *p = PART;
chain_t *chain = CHAIN;
part_set_signal( p, nRCS[0], 1, 0 );
part_set_signal( p, nRCS[1], 1, 1 );
part_set_signal( p, nRCS[2], 1, 1 );
part_set_signal( p, nRCS[3], 1, 1 );
part_set_signal( p, nRCS[4], 1, 1 );
part_set_signal( p, nRCS[5], 1, 1 );
part_set_signal( p, nWBE[0], 1, 1 );
part_set_signal( p, nWBE[1], 1, 1 );
part_set_signal( p, nWBE[2], 1, 1 );
part_set_signal( p, nWBE[3], 1, 1 );
part_set_signal( p, nOE, 1, 1 );
setup_address( bus, adr );
setup_data( bus, data );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, nWBE[0], 1, 0 );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, nWBE[0], 1, 1 );
part_set_signal( p, nRCS[0], 1, 1 );
part_set_signal( p, nRCS[1], 1, 1 );
part_set_signal( p, nRCS[2], 1, 1 );
part_set_signal( p, nRCS[3], 1, 1 );
part_set_signal( p, nRCS[4], 1, 1 );
part_set_signal( p, nRCS[5], 1, 1 );
chain_shift_data_registers( chain, 0 );
}
void
sa1110_bus_write( parts *ps, uint32_t adr, uint32_t data )
{
/* see Figure 10-16 in SA doc */
part *p = ps->parts[0];
if ( (adr==0x49000000) && (data==1) ) {
part_set_signal( p, "nCS0", 1, 1 );
part_set_signal( p, "nCS5", 1, 0 );
} else {
part_set_signal( p, "nCS0", 1, 0 );
part_set_signal( p, "nCS5", 1, 1 );
}
part_set_signal( p, "nCS1", 1, 1 );
part_set_signal( p, "nCS2", 1, 1 );
part_set_signal( p, "nCS3", 1, 1 );
part_set_signal( p, "nCS4", 1, 1 );
part_set_signal( p, "RD_nWR", 1, 0 );
part_set_signal( p, "nWE", 1, 1 );
part_set_signal( p, "nOE", 1, 1 );
setup_address( p, adr );
setup_data( p, data );
parts_shift_data_registers( ps );
part_set_signal( p, "nWE", 1, 0 );
parts_shift_data_registers( ps );
part_set_signal( p, "nWE", 1, 1 );
parts_shift_data_registers( ps );
part_set_signal( p, "nCS0", 1, 1 );
part_set_signal( p, "nCS5", 1, 1 );
parts_shift_data_registers( ps );
}
/**
* bus->driver->(*read_next)
*
*/
static uint32_t
jopcyc_bus_read_next( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
int i;
uint32_t d = 0;
bus_area_t area;
component_t *comp;
comp_bus_area( bus, adr, &area, &comp );
if (!comp) {
printf( _("Address out of range\n") );
LAST_ADDR = adr;
return 0;
}
setup_address( bus, adr, comp );
chain_shift_data_registers( chain, 1 );
for (i = 0; i < area.width; i++)
d |= (uint32_t) (part_get_signal( p, D[i] ) << i);
return d;
}
/**
* bus->driver->(*read_start)
*
*/
static void
sh7750r_bus_read_start( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
int cs[8];
int i;
for (i = 0; i < 8; i++)
cs[i] = 1;
cs[(adr & 0x1C000000) >> 26] = 0;
part_set_signal( p, CS[0], 1, cs[0] );
part_set_signal( p, CS[1], 1, cs[1] );
part_set_signal( p, CS[2], 1, cs[2] );
part_set_signal( p, CS[3], 1, cs[3] );
part_set_signal( p, CS[4], 1, cs[4] );
part_set_signal( p, CS[5], 1, cs[5] );
part_set_signal( p, CS[6], 1, cs[6] );
part_set_signal( p, RDWR, 1, 1 );
part_set_signal( p, RDWR2, 1, 1 );
part_set_signal( p, WE[0], 1, 1 );
part_set_signal( p, WE[1], 1, 1 );
part_set_signal( p, WE[2], 1, 1 );
part_set_signal( p, WE[3], 1, 1 );
part_set_signal( p, RD, 1, 0 );
part_set_signal( p, RD2, 1, 0 );
setup_address( bus, adr );
set_data_in( bus );
chain_shift_data_registers( CHAIN, 0 );
}
/**
* bus->driver->(*read_start)
*
*/
static void
jopcyc_bus_read_start( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
bus_area_t area;
component_t *comp;
comp_bus_area( bus, adr, &area, &comp );
if (!comp) {
printf( _("Address out of range\n") );
LAST_ADDR = adr;
return;
}
part_set_signal( p, nCS, 1, 0 );
part_set_signal( p, nWE, 1, 1 );
part_set_signal( p, nOE, 1, 0 );
if (comp->ctype == RAM) {
part_set_signal( p, nLB, 1, 0 );
part_set_signal( p, nUB, 1, 0 );
}
setup_address( bus, adr, comp );
set_data_in( bus, comp );
chain_shift_data_registers( chain, 0 );
}
/**
* bus->driver->(*read_next)
*
*/
static uint32_t
sharc_21065L_bus_read_next( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
uint32_t d;
//uint32_t old_last_adr = LAST_ADR;
LAST_ADR = adr;
if (adr < UINT32_C(0x080000)) {
int i;
bus_area_t area;
sharc_21065L_bus_area( bus, adr, &area );
setup_address( bus, adr );
chain_shift_data_registers( chain, 1 );
d = 0;
for (i = 0; i < area.width; i++)
d |= (uint32_t) (part_get_signal( p, MD[i] ) << i);
return d;
}
return 0;
}
/**
* bus->driver->(*read_start)
*
*/
static void
s3c4510_bus_read_start( bus_t *bus, uint32_t adr )
{
/* see Figure 4-19 in [1] */
chain_t *chain = CHAIN;
s3c4510_bus_setup_ctrl( bus, 0x00fffe); /* nOE=0, nRCS0 =0 */
setup_address( bus, adr );
set_data_in( bus );
chain_shift_data_registers( chain, 0 );
}
/**
* bus->driver->(*write)
*
* @brief
* ROM/SRAM/FlashPage Write Access Timing
*/
static void
s3c4510_bus_write( bus_t *bus, uint32_t adr, uint32_t data )
{
/* see Figure 4-21 in [1] */
chain_t *chain = CHAIN;
s3c4510_bus_setup_ctrl( bus, 0x01fffe); /* nOE=1, nRCS0 =0 */
setup_address( bus, adr );
setup_data( bus, data );
chain_shift_data_registers( chain, 0 );
switch (dbus_width)
{
default:
case 8:
s3c4510_bus_setup_ctrl( bus, 0x01fefe); /* nOE=1, nRCS0 =0, nWBE0=0 */
break;
case 16:
s3c4510_bus_setup_ctrl( bus, 0x01fcfe); /* nOE=1, nRCS0 =0, nWBE0-1=0 */
break;
case 32:
s3c4510_bus_setup_ctrl( bus, 0x01f0fe); /* nOE=1, nRCS0 =0, nWBE0-3=0 */
break;
}
setup_address( bus, adr );
setup_data( bus, data );
chain_shift_data_registers( chain, 0 );
s3c4510_bus_setup_ctrl( bus, 0x01ffff); /* nOE=1, nRCS0 =1 */
chain_shift_data_registers( chain, 0 );
DEBUG_LVL2( printf("bus_write %08x @ %08x\n", data, adr); )
}
/**
* bus->driver->(*read_next)
*
*/
static uint32_t
sh7750r_bus_read_next( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
int i;
uint32_t d = 0;
setup_address( bus, adr );
chain_shift_data_registers( CHAIN, 1 );
for (i = 0; i < 32; i++)
d |= (uint32_t) (part_get_signal( p, D[i] ) << i);
return d;
}
static void
ppc440gx_ebc8_bus_read_start( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
part_set_signal( p, nCS, 1, 0 );
part_set_signal( p, nWE, 1, 1 );
part_set_signal( p, nOE, 1, 0 );
setup_address( bus, adr );
set_data_in( bus );
chain_shift_data_registers( chain, 0 );
}
t_std_error std_server_client_connect(std_event_client_handle * handle, const char *event_channel_name) {
std_socket_address_t addr;
setup_address(&addr,event_channel_name);
int sock = -1;
t_std_error rc = std_sock_connect(&addr,&sock);
if (rc!=STD_ERR_OK) return rc;
std_sock_set_sndbuf(sock,SOCKET_BUFFER_SIZE);
*handle = sock;
return STD_ERR_OK;
}
/**
* bus->driver->(*read_start)
*
*/
static void
bf533_ezkit_bus_read_start( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
select_flash( bus );
part_set_signal( p, AOE, 1, 0 );
part_set_signal( p, AWE, 1, 1 );
setup_address( bus, adr );
set_data_in( bus );
chain_shift_data_registers( chain, 0 );
}
/**
* bus->driver->(*read_next)
*
*/
static uint32_t
bf533_ezkit_bus_read_next( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
int i;
uint32_t d = 0;
setup_address( bus, adr );
chain_shift_data_registers( chain, 1 );
for (i = 0; i < 16; i++)
d |= (uint32_t) (part_get_signal( p, DATA[i] ) << i);
return d;
}
static uint32_t
s3c4510_bus_read_next( bus_t *bus, uint32_t adr )
{
/* see Figure 4-20 in [1] */
part_t *p = PART;
chain_t *chain = CHAIN;
int i;
uint32_t d = 0;
setup_address( bus, adr );
chain_shift_data_registers( chain, 1 );
for (i = 0; i < dbus_width; i++)
d |= (uint32_t) (part_get_signal( p, D[i] ) << i);
return d;
}
/**
* bus->driver->(*write)
*
*/
static void
sh7727_bus_write( bus_t *bus, uint32_t adr, uint32_t data )
{
chain_t *chain = CHAIN;
part_t *p = PART;
int cs[8];
int i;
for (i = 0; i < 8 ; i++)
cs[i] = 1;
cs[(adr & 0x1C000000) >> 26] = 0;
part_set_signal( p, CS[0], 1, cs[0] );
part_set_signal( p, CS[2], 1, cs[2] );
part_set_signal( p, CS[3], 1, cs[3] );
part_set_signal( p, CS[4], 1, cs[4] );
part_set_signal( p, CS[5], 1, cs[5] );
part_set_signal( p, CS[6], 1, cs[6] );
part_set_signal( p, RDWR, 1, 0 );
part_set_signal( p, WE[0], 1, 1 );
part_set_signal( p, WE[1], 1, 1 );
part_set_signal( p, WE[2], 1, 1 );
part_set_signal( p, WE[3], 1, 1 );
part_set_signal( p, RD, 1, 1 );
setup_address( bus, adr );
setup_data( bus, data );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, WE[0], 1, 0 );
part_set_signal( p, WE[1], 1, 0 );
part_set_signal( p, WE[2], 1, 0 );
part_set_signal( p, WE[3], 1, 0 );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, WE[0], 1, 1 );
part_set_signal( p, WE[1], 1, 1 );
part_set_signal( p, WE[2], 1, 1 );
part_set_signal( p, WE[3], 1, 1 );
chain_shift_data_registers( chain, 0 );
}
/**
* bus->driver->(*read_next)
*
*/
static uint32_t
sh7727_bus_read_next( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
int i;
uint32_t d = 0;
bus_area_t area;
sh7727_bus_area( bus, 0, &area );
setup_address( bus, adr );
chain_shift_data_registers( CHAIN, 1 );
for (i = 0; i < area.width; i++)
d |= (uint32_t) (part_get_signal( p, D[i] ) << i);
return d;
}
static uint32_t
ppc440gx_ebc8_bus_read_next( bus_t *bus, uint32_t adr )
{
part_t *p = PART;
chain_t *chain = CHAIN;
int i;
uint32_t d = 0;
bus_area_t area;
ppc440gx_ebc8_bus_area( bus, adr, &area );
setup_address( bus, adr );
chain_shift_data_registers( chain, 1 );
for (i = 0; i < area.width; i++)
d |= (uint32_t) (part_get_signal( p, D[PPC440GX_DATA_LINES-1-i] ) << i);
return d;
}
/**
* bus->driver->(*read_start)
*
*/
static void
sharc_21065L_bus_read_start( bus_t *bus, uint32_t adr )
{
chain_t *chain = CHAIN;
part_t *p = PART;
LAST_ADR = adr;
if (adr >= 0x080000)
return;
part_set_signal( p, BMS, 1, 0 );
part_set_signal( p, nWE, 1, 1 );
part_set_signal( p, nOE, 1, 0 );
setup_address( bus, adr );
set_data_in( bus, adr );
chain_shift_data_registers( chain, 0 );
}
void
sa1110_bus_read_start( parts *ps, uint32_t adr )
{
/* see Figure 10-12 in SA doc */
part *p = ps->parts[0];
part_set_signal( p, "nCS0", 1, 0 );
part_set_signal( p, "nCS1", 1, 1 );
part_set_signal( p, "nCS2", 1, 1 );
part_set_signal( p, "nCS3", 1, 1 );
part_set_signal( p, "nCS4", 1, 1 );
part_set_signal( p, "nCS5", 1, 1 );
part_set_signal( p, "RD_nWR", 1, 1 );
part_set_signal( p, "nWE", 1, 1 );
part_set_signal( p, "nOE", 1, 0 );
setup_address( p, adr );
set_data_in( p );
parts_shift_data_registers( ps );
}
/**
* bus->driver->(*write)
*
*/
static void
bf533_ezkit_bus_write( bus_t *bus, uint32_t adr, uint32_t data )
{
part_t *p = PART;
chain_t *chain = CHAIN;
// printf("Writing %04X to %08X...\n", data, adr);
select_flash( bus );
part_set_signal( p, AOE, 1, 1 );
setup_address( bus, adr );
setup_data( bus, data );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, AWE, 1, 0 );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, AWE, 1, 1 );
unselect_flash( bus );
chain_shift_data_registers( chain, 0 );
}
t_std_error std_event_server_init(std_event_server_handle_t *handle,
const char * event_channel_name, size_t threads) {
std_socket_event_server_t * p = new std_socket_event_server_t;
if (p==NULL) {
EV_LOG(ERR,COM,0,"COM-EVENT-INIT-FAILED","Failed to initialize the event service");
return STD_ERR(COM,NOMEM,0);
}
std_socket_server_t serv;
memset(&serv,0,sizeof(serv));
serv.context = p;
serv.name = COM_EVT_SERV_NAME;
serv.thread_pool_size = threads;
serv.new_client = event_new_client;
serv.del_client = event_del_client;
serv.some_data = event_some_data;
setup_address(&serv.address, event_channel_name);
if (std_socket_service_init(&p->m_sock_service,&serv)!=STD_ERR_OK) {
delete p;
return STD_ERR(COM,FAIL,0);
}
t_std_error rc = STD_ERR(COM,FAIL,0);
do {
if ((rc=std_rw_lock_create_default(&p->m_tree_lock))!=STD_ERR_OK) break;
if (std_socket_service_run(p->m_sock_service)!=STD_ERR_OK) break;
*handle = p;
return rc;
} while (0);
delete p;
return rc;
}
uint32_t
sa1110_bus_read_next( parts *ps, uint32_t adr )
{
/* see Figure 10-12 in SA doc */
part *p = ps->parts[0];
setup_address( p, adr );
parts_shift_data_registers( ps );
{
int i;
char buff[10];
uint32_t d = 0;
for (i = 0; i < 32; i++) {
sprintf( buff, "D%d", i );
d |= (uint32_t) (part_get_signal( p, buff ) << i);
}
return d;
}
}
/**
* bus->driver->(*write)
*
*/
static void
sharc_21065L_bus_write( bus_t *bus, uint32_t adr, uint32_t data )
{
part_t *p = PART;
chain_t *chain = CHAIN;
if (adr >= 0x080000)
return;
part_set_signal( p, BMS, 1, 0 );
part_set_signal( p, nWE, 1, 1 );
part_set_signal( p, nOE, 1, 1 );
setup_address( bus, adr );
setup_data( bus, adr, data );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, nWE, 1, 0 );
chain_shift_data_registers( chain, 0 );
part_set_signal( p, nWE, 1, 1 );
chain_shift_data_registers( chain, 0 );
}
RF24Network::RF24Network( RF24& _radio ): radio(_radio), frame_size(MAX_FRAME_SIZE)
#else
RF24Network::RF24Network( RF24& _radio, RF24& _radio1 ): radio(_radio), radio1(_radio1),frame_size(MAX_FRAME_SIZE)
#endif
{
}
#elif !defined (DUAL_HEAD_RADIO)
RF24Network::RF24Network( RF24& _radio ): radio(_radio), next_frame(frame_queue)
{
#if !defined ( DISABLE_FRAGMENTATION )
frag_queue.message_buffer=&frag_queue_message_buffer[0];
frag_ptr = &frag_queue;
#endif
}
#else
RF24Network::RF24Network( RF24& _radio, RF24& _radio1 ): radio(_radio), radio1(_radio1), next_frame(frame_queue)
{
#if !defined ( DISABLE_FRAGMENTATION )
frag_queue.message_buffer=&frag_queue_message_buffer[0];
frag_ptr = &frag_queue;
#endif
}
#endif
/******************************************************************/
void RF24Network::begin(uint8_t _channel, uint16_t _node_address )
{
if (! is_valid_address(_node_address) )
return;
node_address = _node_address;
if ( ! radio.isValid() ){
return;
}
// Set up the radio the way we want it to look
if(_channel != USE_CURRENT_CHANNEL){
radio.setChannel(_channel);
}
//radio.enableDynamicAck();
radio.setAutoAck(0,0);
#if defined (ENABLE_DYNAMIC_PAYLOADS)
radio.enableDynamicPayloads();
#endif
// Use different retry periods to reduce data collisions
uint8_t retryVar = (((node_address % 6)+1) *2) + 3;
radio.setRetries(retryVar, 5); // max about 85ms per attempt
txTimeout = 25;
routeTimeout = txTimeout*3; // Adjust for max delay per node within a single chain
#if defined (DUAL_HEAD_RADIO)
radio1.setChannel(_channel);
radio1.enableDynamicAck();
radio1.enableDynamicPayloads();
#endif
// Setup our address helper cache
setup_address();
// Open up all listening pipes
uint8_t i = 6;
while (i--){
radio.openReadingPipe(i,pipe_address(_node_address,i));
}
radio.startListening();
}
/******************************************************************/
#if defined ENABLE_NETWORK_STATS
void RF24Network::failures(uint32_t *_fails, uint32_t *_ok){
*_fails = nFails;
*_ok = nOK;
}
RF24Network::RF24Network( RF24& _radio ): radio(_radio), frame_size(MAX_FRAME_SIZE)
#else
RF24Network::RF24Network( RF24& _radio, RF24& _radio1 ): radio(_radio), radio1(_radio1),frame_size(MAX_FRAME_SIZE)
#endif
{
}
#elif !defined (DUAL_HEAD_RADIO)
RF24Network::RF24Network( RF24& _radio ): radio(_radio), next_frame(frame_queue)
{
}
#else
RF24Network::RF24Network( RF24& _radio, RF24& _radio1 ): radio(_radio), radio1(_radio1), next_frame(frame_queue)
{
}
#endif
/******************************************************************/
void RF24Network::begin(uint8_t _channel, uint16_t _node_address )
{
if (! is_valid_address(_node_address) )
return;
node_address = _node_address;
if ( ! radio.isValid() ){
return;
}
//radio.stopListening();
// Set up the radio the way we want it to look
radio.setChannel(_channel);
radio.enableDynamicAck();
radio.enableDynamicPayloads();
// Use different retry periods to reduce data collisions
uint8_t retryVar = (((node_address % 6)+1) *2) + 3;
radio.setRetries(retryVar, 5);
txTimeout = 25;
routeTimeout = txTimeout*9; // Adjust for max delay per node
#if defined (DUAL_HEAD_RADIO)
radio1.setChannel(_channel);
radio1.enableDynamicAck();
radio1.enableDynamicPayloads();
#endif
// Setup our address helper cache
setup_address();
// Open up all listening pipes
uint8_t i = 6;
while (i--){
radio.openReadingPipe(i,pipe_address(_node_address,i));
}
radio.startListening();
}
/******************************************************************/
#if defined ENABLE_NETWORK_STATS
void RF24Network::failures(uint32_t *_fails, uint32_t *_ok){
*_fails = nFails;
*_ok = nOK;
}
