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#include "x300_init.h"
#include "x300_defs.h"
#include "ethernet.h"
#include "cron.h"
#include <wb_utils.h>
#include <wb_uart.h>
#include <wb_i2c.h>
#include <stdint.h>
#include <stdbool.h>
#include <trace.h>
#include <wb_pkt_iface64.h>
#include <u3_net_stack.h>
#include <link_state_route_proto.h>
#include <udp_uart.h>
#include "x300_fw_common.h"
#include <print_addrs.h>
static wb_pkt_iface64_config_t pkt_config;
struct x300_eeprom_map
{
//indentifying numbers
unsigned char revision[2];
unsigned char product[2];
uint8_t _pad0[4];
//all the mac addrs
uint8_t mac_addr0[6];
uint8_t _pad1[2];
uint8_t mac_addr1[6];
uint8_t _pad2[2];
//all the IP addrs
uint32_t gateway;
uint32_t subnet[4];
uint32_t ip_addr[4];
uint8_t _pad3[16];
};
static struct x300_eeprom_map default_map = {
.mac_addr0 = X300_DEFAULT_MAC_ADDR_0,
.mac_addr1 = X300_DEFAULT_MAC_ADDR_1,
.gateway = X300_DEFAULT_GATEWAY,
.subnet = {
X300_DEFAULT_NETMASK_ETH0_1G,
X300_DEFAULT_NETMASK_ETH1_1G,
X300_DEFAULT_NETMASK_ETH0_10G,
X300_DEFAULT_NETMASK_ETH1_10G
},
.ip_addr = {
X300_DEFAULT_IP_ETH0_1G,
X300_DEFAULT_IP_ETH1_1G,
X300_DEFAULT_IP_ETH0_10G,
X300_DEFAULT_IP_ETH1_10G
},
};
const void *pick_inited_field(const void *eeprom, const void *def, const size_t len)
{
bool all_ones = true;
bool all_zeros = true;
for (size_t i = 0; i < len; i++)
{
const uint8_t b = ((const uint8_t *)eeprom)[i];
if (b != 0x00) all_zeros = false;
if (b != 0xff) all_ones = false;
}
if (all_zeros) return def;
if (all_ones) return def;
return eeprom;
}
static void init_network(void)
{
pkt_config = wb_pkt_iface64_init(PKT_RAM0_BASE, 0x1ffc);
u3_net_stack_init(&pkt_config);
link_state_route_proto_init();
//read everything from eeprom
static const uint8_t eeprom_cmd[2] = {0, 0}; //the command is 16 bits of address offset
struct x300_eeprom_map eeprom_map = default_map;
wb_i2c_write(I2C1_BASE, MBOARD_EEPROM_ADDR, eeprom_cmd, 2);
wb_i2c_read(I2C1_BASE, MBOARD_EEPROM_ADDR, (uint8_t *)(&eeprom_map), sizeof(eeprom_map));
//determine interface number
const size_t eth0no = wb_peek32(SR_ADDR(RB0_BASE, RB_SFP0_TYPE))? 2 : 0;
const size_t eth1no = wb_peek32(SR_ADDR(RB0_BASE, RB_SFP1_TYPE))? 3 : 1;
//pick the address from eeprom or default
const eth_mac_addr_t *my_mac0 = (const eth_mac_addr_t *)pick_inited_field(&eeprom_map.mac_addr0, &default_map.mac_addr0, 6);
const eth_mac_addr_t *my_mac1 = (const eth_mac_addr_t *)pick_inited_field(&eeprom_map.mac_addr1, &default_map.mac_addr1, 6);
const struct ip_addr *my_ip0 = (const struct ip_addr *)pick_inited_field(&eeprom_map.ip_addr[eth0no], &default_map.ip_addr[eth0no], 4);
const struct ip_addr *subnet0 = (const struct ip_addr *)pick_inited_field(&eeprom_map.subnet[eth0no], &default_map.subnet[eth0no], 4);
const struct ip_addr *my_ip1 = (const struct ip_addr *)pick_inited_field(&eeprom_map.ip_addr[eth1no], &default_map.ip_addr[eth1no], 4);
const struct ip_addr *subnet1 = (const struct ip_addr *)pick_inited_field(&eeprom_map.subnet[eth1no], &default_map.subnet[eth1no], 4);
//init eth0
u3_net_stack_init_eth(0, my_mac0, my_ip0, subnet0);
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT0 + 8 + 0), (my_mac0->addr[5] << 0) | (my_mac0->addr[4] << 8) | (my_mac0->addr[3] << 16) | (my_mac0->addr[2] << 24));
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT0 + 8 + 1), (my_mac0->addr[1] << 0) | (my_mac0->addr[0] << 8));
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT0 + 8 + 2), my_ip0->addr);
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT0 + 8 + 4), 0/*nofwd*/);
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT0 + 8 + 5), (ICMP_IRQ << 8) | 0); //no fwd: type, code
//init eth1
u3_net_stack_init_eth(1, my_mac1, my_ip1, subnet1);
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT1 + 8 + 0), (my_mac1->addr[5] << 0) | (my_mac1->addr[4] << 8) | (my_mac1->addr[3] << 16) | (my_mac1->addr[2] << 24));
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT1 + 8 + 1), (my_mac1->addr[1] << 0) | (my_mac1->addr[0] << 8));
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT1 + 8 + 2), my_ip1->addr);
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT1 + 8 + 4), 0/*nofwd*/);
wb_poke32(SR_ADDR(SET0_BASE, SR_ETHINT1 + 8 + 5), (ICMP_IRQ << 8) | 0); //no fwd: type, code
}
static void putc(void *p, char c)
{
//If FW_TRACE_LEVEL is defined, then the trace level is set
//to a non-zero number. Turn on the debug UART to enable tracing
#ifdef UHD_FW_TRACE_LEVEL
wb_uart_putc(UART1_BASE, c);
#endif
}
static uint32_t get_counter_val()
{
return wb_peek32(SR_ADDR(RB0_BASE, RB_COUNTER));
}
void x300_init(void)
{
//first - uart
wb_uart_init(UART0_BASE, CPU_CLOCK/UART0_BAUD);
wb_uart_init(UART1_BASE, CPU_CLOCK/UART1_BAUD);
init_printf(NULL,putc);
//udp_uart_init(UART0_BASE, X300_GPSDO_UDP_PORT);
//now we can init the rest with prints
UHD_FW_TRACE(INFO, "[ZPU Initializing]");
UHD_FW_TRACE_FSTR(INFO, "-- Firmware Compat Number: %u.%u", (int)X300_FW_COMPAT_MAJOR, (int)X300_FW_COMPAT_MINOR);
uint32_t fpga_compat = wb_peek32(SR_ADDR(SET0_BASE, RB_FPGA_COMPAT));
UHD_FW_TRACE_FSTR(INFO, "-- FPGA Compat Number: %u.%u", (fpga_compat>>16), (fpga_compat&0xFFFF));
UHD_FW_TRACE_FSTR(INFO, "-- Clock Frequency: %u MHz", (CPU_CLOCK/1000000));
//Initialize cron
cron_init(get_counter_val, CPU_CLOCK);
//i2c rate init
wb_i2c_init(I2C0_BASE, CPU_CLOCK);
wb_i2c_init(I2C1_BASE, CPU_CLOCK);
wb_i2c_init(I2C2_BASE, CPU_CLOCK);
//hold phy in reset
wb_poke32(SR_ADDR(SET0_BASE, SR_SW_RST), SW_RST_PHY);
//setup net stack and eth state machines
init_network();
//phy reset release
wb_poke32(SR_ADDR(SET0_BASE, SR_SW_RST), 0);
//print network summary
for (uint8_t sfp = 0; sfp < ethernet_ninterfaces(); sfp++)
{
uint32_t sfp_type = wb_peek32(SR_ADDR(RB0_BASE, ((sfp==1) ? RB_SFP1_TYPE : RB_SFP0_TYPE)));
UHD_FW_TRACE_FSTR(INFO, "SFP+ Port %u:", (int)sfp);
if (sfp_type == RB_SFP_AURORA) {
UHD_FW_TRACE (INFO, "-- PHY: 10Gbps Aurora");
} else {
UHD_FW_TRACE_FSTR(INFO, "-- PHY: %s", (sfp_type == RB_SFP_10G_ETH) ? "10Gbps Ethernet" : "1Gbps Ethernet");
UHD_FW_TRACE_FSTR(INFO, "-- MAC: %s", mac_addr_to_str(u3_net_stack_get_mac_addr(sfp)));
UHD_FW_TRACE_FSTR(INFO, "-- IP: %s", ip_addr_to_str(u3_net_stack_get_ip_addr(sfp)));
UHD_FW_TRACE_FSTR(INFO, "-- SUBNET: %s", ip_addr_to_str(u3_net_stack_get_subnet(sfp)));
UHD_FW_TRACE_FSTR(INFO, "-- BCAST: %s", ip_addr_to_str(u3_net_stack_get_bcast(sfp)));
}
}
// For eth interfaces, initialize the PHY's
sleep_ms(100);
ethernet_init(0);
ethernet_init(1);
}
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