//
// Copyright 2010 Ettus Research LLC
//
/*
* Copyright 2007,2008 Free Software Foundation, Inc.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include
#include
#include "u2_init.h"
#include "memory_map.h"
#include "spi.h"
#include "hal_io.h"
#include "buffer_pool.h"
#include "pic.h"
#include
#include "ethernet.h"
#include "nonstdio.h"
#include "dbsm.h"
#include
#include
#include "memcpy_wa.h"
#include
#include
#include
#include "clocks.h"
#include "usrp2/fw_common.h"
#include
#include
#include
#include
#include "udp_fw_update.h"
/*
* Full duplex Tx and Rx between ethernet and DSP pipelines
*
* Buffer 1 is used by the cpu to send frames to the host.
* Buffers 2 and 3 are used to double-buffer the DSP Rx to eth flow
* Buffers 4 and 5 are used to double-buffer the eth to DSP Tx eth flow
*/
//#define CPU_RX_BUF 0 // eth -> cpu
#define DSP_RX_BUF_0 2 // dsp rx -> eth (double buffer)
#define DSP_RX_BUF_1 3 // dsp rx -> eth
#define DSP_TX_BUF_0 4 // eth -> dsp tx (double buffer)
#define DSP_TX_BUF_1 5 // eth -> dsp tx
/*
* ================================================================
* configure DSP TX double buffering state machine (eth -> dsp)
* ================================================================
*/
// DSP Tx reads ethernet header words
#define DSP_TX_FIRST_LINE ((sizeof(padded_eth_hdr_t) + sizeof(struct ip_hdr) + sizeof(struct udp_hdr))/sizeof(uint32_t))
// Receive from ethernet
buf_cmd_args_t dsp_tx_recv_args = {
PORT_ETH,
0,
BP_LAST_LINE
};
// send to DSP Tx
buf_cmd_args_t dsp_tx_send_args = {
PORT_DSP,
DSP_TX_FIRST_LINE, // starts just past transport header
0 // filled in from last_line register
};
dbsm_t dsp_tx_sm; // the state machine
/*
* ================================================================
* configure DSP RX double buffering state machine (dsp -> eth)
* ================================================================
*/
static const uint32_t rx_ctrl_word = 1 << 16;
// DSP Rx writes ethernet header words
#define DSP_RX_FIRST_LINE sizeof(rx_ctrl_word)/sizeof(uint32_t)
static bool dbsm_rx_inspector(dbsm_t *sm, int buf_this){
size_t num_lines = buffer_pool_status->last_line[buf_this]-DSP_RX_FIRST_LINE;
((uint32_t*)buffer_ram(buf_this))[0] = (num_lines*sizeof(uint32_t)) | (1 << 16);
return false;
}
// receive from DSP
buf_cmd_args_t dsp_rx_recv_args = {
PORT_DSP,
DSP_RX_FIRST_LINE,
BP_LAST_LINE
};
// send to ETH
buf_cmd_args_t dsp_rx_send_args = {
PORT_ETH,
0, // starts with ethernet header in line 0
0, // filled in from list_line register
};
dbsm_t dsp_rx_sm; // the state machine
// The mac address of the host we're sending to.
eth_mac_addr_t host_mac_addr;
static void setup_network(void);
// ----------------------------------------------------------------
// the fast-path setup global variables
// ----------------------------------------------------------------
static eth_mac_addr_t fp_mac_addr_src, fp_mac_addr_dst;
static struct socket_address fp_socket_src, fp_socket_dst;
// ----------------------------------------------------------------
void start_rx_streaming_cmd(void);
void stop_rx_cmd(void);
static void print_ip_addr(const void *t){
uint8_t *p = (uint8_t *)t;
printf("%d.%d.%d.%d", p[0], p[1], p[2], p[3]);
}
void handle_udp_data_packet(
struct socket_address src, struct socket_address dst,
unsigned char *payload, int payload_len
){
//its a tiny payload, load the fast-path variables
fp_mac_addr_src = *ethernet_mac_addr();
arp_cache_lookup_mac(&src.addr, &fp_mac_addr_dst);
fp_socket_src = dst;
fp_socket_dst = src;
printf("Storing for fast path:\n");
printf(" source mac addr: ");
print_mac_addr(fp_mac_addr_src.addr); newline();
printf(" source ip addr: ");
print_ip_addr(&fp_socket_src.addr); newline();
printf(" source udp port: %d\n", fp_socket_src.port);
printf(" destination mac addr: ");
print_mac_addr(fp_mac_addr_dst.addr); newline();
printf(" destination ip addr: ");
print_ip_addr(&fp_socket_dst.addr); newline();
printf(" destination udp port: %d\n", fp_socket_dst.port);
newline();
//setup network and vrt
setup_network();
// kick off the state machine
dbsm_start(&dsp_rx_sm);
}
#define OTW_GPIO_BANK_TO_NUM(bank) \
(((bank) == USRP2_DIR_RX)? (GPIO_RX_BANK) : (GPIO_TX_BANK))
//setup the output data
static usrp2_ctrl_data_t ctrl_data_out;
static struct socket_address i2c_src;
static struct socket_address spi_src;
static volatile bool i2c_done = false;
void i2c_read_done_callback(void) {
//printf("I2C read done callback\n");
i2c_async_data_ready(ctrl_data_out.data.i2c_args.data);
i2c_done = true;
i2c_register_callback(0);
}
void i2c_write_done_callback(void) {
//printf("I2C write done callback\n");
i2c_done = true;
i2c_register_callback(0);
}
static volatile bool spi_done = false;
static volatile uint32_t spi_readback_data;
void get_spi_readback_data(void) {
ctrl_data_out.data.spi_args.data = spi_get_data();
spi_done = true;
spi_register_callback(0);
}
void handle_udp_ctrl_packet(
struct socket_address src, struct socket_address dst,
unsigned char *payload, int payload_len
){
//printf("Got ctrl packet #words: %d\n", (int)payload_len);
const usrp2_ctrl_data_t *ctrl_data_in = (usrp2_ctrl_data_t *)payload;
uint32_t ctrl_data_in_id = ctrl_data_in->id;
//ensure that the protocol versions match
if (payload_len >= sizeof(uint32_t) && ctrl_data_in->proto_ver != USRP2_FW_COMPAT_NUM){
printf("!Error in control packet handler: Expected compatibility number %d, but got %d\n",
USRP2_FW_COMPAT_NUM, ctrl_data_in->proto_ver
);
ctrl_data_in_id = USRP2_CTRL_ID_WAZZUP_BRO;
}
//ensure that this is not a short packet
if (payload_len < sizeof(usrp2_ctrl_data_t)){
printf("!Error in control packet handler: Expected payload length %d, but got %d\n",
(int)sizeof(usrp2_ctrl_data_t), payload_len
);
ctrl_data_in_id = USRP2_CTRL_ID_HUH_WHAT;
}
//setup the output data
ctrl_data_out.proto_ver = USRP2_FW_COMPAT_NUM;
ctrl_data_out.id=USRP2_CTRL_ID_HUH_WHAT;
ctrl_data_out.seq=ctrl_data_in->seq;
//handle the data based on the id
switch(ctrl_data_in_id){
/*******************************************************************
* Addressing
******************************************************************/
case USRP2_CTRL_ID_WAZZUP_BRO:
ctrl_data_out.id = USRP2_CTRL_ID_WAZZUP_DUDE;
memcpy(&ctrl_data_out.data.ip_addr, get_ip_addr(), sizeof(struct ip_addr));
send_udp_pkt(USRP2_UDP_CTRL_PORT, src, &ctrl_data_out, sizeof(ctrl_data_out));
break;
/*******************************************************************
* SPI
******************************************************************/
case USRP2_CTRL_ID_TRANSACT_ME_SOME_SPI_BRO:{
//transact
bool success = spi_async_transact(
//(ctrl_data_in->data.spi_args.readback == 0)? SPI_TXONLY : SPI_TXRX,
ctrl_data_in->data.spi_args.dev, //which device
ctrl_data_in->data.spi_args.data, //32 bit data
ctrl_data_in->data.spi_args.num_bits, //length in bits
(ctrl_data_in->data.spi_args.mosi_edge == USRP2_CLK_EDGE_RISE)? SPIF_PUSH_FALL : SPIF_PUSH_RISE | //flags
(ctrl_data_in->data.spi_args.miso_edge == USRP2_CLK_EDGE_RISE)? SPIF_LATCH_RISE : SPIF_LATCH_FALL,
get_spi_readback_data //callback
);
//load output
ctrl_data_out.id = USRP2_CTRL_ID_OMG_TRANSACTED_SPI_DUDE;
spi_src = src;
}
// send_udp_pkt(USRP2_UDP_CTRL_PORT, src, &ctrl_data_out, sizeof(ctrl_data_out));
break;
/*******************************************************************
* I2C
******************************************************************/
case USRP2_CTRL_ID_DO_AN_I2C_READ_FOR_ME_BRO:{
uint8_t num_bytes = ctrl_data_in->data.i2c_args.bytes;
i2c_register_callback(i2c_read_done_callback);
i2c_async_read(
ctrl_data_in->data.i2c_args.addr,
num_bytes
);
i2c_src = src;
// i2c_dst = dst;
ctrl_data_out.id = USRP2_CTRL_ID_HERES_THE_I2C_DATA_DUDE;
ctrl_data_out.data.i2c_args.bytes = num_bytes;
}
break;
case USRP2_CTRL_ID_WRITE_THESE_I2C_VALUES_BRO:{
uint8_t num_bytes = ctrl_data_in->data.i2c_args.bytes;
i2c_register_callback(i2c_read_done_callback);
i2c_async_write(
ctrl_data_in->data.i2c_args.addr,
ctrl_data_in->data.i2c_args.data,
num_bytes
);
i2c_src = src;
// i2c_dst = dst;
ctrl_data_out.id = USRP2_CTRL_ID_COOL_IM_DONE_I2C_WRITE_DUDE;
ctrl_data_out.data.i2c_args.bytes = num_bytes;
}
break;
/*******************************************************************
* Peek and Poke Register
******************************************************************/
case USRP2_CTRL_ID_POKE_THIS_REGISTER_FOR_ME_BRO:
if (0){//ctrl_data_in->data.poke_args.addr < 0xC000){
printf("error! tried to poke into 0x%x\n", ctrl_data_in->data.poke_args.addr);
}
else switch(ctrl_data_in->data.poke_args.num_bytes){
case sizeof(uint64_t):
*((uint32_t *) ctrl_data_in->data.poke_args.addrhi) = (uint32_t)ctrl_data_in->data.poke_args.datahi;
//continue to uint32_t for low addr:
case sizeof(uint32_t):
*((uint32_t *) ctrl_data_in->data.poke_args.addr) = (uint32_t)ctrl_data_in->data.poke_args.data;
break;
case sizeof(uint16_t):
*((uint16_t *) ctrl_data_in->data.poke_args.addr) = (uint16_t)ctrl_data_in->data.poke_args.data;
break;
case sizeof(uint8_t):
*((uint8_t *) ctrl_data_in->data.poke_args.addr) = (uint8_t)ctrl_data_in->data.poke_args.data;
break;
}
ctrl_data_out.id = USRP2_CTRL_ID_OMG_POKED_REGISTER_SO_BAD_DUDE;
send_udp_pkt(USRP2_UDP_CTRL_PORT, src, &ctrl_data_out, sizeof(ctrl_data_out));
break;
case USRP2_CTRL_ID_PEEK_AT_THIS_REGISTER_FOR_ME_BRO:
switch(ctrl_data_in->data.poke_args.num_bytes){
case sizeof(uint64_t):
ctrl_data_out.data.poke_args.datahi = *((uint32_t *) ctrl_data_in->data.poke_args.addrhi);
//continue to uint32_t for low addr:
case sizeof(uint32_t):
ctrl_data_out.data.poke_args.data = *((uint32_t *) ctrl_data_in->data.poke_args.addr);
break;
case sizeof(uint16_t):
ctrl_data_out.data.poke_args.data = *((uint16_t *) ctrl_data_in->data.poke_args.addr);
break;
case sizeof(uint8_t):
ctrl_data_out.data.poke_args.data = *((uint8_t *) ctrl_data_in->data.poke_args.addr);
break;
}
ctrl_data_out.id = USRP2_CTRL_ID_WOAH_I_DEFINITELY_PEEKED_IT_DUDE;
send_udp_pkt(USRP2_UDP_CTRL_PORT, src, &ctrl_data_out, sizeof(ctrl_data_out));
break;
case USRP2_CTRL_ID_SO_LIKE_CAN_YOU_READ_THIS_UART_BRO:{
//executes a readline()-style read, up to num_bytes long, up to and including newline
int num_bytes = ctrl_data_in->data.uart_args.bytes;
if(num_bytes > 20) num_bytes = 20;
num_bytes = fngets_timeout(ctrl_data_in->data.uart_args.dev, (char *) ctrl_data_out.data.uart_args.data, num_bytes);
ctrl_data_out.id = USRP2_CTRL_ID_I_HELLA_READ_THAT_UART_DUDE;
ctrl_data_out.data.uart_args.bytes = num_bytes;
break;
}
case USRP2_CTRL_ID_HEY_WRITE_THIS_UART_FOR_ME_BRO:{
int num_bytes = ctrl_data_in->data.uart_args.bytes;
if(num_bytes > 20) num_bytes = 20;
//before we write to the UART, we flush the receive buffer
//this assumes that we're interested in the reply
hal_uart_rx_flush(ctrl_data_in->data.uart_args.dev);
fnputstr(ctrl_data_in->data.uart_args.dev, (char *) ctrl_data_in->data.uart_args.data, num_bytes);
ctrl_data_out.id = USRP2_CTRL_ID_MAN_I_TOTALLY_WROTE_THAT_UART_DUDE;
ctrl_data_out.data.uart_args.bytes = num_bytes;
break;
}
default:
ctrl_data_out.id = USRP2_CTRL_ID_HUH_WHAT;
send_udp_pkt(USRP2_UDP_CTRL_PORT, src, &ctrl_data_out, sizeof(ctrl_data_out));
}
}
/*
* Called when an ethernet packet is received.
* Return true if we handled it here, otherwise
* it'll be passed on to the DSP Tx pipe
*/
static bool
eth_pkt_inspector(dbsm_t *sm, int bufno)
{
//point me to the ethernet frame
uint32_t *buff = (uint32_t *)buffer_ram(bufno);
//treat this as fast-path data?
// We have to do this operation as fast as possible.
// Therefore, we do not check all the headers,
// just check that the udp port matches
// and that the vrt header is non zero.
// In the future, a hardware state machine will do this...
if ( //warning! magic numbers approaching....
(((buff + ((2 + 14 + 20)/sizeof(uint32_t)))[0] & 0xffff) == USRP2_UDP_DATA_PORT) &&
((buff + ((2 + 14 + 20 + 8)/sizeof(uint32_t)))[1] != USRP2_INVALID_VRT_HEADER)
) return false;
//test if its an ip recovery packet
typedef struct{
padded_eth_hdr_t eth_hdr;
char code[4];
union {
struct ip_addr ip_addr;
} data;
}recovery_packet_t;
recovery_packet_t *recovery_packet = (recovery_packet_t *)buff;
if (recovery_packet->eth_hdr.ethertype == 0xbeee && strncmp(recovery_packet->code, "addr", 4) == 0){
printf("Got ip recovery packet: "); print_ip_addr(&recovery_packet->data.ip_addr); newline();
set_ip_addr(&recovery_packet->data.ip_addr);
return true;
}
//pass it to the slow-path handler
size_t len = buffer_pool_status->last_line[bufno] - 3;
handle_eth_packet(buff, len);
return true;
}
//------------------------------------------------------------------
/*
* 1's complement sum for IP and UDP headers
*
* init chksum to zero to start.
*/
static unsigned int
CHKSUM(unsigned int x, unsigned int *chksum)
{
*chksum += x;
*chksum = (*chksum & 0xffff) + (*chksum>>16);
*chksum = (*chksum & 0xffff) + (*chksum>>16);
return x;
}
/*
* Called when eth phy state changes (w/ interrupts disabled)
*/
volatile bool link_is_up = false; // eth handler sets this
void
link_changed_callback(int speed)
{
link_is_up = speed != 0;
hal_set_leds(link_is_up ? LED_RJ45 : 0x0, LED_RJ45);
printf("\neth link changed: speed = %d\n", speed);
if (link_is_up) send_gratuitous_arp();
}
static void setup_network(void){
//setup ethernet header machine
sr_udp_sm->eth_hdr.mac_dst_0_1 = (fp_mac_addr_dst.addr[0] << 8) | fp_mac_addr_dst.addr[1];
sr_udp_sm->eth_hdr.mac_dst_2_3 = (fp_mac_addr_dst.addr[2] << 8) | fp_mac_addr_dst.addr[3];
sr_udp_sm->eth_hdr.mac_dst_4_5 = (fp_mac_addr_dst.addr[4] << 8) | fp_mac_addr_dst.addr[5];
sr_udp_sm->eth_hdr.mac_src_0_1 = (fp_mac_addr_src.addr[0] << 8) | fp_mac_addr_src.addr[1];
sr_udp_sm->eth_hdr.mac_src_2_3 = (fp_mac_addr_src.addr[2] << 8) | fp_mac_addr_src.addr[3];
sr_udp_sm->eth_hdr.mac_src_4_5 = (fp_mac_addr_src.addr[4] << 8) | fp_mac_addr_src.addr[5];
sr_udp_sm->eth_hdr.ether_type = ETHERTYPE_IPV4;
//setup ip header machine
unsigned int chksum = 0;
sr_udp_sm->ip_hdr.ver_ihl_tos = CHKSUM(0x4500, &chksum); // IPV4, 5 words of header (20 bytes), TOS=0
sr_udp_sm->ip_hdr.total_length = UDP_SM_INS_IP_LEN; // Don't checksum this line in SW
sr_udp_sm->ip_hdr.identification = CHKSUM(0x0000, &chksum); // ID
sr_udp_sm->ip_hdr.flags_frag_off = CHKSUM(0x4000, &chksum); // don't fragment
sr_udp_sm->ip_hdr.ttl_proto = CHKSUM(0x2011, &chksum); // TTL=32, protocol = UDP (17 decimal)
//sr_udp_sm->ip_hdr.checksum .... filled in below
uint32_t src_ip_addr = fp_socket_src.addr.addr;
uint32_t dst_ip_addr = fp_socket_dst.addr.addr;
sr_udp_sm->ip_hdr.src_addr_high = CHKSUM(src_ip_addr >> 16, &chksum); // IP src high
sr_udp_sm->ip_hdr.src_addr_low = CHKSUM(src_ip_addr & 0xffff, &chksum); // IP src low
sr_udp_sm->ip_hdr.dst_addr_high = CHKSUM(dst_ip_addr >> 16, &chksum); // IP dst high
sr_udp_sm->ip_hdr.dst_addr_low = CHKSUM(dst_ip_addr & 0xffff, &chksum); // IP dst low
sr_udp_sm->ip_hdr.checksum = UDP_SM_INS_IP_HDR_CHKSUM | (chksum & 0xffff);
//setup the udp header machine
sr_udp_sm->udp_hdr.src_port = fp_socket_src.port;
sr_udp_sm->udp_hdr.dst_port = fp_socket_dst.port;
sr_udp_sm->udp_hdr.length = UDP_SM_INS_UDP_LEN;
sr_udp_sm->udp_hdr.checksum = UDP_SM_LAST_WORD; // zero UDP checksum
}
inline static void
buffer_irq_handler(unsigned irq)
{
uint32_t status = buffer_pool_status->status;
dbsm_process_status(&dsp_tx_sm, status);
dbsm_process_status(&dsp_rx_sm, status);
}
int
main(void)
{
u2_init();
//we do this to see if we should set a default ip addr or not
#ifdef USRP2P
bool safe_fw = find_safe_booted_flag();
set_safe_booted_flag(0);
if(safe_fw) {
set_default_ip_addr();
set_default_mac_addr();
}
#endif
putstr("\nTxRx-NEWETH\n");
print_mac_addr(ethernet_mac_addr()->addr);
newline();
print_ip_addr(get_ip_addr()); newline();
printf("FPGA compatibility number: %d\n", USRP2_FPGA_COMPAT_NUM);
printf("Firmware compatibility number: %d\n", USRP2_FW_COMPAT_NUM);
//1) register the addresses into the network stack
register_mac_addr(ethernet_mac_addr());
register_ip_addr(get_ip_addr());
//2) register callbacks for udp ports we service
register_udp_listener(USRP2_UDP_CTRL_PORT, handle_udp_ctrl_packet);
register_udp_listener(USRP2_UDP_DATA_PORT, handle_udp_data_packet);
register_udp_listener(USRP2_UDP_UPDATE_PORT, handle_udp_fw_update_packet);
//3) setup ethernet hardware to bring the link up
ethernet_register_link_changed_callback(link_changed_callback);
ethernet_init();
// initialize double buffering state machine for ethernet -> DSP Tx
dbsm_init(&dsp_tx_sm, DSP_TX_BUF_0,
&dsp_tx_recv_args, &dsp_tx_send_args,
eth_pkt_inspector);
// initialize double buffering state machine for DSP RX -> Ethernet
dbsm_init(&dsp_rx_sm, DSP_RX_BUF_0,
&dsp_rx_recv_args, &dsp_rx_send_args,
dbsm_rx_inspector);
sr_tx_ctrl->clear_state = 1;
bp_clear_buf(DSP_TX_BUF_0);
bp_clear_buf(DSP_TX_BUF_1);
// kick off the state machine
dbsm_start(&dsp_tx_sm);
//int which = 0;
while(1){
// hal_gpio_write(GPIO_TX_BANK, which, 0x8000);
// which ^= 0x8000;
buffer_irq_handler(0);
if(i2c_done) {
i2c_done = false;
send_udp_pkt(USRP2_UDP_CTRL_PORT, i2c_src, &ctrl_data_out, sizeof(ctrl_data_out));
//printf("Sending UDP packet from main loop for I2C...\n");
}
if(spi_done) {
spi_done = false;
send_udp_pkt(USRP2_UDP_CTRL_PORT, spi_src, &ctrl_data_out, sizeof(ctrl_data_out));
}
int pending = pic_regs->pending; // poll for under or overrun
if (pending & PIC_UNDERRUN_INT){
//dbsm_handle_tx_underrun(&dsp_tx_sm);
pic_regs->pending = PIC_UNDERRUN_INT; // clear interrupt
putchar('U');
}
if (pending & PIC_OVERRUN_INT){
//dbsm_handle_rx_overrun(&dsp_rx_sm);
pic_regs->pending = PIC_OVERRUN_INT; // clear pending interrupt
// FIXME Figure out how to handle this robustly.
// Any buffers that are emptying should be allowed to drain...
putchar('O');
}
}
}