/*
* 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 "u2_init.h"
#include "memory_map.h"
#include "spi.h"
#include "hal_io.h"
#include "buffer_pool.h"
#include "pic.h"
#include "bool.h"
#include "ethernet.h"
#include "nonstdio.h"
#include "usrp2_eth_packet.h"
#include "dbsm.h"
#include "app_common_v2.h"
#include "memcpy_wa.h"
#include
#include
#include
#include
#include
#include
#include "sd.h"
#define FW_SETS_SEQNO 1 // define to 0 or 1 (FIXME must be 1 for now)
#if (FW_SETS_SEQNO)
static int fw_seqno; // used when f/w is filling in sequence numbers
#endif
/*
* 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)
* ================================================================
*/
// 4 lines of ethernet hdr + 1 line transport hdr + 2 lines (word0 + timestamp)
// DSP Tx reads word0 (flags) + timestamp followed by samples
#define DSP_TX_FIRST_LINE ((sizeof(u2_eth_hdr_t) + sizeof(u2_transport_hdr_t))/4)
// 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)
* ================================================================
*/
// 4 lines of ethernet hdr + 1 line transport hdr + 1 line (word0)
// DSP Rx writes timestamp followed by nlines_per_frame of samples
#define DSP_RX_FIRST_LINE ((sizeof(u2_eth_hdr_t) + sizeof(u2_transport_hdr_t))/4 + 1)
// 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.
u2_mac_addr_t host_mac_addr;
// variables for streaming mode
static bool streaming_p = false;
static unsigned int streaming_items_per_frame = 0;
static int streaming_frame_count = 0;
#define FRAMES_PER_CMD 1000
bool is_streaming(void){ return streaming_p; }
// ----------------------------------------------------------------
void
restart_streaming(void)
{
// setup RX DSP regs
dsp_rx_regs->clear_state = 1; // reset
streaming_p = true;
streaming_frame_count = FRAMES_PER_CMD;
dsp_rx_regs->rx_command =
MK_RX_CMD(FRAMES_PER_CMD * streaming_items_per_frame,
streaming_items_per_frame,
1, 1); // set "chain" bit
// kick off the state machine
dbsm_start(&dsp_rx_sm);
dsp_rx_regs->rx_time = 0; // enqueue first of two commands
// make sure this one and the rest have the "now" and "chain" bits set.
dsp_rx_regs->rx_command =
MK_RX_CMD(FRAMES_PER_CMD * streaming_items_per_frame,
streaming_items_per_frame,
1, 1);
dsp_rx_regs->rx_time = 0; // enqueue second command
}
void
start_rx_streaming_cmd(const u2_mac_addr_t *host, op_start_rx_streaming_t *p)
{
host_mac_addr = *host; // remember who we're sending to
/*
* Construct ethernet header and word0 and preload into two buffers
*/
u2_eth_packet_t pkt;
memset(&pkt, 0, sizeof(pkt));
pkt.ehdr.dst = *host;
pkt.ehdr.ethertype = U2_ETHERTYPE;
u2p_set_word0(&pkt.fixed, 0, 0);
// DSP RX will fill in timestamp
memcpy_wa(buffer_ram(DSP_RX_BUF_0), &pkt, sizeof(pkt));
memcpy_wa(buffer_ram(DSP_RX_BUF_1), &pkt, sizeof(pkt));
if (FW_SETS_SEQNO)
fw_seqno = 0;
streaming_items_per_frame = p->items_per_frame;
restart_streaming();
}
void
stop_rx_cmd(void)
{
streaming_p = false;
dsp_rx_regs->clear_state = 1; // flush cmd queue
bp_clear_buf(DSP_RX_BUF_0);
bp_clear_buf(DSP_RX_BUF_1);
}
static void
setup_tx()
{
dsp_tx_regs->clear_state = 1;
bp_clear_buf(DSP_TX_BUF_0);
bp_clear_buf(DSP_TX_BUF_1);
int tx_scale = 256;
int interp = 32;
// setup some defaults
dsp_tx_regs->freq = 0;
dsp_tx_regs->scale_iq = (tx_scale << 16) | tx_scale;
dsp_tx_regs->interp_rate = interp;
}
#if (FW_SETS_SEQNO)
/*
* Debugging ONLY. This will be handled by the tx_protocol_engine.
*
* This is called when the DSP Rx chain has filled in a packet.
* We set and increment the seqno, then return false, indicating
* that we didn't handle the packet. A bit of a kludge
* but it should work.
*/
bool
fw_sets_seqno_inspector(dbsm_t *sm, int buf_this) // returns false
{
uint32_t *p = buffer_ram(buf_this);
uint32_t seqno = fw_seqno++;
// KLUDGE all kinds of nasty magic numbers and embedded knowledge
uint32_t t = p[4];
t = (t & 0xffff00ff) | ((seqno & 0xff) << 8);
p[4] = t;
// queue up another rx command when required
if (streaming_p && --streaming_frame_count == 0){
streaming_frame_count = FRAMES_PER_CMD;
dsp_rx_regs->rx_time = 0;
}
return false; // we didn't handle the packet
}
#endif
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 test_ram()
{
int i,j,k;
output_regs->ram_page = 1<<10;
extram[0] = 0xDEADBEEF;
extram[1] = 0xF00D1234;
extram[7] = 0x76543210;
output_regs->ram_page = 2<<10;
extram[7] = 0x55555555;
extram[1] = 0xaaaaaaaa;
extram[0] = 0xeeeeeeee;
output_regs->ram_page = 1<<10;
i = extram[0];
k = extram[1];
j = extram[7];
if((i != 0xDEADBEEF)||(j!=0x76543210)||(k!=0xF00D1234)) {
puts("RAM FAIL1!\n");
puthex32_nl(i);
puthex32_nl(j);
puthex32_nl(k);
return 0;
}
output_regs->ram_page = 2<<10;
j = extram[7];
k = extram[1];
i = extram[0];
if((i != 0xeeeeeeee)||(j!=0x55555555)||(k!=0xaaaaaaaa)) {
puts("RAM FAIL2!\n");
puthex32_nl(i);
puthex32_nl(j);
puthex32_nl(k);
return 0;
}
return 1;
}
int test_sd()
{
int i = sd_init();
if(i==0) {
puts("FAILED INIT of Card\n");
return 0;
}
unsigned char buf[512];
i = sd_read_block(2048,buf);
if(i == 0) {
puts("READ Command Rejected\n");
return 0;
}
if((buf[0]==0xb8)&&(buf[1]==0x08)&&(buf[2]==0x00)&&(buf[3]==0x50))
;
else {
puts("Read bad data from SD Card\n");
return 0;
}
return 1;
}
int
main(void)
{
u2_init();
putstr("\nFactory Test\n");
print_mac_addr(ethernet_mac_addr()->addr);
newline();
if(test_sd())
puts("SD OK\n");
else {
puts("SD FAIL\n");
// hal_finish();
//return 0;
}
if(test_ram())
puts("RAM OK\n");
else {
puts("RAM FAIL\n");
hal_finish();
return 0;
}
print_mac_addr(ethernet_mac_addr()->addr);
newline();
output_regs->led_src = 0x7; // make bottom 3 controlled by HW
ethernet_register_link_changed_callback(link_changed_callback);
ethernet_init();
clocks_enable_tx_dboard(true,1);
clocks_mimo_config(MC_WE_LOCK_TO_SMA);
#if 0
// make bit 15 of Tx gpio's be a s/w output
hal_gpio_set_sel(GPIO_TX_BANK, 15, 's');
hal_gpio_set_ddr(GPIO_TX_BANK, 0x8000, 0x8000);
#endif
output_regs->debug_mux_ctrl = 1;
#if 0
hal_gpio_set_sels(GPIO_TX_BANK, "1111111111111111");
hal_gpio_set_sels(GPIO_RX_BANK, "1111111111111111");
hal_gpio_set_ddr(GPIO_TX_BANK, 0xffff, 0xffff);
hal_gpio_set_ddr(GPIO_RX_BANK, 0xffff, 0xffff);
#endif
// 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
if (FW_SETS_SEQNO){
dbsm_init(&dsp_rx_sm, DSP_RX_BUF_0,
&dsp_rx_recv_args, &dsp_rx_send_args,
fw_sets_seqno_inspector);
}
else {
dbsm_init(&dsp_rx_sm, DSP_RX_BUF_0,
&dsp_rx_recv_args, &dsp_rx_send_args,
dbsm_nop_inspector);
}
// tell app_common that this dbsm could be sending to the ethernet
ac_could_be_sending_to_eth = &dsp_rx_sm;
// program tx registers
setup_tx();
// 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);
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...
if (streaming_p){
// restart_streaming();
// FIXME report error
}
else {
// FIXME report error
}
putchar('O');
}
}
}