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//
// Copyright 2010-2014 Ettus Research LLC
//
// 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 <http://www.gnu.org/licenses/>.
//
#include "x300_dac_ctrl.hpp"
#include "x300_regs.hpp"
#include <uhd/types/time_spec.hpp>
#include <uhd/utils/msg.hpp>
#include <uhd/utils/log.hpp>
#include <uhd/utils/safe_call.hpp>
#include <uhd/exception.hpp>
#include <boost/foreach.hpp>
#include <boost/thread/thread.hpp> //sleep
#define X300_DAC_FRONTEND_SYNC_FAILURE_FATAL
using namespace uhd;
#define write_ad9146_reg(addr, data) \
_iface->write_spi(_slaveno, spi_config_t::EDGE_RISE, ((addr) << 8) | (data), 16)
#define read_ad9146_reg(addr) \
(_iface->read_spi(_slaveno, spi_config_t::EDGE_RISE, ((addr) << 8) | (1 << 15), 16) & 0xff)
x300_dac_ctrl::~x300_dac_ctrl(void){
/* NOP */
}
/*!
* A X300 codec control specific to the ad9146 ic.
*/
class x300_dac_ctrl_impl : public x300_dac_ctrl
{
public:
x300_dac_ctrl_impl(uhd::spi_iface::sptr iface, const size_t slaveno, const double refclk):
_iface(iface), _slaveno(slaveno), _refclk(refclk)
{
//Power up all DAC subsystems
write_ad9146_reg(0x01, 0x10); //Up: I DAC, Q DAC, Receiver, Voltage Ref, Clocks
write_ad9146_reg(0x02, 0x00); //No extended delays. Up: Voltage Ref, PLL, DAC, FIFO, Filters
reset();
}
~x300_dac_ctrl_impl(void)
{
UHD_SAFE_CALL
(
//Power down all DAC subsystems
write_ad9146_reg(0x01, 0xEF); //Down: I DAC, Q DAC, Receiver, Voltage Ref, Clocks
write_ad9146_reg(0x02, 0x1F); //No extended delays. Down: Voltage Ref, PLL, DAC, FIFO, Filters
)
}
void reset()
{
//ADI recommendations:
//- soft reset the chip before configuration
//- put the chip in sleep mode during configuration and wake it up when done
//- configure synchronization settings when sleeping
_soft_reset();
_sleep_mode(true);
_init();
//We run backend sync regardless of whether we need to sync multiple DACs
//because we use the internal DAC FIFO to meet system synchronous timing
//and we need to guarantee that the FIFO is not empty.
_backend_sync();
_sleep_mode(false);
}
void verify_sync()
{
_check_pll();
_check_dac_sync();
#ifdef X300_DAC_FRONTEND_SYNC_FAILURE_FATAL
_check_frontend_sync(true);
#else
_check_frontend_sync(false);
#endif
}
//
// Setup all non-synchronization related DAC parameters
//
void _init()
{
write_ad9146_reg(0x1e, 0x01); //Datasheet: "Set 1 for proper operation"
write_ad9146_reg(0x06, 0xFF); //Clear all event flags
// Calculate N0 to be VCO friendly.
// Aim for VCO between 1 and 2GHz, assert otherwise.
const int N1 = 4;
int N0_val, N0;
for (N0_val = 0; N0_val < 3; N0_val++)
{
N0 = (1 << N0_val); //1, 2, 4
if ((_refclk * N0 * N1) >= 1e9) break;
}
UHD_ASSERT_THROW((_refclk * N0 * N1) >= 1e9);
UHD_ASSERT_THROW((_refclk * N0 * N1) <= 2e9);
// Start PLL
write_ad9146_reg(0x06, 0xC0); //Clear PLL event flags
write_ad9146_reg(0x0C, 0xD1); // Narrow PLL loop filter, Midrange charge pump.
write_ad9146_reg(0x0D, 0xD1 | (N0_val << 2)); // N1=4, N2=16, N0 as calculated
write_ad9146_reg(0x0A, 0xCF); // Auto init VCO band training as per datasheet
write_ad9146_reg(0x0A, 0xA0); // See above.
_check_pll();
// Configure digital interface settings
// Bypass DCI delay. We center the clock edge in the data
// valid window in the FPGA by phase shifting the DCI going
// to the DAC.
write_ad9146_reg(0x16, 0x04);
// 2's comp, I first, byte wide interface
write_ad9146_reg(0x03, 0x00);
// FPGA wants I,Q in the sample word:
// - First transaction goes into low bits
// - Second transaction goes into high bits
// therefore, we want Q to go first (bit 6 == 1)
write_ad9146_reg(0x03, (1 << 6)); //2s comp, i first, byte mode
// Configure interpolation filters
write_ad9146_reg(0x1C, 0x00); // Configure HB1
write_ad9146_reg(0x1D, 0x00); // Configure HB2
write_ad9146_reg(0x1B, 0xE4); // Bypass: Modulator, InvSinc, IQ Bal
// Disable sync mode by default (may get turned on later)
write_ad9146_reg(0x10, 0x40); // Disable SYNC mode.
}
//
// Attempt to synchronize AD9146's
//
void _backend_sync(void)
{
write_ad9146_reg(0x10, 0x40); // Disable SYNC mode to reset state machines.
write_ad9146_reg(0x06, 0x30); // Clear Sync event flags
//SYNC Settings:
//- SYNC = Enabled
//- Data Rate Mode: Synchronize at the rate at which data is consumed and not at
// the granularity of the FIFO
//- Falling edge sync: For the X300, DACCLK is generated using RefClk. Within the
// DAC, the RefClk is sampled by DACCLK to sync interpolation
// stages across multiple DACs. To ensure that we capture the
// RefClk when it is not transitioning, we sample on the falling
// edge of DACCLK
//- Averaging = MAX
write_ad9146_reg(0x10, 0xC7); // Enable SYNC mode. Falling edge sync. Averaging set to 128.
//Wait for backend SYNC state machine to lock before proceeding. This guarantees that the
//inputs and output of the FIFO have synchronized clocks
_check_dac_sync();
//FIFO write pointer offset
//One of ADI's requirements to use data-rate synchronization in PLL mode is to meet
//setup and hold times for RefClk -> DCI clock which we *do not* currently meet in
//the FPGA. The DCI clock reaches a full RefClk cycle later which results in the
//FIFO popping before the first push. This results in a steady-state FIFO fullness
//of pointer - 1. To reach the optimal FIFO fullness of 4 we set the pointer to 5.
//FIXME: At some point we should meet timing on this interface
write_ad9146_reg(0x17, 0x05);
// We are requesting a soft FIFO align just to put the FIFO
// in a known state. The FRAME will actually do sync the
// FIFO correctly when a stream is created
write_ad9146_reg(0x18, 0x02); // Request soft FIFO align
write_ad9146_reg(0x18, 0x00); // (See above)
//Verify the FIFO thermometer
_check_frontend_sync(false); //FIFO sanity check
}
//
// Check for PLL lock. Fatal if not locked within timeout
//
void _check_pll()
{
// Verify PLL is Locked. 1 sec timeout.
// NOTE: Data sheet inconsistent about which pins give PLL lock status. FIXME!
const time_spec_t exit_time = time_spec_t::get_system_time() + time_spec_t(1.0);
while (true)
{
const size_t reg_e = read_ad9146_reg(0x0E); // PLL Status (Expect bit 7 = 1)
const size_t reg_6 = read_ad9146_reg(0x06); // Event Flags (Expect bit 7 = 0 and bit 6 = 1)
if ((((reg_e >> 7) & 0x1) == 0x1) && (((reg_6 >> 6) & 0x3) == 0x1))
break;
if (exit_time < time_spec_t::get_system_time())
throw uhd::runtime_error("x300_dac_ctrl: timeout waiting for DAC PLL to lock");
if (reg_6 & (1 << 7)) // Lock lost?
write_ad9146_reg(0x06, 0xC0); // Clear PLL event flags
boost::this_thread::sleep(boost::posix_time::milliseconds(10));
}
}
//
// Check for DAC sync. Fatal if not synced within timeout
//
void _check_dac_sync()
{
const time_spec_t exit_time = time_spec_t::get_system_time() + time_spec_t(1.0);
while (true)
{
boost::this_thread::sleep(boost::posix_time::milliseconds(1)); // wait for sync to complete
const size_t reg_12 = read_ad9146_reg(0x12); // Sync Status (Expect bit 7 = 0, bit 6 = 1)
const size_t reg_6 = read_ad9146_reg(0x06); // Event Flags (Expect bit 5 = 0 and bit 4 = 1)
if ((((reg_12 >> 6) & 0x3) == 0x1) && (((reg_6 >> 4) & 0x3) == 0x1))
break;
if (exit_time < time_spec_t::get_system_time())
throw uhd::runtime_error("x300_dac_ctrl: timeout waiting for backend synchronization");
if (reg_6 & (1 << 5))
write_ad9146_reg(0x06, 0x30); // Clear Sync event flags
#ifdef X300_DAC_RETRY_BACKEND_SYNC
if (reg_12 & (1 << 7)) // Sync acquired and lost?
write_ad9146_reg(0x10, 0xC7); // Enable SYNC mode. Falling edge sync. Averaging set to 128.
#endif
}
}
//
// Check FIFO thermometer.
//
void _check_frontend_sync(bool failure_is_fatal)
{
// Register 0x19 has a thermometer indicator of the FIFO depth
const size_t reg_19 = read_ad9146_reg(0x19);
if ((reg_19 & 0xFF) != 0xF) {
std::string msg((boost::format("x300_dac_ctrl: front-end sync failed. unexpected FIFO depth [0x%x]\n") % (reg_19 & 0xFF)).str());
if (failure_is_fatal) {
throw uhd::runtime_error(msg);
} else {
UHD_MSG(warning) << msg;
}
}
}
void _sleep_mode(bool sleep)
{
boost::uint8_t sleep_val = sleep ? (1<<7) : 0x00;
//Set sleep word and default fullscale value
write_ad9146_reg(0x41, sleep_val | 0x01); //I DAC
write_ad9146_reg(0x45, sleep_val | 0x01); //Q DAC
}
void _soft_reset()
{
write_ad9146_reg(0x00, 0x20); // Take DAC into reset.
write_ad9146_reg(0x00, 0x80); // Enable SPI reads and come out of reset
}
private:
uhd::spi_iface::sptr _iface;
const size_t _slaveno;
const double _refclk;
};
/***********************************************************************
* Public make function for the DAC control
**********************************************************************/
x300_dac_ctrl::sptr x300_dac_ctrl::make(uhd::spi_iface::sptr iface, const size_t slaveno, const double clock_rate)
{
return sptr(new x300_dac_ctrl_impl(iface, slaveno, clock_rate));
}
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