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/* -*- c++ -*- */
/*
* Copyright 2003,2004,2006 Free Software Foundation, Inc.
*
* This file is part of GNU Radio
*
* GNU Radio 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 2, or (at your option)
* any later version.
*
* GNU Radio 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 GNU Radio; see the file COPYING. If not, write to
* the Free Software Foundation, Inc., 51 Franklin Street,
* Boston, MA 02110-1301, USA.
*/
#ifndef INCLUDED_FPGA_REGS_STANDARD_H
#define INCLUDED_FPGA_REGS_STANDARD_H
// Register numbers 0 to 31 are reserved for use in fpga_regs_common.h.
// Registers 64 to 79 are available for custom FPGA builds.
// DDC / DUC
#define FR_INTERP_RATE 32 // [1,1024]
#define FR_DECIM_RATE 33 // [1,256]
// DDC center freq
#define FR_RX_FREQ_0 34
#define FR_RX_FREQ_1 35
#define FR_RX_FREQ_2 36
#define FR_RX_FREQ_3 37
// See below for DDC Starting Phase
// ------------------------------------------------------------------------
// configure FPGA Rx mux
//
// 3 2 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-----------------------+-------+-------+-------+-------+-+-----+
// | must be zero | Q3| I3| Q2| I2| Q1| I1| Q0| I0|Z| NCH |
// +-----------------------+-------+-------+-------+-------+-+-----+
//
// There are a maximum of 4 digital downconverters in the the FPGA.
// Each DDC has two 16-bit inputs, I and Q, and two 16-bit outputs, I & Q.
//
// DDC I inputs are specified by the two bit fields I3, I2, I1 & I0
//
// 0 = DDC input is from ADC 0
// 1 = DDC input is from ADC 1
// 2 = DDC input is from ADC 2
// 3 = DDC input is from ADC 3
//
// If Z == 1, all DDC Q inputs are set to zero
// If Z == 0, DDC Q inputs are specified by the two bit fields Q3, Q2, Q1 & Q0
//
// NCH specifies the number of complex channels that are sent across
// the USB. The legal values are 1, 2 or 4, corresponding to 2, 4 or
// 8 16-bit values.
#define FR_RX_MUX 38
// ------------------------------------------------------------------------
// configure FPGA Tx Mux.
//
// 3 2 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-----------------------+-------+-------+-------+-------+-+-----+
// | | DAC3 | DAC2 | DAC1 | DAC0 |0| NCH |
// +-----------------------------------------------+-------+-+-----+
//
// NCH specifies the number of complex channels that are sent across
// the USB. The legal values are 1 or 2, corresponding to 2 or 4
// 16-bit values.
//
// There are two interpolators with complex inputs and outputs.
// There are four DACs. (We use the DUC in each AD9862.)
//
// Each 4-bit DACx field specifies the source for the DAC and
// whether or not that DAC is enabled. Each subfield is coded
// like this:
//
// 3 2 1 0
// +-+-----+
// |E| N |
// +-+-----+
//
// Where E is set if the DAC is enabled, and N specifies which
// interpolator output is connected to this DAC.
//
// N which interp output
// --- -------------------
// 0 chan 0 I
// 1 chan 0 Q
// 2 chan 1 I
// 3 chan 1 Q
#define FR_TX_MUX 39
// ------------------------------------------------------------------------
// REFCLK control
//
// Control whether a reference clock is sent to the daughterboards,
// and what frequency. The refclk is sent on d'board i/o pin 0.
//
// 3 2 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-----------------------------------------------+-+------------+
// | Reserved (Must be zero) |E| DIVISOR |
// +-----------------------------------------------+-+------------+
//
// Bit 7 -- 1 turns on refclk, 0 allows IO use
// Bits 6:0 Divider value
#define FR_TX_A_REFCLK 40
#define FR_RX_A_REFCLK 41
#define FR_TX_B_REFCLK 42
#define FR_RX_B_REFCLK 43
# define bmFR_REFCLK_EN 0x80
# define bmFR_REFCLK_DIVISOR_MASK 0x7f
// ------------------------------------------------------------------------
// DDC Starting Phase
#define FR_RX_PHASE_0 44
#define FR_RX_PHASE_1 45
#define FR_RX_PHASE_2 46
#define FR_RX_PHASE_3 47
// ------------------------------------------------------------------------
// Tx data format control register
//
// 3 2 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-------------------------------------------------------+-------+
// | Reserved (Must be zero) | FMT |
// +-------------------------------------------------------+-------+
//
// FMT values:
#define FR_TX_FORMAT 48
# define bmFR_TX_FORMAT_16_IQ 0 // 16-bit I, 16-bit Q
// ------------------------------------------------------------------------
// Rx data format control register
//
// 3 2 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-----------------------------------------+-+-+---------+-------+
// | Reserved (Must be zero) |B|Q| WIDTH | SHIFT |
// +-----------------------------------------+-+-+---------+-------+
//
// FMT values:
#define FR_RX_FORMAT 49
# define bmFR_RX_FORMAT_SHIFT_MASK (0x0f << 0) // arithmetic right shift [0, 15]
# define bmFR_RX_FORMAT_SHIFT_SHIFT 0
# define bmFR_RX_FORMAT_WIDTH_MASK (0x1f << 4) // data width in bits [1, 16] (not all valid)
# define bmFR_RX_FORMAT_WIDTH_SHIFT 4
# define bmFR_RX_FORMAT_WANT_Q (0x1 << 9) // deliver both I & Q, else just I
# define bmFR_RX_FORMAT_BYPASS_HB (0x1 << 10) // bypass half-band filter
// The valid combinations currently are:
//
// B Q WIDTH SHIFT
// 0 1 16 0
// 0 1 8 8
// Possible future values of WIDTH = {4, 2, 1}
// 12 takes a bit more work, since we need to know packet alignment.
// ------------------------------------------------------------------------
// FIXME register numbers 50 to 63 are available
// ------------------------------------------------------------------------
// Registers 64 to 79 are reserved for user custom FPGA builds.
// The standard USRP software will not touch these.
#define FR_USER_0 64
#define FR_USER_1 65
#define FR_USER_2 66
#define FR_USER_3 67
#define FR_USER_4 68
#define FR_USER_5 69
#define FR_USER_6 70
#define FR_USER_7 71
#define FR_USER_8 72
#define FR_USER_9 73
#define FR_USER_10 74
#define FR_USER_11 75
#define FR_USER_12 76
#define FR_USER_13 77
#define FR_USER_14 78
#define FR_USER_15 79
//Registers needed for multi usrp master/slave configuration
//
//Rx Master/slave control register (FR_RX_MASTER_SLAVE = FR_USER_0)
//
#define FR_RX_MASTER_SLAVE 64
#define bitnoFR_RX_SYNC 0
#define bitnoFR_RX_SYNC_MASTER 1
#define bitnoFR_RX_SYNC_SLAVE 2
# define bmFR_RX_SYNC (1 <<bitnoFR_RX_SYNC) //1 If this is a master "sync now" and send sync to slave.
// If this is a slave "sync now" (testing purpose only)
// Sync is allmost the same as reset (clear all counters and buffers)
// except that the io outputs and settings don't get reset (otherwise it couldn't send the sync to the slave)
//0 Normal operation
# define bmFR_RX_SYNC_MASTER (1 <<bitnoFR_RX_SYNC_MASTER) //1 This is a rx sync master, output sync_rx on rx_a_io[15]
//0 This is not a rx sync master
# define bmFR_RX_SYNC_SLAVE (1 <<bitnoFR_RX_SYNC_SLAVE) //1 This is a rx sync slave, follow sync_rx on rx_a_io[bitnoFR_RX_SYNC_INPUT_IOPIN]
//0 This is not an rx sync slave.
//Caution The master settings will output values on the io lines.
//They inheritely enable these lines as output. If you have a daughtercard which uses these lines also as output then you will burn your usrp and daughtercard.
//If you set the slave bits then your usrp won't do anything if you don't connect a master.
// Rx Master/slave control register
//
// The way this is supposed to be used is connecting a (short) 16pin flatcable from an rx daughterboard in RXA master io_rx[8..15] to slave io_rx[8..15] on RXA of slave usrp
// This can be done with basic_rx boards or dbsrx boards
//dbsrx: connect master-J25 to slave-J25
//basic rx: connect J25 to slave-J25
//CAUTION: pay attention to the lineup of your connector.
//The red line (pin1) should be at the same side of the daughterboards on master and slave.
//If you turnaround the cable on one end you will burn your usrp.
//You cannot use a 16pin flatcable if you are using FLEX400 or FLEX2400 daughterboards, since these use a lot of the io pins.
//You can still link them but you must use only a 2pin or 1pin cable
//You can also use a 2-wire link. put a 2pin header on io[15],gnd of the master RXA daughterboard and connect it to io15,gnd of the slave RXA db.
//You can use a cable like the ones found with the leds on the mainbord of a PC.
//Make sure you don't twist the cable, otherwise you connect the sync output to ground.
//To be save you could also just use a single wire from master io[15] to slave io[15], but this is not optimal for signal integrity.
// Since rx_io[0] can normally be used as a refclk and is not exported on all daughterboards this line
// still has the refclk function if you use the master/slave setup (it is not touched by the master/slave settings).
// The master/slave circuitry will only use io pin 15 and does not touch any of the other io pins.
#define bitnoFR_RX_SYNC_INPUT_IOPIN 15
#define bmFR_RX_SYNC_INPUT_IOPIN (1<<bitnoFR_RX_SYNC_INPUT_IOPIN)
//TODO the output pin is still hardcoded in the verilog code, make it listen to the following define
#define bitnoFR_RX_SYNC_OUTPUT_IOPIN 15
#define bmFR_RX_SYNC_OUTPUT_IOPIN (1<<bitnoFR_RX_SYNC_OUTPUT_IOPIN)
// =======================================================================
// READBACK Registers
// =======================================================================
#define FR_RB_IO_RX_A_IO_TX_A 1 // read back a-side i/o pins
#define FR_RB_IO_RX_B_IO_TX_B 2 // read back b-side i/o pins
// ------------------------------------------------------------------------
// FPGA Capability register
//
// 3 2 1
// 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0 9 8 7 6 5 4 3 2 1 0
// +-----------------------------------------------+-+-----+-+-----+
// | Reserved (Must be zero) |T|NDUC |R|NDDC |
// +-----------------------------------------------+-+-----+-+-----+
//
// Bottom 4-bits are Rx capabilities
// Next 4-bits are Tx capabilities
#define FR_RB_CAPS 3
# define bmFR_RB_CAPS_NDDC_MASK (0x7 << 0) // # of digital down converters 0,1,2,4
# define bmFR_RB_CAPS_NDDC_SHIFT 0
# define bmFR_RB_CAPS_RX_HAS_HALFBAND (0x1 << 3)
# define bmFR_RB_CAPS_NDUC_MASK (0x7 << 4) // # of digital up converters 0,1,2
# define bmFR_RB_CAPS_NDUC_SHIFT 4
# define bmFR_RB_CAPS_TX_HAS_HALFBAND (0x1 << 7)
#endif /* INCLUDED_FPGA_REGS_STANDARD_H */
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