Hamlib/kit/dds60.c

/*
 *  Hamlib KIT backend - DDS-60 description
 *  Copyright (c) 2007 by Stephane Fillod
 *
 *	$Id: dds60.c,v 1.1 2007-10-23 21:56:30 fillods Exp $
 *
 *   This library 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 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 library; if not, write to the Free Software
 *   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 *
 */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include <stdlib.h>
#include <stdio.h>
#include "hamlib/rig.h"

#include "kit.h"
#include "parallel.h"
#include "token.h"


#define DDS60_MODES (RIG_MODE_AM)

#define DDS60_FUNC (RIG_FUNC_NONE)

#define DDS60_LEVEL_ALL (RIG_LEVEL_NONE)

#define DDS60_PARM_ALL (RIG_PARM_NONE)

#define DDS60_VFO (RIG_VFO_A)

/* defaults */
#define OSCFREQ 	MHz(30)
#define IFMIXFREQ	kHz(0)

#define PHASE_INCR	11.25

struct dds60_priv_data {
	freq_t osc_freq;
	freq_t if_mix_freq;
	int multiplier;
	unsigned phase_step;	/* as 11.25 deg steps */
};
#define TOK_OSCFREQ TOKEN_BACKEND(1)
#define TOK_IFMIXFREQ TOKEN_BACKEND(2)
#define TOK_MULTIPLIER TOKEN_BACKEND(3)
#define TOK_PHASE_MOD TOKEN_BACKEND(4)

static const struct confparams dds60_cfg_params[] = {
	{ TOK_OSCFREQ, "osc_freq", "Oscillator freq", "Oscillator frequency in Hz",
			"30000000", RIG_CONF_NUMERIC, { .n = { 0, MHz(180), 1 } }
	},
	{ TOK_IFMIXFREQ, "if_mix_freq", "IF", "IF mixing frequency in Hz",
			"0", RIG_CONF_NUMERIC, { .n = { 0, MHz(180), 1 } }
	},
	{ TOK_MULTIPLIER, "multiplier", "Multiplier", "Optional X6 multiplier",
			"1", RIG_CONF_CHECKBUTTON 
	},
	{ TOK_IFMIXFREQ, "phase_mod", "Phase Modulation", "Phase modulation in degrees",
			"0", RIG_CONF_NUMERIC, { .n = { 0, 360, PHASE_INCR } }
	},
	{ RIG_CONF_END, NULL, }
};

static int dds60_init(RIG *rig);
static int dds60_cleanup(RIG *rig);
static int dds60_open(RIG *rig);
static int dds60_set_freq(RIG *rig, vfo_t vfo, freq_t freq);
static int dds60_set_conf(RIG *rig, token_t token, const char *val);
static int dds60_get_conf(RIG *rig, token_t token, char *val);

/*
 * The DDS-60 kit exists with a AD9851 chip (60 MHz),
 * as well as with the AD9850 chip (30 MHz) (no multiplier).
 * There is an option to enable/disable the AD9851 X6 multiplier. 
 * http://www.amqrp.org/kits/dds60/
 * http://www.analog.com/en/prod/0,2877,AD9851,00.html
 *
 * The receiver is controlled via the parallel port (D0,D1,D2).
 */

const struct rig_caps dds60_caps = {
.rig_model =  RIG_MODEL_DDS60,
.model_name = "DDS-60",
.mfg_name =  "AmQRP",
.version =  "0.1",
.copyright =  "LGPL",
.status =  RIG_STATUS_ALPHA,
.rig_type =  RIG_TYPE_TUNER,
.ptt_type =  RIG_PTT_NONE,
.dcd_type =  RIG_DCD_NONE,
.port_type =  RIG_PORT_PARALLEL,
.write_delay =  0,
.post_write_delay =  0,
.timeout =  200,
.retry = 0,

.has_get_func =  DDS60_FUNC,
.has_set_func =  DDS60_FUNC,
.has_get_level =  DDS60_LEVEL_ALL,
.has_set_level =  RIG_LEVEL_SET(DDS60_LEVEL_ALL),
.has_get_parm =  DDS60_PARM_ALL,
.has_set_parm =  RIG_PARM_SET(DDS60_PARM_ALL),
.level_gran =  {},
.parm_gran =  {},
.ctcss_list =  NULL,
.dcs_list =  NULL,
.preamp =   { RIG_DBLST_END },
.attenuator =   { RIG_DBLST_END },
.max_rit =  Hz(0),
.max_xit =  Hz(0),
.max_ifshift =  Hz(0),
.targetable_vfo =  0,
.transceive =  RIG_TRN_OFF,
.bank_qty =   0,
.chan_desc_sz =  0,

.chan_list =  { RIG_CHAN_END },

.rx_range_list1 =  {
    {MHz(1),MHz(60),DDS60_MODES,-1,-1,DDS60_VFO},	/* TBC */
	RIG_FRNG_END,
  },
.tx_range_list1 =  { RIG_FRNG_END, },
.rx_range_list2 =  {
    {MHz(1),MHz(60),DDS60_MODES,-1,-1,DDS60_VFO},
	RIG_FRNG_END,
  },
.tx_range_list2 =  { RIG_FRNG_END, },
.tuning_steps =  {
	 {DDS60_MODES,1},
	 RIG_TS_END,
	},
        /* mode/filter list, remember: order matters! */
.filters =  {
		{DDS60_MODES, kHz(12)},
		RIG_FLT_END,
	},
.cfgparams =  dds60_cfg_params,

.rig_init =  dds60_init,
.rig_cleanup =  dds60_cleanup,
.rig_open =  dds60_open,
.set_conf =  dds60_set_conf,
.get_conf =  dds60_get_conf,

.set_freq =  dds60_set_freq,
};


int dds60_init(RIG *rig)
{
	struct dds60_priv_data *priv;

	priv = (struct dds60_priv_data*)malloc(sizeof(struct dds60_priv_data));
	if (!priv) {
		/* whoops! memory shortage! */
		return -RIG_ENOMEM;
	}

	rig->state.priv = (void*)priv;

	priv->osc_freq = OSCFREQ;
	priv->if_mix_freq = IFMIXFREQ;
	priv->multiplier = 1;
	priv->phase_step = 0;

	return RIG_OK;
}

int dds60_cleanup(RIG *rig)
{
	if (!rig)
		return -RIG_EINVAL;

	if (rig->state.priv)
		free(rig->state.priv);
	rig->state.priv = NULL;

	return RIG_OK;
}


/*
 * Assumes rig!=NULL, rig->state.priv!=NULL
 */
int dds60_set_conf(RIG *rig, token_t token, const char *val)
{
	struct dds60_priv_data *priv;
	float phase;

	priv = (struct dds60_priv_data*)rig->state.priv;

	switch(token) {
		case TOK_OSCFREQ:
			sscanf(val, "%"SCNfreq, &priv->osc_freq);
			break;
		case TOK_IFMIXFREQ:
			sscanf(val, "%"SCNfreq, &priv->if_mix_freq);
			break;
		case TOK_MULTIPLIER:
			sscanf(val, "%d", &priv->multiplier);
			break;
		case TOK_PHASE_MOD:
			sscanf(val, "%f", &phase);
			priv->phase_step = ((unsigned)((phase+PHASE_INCR/2) / PHASE_INCR))%32;
			break;
		default:
			return -RIG_EINVAL;
	}
	return RIG_OK;
}

/*
 * assumes rig!=NULL,
 * Assumes rig!=NULL, rig->state.priv!=NULL
 *  and val points to a buffer big enough to hold the conf value.
 */
int dds60_get_conf(RIG *rig, token_t token, char *val)
{
	struct dds60_priv_data *priv;

	priv = (struct dds60_priv_data*)rig->state.priv;

	switch(token) {
		case TOK_OSCFREQ:
			sprintf(val, "%"PRIfreq, priv->osc_freq);
			break;
		case TOK_IFMIXFREQ:
			sprintf(val, "%"PRIfreq, priv->if_mix_freq);
			break;
		case TOK_MULTIPLIER:
			sprintf(val, "%d", priv->multiplier);
			break;
		case TOK_PHASE_MOD:
			sprintf(val, "%f", priv->phase_step*PHASE_INCR);
			break;
		default:
			return -RIG_EINVAL;
	}
	return RIG_OK;
}


#define DATA  0x01  /* d0 */
#define CLOCK 0x02  /* d1 */
#define LOAD  0x03  /* d2 */


static void ad_delay(int delay)
{
	/* none needed, I/O bus should be slow enough */
}

static void ad_bit(hamlib_port_t *port, unsigned char bit)
{
	bit &= DATA;

	par_write_data(port, bit);
	ad_delay(1);

	par_write_data(port, bit|CLOCK);
	ad_delay(1);

	par_write_data(port, bit);
	ad_delay(1);
}

static void ad_write(hamlib_port_t *port, unsigned long word, unsigned char control)
{
	int i;

	/* lock the parallel port */
	par_lock (port);

	/* shift out the least significant 32 bits of the word */
	for(i=0; i<32; i++) {

		ad_bit(port, word&DATA);

		word >>= 1;
	}

	/* write out the control byte */
	for(i=0;i<8;i++) {

		ad_bit(port, control&DATA);

		control >>= 1;
	}

	/* load the register */
	par_write_data(port, LOAD);
	ad_delay(1);
	par_write_data(port, 0);

	/* unlock the parallel port */
	par_unlock (port);
}


int dds60_set_freq(RIG *rig, vfo_t vfo, freq_t freq)
{
	unsigned long frg;
	unsigned char control;
	struct dds60_priv_data *priv;
	hamlib_port_t *port = &rig->state.rigport;
	freq_t osc_ref;

	priv = (struct dds60_priv_data*)rig->state.priv;

	if (priv->multiplier)
		osc_ref = priv->osc_freq * 6;
	else
		osc_ref = priv->osc_freq;

	/* all frequencies are in Hz */
	frg = (unsigned long)(((double)freq + priv->if_mix_freq) /
				osc_ref * 4294967296.0 + 0.5);

	rig_debug(RIG_DEBUG_VERBOSE, "%s: word %lu, X6 multipler %d, phase %.2f\n", 
			__FUNCTION__, frg, priv->multiplier, priv->phase_step*PHASE_INCR);

	control = priv->multiplier ? 0x01 : 0x00;
	control |= (priv->phase_step & 0x1f) << 3;

	ad_write(port, frg, control);

	return RIG_OK;
}

int dds60_open(RIG *rig)
{
	hamlib_port_t *port = &rig->state.rigport;

	/* lock the parallel port */
	par_lock (port);

	/* Serial load enable sequence W_CLK */
	par_write_data(port, 0);
	ad_delay(1);

	par_write_data(port, CLOCK);
	ad_delay(1);

	par_write_data(port, 0);
	ad_delay(1);

	/* Serial load enable sequence FQ_UD */
	par_write_data(port, LOAD);
	ad_delay(1);
	par_write_data(port, 0);

	/* unlock the parallel port */
	par_unlock (port);

	return RIG_OK;
}