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Hamlib/rigs/yaesu/ft920.c

2905 wiersze
77 KiB
C
Czysty Wina Historia

/*
* hamlib - (C) Frank Singleton 2000 (javabear at users.sourceforge.net)
*
* ft920.c - (C) Frank Singleton 2000 (javabear at users.sourceforge.net)
* (C) Nate Bargmann 2002-2005 (n0nb at arrl.net)
* (C) Stephane Fillod 2002-2010 (fillods at users.sourceforge.net)
*
* This shared library provides an API for communicating
* via serial interface to an FT-920 using the "CAT" interface
* Documentation can be found online at:
* http://www.yaesu.com/amateur/pdf/manuals/ft_920.pdf
* pages 86 to 90
*
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
*/
#include <stdlib.h>
#include <string.h> /* String function definitions */
#include "hamlib/rig.h"
#include "bandplan.h"
#include "serial.h"
#include "misc.h"
#include "yaesu.h"
#include "ft920.h"
/*
* Functions considered to be Stable (2010-01-29):
* set_vfo
* get_vfo
* set_freq
* get_freq
* set_mode
* get_mode
* set_split
* get_split
* set_split_freq
* get_split_freq
* set_split_mode
* get_split_mode
* set_rit
* get_rit
* set_xit
* get_xit
* set_ptt
* get_ptt
*/
/*
* Native FT920 functions. More to come :-)
*
*/
enum ft920_native_cmd_e
{
FT920_NATIVE_SPLIT_OFF = 0,
FT920_NATIVE_SPLIT_ON,
FT920_NATIVE_RECALL_MEM,
FT920_NATIVE_VFO_TO_MEM,
FT920_NATIVE_VFO_A,
FT920_NATIVE_VFO_B,
FT920_NATIVE_MEM_TO_VFO,
FT920_NATIVE_CLARIFIER_OPS,
FT920_NATIVE_VFO_A_FREQ_SET,
FT920_NATIVE_MODE_SET,
FT920_NATIVE_PACING,
FT920_NATIVE_PTT_OFF,
FT920_NATIVE_PTT_ON,
FT920_NATIVE_MEM_CHNL,
FT920_NATIVE_OP_DATA,
FT920_NATIVE_VFO_DATA,
FT920_NATIVE_MEM_CHNL_DATA,
FT920_NATIVE_TUNER_BYPASS,
FT920_NATIVE_TUNER_INLINE,
FT920_NATIVE_TUNER_START,
FT920_NATIVE_VFO_B_FREQ_SET,
FT920_NATIVE_VFO_A_PASSBAND_WIDE,
FT920_NATIVE_VFO_A_PASSBAND_NAR,
FT920_NATIVE_VFO_B_PASSBAND_WIDE,
FT920_NATIVE_VFO_B_PASSBAND_NAR,
FT920_NATIVE_STATUS_FLAGS,
FT920_NATIVE_SIZE /* end marker, value indicates number of */
/* native cmd entries */
};
/*
* Internal MODES - when setting modes via FT920_NATIVE_MODE_SET
*
*/
/* VFO A */
#define MODE_SET_A_LSB 0x00
#define MODE_SET_A_USB 0x01
#define MODE_SET_A_CW_U 0x02
#define MODE_SET_A_CW_L 0x03
#define MODE_SET_A_AM_W 0x04
#define MODE_SET_A_AM_N 0x05
#define MODE_SET_A_FM_W 0x06
#define MODE_SET_A_FM_N 0x07
#define MODE_SET_A_DATA_L 0x08
#define MODE_SET_A_DATA_U 0x0a
#define MODE_SET_A_DATA_F 0x0b
/* VFO B */
#define MODE_SET_B_LSB 0x80
#define MODE_SET_B_USB 0x81
#define MODE_SET_B_CW_U 0x82
#define MODE_SET_B_CW_L 0x83
#define MODE_SET_B_AM_W 0x84
#define MODE_SET_B_AM_N 0x85
#define MODE_SET_B_FM_W 0x86
#define MODE_SET_B_FM_N 0x87
#define MODE_SET_B_DATA_L 0x88
#define MODE_SET_B_DATA_U 0x8a
#define MODE_SET_B_DATA_F 0x8b
/*
* Internal Clarifier parms - when setting clarifier via
* FT920_NATIVE_CLARIFIER_OPS
*
*/
/* P1 values */
#define CLAR_RX_OFF 0x00
#define CLAR_RX_ON 0x01
#define CLAR_TX_OFF 0x80
#define CLAR_TX_ON 0x81
#define CLAR_SET_FREQ 0xff
/* P2 values */
#define CLAR_OFFSET_PLUS 0x00
#define CLAR_OFFSET_MINUS 0xff
/* Tuner status values used to set the
* tuner state and indicate tuner status.
*/
#define TUNER_BYPASS 0
#define TUNER_INLINE 1
#define TUNER_TUNING 2
/*
* Local VFO CMD's, according to spec
*
*/
//#define FT920_VFO_A 0x00
//#define FT920_VFO_B 0x01
/*
* Some useful offsets in the status update flags (offset)
* SUMO--Status Update Memory Offset?
*
* SF_ bit tests are now grouped with flag bytes for ease of reference
*
* FIXME: complete flags and bits
*
* CAT command 0xFA, P1 = 01 requests the FT-920 to return its status flags.
* These flags consist of 8 bytes and are documented in the FT-920 manual
* on page 89.
*
*/
#define FT920_SUMO_DISPLAYED_STATUS_0 0x00 /* Status flag byte 0 */
#define SF_VFOA 0x00 /* bits 0 & 1, VFO A TX/RX == 0 */
#define SF_SPLITA (1<<0) /* Split operation with VFO-B on TX */
#define SF_SPLITB (1<<1) /* Split operation with VFO-B on RX */
#define SF_VFOB (SF_SPLITA|SF_SPLITB) /* bits 0 & 1, VFO B TX/RX == 3 */
#define SF_TUNER_TUNE (1<<2) /* Antenna tuner On and Tuning for match*/
#define SF_PTT_OFF (0<<7) /* Receive mode (PTT line open) */
#define SF_PTT_ON (1<<7) /* Transmission in progress (PTT line grounded) */
#define SF_PTT_MASK (SF_PTT_ON)
#define FT920_SUMO_DISPLAYED_STATUS_1 0x01 /* Status flag byte 1 */
#define SF_QMB (1<<3) /* Quick Memory Bank (QMB) selected */
#define SF_MT (1<<4) /* Memory Tuning in progress */
#define SF_VFO (1<<5) /* VFO operation selected */
#define SF_MR (1<<6) /* Memory Mode selected */
#define SF_GC (1<<7) /* General Coverage Reception selected */
#define SF_VFO_MASK (SF_QMB|SF_MT|SF_VFO|SF_MR)
#define FT920_SUMO_DISPLAYED_STATUS_2 0x02 /* Status flag byte 2 */
#define SF_TUNER_INLINE (1<<1) /* Antenna tuner is inline or bypass */
#define SF_VFOB_LOCK (1<<2) /* VFO B tuning lock status */
#define SF_VFOA_LOCK (1<<3) /* VFO A tuning lock status */
/*
* Offsets for VFO record retrieved via 0x10 P1 = 02, 03
*
* The FT-920 returns frequency and mode data via three separate commands.
* CAT command 0x10, P1 = 02 returns the current main and sub displays' data (28 bytes)
* CAT command 0x10, P1 = 03 returns VFO A data and the sub display data (sub display is always VFO B) (28 bytes)
* CAT command 0x10, P1 = 04, P4 = 0x00-0x89 returns memory channel data (14 bytes)
* In all cases the format is (from the FT-920 manual page 90):
*
* Offset Value
* 0x00 Band Selection (not documented!)
* 0x01 Operating Frequency (Hex value of display--Not BCD!)
* 0x05 Clarifier Offset (Hex value)
* 0x07 Mode Data
* 0x08 Flag
* 0x09 Filter Data 1
* 0x0a Filter Data 2
* 0x0b CTCSS Encoder Data
* 0x0c CTCSS Decoder Data
* 0x0d Memory recall Flag
*
* Memory Channel data has the same layout and offsets
* VFO B data has the same layout, but the offset starts at 0x0e and
* continues through 0x1b
*
*/
#define FT920_SUMO_DISPLAYED_FREQ 0x01 /* Current main display, can be VFO A, Memory data, Memory tune */
#define FT920_SUMO_VFO_A_FREQ 0x01 /* VFO A frequency, not necessarily currently displayed! */
#define FT920_SUMO_DISPLAYED_CLAR 0x05 /* RIT/XIT offset -- current display */
#define FT920_SUMO_VFO_A_CLAR 0x05 /* RIT/XIT offset -- VFO A */
#define FT920_SUMO_DISPLAYED_MODE 0x07 /* Current main display mode */
#define FT920_SUMO_VFO_A_MODE 0x07 /* VFO A mode, not necessarily currently displayed! */
#define FT920_SUMO_VFO_B_FREQ 0x0f /* Current sub display && VFO B */
#define FT920_SUMO_VFO_B_CLAR 0x13 /* RIT/XIT offset -- VFO B */
#define FT920_SUMO_VFO_B_MODE 0x15 /* Current sub display && VFO B */
/*
* Mode Bitmap from offset 0x07 or 0x16 in VFO Record.
* Bits 5 and 6 ignored
* used when READING modes from FT-920
*
*/
#define MODE_LSB 0x00
#define MODE_CW_L 0x01 /* CW listening on LSB */
#define MODE_AM 0x02
#define MODE_FM 0x03
#define MODE_DATA_L 0x04 /* DATA on LSB */
#define MODE_DATA_U 0x05 /* DATA on USB (who does that? :) */
#define MODE_DATA_F 0x06 /* DATA on FM */
#define MODE_USB 0x40
#define MODE_CW_U 0x41 /* CW listening on USB */
/* Narrow filter selected */
#define MODE_LSBN 0x80 /* Not sure this actually exists */
#define MODE_CW_LN 0x81
#define MODE_AMN 0x82
#define MODE_FMN 0x83
#define MODE_DATA_LN 0x84
#define MODE_DATA_UN 0x85
#define MODE_DATA_FN 0x86
#define MODE_USBN 0xc0 /* Not sure this actually exists */
#define MODE_CW_UN 0xc1
/* All relevant bits */
#define MODE_MASK 0xc7
/*
* Command string parameter offsets
*/
#define P1 3
#define P2 2
#define P3 1
#define P4 0
/*
* API local implementation
*
*/
static int ft920_init(RIG *rig);
static int ft920_cleanup(RIG *rig);
static int ft920_open(RIG *rig);
static int ft920_close(RIG *rig);
static int ft920_set_freq(RIG *rig, vfo_t vfo, freq_t freq);
static int ft920_get_freq(RIG *rig, vfo_t vfo, freq_t *freq);
static int ft920_set_mode(RIG *rig, vfo_t vfo, rmode_t mode, pbwidth_t width);
static int ft920_get_mode(RIG *rig, vfo_t vfo, rmode_t *mode, pbwidth_t *width);
static int ft920_set_vfo(RIG *rig, vfo_t vfo);
static int ft920_get_vfo(RIG *rig, vfo_t *vfo);
static int ft920_set_split_vfo(RIG *rig, vfo_t vfo, split_t split,
vfo_t tx_vfo);
static int ft920_get_split_vfo(RIG *rig, vfo_t vfo, split_t *split,
vfo_t *tx_vfo);
static int ft920_set_split_freq(RIG *rig, vfo_t vfo, freq_t tx_freq);
static int ft920_get_split_freq(RIG *rig, vfo_t vfo, freq_t *tx_freq);
static int ft920_set_split_mode(RIG *rig, vfo_t vfo, rmode_t tx_mode,
pbwidth_t tx_width);
static int ft920_get_split_mode(RIG *rig, vfo_t vfo, rmode_t *tx_mode,
pbwidth_t *tx_width);
static int ft920_set_rit(RIG *rig, vfo_t vfo, shortfreq_t rit);
static int ft920_get_rit(RIG *rig, vfo_t vfo, shortfreq_t *rit);
static int ft920_set_xit(RIG *rig, vfo_t vfo, shortfreq_t xit);
static int ft920_get_xit(RIG *rig, vfo_t vfo, shortfreq_t *xit);
/* not documented in my FT-920 manual, but it works! - N0NB */
static int ft920_set_ptt(RIG *rig, vfo_t vfo, ptt_t ptt);
static int ft920_get_ptt(RIG *rig, vfo_t vfo, ptt_t *ptt);
static int ft920_set_func(RIG *rig, vfo_t vfo, setting_t func, int status);
static int ft920_get_func(RIG *rig, vfo_t vfo, setting_t func, int *status);
/* Private helper function prototypes */
static int ft920_get_update_data(RIG *rig, unsigned char ci, unsigned char rl);
static int ft920_send_static_cmd(RIG *rig, unsigned char ci);
static int ft920_send_dynamic_cmd(RIG *rig, unsigned char ci, unsigned char p1,
unsigned char p2, unsigned char p3, unsigned char p4);
static int ft920_send_dial_freq(RIG *rig, unsigned char ci, freq_t freq);
static int ft920_send_rit_freq(RIG *rig, unsigned char ci, shortfreq_t rit);
/*
* Native ft920 cmd set prototypes. These are READ ONLY as each
* rig instance will copy from these and modify if required.
* Complete sequences (1) can be read and used directly as a cmd sequence.
* Incomplete sequences (0) must be completed with extra parameters
* eg: mem number, or freq etc..
*
* TODO: Shorten this static array with parameter substitution -N0NB
*
*/
static const yaesu_cmd_set_t ncmd[] =
{
{ 1, { 0x00, 0x00, 0x00, 0x00, 0x01 } }, /* split = off */
{ 1, { 0x00, 0x00, 0x00, 0x01, 0x01 } }, /* split = on */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x02 } }, /* recall memory */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x03 } }, /* memory operations */
{ 1, { 0x00, 0x00, 0x00, 0x00, 0x05 } }, /* select vfo A */
{ 1, { 0x00, 0x00, 0x00, 0x01, 0x05 } }, /* select vfo B */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x06 } }, /* copy memory data to vfo A */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x09 } }, /* clarifier operations */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x0a } }, /* set vfo A freq */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x0c } }, /* mode set */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x0e } }, /* update interval/pacing */
{ 1, { 0x00, 0x00, 0x00, 0x00, 0x0f } }, /* PTT off */
{ 1, { 0x00, 0x00, 0x00, 0x01, 0x0f } }, /* PTT on */
{ 1, { 0x00, 0x00, 0x00, 0x01, 0x10 } }, /* Status Update Data--Memory Channel Number (1 byte) */
{ 1, { 0x00, 0x00, 0x00, 0x02, 0x10 } }, /* Status Update Data--Current operating data for VFO/Memory (28 bytes) */
{ 1, { 0x00, 0x00, 0x00, 0x03, 0x10 } }, /* Status Update DATA--VFO A and B Data (28 bytes) */
{ 0, { 0x00, 0x00, 0x00, 0x04, 0x10 } }, /* Status Update Data--Memory Channel Data (14 bytes) P4 = 0x00-0x89 Memory Channel Number */
{ 1, { 0x00, 0x00, 0x00, 0x00, 0x81 } }, /* Tuner bypass */
{ 1, { 0x00, 0x00, 0x00, 0x01, 0x81 } }, /* Tuner inline */
{ 1, { 0x00, 0x00, 0x00, 0x00, 0x82 } }, /* Tuner start tuning for match */
{ 0, { 0x00, 0x00, 0x00, 0x00, 0x8a } }, /* set vfo B frequency */
{ 1, { 0x00, 0x00, 0x00, 0x00, 0x8c } }, /* VFO A wide filter */
{ 1, { 0x00, 0x00, 0x00, 0x02, 0x8c } }, /* VFO A narrow filter */
{ 1, { 0x00, 0x00, 0x00, 0x80, 0x8c } }, /* VFO B wide filter */
{ 1, { 0x00, 0x00, 0x00, 0x82, 0x8c } }, /* VFO B narrow filter */
{ 1, { 0x00, 0x00, 0x00, 0x01, 0xFA } }, /* Read status flags */
/* { 0, { 0x00, 0x00, 0x00, 0x00, 0x70 } }, */ /* keyer commands */
};
/*
* future - private data
*
* FIXME: Does this need to be exposed to the application/frontend through
* ft920_caps.priv? I'm guessing not as it's private to the backend. -N0NB
*/
struct ft920_priv_data
{
unsigned char pacing; /* pacing value */
vfo_t current_vfo; /* active VFO from last cmd */
vfo_t split_vfo; /* TX VFO in split mode */
split_t split; /* split active or not */
unsigned char
p_cmd[YAESU_CMD_LENGTH]; /* private copy of 1 constructed CAT cmd */
unsigned char
update_data[FT920_VFO_DATA_LENGTH]; /* returned data--max value, some are less */
};
/*
* ft920 rigs capabilities.
* Also this struct is READONLY!
*
*/
const struct rig_caps ft920_caps =
{
RIG_MODEL(RIG_MODEL_FT920),
.model_name = "FT-920",
.mfg_name = "Yaesu",
.version = "20220529.0", /* YYYYMMDD */
.copyright = "LGPL",
.status = RIG_STATUS_STABLE,
.rig_type = RIG_TYPE_TRANSCEIVER,
.ptt_type = RIG_PTT_RIG,
.dcd_type = RIG_DCD_NONE,
.port_type = RIG_PORT_SERIAL,
.serial_rate_min = 4800,
.serial_rate_max = 4800,
.serial_data_bits = 8,
.serial_stop_bits = 2,
.serial_parity = RIG_PARITY_NONE,
.serial_handshake = RIG_HANDSHAKE_NONE,
.write_delay = FT920_WRITE_DELAY,
.post_write_delay = FT920_POST_WRITE_DELAY,
.timeout = 2000,
.retry = 0,
.has_get_func = FT920_FUNC_ALL,
.has_set_func = RIG_FUNC_TUNER,
.has_get_level = RIG_LEVEL_BAND_SELECT,
.has_set_level = RIG_LEVEL_BAND_SELECT,
.has_get_parm = RIG_PARM_NONE,
.has_set_parm = RIG_PARM_NONE,
.level_gran =
{
#include "level_gran_yaesu.h"
},
.ctcss_list = NULL,
.dcs_list = NULL,
.preamp = { RIG_DBLST_END, },
.attenuator = { RIG_DBLST_END, },
.max_rit = Hz(9999),
.max_xit = Hz(9999),
.max_ifshift = Hz(0),
.announces = RIG_ANN_NONE,
.vfo_ops = RIG_OP_NONE,
.scan_ops = RIG_SCAN_NONE,
.targetable_vfo = RIG_TARGETABLE_ALL,
.transceive = RIG_TRN_OFF, /* Yaesus have to be polled, sigh */
.bank_qty = 0,
.chan_desc_sz = 0,
.chan_list = { RIG_CHAN_END, }, /* FIXME: memory channel list: 122 (!) */
.rx_range_list1 = {
{kHz(100), MHz(30), FT920_ALL_RX_MODES, -1, -1, FT920_VFO_ALL, FT920_ANTS}, /* General coverage + ham */
{MHz(48), MHz(56), FT920_ALL_RX_MODES, -1, -1, FT920_VFO_ALL, FT920_ANTS}, /* 6m! */
RIG_FRNG_END,
}, /* FIXME: Are these the correct Region 1 values? */
.tx_range_list1 = {
FRQ_RNG_HF(1, FT920_OTHER_TX_MODES, W(5), W(100), FT920_VFO_ALL, FT920_ANTS),
FRQ_RNG_HF(1, FT920_AM_TX_MODES, W(2), W(25), FT920_VFO_ALL, FT920_ANTS), /* AM class */
FRQ_RNG_6m(1, FT920_OTHER_TX_MODES, W(5), W(100), FT920_VFO_ALL, FT920_ANTS),
FRQ_RNG_6m(1, FT920_AM_TX_MODES, W(2), W(25), FT920_VFO_ALL, FT920_ANTS), /* AM class */
RIG_FRNG_END,
},
.rx_range_list2 = {
{kHz(100), MHz(30), FT920_ALL_RX_MODES, -1, -1, FT920_VFO_ALL, FT920_ANTS},
{MHz(48), MHz(56), FT920_ALL_RX_MODES, -1, -1, FT920_VFO_ALL, FT920_ANTS},
RIG_FRNG_END,
},
.tx_range_list2 = {
FRQ_RNG_HF(2, FT920_OTHER_TX_MODES, W(5), W(100), FT920_VFO_ALL, FT920_ANTS),
FRQ_RNG_HF(2, FT920_AM_TX_MODES, W(2), W(25), FT920_VFO_ALL, FT920_ANTS), /* AM class */
FRQ_RNG_6m(2, FT920_OTHER_TX_MODES, W(5), W(100), FT920_VFO_ALL, FT920_ANTS),
FRQ_RNG_6m(2, FT920_AM_TX_MODES, W(2), W(25), FT920_VFO_ALL, FT920_ANTS), /* AM class */
RIG_FRNG_END,
},
.tuning_steps = {
{FT920_SSB_CW_RX_MODES, Hz(10)}, /* Normal */
{FT920_SSB_CW_RX_MODES, Hz(100)}, /* Fast */
{FT920_AM_RX_MODES, Hz(100)}, /* Normal */
{FT920_AM_RX_MODES, kHz(1)}, /* Fast */
{FT920_FM_RX_MODES, Hz(100)}, /* Normal */
{FT920_FM_RX_MODES, kHz(1)}, /* Fast */
RIG_TS_END,
/*
* The FT-920 has a Fine tuning step which increments in 1 Hz steps
* for SSB_CW_RX_MODES, and 10 Hz steps for AM_RX_MODES and
* FM_RX_MODES. It doesn't appear that anything finer than 10 Hz
* is available through the CAT interface, however. -N0NB
*
*/
},
/* mode/filter list, .remember = order matters! */
.filters = {
{RIG_MODE_SSB, kHz(2.4)}, /* standard SSB filter bandwidth */
{RIG_MODE_CW, kHz(2.4)}, /* normal CW filter */
{RIG_MODE_CW, kHz(0.5)}, /* CW filter with narrow selection (must be installed!) */
{RIG_MODE_AM, kHz(15)}, /* normal AM filter (stock radio has no AM filter!) */
{RIG_MODE_AM, kHz(2.4)}, /* AM filter with narrow selection (SSB filter switched in) */
{RIG_MODE_FM, kHz(12)}, /* FM with optional FM unit */
{RIG_MODE_WFM, kHz(12)}, /* WideFM, with optional FM unit. */
{RIG_MODE_PKTLSB, kHz(1.8)},/* Alias of MODE_DATA_L */
{RIG_MODE_PKTLSB, kHz(0.5)},/* Alias of MODE_DATA_LN */
{RIG_MODE_PKTUSB, kHz(2.4)}, /* Alias for MODE DATA_U */
{RIG_MODE_PKTUSB, kHz(0.5)},/* Alias of MODE_DATA_UN */
{RIG_MODE_PKTFM, kHz(12)}, /* Alias for MODE_DATA _F */
{RIG_MODE_PKTFM, kHz(6)}, /* Alias for MODE_DATA_FN */
RIG_FLT_END,
},
.str_cal = EMPTY_STR_CAL,
.cfgparams = NULL,
.priv = NULL, /* private data FIXME: ?? */
.rig_init = ft920_init,
.rig_cleanup = ft920_cleanup,
.rig_open = ft920_open, /* port opened */
.rig_close = ft920_close, /* port closed */
.set_freq = ft920_set_freq,
.get_freq = ft920_get_freq,
.set_mode = ft920_set_mode,
.get_mode = ft920_get_mode,
.set_vfo = ft920_set_vfo,
.get_vfo = ft920_get_vfo,
.set_ptt = ft920_set_ptt,
.get_ptt = ft920_get_ptt,
.get_dcd = NULL,
.set_rptr_shift = NULL,
.get_rptr_shift = NULL,
.set_rptr_offs = NULL,
.get_rptr_offs = NULL,
.set_split_freq = ft920_set_split_freq,
.get_split_freq = ft920_get_split_freq,
.set_split_mode = ft920_set_split_mode,
.get_split_mode = ft920_get_split_mode,
.set_split_vfo = ft920_set_split_vfo,
.get_split_vfo = ft920_get_split_vfo,
.set_rit = ft920_set_rit,
.get_rit = ft920_get_rit,
.set_xit = ft920_set_xit,
.get_xit = ft920_get_xit,
.set_ts = NULL,
.get_ts = NULL,
.set_dcs_code = NULL,
.get_dcs_code = NULL,
.set_tone = NULL,
.get_tone = NULL,
.set_ctcss_tone = NULL,
.get_ctcss_tone = NULL,
.set_dcs_sql = NULL,
.get_dcs_sql = NULL,
.set_tone_sql = NULL,
.get_tone_sql = NULL,
.set_ctcss_sql = NULL,
.get_ctcss_sql = NULL,
.power2mW = NULL,
.mW2power = NULL,
.set_powerstat = NULL,
.get_powerstat = NULL,
.reset = NULL,
.set_ant = NULL,
.get_ant = NULL,
.set_level = NULL,
.get_level = NULL,
.set_func = ft920_set_func,
.get_func = ft920_get_func,
.set_parm = NULL,
.get_parm = NULL,
.set_ext_level = NULL,
.get_ext_level = NULL,
.set_ext_parm = NULL,
.get_ext_parm = NULL,
.set_conf = NULL,
.get_conf = NULL,
.send_dtmf = NULL,
.recv_dtmf = NULL,
.send_morse = NULL,
.set_bank = NULL,
.set_mem = NULL,
.get_mem = NULL,
.vfo_op = NULL,
.scan = NULL,
.set_trn = NULL,
.get_trn = NULL,
.decode_event = NULL,
.set_channel = NULL,
.get_channel = NULL,
.get_info = NULL,
.set_chan_all_cb = NULL,
.get_chan_all_cb = NULL,
.set_mem_all_cb = NULL,
.get_mem_all_cb = NULL,
.clone_combo_set = NULL,
.clone_combo_get = NULL,
.hamlib_check_rig_caps = HAMLIB_CHECK_RIG_CAPS
};
/*
* ************************************
*
* Hamlib API functions
*
* ************************************
*/
/*
* rig_init*
*
*/
static int ft920_init(RIG *rig)
{
struct ft920_priv_data *priv;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig->state.priv = (struct ft920_priv_data *) calloc(1,
sizeof(struct ft920_priv_data));
if (!rig->state.priv)
{
return -RIG_ENOMEM; /* whoops! memory shortage! */
}
priv = rig->state.priv;
/* TODO: read pacing from preferences */
priv->pacing =
FT920_PACING_DEFAULT_VALUE; /* set pacing to minimum for now */
priv->current_vfo = RIG_VFO_A; /* default to VFO_A */
return RIG_OK;
}
/*
* rig_cleanup*
*
* the serial port is closed by the frontend
*
*/
static int ft920_cleanup(RIG *rig)
{
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
if (rig->state.priv)
{
free(rig->state.priv);
}
rig->state.priv = NULL;
return RIG_OK;
}
/*
* rig_open*
*
*/
static int ft920_open(RIG *rig)
{
struct rig_state *rig_s;
struct ft920_priv_data *priv;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
rig_s = &rig->state;
rig_debug(RIG_DEBUG_TRACE, "%s: write_delay = %i msec\n",
__func__, rig_s->rigport.write_delay);
rig_debug(RIG_DEBUG_TRACE, "%s: post_write_delay = %i msec\n",
__func__, rig_s->rigport.post_write_delay);
/* Copy native cmd PACING to private cmd storage area */
memcpy(&priv->p_cmd, &ncmd[FT920_NATIVE_PACING].nseq, YAESU_CMD_LENGTH);
/* get pacing value, and store in private cmd */
priv->p_cmd[P1] = priv->pacing;
rig_debug(RIG_DEBUG_TRACE, "%s: read pacing = %i\n", __func__, priv->pacing);
err = write_block(&rig->state.rigport, priv->p_cmd, YAESU_CMD_LENGTH);
if (err != RIG_OK)
{
return err;
}
/* TODO: more initialization as necessary */
return RIG_OK;
}
/*
* rig_close*
*
*/
static int ft920_close(RIG *rig)
{
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
return RIG_OK;
}
/*
* rig_set_freq*
*
* Set freq for a given VFO
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | RIG_VFO_A, RIG_VFO_B, RIG_VFO_MEM
* freq | input | frequency to passed VFO
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: If vfo is set to RIG_VFO_CUR then vfo from
* priv_data is used.
*
*/
static int ft920_set_freq(RIG *rig, vfo_t vfo, freq_t freq)
{
struct ft920_priv_data *priv;
int err, cmd_index;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
rig_debug(RIG_DEBUG_TRACE, "%s: passed freq = %"PRIfreq" Hz\n", __func__, freq);
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
switch (vfo)
{
case RIG_VFO_A: /* force main display to VFO */
case RIG_VFO_VFO:
err = ft920_set_vfo(rig, RIG_VFO_A);
if (err != RIG_OK)
{
return err;
}
case RIG_VFO_MEM: /* MEM TUNE or user doesn't care */
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_VFO_A_FREQ_SET;
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_VFO_B_FREQ_SET;
break;
default:
return -RIG_EINVAL; /* sorry, unsupported VFO */
}
rig_debug(RIG_DEBUG_TRACE, "%s: set cmd_index = 0x%02x\n", __func__, cmd_index);
err = ft920_send_dial_freq(rig, cmd_index, freq);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_freq*
*
* Return Freq for a given VFO
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | RIG_VFO_A, RIG_VFO_B, RIG_VFO_MEM
* *freq | output | displayed frequency based on passed VFO
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
*/
static int ft920_get_freq(RIG *rig, vfo_t vfo, freq_t *freq)
{
struct ft920_priv_data *priv;
unsigned char *p;
unsigned char offset;
freq_t f;
int err, cmd_index;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
switch (vfo)
{
case RIG_VFO_A:
case RIG_VFO_VFO:
cmd_index = FT920_NATIVE_VFO_DATA;
offset = FT920_SUMO_VFO_A_FREQ;
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_OP_DATA;
offset = FT920_SUMO_VFO_B_FREQ;
break;
case RIG_VFO_MEM:
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_OP_DATA;
offset = FT920_SUMO_DISPLAYED_FREQ;
break;
default:
return -RIG_EINVAL; /* sorry, wrong VFO */
}
err = ft920_get_update_data(rig, cmd_index, FT920_VFO_DATA_LENGTH);
if (err != RIG_OK)
{
return err;
}
p = &priv->update_data[offset];
/* big endian integer */
f = (((((p[0] << 8) + p[1]) << 8) + p[2]) << 8) + p[3];
rig_debug(RIG_DEBUG_TRACE, "%s: freq = %"PRIfreq" Hz for vfo 0x%02x\n",
__func__, f, vfo);
*freq = f; /* return displayed frequency */
return RIG_OK;
}
/*
* rig_set_mode*
*
* Set mode and passband: eg AM, CW etc for a given VFO
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | RIG_VFO_A, RIG_VFO_B, RIG_VFO_MEM
* mode | input | supported modes (see ft920.h)
* width | input | supported widths (see ft920.h)
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: If vfo is set to RIG_VFO_CUR then vfo from
* priv_data is used.
*
*/
static int ft920_set_mode(RIG *rig, vfo_t vfo, rmode_t mode, pbwidth_t width)
{
struct ft920_priv_data *priv;
unsigned char cmd_index =
FT920_NATIVE_VFO_A_PASSBAND_WIDE; /* index of sequence to send */
unsigned char mode_parm; /* mode parameter */
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = %s\n", __func__, rig_strvfo(vfo));
rig_debug(RIG_DEBUG_TRACE, "%s: passed mode = %s\n", __func__,
rig_strrmode(mode));
rig_debug(RIG_DEBUG_TRACE, "%s: passed width = %d Hz\n", __func__, (int)width);
priv = (struct ft920_priv_data *)rig->state.priv;
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE,
"%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
/* translate mode from generic to ft920 specific */
switch (vfo)
{
case RIG_VFO_A: /* force to VFO */
case RIG_VFO_VFO:
err = ft920_set_vfo(rig, RIG_VFO_A);
if (err != RIG_OK)
{
return err;
}
case RIG_VFO_MEM: /* MEM TUNE or user doesn't care */
case RIG_VFO_MAIN:
switch (mode)
{
case RIG_MODE_AM:
mode_parm = MODE_SET_A_AM_W;
break;
case RIG_MODE_CW:
mode_parm = MODE_SET_A_CW_U;
break;
case RIG_MODE_USB:
mode_parm = MODE_SET_A_USB;
break;
case RIG_MODE_LSB:
mode_parm = MODE_SET_A_LSB;
break;
case RIG_MODE_FM:
mode_parm = MODE_SET_A_FM_W;
break;
case RIG_MODE_RTTY:
mode_parm = MODE_SET_A_DATA_L;
break;
case RIG_MODE_PKTLSB:
mode_parm = MODE_SET_A_DATA_L;
break;
case RIG_MODE_PKTUSB:
mode_parm = MODE_SET_A_DATA_U;
break;
case RIG_MODE_PKTFM:
mode_parm = MODE_SET_A_DATA_F;
break;
default:
return -RIG_EINVAL; /* sorry, wrong MODE */
}
break;
/* Now VFO B */
case RIG_VFO_B:
case RIG_VFO_SUB:
switch (mode)
{
case RIG_MODE_AM:
mode_parm = MODE_SET_B_AM_W;
break;
case RIG_MODE_CW:
mode_parm = MODE_SET_B_CW_U;
break;
case RIG_MODE_USB:
mode_parm = MODE_SET_B_USB;
break;
case RIG_MODE_LSB:
mode_parm = MODE_SET_B_LSB;
break;
case RIG_MODE_FM:
mode_parm = MODE_SET_B_FM_W;
break;
case RIG_MODE_RTTY:
mode_parm = MODE_SET_B_DATA_L;
break;
case RIG_MODE_PKTLSB:
mode_parm = MODE_SET_B_DATA_L;
break;
case RIG_MODE_PKTUSB:
mode_parm = MODE_SET_B_DATA_U;
break;
case RIG_MODE_PKTFM:
mode_parm = MODE_SET_B_DATA_F;
break;
default:
return -RIG_EINVAL;
}
break;
default:
return -RIG_EINVAL; /* sorry, wrong VFO */
}
/*
* Now set width (shamelessly stolen from ft847.c and then butchered :)
* The FT-920 doesn't appear to support narrow width in USB or LSB modes
*
* Yeah, it's ugly... -N0NB
*
*/
if (width != RIG_PASSBAND_NOCHANGE)
{
if (width == RIG_PASSBAND_NORMAL || width == rig_passband_normal(rig, mode))
{
switch (vfo)
{
case RIG_VFO_A:
case RIG_VFO_VFO:
case RIG_VFO_MEM:
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_VFO_A_PASSBAND_WIDE;
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_VFO_B_PASSBAND_WIDE;
break;
}
}
else
{
if (width == rig_passband_narrow(rig, mode))
{
switch (mode)
{
case RIG_MODE_CW:
case RIG_MODE_AM:
case RIG_MODE_FM:
case RIG_MODE_PKTFM:
case RIG_MODE_RTTY:
switch (vfo)
{
case RIG_VFO_A:
case RIG_VFO_VFO:
case RIG_VFO_MEM:
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_VFO_A_PASSBAND_NAR;
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_VFO_B_PASSBAND_NAR;
break;
}
break;
default:
return -RIG_EINVAL; /* Invalid mode; how can caller know? */
}
}
else
{
if (width != RIG_PASSBAND_NORMAL && width != rig_passband_normal(rig, mode))
{
return -RIG_EINVAL; /* Invalid width; how can caller know? */
}
}
}
}
rig_debug(RIG_DEBUG_TRACE, "%s: set mode_parm = 0x%02x\n", __func__, mode_parm);
rig_debug(RIG_DEBUG_TRACE, "%s: set cmd_index = %i\n", __func__, cmd_index);
err = ft920_send_dynamic_cmd(rig, FT920_NATIVE_MODE_SET, mode_parm, 0, 0, 0);
if (err != RIG_OK)
{
return err;
}
err = ft920_send_static_cmd(rig, cmd_index);
if (err != RIG_OK)
{
return err;
}
return RIG_OK; /* Whew! */
}
/*
* rig_get_mode*
*
* Get mode and passband: eg AM, CW etc for a given VFO
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | RIG_VFO_A, RIG_VFO_B, RIG_VFO_MEM
* *mode | output | supported modes (see ft920.h)
* *width | output | supported widths (see ft920.h)
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
*/
static int ft920_get_mode(RIG *rig, vfo_t vfo, rmode_t *mode, pbwidth_t *width)
{
struct ft920_priv_data *priv;
unsigned char mymode, offset; /* ft920 mode, flag offset */
int err, cmd_index, norm;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
priv = (struct ft920_priv_data *)rig->state.priv;
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
switch (vfo)
{
case RIG_VFO_A:
case RIG_VFO_VFO:
cmd_index = FT920_NATIVE_VFO_DATA;
offset = FT920_SUMO_DISPLAYED_MODE;
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_VFO_DATA;
offset = FT920_SUMO_VFO_B_MODE;
break;
case RIG_VFO_MEM:
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_OP_DATA;
offset = FT920_SUMO_DISPLAYED_MODE;
break;
default:
return -RIG_EINVAL;
}
err = ft920_get_update_data(rig, cmd_index, FT920_VFO_DATA_LENGTH);
if (err != RIG_OK)
{
return err;
}
mymode = priv->update_data[offset];
mymode &= MODE_MASK;
rig_debug(RIG_DEBUG_TRACE, "%s: mymode = 0x%02x\n", __func__, mymode);
/*
* translate mode from ft920 to generic.
*
* FIXME: FT-920 has 3 DATA modes, LSB, USB, and FM
* do we need more bit fields in rmode_t? -N0NB
*
*/
switch (mymode)
{
case MODE_USBN: /* not sure this even exists */
*mode = RIG_MODE_USB;
norm = FALSE;
break;
case MODE_USB:
*mode = RIG_MODE_USB;
norm = TRUE;
break;
case MODE_LSBN: /* not sure this even exists */
*mode = RIG_MODE_LSB;
norm = FALSE;
break;
case MODE_LSB:
*mode = RIG_MODE_LSB;
norm = TRUE;
break;
case MODE_CW_UN:
case MODE_CW_LN:
*mode = RIG_MODE_CW;
norm = FALSE;
break;
case MODE_CW_U:
case MODE_CW_L:
*mode = RIG_MODE_CW;
norm = TRUE;
break;
case MODE_AMN:
*mode = RIG_MODE_AM;
norm = FALSE;
break;
case MODE_AM:
*mode = RIG_MODE_AM;
norm = TRUE;
break;
case MODE_FMN:
*mode = RIG_MODE_FM;
norm = FALSE;
break;
case MODE_FM:
*mode = RIG_MODE_FM;
norm = TRUE;
break;
case MODE_DATA_LN:
*mode = RIG_MODE_PKTLSB;
norm = FALSE;
break;
case MODE_DATA_L:
*mode = RIG_MODE_PKTLSB;
norm = TRUE;
break;
case MODE_DATA_UN:
*mode = RIG_MODE_PKTUSB;
norm = FALSE;
break;
case MODE_DATA_U:
*mode = RIG_MODE_PKTUSB;
norm = TRUE;
break;
case MODE_DATA_F:
*mode = RIG_MODE_PKTFM;
norm = TRUE;
break;
case MODE_DATA_FN:
*mode = RIG_MODE_PKTFM;
norm = FALSE;
break;
default:
return -RIG_EINVAL; /* Oops! file bug report */
}
if (norm)
{
*width = rig_passband_normal(rig, *mode);
}
else
{
*width = rig_passband_narrow(rig, *mode);
}
rig_debug(RIG_DEBUG_TRACE, "%s: set mode = %s\n", __func__,
rig_strrmode(*mode));
rig_debug(RIG_DEBUG_TRACE, "%s: set width = %d Hz\n", __func__, (int)*width);
return RIG_OK;
}
/*
* rig_set_vfo*
*
* Get active VFO
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | RIG_VFO_A, RIG_VFO_B
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Set vfo and store requested vfo for later
* RIG_VFO_CURR requests.
*
*/
static int ft920_set_vfo(RIG *rig, vfo_t vfo)
{
struct ft920_priv_data *priv;
unsigned char cmd_index; /* index of sequence to send */
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
priv = (struct ft920_priv_data *)rig->state.priv;
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
switch (vfo)
{
case RIG_VFO_A:
case RIG_VFO_VFO:
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_VFO_A;
priv->current_vfo = vfo; /* update active VFO */
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_VFO_B;
priv->current_vfo = vfo;
break;
default:
return -RIG_EINVAL; /* sorry, wrong VFO */
}
rig_debug(RIG_DEBUG_TRACE, "%s: set cmd_index = %i\n", __func__, cmd_index);
err = ft920_send_static_cmd(rig, cmd_index);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_vfo*
*
* Get active VFO
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* *vfo | output | RIG_VFO_A, RIG_VFO_B, RIG_VFO_MEM
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Get current RX vfo/mem and store requested vfo for
* later RIG_VFO_CURR requests plus pass the tested
* vfo/mem back to the frontend.
*
*/
static int ft920_get_vfo(RIG *rig, vfo_t *vfo)
{
struct ft920_priv_data *priv;
unsigned char status_0; /* ft920 status flag 0 */
unsigned char status_1; /* ft920 status flag 1 */
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
/* Get flags for VFO status */
err = ft920_get_update_data(rig, FT920_NATIVE_STATUS_FLAGS,
FT920_STATUS_FLAGS_LENGTH);
if (err != RIG_OK)
{
return err;
}
status_0 = priv->update_data[FT920_SUMO_DISPLAYED_STATUS_0];
status_0 &= SF_VFOB; /* get VFO B (sub display) active bits */
status_1 = priv->update_data[FT920_SUMO_DISPLAYED_STATUS_1];
status_1 &= SF_VFO_MASK; /* get VFO/MEM (main display) active bits */
rig_debug(RIG_DEBUG_TRACE, "%s: vfo status_0 = 0x%02x\n", __func__, status_0);
rig_debug(RIG_DEBUG_TRACE, "%s: vfo status_1 = 0x%02x\n", __func__, status_1);
/*
* translate vfo status from ft920 to generic.
*
* Figuring out whether VFO B is the active RX vfo is tough as
* Status Flag 0 bits 0 & 1 contain this information. Testing
* Status Flag 1 only gives us the state of the main display.
*
*/
switch (status_0)
{
case SF_VFOB:
*vfo = RIG_VFO_B;
priv->current_vfo = RIG_VFO_B;
break;
case SF_SPLITB: /* Split operation, RX on VFO B */
*vfo = RIG_VFO_B;
priv->current_vfo = RIG_VFO_B;
break;
}
/*
* Okay now test for the active MEM/VFO status of the main display
*
*/
switch (status_1)
{
case SF_QMB:
case SF_MT:
case SF_MR:
*vfo = RIG_VFO_MEM;
priv->current_vfo = RIG_VFO_MEM;
break;
case SF_VFO:
switch (status_0)
{
case SF_SPLITA: /* Split operation, RX on VFO A */
*vfo = RIG_VFO_A;
priv->current_vfo = RIG_VFO_A;
break;
case SF_VFOA:
*vfo = RIG_VFO_A;
priv->current_vfo = RIG_VFO_A;
break;
}
break;
default: /* Oops! */
return -RIG_EINVAL; /* sorry, wrong current VFO */
}
rig_debug(RIG_DEBUG_TRACE, "%s: set vfo = 0x%02x\n", __func__, *vfo);
return RIG_OK;
}
/*
* rig_set_split_vfo*
*
* Set the '920 into split TX/RX mode
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | not used
* split | input | RIG_SPLIT_ON, RIG_SPLIT_OFF
* tx_vfo | input | VFO to use for TX (not used)
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: VFO cannot be set as the set split_on command only
* changes the TX to the sub display. Setting split off
* returns the TX to the main display.
*
*/
static int ft920_set_split_vfo(RIG *rig, vfo_t vfo, split_t split,
vfo_t tx_vfo)
{
unsigned char cmd_index;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
rig_debug(RIG_DEBUG_TRACE, "%s: passed split = 0x%02x\n", __func__, split);
rig_debug(RIG_DEBUG_TRACE, "%s: passed tx_vfo = 0x%02x\n", __func__, tx_vfo);
switch (tx_vfo)
{
case RIG_VFO_A:
case RIG_VFO_MAIN:
case RIG_VFO_VFO:
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
break;
default:
return -RIG_EINVAL;
}
switch (split)
{
case RIG_SPLIT_OFF:
cmd_index = FT920_NATIVE_SPLIT_OFF;
break;
case RIG_SPLIT_ON:
cmd_index = FT920_NATIVE_SPLIT_ON;
break;
default:
return -RIG_EINVAL;
}
err = ft920_send_static_cmd(rig, cmd_index);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_split_vfo*
*
* Get whether the '920 is in split mode
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | not used
* *split | output | RIG_SPLIT_ON, RIG_SPLIT_OFF
* *tx_vfo | output | not used
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
*/
static int ft920_get_split_vfo(RIG *rig, vfo_t vfo, split_t *split,
vfo_t *tx_vfo)
{
struct ft920_priv_data *priv;
unsigned char status_0;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
priv = (struct ft920_priv_data *)rig->state.priv;
/* Get flags for VFO split status */
err = ft920_get_update_data(rig, FT920_NATIVE_STATUS_FLAGS,
FT920_STATUS_FLAGS_LENGTH);
if (err != RIG_OK)
{
return err;
}
status_0 = priv->update_data[FT920_SUMO_DISPLAYED_STATUS_0];
status_0 &= SF_VFOB; /* get VFO B (sub display) active bits */
rig_debug(RIG_DEBUG_TRACE, "%s: split status_0 = 0x%02x\n", __func__, status_0);
switch (status_0)
{
case SF_SPLITA: /* VFOB (sub display) is TX Got that? */
*tx_vfo = RIG_VFO_B;
*split = RIG_SPLIT_ON;
break;
case SF_SPLITB: /* VFOA is TX */
*tx_vfo = RIG_VFO_A;
*split = RIG_SPLIT_ON;
break;
case SF_VFOA:
*tx_vfo = RIG_VFO_A;
*split = RIG_SPLIT_OFF;
break;
case SF_VFOB:
*tx_vfo = RIG_VFO_B;
*split = RIG_SPLIT_OFF;
break;
default:
return -RIG_EINVAL;
}
return RIG_OK;
}
/*
* rig_set_split_freq*
*
* Set the '920 split TX freq
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* tx_freq | input | split transmit frequency
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Checks to see if 920 is in split mode and if so sets
* the frequency of the TX VFO. If not in split mode
* does nothing and returns.
*
*/
static int ft920_set_split_freq(RIG *rig, vfo_t vfo, freq_t tx_freq)
{
struct ft920_priv_data *priv;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
rig_debug(RIG_DEBUG_TRACE, "%s: passed freq = %"PRIfreq" Hz\n", __func__,
tx_freq);
err = rig_set_split_vfo(rig, RIG_VFO_A, RIG_SPLIT_ON, RIG_VFO_B);
if (err != RIG_OK) { RETURNFUNC(err); }
priv = (struct ft920_priv_data *)rig->state.priv;
err = ft920_get_split_vfo(rig, vfo, &priv->split, &priv->split_vfo);
if (err != RIG_OK)
{
return err;
}
switch ((int)priv->split)
{
case TRUE: /* '920 is in split mode */
err = ft920_set_freq(rig, priv->split_vfo, tx_freq);
if (err != RIG_OK)
{
return err;
}
break;
default:
break;
}
return RIG_OK;
}
/*
* rig_get_split_freq*
*
* Get the '920 split TX freq
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* *tx_freq | output | split transmit frequency
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Checks to see if the 920 is in split mode, if so it
* checks which VFO is set for TX and then gets the
* frequency of that VFO and stores it into *tx_freq.
* If not in split mode returns 0 Hz.
*
*/
static int ft920_get_split_freq(RIG *rig, vfo_t vfo, freq_t *tx_freq)
{
struct ft920_priv_data *priv;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
err = ft920_get_split_vfo(rig, vfo, &priv->split, &priv->split_vfo);
if (err != RIG_OK)
{
return err;
}
switch ((int)priv->split)
{
case TRUE: /* '920 is in split mode */
err = ft920_get_freq(rig, priv->split_vfo, tx_freq);
if (err != RIG_OK)
{
return err;
}
break;
default:
*tx_freq = 0;
break;
}
return RIG_OK;
}
/*
* rig_set_split_mode
*
* Set the '920 split TX mode
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* tx_mode | input | supported modes
* tx_width | input | supported widths
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Checks to see if 920 is in split mode and if so sets
* the mode and passband of the TX VFO. If not in split mode
* does nothing and returns.
*
*/
static int ft920_set_split_mode(RIG *rig, vfo_t vfo, rmode_t tx_mode,
pbwidth_t tx_width)
{
struct ft920_priv_data *priv;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = %s\n", __func__, rig_strvfo(vfo));
rig_debug(RIG_DEBUG_TRACE, "%s: passed mode = %s\n", __func__,
rig_strrmode(tx_mode));
rig_debug(RIG_DEBUG_TRACE, "%s: passed width = %d Hz\n", __func__,
(int)tx_width);
priv = (struct ft920_priv_data *)rig->state.priv;
err = ft920_get_split_vfo(rig, vfo, &priv->split, &priv->split_vfo);
if (err != RIG_OK)
{
return err;
}
switch ((int)priv->split)
{
case TRUE: /* '920 is in split mode */
err = ft920_set_mode(rig, priv->split_vfo, tx_mode, tx_width);
if (err != RIG_OK)
{
return err;
}
break;
default:
break;
}
return RIG_OK;
}
/*
* rig_get_split_mode*
*
* Get the '920 split TX mode
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* *tx_mode | output | supported modes
* *tx_width | output | supported widths
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Checks to see if the 920 is in split mode, if so it
* checks which VFO is set for TX and then gets the
* mode and passband of that VFO and stores it into *tx_mode
* and tx_width respectively. If not in split mode returns
* RIG_MODE_NONE and 0 Hz.
*
*/
static int ft920_get_split_mode(RIG *rig, vfo_t vfo, rmode_t *tx_mode,
pbwidth_t *tx_width)
{
struct ft920_priv_data *priv;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
err = ft920_get_split_vfo(rig, vfo, &priv->split, &priv->split_vfo);
if (err != RIG_OK)
{
return err;
}
switch ((int)priv->split)
{
case TRUE: /* '920 is in split mode */
err = ft920_get_mode(rig, priv->split_vfo, tx_mode, tx_width);
if (err != RIG_OK)
{
return err;
}
break;
default:
*tx_mode = RIG_MODE_NONE;
*tx_width = 0;
break;
}
return RIG_OK;
}
/*
* rig_set_rit*
*
* Set the RIT offset
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* rit | input | -9999 to 9999 Hz
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: vfo is ignored as RIT cannot be changed on sub VFO
*
* FIXME: Should rig be forced into VFO mode if RIG_VFO_A
* or RIG_VFO_VFO is received?
*
* VFO and MEM rit values are independent. The sub display
* carries an RIT value only if A<>B button is pressed or
* set_vfo is called with RIG_VFO_B and the main display has
* an RIT value.
*/
static int ft920_set_rit(RIG *rig, vfo_t vfo, shortfreq_t rit)
{
unsigned char offset;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
if (rit < -9999 || rit > 9999)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
rig_debug(RIG_DEBUG_TRACE, "%s: passed rit = %li\n", __func__, rit);
if (rit == 0)
{
offset = CLAR_RX_OFF;
}
else
{
offset = CLAR_RX_ON;
}
rig_debug(RIG_DEBUG_TRACE, "%s: set offset = 0x%02x\n", __func__, offset);
err = ft920_send_dynamic_cmd(rig, FT920_NATIVE_CLARIFIER_OPS, offset, 0, 0, 0);
if (err != RIG_OK)
{
return err;
}
err = ft920_send_rit_freq(rig, FT920_NATIVE_CLARIFIER_OPS, rit);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_rit*
*
* Get the RIT offset
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* *rit | output | -9999 to 9999 Hz
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Value of vfo is ignored as it's not needed.
*
* Rig returns offset as hex from 0x0000 to 0x270f for
* 0 to +9999 Hz and 0xffff to 0xd8f1 for -1 to -9999 Hz
*
* VFO and MEM rit values are independent. The sub display
* carries an RIT value only if A<>B button is pressed or
* set_vfo is called with RIG_VFO_B and the main display has
* an RIT value.
*/
static int ft920_get_rit(RIG *rig, vfo_t vfo, shortfreq_t *rit)
{
struct ft920_priv_data *priv;
unsigned char *p;
unsigned char offset;
shortfreq_t f;
int err, cmd_index;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
priv = (struct ft920_priv_data *)rig->state.priv;
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
switch (vfo)
{
case RIG_VFO_MEM:
case RIG_VFO_MAIN:
cmd_index = FT920_NATIVE_OP_DATA;
offset = FT920_SUMO_DISPLAYED_CLAR;
break;
case RIG_VFO_A:
case RIG_VFO_VFO:
cmd_index = FT920_NATIVE_VFO_DATA;
offset = FT920_SUMO_VFO_A_CLAR;
break;
case RIG_VFO_B:
case RIG_VFO_SUB:
cmd_index = FT920_NATIVE_VFO_DATA;
offset = FT920_SUMO_VFO_B_CLAR;
break;
default:
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: set cmd_index = %i\n", __func__, cmd_index);
rig_debug(RIG_DEBUG_TRACE, "%s: set offset = 0x%02x\n", __func__, offset);
err = ft920_get_update_data(rig, cmd_index, FT920_VFO_DATA_LENGTH);
if (err != RIG_OK)
{
return err;
}
p = &priv->update_data[offset];
/* big endian integer */
f = (p[0] << 8) + p[1];
if (f > 0xd8f0) /* 0xd8f1 to 0xffff is negative offset */
{
f = ~(0xffff - f);
}
rig_debug(RIG_DEBUG_TRACE, "%s: read freq = %li Hz\n", __func__, f);
*rit = f; /* store clarifier frequency */
return RIG_OK;
}
/*
* rig_set_xit
*
* Set the XIT offset
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* xit | input | -9999 to 9999 Hz
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: vfo is ignored as XIT cannot be changed on sub VFO
*
* FIXME: Should rig be forced into VFO mode if RIG_VFO_A
* or RIG_VFO_VFO is received?
*/
static int ft920_set_xit(RIG *rig, vfo_t vfo, shortfreq_t xit)
{
unsigned char offset;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
if (xit < -9999 || xit > 9999)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
rig_debug(RIG_DEBUG_TRACE, "%s: passed xit = %li\n", __func__, xit);
if (xit == 0)
{
offset = CLAR_TX_OFF;
}
else
{
offset = CLAR_TX_ON;
}
rig_debug(RIG_DEBUG_TRACE, "%s: set offset = 0x%02x\n", __func__, offset);
err = ft920_send_dynamic_cmd(rig, FT920_NATIVE_CLARIFIER_OPS, offset, 0, 0, 0);
if (err != RIG_OK)
{
return err;
}
err = ft920_send_rit_freq(rig, FT920_NATIVE_CLARIFIER_OPS, xit);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_xit*
*
* Get the XIT offset
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* *xit | output | -9999 to 9999 Hz
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Value of vfo is ignored as it's not needed
*
* Rig returns offset as hex from 0x0000 to 0x270f for
* 0 to +9999 Hz and 0xffff to 0xd8f1 for -1 to -9999 Hz
*/
static int ft920_get_xit(RIG *rig, vfo_t vfo, shortfreq_t *xit)
{
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
err = ft920_get_rit(rig, vfo, xit); /* abuse get_rit and store in *xit */
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_set_ptt*
*
* Set the '920 into TX mode
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* ptt | input | RIG_PTT_OFF, RIG_PTT_ON
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: vfo is respected by calling ft920_set_vfo if
* passed vfo != priv->current_vfo
*
* This command is not documented in my '920 manual,
* but it works! -N0NB
*
*/
static int ft920_set_ptt(RIG *rig, vfo_t vfo, ptt_t ptt)
{
struct ft920_priv_data *priv;
unsigned char cmd_index;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo);
rig_debug(RIG_DEBUG_TRACE, "%s: passed ptt = 0x%02x\n", __func__, ptt);
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE,
"%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
else if (vfo != priv->current_vfo)
{
ft920_set_vfo(rig, vfo);
}
switch (ptt)
{
case RIG_PTT_OFF:
cmd_index = FT920_NATIVE_PTT_OFF;
break;
case RIG_PTT_ON:
cmd_index = FT920_NATIVE_PTT_ON;
break;
default:
return -RIG_EINVAL; /* wrong PTT state! */
}
err = ft920_send_static_cmd(rig, cmd_index);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_ptt*
*
* Get current PTT status
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* *ptt | output | RIG_PTT_OFF, RIG_PTT_ON
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Get the PTT state
*/
static int ft920_get_ptt(RIG *rig, vfo_t vfo, ptt_t *ptt)
{
struct ft920_priv_data *priv;
unsigned char stat_0; /* ft920 status flag 0 */
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
/* Get flags for VFO status */
err = ft920_get_update_data(rig, FT920_NATIVE_STATUS_FLAGS,
FT920_STATUS_FLAGS_LENGTH);
if (err != RIG_OK)
{
return err;
}
/*
* The FT-920 status gives two flags for PTT, one if the PTT
* line is grounded externally and the other if the PTT line
* is grounded as the result of a CAT command. However, the
* 7th bit of status byte 0 is set or cleared in each case
* and gives an accurate state of the PTT line.
*/
stat_0 = priv->update_data[FT920_SUMO_DISPLAYED_STATUS_0];
stat_0 &= SF_PTT_MASK; /* get external PTT active bit */
rig_debug(RIG_DEBUG_TRACE, "%s: stat_0 = 0x%02x\n", __func__, stat_0);
switch (stat_0)
{
case SF_PTT_OFF:
*ptt = RIG_PTT_OFF;
break;
case SF_PTT_ON:
*ptt = RIG_PTT_ON;
break;
default: /* Oops! */
return -RIG_EINVAL; /* Invalid PTT bit?! */
}
return RIG_OK;
}
/*
* rig_set_func*
*
* Set rig function
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* func | input | TUNER
* status | input | 0 = bypass, 1 =inline, 2 = start tuning
* | | (toggle)
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Set the tuner to on, off, or start
*/
static int ft920_set_func(RIG *rig, vfo_t vfo, setting_t func, int status)
{
struct ft920_priv_data *priv;
unsigned char cmd_index;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = %s, func = %s, status = %d\n",
__func__, rig_strvfo(vfo), rig_strfunc(func), status);
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE,
"%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
else if (vfo != priv->current_vfo)
{
ft920_set_vfo(rig, vfo);
}
switch (func)
{
case RIG_FUNC_TUNER:
switch (status)
{
case TUNER_BYPASS:
cmd_index = FT920_NATIVE_TUNER_BYPASS;
break;
case TUNER_INLINE:
cmd_index = FT920_NATIVE_TUNER_INLINE;
break;
case TUNER_TUNING:
cmd_index = FT920_NATIVE_TUNER_START;
break;
default:
return -RIG_EINVAL; /* wrong tuner status! */
}
break;
default:
return -RIG_EINVAL; /* wrong function! */
}
err = ft920_send_static_cmd(rig, cmd_index);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* rig_get_func*
*
* Get rig function
*
* Parameter | Type | Accepted/expected values
* ------------------------------------------------------------------
* *rig | input | pointer to private data
* vfo | input | currVFO, VFOA, VFOB, MEM
* func | input | TUNER
* *status | output | 0 = bypass, 1 = inline, 2 = tuning
* ------------------------------------------------------------------
* Returns RIG_OK on success or an error code on failure
*
* Comments: Read the tuner status from status flags
*/
static int ft920_get_func(RIG *rig, vfo_t vfo, setting_t func, int *status)
{
struct ft920_priv_data *priv;
unsigned char stat_0, stat_2; /* ft920 status flags 0, 2 */
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = %s, func = %s\n",
__func__, rig_strvfo(vfo), rig_strfunc(func));
if (vfo == RIG_VFO_CURR)
{
vfo = priv->current_vfo; /* from previous vfo cmd */
rig_debug(RIG_DEBUG_TRACE,
"%s: priv->current_vfo = 0x%02x\n", __func__, vfo);
}
else if (vfo != priv->current_vfo)
{
ft920_set_vfo(rig, vfo);
}
/* Get flags for VFO status */
err = ft920_get_update_data(rig, FT920_NATIVE_STATUS_FLAGS,
FT920_STATUS_FLAGS_LENGTH);
if (err != RIG_OK)
{
return err;
}
/*
* The FT-920 status gives three flags for the tuner state,
* one if the tuner is On/tuning, another if the tuner is
* "inline" and the last if the "WAIT" light is on.
*
* Currently, will only check if tuner is tuning and inline.
*/
stat_0 = priv->update_data[FT920_SUMO_DISPLAYED_STATUS_0];
// stat_0 &= SF_TUNER_TUNE; /* get tuning state */
stat_2 = priv->update_data[FT920_SUMO_DISPLAYED_STATUS_2];
// stat_2 &= SF_TUNER_INLINE; /* get tuner inline state */
rig_debug(RIG_DEBUG_TRACE, "%s: stat_0 = 0x%02x, stat_2 = 0x%02x\n",
__func__, stat_0, stat_2);
switch (func)
{
case RIG_FUNC_TUNER:
if (stat_0 & SF_TUNER_TUNE)
{
*status = TUNER_TUNING;
}
else if (stat_2 & SF_TUNER_INLINE)
{
*status = TUNER_INLINE;
}
else
{
*status = TUNER_BYPASS;
}
break;
case RIG_FUNC_LOCK:
switch (vfo)
{
case RIG_VFO_A:
if (stat_2 & SF_VFOA_LOCK)
{
*status = TRUE;
}
else
{
*status = FALSE;
}
break;
case RIG_VFO_B:
if (stat_2 & SF_VFOB_LOCK)
{
*status = TRUE;
}
else
{
*status = FALSE;
}
break;
}
break;
default:
return -RIG_EINVAL; /* wrong function! */
}
return RIG_OK;
}
/*
* ************************************
*
* Private functions to ft920 backend
*
* ************************************
*/
/*
* Private helper function to retrieve update data from rig.
* using pacing value and buffer indicated in *priv struct.
* Extended to be command agnostic as 920 has several ways to
* get data and several ways to return it.
*
* Need to use this when doing ft920_get_* stuff
*
* Arguments: *rig Valid RIG instance
* ci command index
* rl expected length of returned data in octets
*
* Returns: RIG_OK if all called functions are successful,
* otherwise returns error from called function
*/
static int ft920_get_update_data(RIG *rig, unsigned char ci, unsigned char rl)
{
struct ft920_priv_data *priv;
int n; /* for read_ */
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
priv = (struct ft920_priv_data *)rig->state.priv;
err = ft920_send_static_cmd(rig, ci);
if (err != RIG_OK)
{
return err;
}
n = read_block(&rig->state.rigport, priv->update_data, rl);
if (n < 0)
{
return n; /* die returning read_block error */
}
rig_debug(RIG_DEBUG_TRACE, "%s: read %i bytes\n", __func__, n);
return RIG_OK;
}
/*
* Private helper function to send a complete command sequence.
*
* TODO: place variant of this in yaesu.c
*
* Arguments: *rig Valid RIG instance
* ci Command index of the ncmd table
*
* Returns: RIG_OK if all called functions are successful,
* otherwise returns error from called function
*/
static int ft920_send_static_cmd(RIG *rig, unsigned char ci)
{
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
/*
* If we've been passed a command index (ci) that is marked
* as dynamic (0), then bail out.
*/
if (!ncmd[ci].ncomp)
{
rig_debug(RIG_DEBUG_TRACE, "%s: Attempt to send incomplete sequence\n",
__func__);
return -RIG_EINVAL;
}
err = write_block(&rig->state.rigport, ncmd[ci].nseq, YAESU_CMD_LENGTH);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* Private helper function to build and then send a complete command
* sequence.
*
* TODO: place variant of this in yaesu.c
*
* Arguments: *rig Valid RIG instance
* ci Command index of the ncmd table
* p1-p4 Command parameters
*
* Returns: RIG_OK if all called functions are successful,
* otherwise returns error from called function
*/
static int ft920_send_dynamic_cmd(RIG *rig, unsigned char ci,
unsigned char p1, unsigned char p2,
unsigned char p3, unsigned char p4)
{
struct ft920_priv_data *priv;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed ci = %i\n", __func__, ci);
rig_debug(RIG_DEBUG_TRACE,
"%s: passed p1 = 0x%02x, p2 = 0x%02x, p3 = 0x%02x, p4 = 0x%02x,\n",
__func__, p1, p2, p3, p4);
priv = (struct ft920_priv_data *)rig->state.priv;
/*
* If we've been passed a command index (ci) that is marked
* as static (1), then bail out.
*/
if (ncmd[ci].ncomp)
{
rig_debug(RIG_DEBUG_TRACE,
"%s: Attempted to modify a complete command sequence: %i\n",
__func__, ci);
return -RIG_EINVAL;
}
memcpy(&priv->p_cmd, &ncmd[ci].nseq, YAESU_CMD_LENGTH);
priv->p_cmd[P1] = p1; /* ick */
priv->p_cmd[P2] = p2;
priv->p_cmd[P3] = p3;
priv->p_cmd[P4] = p4;
err = write_block(&rig->state.rigport, (unsigned char *) &priv->p_cmd,
YAESU_CMD_LENGTH);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* Private helper function to build and send a complete command to
* change the Main or Sub display frequency.
*
* TODO: place variant of this in yaesu.c
*
* Arguments: *rig Valid RIG instance
* ci Command index of the ncmd table
* freq freq_t frequency value
*
* Returns: RIG_OK if all called functions are successful,
* otherwise returns error from called function
*/
static int ft920_send_dial_freq(RIG *rig, unsigned char ci, freq_t freq)
{
struct ft920_priv_data *priv;
int err;
// cppcheck-suppress *
char *fmt = "%s: requested freq after conversion = %"PRIll" Hz\n";
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed ci = %i\n", __func__, ci);
rig_debug(RIG_DEBUG_TRACE, "%s: passed freq = %"PRIfreq" Hz\n", __func__, freq);
priv = (struct ft920_priv_data *)rig->state.priv;
/*
* If we've been passed a command index (ci) that is marked
* as static (1), then bail out.
*/
if (ncmd[ci].ncomp)
{
rig_debug(RIG_DEBUG_TRACE, "%s: Attempt to modify complete sequence\n",
__func__);
return -RIG_EINVAL;
}
/* Copy native cmd freq_set to private cmd storage area */
memcpy(&priv->p_cmd, &ncmd[ci].nseq, YAESU_CMD_LENGTH);
/* store bcd format in in p_cmd */
to_bcd(priv->p_cmd, freq / 10, FT920_BCD_DIAL);
rig_debug(RIG_DEBUG_TRACE, fmt, __func__, (int64_t)from_bcd(priv->p_cmd,
FT920_BCD_DIAL) * 10);
err = write_block(&rig->state.rigport, (unsigned char *) &priv->p_cmd,
YAESU_CMD_LENGTH);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
/*
* Private helper function to build and send a complete command to
* change the RIT/XIT frequency.
*
* TODO: place variant of this in yaesu.c
*
* Arguments: *rig Valid RIG instance
* ci Command index of the ncmd table
* rit shortfreq_t frequency value
* p1 P1 value -- CLAR_SET_FREQ
* p2 P2 value -- CLAR_OFFSET_PLUS || CLAR_OFFSET_MINUS
*
* Returns: RIG_OK if all called functions are successful,
* otherwise returns error from called function
*
* Assumes: rit doesn't exceed tuning limits of rig
*/
static int ft920_send_rit_freq(RIG *rig, unsigned char ci, shortfreq_t rit)
{
struct ft920_priv_data *priv;
unsigned char p1;
unsigned char p2;
int err;
rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__);
if (!rig)
{
return -RIG_EINVAL;
}
rig_debug(RIG_DEBUG_TRACE, "%s: passed ci = %i\n", __func__, ci);
rig_debug(RIG_DEBUG_TRACE, "%s: passed rit = %li Hz\n", __func__, rit);
priv = (struct ft920_priv_data *)rig->state.priv;
/*
* If we've been passed a command index (ci) that is marked
* as static (1), then bail out.
*/
if (ncmd[ci].ncomp)
{
rig_debug(RIG_DEBUG_TRACE, "%s: Attempt to modify complete sequence\n",
__func__);
return -RIG_EINVAL;
}
p1 = CLAR_SET_FREQ;
if (rit < 0)
{
rit = labs(rit); /* get absolute value of rit */
p2 = CLAR_OFFSET_MINUS;
}
else
{
p2 = CLAR_OFFSET_PLUS;
}
/* Copy native cmd clarifier ops to private cmd storage area */
memcpy(&priv->p_cmd, &ncmd[ci].nseq, YAESU_CMD_LENGTH);
/* store bcd format in in p_cmd */
to_bcd(priv->p_cmd, rit / 10, FT920_BCD_RIT);
rig_debug(RIG_DEBUG_TRACE, "%s: requested rit after conversion = %d Hz\n",
__func__, (int)from_bcd(priv->p_cmd, FT920_BCD_RIT) * 10);
priv->p_cmd[P1] = p1; /* ick */
priv->p_cmd[P2] = p2;
err = write_block(&rig->state.rigport, (unsigned char *) &priv->p_cmd,
YAESU_CMD_LENGTH);
if (err != RIG_OK)
{
return err;
}
return RIG_OK;
}
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