/* * hamlib - (C) Stephane Fillod 2002-2010 (fillods at users.sourceforge.net) * (C) Terry Embry 2009 * * ft990.c - (C) Berndt Josef Wulf (wulf at ping.net.au) * * This shared library provides an API for communicating * via serial interface to an FT-990 using the "CAT" interface * * * 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 * */ /* THIS FILE WAS MODIFIED IN DECEMBER 2016 TO REMOVE ANY REFERENCE TO THE FT-1000/D. SEPARATE ft1000d.c and .h FILES * WERE CREATED TO HANDLE FT-1000/D COMMANDS AND PROVIDE THE FULL RANGE OF FUNCTIONS AVAILABLE ON THE FT-1000/D * TO MAXIMISE COMPATIBILITY WITH RIGCTL. * G0OAN */ /* MODIFIED VERSION for FT-990 with ROM v1.2 : June 2022 * The standard version was written for FT-990 with ROM v1.3 and as the CAT spec was different to ROM v1.2 CAT * would not work with the older ROM. This version enables ROM v1.2 to work although it is necessary to accept * that frequent polling functionality is not feasible with this older ROM. With ROM v1.2 polling fetches 1492 * bytes which at 4800 Baud takes about 3.8 seconds during which the FT-990 has a CAT blackout. The longest poll * interval available in WSJT-X is 99 seconds. * Collaboration between M0EZP David Brewerton and K1MMI Edmund Hajjar */ #include #include #include /* String function definitions */ #include /* UNIX standard function definitions */ #include "hamlib/rig.h" #include "bandplan.h" #include "serial.h" #include "misc.h" #include "yaesu.h" #include "ft990.h" // FT990 native commands enum ft990_native_cmd_e { FT990_NATIVE_SPLIT_OFF = 0, FT990_NATIVE_SPLIT_ON, FT990_NATIVE_RECALL_MEM, FT990_NATIVE_VFO_TO_MEM, FT990_NATIVE_LOCK_OFF, FT990_NATIVE_LOCK_ON, FT990_NATIVE_VFO_A, FT990_NATIVE_VFO_B, FT990_NATIVE_MEM_TO_VFO, FT990_NATIVE_VFO_STEP_UP, FT990_NATIVE_VFO_STEP_UP_FAST, FT990_NATIVE_VFO_STEP_DOWN, FT990_NATIVE_VFO_STEP_DOWN_FAST, FT990_NATIVE_RX_CLARIFIER_OFF, FT990_NATIVE_RX_CLARIFIER_ON, FT990_NATIVE_TX_CLARIFIER_OFF, FT990_NATIVE_TX_CLARIFIER_ON, FT990_NATIVE_CLEAR_CLARIFIER_OFFSET, FT990_NATIVE_CLARIFIER_OPS, FT990_NATIVE_FREQ_SET, FT990_NATIVE_MODE_SET_LSB, FT990_NATIVE_MODE_SET_USB, FT990_NATIVE_MODE_SET_CW_W, FT990_NATIVE_MODE_SET_CW_N, FT990_NATIVE_MODE_SET_AM_W, FT990_NATIVE_MODE_SET_AM_N, FT990_NATIVE_MODE_SET_FM, FT990_NATIVE_MODE_SET_RTTY_LSB, FT990_NATIVE_MODE_SET_RTTY_USB, FT990_NATIVE_MODE_SET_PKT_LSB, FT990_NATIVE_MODE_SET_PKT_FM, FT990_NATIVE_PACING, FT990_NATIVE_PTT_OFF, FT990_NATIVE_PTT_ON, FT990_NATIVE_UPDATE_ALL_DATA, FT990_NATIVE_UPDATE_MEM_CHNL, FT990_NATIVE_UPDATE_OP_DATA, FT990_NATIVE_UPDATE_VFO_DATA, FT990_NATIVE_UPDATE_MEM_CHNL_DATA, FT990_NATIVE_TUNER_OFF, FT990_NATIVE_TUNER_ON, FT990_NATIVE_TUNER_START, FT990_NATIVE_RPTR_SHIFT_NONE, FT990_NATIVE_RPTR_SHIFT_MINUS, FT990_NATIVE_RPTR_SHIFT_PLUS, FT990_NATIVE_VFO_TO_VFO, FT990_NATIVE_BANDWIDTH, FT990_NATIVE_OP_FREQ_STEP_UP, FT990_NATIVE_OP_FREQ_STEP_DOWN, FT990_NATIVE_READ_METER, FT990_NATIVE_DIM_LEVEL, FT990_NATIVE_RPTR_OFFSET, FT990_NATIVE_READ_FLAGS, FT990_NATIVE_SIZE }; /* HAMLIB API implementation */ static int ft990_init(RIG *rig); static int ft990_cleanup(RIG *rig); static int ft990_open(RIG *rig); static int ft990_close(RIG *rig); static int ft990_set_freq(RIG *rig, vfo_t vfo, freq_t freq); static int ft990_get_freq(RIG *rig, vfo_t vfo, freq_t *freq); static int ft990_set_mode(RIG *rig, vfo_t vfo, rmode_t mode, pbwidth_t width); static int ft990_get_mode(RIG *rig, vfo_t vfo, rmode_t *mode, pbwidth_t *width); static int ft990_set_vfo(RIG *rig, vfo_t vfo); static int ft990_get_vfo(RIG *rig, vfo_t *vfo); static int ft990_set_ptt(RIG *rig, vfo_t vfo, ptt_t ptt); static int ft990_get_ptt(RIG *rig, vfo_t vfo, ptt_t *ptt); static int ft990_set_rptr_shift(RIG *rig, vfo_t vfo, rptr_shift_t rptr_shift); static int ft990_get_rptr_shift(RIG *rig, vfo_t vfo, rptr_shift_t *rptr_shift); static int ft990_set_rptr_offs(RIG *rig, vfo_t vfo, shortfreq_t offs); static int ft990_set_split_vfo(RIG *rig, vfo_t vfo, split_t split, vfo_t tx_vfo); static int ft990_get_split_vfo(RIG *rig, vfo_t vfo, split_t *split, vfo_t *tx_vfo); static int ft990_set_rit(RIG *rig, vfo_t vfo, shortfreq_t rit); static int ft990_get_rit(RIG *rig, vfo_t vfo, shortfreq_t *rit); static int ft990_set_func(RIG *rig, vfo_t vfo, setting_t func, int status); static int ft990_get_func(RIG *rig, vfo_t vfo, setting_t func, int *status); static int ft990_set_parm(RIG *rig, setting_t parm, value_t val); static int ft990_set_xit(RIG *rig, vfo_t vfo, shortfreq_t xit); static int ft990_get_xit(RIG *rig, vfo_t vfo, shortfreq_t *xit); static int ft990_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *val); static int ft990_vfo_op(RIG *rig, vfo_t vfo, vfo_op_t op); static int ft990_set_mem(RIG *rig, vfo_t vfo, int ch); static int ft990_get_mem(RIG *rig, vfo_t vfo, int *ch); static int ft990_set_channel(RIG *rig, vfo_t vfo, const channel_t *chan); static int ft990_get_channel(RIG *rig, vfo_t vfo, channel_t *chan, int read_only); /* Private helper function prototypes */ static int ft990_get_update_data(RIG *rig, unsigned char ci, unsigned short ch); static int ft990_send_static_cmd(RIG *rig, unsigned char ci); static int ft990_send_dynamic_cmd(RIG *rig, unsigned char ci, unsigned char p1, unsigned char p2, unsigned char p3, unsigned char p4); static int ft990_send_dial_freq(RIG *rig, unsigned char ci, freq_t freq); static int ft990_send_rit_freq(RIG *rig, unsigned char ci, shortfreq_t rit); static const yaesu_cmd_set_t ncmd[] = { /* ci */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x01 } }, /* 00 00 Split (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x01 } }, /* 01 01 Split (On) */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x02 } }, /* 02 02 Recall Memory */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x03 } }, /* 03 03 Memory Operations */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x04 } }, /* 04 04 Lock (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x04 } }, /* 05 05 Lock (ON) */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x05 } }, /* 06 06 Select VFO (A) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x05 } }, /* 07 07 Select VFO (B) */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x06 } }, /* 08 08 Copy Memory Data to VFO A */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x07 } }, /* 09 09 OP Freq Up 0.1MHz */ { 1, { 0x00, 0x00, 0x01, 0x00, 0x07 } }, /* 10 0a OP Freq Up 1MHz */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x08 } }, /* 11 0b OP Freq Down 0.1MHz */ { 1, { 0x00, 0x00, 0x01, 0x00, 0x08 } }, /* 12 0c OP Freq Down 1MHz */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x09 } }, /* 13 0d RX Clarifier (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x09 } }, /* 14 0e RX Clarifier (ON) */ { 1, { 0x00, 0x00, 0x00, 0x80, 0x09 } }, /* 15 0f TX Clarifier (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x81, 0x09 } }, /* 16 10 TX Clarifier (ON) */ { 1, { 0x00, 0x00, 0x00, 0xff, 0x09 } }, /* 17 11 Clear Clarifier Offset */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x09 } }, /* 18 12 Clarifier */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x0a } }, /* 19 13 Set Op Freq */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x0c } }, /* 20 14 OP Mode Set LSB */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x0c } }, /* 21 15 OP Mode Set USB */ { 1, { 0x00, 0x00, 0x00, 0x02, 0x0c } }, /* 22 16 OP Mode Set CW 2.4KHz */ { 1, { 0x00, 0x00, 0x00, 0x03, 0x0c } }, /* 23 17 OP Mode Set CW 500Hz */ { 1, { 0x00, 0x00, 0x00, 0x04, 0x0c } }, /* 24 18 OP Mode Set AM 6KHz */ { 1, { 0x00, 0x00, 0x00, 0x05, 0x0c } }, /* 25 19 OP Mode Set AM 2.4KHz */ { 1, { 0x00, 0x00, 0x00, 0x06, 0x0c } }, /* 26 1a OP Mode Set FM */ { 1, { 0x00, 0x00, 0x00, 0x08, 0x0c } }, /* 27 1b OP Mode Set RTTY LSB */ { 1, { 0x00, 0x00, 0x00, 0x09, 0x0c } }, /* 28 1c OP Mode Set RTTY USB */ { 1, { 0x00, 0x00, 0x00, 0x0a, 0x0c } }, /* 29 1d OP Mode Set PKT LSB */ { 1, { 0x00, 0x00, 0x00, 0x0b, 0x0c } }, /* 30 1e OP Mode Set PKT FM */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x0e } }, /* 31 1f Pacing */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x0f } }, /* 32 20 PTT (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x0f } }, /* 33 21 PTT (ON) */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x10 } }, /* 34 22 Update All Data (1492 bytes) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x10 } }, /* 35 23 Update Memory Ch Number M0EZP: 2ndByte was 0x01 */ { 1, { 0x00, 0x00, 0x00, 0x02, 0x10 } }, /* 36 24 Update Op Data M0EZP: 2ndByte was 0x02 */ { 1, { 0x00, 0x00, 0x00, 0x03, 0x10 } }, /* 37 25 Update VFO Data M0EZP: 2ndByte was 0x03 */ { 0, { 0x00, 0x00, 0x00, 0x04, 0x10 } }, /* 38 26 Update Memory Ch Data M0EZP: 2ndByte was 0x04 */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x81 } }, /* 39 27 Tuner (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x81 } }, /* 40 28 Tuner (ON) */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x82 } }, /* 41 29 Tuner (Start) */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x84 } }, /* 42 2a Repeater Mode (OFF) */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x84 } }, /* 43 2b Repeater Mode (Minus) */ { 1, { 0x00, 0x00, 0x00, 0x02, 0x84 } }, /* 44 2c Repeater Mode (Plus) */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x85 } }, /* 45 2d Copy displayed VFO (A=B || B=A) */ { 0, { 0x00, 0x00, 0x00, 0x00, 0x8C } }, /* 46 2e Select Bandwidth */ { 1, { 0x00, 0x00, 0x00, 0x00, 0x8E } }, /* 47 2f Step Operating Frequency Up */ { 1, { 0x00, 0x00, 0x00, 0x01, 0x8E } }, /* 48 30 Step Operating Frequency Down */ { 1, { 0x00, 0x00, 0x00, 0x00, 0xf7 } }, /* 49 31 Read Meter */ { 0, { 0x00, 0x00, 0x00, 0x00, 0xf8 } }, /* 50 32 DIM Level */ { 0, { 0x00, 0x00, 0x00, 0x00, 0xf9 } }, /* 51 33 Set Offset for Repeater Shift */ { 1, { 0x00, 0x00, 0x00, 0x00, 0xfa } }, /* 52 34 Read Status Flags */ }; /* * Private data */ // M0EZP: status 0=uni first call, 1=uni after first call int ft990uni_get_freq_state = 0; struct ft990_priv_data { unsigned char pacing; /* pacing value */ vfo_t current_vfo; /* active VFO from last cmd */ unsigned char p_cmd[YAESU_CMD_LENGTH]; /* private copy of CAT cmd */ ft990_update_data_t update_data; /* returned data */ }; /* * ft990 rigs capabilities. */ #define FT990_MEM_CAP { \ .freq = 1, \ .mode = 1, \ .width = 1, \ .rit = 1, \ .xit = 1, \ .rptr_shift = 1, \ .flags = 1, \ } const struct rig_caps ft990_caps = { RIG_MODEL(RIG_MODEL_FT990), .model_name = "FT-990", .mfg_name = "Yaesu", .version = "20211231.0", .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 = FT990_WRITE_DELAY, .post_write_delay = FT990_POST_WRITE_DELAY, .timeout = 2000, .retry = 0, .has_get_func = RIG_FUNC_LOCK | RIG_FUNC_TUNER | RIG_FUNC_MON, .has_set_func = RIG_FUNC_LOCK | RIG_FUNC_TUNER, .has_get_level = RIG_LEVEL_STRENGTH | RIG_LEVEL_SWR | RIG_LEVEL_ALC | \ RIG_LEVEL_RFPOWER | RIG_LEVEL_COMP, .has_set_level = RIG_LEVEL_BAND_SELECT, .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_BACKLIGHT, .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(1200), .vfo_ops = RIG_OP_CPY | RIG_OP_FROM_VFO | RIG_OP_TO_VFO | RIG_OP_UP | RIG_OP_DOWN | RIG_OP_TUNE | RIG_OP_TOGGLE, .targetable_vfo = RIG_TARGETABLE_ALL, .transceive = RIG_TRN_OFF, /* Yaesus have to be polled, sigh */ .bank_qty = 0, .chan_desc_sz = 0, .chan_list = { {1, 90, RIG_MTYPE_MEM, FT990_MEM_CAP}, RIG_CHAN_END, }, .rx_range_list1 = { {kHz(100), MHz(30), FT990_ALL_RX_MODES, -1, -1, FT990_VFO_ALL, FT990_ANTS}, /* General coverage + ham */ RIG_FRNG_END, }, .tx_range_list1 = { FRQ_RNG_HF(1, FT990_OTHER_TX_MODES, W(5), W(100), FT990_VFO_ALL, FT990_ANTS), FRQ_RNG_HF(1, FT990_AM_TX_MODES, W(2), W(25), FT990_VFO_ALL, FT990_ANTS), /* AM class */ RIG_FRNG_END, }, .rx_range_list2 = { {kHz(100), MHz(30), FT990_ALL_RX_MODES, -1, -1, FT990_VFO_ALL, FT990_ANTS}, RIG_FRNG_END, }, .tx_range_list2 = { FRQ_RNG_HF(2, FT990_OTHER_TX_MODES, W(5), W(100), FT990_VFO_ALL, FT990_ANTS), FRQ_RNG_HF(2, FT990_AM_TX_MODES, W(2), W(25), FT990_VFO_ALL, FT990_ANTS), /* AM class */ RIG_FRNG_END, }, .tuning_steps = { {FT990_SSB_CW_RX_MODES, Hz(10)}, /* Normal */ {FT990_SSB_CW_RX_MODES, Hz(100)}, /* Fast */ {FT990_AM_RX_MODES, Hz(100)}, /* Normal */ {FT990_AM_RX_MODES, kHz(1)}, /* Fast */ {FT990_FM_RX_MODES, Hz(100)}, /* Normal */ {FT990_FM_RX_MODES, kHz(1)}, /* Fast */ {FT990_RTTY_RX_MODES, Hz(10)}, /* Normal */ {FT990_RTTY_RX_MODES, Hz(100)}, /* Fast */ RIG_TS_END, }, /* mode/filter list, .remember = order matters! */ .filters = { {RIG_MODE_SSB, RIG_FLT_ANY}, /* Enable all filters for SSB */ {RIG_MODE_CW, RIG_FLT_ANY}, /* Enable all filters for CW */ {RIG_MODE_RTTY, RIG_FLT_ANY}, /* Enable all filters for RTTY */ {RIG_MODE_RTTYR, RIG_FLT_ANY}, /* Enable all filters for Reverse RTTY */ {RIG_MODE_PKTLSB, RIG_FLT_ANY}, /* Enable all filters for Packet Radio LSB */ {RIG_MODE_AM, kHz(6)}, /* normal AM filter */ {RIG_MODE_AM, kHz(2.4)}, /* narrow AM filter */ {RIG_MODE_FM, kHz(8)}, /* FM standard filter */ {RIG_MODE_PKTFM, kHz(8)}, /* FM standard filter for Packet Radio FM */ RIG_FLT_END, }, .priv = NULL, /* private data FIXME: */ .rig_init = ft990_init, .rig_cleanup = ft990_cleanup, .rig_open = ft990_open, /* port opened */ .rig_close = ft990_close, /* port closed */ .set_freq = ft990_set_freq, .get_freq = ft990_get_freq, .set_mode = ft990_set_mode, .get_mode = ft990_get_mode, .set_vfo = ft990_set_vfo, .get_vfo = ft990_get_vfo, .set_ptt = ft990_set_ptt, .get_ptt = ft990_get_ptt, .set_rptr_shift = ft990_set_rptr_shift, .get_rptr_shift = ft990_get_rptr_shift, .set_rptr_offs = ft990_set_rptr_offs, .set_split_vfo = ft990_set_split_vfo, .get_split_vfo = ft990_get_split_vfo, .set_rit = ft990_set_rit, .get_rit = ft990_get_rit, .set_xit = ft990_set_xit, .get_xit = ft990_get_xit, .set_func = ft990_set_func, .get_func = ft990_get_func, .set_parm = ft990_set_parm, .get_level = ft990_get_level, .set_mem = ft990_set_mem, .get_mem = ft990_get_mem, .vfo_op = ft990_vfo_op, .set_channel = ft990_set_channel, .get_channel = ft990_get_channel, .hamlib_check_rig_caps = HAMLIB_CHECK_RIG_CAPS }; // Old FT990 ROM has to read all 1492 to get frequency // So for this model we just use the cache to read freq const struct rig_caps ft990uni_caps = { RIG_MODEL(RIG_MODEL_FT990UNI), .model_name = "FT-990 Old Rom", .mfg_name = "Yaesu", .version = "20220628.0", .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 = FT990_WRITE_DELAY, .post_write_delay = FT990_POST_WRITE_DELAY, .timeout = 2000, .retry = 0, .has_get_func = RIG_FUNC_LOCK | RIG_FUNC_TUNER | RIG_FUNC_MON, .has_set_func = RIG_FUNC_LOCK | RIG_FUNC_TUNER, .has_get_level = RIG_LEVEL_STRENGTH | RIG_LEVEL_SWR | RIG_LEVEL_ALC | \ RIG_LEVEL_RFPOWER | RIG_LEVEL_COMP, .has_set_level = RIG_LEVEL_BAND_SELECT, .has_get_parm = RIG_PARM_NONE, .has_set_parm = RIG_PARM_BACKLIGHT, .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(1200), .vfo_ops = RIG_OP_CPY | RIG_OP_FROM_VFO | RIG_OP_TO_VFO | RIG_OP_UP | RIG_OP_DOWN | RIG_OP_TUNE | RIG_OP_TOGGLE, .targetable_vfo = RIG_TARGETABLE_ALL, .transceive = RIG_TRN_OFF, /* Yaesus have to be polled, sigh */ .bank_qty = 0, .chan_desc_sz = 0, .chan_list = { {1, 90, RIG_MTYPE_MEM, FT990_MEM_CAP}, RIG_CHAN_END, }, .rx_range_list1 = { {kHz(100), MHz(30), FT990_ALL_RX_MODES, -1, -1, FT990_VFO_ALL, FT990_ANTS}, /* General coverage + ham */ RIG_FRNG_END, }, .tx_range_list1 = { FRQ_RNG_HF(1, FT990_OTHER_TX_MODES, W(5), W(100), FT990_VFO_ALL, FT990_ANTS), FRQ_RNG_HF(1, FT990_AM_TX_MODES, W(2), W(25), FT990_VFO_ALL, FT990_ANTS), /* AM class */ RIG_FRNG_END, }, .rx_range_list2 = { {kHz(100), MHz(30), FT990_ALL_RX_MODES, -1, -1, FT990_VFO_ALL, FT990_ANTS}, RIG_FRNG_END, }, .tx_range_list2 = { FRQ_RNG_HF(2, FT990_OTHER_TX_MODES, W(5), W(100), FT990_VFO_ALL, FT990_ANTS), FRQ_RNG_HF(2, FT990_AM_TX_MODES, W(2), W(25), FT990_VFO_ALL, FT990_ANTS), /* AM class */ RIG_FRNG_END, }, .tuning_steps = { {FT990_SSB_CW_RX_MODES, Hz(10)}, /* Normal */ {FT990_SSB_CW_RX_MODES, Hz(100)}, /* Fast */ {FT990_AM_RX_MODES, Hz(100)}, /* Normal */ {FT990_AM_RX_MODES, kHz(1)}, /* Fast */ {FT990_FM_RX_MODES, Hz(100)}, /* Normal */ {FT990_FM_RX_MODES, kHz(1)}, /* Fast */ {FT990_RTTY_RX_MODES, Hz(10)}, /* Normal */ {FT990_RTTY_RX_MODES, Hz(100)}, /* Fast */ RIG_TS_END, }, /* mode/filter list, .remember = order matters! */ .filters = { {RIG_MODE_SSB, RIG_FLT_ANY}, /* Enable all filters for SSB */ {RIG_MODE_CW, RIG_FLT_ANY}, /* Enable all filters for CW */ {RIG_MODE_RTTY, RIG_FLT_ANY}, /* Enable all filters for RTTY */ {RIG_MODE_RTTYR, RIG_FLT_ANY}, /* Enable all filters for Reverse RTTY */ {RIG_MODE_PKTLSB, RIG_FLT_ANY}, /* Enable all filters for Packet Radio LSB */ {RIG_MODE_AM, kHz(6)}, /* normal AM filter */ {RIG_MODE_AM, kHz(2.4)}, /* narrow AM filter */ {RIG_MODE_FM, kHz(8)}, /* FM standard filter */ {RIG_MODE_PKTFM, kHz(8)}, /* FM standard filter for Packet Radio FM */ RIG_FLT_END, }, .priv = NULL, /* private data FIXME: */ .rig_init = ft990_init, .rig_cleanup = ft990_cleanup, .rig_open = ft990_open, /* port opened */ .rig_close = ft990_close, /* port closed */ .set_freq = ft990_set_freq, .get_freq = ft990_get_freq, .set_mode = ft990_set_mode, .get_mode = ft990_get_mode, .set_vfo = ft990_set_vfo, .get_vfo = ft990_get_vfo, .set_ptt = ft990_set_ptt, .get_ptt = ft990_get_ptt, .set_rptr_shift = ft990_set_rptr_shift, .get_rptr_shift = ft990_get_rptr_shift, .set_rptr_offs = ft990_set_rptr_offs, .set_split_vfo = ft990_set_split_vfo, .get_split_vfo = ft990_get_split_vfo, .set_rit = ft990_set_rit, .get_rit = ft990_get_rit, .set_xit = ft990_set_xit, .get_xit = ft990_get_xit, .set_func = ft990_set_func, .get_func = ft990_get_func, .set_parm = ft990_set_parm, .get_level = ft990_get_level, .set_mem = ft990_set_mem, .get_mem = ft990_get_mem, .vfo_op = ft990_vfo_op, .set_channel = ft990_set_channel, .get_channel = ft990_get_channel, .hamlib_check_rig_caps = HAMLIB_CHECK_RIG_CAPS }; /* * ************************************ * * Hamlib API functions * * ************************************ */ /* * rig_init */ int ft990_init(RIG *rig) { struct ft990_priv_data *priv; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } rig->state.priv = (struct ft990_priv_data *) calloc(1, sizeof(struct ft990_priv_data)); if (!rig->state.priv) { return -RIG_ENOMEM; } priv = rig->state.priv; // Set default pacing value priv->pacing = FT990_PACING_DEFAULT_VALUE; // Set operating vfo mode to current VFO priv->current_vfo = RIG_VFO_MAIN; return RIG_OK; } /* * rig_cleanup */ int ft990_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 */ int ft990_open(RIG *rig) { struct rig_state *rig_s; struct ft990_priv_data *priv; int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } priv = (struct ft990_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); rig_debug(RIG_DEBUG_TRACE, "%s: read pacing = %i\n", __func__, priv->pacing); err = ft990_send_dynamic_cmd(rig, FT990_NATIVE_PACING, priv->pacing, 0, 0, 0); if (err != RIG_OK) { return err; } // Get current rig settings and status // err = ft990_get_update_data(rig, FT990_NATIVE_UPDATE_OP_DATA, 0); // M0EZP read flags instead of update err = ft990_get_update_data(rig, FT990_NATIVE_READ_FLAGS, 0); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_close */ int ft990_close(RIG *rig) { rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } return RIG_OK; } /* * rig_set_freq* * * Set frequency for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * freq | input | 100000 - 30000000 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_set_freq(RIG *rig, vfo_t vfo, freq_t freq) { struct ft990_priv_data *priv; int err; vfo_t vfo_save; 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__, freq); // Frequency range sanity check if (freq < 100000 || freq > 30000000) { return -RIG_EINVAL; } priv = (struct ft990_priv_data *)rig->state.priv; vfo_save = priv->current_vfo; // Set to selected VFO if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } else { if (vfo != vfo_save) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } err = ft990_send_dial_freq(rig, FT990_NATIVE_FREQ_SET, freq); if (err != RIG_OK) { return err; } if (vfo != vfo_save) { err = ft990_set_vfo(rig, vfo_save); if (err != RIG_OK) { return err; } } return RIG_OK; } /* * rig_get_freq* * * Get frequency for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, Main, VFO, VFOA, VFOB, MEM * freq * | output | 100000 - 30000000 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_get_freq(RIG *rig, vfo_t vfo, freq_t *freq) { struct ft990_priv_data *priv; unsigned char *p; freq_t f; int err; int ci; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); rig_debug(RIG_DEBUG_TRACE, "%s: passed vfo = 0x%02x\n", __func__, vfo); rig_debug(RIG_DEBUG_TRACE, "%s: ft990uni_get_freq_state = 0x%02x\n", __func__, ft990uni_get_freq_state); if (ft990uni_get_freq_state < 2) { // M0EZP: UNI first call needs UPDATE_ALL ft990uni_get_freq_state = ft990uni_get_freq_state + 1; if (!rig) { return -RIG_EINVAL; } priv = (struct ft990_priv_data *)rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } switch (vfo) { case RIG_VFO_A: case RIG_VFO_VFO: p = priv->update_data.vfoa.basefreq; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_B: p = priv->update_data.vfob.basefreq; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_MEM: case RIG_VFO_MAIN: p = priv->update_data.current_front.basefreq; ci = FT990_NATIVE_UPDATE_OP_DATA; break; default: return -RIG_EINVAL; } ci = FT990_NATIVE_UPDATE_ALL_DATA; /* M0EZP: inserted to override CI */ err = ft990_get_update_data(rig, ci, 0); if (err != RIG_OK) { return err; } /* big endian integer */ f = ((((p[0] << 8) + p[1]) << 8) + p[2]) * 10; rig_debug(RIG_DEBUG_TRACE, "%s: p0=0x%02x p1=0x%02x p2=0x%02x\n", __func__, p[0], p[1], p[2]); rig_debug(RIG_DEBUG_TRACE, "%s: freq = %"PRIfreq" Hz for vfo 0x%02x\n", __func__, f, vfo); // Frequency sanity check if (f < 100000 || f > 30000000) { return -RIG_EINVAL; } *freq = f; return RIG_OK; } else { // M0EZP: Uni use cache // *freq = vfo == RIG_VFO_A ? rig->state.cache.freqMainA : rig->state.cache.freqMainB; return (RIG_OK); } } /* * rig_set_ptt* * * Control PTT for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * ptt | input | 0 = off, 1 = off * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_set_ptt(RIG *rig, vfo_t vfo, ptt_t ptt) { struct ft990_priv_data *priv; int err; unsigned char ci; 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 ptt = 0x%02x\n", __func__, ptt); priv = (struct ft990_priv_data *) rig->state.priv; // Set to selected VFO if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } switch (ptt) { case RIG_PTT_ON: ci = FT990_NATIVE_PTT_ON; break; case RIG_PTT_OFF: ci = FT990_NATIVE_PTT_OFF; break; default: return -RIG_EINVAL; } err = ft990_send_static_cmd(rig, ci); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_get_ptt* * * Get PTT line status * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, Main, VFO, VFOA, VFOB, MEM * ptt * | output | 0 = off, 1 = on * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored since the PTT status * is independent from the VFO selection. */ int ft990_get_ptt(RIG *rig, vfo_t vfo, ptt_t *ptt) { struct ft990_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); priv = (struct ft990_priv_data *) rig->state.priv; err = ft990_get_update_data(rig, FT990_NATIVE_READ_FLAGS, 0); if (err != RIG_OK) { return err; } *ptt = ((priv->update_data.flag1 & FT990_SF_XMIT) != 0); rig_debug(RIG_DEBUG_TRACE, "%s: set ptt = 0x%02x\n", __func__, *ptt); return RIG_OK; } /* * rig_set_rptr_shift* * * Set repeater shift for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * freq | input | - = negative repeater shift, * | | + = positive repeater shift, * | | any other character = simplex (is this a bug?) * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. * Repeater shift can only be set when in FM mode. */ int ft990_set_rptr_shift(RIG *rig, vfo_t vfo, rptr_shift_t rptr_shift) { struct ft990_priv_data *priv; unsigned char ci; char *p; 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 rptr_shift = 0x%02x\n", __func__, rptr_shift); priv = (struct ft990_priv_data *) rig->state.priv; // Set to selected VFO if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } // Construct update query switch (vfo) { case RIG_VFO_A: p = (char *) &priv->update_data.vfoa.mode; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_B: p = (char *) &priv->update_data.vfob.mode; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_MEM: p = (char *) &priv->update_data.current_front.mode; ci = FT990_NATIVE_UPDATE_OP_DATA; break; default: return -RIG_EINVAL; } // Get update for selected VFO err = ft990_get_update_data(rig, ci, 0); if (err != RIG_OK) { return err; } rig_debug(RIG_DEBUG_TRACE, "%s: set mode = 0x%02x\n", __func__, *p); // Shift mode settings are only valid in FM mode if ((*p & FT990_MODE_FM) == 0) { return -RIG_EINVAL; } // Construct repeater shift command switch (rptr_shift) { case RIG_RPT_SHIFT_NONE: ci = FT990_NATIVE_RPTR_SHIFT_NONE; break; case RIG_RPT_SHIFT_MINUS: ci = FT990_NATIVE_RPTR_SHIFT_MINUS; break; case RIG_RPT_SHIFT_PLUS: ci = FT990_NATIVE_RPTR_SHIFT_PLUS; break; default: return -RIG_EINVAL; } // Set repeater shift err = ft990_send_static_cmd(rig, ci); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_get_rptr_shift* * * Get repeater shift setting for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, Main, VFO, VFOA, VFOB, MEM * shift * | output | 0 = simplex * | | 1 = negative repeater shift * | | 2 = positive repeater shift * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. * Repeater shift can only be obtained when in FM mode. */ int ft990_get_rptr_shift(RIG *rig, vfo_t vfo, rptr_shift_t *rptr_shift) { struct ft990_priv_data *priv; ft990_op_data_t *p; unsigned char ci; 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 ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } // Construct update query switch (vfo) { case RIG_VFO_A: case RIG_VFO_VFO: p = &priv->update_data.vfoa; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_B: p = &priv->update_data.vfob; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_MEM: case RIG_VFO_MAIN: p = &priv->update_data.current_front; ci = FT990_NATIVE_UPDATE_OP_DATA; break; default: return -RIG_EINVAL; } // Get update for selected VFO err = ft990_get_update_data(rig, ci, 0); if (err != RIG_OK) { return err; } rig_debug(RIG_DEBUG_TRACE, "%s: set mode = 0x%02x\n", __func__, p->mode); // Shift mode settings are only valid in FM mode if (p->mode & FT990_MODE_FM) { *rptr_shift = (p->status & FT990_RPT_MASK) >> 2; } else { return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: set rptr shift = 0x%02x\n", __func__, *rptr_shift); return RIG_OK; } /* * rig_set_rptr_offs* * * Set repeater frequency offset for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * off | input | 0 - 199999 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored since the * repeater frequency offset is independent from the VFO selection. */ int ft990_set_rptr_offs(RIG *rig, vfo_t vfo, shortfreq_t offs) { unsigned char bcd[(int) FT990_BCD_RPTR_OFFSET / 2]; 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 offs = %d\n", __func__, (int)offs); // Check for valid offset if (offs < 0 || offs > 199999) { return -RIG_EINVAL; } to_bcd(bcd, offs / 10, FT990_BCD_RPTR_OFFSET); rig_debug(RIG_DEBUG_TRACE, "%s: set bcd[0] = 0x%02x, bcd[1] = 0x%02x, bcd[2] = 0x%02x\n", __func__, bcd[0], bcd[1], bcd[2]); err = ft990_send_dynamic_cmd(rig, FT990_NATIVE_RPTR_OFFSET, 0, bcd[2], bcd[1], bcd[0]); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_set_split_vfo* * * Set split operation for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * split | input | 0 = off, 1 = on * tx_vfo | input | currVFO, VFOA, VFOB * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo or tx_vfo will use the currently * selected VFO obtained from the priv->current_vfo data structure. * Only VFOA and VFOB are valid assignments for the tx_vfo. * The tx_vfo is loaded first when assigning MEM to vfo to ensure * the correct TX VFO is selected by the rig in split mode. * An error is returned if vfo and tx_vfo are the same. */ int ft990_set_split_vfo(RIG *rig, vfo_t vfo, split_t split, vfo_t tx_vfo) { struct ft990_priv_data *priv; unsigned char ci; 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); priv = (struct ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: vfo = priv->current.vfo = 0x%02x\n", __func__, vfo); } if (tx_vfo == RIG_VFO_CURR) { tx_vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: tx_vfo = priv->current.vfo = 0x%02x\n", __func__, tx_vfo); } // RX VFO and TX VFO cannot be the same, no support for MEM as TX VFO if (vfo == tx_vfo || tx_vfo == RIG_VFO_MEM) { return -RIG_ENTARGET; } // Set TX VFO first if RIG_VFO_MEM selected for RX VFO if (vfo == RIG_VFO_MEM) { err = ft990_set_vfo(rig, tx_vfo); if (err != RIG_OK) { return err; } } // Set RX VFO err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } switch (split) { case RIG_SPLIT_ON: ci = FT990_NATIVE_SPLIT_ON; break; case RIG_SPLIT_OFF: ci = FT990_NATIVE_SPLIT_OFF; break; default: return -RIG_EINVAL; } err = ft990_send_static_cmd(rig, ci); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_get_split_vfo* * * Get split mode status for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, Main, VFO, VFOA, VFOB, MEM * split * | output | 0 = on, 1 = off * tx_vfo * | output | VFOA, VFOB * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored in order to * preserve the current split vfo system settings. */ int ft990_get_split_vfo(RIG *rig, vfo_t vfo, split_t *split, vfo_t *tx_vfo) { struct ft990_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); priv = (struct ft990_priv_data *) rig->state.priv; // Read status flags err = ft990_get_update_data(rig, FT990_NATIVE_READ_FLAGS, 0); if (err != RIG_OK) { return err; } // Get split mode status *split = priv->update_data.flag1 & FT990_SF_SPLIT; rig_debug(RIG_DEBUG_TRACE, "%s: set split = 0x%02x\n", __func__, priv->update_data.flag1); rig_debug(RIG_DEBUG_TRACE, "%s: set split = 0x%02x\n", __func__, *split); // Get transmit vfo switch (priv->current_vfo) { case RIG_VFO_A: *tx_vfo = RIG_VFO_B; break; case RIG_VFO_B: *tx_vfo = RIG_VFO_A; break; case RIG_VFO_MEM: if (priv->update_data.flag1 & FT990_SF_VFOB) { *tx_vfo = RIG_VFO_B; } else { *tx_vfo = RIG_VFO_A; } break; default: return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: set tx_vfo = 0x%02x\n", __func__, *tx_vfo); return RIG_OK; } /* * rig_set_rit* * * Set receiver clarifier offset for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * rit | input | -9999 - 9999 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. * * The following conditions are checked: * * rit = 0 && xit enabled -> disable rit * rit = 0 && xit disabled -> disable rit and set frequency = 0 */ int ft990_set_rit(RIG *rig, vfo_t vfo, shortfreq_t rit) { struct ft990_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 rit = %d\n", __func__, (int)rit); // Check for valid clarifier offset frequency if (rit < -9999 || rit > 9999) { return -RIG_EINVAL; } priv = (struct ft990_priv_data *) rig->state.priv; // Set to selected VFO if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } // If rit = 0 disable RX clarifier if (rit == 0) { err = ft990_get_update_data(rig, FT990_NATIVE_UPDATE_OP_DATA, 0); if (err != RIG_OK) { return err; } if ((priv->update_data.current_front.status & FT990_CLAR_TX_EN) == 0) { err = ft990_send_static_cmd(rig, FT990_NATIVE_CLEAR_CLARIFIER_OFFSET); if (err != RIG_OK) { return err; } } // Disable RX Clarifier err = ft990_send_static_cmd(rig, FT990_NATIVE_RX_CLARIFIER_OFF); if (err != RIG_OK) { return err; } } else { // Enable RX Clarifier err = ft990_send_static_cmd(rig, FT990_NATIVE_RX_CLARIFIER_ON); if (err != RIG_OK) { return err; } // Set RX clarifier offset err = ft990_send_rit_freq(rig, FT990_NATIVE_CLARIFIER_OPS, rit); if (err != RIG_OK) { return err; } } return RIG_OK; } /* * rig_get_rit* * * Get receiver clarifier offset for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * rit * | output | -9999 - 9999 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_get_rit(RIG *rig, vfo_t vfo, shortfreq_t *rit) { struct ft990_priv_data *priv; unsigned char ci; ft990_op_data_t *p; 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 ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo); } // Construct update query switch (vfo) { case RIG_VFO_A: case RIG_VFO_VFO: ci = FT990_NATIVE_UPDATE_VFO_DATA; p = (ft990_op_data_t *) &priv->update_data.vfoa; break; case RIG_VFO_B: ci = FT990_NATIVE_UPDATE_VFO_DATA; p = (ft990_op_data_t *) &priv->update_data.vfob; break; case RIG_VFO_MEM: case RIG_VFO_MAIN: ci = FT990_NATIVE_UPDATE_OP_DATA; p = (ft990_op_data_t *) &priv->update_data.current_front; break; default: return -RIG_EINVAL; } // Get update for selected VFO/MEM err = ft990_get_update_data(rig, ci, 0); if (err != RIG_OK) { return err; } // Clarifier offset is only returned when enabled if (p->status & FT990_CLAR_RX_EN) { *rit = (short)((p->coffset[0] << 8) | p->coffset[1]) * 10; } else { *rit = 0; } rig_debug(RIG_DEBUG_TRACE, "%s: rit freq = %li Hz\n", __func__, *rit); return RIG_OK; } /* * rig_set_xit* * * Set transmitter clarifier offset for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * xit | input | -9999 - 9999 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. * * The following conditions are checked: * * xit = 0 && rit enabled -> disable xit * xit = 0 && rit disabled -> disable xit and set frequency = 0 */ int ft990_set_xit(RIG *rig, vfo_t vfo, shortfreq_t xit) { struct ft990_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 rit = %d\n", __func__, (int)xit); if (xit < -9999 || xit > 9999) { return -RIG_EINVAL; } priv = (struct ft990_priv_data *) rig->state.priv; // Set to selected VFO if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } // Disable TX clarifier and return if xit = 0 if (xit == 0) { err = ft990_get_update_data(rig, FT990_NATIVE_UPDATE_OP_DATA, 0); if (err != RIG_OK) { return err; } if ((priv->update_data.current_front.status & FT990_CLAR_RX_EN) == 0) { err = ft990_send_static_cmd(rig, FT990_NATIVE_CLEAR_CLARIFIER_OFFSET); if (err != RIG_OK) { return err; } } err = ft990_send_static_cmd(rig, FT990_NATIVE_TX_CLARIFIER_OFF); if (err != RIG_OK) { return err; } } else { // Enable TX Clarifier err = ft990_send_static_cmd(rig, FT990_NATIVE_TX_CLARIFIER_ON); if (err != RIG_OK) { return err; } // Set TX clarifier offset err = ft990_send_rit_freq(rig, FT990_NATIVE_CLARIFIER_OPS, xit); if (err != RIG_OK) { return err; } } return RIG_OK; } /* * rig_get_xit* * * Get transmitter clarifier offset for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * xit * | output | -9999 - 9999 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_get_xit(RIG *rig, vfo_t vfo, shortfreq_t *xit) { struct ft990_priv_data *priv; unsigned char ci; ft990_op_data_t *p; 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 ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo); } switch (vfo) { case RIG_VFO_A: case RIG_VFO_VFO: ci = FT990_NATIVE_UPDATE_VFO_DATA; p = (ft990_op_data_t *) &priv->update_data.vfoa; break; case RIG_VFO_B: ci = FT990_NATIVE_UPDATE_VFO_DATA; p = (ft990_op_data_t *) &priv->update_data.vfob; break; case RIG_VFO_MEM: case RIG_VFO_MAIN: ci = FT990_NATIVE_UPDATE_OP_DATA; p = (ft990_op_data_t *) &priv->update_data.current_front; break; default: return -RIG_EINVAL; } err = ft990_get_update_data(rig, ci, 0); if (err != RIG_OK) { return err; } // Clarifier offset is only returned when enabled if (p->status & FT990_CLAR_TX_EN) { *xit = (short)((p->coffset[0] << 8) | p->coffset[1]) * 10; } else { *xit = 0; } rig_debug(RIG_DEBUG_TRACE, "%s: read freq = %li Hz\n", __func__, *xit); 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 | LOCK, TUNER * status | input | 0 = off, 1 = off * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored since the * the status of rig functions are vfo independent. */ int ft990_set_func(RIG *rig, vfo_t vfo, setting_t func, int status) { unsigned char ci; 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 func = %s\n", __func__, rig_strfunc(func)); rig_debug(RIG_DEBUG_TRACE, "%s: passed status = %d\n", __func__, status); switch (func) { case RIG_FUNC_LOCK: if (status) { ci = FT990_NATIVE_LOCK_ON; } else { ci = FT990_NATIVE_LOCK_OFF; } break; case RIG_FUNC_TUNER: if (status) { ci = FT990_NATIVE_TUNER_ON; } else { ci = FT990_NATIVE_TUNER_OFF; } break; default: return -RIG_EINVAL; } err = ft990_send_static_cmd(rig, ci); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_get_func* * * Get status of a rig function * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, Main, VFO, VFOA, VFOB, MEM * func | input | LOCK, TUNER, MON * status * | output | 0 = off, 1 = on * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored since the * the status of rig function are vfo independent. */ int ft990_get_func(RIG *rig, vfo_t vfo, setting_t func, int *status) { struct ft990_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 func = %s\n", __func__, rig_strfunc(func)); priv = (struct ft990_priv_data *)rig->state.priv; err = ft990_get_update_data(rig, FT990_NATIVE_READ_FLAGS, 0); if (err != RIG_OK) { return err; } switch (func) { case RIG_FUNC_LOCK: *status = ((priv->update_data.flag2 & FT990_SF_LOCKED) != 0); break; case RIG_FUNC_TUNER: *status = ((priv->update_data.flag3 & FT990_SF_TUNER_ON) != 0); break; case RIG_FUNC_MON: *status = ((priv->update_data.flag3 & FT990_SF_XMIT_MON) != 0); break; default: return -RIG_EINVAL; } return RIG_OK; } /* * rig_set_parm* * * Set rig parameters that are not VFO specific * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * parm | input | BACKLIGHT * val | input | 0.0..1.0 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: */ int ft990_set_parm(RIG *rig, setting_t parm, value_t val) { int err; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: passed parm = %s\n", __func__, rig_strparm(parm)); rig_debug(RIG_DEBUG_TRACE, "%s: passed val = %f\n", __func__, val.f); switch (parm) { case RIG_PARM_BACKLIGHT: err = ft990_send_dynamic_cmd(rig, FT990_NATIVE_DIM_LEVEL, (unsigned char)(0x0d * val.f), 0, 0, 0); break; default: return -RIG_EINVAL; } if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_set_mode* * * Set operating mode and passband for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * mode | input | USB, LSB, CW, AM, FM, RTTY, RTTYR, PKTLSB, PKTFM * width | input | 2400, 2000, 500, 250 (USB) * | | 2400, 2000, 500, 250 (LSB) * | | 2400, 2000, 500, 250 (CW) * | | 2400, 2000, 500, 250 (RTTY) * | | 2400, 2000, 500, 250 (RTTYR) * | | 2400, 2000, 500, 250 (PKTLSB) * | | 6000, 2400 (AM) * | | 8000 (FM) * | | 8000 (PKTFM) * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_set_mode(RIG *rig, vfo_t vfo, rmode_t mode, pbwidth_t width) { struct ft990_priv_data *priv; unsigned char bw; unsigned char ci; 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 ft990_priv_data *)rig->state.priv; // Set to selected VFO if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current.vfo = 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } switch (mode) { case RIG_MODE_AM: if (width == rig_passband_narrow(rig, mode)) { ci = FT990_NATIVE_MODE_SET_AM_N; } else if (width == rig_passband_normal(rig, mode)) { ci = FT990_NATIVE_MODE_SET_AM_W; } else { return -RIG_EINVAL; } break; case RIG_MODE_CW: ci = FT990_NATIVE_MODE_SET_CW_W; break; case RIG_MODE_USB: ci = FT990_NATIVE_MODE_SET_USB; break; case RIG_MODE_LSB: ci = FT990_NATIVE_MODE_SET_LSB; break; case RIG_MODE_RTTY: ci = FT990_NATIVE_MODE_SET_RTTY_LSB; break; case RIG_MODE_RTTYR: ci = FT990_NATIVE_MODE_SET_RTTY_USB; break; case RIG_MODE_FM: ci = FT990_NATIVE_MODE_SET_FM; break; case RIG_MODE_PKTLSB: ci = FT990_NATIVE_MODE_SET_PKT_LSB; break; case RIG_MODE_PKTFM: ci = FT990_NATIVE_MODE_SET_PKT_FM; break; default: return -RIG_EINVAL; } err = ft990_send_static_cmd(rig, ci); if (err != RIG_OK) { return err; } if (ci == FT990_NATIVE_MODE_SET_AM_N || ci == FT990_NATIVE_MODE_SET_AM_W || ci == FT990_NATIVE_MODE_SET_FM || ci == FT990_NATIVE_MODE_SET_PKT_FM) { return RIG_OK; } if (width <= 250) { bw = FT990_BW_F250; } else if (width <= 500) { bw = FT990_BW_F500; } else if (width <= 2000) { bw = FT990_BW_F2000; } else { bw = FT990_BW_F2400; } rig_debug(RIG_DEBUG_TRACE, "%s: set bw = 0x%02x\n", __func__, bw); err = ft990_send_dynamic_cmd(rig, FT990_NATIVE_BANDWIDTH, bw, 0, 0, 0); if (err != RIG_OK) { return err; } return RIG_OK; } /* * rig_get_mode* * * Get operating mode and passband for a given VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * mode | input | USB, LSB, CW, AM, FM, RTTY, RTTYR, PKTLSB, PKTFM * width * | output | 2400, 2000, 500, 250 (USB) * | | 2400, 2000, 500, 250 (LSB) * | | 2400, 2000, 500, 250 (CW) * | | 2400, 2000, 500, 250 (RTTY) * | | 2400, 2000, 500, 250 (RTTYR) * | | 2400, 2000, 500, 250 (PKTLSB) * | | 6000, 2400 (AM) * | | 8000 (FM) * | | 8000 (PKTFM) * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_get_mode(RIG *rig, vfo_t vfo, rmode_t *mode, pbwidth_t *width) { struct ft990_priv_data *priv; unsigned char *p; unsigned char *fl; unsigned char ci; 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 ft990_priv_data *)rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo); } switch (vfo) { case RIG_VFO_A: case RIG_VFO_VFO: p = &priv->update_data.vfoa.mode; ci = FT990_NATIVE_UPDATE_VFO_DATA; fl = &priv->update_data.vfoa.filter; break; case RIG_VFO_B: p = &priv->update_data.vfob.mode; ci = FT990_NATIVE_UPDATE_VFO_DATA; fl = &priv->update_data.vfob.filter; break; case RIG_VFO_MEM: case RIG_VFO_MAIN: p = &priv->update_data.current_front.mode; ci = FT990_NATIVE_UPDATE_OP_DATA; fl = &priv->update_data.current_front.filter; break; default: return -RIG_EINVAL; } // Get update for selected VFO err = ft990_get_update_data(rig, ci, 0); if (err != RIG_OK) { return err; } rig_debug(RIG_DEBUG_TRACE, "%s: fl = 0x%02x\n", __func__, *fl); rig_debug(RIG_DEBUG_TRACE, "%s: current mode = 0x%02x\n", __func__, *p); switch (*p) { case FT990_MODE_LSB: *mode = RIG_MODE_LSB; break; case FT990_MODE_USB: *mode = RIG_MODE_USB; break; case FT990_MODE_CW: *mode = RIG_MODE_CW; break; case FT990_MODE_AM: *mode = RIG_MODE_AM; break; case FT990_MODE_FM: *mode = RIG_MODE_FM; break; case FT990_MODE_RTTY: if (*fl & FT990_BW_FMPKTRTTY) { *mode = RIG_MODE_RTTYR; } else { *mode = RIG_MODE_RTTY; } break; case FT990_MODE_PKT: if (*fl & FT990_BW_FMPKTRTTY) { *mode = RIG_MODE_PKTFM; } else { *mode = RIG_MODE_PKTLSB; } break; default: return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: get mode = %s\n", __func__, rig_strrmode(*mode)); // The FT990 firmware appears to have a bug since the // AM bandwidth for 2400Hz and 6000Hz are interchanged. switch (*fl & (~FT990_BW_FMPKTRTTY)) { case FT990_BW_F2400: if (*mode == RIG_MODE_FM || *mode == RIG_MODE_PKTFM) { *width = 8000; } else if (*mode == RIG_MODE_AM) // <- FT990 firmware bug? { *width = 6000; } else { *width = 2400; } break; case FT990_BW_F2000: *width = 2000; break; case FT990_BW_F500: *width = 500; break; case FT990_BW_F250: *width = 250; break; case FT990_BW_F6000: *width = 2400; // <- FT990 firmware bug? break; default: return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: get width = %li Hz\n", __func__, *width); return RIG_OK; } /* * rig_set_vfo* * * Set operational VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_set_vfo(RIG *rig, vfo_t vfo) { struct ft990_priv_data *priv; unsigned char ci; 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 ft990_priv_data *)rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo); } switch (vfo) { case RIG_VFO_A: ci = FT990_NATIVE_VFO_A; break; case RIG_VFO_B: ci = FT990_NATIVE_VFO_B; break; case RIG_VFO_MEM: ci = FT990_NATIVE_RECALL_MEM; break; default: return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: set ci = %i\n", __func__, ci); if (vfo == RIG_VFO_MEM) { err = ft990_send_dynamic_cmd(rig, ci, priv->update_data.channelnumber + 1, 0, 0, 0); rig_debug(RIG_DEBUG_TRACE, "%s: set mem channel = 0x%02x\n", __func__, priv->update_data.channelnumber + 1); } else { err = ft990_send_static_cmd(rig, ci); } if (err != RIG_OK) { return err; } priv->current_vfo = vfo; return RIG_OK; } /* * rig_get_vfo* * * Get operational VFO * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo * | output | VFOA, VFOB, MEM * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. * The result is stored in the priv->current_vfo data structure * for later retrieval. */ int ft990_get_vfo(RIG *rig, vfo_t *vfo) { struct ft990_priv_data *priv; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } priv = (struct ft990_priv_data *)rig->state.priv; /* Get flags for VFO status err = ft990_get_update_data(rig, FT990_NATIVE_READ_FLAGS, 0); if (err != RIG_OK) { return err; } */ if (priv->update_data.flag2 & FT990_SF_MEM || priv->update_data.flag2 & FT990_SF_MTUNE) { priv->current_vfo = RIG_VFO_MEM; } else if (priv->update_data.flag1 & FT990_SF_VFOB) { priv->current_vfo = RIG_VFO_B; } else { priv->current_vfo = RIG_VFO_A; } rig_debug(RIG_DEBUG_TRACE, "%s: vfo status_1 = 0x%02x\n", __func__, priv->update_data.flag1); rig_debug(RIG_DEBUG_TRACE, "%s: vfo status_2 = 0x%02x\n", __func__, priv->update_data.flag2); rig_debug(RIG_DEBUG_TRACE, "%s: stat_vfo = 0x%02x\n", __func__, priv->current_vfo); *vfo = priv->current_vfo; return RIG_OK; } /* * rig_get_level * * This function will read the meter level.The data * is processed depending upon selection of the level * parameter. The following are the currently supported * levels and returned value range: * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, Main, VFO, VFOA, VFOB, MEM * level | input | STRENGTH, ALC, COMP, RFPOWER, SWR * value * | output | see table below * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * ---------------------------------------------------------- * level | Description | Returned Value | Units | * ---------------------------------------------------------- * STRENGTH | Signal Strength | -54 .. +60 | db | * COMP | Compression | 0.0 .. 1.0 | %/100 | * RFPOWER | RF Power Output | 0.0 .. 1.0 | %/100 | * SWR | Standing Wave Ratio | 0.0 .. 1.0 | %/100 | * ---------------------------------------------------------- * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_get_level(RIG *rig, vfo_t vfo, setting_t level, value_t *value) { struct ft990_priv_data *priv; unsigned char mdata[YAESU_CMD_LENGTH]; 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 level %s\n", __func__, rig_strlevel(level)); priv = (struct ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } err = ft990_send_static_cmd(rig, FT990_NATIVE_READ_METER); if (err != RIG_OK) { return err; } err = read_block(&rig->state.rigport, mdata, FT990_READ_METER_LENGTH); if (err < 0) { return err; } rig_debug(RIG_DEBUG_TRACE, "%s: meter data %d\n", __func__, mdata[0]); switch (level) { case RIG_LEVEL_STRENGTH: value->i = mdata[0] / 2.246 - 54; rig_debug(RIG_DEBUG_TRACE, "%s: meter level %d\n", __func__, value->i); break; case RIG_LEVEL_ALC: case RIG_LEVEL_COMP: case RIG_LEVEL_RFPOWER: case RIG_LEVEL_SWR: value->f = (float) mdata[0] / 255; rig_debug(RIG_DEBUG_TRACE, "%s: meter level %f\n", __func__, value->f); break; default: return -RIG_EINVAL; } return RIG_OK; } /* * rig_vfo_op* * * Perform vfo operations * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | VFOA, VFOB, MEM * op | input | CPY = copy from VFO to VFO * | | FROM_VFO = copy from VFO to MEM * | | TO_VFO = copy from MEM to VFO * | | UP = step dial frequency up * | | DOWN = step dial frequency down * | | TUNE = start antenna tuner * | | TOGGLE = toggle between VFOA and VFOB * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing currVFO to vfo will use the currently selected VFO * obtained from the priv->current_vfo data structure. * In all other cases the passed vfo is selected if it differs * from the currently selected VFO. */ int ft990_vfo_op(RIG *rig, vfo_t vfo, vfo_op_t op) { struct ft990_priv_data *priv; unsigned char ci; 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 op %s\n", __func__, rig_strvfop(op)); priv = (struct ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo 0x%02x\n", __func__, vfo); } else { if (vfo != priv->current_vfo) { err = ft990_set_vfo(rig, vfo); if (err != RIG_OK) { return err; } } } switch (op) { case RIG_OP_CPY: ci = FT990_NATIVE_VFO_TO_VFO; break; case RIG_OP_FROM_VFO: ci = FT990_NATIVE_VFO_TO_MEM; break; case RIG_OP_TO_VFO: ci = FT990_NATIVE_MEM_TO_VFO; break; case RIG_OP_UP: ci = FT990_NATIVE_OP_FREQ_STEP_UP; break; case RIG_OP_DOWN: ci = FT990_NATIVE_OP_FREQ_STEP_DOWN; break; case RIG_OP_TUNE: ci = FT990_NATIVE_TUNER_START; break; case RIG_OP_TOGGLE: switch (vfo) { case RIG_VFO_A: ci = FT990_NATIVE_VFO_B; vfo = RIG_VFO_B; break; case RIG_VFO_B: ci = FT990_NATIVE_VFO_A; vfo = RIG_VFO_A; break; default: return -RIG_EINVAL; } break; default: return -RIG_EINVAL; } if (op == RIG_OP_TO_VFO || op == RIG_OP_FROM_VFO) err = ft990_send_dynamic_cmd(rig, ci, priv->update_data.channelnumber + 1, 0, 0, 0); else { err = ft990_send_static_cmd(rig, ci); } if (err != RIG_OK) { return err; } if (op == RIG_OP_TOGGLE) { priv->current_vfo = vfo; } return RIG_OK; } /* * rig_set_mem* * * Set main vfo to selected memory channel number * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * ch | input | 1 - 90 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored since the * the channel selection is vfo independent. */ int ft990_set_mem(RIG *rig, vfo_t vfo, int ch) { struct ft990_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 ch = %i\n", __func__, ch); priv = (struct ft990_priv_data *) rig->state.priv; // Check for valid channel number if (ch < 1 || ch > 90) { return -RIG_EINVAL; } // Recall selected memory channel err = ft990_send_dynamic_cmd(rig, FT990_NATIVE_RECALL_MEM, ch, 0, 0, 0); if (err != RIG_OK) { return err; } priv->current_vfo = RIG_VFO_MEM; priv->update_data.channelnumber = ch - 1; return RIG_OK; } /* * rig_get_mem* * * Get memory channel number used by main vfo * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * vfo | input | currVFO, VFOA, VFOB, MEM * ch * | output | 1 - 90 * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: The passed value for the vfo is ignored since * the channel selection is vfo independent. */ int ft990_get_mem(RIG *rig, vfo_t vfo, int *ch) { struct ft990_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); priv = (struct ft990_priv_data *) rig->state.priv; if (vfo == RIG_VFO_CURR) { vfo = priv->current_vfo; rig_debug(RIG_DEBUG_TRACE, "%s: priv->current_vfo = 0x%02x\n", __func__, vfo); } err = ft990_get_update_data(rig, FT990_NATIVE_UPDATE_MEM_CHNL, 0); if (err != RIG_OK) { return err; } rig_debug(RIG_DEBUG_TRACE, "%s: channel number %i\n", __func__, priv->update_data.channelnumber + 1); *ch = priv->update_data.channelnumber + 1; // Check for valid channel number if (*ch < 1 || *ch > 90) { return -RIG_EINVAL; } return RIG_OK; } /* * rig_set_channel* * * Set memory channel parameters and attributes * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * chan * | input | channel attribute data structure * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure */ int ft990_set_channel(RIG *rig, vfo_t vfo, const channel_t *chan) { rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } return -RIG_ENIMPL; } /* * rig_get_channel* * * Get memory channel parameters and attributes * * Parameter | Type | Accepted/Expected Values * ------------------------------------------------------------------------- * RIG * | input | pointer to private data * chan * | input | (chan->vfo) currVFO, VFOA, VFOB, MEM * | | (chan->channel_num) 0 - 90 * chan * | output | channel attributes data structure * ------------------------------------------------------------------------- * Returns RIG_OK on success or an error code on failure * * Comments: Passing a memory channel number of 0 returns information on * the current channel or channel last in use. * * Status for split operation, active rig functions and tuning steps * are only relevant for currVFO */ int ft990_get_channel(RIG *rig, vfo_t vfo, channel_t *chan, int read_only) { struct ft990_priv_data *priv; ft990_op_data_t *p; char ci; int err; channel_t _chan; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); if (!rig) { return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: passed chan->vfo = %s\n", __func__, rig_strvfo(chan->vfo)); rig_debug(RIG_DEBUG_TRACE, "%s: passed chan->channel_num = %i\n", __func__, chan->channel_num); priv = (struct ft990_priv_data *) rig->state.priv; if (chan->channel_num < 0 || chan->channel_num > 90) { return -RIG_EINVAL; } /* * Get a clean slate so we don't have to assign value to * variables that are not relevant to this equipment */ _chan.channel_num = chan->channel_num; _chan.vfo = chan->vfo; memset(chan, 0, sizeof(channel_t)); chan->channel_num = _chan.channel_num; chan->vfo = _chan.vfo; if (chan->channel_num == 0) { switch (chan->vfo) { // Current or last selected memory channel case RIG_VFO_MEM: err = ft990_get_update_data(rig, FT990_NATIVE_UPDATE_MEM_CHNL, 0); if (err != RIG_OK) { return err; } chan->channel_num = priv->update_data.channelnumber + 1; p = (ft990_op_data_t *) &priv->update_data.channel[chan->channel_num]; ci = FT990_NATIVE_UPDATE_MEM_CHNL_DATA; break; case RIG_VFO_A: p = (ft990_op_data_t *) &priv->update_data.vfoa; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_B: p = (ft990_op_data_t *) &priv->update_data.vfob; ci = FT990_NATIVE_UPDATE_VFO_DATA; break; case RIG_VFO_CURR: p = (ft990_op_data_t *) &priv->update_data.current_front; ci = FT990_NATIVE_UPDATE_OP_DATA; break; default: return -RIG_EINVAL; } } else { p = (ft990_op_data_t *) &priv->update_data.channel[chan->channel_num]; ci = FT990_NATIVE_UPDATE_MEM_CHNL_DATA; chan->vfo = RIG_VFO_MEM; } /* * Get data for selected VFO/MEM */ err = ft990_get_update_data(rig, ci, chan->channel_num); if (err != RIG_OK) { return err; } // Blanked memory, nothing to report if (p->bpf & FT990_EMPTY_MEM) { return RIG_OK; } /* * Get RX frequency */ chan->freq = ((((p->basefreq[0] << 8) + p->basefreq[1]) << 8) + p->basefreq[2]) * 10; /* * Get RX operating mode */ switch (p->mode) { case FT990_MODE_LSB: chan->mode = RIG_MODE_LSB; break; case FT990_MODE_USB: chan->mode = RIG_MODE_USB; break; case FT990_MODE_CW: chan->mode = RIG_MODE_CW; break; case FT990_MODE_AM: chan->mode = RIG_MODE_AM; break; case FT990_MODE_FM: chan->mode = RIG_MODE_FM; break; case FT990_MODE_RTTY: if (p->filter & FT990_BW_FMPKTRTTY) { chan->mode = RIG_MODE_RTTYR; } else { chan->mode = RIG_MODE_RTTY; } break; case FT990_MODE_PKT: if (p->filter & FT990_BW_FMPKTRTTY) { chan->mode = RIG_MODE_PKTFM; } else { chan->mode = RIG_MODE_PKTLSB; } break; default: return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: mode = 0x%02x\n", __func__, p->mode); rig_debug(RIG_DEBUG_TRACE, "%s: filter = 0x%02x\n", __func__, p->filter); /* * Get RX bandwidth selection * * The FT990 firmware appears to have a bug since the * AM bandwidth for 2400Hz and 6000Hz are interchanged. */ switch (p->filter & (~FT990_BW_FMPKTRTTY)) { case FT990_BW_F2400: if (chan->mode == RIG_MODE_FM || chan->mode == RIG_MODE_PKTFM) { chan->width = 8000; } else if (chan->mode == RIG_MODE_AM) // <- FT990 firmware bug? { chan->width = 6000; } else { chan->width = 2400; } break; case FT990_BW_F2000: chan->width = 2000; break; case FT990_BW_F500: chan->width = 500; break; case FT990_BW_F250: chan->width = 250; break; case FT990_BW_F6000: chan->width = 2400; // <- FT990 firmware bug? break; default: return -RIG_EINVAL; } err = ft990_get_update_data(rig, FT990_NATIVE_READ_FLAGS, 0); if (err != RIG_OK) { return err; } rig_debug(RIG_DEBUG_TRACE, "%s: set status = %i\n", __func__, priv->update_data.flag1); /* * Status for split operation, active rig functions and tuning steps * are only relevant for currVFO */ if (chan->vfo & RIG_VFO_CURR) { chan->split = (priv->update_data.flag1 & FT990_SF_SPLIT); if (priv->update_data.flag1 & FT990_SF_XMIT_MON) { chan->funcs |= RIG_FUNC_MON; } if (priv->update_data.flag1 & FT990_SF_TUNER_ON) { chan->funcs |= RIG_FUNC_TUNER; } if (priv->update_data.flag1 & FT990_SF_FAST) { if (chan->mode & (FT990_AM_RX_MODES | FT990_FM_RX_MODES)) { chan->tuning_step = 1000; } else { chan->tuning_step = 100; } } else { if (chan->mode & (FT990_AM_RX_MODES | FT990_FM_RX_MODES)) { chan->tuning_step = 100; } else { chan->tuning_step = 10; } } } /* * Get RIT frequencies */ if (p->status & FT990_CLAR_RX_EN) { chan->rit = (short)((p->coffset[0] << 8) | p->coffset[1]) * 10; } if (chan->split & RIG_SPLIT_ON) { // Get data for the transmit VFO p = (ft990_op_data_t *) &priv->update_data.current_front; /* M0EZP: was current_rear */ /* FT1000D * if (RIG_MODEL_FT1000D == rig->caps->rig_model) * p = (ft990_op_data_t *) &priv->update_data.vfob; * chan->tx_freq = ((((p->basefreq[0] << 8) + p->basefreq[1]) << 8) + * p->basefreq[2]) * 10; * * THIS SECTION WAS REMOVED IN DECEMBER 2016. SEE SEPARATE ft1000d.c and .h FILES */ /* Get RX operating mode */ switch (p->mode) { case FT990_MODE_LSB: chan->tx_mode = RIG_MODE_LSB; break; case FT990_MODE_USB: chan->tx_mode = RIG_MODE_USB; break; case FT990_MODE_CW: chan->tx_mode = RIG_MODE_CW; break; case FT990_MODE_AM: chan->tx_mode = RIG_MODE_AM; break; case FT990_MODE_FM: chan->tx_mode = RIG_MODE_FM; break; case FT990_MODE_RTTY: if (p->filter & FT990_BW_FMPKTRTTY) { chan->tx_mode = RIG_MODE_RTTYR; } else { chan->tx_mode = RIG_MODE_RTTY; } break; case FT990_MODE_PKT: if (p->filter & FT990_BW_FMPKTRTTY) { chan->tx_mode = RIG_MODE_PKTFM; } else { chan->tx_mode = RIG_MODE_PKTLSB; } break; default: return -RIG_EINVAL; } rig_debug(RIG_DEBUG_TRACE, "%s: set tx mode = %s\n", __func__, rig_strrmode(chan->mode)); rig_debug(RIG_DEBUG_TRACE, "%s: tx filter = 0x%02x\n", __func__, p->filter); /* * Get RX bandwidth selection * * The FT990 firmware appears to have a bug since the * AM bandwidth for 2400Hz and 6000Hz are interchanged. */ switch (p->filter & (~FT990_BW_FMPKTRTTY)) { case FT990_BW_F2400: if (chan->tx_mode == RIG_MODE_FM || chan->mode == RIG_MODE_PKTFM) { chan->tx_width = 8000; } else if (chan->tx_mode == RIG_MODE_AM) // <- FT990 firmware bug? { chan->tx_width = 6000; } else { chan->tx_width = 2400; } break; case FT990_BW_F2000: chan->tx_width = 2000; break; case FT990_BW_F500: chan->tx_width = 500; break; case FT990_BW_F250: chan->tx_width = 250; break; case FT990_BW_F6000: chan->tx_width = 2400; // <- FT990 firmware bug? break; default: return -RIG_EINVAL; } if (priv->update_data.flag1 & FT990_SF_VFOB) { if (chan->tx_vfo & (RIG_VFO_A | RIG_VFO_MEM)) { chan->tx_vfo = RIG_VFO_B; } else if (chan->vfo & RIG_VFO_MEM) { chan->tx_vfo = RIG_VFO_A; } else { chan->tx_vfo = RIG_VFO_MEM; } } else { if (chan->vfo & RIG_VFO_A) { chan->tx_vfo = RIG_VFO_MEM; } else { chan->tx_vfo = RIG_VFO_A; } } /* * Get XIT frequencies */ if (p->status & FT990_CLAR_TX_EN) { chan->xit = (short)((p->coffset[0] << 8) | p->coffset[1]) * 10; } } else { /* * RX/TX frequency, mode, bandwidth and vfo are identical in simplex mode */ chan->tx_freq = chan->freq; chan->tx_mode = chan->mode; chan->tx_width = chan->width; chan->tx_vfo = chan->vfo; /* * Get XIT frequencies */ if (p->status & FT990_CLAR_TX_EN) { chan->xit = (short)((p->coffset[0] << 8) | p->coffset[1]) * 10; } } rig_debug(RIG_DEBUG_TRACE, "%s: set status = %i\n", __func__, p->status); /* * Repeater shift only possible if transmit mode is FM */ if (chan->tx_mode & RIG_MODE_FM) { chan->rptr_shift = (p->status & FT990_RPT_MASK) >> 2; } /* * Check for skip channel for memory channels */ if (chan->vfo & RIG_VFO_MEM) { chan->flags |= RIG_CHFLAG_SKIP; } if (!read_only) { // Set rig to channel values rig_debug(RIG_DEBUG_ERR, "%s: please contact hamlib mailing list to implement this\n", __func__); rig_debug(RIG_DEBUG_ERR, "%s: need to know if rig updates when channel read or not\n", __func__); return -RIG_ENIMPL; } return RIG_OK; } /* * Private helper function. Retrieves update data from rig. * using pacing value and buffer indicated in *priv struct. * Extended to be command agnostic as 990 has several ways to * get data and several ways to return it. * * Need to use this when doing ft990_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 functiion */ int ft990_get_update_data(RIG *rig, unsigned char ci, unsigned short ch) { struct ft990_priv_data *priv; int n; int err; int rl; unsigned char temp[FT990_STATUS_FLAGS_LENGTH]; unsigned char *p; rig_debug(RIG_DEBUG_VERBOSE, "%s called\n", __func__); rig_debug(RIG_DEBUG_TRACE, "%s: passed ci 0x%02x\n", __func__, ci); rig_debug(RIG_DEBUG_TRACE, "%s: passed ch 0x%02x\n", __func__, ch); if (!rig) { return -RIG_EINVAL; } n = 0; // K1MMI: Initialise as the only time n will be updated is for the FT990_NATIVE_ALL_DATA AND FT990_READ_FLAGS priv = (struct ft990_priv_data *)rig->state.priv; switch (ci) { case FT990_NATIVE_UPDATE_ALL_DATA: case FT990_NATIVE_UPDATE_MEM_CHNL: case FT990_NATIVE_UPDATE_OP_DATA: case FT990_NATIVE_UPDATE_VFO_DATA: case FT990_NATIVE_UPDATE_MEM_CHNL_DATA: if (ft990uni_get_freq_state < 2) { // if (ci == FT990_NATIVE_UPDATE_MEM_CHNL_DATA) // P4 = 0x01 to 0x5a for channel 1 - 90 { /* err = ft990_send_dynamic_cmd(rig, ci, 4, 0, 0, ch); M0EZP: dont send command, rely on the assignment from memory below*/ } else { // err = RIG_OK; K1MMI err = ft990_send_static_cmd(rig, ci); // K1MMI: only send for ALL DATA 1492 bytes or READ FLAGS 5 bytes } if (err != RIG_OK) { return err; } switch (ci) { case FT990_NATIVE_UPDATE_ALL_DATA: rl = FT990_ALL_DATA_LENGTH; // K1MMI: prepare to receive 1492 bytes back p = (unsigned char *)&priv->update_data; // K1MMI: This seems like 1492 will be saved here n = read_block(&rig->state.rigport, p, rl); /* M0EZP: copied here from below */ return RIG_OK; break; case FT990_NATIVE_UPDATE_MEM_CHNL: // we already have the channelnumber in the previously saved 1492 bytes p = (unsigned char *) &priv->update_data.channelnumber; rl = FT990_MEM_CHNL_LENGTH; // 1 break; case FT990_NATIVE_UPDATE_OP_DATA: // we already have the current OP and VFOA in the 1492 bytes p = (unsigned char *) &priv->update_data.current_front; rl = FT990_OP_DATA_LENGTH; // 32 break; case FT990_NATIVE_UPDATE_VFO_DATA: // we already have the VFOA and VFOB in the 1492 bytes p = (unsigned char *) &priv->update_data.vfoa; rl = FT990_VFO_DATA_LENGTH; // 32 break; case FT990_NATIVE_UPDATE_MEM_CHNL_DATA: // we already have the 16 structure for the memory channel number p = (unsigned char *) &priv->update_data.channel[ch]; rl = FT990_MEM_CHNL_DATA_LENGTH; // 16 break; default: // M0EZP: shouldn't be here! rig_debug(RIG_DEBUG_TRACE, "%s: Default clause ci 0x%02x\n", __func__, ci); // M0EZP return -RIG_EINVAL; } ft990uni_get_freq_state = ft990uni_get_freq_state + 1; if (n < 0) { return n; /* die returning read_block error */ } rig_debug(RIG_DEBUG_TRACE, "%s: read %i bytes\n", __func__, n); memcpy(&priv->update_data, p, FT990_ALL_DATA_LENGTH); return RIG_OK; } else { return RIG_OK; } case FT990_NATIVE_READ_FLAGS: rig_debug(RIG_DEBUG_TRACE, "%s: passed ci 0x%02x\n", __func__, ci); err = ft990_send_static_cmd(rig, ci); // K1MMI: only send for ALL DATA 1492 bytes if (err != RIG_OK) { return err; } p = (unsigned char *)&priv->update_data; rl = FT990_STATUS_FLAGS_LENGTH; // 5 n = read_block(&rig->state.rigport, (unsigned char*)&temp, rl); /* M0EZP: copied here from below */ if (n < 0) { return n; /* die returning read_block error */ } rig_debug(RIG_DEBUG_TRACE, "%s: read %i bytes\n", __func__, n); memcpy(&priv->update_data, p, FT990_STATUS_FLAGS_LENGTH - 2); /* just overwrite first 3 bytes */ return RIG_OK; break; default: // M0EZP: shouldn't be here! rig_debug(RIG_DEBUG_TRACE, "%s: Default clause ci 0x%02x\n", __func__, ci); // M0EZP return -RIG_EINVAL; } 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 functiion */ int ft990_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 (!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 functiion */ int ft990_send_dynamic_cmd(RIG *rig, unsigned char ci, unsigned char p1, unsigned char p2, unsigned char p3, unsigned char p4) { struct ft990_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 = 0x%02x\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 ft990_priv_data *)rig->state.priv; if (ncmd[ci].ncomp) { rig_debug(RIG_DEBUG_TRACE, "%s: Attempt to modify complete sequence\n", __func__); return -RIG_EINVAL; } memcpy(&priv->p_cmd, &ncmd[ci].nseq, YAESU_CMD_LENGTH); priv->p_cmd[3] = p1; priv->p_cmd[2] = p2; priv->p_cmd[1] = p3; priv->p_cmd[0] = 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 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 functiion */ int ft990_send_dial_freq(RIG *rig, unsigned char ci, freq_t freq) { struct ft990_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 = 0x%02x\n", __func__, ci); rig_debug(RIG_DEBUG_TRACE, "%s: passed freq = %"PRIfreq" Hz\n", __func__, freq); priv = (struct ft990_priv_data *)rig->state.priv; 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, FT990_BCD_DIAL); rig_debug(RIG_DEBUG_TRACE, fmt, __func__, (int64_t)from_bcd(priv->p_cmd, FT990_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 frequency. * * Arguments: *rig Valid RIG instance * ci Command index of the ncmd table * rit shortfreq_t frequency value * * Returns: RIG_OK if all called functions are successful, * otherwise returns error from called functiion */ int ft990_send_rit_freq(RIG *rig, unsigned char ci, shortfreq_t rit) { struct ft990_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 = 0x%02x\n", __func__, ci); rig_debug(RIG_DEBUG_TRACE, "%s: passed rit = %li Hz\n", __func__, rit); priv = (struct ft990_priv_data *) rig->state.priv; if (ncmd[ci].ncomp) { rig_debug(RIG_DEBUG_TRACE, "%s: Attempt to modify complete sequence\n", __func__); return -RIG_EINVAL; } // Copy native command into privat command storage area memcpy(&priv->p_cmd, &ncmd[ci].nseq, YAESU_CMD_LENGTH); // Reset current clarifier offset priv->p_cmd[3] = FT990_CLAR_CLEAR; // Check and set tuning direction - up or down if (rit < 0) { priv->p_cmd[2] = FT990_CLAR_TUNE_DOWN; } else { priv->p_cmd[2] = FT990_CLAR_TUNE_UP; } // Store bcd format into privat command storage area to_bcd(priv->p_cmd, labs(rit) / 10, FT990_BCD_RIT); err = write_block(&rig->state.rigport, (unsigned char *) &priv->p_cmd, YAESU_CMD_LENGTH); if (err != RIG_OK) { return err; } return RIG_OK; }