Hamlib/aor/ar7030p_utils.c

1398 wiersze
28 KiB
C

/*
* Hamlib AOR backend - AR7030 Plus utility functions
*
* $Id: $
*
* This library is free software; you can redistribute it and/or modify
* it under the terms of the GNU Library General Public License as
* published by the Free Software Foundation; either version 2 of
* the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*
*/
/*
* Version 2009.12.31 Larry Gadallah (VE6VQ)
*/
#include <stdio.h>
#include <string.h>
#include <math.h>
#include <assert.h>
#include <hamlib/rig.h>
#include "ar7030p.h"
#include "serial.h"
#include "idx_builtin.h"
static enum PAGE_e curPage = NONE; /* Current memory page */
static unsigned int curAddr = 65535; /* Current page address */
static enum LOCK_LVL_e curLock = LOCK_0; /* Current lock level */
static const unsigned int PAGE_SIZE[] = {
256, 256, 512, 4096, 4096,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
8
}; /* Page size table */
#if 0
/*
* Code Ident Operation
* 0x NOP No Operation
*/
int NOP( RIG *rig, unsigned char x )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & x ) | op_NOP );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
return ( rc );
}
/*
* Code Ident Operation
* 3x SRH Set H-register x -> H-register (4-bits)
*/
int SRH( RIG *rig, unsigned char x )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & x ) | op_SRH );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
return ( rc );
}
/*
* Code Ident Operation
* 5x PGE Set page x -> Page register (4-bits)
*/
int PGE( RIG *rig, enum PAGE_e page )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & page ) | op_PGE );
assert( NULL != rig );
switch ( page )
{
case WORKING:
case BBRAM:
case EEPROM1:
case EEPROM2:
case EEPROM3:
case ROM:
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
break;
case NONE:
default:
rig_debug( RIG_DEBUG_VERBOSE, "PGE: invalid page %d\n", page );
rc = -RIG_EINVAL;
break;
};
return ( rc );
}
/*
* Code Ident Operation
* 4x ADR Set address 0Hx -> Address register (12-bits)
* 0 -> H-register
*/
int ADR( RIG *rig, unsigned char x )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & x ) | op_ADR );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
return ( rc );
}
/*
* Code Ident Operation
* 1x ADH Set address high x -> Address register (high 4-bits)
*/
int ADH( RIG *rig, unsigned char x )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & x ) | op_ADH );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
return ( rc );
}
/*
* Code Ident Operation
* 6x WRD Write data Hx -> [Page, Address]
* Address register + 1 -> Address register
* 0 -> H-register, 0 -> Mask register
*/
int WRD( RIG *rig, unsigned char out )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & out ) | op_WRD );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
return ( rc );
}
/*
* Code Ident Operation
* 9x MSK Set mask Hx -> Mask register <1>
* 0 -> H-register
*/
int MSK( RIG *rig, unsigned char mask )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & mask ) | op_MSK );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
return ( rc );
}
/*
* Code Ident Operation
* 2x EXE Execute routine x
*/
int EXE( RIG *rig, enum ROUTINE_e routine )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & routine ) | op_EXE );
assert( NULL != rig );
switch ( routine )
{
case RESET:
case SET_FREQ:
case SET_MODE:
case SET_PASS:
case SET_ALL:
case SET_AUDIO:
case SET_RFIF:
case DIR_RX_CTL:
case DIR_DDS_CTL:
case DISP_MENUS:
case DISP_FREQ:
case DISP_BUFF:
case READ_SIGNAL:
case READ_BTNS:
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
break;
default:
rig_debug( RIG_DEBUG_VERBOSE, "EXE: invalid routine %d\n", routine );
rc = -RIG_EINVAL;
break;
};
return ( rc );
}
/*
* Code Ident Operation
* 7x RDD Read data [Page, Address] -> Serial output
* Address register + x -> Address register
*/
int RDD( RIG *rig, unsigned char len )
{
int rc = -RIG_OK;
unsigned char inChr = 0;
unsigned char op = ( ( 0x0f & len ) | op_RDD );
assert( NULL != rig );
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
else
{
rc = read_block( &rig->state.rigport, ( char * ) &inChr, len );
if ( 1 != rc )
{
rc = -RIG_EIO;
}
else
{
rc = (int) inChr;
}
}
return ( rc );
}
/*
* Code Ident Operation
* 8x LOC Set lock level x
*/
int LOC( RIG *rig, enum LOCK_LVL_e level )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & level ) | op_LOC );
assert( NULL != rig );
switch ( level )
{
case LOCK_0:
case LOCK_1:
case LOCK_2:
case LOCK_3:
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
break;
default:
rig_debug( RIG_DEBUG_VERBOSE, "LOC: invalid lock level %d\n", level );
rc = -RIG_EINVAL;
break;
};
return ( rc );
}
/*
* Code Ident Operation
* Ax BUT Operate button x <1>
*/
int BUT( RIG *rig, enum BUTTON_e button )
{
int rc = -RIG_OK;
unsigned char op = ( ( 0x0f & button ) | op_BUT );
assert( NULL != rig );
switch ( button )
{
case BTN_NONE:
break;
case BTN_UP:
case BTN_DOWN:
case BTN_FAST:
case BTN_FILTER:
case BTN_RFIF:
case BTN_MEMORY:
case BTN_STAR:
case BTN_MENU:
case BTN_POWER:
rc = write_block( &rig->state.rigport, ( char * ) &op, 1 );
if ( 0 != rc )
{
rc = -RIG_EIO;
}
break;
default:
rig_debug( RIG_DEBUG_VERBOSE, "BUT: invalid button %d\n", button );
rc = -RIG_EINVAL;
break;
};
return ( rc );
}
#endif // 0
/*
* /brief Execute routine
*
* /param rig Pointer to rig struct
* /param rtn Receiver routine to execute
*
* \return RIG_OK on success, error code on failure
*
*/
int execRoutine( RIG * rig, enum ROUTINE_e rtn )
{
int rc = -RIG_EIO;
unsigned char v = EXE( (rtn & 0x0f) );
assert( NULL != rig );
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
rc = -RIG_OK;
rig_debug( RIG_DEBUG_VERBOSE, "%s: routine %2d\n", __func__, rtn );
}
return( rc );
}
/*
* /brief Set address for I/O with radio
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
*
* \return RIG_OK on success, error code on failure
*
* Statics curPage and curAddr shadow radio's copies so that
* page and address are only set when needed
*/
static int setAddr( RIG * rig, enum PAGE_e page, unsigned int addr )
{
int rc = RIG_OK;
unsigned char v;
assert( NULL != rig );
if ( ( EEPROM3 >= page ) || ( ROM == page ) )
{
if ( PAGE_SIZE[page] > addr )
{
if ( curPage != page )
{
v = PGE( page );
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
curPage = page;
rc = -RIG_OK;
rig_debug( RIG_DEBUG_VERBOSE, "%s: set page %2d\n", __func__, page );
}
else
{
rc = -RIG_EIO;
}
}
if ( curAddr != addr )
{
v = SRH( ( 0x0f0 & addr ) >> 4 );
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
rc = -RIG_OK;
}
else
{
rc = -RIG_EIO;
}
v = ADR( ( 0x00f & addr ) );
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
if ( 0xff < addr )
{
v = ADH( ( 0xf00 & addr ) >> 8 );
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
curAddr = addr;
rc = -RIG_OK;
rig_debug( RIG_DEBUG_VERBOSE, "%s: set addr 0x%04x\n", __func__, addr );
}
else
{
rc = -RIG_EIO;
}
}
else
{
curAddr = addr;
rc = -RIG_OK;
rig_debug( RIG_DEBUG_VERBOSE, "%s: set addr 0x%04x\n", __func__, addr );
}
}
else
{
rc = -RIG_EIO;
}
}
}
else
{
rc = -RIG_EINVAL; /* invalid address */
}
}
else
{
rc = -RIG_EINVAL; /* invalid page */
}
return( rc );
}
/*
* /brief Write one byte to the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Value to write to radio
*
* \return RIG_OK on success, error code on failure
*
*/
int writeByte( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned char x )
{
int rc = -RIG_EIO;
unsigned char hi = SRH((x & 0xf0 ) >> 4 );
unsigned char lo = WRD( x & 0x0f );
assert( NULL != rig );
rc = setAddr( rig, page, addr );
if ( RIG_OK == rc )
{
rc = -RIG_EIO;
if ( 0 == write_block( &rig->state.rigport, (char *) &hi, 1 ) )
{
if ( 0 == write_block( &rig->state.rigport, (char *) &lo, 1 ) )
{
rc = -RIG_OK;
curAddr++;
rig_debug( RIG_DEBUG_VERBOSE, "%s: wrote byte 0x%02x\n", __func__, x );
}
}
}
return( rc );
}
/*
* /brief Write two bytes to the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Value to write to radio
*
* \return Number of bytes written, 0 on error. Get error code with getErrno.
*
*/
int writeShort( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned short x )
{
int rc = -RIG_EIO;
unsigned char v = (unsigned char) ( ( x & 0xff00 ) >> 8 );
rc = writeByte( rig, page, addr, v );
if ( RIG_OK == rc )
{
v = (unsigned char) ( x & 0x00ff );
rc = writeByte( rig, page, addr + 1, v );
}
return( rc );
}
/*
* /brief Write three bytes to the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Value to write to radio
*
* \return Number of bytes written, 0 on error. Get error code with getErrno.
*
*/
int write3Bytes( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned int x )
{
int rc = -RIG_EIO;
unsigned char v = (unsigned char) ( ( x & 0xff0000 ) >> 16 );
rc = writeByte( rig, page, addr, v );
if ( RIG_OK == rc )
{
v = (unsigned char) ( ( x & 0x00ff00 ) >> 8 );
rc = writeByte( rig, page, addr + 1, v );
if ( RIG_OK == rc )
{
v = (unsigned char) ( x & 0x0000ff );
rc = writeByte( rig, page, addr + 2, v );
}
}
return( rc );
}
/*
* /brief Write unsigned int (4 bytes) to the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Value to write to radio
*
* \return Number of bytes written, 0 on error. Get error code with getErrno.
*
*/
int writeInt( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned int x )
{
int rc = -RIG_EIO;
unsigned char v = (unsigned char) ( ( x & 0xff000000 ) >> 24 );
rc = writeByte( rig, page, addr, v );
if ( RIG_OK == rc )
{
v = (unsigned char) ( ( x & 0x00ff0000 ) >> 16 );
rc = writeByte( rig, page, addr + 1, v );
if ( RIG_OK == rc )
{
v = (unsigned char) ( ( x & 0x0000ff00 ) >> 8 );
rc = writeByte( rig, page, addr + 2, v );
if ( RIG_OK == rc )
{
v = (unsigned char) ( x & 0x000000ff );
rc = writeByte( rig, page, addr + 3, v );
}
}
}
return( rc );
}
/*
* /brief Read one byte from the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Pointer to value to read from radio
*
* \return RIG_OK on success, error code on failure
*
*/
int readByte( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned char *x )
{
int rc = -RIG_OK;
unsigned char v = RDD( 1 ); // Read command
assert( NULL != rig );
assert( NULL != x );
rc = setAddr( rig, page, addr );
if ( RIG_OK == rc )
{
rc = -RIG_EIO;
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
if ( 1 == read_block( &rig->state.rigport, (char *) x, 1 ) )
{
curAddr++;
rc = -RIG_OK;
rig_debug( RIG_DEBUG_VERBOSE, "%s: read 0x%02x\n", __func__, *x );
}
}
}
return( rc );
}
/*
* /brief Read an unsigned short (two bytes) from the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Pointer to value to read from radio
*
* \return RIG_OK on success, error code on failure
*
*/
int readShort( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned short *x )
{
int rc = -RIG_OK;
unsigned char v;
assert( NULL != rig );
assert( NULL != x );
rc = readByte( rig, page, addr, &v );
if ( RIG_OK == rc )
{
*x = (unsigned short) v << 8;
rc = readByte( rig, page, addr + 1, &v );
if ( RIG_OK == rc )
{
*x += (unsigned short) v;
rig_debug( RIG_DEBUG_VERBOSE, "%s: read 0x%04x\n", __func__, *x );
}
}
return( rc );
}
/*
* /brief Read an unsigned int (three bytes) from the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Pointer to value to read from radio
*
* \return RIG_OK on success, error code on failure
*
*/
int read3Bytes( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned int *x )
{
int rc = -RIG_OK;
unsigned char v;
assert( NULL != rig );
assert( NULL != x );
rc = readByte( rig, page, addr, &v );
if ( RIG_OK == rc )
{
*x = (unsigned int) v << 16;
rc = readByte( rig, page, addr + 1, &v );
if ( RIG_OK == rc )
{
*x += (unsigned int) v << 8;
rc = readByte( rig, page, addr + 2, &v );
if ( RIG_OK == rc )
{
*x += (unsigned int) v;
rig_debug( RIG_DEBUG_VERBOSE, "%s: read 0x%06x\n", __func__, *x );
}
}
}
return( rc );
}
/*
* /brief Read an unsigned int (four bytes) from the receiver
*
* /param rig Pointer to rig struct
* /param page Memory page number (0-4, 15)
* /param addr Address offset within page (0-4095, depending on page)
* /param x Pointer to value to read from radio
*
* \return RIG_OK on success, error code on failure
*
*/
int readInt( RIG *rig, enum PAGE_e page, unsigned int addr, unsigned int *x )
{
int rc = 0;
unsigned char v;
assert( NULL != rig );
assert( NULL != x );
rc = readByte( rig, page, addr, &v );
if ( RIG_OK == rc )
{
*x = (unsigned int) v << 24;
rc = readByte( rig, page, addr + 1, &v );
if ( RIG_OK == rc )
{
*x += (unsigned int) v << 16;
rc = readByte( rig, page, addr + 2, &v );
if ( RIG_OK == rc )
{
*x += (unsigned int) v << 8;
rc = readByte( rig, page, addr + 3, &v );
{
*x += (unsigned int) v;
rig_debug( RIG_DEBUG_VERBOSE, "%s: read 0x%08x\n", __func__, *x );
}
}
}
}
return( rc );
}
/*
* /brief Read raw AGC value from the radio
*
* /param rig Pointer to rig struct
*
* \return RIG_OK on success, error code on failure
*/
int readSignal( RIG * rig, unsigned char *x )
{
int rc = -RIG_EIO;
assert( NULL != rig );
assert( NULL != x );
rc = execRoutine( rig, READ_SIGNAL ); // Read raw AGC value
if ( RIG_OK == rc )
{
if ( 1 == read_block( &rig->state.rigport, (char *) x, 1 ) )
{
rc = -RIG_OK;
rig_debug( RIG_DEBUG_VERBOSE, "%s: raw AGC %03d\n", __func__, *x );
}
}
return( rc );
}
/*
* /brief Flush I/O with radio
*
* /param rig Pointer to rig struct
*
*/
int flushBuffer( RIG * rig )
{
int rc = -RIG_EIO;
char v = '/';
assert( NULL != rig );
if ( 0 == write_block( &rig->state.rigport, &v, 1 ) )
{
rc = -RIG_OK;
}
return( rc );
}
/*
* /brief Lock receiver for remote operations
*
* /param rig Pointer to rig struct
* /param level Lock level (0-3)
*
*/
int lockRx( RIG * rig, enum LOCK_LVL_e level )
{
int rc = -RIG_EIO;
unsigned char v;
assert( NULL != rig );
if ( LOCK_NONE > level ) /* valid level? */
{
if ( curLock != level ) /* need to change level? */
{
v = LOC( level );
if ( 0 == write_block( &rig->state.rigport, (char *) &v, 1 ) )
{
rc = -RIG_OK;
curLock = level;
}
}
else
{
rc = -RIG_OK;
}
}
else
{
rc = -RIG_EINVAL;
}
return( rc );
}
/*
* \brief Convert one byte BCD value to int
*
* \param bcd BCD value (0-99)
*
* \return Integer value of BCD parameter (0-99), -1 on failure
*/
int bcd2Int( const unsigned char bcd )
{
int rc = -1;
unsigned char hi = ((bcd & 0xf0) >> 4);
unsigned char lo = (bcd & 0x0f);
if ( (unsigned char) 0x0a > hi )
{
rc = (int) hi * 10;
if ( (unsigned char) 0x0a > lo )
{
rc += (int) lo;
}
else
{
rc = -1;
}
}
return( rc );
}
/*
* \brief Convert int into 2 digit BCD number
*
* \param int Integer value (0-99)
*
* \return 2 digit BCD equvalent (0-99), 0xff on failure
*/
unsigned char int2BCD( const unsigned int val )
{
unsigned char rc = (unsigned char) 0xff;
unsigned char tens = (unsigned char) (val / 10);
unsigned char ones = (unsigned char) (val % 10);
if ( (unsigned char) 10 > tens )
{
rc = ( tens << 4 );
if ( (unsigned char) 10 > ones )
{
rc = rc | ones;
}
else
{
rc = (unsigned char) 0xff;
}
}
return ( rc );
}
/*
* \brief Convert raw AGC value to calibrated level in dBm
*
* \param rig Pointer to rig struct
* \param rawAgc raw AGC value (0-255)
* \param tab Pointer to calibration table struct
* \param dbm Pointer to value to hold calibrated level (S9 = 0 dBm)
*
* \return RIG_OK on success, error code on failure
*
* To calculate the signal level, table values should be subtracted from
* the AGC voltage in turn until a negative value would result. This gives
* the rough level from the table position. The accuracy can be improved by
* proportioning the remainder into the next table step. See the following
* example :-
*
* A read signal strength operation returns a value of 100
* Subtract cal byte 1 (64) leaves 36 level > -113dBm
* Subtract cal byte 2 (10) leaves 26 level > -103dBm
* Subtract cal byte 3 (10) leaves 16 level > -93dBm
* Subtract cal byte 4 (12) leaves 4 level > -83dBm
* Test cal byte 5 (12) - no subtraction
* Fine adjustment value = (remainder) / (cal byte 5) * (level step)
* = 4 / 12 * 10 = 3dB
* Signal level = -83dBm + 3dB = -80dB
*
* The receiver can operate the RF attenuator automatically if the signal
* level is likely to overload the RF stages. Reading the RFAGC byte (page 0,
* location 49) gives the attenuation in 10dB steps. This value should be
* read and added to the value calculated above.
*/
int getCalLevel( RIG * rig, unsigned char rawAgc, int *dbm )
{
int rc = -RIG_OK;
int i;
int raw = (int) rawAgc;
int step = 10;
unsigned char v;
assert( NULL != rig );
assert( NULL != dbm );
for ( i = 0; i < rig->state.str_cal.size; i++ )
{
if ( 0 > ( raw - rig->state.str_cal.table[ i ].raw ) )
{
/* calculate step size */
if ( 0 < i )
{
step = rig->state.str_cal.table[ i ].val -
rig->state.str_cal.table[ i - 1 ].val;
}
/* interpolate final value */
*dbm += (int) ( ( (double) raw / (double) rig->state.str_cal.table[ i ].raw ) * (double) step );
break;
}
else
{
raw = raw - rig->state.str_cal.table[ i ].raw;
*dbm = rig->state.str_cal.table[ i ].val;
}
}
/* Factor in RFAGC setting */
rc = readByte( rig, WORKING, RFGAIN, &v );
if ( RIG_OK == rc )
{
*dbm += ( (int) v * -10 ) + 10;
}
/* Adjust to S9 == 0 scale */
*dbm += 73; /* S9 == -73 dBm */
return ( rc );
}
/*
* \brief Get bandwidth of given filter
*
* \param rig Pointer to rig struct
* \param filter Filter number (1-6)
*
* \return Filter bandwidth in Hz, -1 on failure
*/
int getFilterBW( RIG *rig, enum FILTER_e filter )
{
int rc = -1;
unsigned char bw;
rc = readByte( rig, BBRAM, (FL_BW + ((filter - 1) * 4)), &bw );
if ( RIG_OK == rc )
{
rc = bcd2Int( bw ) * 100;
}
else
{
rc = -1;
}
rig_debug( RIG_DEBUG_VERBOSE, "%s: filter %1d BW %5d\n", __func__, filter, rc );
return( rc );
}
/*
* /brief Convert DDS steps to frequency in Hz
*
* /param steps DDS count
*
* /return Frequency in Hz or 0 on failure
*/
freq_t ddsToHz( const unsigned int steps )
{
freq_t rc = 0.0;
rc = ( (freq_t) steps * 44545000.0 / 16777216.0 );
return( rc );
}
/*
* /brief Convert frequency in Hz to DDS steps
*
* /param freq Frequency in Hz
*
* /return DDS steps (24 bits) or 0 on failure
*/
unsigned int hzToDDS( const freq_t freq )
{
unsigned int rc = 0;
double err[3] = { 0.0, 0.0, 0.0 };
rc = (unsigned int) ( freq * 16777216.0 / 44545000.0 );
/* calculate best DDS count based on bletcherous,
irrational tuning step of 2.65508890151977539062 Hz/step
(actual ratio is 44545000.0 / 16777216.0) */
err[ 0 ] = fabs( freq - ddsToHz( (rc - 1) ) );
err[ 1 ] = fabs( freq - ddsToHz( rc ) );
err[ 2 ] = fabs( freq - ddsToHz( (rc + 1) ) );
if ( err[ 0 ] < err[ 1 ] && err[ 0 ] < err[ 2 ] )
{
rc--;
}
else if ( err[ 2 ] < err[ 1 ] && err[ 2 ] < err[ 0 ] )
{
rc++;
}
rig_debug( RIG_DEBUG_VERBOSE, "%s: err[0 - 2] = %f %f %f rc 0x%08x\n",
__func__, err[ 0 ], err[ 1 ], err[ 2 ], rc );
return( rc );
}
/*
* /brief Convert PBS/BFO steps to frequency in Hz
*
* /param steps PBS/BFO offset steps
*
* /return Frequency in Hz or 0 on failure
*
* Max +ve offset is 127, max -ve offset is 128
* Min -ve offset is 255
*/
float pbsToHz( const unsigned char steps )
{
freq_t rc = 0.0;
/* treat steps as a 1's complement signed 8-bit number */
if ( 128 > steps )
{
rc = ( ( (float) steps * 12.5 * 44545000.0 ) / 16777216.0 );
}
else
{
rc = ( ( (float) (~steps & 0x7f) * -12.5 * 44545000.0 ) / 16777216.0 );
}
rig_debug( RIG_DEBUG_VERBOSE, "%s: raw %d hz %f\n", __func__, steps, rc );
return( rc );
}
/*
* /brief Convert PBS/BFO offset frequency in Hz to steps
*
* /param freq Offset frequency in Hz
*
* /return steps (8 bits) or 0 on failure
*/
unsigned char hzToPBS( const float freq )
{
unsigned char rc;
int steps;
if ( 0 < freq )
{
steps = ( ( (freq + 0.5) * 16777216.0 ) / ( 44545000.0 * 12.5 ) );
}
else
{
steps = ( ( (freq - 0.5) * 16777216.0 ) / ( 44545000.0 * 12.5 ) );
}
rig_debug( RIG_DEBUG_VERBOSE, "%s: steps %d\n", __func__, steps );
if ( 0 <= steps )
{
rc = (unsigned char) (steps & 0x7f);
}
else if ( -128 < steps )
{
rc = (unsigned char) (steps + 255);
}
else
{
rc = (unsigned char) 0;
}
rig_debug( RIG_DEBUG_VERBOSE, "%s: hz %f rc %d\n", __func__, freq, rc );
return( rc );
}
/*
* /brief Convert native Mode to Hamlib mode
*
* /param mode Native mode value
*
* /return Hamlib mode value
*/
rmode_t modeToHamlib( const unsigned char mode )
{
rmode_t rc = RIG_MODE_NONE;
switch( mode )
{
case AM:
rc = RIG_MODE_AM;
break;
case SAM:
rc = RIG_MODE_AMS;
break;
case FM:
rc = RIG_MODE_FM;
break;
case DATA:
rc = RIG_MODE_RTTY;
break;
case CW:
rc = RIG_MODE_CW;
break;
case LSB:
rc = RIG_MODE_LSB;
break;
case USB:
rc = RIG_MODE_USB;
break;
default:
break;
};
rig_debug( RIG_DEBUG_VERBOSE, "%s: Native %d, Hamlib %d\n",
__func__, mode, rc );
return( rc );
}
/*
* /brief Convert Hamlib Mode to native mode
*
* /param mode Hamlib mode value
*
* /return Native mode value
*/
unsigned char modeToNative( const rmode_t mode )
{
unsigned char rc = (unsigned char) MODE_NONE;
switch( mode )
{
case RIG_MODE_AM:
rc = (unsigned char) AM;
break;
case RIG_MODE_AMS:
rc = (unsigned char) SAM;
break;
case RIG_MODE_FM:
rc = (unsigned char) FM;
break;
case RIG_MODE_RTTY:
rc = (unsigned char) DATA;
break;
case RIG_MODE_CW:
rc = (unsigned char) CW;
break;
case RIG_MODE_LSB:
rc = (unsigned char) LSB;
break;
case RIG_MODE_USB:
rc = (unsigned char) USB;
break;
default:
break;
};
rig_debug( RIG_DEBUG_VERBOSE, "%s: Hamlib %d, native %d\n",
__func__, mode, rc );
return( rc );
}
/*
* /brief Convert native AGC speed to Hamlib AGC speed
*
* /param agc Native AGC speed value
*
* /return Hamlib AGC speed value
*/
enum agc_level_e agcToHamlib( const unsigned char agc )
{
enum agc_level_e rc = RIG_AGC_AUTO;
switch( agc )
{
case AGC_FAST:
rc = RIG_AGC_FAST;
break;
case AGC_MED:
rc = RIG_AGC_MEDIUM;
break;
case AGC_SLOW:
rc = RIG_AGC_SLOW;
break;
case AGC_OFF:
rc = RIG_AGC_OFF;
break;
default:
break;
};
rig_debug( RIG_DEBUG_VERBOSE, "%s: Native %d, Hamlib %d\n",
__func__, agc, rc );
return( rc );
}
/*
* /brief Convert Hamlib AGC speed to native AGC speed
*
* /param agc Hamlib AGC speed value
*
* /return Native AGC speed value
*/
unsigned char agcToNative( const enum agc_level_e agc )
{
unsigned char rc = (unsigned char) AGC_NONE;
switch( agc )
{
case RIG_AGC_OFF:
rc = (unsigned char) AGC_OFF;
break;
case RIG_AGC_FAST:
rc = (unsigned char) AGC_FAST;
break;
case RIG_AGC_SLOW:
rc = (unsigned char) AGC_SLOW;
break;
case RIG_AGC_MEDIUM:
rc = (unsigned char) AGC_MED;
break;
case RIG_AGC_SUPERFAST:
case RIG_AGC_USER:
case RIG_AGC_AUTO:
default:
rc = (unsigned char) AGC_NONE;
break;
};
rig_debug( RIG_DEBUG_VERBOSE, "%s: Hamlib %d, native %d\n",
__func__, agc, rc );
return( rc );
}
/*
* /brief Get page size
*
* /param page Page to get size of
*
* /return Page size, -1 on error
*/
int pageSize( const enum PAGE_e page )
{
int rc = -1;
if ( ( WORKING <= page ) && ( EEPROM3 >= page ) )
{
rc = (int) PAGE_SIZE[ page ];
}
else if ( ROM == page )
{
rc = (int) PAGE_SIZE[ page ];
}
else
{
rc = -1;
}
return( rc );
}
/*
* /brief Set and execute IR controller code
*
* /param code IR code to execute
*
* \return RIG_OK on success, error code on failure
*/
int sendIRCode( RIG *rig, enum IR_CODE_e code )
{
int rc = -RIG_EIO;
unsigned char v = (unsigned char) code;
assert( NULL != rig );
rc = writeByte( rig, WORKING, IRCODE, v );
if ( RIG_OK == rc )
{
rc = execRoutine( rig, SET_ALL );
if ( RIG_OK == rc )
{
rig_debug( RIG_DEBUG_VERBOSE, "%s: set IR code %d\n", __func__, code );
}
}
return( rc );
}