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tinySA/sa_cmd.c

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extern volatile int SI4432_Sel; // currently selected SI4432
void SI4432_Write_Byte(byte ADR, byte DATA );
byte SI4432_Read_Byte( byte ADR );
int VFO = 0;
int points = 101; // For 's' and 'm' commands
VNA_SHELL_FUNCTION(cmd_mode)
{
if (argc != 2) {
usage:
shell_printf("usage: mode low|high input|output\r\n");
return;
}
if (strcmp(argv[0],"low") == 0) {
if (strcmp(argv[1],"input") == 0)
set_mode(M_LOW);
else if(strcmp(argv[1],"output") == 0)
set_mode(M_GENLOW);
else
goto usage;
} else if (strcmp(argv[0],"high") == 0) {
if (strcmp(argv[1],"input") == 0)
set_mode(M_HIGH);
else if(strcmp(argv[1],"output") == 0)
set_mode(M_GENHIGH);
else
goto usage;
} else
goto usage;
}
VNA_SHELL_FUNCTION(cmd_modulation )
{
if (argc != 1) {
usage:
shell_printf("usage: modulation off|AM|NFM|WFM|extern\r\n");
return;
}
int m = MO_NONE;
if (strcmp(argv[0],"off") == 0) {
} else if (strcmp(argv[0],"AM") == 0) {
m = MO_AM;
} else if (strcmp(argv[0],"NFM") == 0) {
m = MO_NFM;
} else if (strcmp(argv[0],"WFM") == 0) {
m = MO_WFM;
} else if (strcmp(argv[0],"extern") == 0) {
m = MO_EXTERNAL;
} else
goto usage;
set_modulation(m);
}
VNA_SHELL_FUNCTION(cmd_spur)
{
if (argc != 1) {
usage:
shell_printf("usage: spur on|off\r\n");
return;
}
if (strcmp(argv[0],"on") == 0) {
setting.spur = 1;
} else if (strcmp(argv[0],"off") == 0) {
setting.spur = 0;
} else
goto usage;
}
VNA_SHELL_FUNCTION(cmd_attenuate)
{
if (argc != 1) {
usage:
shell_printf("usage: attenuate 0..31|auto\r\n");
return;
}
if (strcmp(argv[0],"auto") == 0) {
set_auto_attenuation();
} else {
int a = my_atoi(argv[0]);
if (a < 0 || a>31)
goto usage;
set_attenuation(a);
}
}
VNA_SHELL_FUNCTION(cmd_level)
{
if (argc != 1) {
usage:
shell_printf("usage: level -76..20\r\n");
return;
}
float f = my_atof(argv[0]);
set_level(f);
}
VNA_SHELL_FUNCTION(cmd_levelsweep)
{
if (argc != 1) {
usage:
shell_printf("usage: levelsweep -76..+76\r\n");
return;
}
float f = my_atof(argv[0]);
set_level_sweep(f);
}
VNA_SHELL_FUNCTION(cmd_reflevel)
{
if (argc != 1) {
usage:
shell_printf("usage: reflevel <level>|auto\r\n");
return;
}
if (strcmp(argv[0],"auto") == 0) {
set_auto_reflevel(true);
} else {
float r = my_atof(argv[0]);
if (r < -150.0 || r>100.0)
goto usage;
set_auto_reflevel(false);
set_reflevel(r);
}
}
VNA_SHELL_FUNCTION(cmd_rbw)
{
if (argc != 1) {
usage:
shell_printf("usage: rbw 2..600|auto\r\n");
return;
}
if (strcmp(argv[0],"auto") == 0 || strcmp(argv[0],"0") == 0) {
set_RBW(0);
} else {
int a = my_atoi(argv[0]);
if (a < 2 || a>600)
goto usage;
set_RBW(a);
}
}
VNA_SHELL_FUNCTION(cmd_if)
{
if (argc != 1) {
usage:
shell_printf("usage: if {freq}\r\n");
return;
} else {
int a = my_atoi(argv[0]);
if (a < 433000000 || a>435000000)
goto usage;
set_IF(a);
}
}
VNA_SHELL_FUNCTION(cmd_v)
{
if (argc != 1) {
shell_printf("%d\r\n", SI4432_Sel);
return;
}
VFO = my_atoi(argv[0]);
shell_printf("VFO %d\r\n", VFO);
}
int xtoi(char *t)
{
int v=0;
while (*t) {
if ('0' <= *t && *t <= '9')
v = v*16 + *t - '0';
else if ('a' <= *t && *t <= 'f')
v = v*16 + *t - 'a' + 10;
else if ('A' <= *t && *t <= 'F')
v = v*16 + *t - 'A' + 10;
else
return v;
t++;
}
return v;
}
VNA_SHELL_FUNCTION(cmd_y)
{
int rvalue;
int lvalue = 0;
if (argc != 1 && argc != 2) {
shell_printf("usage: y {addr(0-95)} [value(0-FF)]\r\n");
return;
}
rvalue = xtoi(argv[0]);
SI4432_Sel = VFO;
if (argc == 2){
lvalue = xtoi(argv[1]);
SI4432_Write_Byte(rvalue, lvalue);
} else {
lvalue = SI4432_Read_Byte(rvalue);
shell_printf("%x\r\n", lvalue);
}
}
VNA_SHELL_FUNCTION(cmd_selftest)
{
if (argc < 1 || argc > 2) {
shell_printf("usage: selftest (1-3) [arg]\r\n");
return;
}
setting.test = my_atoi(argv[0]);
if (argc == 1)
setting.test_argument = 0;
else
setting.test_argument = my_atoi(argv[1]);
sweep_mode = SWEEP_SELFTEST;
}
VNA_SHELL_FUNCTION(cmd_x)
{
uint32_t reg;
if (argc != 1) {
shell_printf("usage: x value(0-FFFFFFFF)\r\n");
return;
}
reg = xtoi(argv[0]);
if ((reg & 7) == 5) {
if (reg & (1<<22))
VFO = 1;
else
VFO = 0;
reg &= ~0xc00000; // Force led to show lock
reg |= 0x400000;
}
#ifdef __ULTRA_SA__
ADF4351_WriteRegister32(VFO, reg);
#endif
shell_printf("x=%x\r\n", reg);
}
VNA_SHELL_FUNCTION(cmd_i)
{
int rvalue;
return; // Don't use!!!!
SI4432_Init();
shell_printf("SI4432 init done\r\n");
if (argc == 1) {
rvalue = xtoi(argv[0]);
set_switches(rvalue);
set_mode(rvalue);
shell_printf("SI4432 mode %d set\r\n", rvalue);
}
}
VNA_SHELL_FUNCTION(cmd_o)
{
(void) argc;
uint32_t value = my_atoi(argv[0]);
if (VFO == 0)
setting.frequency_IF = value;
set_freq(VFO, value);
}
VNA_SHELL_FUNCTION(cmd_d)
{
(void) argc;
(void) argv;
// int32_t a = my_atoi(argv[0]);
// setting.drive = a;
}
VNA_SHELL_FUNCTION(cmd_a)
{
(void)argc;
if (argc != 1) {
shell_printf("a=%d\r\n", frequencyStart);
return;
}
int32_t value = my_atoi(argv[0]);
frequencyStart = value;
}
VNA_SHELL_FUNCTION(cmd_b)
{
(void)argc;
if (argc != 1) {
shell_printf("b=%d\r\n", frequencyStop);
return;
}
int32_t value = my_atoi(argv[0]);
frequencyStop = value;
}
VNA_SHELL_FUNCTION(cmd_t)
{
(void)argc;
(void)argv;
}
VNA_SHELL_FUNCTION(cmd_e)
{
(void)argc;
if (argc != 1) {
shell_printf("e=%d\r\n", setting.tracking);
return;
}
setting.tracking = my_atoi(argv[0]);
if (setting.tracking == -1)
setting.tracking = false;
else
setting.tracking = true;
if (argc >1)
frequencyExtra = my_atoi(argv[1]);
}
VNA_SHELL_FUNCTION(cmd_s)
{
(void)argc;
if (argc != 1) {
shell_printf("s=%d\r\n", points);
return;
}
points = my_atoi(argv[0]);
}
void sweep_remote(void)
{
int old_step = setting.frequency_step;
uint32_t f_step = (frequencyStop-frequencyStart)/ points;
setting.frequency_step = f_step;
streamPut(shell_stream, '{');
dirty = true;
for (int i = 0; i<points; i++) {
if (operation_requested)
break;
float val = perform(false, i, frequencyStart - setting.frequency_IF + f_step * i, false);
streamPut(shell_stream, 'x');
int v = val*2 + 256;
streamPut(shell_stream, (uint8_t)(v & 0xFF));
streamPut(shell_stream, (uint8_t)((v>>8) & 0xFF));
// enable led
}
streamPut(shell_stream, '}');
setting.frequency_step = old_step;
sweep_mode = 0;
}
VNA_SHELL_FUNCTION(cmd_m)
{
(void)argc;
(void)argv;
// set_mode(0);
// setting.tracking = false; //Default test setup
// setting.step_atten = false;
// set_attenuation(0);
// set_reflevel(-10);
// set_sweep_frequency(ST_START,frequencyStart - setting.frequency_IF );
// set_sweep_frequency(ST_STOP, frequencyStop - setting.frequency_IF);
// draw_cal_status();
pause_sweep();
// update_rbw();
chThdSleepMilliseconds(10);
sweep_mode = SWEEP_REMOTE;
// update_rbw();
}
VNA_SHELL_FUNCTION(cmd_p)
{
(void)argc;
return;
int p = my_atoi(argv[0]);
int a = my_atoi(argv[1]);
if (p==5)
set_attenuation(-a);
if (p==6)
set_mode(a);
if (p==1)
if (get_refer_output() != a)
set_refer_output(a);
}
VNA_SHELL_FUNCTION(cmd_w)
{
(void)argc;
int p = my_atoi(argv[0]);
return;
set_RBW(p);
}
VNA_SHELL_FUNCTION(cmd_correction)
{
(void)argc;
if (argc == 0) {
shell_printf("index frequency value\r\n");
for (int i=0; i<CORRECTION_POINTS; i++) {
shell_printf("%d %d %.1f\r\n", i, config.correction_frequency[i], config.correction_value[i]);
}
return;
}
if (argc == 1 && (strcmp(argv[0],"reset") == 0)) {
for (int i=0; i<CORRECTION_POINTS; i++) {
config.correction_value[i] = 0.0;
}
shell_printf("correction table reset\r\n");
return;
}
if (argc != 3) {
shell_printf("usage: correction 0-9 frequency(Hz) value(dB)\r\n");
return;
}
int i = my_atoi(argv[0]);
uint32_t f = my_atoui(argv[1]);
float v = my_atof(argv[2]);
config.correction_frequency[i] = f;
config.correction_value[i] = v;
shell_printf("updated %d to %d %.1f\r\n", i, config.correction_frequency[i], config.correction_value[i]);
}
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