2014-06-26 11:10:51 +00:00
# include <cmath>
# include <stack>
# include <cerrno>
# include <cstring>
# include "pthread.h"
# include "core/core.h"
# include "core/stopwatch.h"
# include "core/result.h"
# include "core/xml_states.h"
# include "Spectrum-MI40xxSeries.h"
2014-08-01 14:18:05 +00:00
# include <sstream>
2014-06-26 11:10:51 +00:00
# ifndef SPC_DEBUG
# define SPC_DEBUG 0
# endif
# ifndef SIZETPRINTFLETTER
# ifndef __LP64__
# define SIZETPRINTFLETTER "u"
# else
# define SIZETPRINTFLETTER "lu"
# endif
# endif
void SpectrumMI40xxSeries : : Configuration : : print ( FILE * f ) {
fprintf ( f , " Spectrum MI40xx Series Configuration: \n " ) ;
fprintf ( f , " Sample Frequency %g Hz, Acquisition Timeout %g \n " , samplefreq , timeout ) ;
if ( data_structure ! = NULL )
data_structure - > print ( f , 2 ) ;
else
fprintf ( f , " No Data to acquire \n " ) ;
for ( int i = 0 ; i < lSetChannels ; i + + ) {
fprintf ( f , " Channel %i: Impedance %f Ohm, Sensitivity %f V, Coupling %s \n " , i , impedance [ i ] , sensitivity [ i ] , ( coupling = = 0 ) ? " DC " : " AC " ) ;
}
}
SpectrumMI40xxSeries : : SpectrumMI40xxSeries ( const ttlout & t_line , float impedance , int ext_reference_clock ) {
// print neat string to inform the user
fprintf ( stderr , " Initializing ADC card \n " ) ;
// to be configured
device_id = 0 ;
trigger_line = t_line ;
default_settings . qwSetChEnableMap = channel_array ( ADC_MI_DEFAULT_CHANNELS ) ;
default_settings . lSetChannels = default_settings . qwSetChEnableMap . count ( ) ;
default_settings . impedance = new double [ default_settings . lSetChannels ] ;
default_settings . sensitivity = new double [ default_settings . lSetChannels ] ;
default_settings . offset = new int [ default_settings . lSetChannels ] ;
for ( int i = 0 ; i < default_settings . lSetChannels ; i + + ) {
default_settings . impedance [ i ] = ADC_MI_DEFAULT_IMPEDANCE ;
default_settings . sensitivity [ i ] = ADC_MI_DEFAULT_SENSITIVITY ; // Set sensitivity in Volts to the default (maximum) value
default_settings . offset [ i ] = ADC_MI_DEFAULT_OFFSET ; // Set offsets in % of sensitivity to default (0)
}
default_settings . ext_reference_clock = ext_reference_clock ; // Hz
effective_settings = NULL ;
# if defined __linux__
// ----- open driver -----
deviceno = open ( " /dev/spc0 " , O_RDWR ) ;
if ( deviceno = = - 1 ) {
std : : string error_message = " could not open /dev/spc0 " ;
if ( errno = = 0 ) throw SpectrumMI40xxSeries_error ( error_message + " (unknown error) " ) ;
else throw SpectrumMI40xxSeries_error ( error_message + " ( " + strerror ( errno ) + " ) " ) ;
}
# endif
# if defined __CYGWIN__
// open library dll
spectrum_driver_dll = LoadLibrary ( " spectrum.dll " ) ;
if ( spectrum_driver_dll = = NULL )
throw SpectrumMI40xxSeries_error ( " could not open driver dll " ) ;
deviceno = 0 ;
// load driver functions
# define load_spectrum_function(name) name = ( name##_type)GetProcAddress(spectrum_driver_dll, #name); \
if ( name = = NULL ) { FreeLibrary ( spectrum_driver_dll ) ; \
throw SpectrumMI40xxSeries_error ( " failed to load function " # name " " ) ; \
}
load_spectrum_function ( SpcInitPCIBoards ) ;
load_spectrum_function ( SpcGetParam ) ;
load_spectrum_function ( SpcSetParam ) ;
load_spectrum_function ( SpcGetData ) ;
// find spectrum boards
boardcount = 0 ;
SpcInitPCIBoards ( & boardcount , & PCIVersion ) ;
if ( boardcount < = 0 ) {
FreeLibrary ( spectrum_driver_dll ) ;
throw SpectrumMI40xxSeries_error ( " no spectrum boards found " ) ;
}
# endif
/* calculate the sample number that can be saved without fifo */
int memory_size = 0 ;
SpcGetParam ( deviceno , SPC_PCIMEMSIZE , & memory_size ) ;
fifo_minimal_size = memory_size / ( sizeof ( short int ) * 2 ) ;
/* get the device type */
SpcGetParam ( deviceno , SPC_PCITYP , & cardType ) ;
if ( cardType ! = TYP_MI4020 & & cardType ! = TYP_MI4021 & & cardType ! = TYP_MI4022 & & cardType ! = TYP_MI4030 & & cardType ! = TYP_MI4031 & & cardType ! = TYP_MI4032 ) {
throw SpectrumMI40xxSeries_error ( " Board type not supported " ) ;
}
/* make a check, whether spectrum board is running */
int actual_status = 0 ;
SpcGetParam ( deviceno , SPC_STATUS , & actual_status ) ;
if ( actual_status ! = SPC_READY ) {
fprintf ( stderr , " Warning: Spectrum board was is running before reset. \n " ) ;
}
# if SPC_DEBUG
fprintf ( stderr , " External reference clock: %i \n " , default_settings . ext_reference_clock ) ;
# endif
int ErrorOccurred = 1 ;
SpcSetParam ( deviceno , SPC_COMMAND , SPC_RESET ) = = ERR_OK & & // reset device first
SpcSetParam ( deviceno , SPC_GATE , 1 ) = = ERR_OK & & // Gated Triggering
SpcSetParam ( deviceno , SPC_PLL_ENABLE , 1 ) = = ERR_OK & & // Internal PLL enabled for clock
SpcSetParam ( deviceno , SPC_CLOCKOUT , 0 ) = = ERR_OK & & // No clock output
SpcSetParam ( deviceno , SPC_REFERENCECLOCK , default_settings . ext_reference_clock ) = = ERR_OK & & // external reference clock
SpcSetParam ( deviceno , SPC_EXTERNALCLOCK , 0 ) = = ERR_OK & & // but no external sample clock
SpcSetParam ( deviceno , SPC_CLOCK50OHM , 0 ) = = ERR_OK & & // clock input NOT with 50Ohm impedance
SpcSetParam ( deviceno , SPC_TRIGGERMODE , TM_TTLPOS ) = = ERR_OK & & // ttl trigger is used
SpcSetParam ( deviceno , SPC_TRIGGEROUT , 0 ) = = ERR_OK & & // No trigger output
SpcSetParam ( deviceno , SPC_TRIGGER50OHM , 0 ) = = ERR_OK & & // Trigger to 1MOhm, necessary for steep slopes
( ErrorOccurred = 0 ) ; // done, really no error occurred
// ----- driver error: request error and end program -----
if ( ErrorOccurred ! = 0 ) {
int32 lErrorCode , lErrorReg , lErrorValue ;
SpcGetParam ( deviceno , SPC_LASTERRORCODE , & lErrorCode ) ;
SpcGetParam ( deviceno , SPC_LASTERRORREG , & lErrorReg ) ;
SpcGetParam ( deviceno , SPC_LASTERRORVALUE , & lErrorValue ) ;
char error_message [ 256 ] ;
snprintf ( error_message , sizeof ( error_message ) , " Configuration error %d in register %d at value %d " , lErrorCode , lErrorReg , lErrorValue ) ;
throw SpectrumMI40xxSeries_error ( error_message ) ;
}
/* print lines with useful information: */
fprintf ( stderr , " Spectrum MI40xx series board with %d byte memory \n " , memory_size ) ;
fprintf ( stderr ,
2017-02-06 21:05:00 +00:00
" impedance set to %g Ohm \n expecting trigger on id=%d ttl=0x%lx \n external clock frequency is %f Hz \n " ,
2014-06-26 11:10:51 +00:00
impedance ,
t_line . id ,
t_line . ttls . to_ulong ( ) ,
( float ) ext_reference_clock ) ;
}
void SpectrumMI40xxSeries : : sample_after_external_trigger ( double rate , size_t samples , double sensitivity , size_t resolution ) {
throw SpectrumMI40xxSeries_error ( " SpectrumMI40xxSeries::sample_after_external_trigger is not jet implemented " ) ;
}
void SpectrumMI40xxSeries : : collect_config_recursive ( state_sequent & exp , SpectrumMI40xxSeries : : Configuration & settings ) {
/* start with dummy node */
DataManagementNode * new_branch = new DataManagementNode ( NULL ) ;
DataManagementNode * where_to_append = new_branch ;
double parent_timeout = settings . timeout ;
settings . timeout = 0.0 ;
/* loop over all states and sequences */
for ( state_sequent : : iterator i = exp . begin ( ) ; i ! = exp . end ( ) ; + + i ) {
state * a_state = dynamic_cast < state * > ( * i ) ;
if ( a_state = = NULL )
throw SpectrumMI40xxSeries_error ( " state_atom not expected in sate_sequent " ) ;
if ( dynamic_cast < state_parallel * > ( * i ) ! = NULL )
throw SpectrumMI40xxSeries_error ( " state_parallel handling is not jet implemented " ) ;
state_sequent * a_sequence = dynamic_cast < state_sequent * > ( a_state ) ;
if ( a_sequence ! = NULL ) {
// found a sequence
DataManagementNode * tmp_structure = settings . data_structure ;
settings . data_structure = where_to_append ;
collect_config_recursive ( * a_sequence , settings ) ;
settings . data_structure = tmp_structure ;
2017-02-06 21:05:00 +00:00
} /* end working on sequence */
else {
2014-06-26 11:10:51 +00:00
// found a state, not a sequence
settings . timeout + = a_state - > length ;
2017-02-06 21:05:00 +00:00
2014-06-26 11:10:51 +00:00
# if SPC_DEBUG
2017-02-06 21:05:00 +00:00
fprintf ( stderr , " SETTINGS %e %e \n " , settings . timeout , a_state - > length ) ;
2014-06-26 11:10:51 +00:00
# endif
// collect analogin sections in state
std : : list < analogin * > inputs ;
/* loop over all device definitions in a state */
state : : iterator j = a_state - > begin ( ) ;
while ( j ! = a_state - > end ( ) ) {
analogin * input = dynamic_cast < analogin * > ( * j ) ;
if ( input ! = NULL & & input - > id = = device_id ) {
/* collect appropiate analogin sections, forget others */
if ( input - > samples < = 0 | | input - > sample_frequency < = 0 )
delete input ;
else
inputs . push_back ( input ) ;
j = a_state - > erase ( j ) ;
} else
+ + j ;
}
if ( ! inputs . empty ( ) ) {
/* evaluate the found analogin definitions */
if ( inputs . size ( ) > 1 ) {
while ( ! inputs . empty ( ) ) {
delete inputs . front ( ) ;
inputs . pop_front ( ) ;
}
throw ADC_exception ( " can not handle more than one analogin section per state " ) ;
}
/* save sampling frequency */
if ( settings . samplefreq < = 0 )
settings . samplefreq = inputs . front ( ) - > sample_frequency ;
else if ( settings . samplefreq ! = inputs . front ( ) - > sample_frequency ) {
while ( ! inputs . empty ( ) ) {
delete inputs . front ( ) ;
inputs . pop_front ( ) ;
}
throw ADC_exception ( " Sorry, but gated sampling requires same sampling frequency in all analogin sections " ) ;
}
/* save channel mask and number of channels */
if ( settings . lSetChannels > 0 & & settings . qwSetChEnableMap . to_ulong ( ) > 0 ) {
if ( settings . qwSetChEnableMap ! = inputs . front ( ) - > channels ) {
fprintf ( stderr , " Warning! different channels enabled in input %lu and in config %lu, setting to default \n " ,
settings . qwSetChEnableMap . to_ulong ( ) ,
inputs . front ( ) - > channels . to_ulong ( ) ) ;
settings . qwSetChEnableMap = channel_array ( ADC_MI_DEFAULT_CHANNELS ) ;
settings . lSetChannels = settings . qwSetChEnableMap . count ( ) ;
}
} else {
settings . qwSetChEnableMap = inputs . front ( ) - > channels ;
settings . lSetChannels = inputs . front ( ) - > nchannels ;
}
/* save sensitivity */
if ( settings . sensitivity ! = NULL ) { // if sensitivity is set, make sure it's valid (i.e. the same for all inputs)
for ( int k = 0 ; k < inputs . front ( ) - > nchannels ; k + + ) {
if ( settings . sensitivity [ k ] ! = inputs . front ( ) - > sensitivity [ k ] ) {
fprintf ( stderr , " Warning! different sensitivity specified (here %f, elsewhere %f), choosing higher voltage \n " ,
settings . sensitivity [ k ] ,
inputs . front ( ) - > sensitivity [ k ] ) ;
if ( settings . sensitivity [ k ] < inputs . front ( ) - > sensitivity [ k ] ) {
settings . sensitivity [ k ] = inputs . front ( ) - > sensitivity [ k ] ;
}
}
}
} else {
settings . sensitivity = inputs . front ( ) - > sensitivity ;
}
// check if sensitivity is valid
for ( int k = 0 ; k < inputs . front ( ) - > nchannels ; k + + ) {
bool sensAllowed = false ;
for ( int l = 0 ; l < ADC_MI_ALLOWED_SENSITIVITY_LENGTH ; l + + ) {
if ( settings . sensitivity [ k ] = = ADC_MI_ALLOWED_SENSITIVITY [ l ] ) {
sensAllowed = true ;
break ;
}
}
if ( ! sensAllowed ) {
fprintf ( stderr , " Warning! Illegal sensitivity specified for channel %i: %f " , k , inputs . front ( ) - > sensitivity [ k ] ) ;
settings . sensitivity [ k ] = ADC_MI_DEFAULT_SENSITIVITY ;
}
}
/* save impedance */
if ( settings . impedance ! = NULL ) {
for ( int k = 0 ; k < inputs . front ( ) - > nchannels ; k + + ) {
if ( settings . impedance [ k ] ! = inputs . front ( ) - > impedance [ k ] ) {
fprintf ( stderr , " Warning! different impedance specified (here %f, elsewhere %f), setting to default \n " ,
settings . impedance [ k ] ,
inputs . front ( ) - > impedance [ k ] ) ;
settings . impedance [ k ] = ADC_MI_DEFAULT_IMPEDANCE ;
}
if ( settings . impedance [ k ] ! = ADC_MI_DEFAULT_IMPEDANCE & & settings . impedance [ k ] ! = ADC_MI_ALLOWED_IMPEDANCE ) {
fprintf ( stderr , " Warning! Illegal impedance specified for channel %i: %f " , k , inputs . front ( ) - > impedance [ k ] ) ;
settings . offset [ k ] = 0 ;
}
}
} else {
settings . impedance = inputs . front ( ) - > impedance ;
}
/* save offsets */
if ( settings . offset ! = NULL ) {
for ( int k = 0 ; k < inputs . front ( ) - > nchannels ; k + + ) {
if ( settings . offset [ k ] ! = inputs . front ( ) - > offset [ k ] ) {
fprintf ( stderr , " Warning! different impedance specified (here %i, elsewhere %i), setting to default \n " ,
settings . offset [ k ] ,
inputs . front ( ) - > offset [ k ] ) ;
settings . offset [ k ] = ADC_MI_DEFAULT_OFFSET ;
}
if ( inputs . front ( ) - > offset [ k ] > 100 | | inputs . front ( ) - > offset [ k ] < - 100 ) {
fprintf ( stderr , " Warning! Illegal offset specified for channel %i: %i " , k , inputs . front ( ) - > offset [ k ] ) ;
settings . offset [ k ] = 0 ;
}
}
} else {
settings . offset = inputs . front ( ) - > offset ;
}
if ( inputs . front ( ) - > samples % 4 ! = 0 ) {
throw ADC_exception ( " Number of samples must be a multiple of four " ) ;
}
// calculate the time required
double delayed_gating_time = 0.0 ;
// the gating time has an offset, which was found to be 1.5 dwelltimes for <2.5MHz and 4.5 dwelltimes for >=2.5MHz
double gating_time ;
# if SPC_DEBUG
fprintf ( stderr , " Channels: %lu \n " , settings . qwSetChEnableMap . to_ulong ( ) ) ;
# endif
/* check if channel mask is legal for the card */
if ( this - > IsChannelMaskLegal ( inputs . front ( ) - > channels . to_ulong ( ) ) ) {
settings . qwSetChEnableMap = inputs . front ( ) - > channels ;
settings . lSetChannels = inputs . front ( ) - > nchannels ;
} else {
throw SpectrumMI40xxSeries_error ( " Selected channels combination not allowed for this card type " ) ;
}
/* apply proper timing */
if ( settings . qwSetChEnableMap . to_ulong ( ) = = ( CHANNEL0 | CHANNEL1 ) | | settings . qwSetChEnableMap . to_ulong ( ) = = ( CHANNEL0 | CHANNEL1 | CHANNEL2 | CHANNEL3 ) ) {
# if SPC_DEBUG
fprintf ( stderr , " Default Channels \n " ) ;
# endif
if ( settings . samplefreq < 2.5e6 ) {
// if sampling rate is <2.5MHz, there is another data handling mode,
// see MI4021 manual page 79: "Accquisition Delay: -6 Samples"
// it might be necessary to add 0.1 dwelltime to shift the sampling start a little more...
// edit by Stefan Reutter @2013-06, it seems that the MI4021 cards actually have a second
// threshold at 500 kHz that is not mentioned in the manual.
// this can be tested by disabling the if below and switching over the threshold
gating_time = ( inputs . front ( ) - > samples ) / settings . samplefreq ;
if ( settings . samplefreq > = 5e5 ) {
delayed_gating_time = ceil ( 1e8 * 6.0 / settings . samplefreq ) / 1e8 ;
} else {
delayed_gating_time = 0.0 ;
}
} else {
gating_time = ( inputs . front ( ) - > samples + 3 ) / settings . samplefreq ;
delayed_gating_time = 0.0 ;
}
}
// disabled the more exotic channel setup as it is untested with the updated timings and probably not used anyways
/* else if (settings.qwSetChEnableMap.to_ulong()==CHANNEL0 || settings.qwSetChEnableMap.to_ulong()==(CHANNEL0|CHANNEL2) ) {
# if SPC_DEBUG
fprintf ( stderr , " Weird Channels \n " ) ;
# endif
if ( settings . samplefreq < 5e6 ) {
gating_time = ( inputs . front ( ) - > samples + 1.5 ) / settings . samplefreq ;
delayed_gating_time = ceil ( 1e8 * 6.0 / settings . samplefreq ) / 1e8 ;
} else {
gating_time = ( inputs . front ( ) - > samples + 4.5 ) / settings . samplefreq ;
delayed_gating_time = - ceil ( 1e8 * 7.0 / settings . samplefreq ) / 1e8 ;
} */ else {
throw SpectrumMI40xxSeries_error ( " Selected channels combination not allowed " ) ;
}
gating_time = ceil ( 1e8 * gating_time ) / 1e8 ;
double time_required = delayed_gating_time + gating_time ;
// check time requirements
if ( a_state - > length < gating_time ) {
# if SPC_DEBUG
fprintf ( stderr , " state is shorter than acquisition time %e time required, %e state time \n " , gating_time , a_state - > length ) ;
# endif
// update the state length if it's shorter than the gate. this is usually due to rounding to 10 ns for the pulseblaster
2014-08-01 14:19:38 +00:00
if ( ceil ( 1e8 * ( a_state - > length + 3.0f / settings . samplefreq ) ) / 1e8 < time_required ) { //
2014-08-01 14:18:05 +00:00
std : : stringstream parameter_inf ;
parameter_inf < < " state is ( " < < inputs . front ( ) - > samples < < " samples, " < < settings . samplefreq < < " sampling rate, " < < time_required < < " time required, " < < a_state - > length < < " state time) " < < std : : endl ;
throw ADC_exception ( parameter_inf . str ( ) ) ;
2014-06-26 11:10:51 +00:00
} else {
a_state - > length = time_required ;
}
}
// if necessary, add the gating pulse delay...
if ( delayed_gating_time > 0.0 ) {
state * delayed_gating_state = new state ( * a_state ) ;
delayed_gating_state - > length = delayed_gating_time ;
// insert before me
exp . insert ( i , ( state_atom * ) delayed_gating_state ) ;
} else if ( delayed_gating_time < 0.0 ) {
/*
For + samples delays
1. get the previous state
2. if the length is not long enough ( 6 * dw ) add the state before
3. split the state ( s ) so that we have the gating on 6 * dw before the actual recording
*/
double rest_length = delayed_gating_time ;
state_sequent : : iterator i_prev ;
state * prev_state ;
i_prev = i ;
do {
i_prev - - ;
prev_state = dynamic_cast < state * > ( * ( i_prev ) ) ;
rest_length - = prev_state - > length ;
fprintf ( stderr , " DW rest_length: %g \n " , rest_length ) ;
fprintf ( stderr , " DW state_length: %g \n " , prev_state - > length ) ;
if ( rest_length > = 0 )
prev_state - > push_back ( trigger_line . copy_new ( ) ) ; // add trigger to this state
else { // split final state
state * prev_state_1 = prev_state - > copy_flat ( ) ; //create copy of current state
prev_state_1 - > length + = rest_length ; // adjust 1st part length
exp . insert ( i_prev , ( state_atom * ) prev_state_1 ) ; // insert AFTER prev_state
prev_state - > length = - rest_length ; // adjust 2nd part length
prev_state - > push_back ( trigger_line . copy_new ( ) ) ; // add trigger to 2nd part
break ;
}
} while ( i_prev ! = exp . begin ( ) | | rest_length > 0.0 ) ;
}
# if SPC_DEBUG
fprintf ( stderr , " sequence after pre_trigger correction: \n " ) ;
xml_state_writer ( ) . write_states ( stderr , exp ) ;
# endif
// adapt the pulse program for gated sampling
if ( a_state - > length = = gating_time ) {
// state has proper length
a_state - > push_back ( trigger_line . copy_new ( ) ) ;
} else {
# if SPC_DEBUG
fprintf ( stderr , " state too long, length %e, time required %e \n " , a_state - > length , time_required ) ;
# endif
// state is too long...
// create new one with proper time and gated sampling pulse
state * gated_sampling_pulse = new state ( * a_state ) ;
gated_sampling_pulse - > length = gating_time ;
gated_sampling_pulse - > push_back ( trigger_line . copy_new ( ) ) ;
// insert gate pulse state before remaining (original) state
exp . insert ( i , ( state_atom * ) gated_sampling_pulse ) ;
// shorten this state
a_state - > length - = time_required ;
}
# if SPC_DEBUG
fprintf ( stderr , " sequence after correcting trigger state: \n " ) ;
xml_state_writer ( ) . write_states ( stderr , exp ) ;
# endif
/* save sampleno */
DataManagementNode * new_one = new DataManagementNode ( new_branch ) ;
new_one - > n = inputs . front ( ) - > samples ;
new_one - > child = NULL ;
new_one - > next = where_to_append - > next ;
where_to_append - > next = new_one ;
where_to_append = new_one ;
while ( ! inputs . empty ( ) ) { delete inputs . front ( ) ; inputs . pop_front ( ) ; }
} /* !inputs.empty() */
} /* end working on state */
} /* i */
/* something happened? */
if ( new_branch - > next ! = NULL ) {
/* make dummy node to a loop */
new_branch - > n = exp . repeat ;
new_branch - > child = new_branch - > next ;
/* if possible, append it */
if ( settings . data_structure ! = NULL ) {
new_branch - > parent = settings . data_structure - > parent ;
new_branch - > next = settings . data_structure - > next ;
settings . data_structure - > next = new_branch ;
}
else {
new_branch - > parent = NULL ;
new_branch - > next = NULL ;
settings . data_structure = new_branch ;
}
}
else
delete new_branch ;
settings . timeout * = exp . repeat ;
settings . timeout + = parent_timeout ;
# ifdef SPC_DEBUG
fprintf ( stderr , " setting.timout %g \n " , settings . timeout ) ;
# endif
return ;
}
static void * SpectrumMI40xxSeries_TimeoutThread ( void * data ) {
int * ret = new int ;
* ret = ( ( SpectrumMI40xxSeries * ) data ) - > TimeoutThread ( ) ;
return ( void * ) ret ;
}
void SpectrumMI40xxSeries : : set_daq ( state & exp ) {
// cleanup?!
if ( ! fifobuffers . empty ( ) ) {
fprintf ( stderr , " normally there should be a cleanup at the end of acquisition \n " ) ;
for ( std : : vector < short int * > : : iterator i = fifobuffers . begin ( ) ; i ! = fifobuffers . end ( ) ; + + i ) free ( * i ) ;
fifobuffers . clear ( ) ;
}
/* what could be done: PCIBIT_GATE, PCIBIT_MULTI */
int features ;
SpcGetParam ( deviceno , SPC_PCIFEATURES , & features ) ;
state_sequent * exp_sequence = dynamic_cast < state_sequent * > ( & exp ) ;
if ( exp_sequence = = NULL )
throw ADC_exception ( " Spectrum-MI40xxSeries::set_daq only working on sequences " ) ;
# if SPC_DEBUG
fprintf ( stderr , " working on sequence: \n " ) ;
xml_state_writer ( ) . write_states ( stderr , * exp_sequence ) ;
# endif
/* find out what to do */
Configuration * conf = new Configuration ( ) ;
collect_config_recursive ( * exp_sequence , * conf ) ;
if ( conf - > samplefreq < = 0 ) conf - > samplefreq = default_settings . samplefreq ;
if ( conf - > impedance = = NULL ) conf - > impedance = default_settings . impedance ;
if ( conf - > sensitivity = = NULL ) conf - > sensitivity = default_settings . sensitivity ;
if ( conf - > offset = = NULL ) conf - > offset = default_settings . offset ;
if ( conf - > lSetChannels = = 0 ) {
conf - > lSetChannels = default_settings . lSetChannels ;
conf - > qwSetChEnableMap = default_settings . qwSetChEnableMap ;
}
size_t sampleno = ( conf - > data_structure = = NULL ) ? 0 : conf - > data_structure - > size ( ) ;
/* nothing to do! */
if ( sampleno = = 0 ) {
2017-02-06 21:05:00 +00:00
fprintf ( stderr , " oops, no sample number \n " ) ;
2014-06-26 11:10:51 +00:00
delete conf ;
effective_settings = NULL ;
return ;
}
if ( sampleno < 16 | | sampleno % 16 ! = 0 ) {
delete conf ;
throw SpectrumMI40xxSeries_error ( " Total number of samples must be multiple of 16 and at least 16 " ) ;
}
effective_settings = conf ;
# if SPC_DEBUG
/* settings for this experiment */
conf - > print ( stderr ) ;
# endif
/* make a check, whether spectrum board is running */
int actual_status = 0 ;
SpcGetParam ( deviceno , SPC_STATUS , & actual_status ) ;
if ( actual_status ! = SPC_READY ) {
fprintf ( stderr , " Warning: Spectrum board was/is running before starting data aquisition. \n " ) ;
SpcSetParam ( deviceno , SPC_COMMAND , SPC_STOP ) ; // stop the board
}
/* and the dirty things there...
- - - - - setup board for recording - - - - -
*/
for ( unsigned int j = 0 ; j < ( unsigned int ) effective_settings - > lSetChannels ; j + + ) {
SpcSetParam ( deviceno , SPC_AMP0 + 100 * j , ( int ) floor ( effective_settings - > sensitivity [ j ] * 1000 ) ) ; // +/- 5V input range
SpcSetParam ( deviceno , SPC_50OHM0 + 100 * j , ( ( effective_settings - > impedance [ j ] = = 50.0 ) ? 1 : 0 ) ) ; // 1 = 50 Ohm input impedance, 0 = 1MOhm input impedance
SpcSetParam ( deviceno , SPC_OFFS0 + 100 * j , effective_settings - > offset [ j ] ) ; // set offset to zero
}
SpcSetParam ( deviceno , SPC_CHENABLE , effective_settings - > qwSetChEnableMap . to_ulong ( ) ) ; // Enable channels for recording
int activated_channels ;
SpcGetParam ( deviceno , SPC_CHENABLE , & activated_channels ) ;
SpcSetParam ( deviceno , SPC_SAMPLERATE , ( int ) floor ( effective_settings - > samplefreq ) ) ; // Samplerate
// the MI4021 card doesn't accept all sampling frequency settings. check if the sampling rate is set correctly. if not, throw an exception
int setSamplingRate = 0 ;
SpcGetParam ( deviceno , SPC_SAMPLERATE , & setSamplingRate ) ;
if ( setSamplingRate ! = ( int ) floor ( effective_settings - > samplefreq ) ) {
char parameter_info [ 16 ] ;
snprintf ( parameter_info , sizeof ( parameter_info ) , " %d " , setSamplingRate ) ;
throw ADC_exception ( std : : string ( " DAC sampling rate not available. Try setting to: " ) + parameter_info ) ;
}
// decide for aquisition mode and start it
int16 nErr = ERR_OK ;
if ( sampleno < fifo_minimal_size ) {
# if SPC_DEBUG
fprintf ( stderr , " expecting % " SIZETPRINTFLETTER " samples in normal mode \n " , sampleno ) ;
# endif
SpcSetParam ( deviceno , SPC_MEMSIZE , sampleno ) ; // Memory size
// ----- start the board -----
nErr = SpcSetParam ( deviceno , SPC_COMMAND , SPC_START ) ; // start the board
} else {
# if SPC_DEBUG
fprintf ( stderr , " expecting % " SIZETPRINTFLETTER " samples in fifo mode \n " , sampleno ) ;
# endif
// todo: fifo should really write directly to recursive gated sampling structures
fifo_adc_data = ( short int * ) malloc ( sampleno * sizeof ( short int ) * 2 ) ;
if ( fifo_adc_data = = NULL ) {
throw SpectrumMI40xxSeries_error ( " could not allocate adc data memory for fifo recording " ) ;
}
// ToDo: do some magic calculations
fifobufferno = 16 ;
fifobufferlen = 1 < < 20 ;
# if SPC_DEBUG
fprintf ( stderr , " configuring for % " SIZETPRINTFLETTER " buffers, each of size % " SIZETPRINTFLETTER " \n " , fifobufferno , fifobufferlen ) ;
# endif
SpcSetParam ( deviceno , SPC_FIFO_BUFFERS , fifobufferno ) ;
SpcSetParam ( deviceno , SPC_FIFO_BUFLEN , fifobufferlen ) ;
// allocate FIFO buffers
fifobuffers . resize ( fifobufferno , ( short int * ) NULL ) ;
for ( size_t i = 0 ; i ! = fifobufferno ; + + i ) {
void * newbuffer ;
# if SPC_DEBUG
fprintf ( stderr , " allocating fifobuffer % " SIZETPRINTFLETTER " ... " , i ) ;
# endif
newbuffer = malloc ( fifobufferlen ) ;
if ( newbuffer = = NULL ) {
// free the buffers, if there is not enough memory
for ( size_t j = 0 ; j ! = i ; + + j ) free ( fifobuffers [ j ] ) ;
fifobuffers . clear ( ) ;
throw SpectrumMI40xxSeries_error ( " could not allocate buffers for fifo mode " ) ;
}
# if SPC_DEBUG
fprintf ( stderr , " and registering with ADC driver.... " ) ;
# endif
fifobuffers [ i ] = ( short int * ) newbuffer ;
// todo: check for errors
# ifndef _LINUX64
SpcSetParam ( deviceno , SPC_FIFO_BUFADR0 + i , ( int32 ) newbuffer ) ;
# else
// 64 bit Linux needs SetAdr function, 32 bit linux can also use this if driver build > 1093
SpcSetAdr ( deviceno , SPC_FIFO_BUFADR0 + i , newbuffer ) ;
# endif
# if SPC_DEBUG
fprintf ( stderr , " success. \n " ) ;
# endif
}
# if SPC_DEBUG
fprintf ( stderr , " starting fifo thread \n " ) ;
# endif
// to do: append a new state to overcome problems with fifo...
// need another thread, that collects the data
pthread_attr_init ( & timeout_pt_attrs ) ;
pthread_create ( & timeout_pt , & timeout_pt_attrs , SpectrumMI40xxSeries_TimeoutThread , ( void * ) this ) ;
}
// ----- driver error: request error and end program -----
if ( nErr ! = ERR_OK ) {
if ( effective_settings ! = NULL ) delete effective_settings ;
effective_settings = NULL ;
for ( std : : vector < short int * > : : iterator i = fifobuffers . begin ( ) ; i ! = fifobuffers . end ( ) ; + + i ) free ( * i ) ;
fifobuffers . clear ( ) ;
// create an error message
int32 lErrorCode , lErrorReg , lErrorValue ;
SpcGetParam ( deviceno , SPC_LASTERRORCODE , & lErrorCode ) ;
SpcGetParam ( deviceno , SPC_LASTERRORREG , & lErrorReg ) ;
SpcGetParam ( deviceno , SPC_LASTERRORVALUE , & lErrorValue ) ;
char error_message [ 256 ] ;
snprintf ( error_message , sizeof ( error_message ) , " Configuration error %d in register %d at value %d " , lErrorCode , lErrorReg , lErrorValue ) ;
throw SpectrumMI40xxSeries_error ( error_message ) ;
}
}
double SpectrumMI40xxSeries : : get_sample_clock_frequency ( ) const {
if ( effective_settings = = NULL | |
effective_settings - > samplefreq < = 0 | |
effective_settings - > data_structure = = NULL | |
effective_settings - > data_structure - > size ( ) = = 0 )
return 0 ;
return effective_settings - > samplefreq ;
}
int SpectrumMI40xxSeries : : TimeoutThread ( ) {
// now collect data
assert ( effective_settings ! = NULL ) ;
size_t sampleno = effective_settings - > data_structure - > size ( ) ;
size_t buff_number_expected = ( sampleno * 2 * sizeof ( short int ) + fifobufferlen - 1 ) / fifobufferlen ;
SpcSetParam ( deviceno , SPC_FIFO_BUFMAXCNT , buff_number_expected ) ;
size_t buff_number = 0 ;
short int * buff_pointer = fifo_adc_data ;
// start fifo aquisition
# if SPC_DEBUG
fprintf ( stderr , " SPC_FIFOSTART \n " ) ;
# endif
SpcSetParam ( deviceno , SPC_COMMAND , SPC_FIFOSTART ) ;
do {
// wait for the buffers
pthread_testcancel ( ) ;
# if SPC_DEBUG
fprintf ( stderr , " reading buffer no % " SIZETPRINTFLETTER " /% " SIZETPRINTFLETTER " \n " , buff_number + 1 , buff_number_expected ) ;
# endif
if ( buff_number + 1 = = buff_number_expected ) {
// the last one is special, copy only expected bytes
memcpy ( buff_pointer , fifobuffers [ buff_number % ( fifobuffers . size ( ) ) ] , sampleno * 2 * sizeof ( short int ) - fifobufferlen * buff_number ) ;
break ;
}
else
buff_pointer = ( short int * ) mempcpy ( buff_pointer , fifobuffers [ buff_number % ( fifobuffers . size ( ) ) ] , fifobufferlen ) ;
SpcSetParam ( deviceno , SPC_FIFO_BUFREADY , buff_number % ( fifobuffers . size ( ) ) ) ;
buff_number + + ;
int buff_available ;
SpcGetParam ( deviceno , SPC_FIFO_BUFCOUNT , & buff_available ) ;
if ( ( ( size_t ) buff_available ) > buff_number ) {
// get also the next buffer...
# if SPC_DEBUG
fprintf ( stderr , " read % " SIZETPRINTFLETTER " buffers, %d buffers gained by the hardware sofar \n " , buff_number , buff_available ) ;
# endif
continue ;
}
int adc_status ;
# if SPC_DEBUG
fprintf ( stderr , " SPC_STATUS \n " ) ;
# endif
SpcGetParam ( deviceno , SPC_STATUS , & adc_status ) ;
if ( adc_status = = SPC_READY ) {
// this must be a timeout!
//pthread_cancel(timeout_pt);
//pthread_join(timeout_pt,NULL);
//pthread_attr_destroy(&timeout_pt_attrs);
free ( fifo_adc_data ) ;
fifo_adc_data = NULL ;
2016-12-19 14:03:14 +00:00
throw SpectrumMI40xxSeries_error ( " timeout occured while collecting data " ) ;
2014-06-26 11:10:51 +00:00
return 0 ;
}
# if SPC_DEBUG
fprintf ( stderr , " waiting for next fifo buffer \n " ) ;
fprintf ( stderr , " SPC_FIFOWAIT \n " ) ;
# endif
SpcSetParam ( deviceno , SPC_COMMAND , SPC_FIFOWAIT ) ;
}
while ( buff_number < buff_number_expected ) ;
# if SPC_DEBUG
fprintf ( stderr , " SPC_STOP \n " ) ;
# endif
SpcSetParam ( deviceno , SPC_COMMAND , SPC_STOP ) ;
return 1 ;
}
short int * SpectrumMI40xxSeries : : split_adcdata_recursive ( short int * data , const DataManagementNode & structure , adc_results & result_splitted ) {
short nchannels = effective_settings - > lSetChannels ;
if ( structure . child = = NULL ) {
// simple case: do real work
// todo: Channel selection
short int * datachunk = ( short int * ) malloc ( sizeof ( short int ) * structure . n * nchannels ) ;
if ( datachunk = = NULL ) {
throw SpectrumMI40xxSeries_error ( " not enough memory to create results " ) ;
}
// todo: error checking
memcpy ( datachunk , data , sizeof ( short int ) * structure . n * nchannels ) ;
data + = structure . n * nchannels ;
adc_result * the_result = new adc_result ( 0 , structure . n , datachunk , effective_settings - > samplefreq , nchannels ) ;
result_splitted . push_back ( the_result ) ;
if ( structure . next ! = NULL )
data = split_adcdata_recursive ( data , * ( structure . next ) , result_splitted ) ;
}
else
for ( size_t i = 0 ; i < structure . n ; + + i ) {
data = split_adcdata_recursive ( data , * ( structure . child ) , result_splitted ) ;
}
return data ;
}
result * SpectrumMI40xxSeries : : get_samples ( double _timeout ) {
if ( core : : term_signal ! = 0 ) return NULL ;
size_t sampleno = ( effective_settings = = NULL | | effective_settings - > data_structure = = NULL ) ? 0 : effective_settings - > data_structure - > size ( ) ;
if ( sampleno = = 0 ) return new adc_result ( 1 , 0 , NULL ) ;
short nchannels = ( effective_settings = = NULL ) ? 0 : effective_settings - > lSetChannels ;
if ( nchannels = = 0 ) throw SpectrumMI40xxSeries_error ( " No channels specified " ) ;
// double timeout=_timeout;
# if SPC_DEBUG
fprintf ( stderr , " effective_settings in get_samples: %g \n " , effective_settings - > timeout ) ;
# endif
// allocate a lot of space
// todo: use GatedSampling buffers directly!
if ( fifobuffers . empty ( ) ) {
# if SPC_DEBUG
printf ( " ADC not in FIFO mode \n " ) ;
# endif
short int * adc_data = ( short int * ) malloc ( sampleno * sizeof ( short int ) * nchannels ) ;
if ( adc_data = = NULL ) {
for ( std : : vector < short int * > : : iterator i = fifobuffers . begin ( ) ; i ! = fifobuffers . end ( ) ; + + i ) free ( * i ) ;
fifobuffers . clear ( ) ;
throw SpectrumMI40xxSeries_error ( " could not allocate adc data memory " ) ;
}
// simple version: standard acquisition, wait and get...
# if SPC_DEBUG
fprintf ( stderr , " fetching % " SIZETPRINTFLETTER " samples in normal mode (timeout is %g) \n " , sampleno , effective_settings - > timeout ) ;
# endif
stopwatch adc_timer ;
adc_timer . start ( ) ;
int adc_status , i ;
double elapsed_time = 0 ;
/*
The gate - end signal can only be recognized at an eigth samples alignement .
The board can record up to 7 more samples , the timeout has to be allowed to be longer
*/
double post_gate_maxtime = ( 1e8 * 7.5 / effective_settings - > samplefreq ) / 1e8 ;
i = 0 ;
SpcGetParam ( deviceno , SPC_STATUS , & adc_status ) ;
/*
Sometimes the timeout is not enough , the reason could be that the timer
starts running before the actual start of the pulse program because the OS is not loading and starting
the pulseblaster immediatly . It is not possible to
synchronize the timers for now .
2016-12-19 14:03:14 +00:00
Thus , we add a generous 1 s to the timeout to be on the safe side .
2014-06-26 11:10:51 +00:00
*/
2016-12-19 14:03:14 +00:00
while ( core : : term_signal = = 0 & & adc_status ! = SPC_READY & & elapsed_time < = ( effective_settings - > timeout + post_gate_maxtime + 1 ) ) {
2014-06-26 11:10:51 +00:00
timespec sleeptime ;
sleeptime . tv_nsec = 10 * 1000 * 1000 ; // 10 ms
sleeptime . tv_sec = 0 ;
nanosleep ( & sleeptime , NULL ) ;
SpcGetParam ( deviceno , SPC_STATUS , & adc_status ) ;
elapsed_time = adc_timer . elapsed ( ) ;
# if SPC_DEBUG
fprintf ( stderr , " (nofifo) loop %i (adc_status, t, t_out, post_gate, core): %i %g %g %g %i \n " , i , adc_status , elapsed_time , effective_settings - > timeout , post_gate_maxtime , core : : term_signal ) ;
# endif
i + + ;
}
# if SPC_DEBUG
fprintf ( stderr , " (nofifo) loop stopped (adc_status, t, t_out, core): %i %g %g %i \n " , adc_status , elapsed_time , effective_settings - > timeout , core : : term_signal ) ;
# endif
/* card ready to transfer samples */
if ( adc_status ! = SPC_READY ) {
free ( adc_data ) ;
# if SPC_DEBUG
fprintf ( stderr , " ERROR: adc_status not ready (%i) \n " , adc_status ) ;
# endif
throw SpectrumMI40xxSeries_error ( " timeout occured while collecting data " ) ;
}
SpcSetParam ( deviceno , SPC_COMMAND , SPC_STOP ) ;
if ( core : : term_signal ! = 0 ) {
# if SPC_DEBUG
fprintf ( stderr , " received core::term_signal %i \n " , core : : term_signal ) ;
# endif
free ( adc_data ) ;
return NULL ;
}
# if defined __linux__
size_t data_length = SpcGetData ( deviceno , 0 , 0 , nchannels * sampleno , 2 , ( dataptr ) adc_data ) ;
# if SPC_DEBUG
fprintf ( stderr , " SpcGetData returned % " SIZETPRINTFLETTER " bytes, got % " SIZETPRINTFLETTER " out of % " SIZETPRINTFLETTER " expected samples \n " , data_length , data_length / sizeof ( short int ) / 2 , sampleno ) ;
# endif
if ( nchannels * sizeof ( short int ) * sampleno ! = data_length ) {
free ( adc_data ) ;
throw SpectrumMI40xxSeries_error ( " wrong amount of data from adc card " ) ;
}
// current position in adc data array
# elif defined __CYGWIN__
int16 read_result = SpcGetData ( deviceno , 0 , 0 , nchannels * sampleno , ( void * ) adc_data ) ;
# if SPC_DEBUG
fprintf ( stderr , " SpcGetData returned %d \n " , read_result ) ;
# endif
if ( read_result ! = 0 ) {
free ( adc_data ) ;
throw SpectrumMI40xxSeries_error ( " wrong amount of data from adc card " ) ;
}
# endif
short int * data_position = adc_data ;
// produced results
adc_results * the_results = new adc_results ( 0 ) ;
data_position = split_adcdata_recursive ( data_position , * ( effective_settings - > data_structure ) , * the_results ) ;
if ( data_position = = 0 | | ( size_t ) ( data_position - adc_data ) ! = ( sampleno * nchannels ) ) {
fprintf ( stderr , " something went wrong while spliting data \n " ) ;
}
free ( adc_data ) ;
delete effective_settings ;
effective_settings = NULL ;
return the_results ;
}
else {
# if SPC_DEBUG
printf ( " ADC in FIFO mode! \n " ) ;
fprintf ( stderr , " fetching % " SIZETPRINTFLETTER " samples in fifo mode (timeout is %g) \n " , sampleno , effective_settings - > timeout ) ;
# endif
// FIFO method
stopwatch timer ;
timer . start ( ) ;
do {
int32 lStatus ;
timespec sleeptime ;
sleeptime . tv_sec = 0 ;
sleeptime . tv_nsec = 100 * 1000 * 1000 ;
nanosleep ( & sleeptime , NULL ) ;
//pthread_testcancel();
SpcGetParam ( deviceno , SPC_STATUS , & lStatus ) ;
# if SPC_DEBUG
fprintf ( stderr , " while loop FIFO (lStatis, timer, effective_timeout): %i %g %g \n " , lStatus , timer . elapsed ( ) , effective_settings - > timeout ) ;
# endif
if ( lStatus = = SPC_READY ) break ;
} while ( timer . elapsed ( ) < effective_settings - > timeout ) ; //rosi _timeout
SpcSetParam ( deviceno , SPC_COMMAND , SPC_STOP ) ;
# if SPC_DEBUG
fprintf ( stderr , " waiting for read thread terminating \n " ) ;
# endif
/* wait for read thread */
pthread_cancel ( timeout_pt ) ;
pthread_join ( timeout_pt , NULL ) ;
pthread_attr_destroy ( & timeout_pt_attrs ) ;
/* free it's resources */
# if SPC_DEBUG
fprintf ( stderr , " freeing fifo data buffers \n " ) ;
# endif
for ( std : : vector < short int * > : : iterator i = fifobuffers . begin ( ) ; i ! = fifobuffers . end ( ) ; + + i ) free ( * i ) ;
fifobuffers . clear ( ) ;
adc_results * the_results = NULL ;
if ( fifo_adc_data ! = NULL ) {
// split data to (small) pieces
short int * data_position = fifo_adc_data ;
the_results = new adc_results ( 0 ) ;
data_position = split_adcdata_recursive ( data_position , * ( effective_settings - > data_structure ) , * the_results ) ;
if ( data_position = = 0 | | ( size_t ) ( data_position - fifo_adc_data ) ! = ( sampleno * nchannels ) ) {
fprintf ( stderr , " something went wrong while spliting data from fifo mode \n " ) ;
}
free ( fifo_adc_data ) ;
fifo_adc_data = NULL ;
}
else
fprintf ( stderr , " something went wrong while collecting data with fifo mode \n " ) ;
delete effective_settings ;
effective_settings = NULL ;
return the_results ;
}
}
/* check whether a channel mask is legal for this board */
bool SpectrumMI40xxSeries : : IsChannelMaskLegal ( int mask ) {
if ( ( cardType = = TYP_MI4020 | | cardType = = TYP_MI4030 ) & & mask ! = CHANNEL0 ) {
return false ;
} else if ( ( cardType = = TYP_MI4021 | | cardType = = TYP_MI4031 ) & & mask ! = ( CHANNEL0 | CHANNEL1 ) & & mask ! = CHANNEL0 ) {
return false ;
} else if ( ( cardType = = TYP_MI4022 | | cardType = = TYP_MI4032 ) & & mask ! = ( CHANNEL0 | CHANNEL1 | CHANNEL2 | CHANNEL3 ) & & mask ! = ( CHANNEL0 | CHANNEL1 ) & & mask ! = ( CHANNEL0 | CHANNEL2 ) & & mask ! = CHANNEL0 ) {
return false ;
}
return true ;
}
SpectrumMI40xxSeries : : ~ SpectrumMI40xxSeries ( ) {
SpcSetParam ( deviceno , SPC_COMMAND , SPC_STOP ) ; // stop the board
# if defined __linux__
close ( deviceno ) ;
# elif defined __CYGWIN__
FreeLibrary ( spectrum_driver_dll ) ;
# endif
}