/* * Copyright (c) 2007 - 2021 Joseph Gaeddert * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #ifndef __LIQUID_H__ #define __LIQUID_H__ #ifdef _MSC_VER #pragma warning( push ) #pragma warning( disable : 4003 ) #endif #ifdef __cplusplus extern "C" { # define LIQUID_USE_COMPLEX_H 0 #else # define LIQUID_USE_COMPLEX_H 1 #endif // __cplusplus // common headers #include // // Make sure the version and version number macros weren't defined by // some prevoiusly included header file. // #ifdef LIQUID_VERSION # undef LIQUID_VERSION #endif #ifdef LIQUID_VERSION_NUMBER # undef LIQUID_VERSION_NUMBER #endif // // Compile-time version numbers // // LIQUID_VERSION = "X.Y.Z" // LIQUID_VERSION_NUMBER = (X*1000000 + Y*1000 + Z) // #define LIQUID_VERSION "1.3.2" #define LIQUID_VERSION_NUMBER 1003002 // // Run-time library version numbers // extern const char liquid_version[]; const char * liquid_libversion(void); int liquid_libversion_number(void); // run-time library validation #define LIQUID_VALIDATE_LIBVERSION \ if (LIQUID_VERSION_NUMBER != liquid_libversion_number()) { \ fprintf(stderr,"%s:%u: ", __FILE__,__LINE__); \ fprintf(stderr,"error: invalid liquid runtime library\n"); \ exit(1); \ } \ // basic error types #define LIQUID_NUM_ERRORS 12 typedef enum { // everything ok LIQUID_OK=0, // internal logic error; this is a bug with liquid and should be reported immediately LIQUID_EINT, // invalid object, examples: // - destroy() method called on NULL pointer LIQUID_EIOBJ, // invalid parameter, or configuration; examples: // - setting bandwidth of a filter to a negative number // - setting FFT size to zero // - create a spectral periodogram object with window size greater than nfft LIQUID_EICONFIG, // input out of range; examples: // - try to take log of -1 // - try to create an FFT plan of size zero LIQUID_EIVAL, // invalid vector length or dimension; examples // - trying to refer to the 17th element of a 2 x 2 matrix // - trying to multiply two matrices of incompatible dimensions LIQUID_EIRANGE, // invalid mode; examples: // - try to create a modem of type 'LIQUID_MODEM_XXX' which does not exit LIQUID_EIMODE, // unsupported mode (e.g. LIQUID_FEC_CONV_V27 with 'libfec' not installed) LIQUID_EUMODE, // object has not been created or properly initialized // - try to run firfilt_crcf_execute(NULL, ...) // - try to modulate using an arbitrary modem without initializing the constellation LIQUID_ENOINIT, // not enough memory allocated for operation; examples: // - try to factor 100 = 2*2*5*5 but only give 3 spaces for factors LIQUID_EIMEM, // file input/output; examples: // - could not open a file for writing because of insufficient permissions // - could not open a file for reading because it does not exist // - try to read more data than a file has space for // - could not parse line in file (improper formatting) LIQUID_EIO, } liquid_error_code; // error descriptions extern const char * liquid_error_str[LIQUID_NUM_ERRORS]; const char * liquid_error_info(liquid_error_code _code); #define LIQUID_CONCAT(prefix, name) prefix ## name #define LIQUID_VALIDATE_INPUT /* * Compile-time complex data type definitions * * Default: use the C99 complex data type, otherwise * define complex type compatible with the C++ complex standard, * otherwise resort to defining binary compatible array. */ #if LIQUID_USE_COMPLEX_H==1 # include # define LIQUID_DEFINE_COMPLEX(R,C) typedef R _Complex C #elif defined _GLIBCXX_COMPLEX || defined _LIBCPP_COMPLEX # define LIQUID_DEFINE_COMPLEX(R,C) typedef std::complex C #else # define LIQUID_DEFINE_COMPLEX(R,C) typedef struct {R real; R imag;} C; #endif //# define LIQUID_DEFINE_COMPLEX(R,C) typedef R C[2] LIQUID_DEFINE_COMPLEX(float, liquid_float_complex); LIQUID_DEFINE_COMPLEX(double, liquid_double_complex); // // MODULE : agc (automatic gain control) // // available squelch modes typedef enum { LIQUID_AGC_SQUELCH_UNKNOWN=0, // unknown/unavailable squelch mode LIQUID_AGC_SQUELCH_ENABLED, // squelch enabled but signal not detected LIQUID_AGC_SQUELCH_RISE, // signal first hit/exceeded threshold LIQUID_AGC_SQUELCH_SIGNALHI, // signal level high (above threshold) LIQUID_AGC_SQUELCH_FALL, // signal first dropped below threshold LIQUID_AGC_SQUELCH_SIGNALLO, // signal level low (below threshold) LIQUID_AGC_SQUELCH_TIMEOUT, // signal level low (below threshold for a certain time) LIQUID_AGC_SQUELCH_DISABLED, // squelch not enabled } agc_squelch_mode; #define LIQUID_AGC_MANGLE_CRCF(name) LIQUID_CONCAT(agc_crcf, name) #define LIQUID_AGC_MANGLE_RRRF(name) LIQUID_CONCAT(agc_rrrf, name) // large macro // AGC : name-mangling macro // T : primitive data type // TC : input/output data type #define LIQUID_AGC_DEFINE_API(AGC,T,TC) \ \ /* Automatic gain control (agc) for level correction and signal */ \ /* detection */ \ typedef struct AGC(_s) * AGC(); \ \ /* Create automatic gain control object. */ \ AGC() AGC(_create)(void); \ \ /* Destroy object, freeing all internally-allocated memory. */ \ int AGC(_destroy)(AGC() _q); \ \ /* Print object properties to stdout, including received signal */ \ /* strength indication (RSSI), loop bandwidth, lock status, and squelch */ \ /* status. */ \ int AGC(_print)(AGC() _q); \ \ /* Reset internal state of agc object, including gain estimate, input */ \ /* signal level estimate, lock status, and squelch mode */ \ /* If the squelch mode is disabled, it stays disabled, but all enabled */ \ /* modes (e.g. LIQUID_AGC_SQUELCH_TIMEOUT) resets to just */ \ /* LIQUID_AGC_SQUELCH_ENABLED. */ \ int AGC(_reset)(AGC() _q); \ \ /* Execute automatic gain control on an single input sample */ \ /* _q : automatic gain control object */ \ /* _x : input sample */ \ /* _y : output sample */ \ int AGC(_execute)(AGC() _q, \ TC _x, \ TC * _y); \ \ /* Execute automatic gain control on block of samples pointed to by _x */ \ /* and store the result in the array of the same length _y. */ \ /* _q : automatic gain control object */ \ /* _x : input data array, [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _y : output data array, [size: _n x 1] */ \ int AGC(_execute_block)(AGC() _q, \ TC * _x, \ unsigned int _n, \ TC * _y); \ \ /* Lock agc object. When locked, the agc object still makes an estimate */ \ /* of the signal level, but the gain setting is fixed and does not */ \ /* change. */ \ /* This is useful for providing coarse input signal level correction */ \ /* and quickly detecting a packet burst but not distorting signals with */ \ /* amplitude variation due to modulation. */ \ int AGC(_lock)(AGC() _q); \ \ /* Unlock agc object, and allow amplitude correction to resume. */ \ int AGC(_unlock)(AGC() _q); \ \ /* Get lock state of agc object */ \ int AGC(_is_locked)(AGC() _q); \ \ /* Set loop filter bandwidth: attack/release time. */ \ /* _q : automatic gain control object */ \ /* _bt : bandwidth-time constant, _bt > 0 */ \ int AGC(_set_bandwidth)(AGC() _q, float _bt); \ \ /* Get the agc object's loop filter bandwidth. */ \ float AGC(_get_bandwidth)(AGC() _q); \ \ /* Get the input signal's estimated energy level, relative to unity. */ \ /* The result is a linear value. */ \ float AGC(_get_signal_level)(AGC() _q); \ \ /* Set the agc object's estimate of the input signal by specifying an */ \ /* explicit linear value. This is useful for initializing the agc */ \ /* object with a preliminary estimate of the signal level to help gain */ \ /* convergence. */ \ /* _q : automatic gain control object */ \ /* _x2 : signal level of input, _x2 > 0 */ \ int AGC(_set_signal_level)(AGC() _q, \ float _x2); \ \ /* Get the agc object's estimated received signal strength indication */ \ /* (RSSI) on the input signal. */ \ /* This is similar to getting the signal level (above), but returns the */ \ /* result in dB rather than on a linear scale. */ \ float AGC(_get_rssi)(AGC() _q); \ \ /* Set the agc object's estimated received signal strength indication */ \ /* (RSSI) on the input signal by specifying an explicit value in dB. */ \ /* _q : automatic gain control object */ \ /* _rssi : signal level of input [dB] */ \ int AGC(_set_rssi)(AGC() _q, float _rssi); \ \ /* Get the gain value currently being applied to the input signal */ \ /* (linear). */ \ float AGC(_get_gain)(AGC() _q); \ \ /* Set the agc object's internal gain by specifying an explicit linear */ \ /* value. */ \ /* _q : automatic gain control object */ \ /* _gain : gain to apply to input signal, _gain > 0 */ \ int AGC(_set_gain)(AGC() _q, \ float _gain); \ \ /* Get the ouput scaling applied to each sample (linear). */ \ float AGC(_get_scale)(AGC() _q); \ \ /* Set the agc object's output scaling (linear). Note that this does */ \ /* affect the response of the AGC. */ \ /* _q : automatic gain control object */ \ /* _gain : gain to apply to input signal, _gain > 0 */ \ int AGC(_set_scale)(AGC() _q, \ float _scale); \ \ /* Estimate signal level and initialize internal gain on an input */ \ /* array. */ \ /* _q : automatic gain control object */ \ /* _x : input data array, [size: _n x 1] */ \ /* _n : number of input, output samples */ \ int AGC(_init)(AGC() _q, \ TC * _x, \ unsigned int _n); \ \ /* Enable squelch mode. */ \ int AGC(_squelch_enable)(AGC() _q); \ \ /* Disable squelch mode. */ \ int AGC(_squelch_disable)(AGC() _q); \ \ /* Return flag indicating if squelch is enabled or not. */ \ int AGC(_squelch_is_enabled)(AGC() _q); \ \ /* Set threshold for enabling/disabling squelch. */ \ /* _q : automatic gain control object */ \ /* _thresh : threshold for enabling squelch [dB] */ \ int AGC(_squelch_set_threshold)(AGC() _q, \ T _thresh); \ \ /* Get squelch threshold (value in dB) */ \ T AGC(_squelch_get_threshold)(AGC() _q); \ \ /* Set timeout before enabling squelch. */ \ /* _q : automatic gain control object */ \ /* _timeout : timeout before enabling squelch [samples] */ \ int AGC(_squelch_set_timeout)(AGC() _q, \ unsigned int _timeout); \ \ /* Get squelch timeout (number of samples) */ \ unsigned int AGC(_squelch_get_timeout)(AGC() _q); \ \ /* Get squelch status (e.g. LIQUID_AGC_SQUELCH_TIMEOUT) */ \ int AGC(_squelch_get_status)(AGC() _q); \ // Define agc APIs LIQUID_AGC_DEFINE_API(LIQUID_AGC_MANGLE_CRCF, float, liquid_float_complex) LIQUID_AGC_DEFINE_API(LIQUID_AGC_MANGLE_RRRF, float, float) // // MODULE : audio // // CVSD: continuously variable slope delta typedef struct cvsd_s * cvsd; // create cvsd object // _num_bits : number of adjacent bits to observe (4 recommended) // _zeta : slope adjustment multiplier (1.5 recommended) // _alpha : pre-/post-emphasis filter coefficient (0.9 recommended) // NOTE: _alpha must be in [0,1] cvsd cvsd_create(unsigned int _num_bits, float _zeta, float _alpha); // destroy cvsd object int cvsd_destroy(cvsd _q); // print cvsd object parameters int cvsd_print(cvsd _q); // encode/decode single sample unsigned char cvsd_encode(cvsd _q, float _audio_sample); float cvsd_decode(cvsd _q, unsigned char _bit); // encode/decode 8 samples at a time int cvsd_encode8(cvsd _q, float * _audio, unsigned char * _data); int cvsd_decode8(cvsd _q, unsigned char _data, float * _audio); // // MODULE : buffer // // circular buffer #define LIQUID_CBUFFER_MANGLE_FLOAT(name) LIQUID_CONCAT(cbufferf, name) #define LIQUID_CBUFFER_MANGLE_CFLOAT(name) LIQUID_CONCAT(cbuffercf, name) // large macro // CBUFFER : name-mangling macro // T : data type #define LIQUID_CBUFFER_DEFINE_API(CBUFFER,T) \ \ /* Circular buffer object for storing and retrieving samples in a */ \ /* first-in/first-out (FIFO) manner using a minimal amount of memory */ \ typedef struct CBUFFER(_s) * CBUFFER(); \ \ /* Create circular buffer object of a particular maximum storage length */ \ /* _max_size : maximum buffer size, _max_size > 0 */ \ CBUFFER() CBUFFER(_create)(unsigned int _max_size); \ \ /* Create circular buffer object of a particular maximum storage size */ \ /* and specify the maximum number of elements that can be read at any */ \ /* any given time */ \ /* _max_size : maximum buffer size, _max_size > 0 */ \ /* _max_read : maximum size that will be read from buffer */ \ CBUFFER() CBUFFER(_create_max)(unsigned int _max_size, \ unsigned int _max_read); \ \ /* Destroy cbuffer object, freeing all internal memory */ \ int CBUFFER(_destroy)(CBUFFER() _q); \ \ /* Print cbuffer object properties to stdout */ \ int CBUFFER(_print)(CBUFFER() _q); \ \ /* Print cbuffer object properties and internal state */ \ int CBUFFER(_debug_print)(CBUFFER() _q); \ \ /* Clear internal buffer */ \ int CBUFFER(_reset)(CBUFFER() _q); \ \ /* Get the number of elements currently in the buffer */ \ unsigned int CBUFFER(_size)(CBUFFER() _q); \ \ /* Get the maximum number of elements the buffer can hold */ \ unsigned int CBUFFER(_max_size)(CBUFFER() _q); \ \ /* Get the maximum number of elements you may read at once */ \ unsigned int CBUFFER(_max_read)(CBUFFER() _q); \ \ /* Get the number of available slots (max_size - size) */ \ unsigned int CBUFFER(_space_available)(CBUFFER() _q); \ \ /* Return flag indicating if the buffer is empty or not */ \ int CBUFFER(_is_empty)(CBUFFER() _q); \ \ /* Return flag indicating if the buffer is full or not */ \ int CBUFFER(_is_full)(CBUFFER() _q); \ \ /* Write a single sample into the buffer */ \ /* _q : circular buffer object */ \ /* _v : input sample */ \ int CBUFFER(_push)(CBUFFER() _q, \ T _v); \ \ /* Write a block of samples to the buffer */ \ /* _q : circular buffer object */ \ /* _v : array of samples to write to buffer */ \ /* _n : number of samples to write */ \ int CBUFFER(_write)(CBUFFER() _q, \ T * _v, \ unsigned int _n); \ \ /* Remove and return a single element from the buffer by setting the */ \ /* value of the output sample pointed to by _v */ \ /* _q : circular buffer object */ \ /* _v : pointer to sample output */ \ int CBUFFER(_pop)(CBUFFER() _q, \ T * _v); \ \ /* Read buffer contents by returning a pointer to the linearized array; */ \ /* note that the returned pointer is only valid until another operation */ \ /* is performed on the circular buffer object */ \ /* _q : circular buffer object */ \ /* _num_requested : number of elements requested */ \ /* _v : output pointer */ \ /* _num_read : number of elements referenced by _v */ \ int CBUFFER(_read)(CBUFFER() _q, \ unsigned int _num_requested, \ T ** _v, \ unsigned int * _num_read); \ \ /* Release _n samples from the buffer */ \ /* _q : circular buffer object */ \ /* _n : number of elements to release */ \ int CBUFFER(_release)(CBUFFER() _q, \ unsigned int _n); \ // Define buffer APIs LIQUID_CBUFFER_DEFINE_API(LIQUID_CBUFFER_MANGLE_FLOAT, float) LIQUID_CBUFFER_DEFINE_API(LIQUID_CBUFFER_MANGLE_CFLOAT, liquid_float_complex) // Windowing functions #define LIQUID_WINDOW_MANGLE_FLOAT(name) LIQUID_CONCAT(windowf, name) #define LIQUID_WINDOW_MANGLE_CFLOAT(name) LIQUID_CONCAT(windowcf, name) // large macro // WINDOW : name-mangling macro // T : data type #define LIQUID_WINDOW_DEFINE_API(WINDOW,T) \ \ /* Sliding window first-in/first-out buffer with a fixed size */ \ typedef struct WINDOW(_s) * WINDOW(); \ \ /* Create window buffer object of a fixed length */ \ WINDOW() WINDOW(_create)(unsigned int _n); \ \ /* Recreate window buffer object with new length. */ \ /* This extends an existing window's size, similar to the standard C */ \ /* library's realloc() to n samples. */ \ /* If the size of the new window is larger than the old one, the newest */ \ /* values are retained at the beginning of the buffer and the oldest */ \ /* values are truncated. If the size of the new window is smaller than */ \ /* the old one, the oldest values are truncated. */ \ /* _q : old window object */ \ /* _n : new window length */ \ WINDOW() WINDOW(_recreate)(WINDOW() _q, unsigned int _n); \ \ /* Destroy window object, freeing all internally memory */ \ int WINDOW(_destroy)(WINDOW() _q); \ \ /* Print window object to stdout */ \ int WINDOW(_print)(WINDOW() _q); \ \ /* Print window object to stdout (with extra information) */ \ int WINDOW(_debug_print)(WINDOW() _q); \ \ /* Reset window object (initialize to zeros) */ \ int WINDOW(_reset)(WINDOW() _q); \ \ /* Read the contents of the window by returning a pointer to the */ \ /* aligned internal memory array. This method guarantees that the */ \ /* elements are linearized. This method should only be used for */ \ /* reading; writing values to the buffer has unspecified results. */ \ /* Note that the returned pointer is only valid until another operation */ \ /* is performed on the window buffer object */ \ /* _q : window object */ \ /* _v : output pointer (set to internal array) */ \ int WINDOW(_read)(WINDOW() _q, \ T ** _v); \ \ /* Index single element in buffer at a particular index */ \ /* This retrieves the \(i^{th}\) sample in the window, storing the */ \ /* output value in _v. */ \ /* This is equivalent to first invoking read() and then indexing on the */ \ /* resulting pointer; however the result is obtained much faster. */ \ /* Therefore setting the index to 0 returns the oldest value in the */ \ /* window. */ \ /* _q : window object */ \ /* _i : index of element to read */ \ /* _v : output value pointer */ \ int WINDOW(_index)(WINDOW() _q, \ unsigned int _i, \ T * _v); \ \ /* Shifts a single sample into the right side of the window, pushing */ \ /* the oldest (left-most) sample out of the end. Unlike stacks, the */ \ /* window object has no equivalent "pop" method, as values are retained */ \ /* in memory until they are overwritten. */ \ /* _q : window object */ \ /* _v : single input element */ \ int WINDOW(_push)(WINDOW() _q, \ T _v); \ \ /* Write array of elements onto window buffer */ \ /* Effectively, this is equivalent to pushing each sample one at a */ \ /* time, but executes much faster. */ \ /* _q : window object */ \ /* _v : input array of values to write */ \ /* _n : number of input values to write */ \ int WINDOW(_write)(WINDOW() _q, \ T * _v, \ unsigned int _n); \ // Define window APIs LIQUID_WINDOW_DEFINE_API(LIQUID_WINDOW_MANGLE_FLOAT, float) LIQUID_WINDOW_DEFINE_API(LIQUID_WINDOW_MANGLE_CFLOAT, liquid_float_complex) //LIQUID_WINDOW_DEFINE_API(LIQUID_WINDOW_MANGLE_UINT, unsigned int) // wdelay functions : windowed-delay // Implements an efficient z^-k delay with minimal memory #define LIQUID_WDELAY_MANGLE_FLOAT(name) LIQUID_CONCAT(wdelayf, name) #define LIQUID_WDELAY_MANGLE_CFLOAT(name) LIQUID_CONCAT(wdelaycf, name) //#define LIQUID_WDELAY_MANGLE_UINT(name) LIQUID_CONCAT(wdelayui, name) // large macro // WDELAY : name-mangling macro // T : data type #define LIQUID_WDELAY_DEFINE_API(WDELAY,T) \ \ /* Efficient digital delay line using a minimal amount of memory */ \ typedef struct WDELAY(_s) * WDELAY(); \ \ /* Create delay buffer object with a particular number of samples of */ \ /* delay */ \ /* _delay : number of samples of delay in the wdelay object */ \ WDELAY() WDELAY(_create)(unsigned int _delay); \ \ /* Re-create delay buffer object, adjusting the delay size, preserving */ \ /* the internal state of the object */ \ /* _q : old delay buffer object */ \ /* _delay : delay for new object */ \ WDELAY() WDELAY(_recreate)(WDELAY() _q, \ unsigned int _delay); \ \ /* Destroy delay buffer object, freeing internal memory */ \ int WDELAY(_destroy)(WDELAY() _q); \ \ /* Print delay buffer object's state to stdout */ \ int WDELAY(_print)(WDELAY() _q); \ \ /* Clear/reset state of object */ \ int WDELAY(_reset)(WDELAY() _q); \ \ /* Read delayed sample at the head of the buffer and store it to the */ \ /* output pointer */ \ /* _q : delay buffer object */ \ /* _v : value of delayed element */ \ int WDELAY(_read)(WDELAY() _q, \ T * _v); \ \ /* Push new sample into delay buffer object */ \ /* _q : delay buffer object */ \ /* _v : new value to be added to buffer */ \ int WDELAY(_push)(WDELAY() _q, \ T _v); \ // Define wdelay APIs LIQUID_WDELAY_DEFINE_API(LIQUID_WDELAY_MANGLE_FLOAT, float) LIQUID_WDELAY_DEFINE_API(LIQUID_WDELAY_MANGLE_CFLOAT, liquid_float_complex) //LIQUID_WDELAY_DEFINE_API(LIQUID_WDELAY_MANGLE_UINT, unsigned int) // // MODULE : channel // #define LIQUID_CHANNEL_MANGLE_CCCF(name) LIQUID_CONCAT(channel_cccf,name) // large macro // CHANNEL : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_CHANNEL_DEFINE_API(CHANNEL,TO,TC,TI) \ \ /* Channel emulation */ \ typedef struct CHANNEL(_s) * CHANNEL(); \ \ /* Create channel object with default parameters */ \ CHANNEL() CHANNEL(_create)(void); \ \ /* Destroy channel object, freeing all internal memory */ \ int CHANNEL(_destroy)(CHANNEL() _q); \ \ /* Print channel object internals to standard output */ \ int CHANNEL(_print)(CHANNEL() _q); \ \ /* Include additive white Gausss noise impairment */ \ /* _q : channel object */ \ /* _N0dB : noise floor power spectral density [dB] */ \ /* _SNRdB : signal-to-noise ratio [dB] */ \ int CHANNEL(_add_awgn)(CHANNEL() _q, \ float _N0dB, \ float _SNRdB); \ \ /* Include carrier offset impairment */ \ /* _q : channel object */ \ /* _frequency : carrier frequency offset [radians/sample] */ \ /* _phase : carrier phase offset [radians] */ \ int CHANNEL(_add_carrier_offset)(CHANNEL() _q, \ float _frequency, \ float _phase); \ \ /* Include multi-path channel impairment */ \ /* _q : channel object */ \ /* _h : channel coefficients (NULL for random) */ \ /* _h_len : number of channel coefficients */ \ int CHANNEL(_add_multipath)(CHANNEL() _q, \ TC * _h, \ unsigned int _h_len); \ \ /* Include slowly-varying shadowing impairment */ \ /* _q : channel object */ \ /* _sigma : standard deviation for log-normal shadowing */ \ /* _fd : Doppler frequency, 0 <= _fd < 0.5 */ \ int CHANNEL(_add_shadowing)(CHANNEL() _q, \ float _sigma, \ float _fd); \ \ /* Apply channel impairments on single input sample */ \ /* _q : channel object */ \ /* _x : input sample */ \ /* _y : pointer to output sample */ \ int CHANNEL(_execute)(CHANNEL() _q, \ TI _x, \ TO * _y); \ \ /* Apply channel impairments on block of samples */ \ /* _q : channel object */ \ /* _x : input array, [size: _n x 1] */ \ /* _n : input array, length */ \ /* _y : output array, [size: _n x 1] */ \ int CHANNEL(_execute_block)(CHANNEL() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_CHANNEL_DEFINE_API(LIQUID_CHANNEL_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // time-varying multi-path channel // #define LIQUID_TVMPCH_MANGLE_CCCF(name) LIQUID_CONCAT(tvmpch_cccf,name) // large macro // TVMPCH : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_TVMPCH_DEFINE_API(TVMPCH,TO,TC,TI) \ \ /* Time-varying multipath channel emulation */ \ typedef struct TVMPCH(_s) * TVMPCH(); \ \ /* Create time-varying multi-path channel emulator object, specifying */ \ /* the number of coefficients, the standard deviation of coefficients, */ \ /* and the coherence time. The larger the standard deviation, the more */ \ /* dramatic the frequency response of the channel. The shorter the */ \ /* coeherent time, the faster the channel effects. */ \ /* _n : number of coefficients, _n > 0 */ \ /* _std : standard deviation, _std >= 0 */ \ /* _tau : normalized coherence time, 0 < _tau < 1 */ \ TVMPCH() TVMPCH(_create)(unsigned int _n, \ float _std, \ float _tau); \ \ /* Destroy channel object, freeing all internal memory */ \ int TVMPCH(_destroy)(TVMPCH() _q); \ \ /* Reset object */ \ int TVMPCH(_reset)(TVMPCH() _q); \ \ /* Print channel object internals to standard output */ \ int TVMPCH(_print)(TVMPCH() _q); \ \ /* Push sample into emulator */ \ /* _q : channel object */ \ /* _x : input sample */ \ int TVMPCH(_push)(TVMPCH() _q, \ TI _x); \ \ /* Compute output sample */ \ /* _q : channel object */ \ /* _y : output sample */ \ int TVMPCH(_execute)(TVMPCH() _q, \ TO * _y); \ \ /* Apply channel impairments on a block of samples */ \ /* _q : channel object */ \ /* _x : input array, [size: _n x 1] */ \ /* _n : input array length */ \ /* _y : output array, [size: _n x 1] */ \ int TVMPCH(_execute_block)(TVMPCH() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_TVMPCH_DEFINE_API(LIQUID_TVMPCH_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // MODULE : dotprod (vector dot product) // #define LIQUID_DOTPROD_MANGLE_RRRF(name) LIQUID_CONCAT(dotprod_rrrf,name) #define LIQUID_DOTPROD_MANGLE_CCCF(name) LIQUID_CONCAT(dotprod_cccf,name) #define LIQUID_DOTPROD_MANGLE_CRCF(name) LIQUID_CONCAT(dotprod_crcf,name) // large macro // DOTPROD : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_DOTPROD_DEFINE_API(DOTPROD,TO,TC,TI) \ \ /* Vector dot product operation */ \ typedef struct DOTPROD(_s) * DOTPROD(); \ \ /* Run dot product without creating object. This is less efficient than */ \ /* creating the object as it is an unoptimized portable implementation */ \ /* that doesn't take advantage of processor extensions. It is meant to */ \ /* provide a baseline for performance comparison and a convenient way */ \ /* to invoke a dot product operation when fast operation is not */ \ /* necessary. */ \ /* _v : coefficients array [size: _n x 1] */ \ /* _x : input array [size: _n x 1] */ \ /* _n : dotprod length, _n > 0 */ \ /* _y : output sample pointer */ \ int DOTPROD(_run)( TC * _v, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* This provides the same unoptimized operation as the 'run()' method */ \ /* above, but with the loop unrolled by a factor of 4. It is marginally */ \ /* faster than 'run()' without unrolling the loop. */ \ /* _v : coefficients array [size: _n x 1] */ \ /* _x : input array [size: _n x 1] */ \ /* _n : dotprod length, _n > 0 */ \ /* _y : output sample pointer */ \ int DOTPROD(_run4)(TC * _v, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* Create vector dot product object */ \ /* _v : coefficients array [size: _n x 1] */ \ /* _n : dotprod length, _n > 0 */ \ DOTPROD() DOTPROD(_create)(TC * _v, \ unsigned int _n); \ \ /* Create vector dot product object with time-reversed coefficients */ \ /* _v : time-reversed coefficients array [size: _n x 1] */ \ /* _n : dotprod length, _n > 0 */ \ DOTPROD() DOTPROD(_create_rev)(TC * _v, \ unsigned int _n); \ \ /* Re-create dot product object of potentially a different length with */ \ /* different coefficients. If the length of the dot product object does */ \ /* not change, no memory reallocation is invoked. */ \ /* _q : old dotprod object */ \ /* _v : coefficients array [size: _n x 1] */ \ /* _n : dotprod length, _n > 0 */ \ DOTPROD() DOTPROD(_recreate)(DOTPROD() _q, \ TC * _v, \ unsigned int _n); \ \ /* Re-create dot product object of potentially a different length with */ \ /* different coefficients. If the length of the dot product object does */ \ /* not change, no memory reallocation is invoked. Filter coefficients */ \ /* are stored in reverse order. */ \ /* _q : old dotprod object */ \ /* _v : time-reversed coefficients array [size: _n x 1] */ \ /* _n : dotprod length, _n > 0 */ \ DOTPROD() DOTPROD(_recreate_rev)(DOTPROD() _q, \ TC * _v, \ unsigned int _n); \ \ /* Destroy dotprod object, freeing all internal memory */ \ int DOTPROD(_destroy)(DOTPROD() _q); \ \ /* Print dotprod object internals to standard output */ \ int DOTPROD(_print)(DOTPROD() _q); \ \ /* Execute dot product on an input array */ \ /* _q : dotprod object */ \ /* _x : input array [size: _n x 1] */ \ /* _y : output sample pointer */ \ int DOTPROD(_execute)(DOTPROD() _q, \ TI * _x, \ TO * _y); \ LIQUID_DOTPROD_DEFINE_API(LIQUID_DOTPROD_MANGLE_RRRF, float, float, float) LIQUID_DOTPROD_DEFINE_API(LIQUID_DOTPROD_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) LIQUID_DOTPROD_DEFINE_API(LIQUID_DOTPROD_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) // // sum squared methods // float liquid_sumsqf(float * _v, unsigned int _n); float liquid_sumsqcf(liquid_float_complex * _v, unsigned int _n); // // MODULE : equalization // // least mean-squares (LMS) #define LIQUID_EQLMS_MANGLE_RRRF(name) LIQUID_CONCAT(eqlms_rrrf,name) #define LIQUID_EQLMS_MANGLE_CCCF(name) LIQUID_CONCAT(eqlms_cccf,name) // large macro // EQLMS : name-mangling macro // T : data type #define LIQUID_EQLMS_DEFINE_API(EQLMS,T) \ \ /* Least mean-squares equalization object */ \ typedef struct EQLMS(_s) * EQLMS(); \ \ /* Create LMS EQ initialized with external coefficients */ \ /* _h : filter coefficients; set to NULL for {1,0,0...},[size: _n x 1] */ \ /* _n : filter length */ \ EQLMS() EQLMS(_create)(T * _h, \ unsigned int _n); \ \ /* Create LMS EQ initialized with square-root Nyquist prototype filter */ \ /* as initial set of coefficients. This is useful for applications */ \ /* where the baseline matched filter is a good starting point, but */ \ /* where equalization is needed to properly remove inter-symbol */ \ /* interference. */ \ /* The filter length is \(2 k m + 1\) */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _k : samples/symbol */ \ /* _m : filter delay (symbols) */ \ /* _beta : rolloff factor (0 < beta <= 1) */ \ /* _dt : fractional sample delay */ \ EQLMS() EQLMS(_create_rnyquist)(int _type, \ unsigned int _k, \ unsigned int _m, \ float _beta, \ float _dt); \ \ /* Create LMS EQ initialized with low-pass filter */ \ /* _n : filter length */ \ /* _fc : filter cut-off normalized to sample rate, 0 < _fc <= 0.5 */ \ EQLMS() EQLMS(_create_lowpass)(unsigned int _n, \ float _fc); \ \ /* Destroy equalizer object, freeing all internal memory */ \ int EQLMS(_destroy)(EQLMS() _q); \ \ /* Reset equalizer object, clearing internal state */ \ int EQLMS(_reset)(EQLMS() _q); \ \ /* Print equalizer internal state */ \ int EQLMS(_print)(EQLMS() _q); \ \ /* Get equalizer learning rate */ \ float EQLMS(_get_bw)(EQLMS() _q); \ \ /* Set equalizer learning rate */ \ /* _q : equalizer object */ \ /* _lambda : learning rate, _lambda > 0 */ \ int EQLMS(_set_bw)(EQLMS() _q, \ float _lambda); \ \ /* Push sample into equalizer internal buffer */ \ /* _q : equalizer object */ \ /* _x : input sample */ \ int EQLMS(_push)(EQLMS() _q, \ T _x); \ \ /* Push block of samples into internal buffer of equalizer object */ \ /* _q : equalizer object */ \ /* _x : input sample array, [size: _n x 1] */ \ /* _n : input sample array length */ \ int EQLMS(_push_block)(EQLMS() _q, \ T * _x, \ unsigned int _n); \ \ /* Execute internal dot product and return result */ \ /* _q : equalizer object */ \ /* _y : output sample */ \ int EQLMS(_execute)(EQLMS() _q, \ T * _y); \ \ /* Execute equalizer as decimator */ \ /* _q : equalizer object */ \ /* _x : input sample array [size: _k x 1] */ \ /* _y : output sample */ \ /* _k : down-sampling rate */ \ int EQLMS(_decim_execute)(EQLMS() _q, \ T * _x, \ T * _y, \ unsigned int _k); \ \ /* Execute equalizer with block of samples using constant */ \ /* modulus algorithm, operating on a decimation rate of _k */ \ /* samples. */ \ /* _q : equalizer object */ \ /* _k : down-sampling rate */ \ /* _x : input sample array [size: _n x 1] */ \ /* _n : input sample array length */ \ /* _y : output sample array [size: _n x 1] */ \ int EQLMS(_execute_block)(EQLMS() _q, \ unsigned int _k, \ T * _x, \ unsigned int _n, \ T * _y); \ \ /* Step through one cycle of equalizer training */ \ /* _q : equalizer object */ \ /* _d : desired output */ \ /* _d_hat : actual output */ \ int EQLMS(_step)(EQLMS() _q, \ T _d, \ T _d_hat); \ \ /* Step through one cycle of equalizer training (blind) */ \ /* _q : equalizer object */ \ /* _d_hat : actual output */ \ int EQLMS(_step_blind)(EQLMS() _q, \ T _d_hat); \ \ /* Get equalizer's internal coefficients */ \ /* _q : equalizer object */ \ /* _w : weights, [size: _p x 1] */ \ int EQLMS(_get_weights)(EQLMS() _q, \ T * _w); \ \ /* Train equalizer object on group of samples */ \ /* _q : equalizer object */ \ /* _w : input/output weights, [size: _p x 1] */ \ /* _x : received sample vector,[size: _n x 1] */ \ /* _d : desired output vector, [size: _n x 1] */ \ /* _n : input, output vector length */ \ int EQLMS(_train)(EQLMS() _q, \ T * _w, \ T * _x, \ T * _d, \ unsigned int _n); \ LIQUID_EQLMS_DEFINE_API(LIQUID_EQLMS_MANGLE_RRRF, float) LIQUID_EQLMS_DEFINE_API(LIQUID_EQLMS_MANGLE_CCCF, liquid_float_complex) // recursive least-squares (RLS) #define LIQUID_EQRLS_MANGLE_RRRF(name) LIQUID_CONCAT(eqrls_rrrf,name) #define LIQUID_EQRLS_MANGLE_CCCF(name) LIQUID_CONCAT(eqrls_cccf,name) // large macro // EQRLS : name-mangling macro // T : data type #define LIQUID_EQRLS_DEFINE_API(EQRLS,T) \ \ /* Recursive least mean-squares equalization object */ \ typedef struct EQRLS(_s) * EQRLS(); \ \ /* Create RLS EQ initialized with external coefficients */ \ /* _h : filter coefficients; set to NULL for {1,0,0...},[size: _n x 1] */ \ /* _n : filter length */ \ EQRLS() EQRLS(_create)(T * _h, \ unsigned int _n); \ \ /* Re-create EQ initialized with external coefficients */ \ /* _q : equalizer object */ \ /* _h : filter coefficients (NULL for {1,0,0...}), [size: _n x 1] */ \ /* _n : filter length */ \ EQRLS() EQRLS(_recreate)(EQRLS() _q, \ T * _h, \ unsigned int _n); \ \ /* Destroy equalizer object, freeing all internal memory */ \ int EQRLS(_destroy)(EQRLS() _q); \ \ /* Reset equalizer object, clearing internal state */ \ int EQRLS(_reset)(EQRLS() _q); \ \ /* Print equalizer internal state */ \ int EQRLS(_print)(EQRLS() _q); \ \ /* Get equalizer learning rate */ \ float EQRLS(_get_bw)(EQRLS() _q); \ \ /* Set equalizer learning rate */ \ /* _q : equalizer object */ \ /* _mu : learning rate, _mu > 0 */ \ int EQRLS(_set_bw)(EQRLS() _q, \ float _mu); \ \ /* Push sample into equalizer internal buffer */ \ /* _q : equalizer object */ \ /* _x : input sample */ \ int EQRLS(_push)(EQRLS() _q, T _x); \ \ /* Execute internal dot product and return result */ \ /* _q : equalizer object */ \ /* _y : output sample */ \ int EQRLS(_execute)(EQRLS() _q, T * _y); \ \ /* Step through one cycle of equalizer training */ \ /* _q : equalizer object */ \ /* _d : desired output */ \ /* _d_hat : actual output */ \ int EQRLS(_step)(EQRLS() _q, T _d, T _d_hat); \ \ /* Get equalizer's internal coefficients */ \ /* _q : equalizer object */ \ /* _w : weights, [size: _p x 1] */ \ int EQRLS(_get_weights)(EQRLS() _q, \ T * _w); \ \ /* Train equalizer object on group of samples */ \ /* _q : equalizer object */ \ /* _w : input/output weights, [size: _p x 1] */ \ /* _x : received sample vector,[size: _n x 1] */ \ /* _d : desired output vector, [size: _n x 1] */ \ /* _n : input, output vector length */ \ int EQRLS(_train)(EQRLS() _q, \ T * _w, \ T * _x, \ T * _d, \ unsigned int _n); \ LIQUID_EQRLS_DEFINE_API(LIQUID_EQRLS_MANGLE_RRRF, float) LIQUID_EQRLS_DEFINE_API(LIQUID_EQRLS_MANGLE_CCCF, liquid_float_complex) // // MODULE : fec (forward error-correction) // // soft bit values #define LIQUID_SOFTBIT_0 (0) #define LIQUID_SOFTBIT_1 (255) #define LIQUID_SOFTBIT_ERASURE (127) // available CRC schemes #define LIQUID_CRC_NUM_SCHEMES 7 typedef enum { LIQUID_CRC_UNKNOWN=0, // unknown/unavailable CRC scheme LIQUID_CRC_NONE, // no error-detection LIQUID_CRC_CHECKSUM, // 8-bit checksum LIQUID_CRC_8, // 8-bit CRC LIQUID_CRC_16, // 16-bit CRC LIQUID_CRC_24, // 24-bit CRC LIQUID_CRC_32 // 32-bit CRC } crc_scheme; // pretty names for crc schemes extern const char * crc_scheme_str[LIQUID_CRC_NUM_SCHEMES][2]; // Print compact list of existing and available CRC schemes void liquid_print_crc_schemes(); // returns crc_scheme based on input string crc_scheme liquid_getopt_str2crc(const char * _str); // get length of CRC (bytes) unsigned int crc_get_length(crc_scheme _scheme); // generate error-detection key // _scheme : error-detection scheme // _msg : input data message, [size: _n x 1] // _n : input data message size unsigned int crc_generate_key(crc_scheme _scheme, unsigned char * _msg, unsigned int _n); // generate error-detection key and append to end of message // _scheme : error-detection scheme (resulting in 'p' bytes) // _msg : input data message, [size: _n+p x 1] // _n : input data message size (excluding key at end) int crc_append_key(crc_scheme _scheme, unsigned char * _msg, unsigned int _n); // validate message using error-detection key // _scheme : error-detection scheme // _msg : input data message, [size: _n x 1] // _n : input data message size // _key : error-detection key int crc_validate_message(crc_scheme _scheme, unsigned char * _msg, unsigned int _n, unsigned int _key); // check message with key appended to end of array // _scheme : error-detection scheme (resulting in 'p' bytes) // _msg : input data message, [size: _n+p x 1] // _n : input data message size (excluding key at end) int crc_check_key(crc_scheme _scheme, unsigned char * _msg, unsigned int _n); // get size of key (bytes) unsigned int crc_sizeof_key(crc_scheme _scheme); // available FEC schemes #define LIQUID_FEC_NUM_SCHEMES 28 typedef enum { LIQUID_FEC_UNKNOWN=0, // unknown/unsupported scheme LIQUID_FEC_NONE, // no error-correction LIQUID_FEC_REP3, // simple repeat code, r1/3 LIQUID_FEC_REP5, // simple repeat code, r1/5 LIQUID_FEC_HAMMING74, // Hamming (7,4) block code, r1/2 (really 4/7) LIQUID_FEC_HAMMING84, // Hamming (7,4) with extra parity bit, r1/2 LIQUID_FEC_HAMMING128, // Hamming (12,8) block code, r2/3 LIQUID_FEC_GOLAY2412, // Golay (24,12) block code, r1/2 LIQUID_FEC_SECDED2216, // SEC-DED (22,16) block code, r8/11 LIQUID_FEC_SECDED3932, // SEC-DED (39,32) block code LIQUID_FEC_SECDED7264, // SEC-DED (72,64) block code, r8/9 // codecs not defined internally (see http://www.ka9q.net/code/fec/) LIQUID_FEC_CONV_V27, // r1/2, K=7, dfree=10 LIQUID_FEC_CONV_V29, // r1/2, K=9, dfree=12 LIQUID_FEC_CONV_V39, // r1/3, K=9, dfree=18 LIQUID_FEC_CONV_V615, // r1/6, K=15, dfree<=57 (Heller 1968) // punctured (perforated) codes LIQUID_FEC_CONV_V27P23, // r2/3, K=7, dfree=6 LIQUID_FEC_CONV_V27P34, // r3/4, K=7, dfree=5 LIQUID_FEC_CONV_V27P45, // r4/5, K=7, dfree=4 LIQUID_FEC_CONV_V27P56, // r5/6, K=7, dfree=4 LIQUID_FEC_CONV_V27P67, // r6/7, K=7, dfree=3 LIQUID_FEC_CONV_V27P78, // r7/8, K=7, dfree=3 LIQUID_FEC_CONV_V29P23, // r2/3, K=9, dfree=7 LIQUID_FEC_CONV_V29P34, // r3/4, K=9, dfree=6 LIQUID_FEC_CONV_V29P45, // r4/5, K=9, dfree=5 LIQUID_FEC_CONV_V29P56, // r5/6, K=9, dfree=5 LIQUID_FEC_CONV_V29P67, // r6/7, K=9, dfree=4 LIQUID_FEC_CONV_V29P78, // r7/8, K=9, dfree=4 // Reed-Solomon codes LIQUID_FEC_RS_M8 // m=8, n=255, k=223 } fec_scheme; // pretty names for fec schemes extern const char * fec_scheme_str[LIQUID_FEC_NUM_SCHEMES][2]; // Print compact list of existing and available FEC schemes void liquid_print_fec_schemes(); // returns fec_scheme based on input string fec_scheme liquid_getopt_str2fec(const char * _str); // fec object (pointer to fec structure) typedef struct fec_s * fec; // return the encoded message length using a particular error- // correction scheme (object-independent method) // _scheme : forward error-correction scheme // _msg_len : raw, uncoded message length unsigned int fec_get_enc_msg_length(fec_scheme _scheme, unsigned int _msg_len); // get the theoretical rate of a particular forward error- // correction scheme (object-independent method) float fec_get_rate(fec_scheme _scheme); // create a fec object of a particular scheme // _scheme : error-correction scheme // _opts : (ignored) fec fec_create(fec_scheme _scheme, void *_opts); // recreate fec object // _q : old fec object // _scheme : new error-correction scheme // _opts : (ignored) fec fec_recreate(fec _q, fec_scheme _scheme, void *_opts); // destroy fec object int fec_destroy(fec _q); // print fec object internals int fec_print(fec _q); // encode a block of data using a fec scheme // _q : fec object // _dec_msg_len : decoded message length // _msg_dec : decoded message // _msg_enc : encoded message int fec_encode(fec _q, unsigned int _dec_msg_len, unsigned char * _msg_dec, unsigned char * _msg_enc); // decode a block of data using a fec scheme // _q : fec object // _dec_msg_len : decoded message length // _msg_enc : encoded message // _msg_dec : decoded message int fec_decode(fec _q, unsigned int _dec_msg_len, unsigned char * _msg_enc, unsigned char * _msg_dec); // decode a block of data using a fec scheme (soft decision) // _q : fec object // _dec_msg_len : decoded message length // _msg_enc : encoded message (soft bits) // _msg_dec : decoded message int fec_decode_soft(fec _q, unsigned int _dec_msg_len, unsigned char * _msg_enc, unsigned char * _msg_dec); // // Packetizer // // computes the number of encoded bytes after packetizing // // _n : number of uncoded input bytes // _crc : error-detecting scheme // _fec0 : inner forward error-correction code // _fec1 : outer forward error-correction code unsigned int packetizer_compute_enc_msg_len(unsigned int _n, int _crc, int _fec0, int _fec1); // computes the number of decoded bytes before packetizing // // _k : number of encoded bytes // _crc : error-detecting scheme // _fec0 : inner forward error-correction code // _fec1 : outer forward error-correction code unsigned int packetizer_compute_dec_msg_len(unsigned int _k, int _crc, int _fec0, int _fec1); typedef struct packetizer_s * packetizer; // create packetizer object // // _n : number of uncoded input bytes // _crc : error-detecting scheme // _fec0 : inner forward error-correction code // _fec1 : outer forward error-correction code packetizer packetizer_create(unsigned int _dec_msg_len, int _crc, int _fec0, int _fec1); // re-create packetizer object // // _p : initialz packetizer object // _n : number of uncoded input bytes // _crc : error-detecting scheme // _fec0 : inner forward error-correction code // _fec1 : outer forward error-correction code packetizer packetizer_recreate(packetizer _p, unsigned int _dec_msg_len, int _crc, int _fec0, int _fec1); // destroy packetizer object void packetizer_destroy(packetizer _p); // print packetizer object internals void packetizer_print(packetizer _p); // access methods unsigned int packetizer_get_dec_msg_len(packetizer _p); unsigned int packetizer_get_enc_msg_len(packetizer _p); crc_scheme packetizer_get_crc (packetizer _p); fec_scheme packetizer_get_fec0 (packetizer _p); fec_scheme packetizer_get_fec1 (packetizer _p); // Execute the packetizer on an input message // // _p : packetizer object // _msg : input message (uncoded bytes) // _pkt : encoded output message void packetizer_encode(packetizer _p, const unsigned char * _msg, unsigned char * _pkt); // Execute the packetizer to decode an input message, return validity // check of resulting data // // _p : packetizer object // _pkt : input message (coded bytes) // _msg : decoded output message int packetizer_decode(packetizer _p, const unsigned char * _pkt, unsigned char * _msg); // Execute the packetizer to decode an input message, return validity // check of resulting data // // _p : packetizer object // _pkt : input message (coded soft bits) // _msg : decoded output message int packetizer_decode_soft(packetizer _p, const unsigned char * _pkt, unsigned char * _msg); // // interleaver // typedef struct interleaver_s * interleaver; // create interleaver // _n : number of bytes interleaver interleaver_create(unsigned int _n); // destroy interleaver object void interleaver_destroy(interleaver _q); // print interleaver object internals void interleaver_print(interleaver _q); // set depth (number of internal iterations) // _q : interleaver object // _depth : depth void interleaver_set_depth(interleaver _q, unsigned int _depth); // execute forward interleaver (encoder) // _q : interleaver object // _msg_dec : decoded (un-interleaved) message // _msg_enc : encoded (interleaved) message void interleaver_encode(interleaver _q, unsigned char * _msg_dec, unsigned char * _msg_enc); // execute forward interleaver (encoder) on soft bits // _q : interleaver object // _msg_dec : decoded (un-interleaved) message // _msg_enc : encoded (interleaved) message void interleaver_encode_soft(interleaver _q, unsigned char * _msg_dec, unsigned char * _msg_enc); // execute reverse interleaver (decoder) // _q : interleaver object // _msg_enc : encoded (interleaved) message // _msg_dec : decoded (un-interleaved) message void interleaver_decode(interleaver _q, unsigned char * _msg_enc, unsigned char * _msg_dec); // execute reverse interleaver (decoder) on soft bits // _q : interleaver object // _msg_enc : encoded (interleaved) message // _msg_dec : decoded (un-interleaved) message void interleaver_decode_soft(interleaver _q, unsigned char * _msg_enc, unsigned char * _msg_dec); // // MODULE : fft (fast Fourier transform) // // type of transform typedef enum { LIQUID_FFT_UNKNOWN = 0, // unknown transform type // regular complex one-dimensional transforms LIQUID_FFT_FORWARD = +1, // complex one-dimensional FFT LIQUID_FFT_BACKWARD = -1, // complex one-dimensional inverse FFT // discrete cosine transforms LIQUID_FFT_REDFT00 = 10, // real one-dimensional DCT-I LIQUID_FFT_REDFT10 = 11, // real one-dimensional DCT-II LIQUID_FFT_REDFT01 = 12, // real one-dimensional DCT-III LIQUID_FFT_REDFT11 = 13, // real one-dimensional DCT-IV // discrete sine transforms LIQUID_FFT_RODFT00 = 20, // real one-dimensional DST-I LIQUID_FFT_RODFT10 = 21, // real one-dimensional DST-II LIQUID_FFT_RODFT01 = 22, // real one-dimensional DST-III LIQUID_FFT_RODFT11 = 23, // real one-dimensional DST-IV // modified discrete cosine transform LIQUID_FFT_MDCT = 30, // MDCT LIQUID_FFT_IMDCT = 31, // IMDCT } liquid_fft_type; #define LIQUID_FFT_MANGLE_FLOAT(name) LIQUID_CONCAT(fft,name) // Macro : FFT // FFT : name-mangling macro // T : primitive data type // TC : primitive data type (complex) #define LIQUID_FFT_DEFINE_API(FFT,T,TC) \ \ /* Fast Fourier Transform (FFT) and inverse (plan) object */ \ typedef struct FFT(plan_s) * FFT(plan); \ \ /* Create regular complex one-dimensional transform */ \ /* _n : transform size */ \ /* _x : pointer to input array [size: _n x 1] */ \ /* _y : pointer to output array [size: _n x 1] */ \ /* _dir : direction (e.g. LIQUID_FFT_FORWARD) */ \ /* _flags : options, optimization */ \ FFT(plan) FFT(_create_plan)(unsigned int _n, \ TC * _x, \ TC * _y, \ int _dir, \ int _flags); \ \ /* Create real-to-real one-dimensional transform */ \ /* _n : transform size */ \ /* _x : pointer to input array [size: _n x 1] */ \ /* _y : pointer to output array [size: _n x 1] */ \ /* _type : transform type (e.g. LIQUID_FFT_REDFT00) */ \ /* _flags : options, optimization */ \ FFT(plan) FFT(_create_plan_r2r_1d)(unsigned int _n, \ T * _x, \ T * _y, \ int _type, \ int _flags); \ \ /* Destroy transform and free all internally-allocated memory */ \ int FFT(_destroy_plan)(FFT(plan) _p); \ \ /* Print transform plan and internal strategy to stdout. This includes */ \ /* information on the strategy for computing large transforms with many */ \ /* prime factors or with large prime factors. */ \ int FFT(_print_plan)(FFT(plan) _p); \ \ /* Run the transform */ \ int FFT(_execute)(FFT(plan) _p); \ \ /* Perform n-point FFT allocating plan internally */ \ /* _nfft : fft size */ \ /* _x : input array [size: _nfft x 1] */ \ /* _y : output array [size: _nfft x 1] */ \ /* _dir : fft direction: LIQUID_FFT_{FORWARD,BACKWARD} */ \ /* _flags : fft flags */ \ int FFT(_run)(unsigned int _n, \ TC * _x, \ TC * _y, \ int _dir, \ int _flags); \ \ /* Perform n-point real one-dimensional FFT allocating plan internally */ \ /* _nfft : fft size */ \ /* _x : input array [size: _nfft x 1] */ \ /* _y : output array [size: _nfft x 1] */ \ /* _type : fft type, e.g. LIQUID_FFT_REDFT10 */ \ /* _flags : fft flags */ \ int FFT(_r2r_1d_run)(unsigned int _n, \ T * _x, \ T * _y, \ int _type, \ int _flags); \ \ /* Perform _n-point fft shift */ \ /* _x : input array [size: _n x 1] */ \ /* _n : input array size */ \ int FFT(_shift)(TC * _x, \ unsigned int _n); \ LIQUID_FFT_DEFINE_API(LIQUID_FFT_MANGLE_FLOAT,float,liquid_float_complex) // antiquated fft methods // FFT(plan) FFT(_create_plan_mdct)(unsigned int _n, // T * _x, // T * _y, // int _kind, // int _flags); // // spectral periodogram // #define LIQUID_SPGRAM_MANGLE_CFLOAT(name) LIQUID_CONCAT(spgramcf,name) #define LIQUID_SPGRAM_MANGLE_FLOAT(name) LIQUID_CONCAT(spgramf, name) #define LIQUID_SPGRAM_PSD_MIN (1e-12) // Macro : SPGRAM // SPGRAM : name-mangling macro // T : primitive data type // TC : primitive data type (complex) // TI : primitive data type (input) #define LIQUID_SPGRAM_DEFINE_API(SPGRAM,T,TC,TI) \ \ /* Spectral periodogram object for computing power spectral density */ \ /* estimates of various signals */ \ typedef struct SPGRAM(_s) * SPGRAM(); \ \ /* Create spgram object, fully defined */ \ /* _nfft : transform (FFT) size, _nfft >= 2 */ \ /* _wtype : window type, e.g. LIQUID_WINDOW_HAMMING */ \ /* _window_len : window length, 1 <= _window_len <= _nfft */ \ /* _delay : delay between transforms, _delay > 0 */ \ SPGRAM() SPGRAM(_create)(unsigned int _nfft, \ int _wtype, \ unsigned int _window_len, \ unsigned int _delay); \ \ /* Create default spgram object of a particular transform size using */ \ /* the Kaiser-Bessel window (LIQUID_WINDOW_KAISER), a window length */ \ /* equal to _nfft/2, and a delay of _nfft/4 */ \ /* _nfft : FFT size, _nfft >= 2 */ \ SPGRAM() SPGRAM(_create_default)(unsigned int _nfft); \ \ /* Destroy spgram object, freeing all internally-allocated memory */ \ int SPGRAM(_destroy)(SPGRAM() _q); \ \ /* Clears the internal state of the object, but not the internal buffer */ \ int SPGRAM(_clear)(SPGRAM() _q); \ \ /* Reset the object to its original state completely. This effectively */ \ /* executes the clear() method and then resets the internal buffer */ \ int SPGRAM(_reset)(SPGRAM() _q); \ \ /* Print internal state of the object to stdout */ \ int SPGRAM(_print)(SPGRAM() _q); \ \ /* Set the filter bandwidth for accumulating independent transform */ \ /* squared magnitude outputs. */ \ /* This is used to compute a running time-average power spectral */ \ /* density output. */ \ /* The value of _alpha determines how the power spectral estimate is */ \ /* accumulated across transforms and can range from 0 to 1 with a */ \ /* special case of -1 to accumulate infinitely. */ \ /* Setting _alpha to 0 minimizes the bandwidth and the PSD estimate */ \ /* will never update. */ \ /* Setting _alpha to 1 forces the object to always use the most recent */ \ /* spectral estimate. */ \ /* Setting _alpha to -1 is a special case to enable infinite spectral */ \ /* accumulation. */ \ /* _q : spectral periodogram object */ \ /* _alpha : forgetting factor, set to -1 for infinite, 0<=_alpha<=1 */ \ int SPGRAM(_set_alpha)(SPGRAM() _q, \ float _alpha); \ \ /* Get the filter bandwidth for accumulating independent transform */ \ /* squared magnitude outputs. */ \ float SPGRAM(_get_alpha)(SPGRAM() _q); \ \ /* Set the center frequency of the received signal. */ \ /* This is for display purposes only when generating the output image. */ \ /* _q : spectral periodogram object */ \ /* _freq : center frequency [Hz] */ \ int SPGRAM(_set_freq)(SPGRAM() _q, \ float _freq); \ \ /* Set the sample rate (frequency) of the received signal. */ \ /* This is for display purposes only when generating the output image. */ \ /* _q : spectral periodogram object */ \ /* _rate : sample rate [Hz] */ \ int SPGRAM(_set_rate)(SPGRAM() _q, \ float _rate); \ \ /* Get transform (FFT) size */ \ unsigned int SPGRAM(_get_nfft)(SPGRAM() _q); \ \ /* Get window length */ \ unsigned int SPGRAM(_get_window_len)(SPGRAM() _q); \ \ /* Get delay between transforms */ \ unsigned int SPGRAM(_get_delay)(SPGRAM() _q); \ \ /* Get window type used for spectral estimation */ \ int SPGRAM(_get_wtype)(SPGRAM() _q); \ \ /* Get number of samples processed since reset */ \ unsigned long long int SPGRAM(_get_num_samples)(SPGRAM() _q); \ \ /* Get number of samples processed since object was created */ \ unsigned long long int SPGRAM(_get_num_samples_total)(SPGRAM() _q); \ \ /* Get number of transforms processed since reset */ \ unsigned long long int SPGRAM(_get_num_transforms)(SPGRAM() _q); \ \ /* Get number of transforms processed since object was created */ \ unsigned long long int SPGRAM(_get_num_transforms_total)(SPGRAM() _q); \ \ /* Push a single sample into the object, executing internal transform */ \ /* as necessary. */ \ /* _q : spgram object */ \ /* _x : input sample */ \ int SPGRAM(_push)(SPGRAM() _q, \ TI _x); \ \ /* Write a block of samples to the object, executing internal */ \ /* transform as necessary. */ \ /* _q : spgram object */ \ /* _x : input buffer [size: _n x 1] */ \ /* _n : input buffer length */ \ int SPGRAM(_write)(SPGRAM() _q, \ TI * _x, \ unsigned int _n); \ \ /* Compute spectral periodogram output (fft-shifted values, linear) */ \ /* from current buffer contents */ \ /* _q : spgram object */ \ /* _X : output spectrum (linear), [size: _nfft x 1] */ \ int SPGRAM(_get_psd_mag)(SPGRAM() _q, \ T * _X); \ \ /* Compute spectral periodogram output (fft-shifted values in dB) from */ \ /* current buffer contents */ \ /* _q : spgram object */ \ /* _X : output spectrum (dB), [size: _nfft x 1] */ \ int SPGRAM(_get_psd)(SPGRAM() _q, \ T * _X); \ \ /* Export stand-alone gnuplot file for plotting output spectrum, */ \ /* returning 0 on sucess, anything other than 0 for failure */ \ /* _q : spgram object */ \ /* _filename : input buffer [size: _n x 1] */ \ int SPGRAM(_export_gnuplot)(SPGRAM() _q, \ const char * _filename); \ \ /* Estimate spectrum on input signal (create temporary object for */ \ /* convenience */ \ /* _nfft : FFT size */ \ /* _x : input signal [size: _n x 1] */ \ /* _n : input signal length */ \ /* _psd : output spectrum, [size: _nfft x 1] */ \ int SPGRAM(_estimate_psd)(unsigned int _nfft, \ TI * _x, \ unsigned int _n, \ T * _psd); \ LIQUID_SPGRAM_DEFINE_API(LIQUID_SPGRAM_MANGLE_CFLOAT, float, liquid_float_complex, liquid_float_complex) LIQUID_SPGRAM_DEFINE_API(LIQUID_SPGRAM_MANGLE_FLOAT, float, liquid_float_complex, float) // // asgram : ascii spectral periodogram // #define LIQUID_ASGRAM_MANGLE_CFLOAT(name) LIQUID_CONCAT(asgramcf,name) #define LIQUID_ASGRAM_MANGLE_FLOAT(name) LIQUID_CONCAT(asgramf, name) // Macro : ASGRAM // ASGRAM : name-mangling macro // T : primitive data type // TC : primitive data type (complex) // TI : primitive data type (input) #define LIQUID_ASGRAM_DEFINE_API(ASGRAM,T,TC,TI) \ \ /* ASCII spectral periodogram for computing and displaying an estimate */ \ /* of a signal's power spectrum with ASCII characters */ \ typedef struct ASGRAM(_s) * ASGRAM(); \ \ /* Create asgram object with size _nfft */ \ /* _nfft : size of FFT taken for each transform (character width) */ \ ASGRAM() ASGRAM(_create)(unsigned int _nfft); \ \ /* Destroy asgram object, freeing all internally-allocated memory */ \ int ASGRAM(_destroy)(ASGRAM() _q); \ \ /* Reset the internal state of the asgram object */ \ int ASGRAM(_reset)(ASGRAM() _q); \ \ /* Set the scale and offset for spectrogram in terms of dB for display */ \ /* purposes */ \ /* _q : asgram object */ \ /* _ref : signal reference level [dB] */ \ /* _div : signal division [dB] */ \ int ASGRAM(_set_scale)(ASGRAM() _q, \ float _ref, \ float _div); \ \ /* Set the display's 10 characters for output string starting from the */ \ /* weakest and ending with the strongest */ \ /* _q : asgram object */ \ /* _ascii : 10-character display, default: " .,-+*&NM#" */ \ int ASGRAM(_set_display)(ASGRAM() _q, \ const char * _ascii); \ \ /* Push a single sample into the asgram object, executing internal */ \ /* transform as necessary. */ \ /* _q : asgram object */ \ /* _x : input sample */ \ int ASGRAM(_push)(ASGRAM() _q, \ TI _x); \ \ /* Write a block of samples to the asgram object, executing internal */ \ /* transforms as necessary. */ \ /* _q : asgram object */ \ /* _x : input buffer [size: _n x 1] */ \ /* _n : input buffer length */ \ int ASGRAM(_write)(ASGRAM() _q, \ TI * _x, \ unsigned int _n); \ \ /* Compute spectral periodogram output from current buffer contents */ \ /* and return the ascii character string to display along with the peak */ \ /* value and its frequency location */ \ /* _q : asgram object */ \ /* _ascii : output ASCII string [size: _nfft x 1] */ \ /* _peakval : peak power spectral density value [dB] */ \ /* _peakfreq : peak power spectral density frequency */ \ int ASGRAM(_execute)(ASGRAM() _q, \ char * _ascii, \ float * _peakval, \ float * _peakfreq); \ \ /* Compute spectral periodogram output from current buffer contents and */ \ /* print standard format to stdout */ \ int ASGRAM(_print)(ASGRAM() _q); \ LIQUID_ASGRAM_DEFINE_API(LIQUID_ASGRAM_MANGLE_CFLOAT, float, liquid_float_complex, liquid_float_complex) LIQUID_ASGRAM_DEFINE_API(LIQUID_ASGRAM_MANGLE_FLOAT, float, liquid_float_complex, float) // // spectral periodogram waterfall // #define LIQUID_SPWATERFALL_MANGLE_CFLOAT(name) LIQUID_CONCAT(spwaterfallcf,name) #define LIQUID_SPWATERFALL_MANGLE_FLOAT(name) LIQUID_CONCAT(spwaterfallf, name) // Macro : SPWATERFALL // SPWATERFALL : name-mangling macro // T : primitive data type // TC : primitive data type (complex) // TI : primitive data type (input) #define LIQUID_SPWATERFALL_DEFINE_API(SPWATERFALL,T,TC,TI) \ \ /* Spectral periodogram waterfall object for computing time-varying */ \ /* power spectral density estimates */ \ typedef struct SPWATERFALL(_s) * SPWATERFALL(); \ \ /* Create spwaterfall object, fully defined */ \ /* _nfft : transform (FFT) size, _nfft >= 2 */ \ /* _wtype : window type, e.g. LIQUID_WINDOW_HAMMING */ \ /* _window_len : window length, 1 <= _window_len <= _nfft */ \ /* _delay : delay between transforms, _delay > 0 */ \ /* _time : number of aggregated transforms, _time > 0 */ \ SPWATERFALL() SPWATERFALL(_create)(unsigned int _nfft, \ int _wtype, \ unsigned int _window_len, \ unsigned int _delay, \ unsigned int _time); \ \ /* Create default spwatefall object (Kaiser-Bessel window) */ \ /* _nfft : transform size, _nfft >= 2 */ \ /* _time : delay between transforms, _delay > 0 */ \ SPWATERFALL() SPWATERFALL(_create_default)(unsigned int _nfft, \ unsigned int _time); \ \ /* Destroy spwaterfall object, freeing all internally-allocated memory */ \ int SPWATERFALL(_destroy)(SPWATERFALL() _q); \ \ /* Clears the internal state of the object, but not the internal buffer */ \ int SPWATERFALL(_clear)(SPWATERFALL() _q); \ \ /* Reset the object to its original state completely. This effectively */ \ /* executes the clear() method and then resets the internal buffer */ \ int SPWATERFALL(_reset)(SPWATERFALL() _q); \ \ /* Print internal state of the object to stdout */ \ int SPWATERFALL(_print)(SPWATERFALL() _q); \ \ /* Get number of samples processed since object was created */ \ uint64_t SPWATERFALL(_get_num_samples_total)(SPWATERFALL() _q); \ \ /* Get FFT size (columns in PSD output) */ \ unsigned int SPWATERFALL(_get_num_freq)(SPWATERFALL() _q); \ \ /* Get number of accumulated FFTs (rows in PSD output) */ \ unsigned int SPWATERFALL(_get_num_time)(SPWATERFALL() _q); \ \ /* Get window length used in spectral estimation */ \ unsigned int SPWATERFALL(_get_window_len)(SPWATERFALL() _q); \ \ /* Get delay between transforms used in spectral estimation */ \ unsigned int SPWATERFALL(_get_delay)(SPWATERFALL() _q); \ \ /* Get window type used in spectral estimation */ \ int SPWATERFALL(_get_wtype)(SPWATERFALL() _q); \ \ /* Get power spectral density (PSD), size: nfft x time */ \ const T * SPWATERFALL(_get_psd)(SPWATERFALL() _q); \ \ /* Set the center frequency of the received signal. */ \ /* This is for display purposes only when generating the output image. */ \ /* _q : spectral periodogram waterfall object */ \ /* _freq : center frequency [Hz] */ \ int SPWATERFALL(_set_freq)(SPWATERFALL() _q, \ float _freq); \ \ /* Set the sample rate (frequency) of the received signal. */ \ /* This is for display purposes only when generating the output image. */ \ /* _q : spectral periodogram waterfall object */ \ /* _rate : sample rate [Hz] */ \ int SPWATERFALL(_set_rate)(SPWATERFALL() _q, \ float _rate); \ \ /* Set the canvas size. */ \ /* This is for display purposes only when generating the output image. */ \ /* _q : spectral periodogram waterfall object */ \ /* _width : image width [pixels] */ \ /* _height : image height [pixels] */ \ int SPWATERFALL(_set_dims)(SPWATERFALL() _q, \ unsigned int _width, \ unsigned int _height); \ \ /* Set commands for executing directly before 'plot' statement. */ \ /* _q : spectral periodogram waterfall object */ \ /* _commands : gnuplot commands separated by semicolons */ \ int SPWATERFALL(_set_commands)(SPWATERFALL() _q, \ const char * _commands); \ \ /* Push a single sample into the object, executing internal transform */ \ /* as necessary. */ \ /* _q : spwaterfall object */ \ /* _x : input sample */ \ int SPWATERFALL(_push)(SPWATERFALL() _q, \ TI _x); \ \ /* Write a block of samples to the object, executing internal */ \ /* transform as necessary. */ \ /* _q : spwaterfall object */ \ /* _x : input buffer, [size: _n x 1] */ \ /* _n : input buffer length */ \ int SPWATERFALL(_write)(SPWATERFALL() _q, \ TI * _x, \ unsigned int _n); \ \ /* Export set of files for plotting */ \ /* _q : spwaterfall object */ \ /* _base : base filename (will export .gnu, .bin, and .png files) */ \ int SPWATERFALL(_export)(SPWATERFALL() _q, \ const char * _base); \ LIQUID_SPWATERFALL_DEFINE_API(LIQUID_SPWATERFALL_MANGLE_CFLOAT, float, liquid_float_complex, liquid_float_complex) LIQUID_SPWATERFALL_DEFINE_API(LIQUID_SPWATERFALL_MANGLE_FLOAT, float, liquid_float_complex, float) // // MODULE : filter // // // firdes: finite impulse response filter design // // prototypes #define LIQUID_FIRFILT_NUM_TYPES (16) typedef enum { LIQUID_FIRFILT_UNKNOWN=0, // unknown filter type // Nyquist filter prototypes LIQUID_FIRFILT_KAISER, // Nyquist Kaiser filter LIQUID_FIRFILT_PM, // Parks-McClellan filter LIQUID_FIRFILT_RCOS, // raised-cosine filter LIQUID_FIRFILT_FEXP, // flipped exponential LIQUID_FIRFILT_FSECH, // flipped hyperbolic secant LIQUID_FIRFILT_FARCSECH, // flipped arc-hyperbolic secant // root-Nyquist filter prototypes LIQUID_FIRFILT_ARKAISER, // root-Nyquist Kaiser (approximate optimum) LIQUID_FIRFILT_RKAISER, // root-Nyquist Kaiser (true optimum) LIQUID_FIRFILT_RRC, // root raised-cosine LIQUID_FIRFILT_hM3, // harris-Moerder-3 filter LIQUID_FIRFILT_GMSKTX, // GMSK transmit filter LIQUID_FIRFILT_GMSKRX, // GMSK receive filter LIQUID_FIRFILT_RFEXP, // flipped exponential LIQUID_FIRFILT_RFSECH, // flipped hyperbolic secant LIQUID_FIRFILT_RFARCSECH, // flipped arc-hyperbolic secant } liquid_firfilt_type; // Design (root-)Nyquist filter from prototype // _type : filter type (e.g. LIQUID_FIRFILT_RRC) // _k : samples/symbol, _k > 1 // _m : symbol delay, _m > 0 // _beta : excess bandwidth factor, _beta in [0,1) // _dt : fractional sample delay, _dt in [-1,1] // _h : output coefficient buffer (length: 2*_k*_m+1) void liquid_firdes_prototype(liquid_firfilt_type _type, unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // pretty names for filter design types extern const char * liquid_firfilt_type_str[LIQUID_FIRFILT_NUM_TYPES][2]; // returns filter type based on input string int liquid_getopt_str2firfilt(const char * _str); // estimate required filter length given // _df : transition bandwidth (0 < _b < 0.5) // _As : stop-band attenuation [dB], _As > 0 unsigned int estimate_req_filter_len(float _df, float _As); // estimate filter stop-band attenuation given // _df : transition bandwidth (0 < _b < 0.5) // _N : filter length float estimate_req_filter_As(float _df, unsigned int _N); // estimate filter transition bandwidth given // _As : stop-band attenuation [dB], _As > 0 // _N : filter length float estimate_req_filter_df(float _As, unsigned int _N); // returns the Kaiser window beta factor give the filter's target // stop-band attenuation (As) [Vaidyanathan:1993] // _As : target filter's stop-band attenuation [dB], _As > 0 float kaiser_beta_As(float _As); // Design FIR filter using Parks-McClellan algorithm // band type specifier typedef enum { LIQUID_FIRDESPM_BANDPASS=0, // regular band-pass filter LIQUID_FIRDESPM_DIFFERENTIATOR, // differentiating filter LIQUID_FIRDESPM_HILBERT // Hilbert transform } liquid_firdespm_btype; // weighting type specifier typedef enum { LIQUID_FIRDESPM_FLATWEIGHT=0, // flat weighting LIQUID_FIRDESPM_EXPWEIGHT, // exponential weighting LIQUID_FIRDESPM_LINWEIGHT, // linear weighting } liquid_firdespm_wtype; // run filter design (full life cycle of object) // _h_len : length of filter (number of taps) // _num_bands : number of frequency bands // _bands : band edges, f in [0,0.5], [size: _num_bands x 2] // _des : desired response [size: _num_bands x 1] // _weights : response weighting [size: _num_bands x 1] // _wtype : weight types (e.g. LIQUID_FIRDESPM_FLATWEIGHT) [size: _num_bands x 1] // _btype : band type (e.g. LIQUID_FIRDESPM_BANDPASS) // _h : output coefficients array [size: _h_len x 1] int firdespm_run(unsigned int _h_len, unsigned int _num_bands, float * _bands, float * _des, float * _weights, liquid_firdespm_wtype * _wtype, liquid_firdespm_btype _btype, float * _h); // run filter design for basic low-pass filter // _n : filter length, _n > 0 // _fc : cutoff frequency, 0 < _fc < 0.5 // _As : stop-band attenuation [dB], _As > 0 // _mu : fractional sample offset, -0.5 < _mu < 0.5 [ignored] // _h : output coefficient buffer, [size: _n x 1] int firdespm_lowpass(unsigned int _n, float _fc, float _As, float _mu, float * _h); // firdespm response callback function // _frequency : normalized frequency // _userdata : pointer to userdata // _desired : (return) desired response // _weight : (return) weight typedef int (*firdespm_callback)(double _frequency, void * _userdata, double * _desired, double * _weight); // structured object typedef struct firdespm_s * firdespm; // create firdespm object // _h_len : length of filter (number of taps) // _num_bands : number of frequency bands // _bands : band edges, f in [0,0.5], [size: _num_bands x 2] // _des : desired response [size: _num_bands x 1] // _weights : response weighting [size: _num_bands x 1] // _wtype : weight types (e.g. LIQUID_FIRDESPM_FLATWEIGHT) [size: _num_bands x 1] // _btype : band type (e.g. LIQUID_FIRDESPM_BANDPASS) firdespm firdespm_create(unsigned int _h_len, unsigned int _num_bands, float * _bands, float * _des, float * _weights, liquid_firdespm_wtype * _wtype, liquid_firdespm_btype _btype); // create firdespm object with user-defined callback // _h_len : length of filter (number of taps) // _num_bands : number of frequency bands // _bands : band edges, f in [0,0.5], [size: _num_bands x 2] // _btype : band type (e.g. LIQUID_FIRDESPM_BANDPASS) // _callback : user-defined callback for specifying desired response & weights // _userdata : user-defined data structure for callback function firdespm firdespm_create_callback(unsigned int _h_len, unsigned int _num_bands, float * _bands, liquid_firdespm_btype _btype, firdespm_callback _callback, void * _userdata); // destroy firdespm object int firdespm_destroy(firdespm _q); // print firdespm object internals int firdespm_print(firdespm _q); // execute filter design, storing result in _h int firdespm_execute(firdespm _q, float * _h); // Design FIR using kaiser window // _n : filter length, _n > 0 // _fc : cutoff frequency, 0 < _fc < 0.5 // _As : stop-band attenuation [dB], _As > 0 // _mu : fractional sample offset, -0.5 < _mu < 0.5 // _h : output coefficient buffer, [size: _n x 1] void liquid_firdes_kaiser(unsigned int _n, float _fc, float _As, float _mu, float *_h); // Design finite impulse response notch filter // _m : filter semi-length, m in [1,1000] // _f0 : filter notch frequency (normalized), -0.5 <= _fc <= 0.5 // _As : stop-band attenuation [dB], _As > 0 // _h : output coefficient buffer, [size: 2*_m+1 x 1] void liquid_firdes_notch(unsigned int _m, float _f0, float _As, float * _h); // Design FIR doppler filter // _n : filter length // _fd : normalized doppler frequency (0 < _fd < 0.5) // _K : Rice fading factor (K >= 0) // _theta : LoS component angle of arrival // _h : output coefficient buffer void liquid_firdes_doppler(unsigned int _n, float _fd, float _K, float _theta, float * _h); // Design Nyquist raised-cosine filter // _k : samples/symbol // _m : symbol delay // _beta : rolloff factor (0 < beta <= 1) // _dt : fractional sample delay // _h : output coefficient buffer (length: 2*k*m+1) void liquid_firdes_rcos(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design root-Nyquist raised-cosine filter void liquid_firdes_rrcos(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design root-Nyquist Kaiser filter void liquid_firdes_rkaiser(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design (approximate) root-Nyquist Kaiser filter void liquid_firdes_arkaiser(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design root-Nyquist harris-Moerder filter void liquid_firdes_hM3(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design GMSK transmit and receive filters void liquid_firdes_gmsktx(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); void liquid_firdes_gmskrx(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design flipped exponential Nyquist/root-Nyquist filters void liquid_firdes_fexp( unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); void liquid_firdes_rfexp(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design flipped hyperbolic secand Nyquist/root-Nyquist filters void liquid_firdes_fsech( unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); void liquid_firdes_rfsech(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Design flipped arc-hyperbolic secand Nyquist/root-Nyquist filters void liquid_firdes_farcsech( unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); void liquid_firdes_rfarcsech(unsigned int _k, unsigned int _m, float _beta, float _dt, float * _h); // Compute group delay for an FIR filter // _h : filter coefficients array // _n : filter length // _fc : frequency at which delay is evaluated (-0.5 < _fc < 0.5) float fir_group_delay(float * _h, unsigned int _n, float _fc); // Compute group delay for an IIR filter // _b : filter numerator coefficients // _nb : filter numerator length // _a : filter denominator coefficients // _na : filter denominator length // _fc : frequency at which delay is evaluated (-0.5 < _fc < 0.5) float iir_group_delay(float * _b, unsigned int _nb, float * _a, unsigned int _na, float _fc); // liquid_filter_autocorr() // // Compute auto-correlation of filter at a specific lag. // // _h : filter coefficients [size: _h_len x 1] // _h_len : filter length // _lag : auto-correlation lag (samples) float liquid_filter_autocorr(float * _h, unsigned int _h_len, int _lag); // liquid_filter_crosscorr() // // Compute cross-correlation of two filters at a specific lag. // // _h : filter coefficients [size: _h_len] // _h_len : filter length // _g : filter coefficients [size: _g_len] // _g_len : filter length // _lag : cross-correlation lag (samples) float liquid_filter_crosscorr(float * _h, unsigned int _h_len, float * _g, unsigned int _g_len, int _lag); // liquid_filter_isi() // // Compute inter-symbol interference (ISI)--both RMS and // maximum--for the filter _h. // // _h : filter coefficients [size: 2*_k*_m+1 x 1] // _k : filter over-sampling rate (samples/symbol) // _m : filter delay (symbols) // _rms : output root mean-squared ISI // _max : maximum ISI void liquid_filter_isi(float * _h, unsigned int _k, unsigned int _m, float * _rms, float * _max); // Compute relative out-of-band energy // // _h : filter coefficients [size: _h_len x 1] // _h_len : filter length // _fc : analysis cut-off frequency // _nfft : fft size float liquid_filter_energy(float * _h, unsigned int _h_len, float _fc, unsigned int _nfft); // // IIR filter design // // IIR filter design filter type typedef enum { LIQUID_IIRDES_BUTTER=0, LIQUID_IIRDES_CHEBY1, LIQUID_IIRDES_CHEBY2, LIQUID_IIRDES_ELLIP, LIQUID_IIRDES_BESSEL } liquid_iirdes_filtertype; // IIR filter design band type typedef enum { LIQUID_IIRDES_LOWPASS=0, LIQUID_IIRDES_HIGHPASS, LIQUID_IIRDES_BANDPASS, LIQUID_IIRDES_BANDSTOP } liquid_iirdes_bandtype; // IIR filter design coefficients format typedef enum { LIQUID_IIRDES_SOS=0, LIQUID_IIRDES_TF } liquid_iirdes_format; // IIR filter design template // _ftype : filter type (e.g. LIQUID_IIRDES_BUTTER) // _btype : band type (e.g. LIQUID_IIRDES_BANDPASS) // _format : coefficients format (e.g. LIQUID_IIRDES_SOS) // _n : filter order // _fc : low-pass prototype cut-off frequency // _f0 : center frequency (band-pass, band-stop) // _Ap : pass-band ripple in dB // _As : stop-band ripple in dB // _B : numerator // _A : denominator void liquid_iirdes(liquid_iirdes_filtertype _ftype, liquid_iirdes_bandtype _btype, liquid_iirdes_format _format, unsigned int _n, float _fc, float _f0, float _Ap, float _As, float * _B, float * _A); // compute analog zeros, poles, gain for specific filter types void butter_azpkf(unsigned int _n, liquid_float_complex * _za, liquid_float_complex * _pa, liquid_float_complex * _ka); void cheby1_azpkf(unsigned int _n, float _ep, liquid_float_complex * _z, liquid_float_complex * _p, liquid_float_complex * _k); void cheby2_azpkf(unsigned int _n, float _es, liquid_float_complex * _z, liquid_float_complex * _p, liquid_float_complex * _k); void ellip_azpkf(unsigned int _n, float _ep, float _es, liquid_float_complex * _z, liquid_float_complex * _p, liquid_float_complex * _k); void bessel_azpkf(unsigned int _n, liquid_float_complex * _z, liquid_float_complex * _p, liquid_float_complex * _k); // compute frequency pre-warping factor float iirdes_freqprewarp(liquid_iirdes_bandtype _btype, float _fc, float _f0); // convert analog z/p/k form to discrete z/p/k form (bilinear z-transform) // _za : analog zeros [length: _nza] // _nza : number of analog zeros // _pa : analog poles [length: _npa] // _npa : number of analog poles // _m : frequency pre-warping factor // _zd : output digital zeros [length: _npa] // _pd : output digital poles [length: _npa] // _kd : output digital gain (should actually be real-valued) void bilinear_zpkf(liquid_float_complex * _za, unsigned int _nza, liquid_float_complex * _pa, unsigned int _npa, liquid_float_complex _ka, float _m, liquid_float_complex * _zd, liquid_float_complex * _pd, liquid_float_complex * _kd); // digital z/p/k low-pass to high-pass // _zd : digital zeros (low-pass prototype), [length: _n] // _pd : digital poles (low-pass prototype), [length: _n] // _n : low-pass filter order // _zdt : output digital zeros transformed [length: _n] // _pdt : output digital poles transformed [length: _n] void iirdes_dzpk_lp2hp(liquid_float_complex * _zd, liquid_float_complex * _pd, unsigned int _n, liquid_float_complex * _zdt, liquid_float_complex * _pdt); // digital z/p/k low-pass to band-pass // _zd : digital zeros (low-pass prototype), [length: _n] // _pd : digital poles (low-pass prototype), [length: _n] // _n : low-pass filter order // _f0 : center frequency // _zdt : output digital zeros transformed [length: 2*_n] // _pdt : output digital poles transformed [length: 2*_n] void iirdes_dzpk_lp2bp(liquid_float_complex * _zd, liquid_float_complex * _pd, unsigned int _n, float _f0, liquid_float_complex * _zdt, liquid_float_complex * _pdt); // convert discrete z/p/k form to transfer function // _zd : digital zeros [length: _n] // _pd : digital poles [length: _n] // _n : filter order // _kd : digital gain // _b : output numerator [length: _n+1] // _a : output denominator [length: _n+1] void iirdes_dzpk2tff(liquid_float_complex * _zd, liquid_float_complex * _pd, unsigned int _n, liquid_float_complex _kd, float * _b, float * _a); // convert discrete z/p/k form to second-order sections // _zd : digital zeros [length: _n] // _pd : digital poles [length: _n] // _n : filter order // _kd : digital gain // _B : output numerator [size: 3 x L+r] // _A : output denominator [size: 3 x L+r] // where r = _n%2, L = (_n-r)/2 void iirdes_dzpk2sosf(liquid_float_complex * _zd, liquid_float_complex * _pd, unsigned int _n, liquid_float_complex _kd, float * _B, float * _A); // additional IIR filter design templates // design 2nd-order IIR filter (active lag) // 1 + t2 * s // F(s) = ------------ // 1 + t1 * s // // _w : filter bandwidth // _zeta : damping factor (1/sqrt(2) suggested) // _K : loop gain (1000 suggested) // _b : output feed-forward coefficients [size: 3 x 1] // _a : output feed-back coefficients [size: 3 x 1] void iirdes_pll_active_lag(float _w, float _zeta, float _K, float * _b, float * _a); // design 2nd-order IIR filter (active PI) // 1 + t2 * s // F(s) = ------------ // t1 * s // // _w : filter bandwidth // _zeta : damping factor (1/sqrt(2) suggested) // _K : loop gain (1000 suggested) // _b : output feed-forward coefficients [size: 3 x 1] // _a : output feed-back coefficients [size: 3 x 1] void iirdes_pll_active_PI(float _w, float _zeta, float _K, float * _b, float * _a); // checks stability of iir filter // _b : feed-forward coefficients [size: _n x 1] // _a : feed-back coefficients [size: _n x 1] // _n : number of coefficients int iirdes_isstable(float * _b, float * _a, unsigned int _n); // // linear prediction // // compute the linear prediction coefficients for an input signal _x // _x : input signal [size: _n x 1] // _n : input signal length // _p : prediction filter order // _a : prediction filter [size: _p+1 x 1] // _e : prediction error variance [size: _p+1 x 1] void liquid_lpc(float * _x, unsigned int _n, unsigned int _p, float * _a, float * _g); // solve the Yule-Walker equations using Levinson-Durbin recursion // for _symmetric_ autocorrelation // _r : autocorrelation array [size: _p+1 x 1] // _p : filter order // _a : output coefficients [size: _p+1 x 1] // _e : error variance [size: _p+1 x 1] // // NOTES: // By definition _a[0] = 1.0 void liquid_levinson(float * _r, unsigned int _p, float * _a, float * _e); // // auto-correlator (delay cross-correlation) // #define LIQUID_AUTOCORR_MANGLE_CCCF(name) LIQUID_CONCAT(autocorr_cccf,name) #define LIQUID_AUTOCORR_MANGLE_RRRF(name) LIQUID_CONCAT(autocorr_rrrf,name) // Macro: // AUTOCORR : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_AUTOCORR_DEFINE_API(AUTOCORR,TO,TC,TI) \ \ /* Computes auto-correlation with a fixed lag on input signals */ \ typedef struct AUTOCORR(_s) * AUTOCORR(); \ \ /* Create auto-correlator object with a particular window length and */ \ /* delay */ \ /* _window_size : size of the correlator window */ \ /* _delay : correlator delay [samples] */ \ AUTOCORR() AUTOCORR(_create)(unsigned int _window_size, \ unsigned int _delay); \ \ /* Destroy auto-correlator object, freeing internal memory */ \ void AUTOCORR(_destroy)(AUTOCORR() _q); \ \ /* Reset auto-correlator object's internals */ \ void AUTOCORR(_reset)(AUTOCORR() _q); \ \ /* Print auto-correlator parameters to stdout */ \ void AUTOCORR(_print)(AUTOCORR() _q); \ \ /* Push sample into auto-correlator object */ \ /* _q : auto-correlator object */ \ /* _x : single input sample */ \ void AUTOCORR(_push)(AUTOCORR() _q, \ TI _x); \ \ /* Write block of samples to auto-correlator object */ \ /* _q : auto-correlation object */ \ /* _x : input array [size: _n x 1] */ \ /* _n : number of input samples */ \ void AUTOCORR(_write)(AUTOCORR() _q, \ TI * _x, \ unsigned int _n); \ \ /* Compute single auto-correlation output */ \ /* _q : auto-correlator object */ \ /* _rxx : auto-correlated output */ \ void AUTOCORR(_execute)(AUTOCORR() _q, \ TO * _rxx); \ \ /* Compute auto-correlation on block of samples; the input and output */ \ /* arrays may have the same pointer */ \ /* _q : auto-correlation object */ \ /* _x : input array [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _rxx : input array [size: _n x 1] */ \ void AUTOCORR(_execute_block)(AUTOCORR() _q, \ TI * _x, \ unsigned int _n, \ TO * _rxx); \ \ /* return sum of squares of buffered samples */ \ float AUTOCORR(_get_energy)(AUTOCORR() _q); \ LIQUID_AUTOCORR_DEFINE_API(LIQUID_AUTOCORR_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) LIQUID_AUTOCORR_DEFINE_API(LIQUID_AUTOCORR_MANGLE_RRRF, float, float, float) // // Finite impulse response filter // #define LIQUID_FIRFILT_MANGLE_RRRF(name) LIQUID_CONCAT(firfilt_rrrf,name) #define LIQUID_FIRFILT_MANGLE_CRCF(name) LIQUID_CONCAT(firfilt_crcf,name) #define LIQUID_FIRFILT_MANGLE_CCCF(name) LIQUID_CONCAT(firfilt_cccf,name) // Macro: // FIRFILT : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FIRFILT_DEFINE_API(FIRFILT,TO,TC,TI) \ \ /* Finite impulse response (FIR) filter */ \ typedef struct FIRFILT(_s) * FIRFILT(); \ \ /* Create a finite impulse response filter (firfilt) object by directly */ \ /* specifying the filter coefficients in an array */ \ /* _h : filter coefficients [size: _n x 1] */ \ /* _n : number of filter coefficients, _n > 0 */ \ FIRFILT() FIRFILT(_create)(TC * _h, \ unsigned int _n); \ \ /* Create object using Kaiser-Bessel windowed sinc method */ \ /* _n : filter length, _n > 0 */ \ /* _fc : filter normalized cut-off frequency, 0 < _fc < 0.5 */ \ /* _As : filter stop-band attenuation [dB], _As > 0 */ \ /* _mu : fractional sample offset, -0.5 < _mu < 0.5 */ \ FIRFILT() FIRFILT(_create_kaiser)(unsigned int _n, \ float _fc, \ float _As, \ float _mu); \ \ /* Create object from square-root Nyquist prototype. */ \ /* The filter length will be \(2 k m + 1 \) samples long with a delay */ \ /* of \( k m + 1 \) samples. */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _k : nominal samples per symbol, _k > 1 */ \ /* _m : filter delay [symbols], _m > 0 */ \ /* _beta : rolloff factor, 0 < beta <= 1 */ \ /* _mu : fractional sample offset [samples], -0.5 < _mu < 0.5 */ \ FIRFILT() FIRFILT(_create_rnyquist)(int _type, \ unsigned int _k, \ unsigned int _m, \ float _beta, \ float _mu); \ \ /* Create object from Parks-McClellan algorithm prototype */ \ /* _h_len : filter length, _h_len > 0 */ \ /* _fc : cutoff frequency, 0 < _fc < 0.5 */ \ /* _As : stop-band attenuation [dB], _As > 0 */ \ FIRFILT() FIRFILT(_create_firdespm)(unsigned int _h_len, \ float _fc, \ float _As); \ \ /* Create rectangular filter prototype; that is */ \ /* \( \vec{h} = \{ 1, 1, 1, \ldots 1 \} \) */ \ /* _n : length of filter [samples], 0 < _n <= 1024 */ \ FIRFILT() FIRFILT(_create_rect)(unsigned int _n); \ \ /* Create DC blocking filter from prototype */ \ /* _m : prototype filter semi-length such that filter length is 2*m+1 */ \ /* _As : prototype filter stop-band attenuation [dB], _As > 0 */ \ FIRFILT() FIRFILT(_create_dc_blocker)(unsigned int _m, \ float _As); \ \ /* Create notch filter from prototype */ \ /* _m : prototype filter semi-length such that filter length is 2*m+1 */ \ /* _As : prototype filter stop-band attenuation [dB], _As > 0 */ \ /* _f0 : center frequency for notch, _fc in [-0.5, 0.5] */ \ FIRFILT() FIRFILT(_create_notch)(unsigned int _m, \ float _As, \ float _f0); \ \ /* Re-create filter object of potentially a different length with */ \ /* different coefficients. If the length of the filter does not change, */ \ /* not memory reallocation is invoked. */ \ /* _q : original filter object */ \ /* _h : pointer to filter coefficients, [size: _n x 1] */ \ /* _n : filter length, _n > 0 */ \ FIRFILT() FIRFILT(_recreate)(FIRFILT() _q, \ TC * _h, \ unsigned int _n); \ \ /* Destroy filter object and free all internal memory */ \ void FIRFILT(_destroy)(FIRFILT() _q); \ \ /* Reset filter object's internal buffer */ \ void FIRFILT(_reset)(FIRFILT() _q); \ \ /* Print filter object information to stdout */ \ void FIRFILT(_print)(FIRFILT() _q); \ \ /* Set output scaling for filter */ \ /* _q : filter object */ \ /* _scale : scaling factor to apply to each output sample */ \ void FIRFILT(_set_scale)(FIRFILT() _q, \ TC _scale); \ \ /* Get output scaling for filter */ \ /* _q : filter object */ \ /* _scale : scaling factor applied to each output sample */ \ void FIRFILT(_get_scale)(FIRFILT() _q, \ TC * _scale); \ \ /* Push sample into filter object's internal buffer */ \ /* _q : filter object */ \ /* _x : single input sample */ \ void FIRFILT(_push)(FIRFILT() _q, \ TI _x); \ \ /* Write block of samples into filter object's internal buffer */ \ /* _q : filter object */ \ /* _x : buffer of input samples, [size: _n x 1] */ \ /* _n : number of input samples */ \ void FIRFILT(_write)(FIRFILT() _q, \ TI * _x, \ unsigned int _n); \ \ /* Execute vector dot product on the filter's internal buffer and */ \ /* coefficients */ \ /* _q : filter object */ \ /* _y : pointer to single output sample */ \ void FIRFILT(_execute)(FIRFILT() _q, \ TO * _y); \ \ /* Execute the filter on a block of input samples; in-place operation */ \ /* is permitted (_x and _y may point to the same place in memory) */ \ /* _q : filter object */ \ /* _x : pointer to input array, [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _y : pointer to output array, [size: _n x 1] */ \ void FIRFILT(_execute_block)(FIRFILT() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* Get length of filter object (number of internal coefficients) */ \ unsigned int FIRFILT(_get_length)(FIRFILT() _q); \ \ /* Get pointer to coefficients array */ \ const TC * FIRFILT(_get_coefficients)(FIRFILT() _q); \ \ /* Copy internal coefficients to external buffer */ \ /* _q : filter object */ \ /* _h : pointer to output coefficients array [size: _n x 1] */ \ int FIRFILT(_copy_coefficients)(FIRFILT() _q, \ TC * _h); \ \ /* Compute complex frequency response of filter object */ \ /* _q : filter object */ \ /* _fc : normalized frequency for evaluation */ \ /* _H : pointer to output complex frequency response */ \ void FIRFILT(_freqresponse)(FIRFILT() _q, \ float _fc, \ liquid_float_complex * _H); \ \ /* Compute and return group delay of filter object */ \ /* _q : filter object */ \ /* _fc : frequency to evaluate */ \ float FIRFILT(_groupdelay)(FIRFILT() _q, \ float _fc); \ LIQUID_FIRFILT_DEFINE_API(LIQUID_FIRFILT_MANGLE_RRRF, float, float, float) LIQUID_FIRFILT_DEFINE_API(LIQUID_FIRFILT_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_FIRFILT_DEFINE_API(LIQUID_FIRFILT_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // fdelay : arbitrary delay #define LIQUID_FDELAY_MANGLE_RRRF(name) LIQUID_CONCAT(fdelay_rrrf,name) #define LIQUID_FDELAY_MANGLE_CRCF(name) LIQUID_CONCAT(fdelay_crcf,name) // Macro: // FDELAY : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FDELAY_DEFINE_API(FDELAY,TO,TC,TI) \ \ /* Finite impulse response (FIR) filter */ \ typedef struct FDELAY(_s) * FDELAY(); \ \ /* Create a delay object with a maximum offset and filter specification */ \ /* _nmax : maximum integer sample offset */ \ /* _m : polyphase filter-bank semi-length, _m > 0 */ \ /* _npfb : number of filters in polyphase filter-bank, _npfb > 0 */ \ FDELAY() FDELAY(_create)(unsigned int _nmax, \ unsigned int _m, \ unsigned int _npfb); \ \ /* Create a delay object with a maximum offset and default filter */ \ /* parameters (_m = 8, _npfb = 64) */ \ /* _nmax : maximum integer sample offset */ \ FDELAY() FDELAY(_create_default)(unsigned int _nmax); \ \ /* Destroy delay object and free all internal memory */ \ int FDELAY(_destroy)(FDELAY() _q); \ \ /* Reset delay object internals */ \ int FDELAY(_reset)(FDELAY() _q); \ \ /* Print delay object internals */ \ int FDELAY(_print)(FDELAY() _q); \ \ /* Get current delay (accounting for _m?) */ \ float FDELAY(_get_delay)(FDELAY() _q); \ int FDELAY(_set_delay)(FDELAY() _q, float _delay); \ int FDELAY(_adjust_delay)(FDELAY() _q, float _delta); \ \ unsigned int FDELAY(_get_nmax)(FDELAY() _q); \ unsigned int FDELAY(_get_m) (FDELAY() _q); \ unsigned int FDELAY(_get_npfb)(FDELAY() _q); \ \ /* Push sample into filter object's internal buffer */ \ /* _q : filter object */ \ /* _x : single input sample */ \ int FDELAY(_push)(FDELAY() _q, \ TI _x); \ \ /* Write a block of samplex into filter object's internal buffer */ \ /* _q : filter object */ \ /* _x : buffer of input samples, [size: _n x 1] */ \ /* _n : number of input samples */ \ int FDELAY(_write)(FDELAY() _q, \ TI * _x, \ unsigned int _n); \ \ /* Execute vector dot product on the filter's internal buffer and */ \ /* coefficients */ \ /* _q : filter object */ \ /* _y : pointer to single output sample */ \ int FDELAY(_execute)(FDELAY() _q, \ TO * _y); \ \ /* Execute the filter on a block of input samples; in-place operation */ \ /* is permitted (_x and _y may point to the same place in memory) */ \ /* _q : filter object */ \ /* _x : pointer to input array, [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _y : pointer to output array, [size: _n x 1] */ \ int FDELAY(_execute_block)(FDELAY() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_FDELAY_DEFINE_API(LIQUID_FDELAY_MANGLE_RRRF, float, float, float) LIQUID_FDELAY_DEFINE_API(LIQUID_FDELAY_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) // // FIR Hilbert transform // 2:1 real-to-complex decimator // 1:2 complex-to-real interpolator // #define LIQUID_FIRHILB_MANGLE_FLOAT(name) LIQUID_CONCAT(firhilbf, name) //#define LIQUID_FIRHILB_MANGLE_DOUBLE(name) LIQUID_CONCAT(firhilb, name) // NOTES: // Although firhilb is a placeholder for both decimation and // interpolation, separate objects should be used for each task. #define LIQUID_FIRHILB_DEFINE_API(FIRHILB,T,TC) \ \ /* Finite impulse response (FIR) Hilbert transform */ \ typedef struct FIRHILB(_s) * FIRHILB(); \ \ /* Create a firhilb object with a particular filter semi-length and */ \ /* desired stop-band attenuation. */ \ /* Internally the object designs a half-band filter based on applying */ \ /* a Kaiser-Bessel window to a sinc function to guarantee zeros at all */ \ /* off-center odd indexed samples. */ \ /* _m : filter semi-length, delay is \( 2 m + 1 \) */ \ /* _As : filter stop-band attenuation [dB] */ \ FIRHILB() FIRHILB(_create)(unsigned int _m, \ float _As); \ \ /* Destroy finite impulse response Hilbert transform, freeing all */ \ /* internally-allocted memory and objects. */ \ void FIRHILB(_destroy)(FIRHILB() _q); \ \ /* Print firhilb object internals to stdout */ \ void FIRHILB(_print)(FIRHILB() _q); \ \ /* Reset firhilb object internal state */ \ void FIRHILB(_reset)(FIRHILB() _q); \ \ /* Execute Hilbert transform (real to complex) */ \ /* _q : Hilbert transform object */ \ /* _x : real-valued input sample */ \ /* _y : complex-valued output sample */ \ void FIRHILB(_r2c_execute)(FIRHILB() _q, \ T _x, \ TC * _y); \ \ /* Execute Hilbert transform (complex to real) */ \ /* _q : Hilbert transform object */ \ /* _x : complex-valued input sample */ \ /* _y0 : real-valued output sample, lower side-band retained */ \ /* _y1 : real-valued output sample, upper side-band retained */ \ void FIRHILB(_c2r_execute)(FIRHILB() _q, \ TC _x, \ T * _y0, \ T * _y1); \ \ /* Execute Hilbert transform decimator (real to complex) */ \ /* _q : Hilbert transform object */ \ /* _x : real-valued input array, [size: 2 x 1] */ \ /* _y : complex-valued output sample */ \ void FIRHILB(_decim_execute)(FIRHILB() _q, \ T * _x, \ TC * _y); \ \ /* Execute Hilbert transform decimator (real to complex) on a block of */ \ /* samples */ \ /* _q : Hilbert transform object */ \ /* _x : real-valued input array, [size: 2*_n x 1] */ \ /* _n : number of output samples */ \ /* _y : complex-valued output array, [size: _n x 1] */ \ void FIRHILB(_decim_execute_block)(FIRHILB() _q, \ T * _x, \ unsigned int _n, \ TC * _y); \ \ /* Execute Hilbert transform interpolator (real to complex) */ \ /* _q : Hilbert transform object */ \ /* _x : complex-valued input sample */ \ /* _y : real-valued output array, [size: 2 x 1] */ \ void FIRHILB(_interp_execute)(FIRHILB() _q, \ TC _x, \ T * _y); \ \ /* Execute Hilbert transform interpolator (complex to real) on a block */ \ /* of samples */ \ /* _q : Hilbert transform object */ \ /* _x : complex-valued input array, [size: _n x 1] */ \ /* _n : number of *input* samples */ \ /* _y : real-valued output array, [size: 2*_n x 1] */ \ void FIRHILB(_interp_execute_block)(FIRHILB() _q, \ TC * _x, \ unsigned int _n, \ T * _y); \ LIQUID_FIRHILB_DEFINE_API(LIQUID_FIRHILB_MANGLE_FLOAT, float, liquid_float_complex) //LIQUID_FIRHILB_DEFINE_API(LIQUID_FIRHILB_MANGLE_DOUBLE, double, liquid_double_complex) // // Infinite impulse response (IIR) Hilbert transform // 2:1 real-to-complex decimator // 1:2 complex-to-real interpolator // #define LIQUID_IIRHILB_MANGLE_FLOAT(name) LIQUID_CONCAT(iirhilbf, name) //#define LIQUID_IIRHILB_MANGLE_DOUBLE(name) LIQUID_CONCAT(iirhilb, name) // NOTES: // Although iirhilb is a placeholder for both decimation and // interpolation, separate objects should be used for each task. #define LIQUID_IIRHILB_DEFINE_API(IIRHILB,T,TC) \ \ /* Infinite impulse response (IIR) Hilbert transform */ \ typedef struct IIRHILB(_s) * IIRHILB(); \ \ /* Create a iirhilb object with a particular filter type, order, and */ \ /* desired pass- and stop-band attenuation. */ \ /* _ftype : filter type (e.g. LIQUID_IIRDES_BUTTER) */ \ /* _n : filter order, _n > 0 */ \ /* _Ap : pass-band ripple [dB], _Ap > 0 */ \ /* _As : stop-band ripple [dB], _Ap > 0 */ \ IIRHILB() IIRHILB(_create)(liquid_iirdes_filtertype _ftype, \ unsigned int _n, \ float _Ap, \ float _As); \ \ /* Create a default iirhilb object with a particular filter order. */ \ /* _n : filter order, _n > 0 */ \ IIRHILB() IIRHILB(_create_default)(unsigned int _n); \ \ /* Destroy finite impulse response Hilbert transform, freeing all */ \ /* internally-allocted memory and objects. */ \ void IIRHILB(_destroy)(IIRHILB() _q); \ \ /* Print iirhilb object internals to stdout */ \ void IIRHILB(_print)(IIRHILB() _q); \ \ /* Reset iirhilb object internal state */ \ void IIRHILB(_reset)(IIRHILB() _q); \ \ /* Execute Hilbert transform (real to complex) */ \ /* _q : Hilbert transform object */ \ /* _x : real-valued input sample */ \ /* _y : complex-valued output sample */ \ void IIRHILB(_r2c_execute)(IIRHILB() _q, \ T _x, \ TC * _y); \ \ /* Execute Hilbert transform (complex to real) */ \ /* _q : Hilbert transform object */ \ /* _x : complex-valued input sample */ \ /* _y : real-valued output sample */ \ void IIRHILB(_c2r_execute)(IIRHILB() _q, \ TC _x, \ T * _y); \ \ /* Execute Hilbert transform decimator (real to complex) */ \ /* _q : Hilbert transform object */ \ /* _x : real-valued input array, [size: 2 x 1] */ \ /* _y : complex-valued output sample */ \ void IIRHILB(_decim_execute)(IIRHILB() _q, \ T * _x, \ TC * _y); \ \ /* Execute Hilbert transform decimator (real to complex) on a block of */ \ /* samples */ \ /* _q : Hilbert transform object */ \ /* _x : real-valued input array, [size: 2*_n x 1] */ \ /* _n : number of output samples */ \ /* _y : complex-valued output array, [size: _n x 1] */ \ void IIRHILB(_decim_execute_block)(IIRHILB() _q, \ T * _x, \ unsigned int _n, \ TC * _y); \ \ /* Execute Hilbert transform interpolator (real to complex) */ \ /* _q : Hilbert transform object */ \ /* _x : complex-valued input sample */ \ /* _y : real-valued output array, [size: 2 x 1] */ \ void IIRHILB(_interp_execute)(IIRHILB() _q, \ TC _x, \ T * _y); \ \ /* Execute Hilbert transform interpolator (complex to real) on a block */ \ /* of samples */ \ /* _q : Hilbert transform object */ \ /* _x : complex-valued input array, [size: _n x 1] */ \ /* _n : number of *input* samples */ \ /* _y : real-valued output array, [size: 2*_n x 1] */ \ void IIRHILB(_interp_execute_block)(IIRHILB() _q, \ TC * _x, \ unsigned int _n, \ T * _y); \ LIQUID_IIRHILB_DEFINE_API(LIQUID_IIRHILB_MANGLE_FLOAT, float, liquid_float_complex) //LIQUID_IIRHILB_DEFINE_API(LIQUID_IIRHILB_MANGLE_DOUBLE, double, liquid_double_complex) // // FFT-based finite impulse response filter // #define LIQUID_FFTFILT_MANGLE_RRRF(name) LIQUID_CONCAT(fftfilt_rrrf,name) #define LIQUID_FFTFILT_MANGLE_CRCF(name) LIQUID_CONCAT(fftfilt_crcf,name) #define LIQUID_FFTFILT_MANGLE_CCCF(name) LIQUID_CONCAT(fftfilt_cccf,name) // Macro: // FFTFILT : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FFTFILT_DEFINE_API(FFTFILT,TO,TC,TI) \ \ /* Fast Fourier transform (FFT) finite impulse response filter */ \ typedef struct FFTFILT(_s) * FFTFILT(); \ \ /* Create FFT-based FIR filter using external coefficients */ \ /* _h : filter coefficients, [size: _h_len x 1] */ \ /* _h_len : filter length, _h_len > 0 */ \ /* _n : block size = nfft/2, _n >= _h_len-1 */ \ FFTFILT() FFTFILT(_create)(TC * _h, \ unsigned int _h_len, \ unsigned int _n); \ \ /* Destroy filter object and free all internal memory */ \ void FFTFILT(_destroy)(FFTFILT() _q); \ \ /* Reset filter object's internal buffer */ \ void FFTFILT(_reset)(FFTFILT() _q); \ \ /* Print filter object information to stdout */ \ void FFTFILT(_print)(FFTFILT() _q); \ \ /* Set output scaling for filter */ \ void FFTFILT(_set_scale)(FFTFILT() _q, \ TC _scale); \ \ /* Get output scaling for filter */ \ void FFTFILT(_get_scale)(FFTFILT() _q, \ TC * _scale); \ \ /* Execute the filter on internal buffer and coefficients given a block */ \ /* of input samples; in-place operation is permitted (_x and _y may */ \ /* point to the same place in memory) */ \ /* _q : filter object */ \ /* _x : pointer to input data array, [size: _n x 1] */ \ /* _y : pointer to output data array, [size: _n x 1] */ \ void FFTFILT(_execute)(FFTFILT() _q, \ TI * _x, \ TO * _y); \ \ /* Get length of filter object's internal coefficients */ \ unsigned int FFTFILT(_get_length)(FFTFILT() _q); \ LIQUID_FFTFILT_DEFINE_API(LIQUID_FFTFILT_MANGLE_RRRF, float, float, float) LIQUID_FFTFILT_DEFINE_API(LIQUID_FFTFILT_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_FFTFILT_DEFINE_API(LIQUID_FFTFILT_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Infinite impulse response filter // #define LIQUID_IIRFILT_MANGLE_RRRF(name) LIQUID_CONCAT(iirfilt_rrrf,name) #define LIQUID_IIRFILT_MANGLE_CRCF(name) LIQUID_CONCAT(iirfilt_crcf,name) #define LIQUID_IIRFILT_MANGLE_CCCF(name) LIQUID_CONCAT(iirfilt_cccf,name) // Macro: // IIRFILT : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_IIRFILT_DEFINE_API(IIRFILT,TO,TC,TI) \ \ /* Infinite impulse response (IIR) filter */ \ typedef struct IIRFILT(_s) * IIRFILT(); \ \ /* Create infinite impulse response filter from external coefficients. */ \ /* Note that the number of feed-forward and feed-back coefficients do */ \ /* not need to be equal, but they do need to be non-zero. */ \ /* Furthermore, the first feed-back coefficient \(a_0\) cannot be */ \ /* equal to zero, otherwise the filter will be invalid as this value is */ \ /* factored out from all coefficients. */ \ /* For stability reasons the number of coefficients should reasonably */ \ /* not exceed about 8 for single-precision floating-point. */ \ /* _b : feed-forward coefficients (numerator), [size: _nb x 1] */ \ /* _nb : number of feed-forward coefficients, _nb > 0 */ \ /* _a : feed-back coefficients (denominator), [size: _na x 1] */ \ /* _na : number of feed-back coefficients, _na > 0 */ \ IIRFILT() IIRFILT(_create)(TC * _b, \ unsigned int _nb, \ TC * _a, \ unsigned int _na); \ \ /* Create IIR filter using 2nd-order secitons from external */ \ /* coefficients. */ \ /* _B : feed-forward coefficients [size: _nsos x 3] */ \ /* _A : feed-back coefficients [size: _nsos x 3] */ \ /* _nsos : number of second-order sections (sos), _nsos > 0 */ \ IIRFILT() IIRFILT(_create_sos)(TC * _B, \ TC * _A, \ unsigned int _nsos); \ \ /* Create IIR filter from design template */ \ /* _ftype : filter type (e.g. LIQUID_IIRDES_BUTTER) */ \ /* _btype : band type (e.g. LIQUID_IIRDES_BANDPASS) */ \ /* _format : coefficients format (e.g. LIQUID_IIRDES_SOS) */ \ /* _order : filter order, _order > 0 */ \ /* _fc : low-pass prototype cut-off frequency, 0 <= _fc <= 0.5 */ \ /* _f0 : center frequency (band-pass, band-stop), 0 <= _f0 <= 0.5 */ \ /* _Ap : pass-band ripple in dB, _Ap > 0 */ \ /* _As : stop-band ripple in dB, _As > 0 */ \ IIRFILT() IIRFILT(_create_prototype)( \ liquid_iirdes_filtertype _ftype, \ liquid_iirdes_bandtype _btype, \ liquid_iirdes_format _format, \ unsigned int _order, \ float _fc, \ float _f0, \ float _Ap, \ float _As); \ \ /* Create simplified low-pass Butterworth IIR filter */ \ /* _order : filter order, _order > 0 */ \ /* _fc : low-pass prototype cut-off frequency */ \ IIRFILT() IIRFILT(_create_lowpass)(unsigned int _order, \ float _fc); \ \ /* Create 8th-order integrator filter */ \ IIRFILT() IIRFILT(_create_integrator)(void); \ \ /* Create 8th-order differentiator filter */ \ IIRFILT() IIRFILT(_create_differentiator)(void); \ \ /* Create simple first-order DC-blocking filter with transfer function */ \ /* \( H(z) = \frac{1 - z^{-1}}{1 - (1-\alpha)z^{-1}} \) */ \ /* _alpha : normalized filter bandwidth, _alpha > 0 */ \ IIRFILT() IIRFILT(_create_dc_blocker)(float _alpha); \ \ /* Create filter to operate as second-order integrating phase-locked */ \ /* loop (active lag design) */ \ /* _w : filter bandwidth, 0 < _w < 1 */ \ /* _zeta : damping factor, \( 1/\sqrt{2} \) suggested, 0 < _zeta < 1 */ \ /* _K : loop gain, 1000 suggested, _K > 0 */ \ IIRFILT() IIRFILT(_create_pll)(float _w, \ float _zeta, \ float _K); \ \ /* Destroy iirfilt object, freeing all internal memory */ \ void IIRFILT(_destroy)(IIRFILT() _q); \ \ /* Print iirfilt object properties to stdout */ \ void IIRFILT(_print)(IIRFILT() _q); \ \ /* Reset iirfilt object internals */ \ void IIRFILT(_reset)(IIRFILT() _q); \ \ /* Compute filter output given a signle input sample */ \ /* _q : iirfilt object */ \ /* _x : input sample */ \ /* _y : output sample pointer */ \ void IIRFILT(_execute)(IIRFILT() _q, \ TI _x, \ TO * _y); \ \ /* Execute the filter on a block of input samples; */ \ /* in-place operation is permitted (the input and output buffers may be */ \ /* the same) */ \ /* _q : filter object */ \ /* _x : pointer to input array, [size: _n x 1] */ \ /* _n : number of input, output samples, _n > 0 */ \ /* _y : pointer to output array, [size: _n x 1] */ \ void IIRFILT(_execute_block)(IIRFILT() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* Return number of coefficients for iirfilt object (maximum between */ \ /* the feed-forward and feed-back coefficients). Note that the filter */ \ /* length = filter order + 1 */ \ unsigned int IIRFILT(_get_length)(IIRFILT() _q); \ \ /* Compute complex frequency response of filter object */ \ /* _q : filter object */ \ /* _fc : normalized frequency for evaluation */ \ /* _H : pointer to output complex frequency response */ \ void IIRFILT(_freqresponse)(IIRFILT() _q, \ float _fc, \ liquid_float_complex * _H); \ \ /* Compute and return group delay of filter object */ \ /* _q : filter object */ \ /* _fc : frequency to evaluate */ \ float IIRFILT(_groupdelay)(IIRFILT() _q, float _fc); \ LIQUID_IIRFILT_DEFINE_API(LIQUID_IIRFILT_MANGLE_RRRF, float, float, float) LIQUID_IIRFILT_DEFINE_API(LIQUID_IIRFILT_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_IIRFILT_DEFINE_API(LIQUID_IIRFILT_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // iirfiltsos : infinite impulse respone filter (second-order sections) // #define LIQUID_IIRFILTSOS_MANGLE_RRRF(name) LIQUID_CONCAT(iirfiltsos_rrrf,name) #define LIQUID_IIRFILTSOS_MANGLE_CRCF(name) LIQUID_CONCAT(iirfiltsos_crcf,name) #define LIQUID_IIRFILTSOS_MANGLE_CCCF(name) LIQUID_CONCAT(iirfiltsos_cccf,name) #define LIQUID_IIRFILTSOS_DEFINE_API(IIRFILTSOS,TO,TC,TI) \ typedef struct IIRFILTSOS(_s) * IIRFILTSOS(); \ \ /* create 2nd-order infinite impulse reponse filter */ \ /* _b : feed-forward coefficients [size: _3 x 1] */ \ /* _a : feed-back coefficients [size: _3 x 1] */ \ IIRFILTSOS() IIRFILTSOS(_create)(TC * _b, \ TC * _a); \ \ /* explicitly set 2nd-order IIR filter coefficients */ \ /* _q : iirfiltsos object */ \ /* _b : feed-forward coefficients [size: _3 x 1] */ \ /* _a : feed-back coefficients [size: _3 x 1] */ \ void IIRFILTSOS(_set_coefficients)(IIRFILTSOS() _q, \ TC * _b, \ TC * _a); \ \ /* destroy iirfiltsos object, freeing all internal memory */ \ void IIRFILTSOS(_destroy)(IIRFILTSOS() _q); \ \ /* print iirfiltsos object properties to stdout */ \ void IIRFILTSOS(_print)(IIRFILTSOS() _q); \ \ /* clear/reset iirfiltsos object internals */ \ void IIRFILTSOS(_reset)(IIRFILTSOS() _q); \ \ /* compute filter output */ \ /* _q : iirfiltsos object */ \ /* _x : input sample */ \ /* _y : output sample pointer */ \ void IIRFILTSOS(_execute)(IIRFILTSOS() _q, \ TI _x, \ TO * _y); \ \ /* compute filter output, direct-form I method */ \ /* _q : iirfiltsos object */ \ /* _x : input sample */ \ /* _y : output sample pointer */ \ void IIRFILTSOS(_execute_df1)(IIRFILTSOS() _q, \ TI _x, \ TO * _y); \ \ /* compute filter output, direct-form II method */ \ /* _q : iirfiltsos object */ \ /* _x : input sample */ \ /* _y : output sample pointer */ \ void IIRFILTSOS(_execute_df2)(IIRFILTSOS() _q, \ TI _x, \ TO * _y); \ \ /* compute and return group delay of filter object */ \ /* _q : filter object */ \ /* _fc : frequency to evaluate */ \ float IIRFILTSOS(_groupdelay)(IIRFILTSOS() _q, \ float _fc); \ LIQUID_IIRFILTSOS_DEFINE_API(LIQUID_IIRFILTSOS_MANGLE_RRRF, float, float, float) LIQUID_IIRFILTSOS_DEFINE_API(LIQUID_IIRFILTSOS_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_IIRFILTSOS_DEFINE_API(LIQUID_IIRFILTSOS_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // FIR Polyphase filter bank // #define LIQUID_FIRPFB_MANGLE_RRRF(name) LIQUID_CONCAT(firpfb_rrrf,name) #define LIQUID_FIRPFB_MANGLE_CRCF(name) LIQUID_CONCAT(firpfb_crcf,name) #define LIQUID_FIRPFB_MANGLE_CCCF(name) LIQUID_CONCAT(firpfb_cccf,name) // Macro: // FIRPFB : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FIRPFB_DEFINE_API(FIRPFB,TO,TC,TI) \ \ /* Finite impulse response (FIR) polyphase filter bank (PFB) */ \ typedef struct FIRPFB(_s) * FIRPFB(); \ \ /* Create firpfb object with _M sub-filter each of length _h_len/_M */ \ /* from an external array of coefficients */ \ /* _M : number of filters in the bank, _M > 1 */ \ /* _h : coefficients, [size: _h_len x 1] */ \ /* _h_len : filter length (multiple of _M), _h_len >= _M */ \ FIRPFB() FIRPFB(_create)(unsigned int _M, \ TC * _h, \ unsigned int _h_len); \ \ /* Create firpfb object using Kaiser-Bessel windowed sinc filter design */ \ /* method, using default values for cut-off frequency and stop-band */ \ /* attenuation. This is equivalent to: */ \ /* FIRPFB(_create_kaiser)(_M, _m, 0.5, 60.0) */ \ /* which creates a Nyquist filter at the appropriate cut-off frequency. */ \ /* _M : number of filters in the bank, _M > 0 */ \ /* _m : filter semi-length [samples], _m > 0 */ \ FIRPFB() FIRPFB(_create_default)(unsigned int _M, \ unsigned int _m); \ \ /* Create firpfb object using Kaiser-Bessel windowed sinc filter design */ \ /* method */ \ /* _M : number of filters in the bank, _M > 0 */ \ /* _m : filter semi-length [samples], _m > 0 */ \ /* _fc : filter normalized cut-off frequency, 0 < _fc < 0.5 */ \ /* _As : filter stop-band suppression [dB], _As > 0 */ \ FIRPFB() FIRPFB(_create_kaiser)(unsigned int _M, \ unsigned int _m, \ float _fc, \ float _As); \ \ /* Create firpfb from square-root Nyquist prototype */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _M : number of filters in the bank, _M > 0 */ \ /* _k : nominal samples/symbol, _k > 1 */ \ /* _m : filter delay [symbols], _m > 0 */ \ /* _beta : rolloff factor, 0 < _beta <= 1 */ \ FIRPFB() FIRPFB(_create_rnyquist)(int _type, \ unsigned int _M, \ unsigned int _k, \ unsigned int _m, \ float _beta); \ \ /* Create from square-root derivative Nyquist prototype */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _M : number of filters in the bank, _M > 0 */ \ /* _k : nominal samples/symbol, _k > 1 */ \ /* _m : filter delay [symbols], _m > 0 */ \ /* _beta : rolloff factor, 0 < _beta <= 1 */ \ FIRPFB() FIRPFB(_create_drnyquist)(int _type, \ unsigned int _M, \ unsigned int _k, \ unsigned int _m, \ float _beta); \ \ /* Re-create firpfb object of potentially a different length with */ \ /* different coefficients. If the length of the filter does not change, */ \ /* not memory reallocation is invoked. */ \ /* _q : original firpfb object */ \ /* _M : number of filters in the bank, _M > 1 */ \ /* _h : coefficients, [size: _h_len x 1] */ \ /* _h_len : filter length (multiple of _M), _h_len >= _M */ \ FIRPFB() FIRPFB(_recreate)(FIRPFB() _q, \ unsigned int _M, \ TC * _h, \ unsigned int _h_len); \ \ /* Destroy firpfb object, freeing all internal memory and destroying */ \ /* all internal objects */ \ void FIRPFB(_destroy)(FIRPFB() _q); \ \ /* Print firpfb object's parameters to stdout */ \ void FIRPFB(_print)(FIRPFB() _q); \ \ /* Set output scaling for filter */ \ /* _q : filter object */ \ /* _scale : scaling factor to apply to each output sample */ \ void FIRPFB(_set_scale)(FIRPFB() _q, \ TC _scale); \ \ /* Get output scaling for filter */ \ /* _q : filter object */ \ /* _scale : scaling factor applied to each output sample */ \ void FIRPFB(_get_scale)(FIRPFB() _q, \ TC * _scale); \ \ /* Reset firpfb object's internal buffer */ \ void FIRPFB(_reset)(FIRPFB() _q); \ \ /* Push sample into filter object's internal buffer */ \ /* _q : filter object */ \ /* _x : single input sample */ \ void FIRPFB(_push)(FIRPFB() _q, \ TI _x); \ \ /* Write a block of samples into object's internal buffer */ \ /* _q : filter object */ \ /* _x : single input sample */ \ void FIRPFB(_write)(FIRPFB() _q, \ TI * _x, \ unsigned int _n); \ \ /* Execute vector dot product on the filter's internal buffer and */ \ /* coefficients using the coefficients from sub-filter at index _i */ \ /* _q : firpfb object */ \ /* _i : index of filter to use */ \ /* _y : pointer to output sample */ \ void FIRPFB(_execute)(FIRPFB() _q, \ unsigned int _i, \ TO * _y); \ \ /* Execute the filter on a block of input samples, all using index _i. */ \ /* In-place operation is permitted (_x and _y may point to the same */ \ /* place in memory) */ \ /* _q : firpfb object */ \ /* _i : index of filter to use */ \ /* _x : pointer to input array [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _y : pointer to output array [size: _n x 1] */ \ void FIRPFB(_execute_block)(FIRPFB() _q, \ unsigned int _i, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_FIRPFB_DEFINE_API(LIQUID_FIRPFB_MANGLE_RRRF, float, float, float) LIQUID_FIRPFB_DEFINE_API(LIQUID_FIRPFB_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_FIRPFB_DEFINE_API(LIQUID_FIRPFB_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Interpolators // // firinterp : finite impulse response interpolator #define LIQUID_FIRINTERP_MANGLE_RRRF(name) LIQUID_CONCAT(firinterp_rrrf,name) #define LIQUID_FIRINTERP_MANGLE_CRCF(name) LIQUID_CONCAT(firinterp_crcf,name) #define LIQUID_FIRINTERP_MANGLE_CCCF(name) LIQUID_CONCAT(firinterp_cccf,name) #define LIQUID_FIRINTERP_DEFINE_API(FIRINTERP,TO,TC,TI) \ \ /* Finite impulse response (FIR) interpolator */ \ typedef struct FIRINTERP(_s) * FIRINTERP(); \ \ /* Create interpolator from external coefficients. Internally the */ \ /* interpolator creates a polyphase filter bank to efficiently realize */ \ /* resampling of the input signal. */ \ /* If the input filter length is not a multiple of the interpolation */ \ /* factor, the object internally pads the coefficients with zeros to */ \ /* compensate. */ \ /* _M : interpolation factor, _M >= 2 */ \ /* _h : filter coefficients, [size: _h_len x 1] */ \ /* _h_len : filter length, _h_len >= _M */ \ FIRINTERP() FIRINTERP(_create)(unsigned int _M, \ TC * _h, \ unsigned int _h_len); \ \ /* Create interpolator from filter prototype prototype (Kaiser-Bessel */ \ /* windowed-sinc function) */ \ /* _M : interpolation factor, _M >= 2 */ \ /* _m : filter delay [symbols], _m >= 1 */ \ /* _As : stop-band attenuation [dB], _As >= 0 */ \ FIRINTERP() FIRINTERP(_create_kaiser)(unsigned int _M, \ unsigned int _m, \ float _As); \ \ /* Create interpolator object from filter prototype */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RCOS) */ \ /* _M : interpolation factor, _M > 1 */ \ /* _m : filter delay (symbols), _m > 0 */ \ /* _beta : excess bandwidth factor, 0 <= _beta <= 1 */ \ /* _dt : fractional sample delay, -1 <= _dt <= 1 */ \ FIRINTERP() FIRINTERP(_create_prototype)(int _type, \ unsigned int _M, \ unsigned int _m, \ float _beta, \ float _dt); \ \ /* Create linear interpolator object */ \ /* _M : interpolation factor, _M > 1 */ \ FIRINTERP() FIRINTERP(_create_linear)(unsigned int _M); \ \ /* Create window interpolator object */ \ /* _M : interpolation factor, _M > 1 */ \ /* _m : filter semi-length, _m > 0 */ \ FIRINTERP() FIRINTERP(_create_window)(unsigned int _M, \ unsigned int _m); \ \ /* Destroy firinterp object, freeing all internal memory */ \ void FIRINTERP(_destroy)(FIRINTERP() _q); \ \ /* Print firinterp object's internal properties to stdout */ \ void FIRINTERP(_print)(FIRINTERP() _q); \ \ /* Reset internal state */ \ void FIRINTERP(_reset)(FIRINTERP() _q); \ \ /* Get interpolation rate */ \ unsigned int FIRINTERP(_get_interp_rate)(FIRINTERP() _q); \ \ /* Get sub-filter length (length of each poly-phase filter) */ \ unsigned int FIRINTERP(_get_sub_len)(FIRINTERP() _q); \ \ /* Set output scaling for interpolator */ \ /* _q : interpolator object */ \ /* _scale : scaling factor to apply to each output sample */ \ void FIRINTERP(_set_scale)(FIRINTERP() _q, \ TC _scale); \ \ /* Get output scaling for interpolator */ \ /* _q : interpolator object */ \ /* _scale : scaling factor to apply to each output sample */ \ void FIRINTERP(_get_scale)(FIRINTERP() _q, \ TC * _scale); \ \ /* Execute interpolation on single input sample and write \(M\) output */ \ /* samples (\(M\) is the interpolation factor) */ \ /* _q : firinterp object */ \ /* _x : input sample */ \ /* _y : output sample array, [size: _M x 1] */ \ void FIRINTERP(_execute)(FIRINTERP() _q, \ TI _x, \ TO * _y); \ \ /* Execute interpolation on block of input samples */ \ /* _q : firinterp object */ \ /* _x : input array, [size: _n x 1] */ \ /* _n : size of input array */ \ /* _y : output sample array, [size: _M*_n x 1] */ \ void FIRINTERP(_execute_block)(FIRINTERP() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_FIRINTERP_DEFINE_API(LIQUID_FIRINTERP_MANGLE_RRRF, float, float, float) LIQUID_FIRINTERP_DEFINE_API(LIQUID_FIRINTERP_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_FIRINTERP_DEFINE_API(LIQUID_FIRINTERP_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // iirinterp : infinite impulse response interpolator #define LIQUID_IIRINTERP_MANGLE_RRRF(name) LIQUID_CONCAT(iirinterp_rrrf,name) #define LIQUID_IIRINTERP_MANGLE_CRCF(name) LIQUID_CONCAT(iirinterp_crcf,name) #define LIQUID_IIRINTERP_MANGLE_CCCF(name) LIQUID_CONCAT(iirinterp_cccf,name) #define LIQUID_IIRINTERP_DEFINE_API(IIRINTERP,TO,TC,TI) \ \ /* Infinite impulse response (IIR) interpolator */ \ typedef struct IIRINTERP(_s) * IIRINTERP(); \ \ /* Create infinite impulse response interpolator from external */ \ /* coefficients. */ \ /* Note that the number of feed-forward and feed-back coefficients do */ \ /* not need to be equal, but they do need to be non-zero. */ \ /* Furthermore, the first feed-back coefficient \(a_0\) cannot be */ \ /* equal to zero, otherwise the filter will be invalid as this value is */ \ /* factored out from all coefficients. */ \ /* For stability reasons the number of coefficients should reasonably */ \ /* not exceed about 8 for single-precision floating-point. */ \ /* _M : interpolation factor, _M >= 2 */ \ /* _b : feed-forward coefficients (numerator), [size: _nb x 1] */ \ /* _nb : number of feed-forward coefficients, _nb > 0 */ \ /* _a : feed-back coefficients (denominator), [size: _na x 1] */ \ /* _na : number of feed-back coefficients, _na > 0 */ \ IIRINTERP() IIRINTERP(_create)(unsigned int _M, \ TC * _b, \ unsigned int _nb, \ TC * _a, \ unsigned int _na); \ \ /* Create interpolator object with default Butterworth prototype */ \ /* _M : interpolation factor, _M >= 2 */ \ /* _order : filter order, _order > 0 */ \ IIRINTERP() IIRINTERP(_create_default)(unsigned int _M, \ unsigned int _order); \ \ /* Create IIR interpolator from prototype */ \ /* _M : interpolation factor, _M >= 2 */ \ /* _ftype : filter type (e.g. LIQUID_IIRDES_BUTTER) */ \ /* _btype : band type (e.g. LIQUID_IIRDES_BANDPASS) */ \ /* _format : coefficients format (e.g. LIQUID_IIRDES_SOS) */ \ /* _order : filter order, _order > 0 */ \ /* _fc : low-pass prototype cut-off frequency, 0 <= _fc <= 0.5 */ \ /* _f0 : center frequency (band-pass, band-stop), 0 <= _f0 <= 0.5 */ \ /* _Ap : pass-band ripple in dB, _Ap > 0 */ \ /* _As : stop-band ripple in dB, _As > 0 */ \ IIRINTERP() IIRINTERP(_create_prototype)( \ unsigned int _M, \ liquid_iirdes_filtertype _ftype, \ liquid_iirdes_bandtype _btype, \ liquid_iirdes_format _format, \ unsigned int _order, \ float _fc, \ float _f0, \ float _Ap, \ float _As); \ \ /* Destroy interpolator object and free internal memory */ \ void IIRINTERP(_destroy)(IIRINTERP() _q); \ \ /* Print interpolator object internals to stdout */ \ void IIRINTERP(_print)(IIRINTERP() _q); \ \ /* Reset interpolator object */ \ void IIRINTERP(_reset)(IIRINTERP() _q); \ \ /* Execute interpolation on single input sample and write \(M\) output */ \ /* samples (\(M\) is the interpolation factor) */ \ /* _q : iirinterp object */ \ /* _x : input sample */ \ /* _y : output sample array, [size: _M x 1] */ \ void IIRINTERP(_execute)(IIRINTERP() _q, \ TI _x, \ TO * _y); \ \ /* Execute interpolation on block of input samples */ \ /* _q : iirinterp object */ \ /* _x : input array, [size: _n x 1] */ \ /* _n : size of input array */ \ /* _y : output sample array, [size: _M*_n x 1] */ \ void IIRINTERP(_execute_block)(IIRINTERP() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* Compute and return group delay of object */ \ /* _q : filter object */ \ /* _fc : frequency to evaluate */ \ float IIRINTERP(_groupdelay)(IIRINTERP() _q, \ float _fc); \ LIQUID_IIRINTERP_DEFINE_API(LIQUID_IIRINTERP_MANGLE_RRRF, float, float, float) LIQUID_IIRINTERP_DEFINE_API(LIQUID_IIRINTERP_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_IIRINTERP_DEFINE_API(LIQUID_IIRINTERP_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Decimators // // firdecim : finite impulse response decimator #define LIQUID_FIRDECIM_MANGLE_RRRF(name) LIQUID_CONCAT(firdecim_rrrf,name) #define LIQUID_FIRDECIM_MANGLE_CRCF(name) LIQUID_CONCAT(firdecim_crcf,name) #define LIQUID_FIRDECIM_MANGLE_CCCF(name) LIQUID_CONCAT(firdecim_cccf,name) #define LIQUID_FIRDECIM_DEFINE_API(FIRDECIM,TO,TC,TI) \ \ /* Finite impulse response (FIR) decimator */ \ typedef struct FIRDECIM(_s) * FIRDECIM(); \ \ /* Create decimator from external coefficients */ \ /* _M : decimation factor, _M >= 2 */ \ /* _h : filter coefficients, [size: _h_len x 1] */ \ /* _h_len : filter length, _h_len >= _M */ \ FIRDECIM() FIRDECIM(_create)(unsigned int _M, \ TC * _h, \ unsigned int _h_len); \ \ /* Create decimator from filter prototype prototype (Kaiser-Bessel */ \ /* windowed-sinc function) */ \ /* _M : decimation factor, _M >= 2 */ \ /* _m : filter delay [symbols], _m >= 1 */ \ /* _As : stop-band attenuation [dB], _As >= 0 */ \ FIRDECIM() FIRDECIM(_create_kaiser)(unsigned int _M, \ unsigned int _m, \ float _As); \ \ /* Create decimator object from filter prototype */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RCOS) */ \ /* _M : interpolation factor, _M > 1 */ \ /* _m : filter delay (symbols), _m > 0 */ \ /* _beta : excess bandwidth factor, 0 <= _beta <= 1 */ \ /* _dt : fractional sample delay, -1 <= _dt <= 1 */ \ FIRDECIM() FIRDECIM(_create_prototype)(int _type, \ unsigned int _M, \ unsigned int _m, \ float _beta, \ float _dt); \ \ /* Destroy decimator object, freeing all internal memory */ \ void FIRDECIM(_destroy)(FIRDECIM() _q); \ \ /* Print decimator object propreties to stdout */ \ void FIRDECIM(_print)(FIRDECIM() _q); \ \ /* Reset decimator object internal state */ \ void FIRDECIM(_reset)(FIRDECIM() _q); \ \ /* Get decimation rate */ \ unsigned int FIRDECIM(_get_decim_rate)(FIRDECIM() _q); \ \ /* Set output scaling for decimator */ \ /* _q : decimator object */ \ /* _scale : scaling factor to apply to each output sample */ \ void FIRDECIM(_set_scale)(FIRDECIM() _q, \ TC _scale); \ \ /* Get output scaling for decimator */ \ /* _q : decimator object */ \ /* _scale : scaling factor to apply to each output sample */ \ void FIRDECIM(_get_scale)(FIRDECIM() _q, \ TC * _scale); \ \ /* Execute decimator on _M input samples */ \ /* _q : decimator object */ \ /* _x : input samples, [size: _M x 1] */ \ /* _y : output sample pointer */ \ void FIRDECIM(_execute)(FIRDECIM() _q, \ TI * _x, \ TO * _y); \ \ /* Execute decimator on block of _n*_M input samples */ \ /* _q : decimator object */ \ /* _x : input array, [size: _n*_M x 1] */ \ /* _n : number of _output_ samples */ \ /* _y : output array, [_size: _n x 1] */ \ void FIRDECIM(_execute_block)(FIRDECIM() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_FIRDECIM_DEFINE_API(LIQUID_FIRDECIM_MANGLE_RRRF, float, float, float) LIQUID_FIRDECIM_DEFINE_API(LIQUID_FIRDECIM_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_FIRDECIM_DEFINE_API(LIQUID_FIRDECIM_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // iirdecim : infinite impulse response decimator #define LIQUID_IIRDECIM_MANGLE_RRRF(name) LIQUID_CONCAT(iirdecim_rrrf,name) #define LIQUID_IIRDECIM_MANGLE_CRCF(name) LIQUID_CONCAT(iirdecim_crcf,name) #define LIQUID_IIRDECIM_MANGLE_CCCF(name) LIQUID_CONCAT(iirdecim_cccf,name) #define LIQUID_IIRDECIM_DEFINE_API(IIRDECIM,TO,TC,TI) \ \ /* Infinite impulse response (IIR) decimator */ \ typedef struct IIRDECIM(_s) * IIRDECIM(); \ \ /* Create infinite impulse response decimator from external */ \ /* coefficients. */ \ /* Note that the number of feed-forward and feed-back coefficients do */ \ /* not need to be equal, but they do need to be non-zero. */ \ /* Furthermore, the first feed-back coefficient \(a_0\) cannot be */ \ /* equal to zero, otherwise the filter will be invalid as this value is */ \ /* factored out from all coefficients. */ \ /* For stability reasons the number of coefficients should reasonably */ \ /* not exceed about 8 for single-precision floating-point. */ \ /* _M : decimation factor, _M >= 2 */ \ /* _b : feed-forward coefficients (numerator), [size: _nb x 1] */ \ /* _nb : number of feed-forward coefficients, _nb > 0 */ \ /* _a : feed-back coefficients (denominator), [size: _na x 1] */ \ /* _na : number of feed-back coefficients, _na > 0 */ \ IIRDECIM() IIRDECIM(_create)(unsigned int _M, \ TC * _b, \ unsigned int _nb, \ TC * _a, \ unsigned int _na); \ \ /* Create decimator object with default Butterworth prototype */ \ /* _M : decimation factor, _M >= 2 */ \ /* _order : filter order, _order > 0 */ \ IIRDECIM() IIRDECIM(_create_default)(unsigned int _M, \ unsigned int _order); \ \ /* Create IIR decimator from prototype */ \ /* _M : decimation factor, _M >= 2 */ \ /* _ftype : filter type (e.g. LIQUID_IIRDES_BUTTER) */ \ /* _btype : band type (e.g. LIQUID_IIRDES_BANDPASS) */ \ /* _format : coefficients format (e.g. LIQUID_IIRDES_SOS) */ \ /* _order : filter order, _order > 0 */ \ /* _fc : low-pass prototype cut-off frequency, 0 <= _fc <= 0.5 */ \ /* _f0 : center frequency (band-pass, band-stop), 0 <= _f0 <= 0.5 */ \ /* _Ap : pass-band ripple in dB, _Ap > 0 */ \ /* _As : stop-band ripple in dB, _As > 0 */ \ IIRDECIM() IIRDECIM(_create_prototype)( \ unsigned int _M, \ liquid_iirdes_filtertype _ftype, \ liquid_iirdes_bandtype _btype, \ liquid_iirdes_format _format, \ unsigned int _order, \ float _fc, \ float _f0, \ float _Ap, \ float _As); \ \ /* Destroy decimator object and free internal memory */ \ void IIRDECIM(_destroy)(IIRDECIM() _q); \ \ /* Print decimator object internals */ \ void IIRDECIM(_print)(IIRDECIM() _q); \ \ /* Reset decimator object */ \ void IIRDECIM(_reset)(IIRDECIM() _q); \ \ /* Execute decimator on _M input samples */ \ /* _q : decimator object */ \ /* _x : input samples, [size: _M x 1] */ \ /* _y : output sample pointer */ \ void IIRDECIM(_execute)(IIRDECIM() _q, \ TI * _x, \ TO * _y); \ \ /* Execute decimator on block of _n*_M input samples */ \ /* _q : decimator object */ \ /* _x : input array, [size: _n*_M x 1] */ \ /* _n : number of _output_ samples */ \ /* _y : output array, [_sze: _n x 1] */ \ void IIRDECIM(_execute_block)(IIRDECIM() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* Compute and return group delay of object */ \ /* _q : filter object */ \ /* _fc : frequency to evaluate */ \ float IIRDECIM(_groupdelay)(IIRDECIM() _q, \ float _fc); \ LIQUID_IIRDECIM_DEFINE_API(LIQUID_IIRDECIM_MANGLE_RRRF, float, float, float) LIQUID_IIRDECIM_DEFINE_API(LIQUID_IIRDECIM_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_IIRDECIM_DEFINE_API(LIQUID_IIRDECIM_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Half-band resampler // #define LIQUID_RESAMP2_MANGLE_RRRF(name) LIQUID_CONCAT(resamp2_rrrf,name) #define LIQUID_RESAMP2_MANGLE_CRCF(name) LIQUID_CONCAT(resamp2_crcf,name) #define LIQUID_RESAMP2_MANGLE_CCCF(name) LIQUID_CONCAT(resamp2_cccf,name) #define LIQUID_RESAMP2_DEFINE_API(RESAMP2,TO,TC,TI) \ \ /* Half-band resampler, implemented as a dyadic (half-band) polyphase */ \ /* filter bank for interpolation, decimation, synthesis, and analysis. */ \ typedef struct RESAMP2(_s) * RESAMP2(); \ \ /* Create half-band resampler from design prototype. */ \ /* _m : filter semi-length (h_len = 4*m+1), _m >= 2 */ \ /* _f0 : filter center frequency, -0.5 <= _f0 <= 0.5 */ \ /* _As : stop-band attenuation [dB], _As > 0 */ \ RESAMP2() RESAMP2(_create)(unsigned int _m, \ float _f0, \ float _As); \ \ /* Re-create half-band resampler with new properties */ \ /* _q : original half-band resampler object */ \ /* _m : filter semi-length (h_len = 4*m+1), _m >= 2 */ \ /* _f0 : filter center frequency, -0.5 <= _f0 <= 0.5 */ \ /* _As : stop-band attenuation [dB], _As > 0 */ \ RESAMP2() RESAMP2(_recreate)(RESAMP2() _q, \ unsigned int _m, \ float _f0, \ float _As); \ \ /* Destroy resampler, freeing all internally-allocated memory */ \ void RESAMP2(_destroy)(RESAMP2() _q); \ \ /* print resampler object's internals to stdout */ \ void RESAMP2(_print)(RESAMP2() _q); \ \ /* Reset internal buffer */ \ void RESAMP2(_reset)(RESAMP2() _q); \ \ /* Get resampler filter delay (semi-length m) */ \ unsigned int RESAMP2(_get_delay)(RESAMP2() _q); \ \ /* Set output scaling for resampler */ \ /* _q : resampler object */ \ /* _scale : scaling factor to apply to each output sample */ \ int RESAMP2(_set_scale)(RESAMP2() _q, \ TC _scale); \ \ /* Get output scaling for resampler */ \ /* _q : resampler object */ \ /* _scale : scaling factor applied to each output sample */ \ void RESAMP2(_get_scale)(RESAMP2() _q, \ TC * _scale); \ \ /* Execute resampler as half-band filter for a single input sample */ \ /* \(x\) where \(y_0\) is the output of the effective low-pass filter, */ \ /* and \(y_1\) is the output of the effective high-pass filter. */ \ /* _q : resampler object */ \ /* _x : input sample */ \ /* _y0 : output sample pointer (low frequency) */ \ /* _y1 : output sample pointer (high frequency) */ \ void RESAMP2(_filter_execute)(RESAMP2() _q, \ TI _x, \ TO * _y0, \ TO * _y1); \ \ /* Execute resampler as half-band analysis filterbank on a pair of */ \ /* sequential time-domain input samples. */ \ /* The decimated outputs of the low- and high-pass equivalent filters */ \ /* are stored in \(y_0\) and \(y_1\), respectively. */ \ /* _q : resampler object */ \ /* _x : input array, [size: 2 x 1] */ \ /* _y : output array, [size: 2 x 1] */ \ void RESAMP2(_analyzer_execute)(RESAMP2() _q, \ TI * _x, \ TO * _y); \ \ /* Execute resampler as half-band synthesis filterbank on a pair of */ \ /* input samples. The low- and high-pass input samples are provided by */ \ /* \(x_0\) and \(x_1\), respectively. The sequential time-domain output */ \ /* samples are stored in \(y_0\) and \(y_1\). */ \ /* _q : resampler object */ \ /* _x : input array [size: 2 x 1] */ \ /* _y : output array [size: 2 x 1] */ \ void RESAMP2(_synthesizer_execute)(RESAMP2() _q, \ TI * _x, \ TO * _y); \ \ /* Execute resampler as half-band decimator on a pair of sequential */ \ /* time-domain input samples. */ \ /* _q : resampler object */ \ /* _x : input array [size: 2 x 1] */ \ /* _y : output sample pointer */ \ void RESAMP2(_decim_execute)(RESAMP2() _q, \ TI * _x, \ TO * _y); \ \ /* Execute resampler as half-band interpolator on a single input sample */ \ /* _q : resampler object */ \ /* _x : input sample */ \ /* _y : output array [size: 2 x 1] */ \ void RESAMP2(_interp_execute)(RESAMP2() _q, \ TI _x, \ TO * _y); \ LIQUID_RESAMP2_DEFINE_API(LIQUID_RESAMP2_MANGLE_RRRF, float, float, float) LIQUID_RESAMP2_DEFINE_API(LIQUID_RESAMP2_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_RESAMP2_DEFINE_API(LIQUID_RESAMP2_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Rational resampler // #define LIQUID_RRESAMP_MANGLE_RRRF(name) LIQUID_CONCAT(rresamp_rrrf,name) #define LIQUID_RRESAMP_MANGLE_CRCF(name) LIQUID_CONCAT(rresamp_crcf,name) #define LIQUID_RRESAMP_MANGLE_CCCF(name) LIQUID_CONCAT(rresamp_cccf,name) #define LIQUID_RRESAMP_DEFINE_API(RRESAMP,TO,TC,TI) \ \ /* Rational rate resampler, implemented as a polyphase filterbank */ \ typedef struct RRESAMP(_s) * RRESAMP(); \ \ /* Create rational-rate resampler object from external coeffcients to */ \ /* resample at an exact rate P/Q. */ \ /* Note that to preserve the input filter coefficients, the greatest */ \ /* common divisor (gcd) is not removed internally from _P and _Q when */ \ /* this method is called. */ \ /* _P : interpolation factor, P > 0 */ \ /* _Q : decimation factor, Q > 0 */ \ /* _m : filter semi-length (delay), 0 < _m */ \ /* _h : filter coefficients, [size: 2*_P*_m x 1] */ \ RRESAMP() RRESAMP(_create)(unsigned int _P, \ unsigned int _Q, \ unsigned int _m, \ TC * _h); \ \ /* Create rational-rate resampler object from filter prototype to */ \ /* resample at an exact rate P/Q. */ \ /* Note that because the filter coefficients are computed internally */ \ /* here, the greatest common divisor (gcd) from _P and _Q is internally */ \ /* removed to improve speed. */ \ /* _P : interpolation factor, P > 0 */ \ /* _Q : decimation factor, Q > 0 */ \ /* _m : filter semi-length (delay), 0 < _m */ \ /* _bw : filter bandwidth relative to sample rate, 0 < _bw <= 0.5 */ \ /* _As : filter stop-band attenuation [dB], 0 < _As */ \ RRESAMP() RRESAMP(_create_kaiser)(unsigned int _P, \ unsigned int _Q, \ unsigned int _m, \ float _bw, \ float _As); \ \ /* Create rational-rate resampler object from filter prototype to */ \ /* resample at an exact rate P/Q. */ \ /* Note that because the filter coefficients are computed internally */ \ /* here, the greatest common divisor (gcd) from _P and _Q is internally */ \ /* removed to improve speed. */ \ RRESAMP() RRESAMP(_create_prototype)(int _type, \ unsigned int _P, \ unsigned int _Q, \ unsigned int _m, \ float _beta); \ \ /* Create rational resampler object with a specified resampling rate of */ \ /* exactly P/Q with default parameters. This is a simplified method to */ \ /* provide a basic resampler with a baseline set of parameters, */ \ /* abstracting away some of the complexities with the filterbank */ \ /* design. */ \ /* The default parameters are */ \ /* m = 12 (filter semi-length), */ \ /* bw = 0.5 (filter bandwidth), and */ \ /* As = 60 dB (filter stop-band attenuation) */ \ /* _P : interpolation factor, P > 0 */ \ /* _Q : decimation factor, Q > 0 */ \ RRESAMP() RRESAMP(_create_default)(unsigned int _P, \ unsigned int _Q); \ \ /* Destroy resampler object, freeing all internal memory */ \ void RRESAMP(_destroy)(RRESAMP() _q); \ \ /* Print resampler object internals to stdout */ \ void RRESAMP(_print)(RRESAMP() _q); \ \ /* Reset resampler object internals */ \ void RRESAMP(_reset)(RRESAMP() _q); \ \ /* Set output scaling for filter, default: \( 2 w \sqrt{P/Q} \) */ \ /* _q : resampler object */ \ /* _scale : scaling factor to apply to each output sample */ \ void RRESAMP(_set_scale)(RRESAMP() _q, \ TC _scale); \ \ /* Get output scaling for filter */ \ /* _q : resampler object */ \ /* _scale : scaling factor to apply to each output sample */ \ void RRESAMP(_get_scale)(RRESAMP() _q, \ TC * _scale); \ \ /* Get resampler delay (filter semi-length \(m\)) */ \ unsigned int RRESAMP(_get_delay)(RRESAMP() _q); \ \ /* Get original interpolation factor \(P\) when object was created */ \ /* before removing greatest common divisor */ \ unsigned int RRESAMP(_get_P)(RRESAMP() _q); \ \ /* Get internal interpolation factor of resampler, \(P\), after */ \ /* removing greatest common divisor */ \ unsigned int RRESAMP(_get_interp)(RRESAMP() _q); \ \ /* Get original decimation factor \(Q\) when object was created */ \ /* before removing greatest common divisor */ \ unsigned int RRESAMP(_get_Q)(RRESAMP() _q); \ \ /* Get internal decimation factor of resampler, \(Q\), after removing */ \ /* greatest common divisor */ \ unsigned int RRESAMP(_get_decim)(RRESAMP() _q); \ \ /* Get block length (e.g. greatest common divisor) between original P */ \ /* and Q values */ \ unsigned int RRESAMP(_get_block_len)(RRESAMP() _q); \ \ /* Get rate of resampler, \(r = P/Q\) */ \ float RRESAMP(_get_rate)(RRESAMP() _q); \ \ /* Write \(Q\) input samples (after removing greatest common divisor) */ \ /* into buffer, but do not compute output. This effectively updates the */ \ /* internal state of the resampler. */ \ /* _q : resamp object */ \ /* _buf : input sample array, [size: Q x 1] */ \ void RRESAMP(_write)(RRESAMP() _q, \ TI * _buf); \ \ /* Execute rational-rate resampler on a block of input samples and */ \ /* store the resulting samples in the output array. */ \ /* Note that the size of the input and output buffers correspond to the */ \ /* values of P and Q passed when the object was created, even if they */ \ /* share a common divisor. Internally the rational resampler reduces P */ \ /* and Q by their greatest commmon denominator to reduce processing; */ \ /* however sometimes it is convenienct to create the object based on */ \ /* expected output/input block sizes. This expectation is preserved. So */ \ /* if an object is created with P=80 and Q=72, the object will */ \ /* internally set P=10 and Q=9 (with a g.c.d of 8); however when */ \ /* "execute" is called the resampler will still expect an input buffer */ \ /* of 72 and an output buffer of 80. */ \ /* _q : resamp object */ \ /* _x : input sample array, [size: Q x 1] */ \ /* _y : output sample array [size: P x 1] */ \ void RRESAMP(_execute)(RRESAMP() _q, \ TI * _x, \ TO * _y); \ \ /* Execute on a block of samples */ \ /* _q : resamp object */ \ /* _x : input sample array, [size: Q*n x 1] */ \ /* _n : block size */ \ /* _y : output sample array [size: P*n x 1] */ \ void RRESAMP(_execute_block)(RRESAMP() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_RRESAMP_DEFINE_API(LIQUID_RRESAMP_MANGLE_RRRF, float, float, float) LIQUID_RRESAMP_DEFINE_API(LIQUID_RRESAMP_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_RRESAMP_DEFINE_API(LIQUID_RRESAMP_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Arbitrary resampler // #define LIQUID_RESAMP_MANGLE_RRRF(name) LIQUID_CONCAT(resamp_rrrf,name) #define LIQUID_RESAMP_MANGLE_CRCF(name) LIQUID_CONCAT(resamp_crcf,name) #define LIQUID_RESAMP_MANGLE_CCCF(name) LIQUID_CONCAT(resamp_cccf,name) #define LIQUID_RESAMP_DEFINE_API(RESAMP,TO,TC,TI) \ \ /* Arbitrary rate resampler, implemented as a polyphase filterbank */ \ typedef struct RESAMP(_s) * RESAMP(); \ \ /* Create arbitrary resampler object from filter prototype */ \ /* _rate : arbitrary resampling rate, 0 < _rate */ \ /* _m : filter semi-length (delay), 0 < _m */ \ /* _fc : filter cutoff frequency, 0 < _fc < 0.5 */ \ /* _As : filter stop-band attenuation [dB], 0 < _As */ \ /* _npfb : number of filters in the bank, 0 < _npfb */ \ RESAMP() RESAMP(_create)(float _rate, \ unsigned int _m, \ float _fc, \ float _As, \ unsigned int _npfb); \ \ /* Create arbitrary resampler object with a specified input resampling */ \ /* rate and default parameters. This is a simplified method to provide */ \ /* a basic resampler with a baseline set of parameters, abstracting */ \ /* away some of the complexities with the filterbank design. */ \ /* The default parameters are */ \ /* m = 7 (filter semi-length), */ \ /* fc = min(0.49,_rate/2) (filter cutoff frequency), */ \ /* As = 60 dB (filter stop-band attenuation), and */ \ /* npfb = 64 (number of filters in the bank). */ \ /* _rate : arbitrary resampling rate, 0 < _rate */ \ RESAMP() RESAMP(_create_default)(float _rate); \ \ /* Destroy arbitrary resampler object, freeing all internal memory */ \ void RESAMP(_destroy)(RESAMP() _q); \ \ /* Print resamp object internals to stdout */ \ void RESAMP(_print)(RESAMP() _q); \ \ /* Reset resamp object internals */ \ void RESAMP(_reset)(RESAMP() _q); \ \ /* Get resampler delay (filter semi-length \(m\)) */ \ unsigned int RESAMP(_get_delay)(RESAMP() _q); \ \ /* Set rate of arbitrary resampler */ \ /* _q : resampling object */ \ /* _rate : new sampling rate, _rate > 0 */ \ void RESAMP(_set_rate)(RESAMP() _q, \ float _rate); \ \ /* Get rate of arbitrary resampler */ \ float RESAMP(_get_rate)(RESAMP() _q); \ \ /* adjust rate of arbitrary resampler */ \ /* _q : resampling object */ \ /* _gamma : rate adjustment factor: rate <- rate * gamma, _gamma > 0 */ \ void RESAMP(_adjust_rate)(RESAMP() _q, \ float _gamma); \ \ /* Set resampling timing phase */ \ /* _q : resampling object */ \ /* _tau : sample timing phase, -1 <= _tau <= 1 */ \ void RESAMP(_set_timing_phase)(RESAMP() _q, \ float _tau); \ \ /* Adjust resampling timing phase */ \ /* _q : resampling object */ \ /* _delta : sample timing adjustment, -1 <= _delta <= 1 */ \ void RESAMP(_adjust_timing_phase)(RESAMP() _q, \ float _delta); \ \ /* Execute arbitrary resampler on a single input sample and store the */ \ /* resulting samples in the output array. The number of output samples */ \ /* is depenent upon the resampling rate but will be at most */ \ /* \( \lceil{ r \rceil} \) samples. */ \ /* _q : resamp object */ \ /* _x : single input sample */ \ /* _y : output sample array (pointer) */ \ /* _num_written : number of samples written to _y */ \ void RESAMP(_execute)(RESAMP() _q, \ TI _x, \ TO * _y, \ unsigned int * _num_written); \ \ /* Execute arbitrary resampler on a block of input samples and store */ \ /* the resulting samples in the output array. The number of output */ \ /* samples is depenent upon the resampling rate and the number of input */ \ /* samples but will be at most \( \lceil{ r n_x \rceil} \) samples. */ \ /* _q : resamp object */ \ /* _x : input buffer, [size: _nx x 1] */ \ /* _nx : input buffer */ \ /* _y : output sample array (pointer) */ \ /* _ny : number of samples written to _y */ \ void RESAMP(_execute_block)(RESAMP() _q, \ TI * _x, \ unsigned int _nx, \ TO * _y, \ unsigned int * _ny); \ LIQUID_RESAMP_DEFINE_API(LIQUID_RESAMP_MANGLE_RRRF, float, float, float) LIQUID_RESAMP_DEFINE_API(LIQUID_RESAMP_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_RESAMP_DEFINE_API(LIQUID_RESAMP_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Multi-stage half-band resampler // // resampling type (interpolator/decimator) typedef enum { LIQUID_RESAMP_INTERP=0, // interpolator LIQUID_RESAMP_DECIM, // decimator } liquid_resamp_type; #define LIQUID_MSRESAMP2_MANGLE_RRRF(name) LIQUID_CONCAT(msresamp2_rrrf,name) #define LIQUID_MSRESAMP2_MANGLE_CRCF(name) LIQUID_CONCAT(msresamp2_crcf,name) #define LIQUID_MSRESAMP2_MANGLE_CCCF(name) LIQUID_CONCAT(msresamp2_cccf,name) #define LIQUID_MSRESAMP2_DEFINE_API(MSRESAMP2,TO,TC,TI) \ \ /* Multi-stage half-band resampler, implemented as cascaded dyadic */ \ /* (half-band) polyphase filter banks for interpolation and decimation. */ \ typedef struct MSRESAMP2(_s) * MSRESAMP2(); \ \ /* Create multi-stage half-band resampler as either decimator or */ \ /* interpolator. */ \ /* _type : resampler type (e.g. LIQUID_RESAMP_DECIM) */ \ /* _num_stages : number of resampling stages, _num_stages <= 16 */ \ /* _fc : filter cut-off frequency, 0 < _fc < 0.5 */ \ /* _f0 : filter center frequency (set to zero) */ \ /* _As : stop-band attenuation [dB], _As > 0 */ \ MSRESAMP2() MSRESAMP2(_create)(int _type, \ unsigned int _num_stages, \ float _fc, \ float _f0, \ float _As); \ \ /* Destroy multi-stage half-band resampler, freeing all internal memory */ \ void MSRESAMP2(_destroy)(MSRESAMP2() _q); \ \ /* Print msresamp object internals to stdout */ \ void MSRESAMP2(_print)(MSRESAMP2() _q); \ \ /* Reset msresamp object internal state */ \ void MSRESAMP2(_reset)(MSRESAMP2() _q); \ \ /* Get multi-stage half-band resampling rate */ \ float MSRESAMP2(_get_rate)(MSRESAMP2() _q); \ \ /* Get number of half-band resampling stages in object */ \ unsigned int MSRESAMP2(_get_num_stages)(MSRESAMP2() _q); \ \ /* Get resampling type (LIQUID_RESAMP_DECIM, LIQUID_RESAMP_INTERP) */ \ int MSRESAMP2(_get_type)(MSRESAMP2() _q); \ \ /* Get group delay (number of output samples) */ \ float MSRESAMP2(_get_delay)(MSRESAMP2() _q); \ \ /* Execute multi-stage resampler, M = 2^num_stages */ \ /* LIQUID_RESAMP_INTERP: input: 1, output: M */ \ /* LIQUID_RESAMP_DECIM: input: M, output: 1 */ \ /* _q : msresamp object */ \ /* _x : input sample array */ \ /* _y : output sample array */ \ void MSRESAMP2(_execute)(MSRESAMP2() _q, \ TI * _x, \ TO * _y); \ LIQUID_MSRESAMP2_DEFINE_API(LIQUID_MSRESAMP2_MANGLE_RRRF, float, float, float) LIQUID_MSRESAMP2_DEFINE_API(LIQUID_MSRESAMP2_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_MSRESAMP2_DEFINE_API(LIQUID_MSRESAMP2_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Multi-stage arbitrary resampler // #define LIQUID_MSRESAMP_MANGLE_RRRF(name) LIQUID_CONCAT(msresamp_rrrf,name) #define LIQUID_MSRESAMP_MANGLE_CRCF(name) LIQUID_CONCAT(msresamp_crcf,name) #define LIQUID_MSRESAMP_MANGLE_CCCF(name) LIQUID_CONCAT(msresamp_cccf,name) #define LIQUID_MSRESAMP_DEFINE_API(MSRESAMP,TO,TC,TI) \ \ /* Multi-stage half-band resampler, implemented as cascaded dyadic */ \ /* (half-band) polyphase filter banks followed by an arbitrary rate */ \ /* resampler for interpolation and decimation. */ \ typedef struct MSRESAMP(_s) * MSRESAMP(); \ \ /* Create multi-stage arbitrary resampler */ \ /* _r : resampling rate (output/input), _r > 0 */ \ /* _As : stop-band attenuation [dB], _As > 0 */ \ MSRESAMP() MSRESAMP(_create)(float _r, \ float _As); \ \ /* Destroy multi-stage arbitrary resampler */ \ void MSRESAMP(_destroy)(MSRESAMP() _q); \ \ /* Print msresamp object internals to stdout */ \ void MSRESAMP(_print)(MSRESAMP() _q); \ \ /* Reset msresamp object internal state */ \ void MSRESAMP(_reset)(MSRESAMP() _q); \ \ /* Get filter delay (output samples) */ \ float MSRESAMP(_get_delay)(MSRESAMP() _q); \ \ /* get overall resampling rate */ \ float MSRESAMP(_get_rate)(MSRESAMP() _q); \ \ /* Execute multi-stage resampler on one or more input samples. */ \ /* The number of output samples is dependent upon the resampling rate */ \ /* and the number of input samples. In general it is good practice to */ \ /* allocate at least \( \lceil{ 1 + 2 r n_x \rceil} \) samples in the */ \ /* output array to avoid overflows. */ \ /* _q : msresamp object */ \ /* _x : input sample array, [size: _nx x 1] */ \ /* _nx : input sample array size */ \ /* _y : pointer to output array for storing result */ \ /* _ny : number of samples written to _y */ \ void MSRESAMP(_execute)(MSRESAMP() _q, \ TI * _x, \ unsigned int _nx, \ TO * _y, \ unsigned int * _ny); \ LIQUID_MSRESAMP_DEFINE_API(LIQUID_MSRESAMP_MANGLE_RRRF, float, float, float) LIQUID_MSRESAMP_DEFINE_API(LIQUID_MSRESAMP_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_MSRESAMP_DEFINE_API(LIQUID_MSRESAMP_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Direct digital [up/down] synthesizer // #define DDS_MANGLE_CCCF(name) LIQUID_CONCAT(dds_cccf,name) #define LIQUID_DDS_DEFINE_API(DDS,TO,TC,TI) \ typedef struct DDS(_s) * DDS(); \ \ /* Create digital synthesizer object */ \ /* _num_stages : number of half-band stages, _num_stages > 0 */ \ /* _fc : signal relative center frequency, _fc in [-0.5,0.5] */ \ /* _bw : signal relative bandwidth, _bw in (0,1) */ \ /* _As : filter stop-band attenuation (dB), _As > 0 */ \ DDS() DDS(_create)(unsigned int _num_stages, \ float _fc, \ float _bw, \ float _As); \ \ /* Destroy digital synthesizer object */ \ int DDS(_destroy)(DDS() _q); \ \ /* Print synthesizer object internals */ \ int DDS(_print)(DDS() _q); \ \ /* Reset synthesizer object internals */ \ int DDS(_reset)(DDS() _q); \ \ /* Get number of half-band states in DDS object */ \ unsigned int DDS(_get_num_stages)(DDS() _q); \ \ /* Get delay (samples) when running as interpolator */ \ unsigned int DDS(_get_delay_interp)(DDS() _q); \ \ /* Get delay (samples) when running as decimator */ \ float DDS(_get_delay_decim)(DDS() _q); \ \ /* Run DDS object as decimator */ \ /* _q : synthesizer object */ \ /* _x : input data array, [size: (1<<_num_stages) x 1] */ \ /* _y : output sample */ \ int DDS(_decim_execute)(DDS() _q, \ TI * _x, \ TO * _y); \ \ /* Run DDS object as interpolator */ \ /* _q : synthesizer object */ \ /* _x : input sample */ \ /* _y : output data array, [size: (1<<_num_stages) x 1] */ \ int DDS(_interp_execute)(DDS() _q, \ TI _x, \ TO * _y); \ LIQUID_DDS_DEFINE_API(DDS_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Symbol timing recovery (symbol synchronizer) // #define LIQUID_SYMSYNC_MANGLE_RRRF(name) LIQUID_CONCAT(symsync_rrrf,name) #define LIQUID_SYMSYNC_MANGLE_CRCF(name) LIQUID_CONCAT(symsync_crcf,name) #define LIQUID_SYMSYNC_DEFINE_API(SYMSYNC,TO,TC,TI) \ \ /* Multi-rate symbol synchronizer for symbol timing recovery. */ \ typedef struct SYMSYNC(_s) * SYMSYNC(); \ \ /* Create synchronizer object from external coefficients */ \ /* _k : samples per symbol, _k >= 2 */ \ /* _M : number of filters in the bank, _M > 0 */ \ /* _h : matched filter coefficients, [size: _h_len x 1] */ \ /* _h_len : length of matched filter; \( h_{len} = 2 k m + 1 \) */ \ SYMSYNC() SYMSYNC(_create)(unsigned int _k, \ unsigned int _M, \ TC * _h, \ unsigned int _h_len); \ \ /* Create square-root Nyquist symbol synchronizer from prototype */ \ /* _type : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _k : samples/symbol, _k >= 2 */ \ /* _m : symbol delay, _m > 0 */ \ /* _beta : rolloff factor, 0 <= _beta <= 1 */ \ /* _M : number of filters in the bank, _M > 0 */ \ SYMSYNC() SYMSYNC(_create_rnyquist)(int _type, \ unsigned int _k, \ unsigned int _m, \ float _beta, \ unsigned int _M); \ \ /* Create symsync using Kaiser filter interpolator. This is useful when */ \ /* the input signal has its matched filter applied already. */ \ /* _k : input samples/symbol, _k >= 2 */ \ /* _m : symbol delay, _m > 0 */ \ /* _beta : rolloff factor, 0<= _beta <= 1 */ \ /* _M : number of filters in the bank, _M > 0 */ \ SYMSYNC() SYMSYNC(_create_kaiser)(unsigned int _k, \ unsigned int _m, \ float _beta, \ unsigned int _M); \ \ /* Destroy symsync object, freeing all internal memory */ \ void SYMSYNC(_destroy)(SYMSYNC() _q); \ \ /* Print symsync object's parameters to stdout */ \ void SYMSYNC(_print)(SYMSYNC() _q); \ \ /* Reset symsync internal state */ \ void SYMSYNC(_reset)(SYMSYNC() _q); \ \ /* Lock the symbol synchronizer's loop control */ \ void SYMSYNC(_lock)(SYMSYNC() _q); \ \ /* Unlock the symbol synchronizer's loop control */ \ void SYMSYNC(_unlock)(SYMSYNC() _q); \ \ /* Set synchronizer output rate (samples/symbol) */ \ /* _q : synchronizer object */ \ /* _k_out : output samples/symbol, _k_out > 0 */ \ void SYMSYNC(_set_output_rate)(SYMSYNC() _q, \ unsigned int _k_out); \ \ /* Set loop-filter bandwidth */ \ /* _q : synchronizer object */ \ /* _bt : loop bandwidth, 0 <= _bt <= 1 */ \ void SYMSYNC(_set_lf_bw)(SYMSYNC() _q, \ float _bt); \ \ /* Return instantaneous fractional timing offset estimate */ \ float SYMSYNC(_get_tau)(SYMSYNC() _q); \ \ /* Execute synchronizer on input data array */ \ /* _q : synchronizer object */ \ /* _x : input data array, [size: _nx x 1] */ \ /* _nx : number of input samples */ \ /* _y : output data array */ \ /* _ny : number of samples written to output buffer */ \ void SYMSYNC(_execute)(SYMSYNC() _q, \ TI * _x, \ unsigned int _nx, \ TO * _y, \ unsigned int * _ny); \ LIQUID_SYMSYNC_DEFINE_API(LIQUID_SYMSYNC_MANGLE_RRRF, float, float, float) LIQUID_SYMSYNC_DEFINE_API(LIQUID_SYMSYNC_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) // // Finite impulse response Farrow filter // #define LIQUID_FIRFARROW_MANGLE_RRRF(name) LIQUID_CONCAT(firfarrow_rrrf,name) #define LIQUID_FIRFARROW_MANGLE_CRCF(name) LIQUID_CONCAT(firfarrow_crcf,name) //#define LIQUID_FIRFARROW_MANGLE_CCCF(name) LIQUID_CONCAT(firfarrow_cccf,name) // Macro: // FIRFARROW : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FIRFARROW_DEFINE_API(FIRFARROW,TO,TC,TI) \ \ /* Finite impulse response (FIR) Farrow filter for timing delay */ \ typedef struct FIRFARROW(_s) * FIRFARROW(); \ \ /* Create firfarrow object */ \ /* _h_len : filter length, _h_len >= 2 */ \ /* _p : polynomial order, _p >= 1 */ \ /* _fc : filter cutoff frequency, 0 <= _fc <= 0.5 */ \ /* _As : stopband attenuation [dB], _As > 0 */ \ FIRFARROW() FIRFARROW(_create)(unsigned int _h_len, \ unsigned int _p, \ float _fc, \ float _As); \ \ /* Destroy firfarrow object, freeing all internal memory */ \ int FIRFARROW(_destroy)(FIRFARROW() _q); \ \ /* Print firfarrow object's internal properties */ \ int FIRFARROW(_print)(FIRFARROW() _q); \ \ /* Reset firfarrow object's internal state */ \ int FIRFARROW(_reset)(FIRFARROW() _q); \ \ /* Push sample into firfarrow object */ \ /* _q : firfarrow object */ \ /* _x : input sample */ \ int FIRFARROW(_push)(FIRFARROW() _q, \ TI _x); \ \ /* Set fractional delay of firfarrow object */ \ /* _q : firfarrow object */ \ /* _mu : fractional sample delay, -1 <= _mu <= 1 */ \ int FIRFARROW(_set_delay)(FIRFARROW() _q, \ float _mu); \ \ /* Execute firfarrow internal dot product */ \ /* _q : firfarrow object */ \ /* _y : output sample pointer */ \ int FIRFARROW(_execute)(FIRFARROW() _q, \ TO * _y); \ \ /* Execute firfarrow filter on block of samples. */ \ /* In-place operation is permitted (the input and output arrays may */ \ /* share the same pointer) */ \ /* _q : firfarrow object */ \ /* _x : input array, [size: _n x 1] */ \ /* _n : input, output array size */ \ /* _y : output array, [size: _n x 1] */ \ int FIRFARROW(_execute_block)(FIRFARROW() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ \ /* Get length of firfarrow object (number of filter taps) */ \ unsigned int FIRFARROW(_get_length)(FIRFARROW() _q); \ \ /* Get coefficients of firfarrow object */ \ /* _q : firfarrow object */ \ /* _h : output coefficients pointer, [size: _h_len x 1] */ \ int FIRFARROW(_get_coefficients)(FIRFARROW() _q, \ float * _h); \ \ /* Compute complex frequency response */ \ /* _q : filter object */ \ /* _fc : frequency */ \ /* _H : output frequency response */ \ int FIRFARROW(_freqresponse)(FIRFARROW() _q, \ float _fc, \ liquid_float_complex * _H); \ \ /* Compute group delay [samples] */ \ /* _q : filter object */ \ /* _fc : frequency */ \ float FIRFARROW(_groupdelay)(FIRFARROW() _q, \ float _fc); \ LIQUID_FIRFARROW_DEFINE_API(LIQUID_FIRFARROW_MANGLE_RRRF, float, float, float) LIQUID_FIRFARROW_DEFINE_API(LIQUID_FIRFARROW_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) // // Order-statistic filter // #define LIQUID_ORDFILT_MANGLE_RRRF(name) LIQUID_CONCAT(ordfilt_rrrf,name) // Macro: // ORDFILT : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_ORDFILT_DEFINE_API(ORDFILT,TO,TC,TI) \ \ /* Finite impulse response (FIR) filter */ \ typedef struct ORDFILT(_s) * ORDFILT(); \ \ /* Create a order-statistic filter (ordfilt) object by specifying */ \ /* the buffer size and appropriate sample index of order statistic. */ \ /* _n : buffer size, _n > 0 */ \ /* _k : sample index for order statistic, 0 <= _k < _n */ \ ORDFILT() ORDFILT(_create)(unsigned int _n, \ unsigned int _k); \ \ /* Create a median filter by specifying buffer semi-length. */ \ /* _m : buffer semi-length */ \ ORDFILT() ORDFILT(_create_medfilt)(unsigned int _m); \ \ /* Destroy filter object and free all internal memory */ \ void ORDFILT(_destroy)(ORDFILT() _q); \ \ /* Reset filter object's internal buffer */ \ void ORDFILT(_reset)(ORDFILT() _q); \ \ /* Print filter object information to stdout */ \ void ORDFILT(_print)(ORDFILT() _q); \ \ /* Push sample into filter object's internal buffer */ \ /* _q : filter object */ \ /* _x : single input sample */ \ void ORDFILT(_push)(ORDFILT() _q, \ TI _x); \ \ /* Write block of samples into object's internal buffer */ \ /* _q : filter object */ \ /* _x : array of input samples, [size: _n x 1] */ \ /* _n : number of input elements */ \ void ORDFILT(_write)(ORDFILT() _q, \ TI * _x, \ unsigned int _n); \ \ /* Execute vector dot product on the filter's internal buffer and */ \ /* coefficients */ \ /* _q : filter object */ \ /* _y : pointer to single output sample */ \ void ORDFILT(_execute)(ORDFILT() _q, \ TO * _y); \ \ /* Execute the filter on a block of input samples; in-place operation */ \ /* is permitted (_x and _y may point to the same place in memory) */ \ /* _q : filter object */ \ /* _x : pointer to input array, [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _y : pointer to output array, [size: _n x 1] */ \ void ORDFILT(_execute_block)(ORDFILT() _q, \ TI * _x, \ unsigned int _n, \ TO * _y); \ LIQUID_ORDFILT_DEFINE_API(LIQUID_ORDFILT_MANGLE_RRRF, float, float, float) // // MODULE : framing // // framesyncstats : generic frame synchronizer statistic structure typedef struct { // signal quality float evm; // error vector magnitude [dB] float rssi; // received signal strength indicator [dB] float cfo; // carrier frequency offset (f/Fs) // demodulated frame symbols liquid_float_complex * framesyms; // pointer to array [size: framesyms x 1] unsigned int num_framesyms; // length of framesyms // modulation/coding scheme etc. unsigned int mod_scheme; // modulation scheme unsigned int mod_bps; // modulation depth (bits/symbol) unsigned int check; // data validity check (crc, checksum) unsigned int fec0; // forward error-correction (inner) unsigned int fec1; // forward error-correction (outer) } framesyncstats_s; // external framesyncstats default object extern framesyncstats_s framesyncstats_default; // initialize framesyncstats object on default int framesyncstats_init_default(framesyncstats_s * _stats); // print framesyncstats object int framesyncstats_print(framesyncstats_s * _stats); // framedatastats : gather frame data typedef struct { unsigned int num_frames_detected; unsigned int num_headers_valid; unsigned int num_payloads_valid; unsigned long int num_bytes_received; } framedatastats_s; // reset framedatastats object int framedatastats_reset(framedatastats_s * _stats); // print framedatastats object int framedatastats_print(framedatastats_s * _stats); // Generic frame synchronizer callback function type // _header : header data [size: 8 bytes] // _header_valid : is header valid? (0:no, 1:yes) // _payload : payload data [size: _payload_len] // _payload_len : length of payload (bytes) // _payload_valid : is payload valid? (0:no, 1:yes) // _stats : frame statistics object // _userdata : pointer to userdata typedef int (*framesync_callback)(unsigned char * _header, int _header_valid, unsigned char * _payload, unsigned int _payload_len, int _payload_valid, framesyncstats_s _stats, void * _userdata); // framesync csma callback functions invoked when signal levels is high or low // _userdata : user-defined data pointer typedef void (*framesync_csma_callback)(void * _userdata); // // packet encoder/decoder // typedef struct qpacketmodem_s * qpacketmodem; // create packet encoder qpacketmodem qpacketmodem_create (); int qpacketmodem_destroy(qpacketmodem _q); int qpacketmodem_reset (qpacketmodem _q); int qpacketmodem_print (qpacketmodem _q); int qpacketmodem_configure(qpacketmodem _q, unsigned int _payload_len, crc_scheme _check, fec_scheme _fec0, fec_scheme _fec1, int _ms); // get length of encoded frame in symbols unsigned int qpacketmodem_get_frame_len(qpacketmodem _q); // get unencoded/decoded payload length (bytes) unsigned int qpacketmodem_get_payload_len(qpacketmodem _q); // regular access methods unsigned int qpacketmodem_get_crc (qpacketmodem _q); unsigned int qpacketmodem_get_fec0 (qpacketmodem _q); unsigned int qpacketmodem_get_fec1 (qpacketmodem _q); unsigned int qpacketmodem_get_modscheme(qpacketmodem _q); float qpacketmodem_get_demodulator_phase_error(qpacketmodem _q); float qpacketmodem_get_demodulator_evm(qpacketmodem _q); // encode packet into un-modulated frame symbol indices // _q : qpacketmodem object // _payload : unencoded payload bytes // _syms : encoded but un-modulated payload symbol indices int qpacketmodem_encode_syms(qpacketmodem _q, const unsigned char * _payload, unsigned char * _syms); // decode packet from demodulated frame symbol indices (hard-decision decoding) // _q : qpacketmodem object // _syms : received hard-decision symbol indices [size: frame_len x 1] // _payload : recovered decoded payload bytes int qpacketmodem_decode_syms(qpacketmodem _q, unsigned char * _syms, unsigned char * _payload); // decode packet from demodulated frame bits (soft-decision decoding) // _q : qpacketmodem object // _bits : received soft-decision bits, [size: bps*frame_len x 1] // _payload : recovered decoded payload bytes int qpacketmodem_decode_bits(qpacketmodem _q, unsigned char * _bits, unsigned char * _payload); // encode and modulate packet into modulated frame samples // _q : qpacketmodem object // _payload : unencoded payload bytes // _frame : encoded/modulated payload symbols int qpacketmodem_encode(qpacketmodem _q, const unsigned char * _payload, liquid_float_complex * _frame); // decode packet from modulated frame samples, returning flag if CRC passed // NOTE: hard-decision decoding // _q : qpacketmodem object // _frame : encoded/modulated payload symbols // _payload : recovered decoded payload bytes int qpacketmodem_decode(qpacketmodem _q, liquid_float_complex * _frame, unsigned char * _payload); // decode packet from modulated frame samples, returning flag if CRC passed // NOTE: soft-decision decoding // _q : qpacketmodem object // _frame : encoded/modulated payload symbols // _payload : recovered decoded payload bytes int qpacketmodem_decode_soft(qpacketmodem _q, liquid_float_complex * _frame, unsigned char * _payload); int qpacketmodem_decode_soft_sym(qpacketmodem _q, liquid_float_complex _symbol); int qpacketmodem_decode_soft_payload(qpacketmodem _q, unsigned char * _payload); // // pilot generator/synchronizer for packet burst recovery // // get number of pilots in frame unsigned int qpilot_num_pilots(unsigned int _payload_len, unsigned int _pilot_spacing); // get length of frame with a particular payload length and pilot spacing unsigned int qpilot_frame_len(unsigned int _payload_len, unsigned int _pilot_spacing); // // pilot generator for packet burst recovery // typedef struct qpilotgen_s * qpilotgen; // create packet encoder qpilotgen qpilotgen_create(unsigned int _payload_len, unsigned int _pilot_spacing); qpilotgen qpilotgen_recreate(qpilotgen _q, unsigned int _payload_len, unsigned int _pilot_spacing); int qpilotgen_destroy(qpilotgen _q); int qpilotgen_reset( qpilotgen _q); int qpilotgen_print( qpilotgen _q); unsigned int qpilotgen_get_frame_len(qpilotgen _q); // insert pilot symbols int qpilotgen_execute(qpilotgen _q, liquid_float_complex * _payload, liquid_float_complex * _frame); // // pilot synchronizer for packet burst recovery // typedef struct qpilotsync_s * qpilotsync; // create packet encoder qpilotsync qpilotsync_create(unsigned int _payload_len, unsigned int _pilot_spacing); qpilotsync qpilotsync_recreate(qpilotsync _q, unsigned int _payload_len, unsigned int _pilot_spacing); int qpilotsync_destroy(qpilotsync _q); int qpilotsync_reset( qpilotsync _q); int qpilotsync_print( qpilotsync _q); unsigned int qpilotsync_get_frame_len(qpilotsync _q); // recover frame symbols from received frame int qpilotsync_execute(qpilotsync _q, liquid_float_complex * _frame, liquid_float_complex * _payload); // get estimates float qpilotsync_get_dphi(qpilotsync _q); float qpilotsync_get_phi (qpilotsync _q); float qpilotsync_get_gain(qpilotsync _q); float qpilotsync_get_evm (qpilotsync _q); // // Basic frame generator (64 bytes data payload) // // frame length in samples #define LIQUID_FRAME64_LEN (1440) typedef struct framegen64_s * framegen64; // create frame generator framegen64 framegen64_create(); // destroy frame generator int framegen64_destroy(framegen64 _q); // print frame generator internal properties int framegen64_print(framegen64 _q); // generate frame // _q : frame generator object // _header : 8-byte header data, NULL for random // _payload : 64-byte payload data, NULL for random // _frame : output frame samples [size: LIQUID_FRAME64_LEN x 1] int framegen64_execute(framegen64 _q, unsigned char * _header, unsigned char * _payload, liquid_float_complex * _frame); typedef struct framesync64_s * framesync64; // create framesync64 object // _callback : callback function // _userdata : user data pointer passed to callback function framesync64 framesync64_create(framesync_callback _callback, void * _userdata); // destroy frame synchronizer int framesync64_destroy(framesync64 _q); // print frame synchronizer internal properties int framesync64_print(framesync64 _q); // reset frame synchronizer internal state int framesync64_reset(framesync64 _q); // push samples through frame synchronizer // _q : frame synchronizer object // _x : input samples [size: _n x 1] // _n : number of input samples int framesync64_execute(framesync64 _q, liquid_float_complex * _x, unsigned int _n); // enable/disable debugging int framesync64_debug_enable(framesync64 _q); int framesync64_debug_disable(framesync64 _q); int framesync64_debug_print(framesync64 _q, const char * _filename); // get/set detection threshold float framesync64_get_threshold(framesync64 _q); int framesync64_set_threshold(framesync64 _q, float _threshold); // frame data statistics int framesync64_reset_framedatastats(framesync64 _q); framedatastats_s framesync64_get_framedatastats (framesync64 _q); #if 0 // advanced modes int framesync64_set_csma_callbacks(framesync64 _q, framesync_csma_callback _csma_lock, framesync_csma_callback _csma_unlock, void * _csma_userdata); #endif // // Flexible frame : adjustable payload, mod scheme, etc., but bring // your own error correction, redundancy check // // frame generator typedef struct { unsigned int check; // data validity check unsigned int fec0; // forward error-correction scheme (inner) unsigned int fec1; // forward error-correction scheme (outer) unsigned int mod_scheme; // modulation scheme } flexframegenprops_s; int flexframegenprops_init_default(flexframegenprops_s * _fgprops); typedef struct flexframegen_s * flexframegen; // create flexframegen object // _props : frame properties (modulation scheme, etc.) flexframegen flexframegen_create(flexframegenprops_s * _props); // destroy flexframegen object int flexframegen_destroy(flexframegen _q); // print flexframegen object internals int flexframegen_print(flexframegen _q); // reset flexframegen object internals int flexframegen_reset(flexframegen _q); // is frame assembled? int flexframegen_is_assembled(flexframegen _q); // get frame properties int flexframegen_getprops(flexframegen _q, flexframegenprops_s * _props); // set frame properties int flexframegen_setprops(flexframegen _q, flexframegenprops_s * _props); // set length of user-defined portion of header int flexframegen_set_header_len(flexframegen _q, unsigned int _len); // set properties for header section int flexframegen_set_header_props(flexframegen _q, flexframegenprops_s * _props); // get length of assembled frame (samples) unsigned int flexframegen_getframelen(flexframegen _q); // assemble a frame from an array of data // _q : frame generator object // _header : frame header // _payload : payload data [size: _payload_len x 1] // _payload_len : payload data length int flexframegen_assemble(flexframegen _q, const unsigned char * _header, const unsigned char * _payload, unsigned int _payload_len); // write samples of assembled frame, two samples at a time, returning // '1' when frame is complete, '0' otherwise. Zeros will be written // to the buffer if the frame is not assembled // _q : frame generator object // _buffer : output buffer [size: _buffer_len x 1] // _buffer_len : output buffer length int flexframegen_write_samples(flexframegen _q, liquid_float_complex * _buffer, unsigned int _buffer_len); // frame synchronizer typedef struct flexframesync_s * flexframesync; // create flexframesync object // _callback : callback function // _userdata : user data pointer passed to callback function flexframesync flexframesync_create(framesync_callback _callback, void * _userdata); // destroy frame synchronizer int flexframesync_destroy(flexframesync _q); // print frame synchronizer internal properties int flexframesync_print(flexframesync _q); // reset frame synchronizer internal state int flexframesync_reset(flexframesync _q); // has frame been detected? int flexframesync_is_frame_open(flexframesync _q); // change length of user-defined region in header int flexframesync_set_header_len(flexframesync _q, unsigned int _len); // enable or disable soft decoding of header int flexframesync_decode_header_soft(flexframesync _q, int _soft); // enable or disable soft decoding of payload int flexframesync_decode_payload_soft(flexframesync _q, int _soft); // set properties for header section int flexframesync_set_header_props(flexframesync _q, flexframegenprops_s * _props); // push samples through frame synchronizer // _q : frame synchronizer object // _x : input samples [size: _n x 1] // _n : number of input samples int flexframesync_execute(flexframesync _q, liquid_float_complex * _x, unsigned int _n); // frame data statistics int flexframesync_reset_framedatastats(flexframesync _q); framedatastats_s flexframesync_get_framedatastats (flexframesync _q); // enable/disable debugging int flexframesync_debug_enable(flexframesync _q); int flexframesync_debug_disable(flexframesync _q); int flexframesync_debug_print(flexframesync _q, const char * _filename); // // bpacket : binary packet suitable for data streaming // // // bpacket generator/encoder // typedef struct bpacketgen_s * bpacketgen; // create bpacketgen object // _m : p/n sequence length (ignored) // _dec_msg_len : decoded message length (original uncoded data) // _crc : data validity check (e.g. cyclic redundancy check) // _fec0 : inner forward error-correction code scheme // _fec1 : outer forward error-correction code scheme bpacketgen bpacketgen_create(unsigned int _m, unsigned int _dec_msg_len, int _crc, int _fec0, int _fec1); // re-create bpacketgen object from old object // _q : old bpacketgen object // _m : p/n sequence length (ignored) // _dec_msg_len : decoded message length (original uncoded data) // _crc : data validity check (e.g. cyclic redundancy check) // _fec0 : inner forward error-correction code scheme // _fec1 : outer forward error-correction code scheme bpacketgen bpacketgen_recreate(bpacketgen _q, unsigned int _m, unsigned int _dec_msg_len, int _crc, int _fec0, int _fec1); // destroy bpacketgen object, freeing all internally-allocated memory void bpacketgen_destroy(bpacketgen _q); // print bpacketgen internals void bpacketgen_print(bpacketgen _q); // return length of full packet unsigned int bpacketgen_get_packet_len(bpacketgen _q); // encode packet void bpacketgen_encode(bpacketgen _q, unsigned char * _msg_dec, unsigned char * _packet); // // bpacket synchronizer/decoder // typedef struct bpacketsync_s * bpacketsync; typedef int (*bpacketsync_callback)(unsigned char * _payload, int _payload_valid, unsigned int _payload_len, framesyncstats_s _stats, void * _userdata); bpacketsync bpacketsync_create(unsigned int _m, bpacketsync_callback _callback, void * _userdata); int bpacketsync_destroy(bpacketsync _q); int bpacketsync_print(bpacketsync _q); int bpacketsync_reset(bpacketsync _q); // run synchronizer on array of input bytes // _q : bpacketsync object // _bytes : input data array [size: _n x 1] // _n : input array size int bpacketsync_execute(bpacketsync _q, unsigned char * _bytes, unsigned int _n); // run synchronizer on input byte // _q : bpacketsync object // _byte : input byte int bpacketsync_execute_byte(bpacketsync _q, unsigned char _byte); // run synchronizer on input symbol // _q : bpacketsync object // _sym : input symbol with _bps significant bits // _bps : number of bits in input symbol int bpacketsync_execute_sym(bpacketsync _q, unsigned char _sym, unsigned int _bps); // execute one bit at a time int bpacketsync_execute_bit(bpacketsync _q, unsigned char _bit); // // M-FSK frame generator // typedef struct fskframegen_s * fskframegen; // create M-FSK frame generator fskframegen fskframegen_create(); int fskframegen_destroy (fskframegen _fg); int fskframegen_print (fskframegen _fg); int fskframegen_reset (fskframegen _fg); int fskframegen_assemble(fskframegen _fg, unsigned char * _header, unsigned char * _payload, unsigned int _payload_len, crc_scheme _check, fec_scheme _fec0, fec_scheme _fec1); unsigned int fskframegen_getframelen(fskframegen _q); int fskframegen_write_samples(fskframegen _fg, liquid_float_complex * _buf, unsigned int _buf_len); // // M-FSK frame synchronizer // typedef struct fskframesync_s * fskframesync; // create M-FSK frame synchronizer // _callback : callback function // _userdata : user data pointer passed to callback function fskframesync fskframesync_create(framesync_callback _callback, void * _userdata); int fskframesync_destroy(fskframesync _q); int fskframesync_print (fskframesync _q); int fskframesync_reset (fskframesync _q); int fskframesync_execute(fskframesync _q, liquid_float_complex _x); int fskframesync_execute_block(fskframesync _q, liquid_float_complex * _x, unsigned int _n); // debugging int fskframesync_debug_enable (fskframesync _q); int fskframesync_debug_disable(fskframesync _q); int fskframesync_debug_export (fskframesync _q, const char * _filename); // // GMSK frame generator // typedef struct gmskframegen_s * gmskframegen; // create GMSK frame generator // _k : samples/symbol // _m : filter delay (symbols) // _BT : excess bandwidth factor gmskframegen gmskframegen_create(unsigned int _k, unsigned int _m, float _BT); int gmskframegen_destroy (gmskframegen _q); int gmskframegen_is_assembled (gmskframegen _q); int gmskframegen_print (gmskframegen _q); int gmskframegen_set_header_len(gmskframegen _q, unsigned int _len); int gmskframegen_reset (gmskframegen _q); int gmskframegen_assemble (gmskframegen _q, const unsigned char * _header, const unsigned char * _payload, unsigned int _payload_len, crc_scheme _check, fec_scheme _fec0, fec_scheme _fec1); // assemble default frame with a particular size payload int gmskframegen_assemble_default(gmskframegen _q, unsigned int _payload_len); unsigned int gmskframegen_getframelen(gmskframegen _q); // write samples of assembled frame // _q : frame generator object // _buf : output buffer [size: _buf_len x 1] // _buf_len : output buffer length int gmskframegen_write(gmskframegen _q, liquid_float_complex * _buf, unsigned int _buf_len); // // GMSK frame synchronizer // typedef struct gmskframesync_s * gmskframesync; // create GMSK frame synchronizer // _k : samples/symbol // _m : filter delay (symbols) // _BT : excess bandwidth factor // _callback : callback function // _userdata : user data pointer passed to callback function gmskframesync gmskframesync_create(unsigned int _k, unsigned int _m, float _BT, framesync_callback _callback, void * _userdata); int gmskframesync_destroy(gmskframesync _q); int gmskframesync_print(gmskframesync _q); int gmskframesync_set_header_len(gmskframesync _q, unsigned int _len); int gmskframesync_reset(gmskframesync _q); int gmskframesync_is_frame_open(gmskframesync _q); int gmskframesync_execute(gmskframesync _q, liquid_float_complex * _x, unsigned int _n); // frame data statistics int gmskframesync_reset_framedatastats(gmskframesync _q); framedatastats_s gmskframesync_get_framedatastats (gmskframesync _q); // // DSSS frame generator // typedef struct { unsigned int check; unsigned int fec0; unsigned int fec1; } dsssframegenprops_s; typedef struct dsssframegen_s * dsssframegen; dsssframegen dsssframegen_create(dsssframegenprops_s * _props); int dsssframegen_destroy(dsssframegen _q); int dsssframegen_reset(dsssframegen _q); int dsssframegen_is_assembled(dsssframegen _q); int dsssframegen_getprops(dsssframegen _q, dsssframegenprops_s * _props); int dsssframegen_setprops(dsssframegen _q, dsssframegenprops_s * _props); int dsssframegen_set_header_len(dsssframegen _q, unsigned int _len); int dsssframegen_set_header_props(dsssframegen _q, dsssframegenprops_s * _props); unsigned int dsssframegen_getframelen(dsssframegen _q); // assemble a frame from an array of data // _q : frame generator object // _header : frame header // _payload : payload data [size: _payload_len x 1] // _payload_len : payload data length int dsssframegen_assemble(dsssframegen _q, const unsigned char * _header, const unsigned char * _payload, unsigned int _payload_len); int dsssframegen_write_samples(dsssframegen _q, liquid_float_complex * _buffer, unsigned int _buffer_len); // // DSSS frame synchronizer // typedef struct dsssframesync_s * dsssframesync; dsssframesync dsssframesync_create(framesync_callback _callback, void * _userdata); int dsssframesync_destroy (dsssframesync _q); int dsssframesync_print (dsssframesync _q); int dsssframesync_reset (dsssframesync _q); int dsssframesync_is_frame_open (dsssframesync _q); int dsssframesync_set_header_len (dsssframesync _q, unsigned int _len); int dsssframesync_decode_header_soft (dsssframesync _q, int _soft); int dsssframesync_decode_payload_soft (dsssframesync _q, int _soft); int dsssframesync_set_header_props (dsssframesync _q, dsssframegenprops_s * _props); int dsssframesync_execute (dsssframesync _q, liquid_float_complex * _x, unsigned int _n); int dsssframesync_reset_framedatastats(dsssframesync _q); int dsssframesync_debug_enable (dsssframesync _q); int dsssframesync_debug_disable (dsssframesync _q); int dsssframesync_debug_print (dsssframesync _q, const char * _filename); framedatastats_s dsssframesync_get_framedatastats (dsssframesync _q); // // OFDM flexframe generator // // ofdm frame generator properties typedef struct { unsigned int check; // data validity check unsigned int fec0; // forward error-correction scheme (inner) unsigned int fec1; // forward error-correction scheme (outer) unsigned int mod_scheme; // modulation scheme //unsigned int block_size; // framing block size } ofdmflexframegenprops_s; int ofdmflexframegenprops_init_default(ofdmflexframegenprops_s * _props); typedef struct ofdmflexframegen_s * ofdmflexframegen; // create OFDM flexible framing generator object // _M : number of subcarriers, >10 typical // _cp_len : cyclic prefix length // _taper_len : taper length (OFDM symbol overlap) // _p : subcarrier allocation (null, pilot, data), [size: _M x 1] // _fgprops : frame properties (modulation scheme, etc.) ofdmflexframegen ofdmflexframegen_create(unsigned int _M, unsigned int _cp_len, unsigned int _taper_len, unsigned char * _p, ofdmflexframegenprops_s * _fgprops); // destroy ofdmflexframegen object int ofdmflexframegen_destroy(ofdmflexframegen _q); // print parameters, properties, etc. int ofdmflexframegen_print(ofdmflexframegen _q); // reset ofdmflexframegen object internals int ofdmflexframegen_reset(ofdmflexframegen _q); // is frame assembled? int ofdmflexframegen_is_assembled(ofdmflexframegen _q); // get properties int ofdmflexframegen_getprops(ofdmflexframegen _q, ofdmflexframegenprops_s * _props); // set properties int ofdmflexframegen_setprops(ofdmflexframegen _q, ofdmflexframegenprops_s * _props); // set user-defined header length int ofdmflexframegen_set_header_len(ofdmflexframegen _q, unsigned int _len); int ofdmflexframegen_set_header_props(ofdmflexframegen _q, ofdmflexframegenprops_s * _props); // get length of frame (symbols) // _q : OFDM frame generator object unsigned int ofdmflexframegen_getframelen(ofdmflexframegen _q); // assemble a frame from an array of data (NULL pointers will use random data) // _q : OFDM frame generator object // _header : frame header [8 bytes] // _payload : payload data [size: _payload_len x 1] // _payload_len : payload data length int ofdmflexframegen_assemble(ofdmflexframegen _q, const unsigned char * _header, const unsigned char * _payload, unsigned int _payload_len); // write samples of assembled frame // _q : OFDM frame generator object // _buf : output buffer [size: _buf_len x 1] // _buf_len : output buffer length int ofdmflexframegen_write(ofdmflexframegen _q, liquid_float_complex * _buf, unsigned int _buf_len); // // OFDM flex frame synchronizer // typedef struct ofdmflexframesync_s * ofdmflexframesync; // create OFDM flexible framing synchronizer object // _M : number of subcarriers // _cp_len : cyclic prefix length // _taper_len : taper length (OFDM symbol overlap) // _p : subcarrier allocation (null, pilot, data), [size: _M x 1] // _callback : user-defined callback function // _userdata : user-defined data pointer ofdmflexframesync ofdmflexframesync_create(unsigned int _M, unsigned int _cp_len, unsigned int _taper_len, unsigned char * _p, framesync_callback _callback, void * _userdata); int ofdmflexframesync_destroy(ofdmflexframesync _q); int ofdmflexframesync_print(ofdmflexframesync _q); // set user-defined header length int ofdmflexframesync_set_header_len(ofdmflexframesync _q, unsigned int _len); int ofdmflexframesync_decode_header_soft(ofdmflexframesync _q, int _soft); int ofdmflexframesync_decode_payload_soft(ofdmflexframesync _q, int _soft); int ofdmflexframesync_set_header_props(ofdmflexframesync _q, ofdmflexframegenprops_s * _props); int ofdmflexframesync_reset(ofdmflexframesync _q); int ofdmflexframesync_is_frame_open(ofdmflexframesync _q); int ofdmflexframesync_execute(ofdmflexframesync _q, liquid_float_complex * _x, unsigned int _n); // query the received signal strength indication float ofdmflexframesync_get_rssi(ofdmflexframesync _q); // query the received carrier offset estimate float ofdmflexframesync_get_cfo(ofdmflexframesync _q); // frame data statistics int ofdmflexframesync_reset_framedatastats(ofdmflexframesync _q); framedatastats_s ofdmflexframesync_get_framedatastats (ofdmflexframesync _q); // set the received carrier offset estimate int ofdmflexframesync_set_cfo(ofdmflexframesync _q, float _cfo); // enable/disable debugging int ofdmflexframesync_debug_enable(ofdmflexframesync _q); int ofdmflexframesync_debug_disable(ofdmflexframesync _q); int ofdmflexframesync_debug_print(ofdmflexframesync _q, const char * _filename); // // Binary P/N synchronizer // #define LIQUID_BSYNC_MANGLE_RRRF(name) LIQUID_CONCAT(bsync_rrrf,name) #define LIQUID_BSYNC_MANGLE_CRCF(name) LIQUID_CONCAT(bsync_crcf,name) #define LIQUID_BSYNC_MANGLE_CCCF(name) LIQUID_CONCAT(bsync_cccf,name) // Macro: // BSYNC : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_BSYNC_DEFINE_API(BSYNC,TO,TC,TI) \ \ /* Binary P/N synchronizer */ \ typedef struct BSYNC(_s) * BSYNC(); \ \ /* Create bsync object */ \ /* _n : sequence length */ \ /* _v : correlation sequence [size: _n x 1] */ \ BSYNC() BSYNC(_create)(unsigned int _n, \ TC * _v); \ \ /* Create binary synchronizer from m-sequence */ \ /* _g : m-sequence generator polynomial */ \ /* _k : samples/symbol (over-sampling factor) */ \ BSYNC() BSYNC(_create_msequence)(unsigned int _g, \ unsigned int _k); \ \ /* Destroy binary synchronizer object, freeing all internal memory */ \ /* _q : bsync object */ \ void BSYNC(_destroy)(BSYNC() _q); \ \ /* Print object internals to stdout */ \ /* _q : bsync object */ \ void BSYNC(_print)(BSYNC() _q); \ \ /* Correlate input signal against internal sequence */ \ /* _q : bsync object */ \ /* _x : input sample */ \ /* _y : pointer to output sample */ \ void BSYNC(_correlate)(BSYNC() _q, \ TI _x, \ TO * _y); \ LIQUID_BSYNC_DEFINE_API(LIQUID_BSYNC_MANGLE_RRRF, float, float, float) LIQUID_BSYNC_DEFINE_API(LIQUID_BSYNC_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_BSYNC_DEFINE_API(LIQUID_BSYNC_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Pre-demodulation synchronizers (binary and otherwise) // #define LIQUID_PRESYNC_MANGLE_CCCF(name) LIQUID_CONCAT( presync_cccf,name) #define LIQUID_BPRESYNC_MANGLE_CCCF(name) LIQUID_CONCAT(bpresync_cccf,name) // Macro: // PRESYNC : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_PRESYNC_DEFINE_API(PRESYNC,TO,TC,TI) \ \ /* Pre-demodulation signal synchronizer */ \ typedef struct PRESYNC(_s) * PRESYNC(); \ \ /* Create pre-demod synchronizer from external sequence */ \ /* _v : baseband sequence, [size: _n x 1] */ \ /* _n : baseband sequence length, _n > 0 */ \ /* _dphi_max : maximum absolute frequency deviation for detection */ \ /* _m : number of correlators, _m > 0 */ \ PRESYNC() PRESYNC(_create)(TC * _v, \ unsigned int _n, \ float _dphi_max, \ unsigned int _m); \ \ /* Destroy pre-demod synchronizer, freeing all internal memory */ \ int PRESYNC(_destroy)(PRESYNC() _q); \ \ /* Print pre-demod synchronizer internal state */ \ int PRESYNC(_print)(PRESYNC() _q); \ \ /* Reset pre-demod synchronizer internal state */ \ int PRESYNC(_reset)(PRESYNC() _q); \ \ /* Push input sample into pre-demod synchronizer */ \ /* _q : pre-demod synchronizer object */ \ /* _x : input sample */ \ int PRESYNC(_push)(PRESYNC() _q, \ TI _x); \ \ /* Correlate original sequence with internal input buffer */ \ /* _q : pre-demod synchronizer object */ \ /* _rxy : output cross correlation */ \ /* _dphi_hat : output frequency offset estimate */ \ int PRESYNC(_execute)(PRESYNC() _q, \ TO * _rxy, \ float * _dphi_hat); \ // non-binary pre-demodulation synchronizer LIQUID_PRESYNC_DEFINE_API(LIQUID_PRESYNC_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // binary pre-demodulation synchronizer LIQUID_PRESYNC_DEFINE_API(LIQUID_BPRESYNC_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Frame detector // typedef struct qdetector_cccf_s * qdetector_cccf; // create detector with generic sequence // _s : sample sequence // _s_len : length of sample sequence qdetector_cccf qdetector_cccf_create(liquid_float_complex * _s, unsigned int _s_len); // create detector from sequence of symbols using internal linear interpolator // _sequence : symbol sequence // _sequence_len : length of symbol sequence // _ftype : filter prototype (e.g. LIQUID_FIRFILT_RRC) // _k : samples/symbol // _m : filter delay // _beta : excess bandwidth factor qdetector_cccf qdetector_cccf_create_linear(liquid_float_complex * _sequence, unsigned int _sequence_len, int _ftype, unsigned int _k, unsigned int _m, float _beta); // create detector from sequence of GMSK symbols // _sequence : bit sequence // _sequence_len : length of bit sequence // _k : samples/symbol // _m : filter delay // _beta : excess bandwidth factor qdetector_cccf qdetector_cccf_create_gmsk(unsigned char * _sequence, unsigned int _sequence_len, unsigned int _k, unsigned int _m, float _beta); // create detector from sequence of CP-FSK symbols (assuming one bit/symbol) // _sequence : bit sequence // _sequence_len : length of bit sequence // _bps : bits per symbol, 0 < _bps <= 8 // _h : modulation index, _h > 0 // _k : samples/symbol // _m : filter delay // _beta : filter bandwidth parameter, _beta > 0 // _type : filter type (e.g. LIQUID_CPFSK_SQUARE) qdetector_cccf qdetector_cccf_create_cpfsk(unsigned char * _sequence, unsigned int _sequence_len, unsigned int _bps, float _h, unsigned int _k, unsigned int _m, float _beta, int _type); int qdetector_cccf_destroy(qdetector_cccf _q); int qdetector_cccf_print (qdetector_cccf _q); int qdetector_cccf_reset (qdetector_cccf _q); // run detector, looking for sequence; return pointer to aligned, buffered samples void * qdetector_cccf_execute(qdetector_cccf _q, liquid_float_complex _x); // get detection threshold float qdetector_cccf_get_threshold(qdetector_cccf _q); // set detection threshold (should be between 0 and 1, good starting point is 0.5) int qdetector_cccf_set_threshold(qdetector_cccf _q, float _threshold); // set carrier offset search range int qdetector_cccf_set_range(qdetector_cccf _q, float _dphi_max); // access methods unsigned int qdetector_cccf_get_seq_len (qdetector_cccf _q); // sequence length const void * qdetector_cccf_get_sequence(qdetector_cccf _q); // pointer to sequence unsigned int qdetector_cccf_get_buf_len (qdetector_cccf _q); // buffer length float qdetector_cccf_get_rxy (qdetector_cccf _q); // correlator output float qdetector_cccf_get_tau (qdetector_cccf _q); // fractional timing offset estimate float qdetector_cccf_get_gamma (qdetector_cccf _q); // channel gain float qdetector_cccf_get_dphi (qdetector_cccf _q); // carrier frequency offset estimate float qdetector_cccf_get_phi (qdetector_cccf _q); // carrier phase offset estimate // // Pre-demodulation detector // typedef struct detector_cccf_s * detector_cccf; // create pre-demod detector // _s : sequence // _n : sequence length // _threshold : detection threshold (default: 0.7) // _dphi_max : maximum carrier offset detector_cccf detector_cccf_create(liquid_float_complex * _s, unsigned int _n, float _threshold, float _dphi_max); // destroy pre-demo detector object void detector_cccf_destroy(detector_cccf _q); // print pre-demod detector internal state void detector_cccf_print(detector_cccf _q); // reset pre-demod detector internal state void detector_cccf_reset(detector_cccf _q); // Run sample through pre-demod detector's correlator. // Returns '1' if signal was detected, '0' otherwise // _q : pre-demod detector // _x : input sample // _tau_hat : fractional sample offset estimate (set when detected) // _dphi_hat : carrier frequency offset estimate (set when detected) // _gamma_hat : channel gain estimate (set when detected) int detector_cccf_correlate(detector_cccf _q, liquid_float_complex _x, float * _tau_hat, float * _dphi_hat, float * _gamma_hat); // // symbol streaming for testing (no meaningful data, just symbols) // #define LIQUID_SYMSTREAM_MANGLE_CFLOAT(name) LIQUID_CONCAT(symstreamcf,name) #define LIQUID_SYMSTREAM_DEFINE_API(SYMSTREAM,TO) \ \ /* Symbol streaming generator object */ \ typedef struct SYMSTREAM(_s) * SYMSTREAM(); \ \ /* Create symstream object with default parameters. */ \ /* This is equivalent to invoking the create_linear() method */ \ /* with _ftype=LIQUID_FIRFILT_ARKAISER, _k=2, _m=7, _beta=0.3, and */ \ /* with _ms=LIQUID_MODEM_QPSK */ \ SYMSTREAM() SYMSTREAM(_create)(void); \ \ /* Create symstream object with linear modulation */ \ /* _ftype : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _k : samples per symbol, _k >= 2 */ \ /* _m : filter delay (symbols), _m > 0 */ \ /* _beta : filter excess bandwidth, 0 < _beta <= 1 */ \ /* _ms : modulation scheme, e.g. LIQUID_MODEM_QPSK */ \ SYMSTREAM() SYMSTREAM(_create_linear)(int _ftype, \ unsigned int _k, \ unsigned int _m, \ float _beta, \ int _ms); \ \ /* Destroy symstream object, freeing all internal memory */ \ int SYMSTREAM(_destroy)(SYMSTREAM() _q); \ \ /* Print symstream object's parameters */ \ int SYMSTREAM(_print)(SYMSTREAM() _q); \ \ /* Reset symstream internal state */ \ int SYMSTREAM(_reset)(SYMSTREAM() _q); \ \ /* Set internal linear modulation scheme, leaving the filter parameters */ \ /* (interpolator) unmodified */ \ int SYMSTREAM(_set_scheme)(SYMSTREAM() _q, \ int _ms); \ \ /* Get internal filter type */ \ int SYMSTREAM(_get_ftype)(SYMSTREAM() _q); \ \ /* Get internal samples per symbol */ \ float SYMSTREAM(_get_k)(SYMSTREAM() _q); \ \ /* Get internal filter semi-length */ \ unsigned int SYMSTREAM(_get_m)(SYMSTREAM() _q); \ \ /* Get internal filter excess bandwidth factor */ \ float SYMSTREAM(_get_beta)(SYMSTREAM() _q); \ \ /* Get internal linear modulation scheme */ \ int SYMSTREAM(_get_scheme)(SYMSTREAM() _q); \ \ /* Set internal linear gain (before interpolation) */ \ int SYMSTREAM(_set_gain)(SYMSTREAM() _q, \ float _gain); \ \ /* Get internal linear gain (before interpolation) */ \ float SYMSTREAM(_get_gain)(SYMSTREAM() _q); \ \ /* Get delay in samples */ \ unsigned int SYMSTREAM(_get_delay)(SYMSTREAM() _q); \ \ /* Write block of samples to output buffer */ \ /* _q : synchronizer object */ \ /* _buf : output buffer [size: _buf_len x 1] */ \ /* _buf_len: output buffer size */ \ int SYMSTREAM(_write_samples)(SYMSTREAM() _q, \ TO * _buf, \ unsigned int _buf_len); \ LIQUID_SYMSTREAM_DEFINE_API(LIQUID_SYMSTREAM_MANGLE_CFLOAT, liquid_float_complex) // // symbol streaming, as with symstream but arbitrary output rate // #define LIQUID_SYMSTREAMR_MANGLE_CFLOAT(name) LIQUID_CONCAT(symstreamrcf,name) #define LIQUID_SYMSTREAMR_DEFINE_API(SYMSTREAMR,TO) \ \ /* Symbol streaming generator object */ \ typedef struct SYMSTREAMR(_s) * SYMSTREAMR(); \ \ /* Create symstream object with default parameters. */ \ /* This is equivalent to invoking the create_linear() method */ \ /* with _ftype=LIQUID_FIRFILT_ARKAISER, _k=2, _m=7, _beta=0.3, and */ \ /* with _ms=LIQUID_MODEM_QPSK */ \ SYMSTREAMR() SYMSTREAMR(_create)(void); \ \ /* Create symstream object with linear modulation */ \ /* _ftype : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _bw : relative signal bandwidth, 0.001 <= _bw <= 1.0 */ \ /* _m : filter delay (symbols), _m > 0 */ \ /* _beta : filter excess bandwidth, 0 < _beta <= 1 */ \ /* _ms : modulation scheme, e.g. LIQUID_MODEM_QPSK */ \ SYMSTREAMR() SYMSTREAMR(_create_linear)(int _ftype, \ float _bw, \ unsigned int _m, \ float _beta, \ int _ms); \ \ /* Destroy symstream object, freeing all internal memory */ \ int SYMSTREAMR(_destroy)(SYMSTREAMR() _q); \ \ /* Print symstream object's parameters */ \ int SYMSTREAMR(_print)(SYMSTREAMR() _q); \ \ /* Reset symstream internal state */ \ int SYMSTREAMR(_reset)(SYMSTREAMR() _q); \ \ /* Get internal filter type */ \ int SYMSTREAMR(_get_ftype)(SYMSTREAMR() _q); \ \ /* Get internal signal bandwidth (symbol rate) */ \ float SYMSTREAMR(_get_bw)(SYMSTREAMR() _q); \ \ /* Get internal filter semi-length */ \ unsigned int SYMSTREAMR(_get_m)(SYMSTREAMR() _q); \ \ /* Get internal filter excess bandwidth factor */ \ float SYMSTREAMR(_get_beta)(SYMSTREAMR() _q); \ \ /* Set internal linear modulation scheme, leaving the filter parameters */ \ /* (interpolator) unmodified */ \ int SYMSTREAMR(_set_scheme)(SYMSTREAMR() _q, \ int _ms); \ \ /* Get internal linear modulation scheme */ \ int SYMSTREAMR(_get_scheme)(SYMSTREAMR() _q); \ \ /* Set internal linear gain (before interpolation) */ \ int SYMSTREAMR(_set_gain)(SYMSTREAMR() _q, \ float _gain); \ \ /* Get internal linear gain (before interpolation) */ \ float SYMSTREAMR(_get_gain)(SYMSTREAMR() _q); \ \ /* Get delay in samples */ \ float SYMSTREAMR(_get_delay)(SYMSTREAMR() _q); \ \ /* Write block of samples to output buffer */ \ /* _q : synchronizer object */ \ /* _buf : output buffer [size: _buf_len x 1] */ \ /* _buf_len: output buffer size */ \ int SYMSTREAMR(_write_samples)(SYMSTREAMR() _q, \ TO * _buf, \ unsigned int _buf_len); \ LIQUID_SYMSTREAMR_DEFINE_API(LIQUID_SYMSTREAMR_MANGLE_CFLOAT, liquid_float_complex) // // multi-signal source for testing (no meaningful data, just signals) // #define LIQUID_MSOURCE_MANGLE_CFLOAT(name) LIQUID_CONCAT(msourcecf,name) #define LIQUID_MSOURCE_DEFINE_API(MSOURCE,TO) \ \ /* Multi-signal source generator object */ \ typedef struct MSOURCE(_s) * MSOURCE(); \ \ /* Create msource object by specifying channelizer parameters */ \ /* _M : number of channels in analysis channelizer object */ \ /* _m : prototype channelizer filter semi-length */ \ /* _As : prototype channelizer filter stop-band suppression (dB) */ \ MSOURCE() MSOURCE(_create)(unsigned int _M, \ unsigned int _m, \ float _As); \ \ /* Create default msource object with default parameters: */ \ /* M = 1200, m = 4, As = 60 */ \ MSOURCE() MSOURCE(_create_default)(void); \ \ /* Destroy msource object */ \ int MSOURCE(_destroy)(MSOURCE() _q); \ \ /* Print msource object */ \ int MSOURCE(_print)(MSOURCE() _q); \ \ /* Reset msource object */ \ int MSOURCE(_reset)(MSOURCE() _q); \ \ /* user-defined callback for generating samples */ \ typedef int (*MSOURCE(_callback))(void * _userdata, \ TO * _v, \ unsigned int _n); \ \ /* Add user-defined signal generator */ \ int MSOURCE(_add_user)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain, \ void * _userdata, \ MSOURCE(_callback) _callback); \ \ /* Add tone to signal generator, returning id of signal */ \ int MSOURCE(_add_tone)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain); \ \ /* Add chirp to signal generator, returning id of signal */ \ /* _q : multi-signal source object */ \ /* _duration : duration of chirp [samples] */ \ /* _negate : negate frequency direction */ \ /* _single : run single chirp? or repeatedly */ \ int MSOURCE(_add_chirp)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain, \ float _duration, \ int _negate, \ int _repeat); \ \ /* Add noise source to signal generator, returning id of signal */ \ /* _q : multi-signal source object */ \ /* _fc : ... */ \ /* _bw : ... */ \ /* _nstd : ... */ \ int MSOURCE(_add_noise)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain); \ \ /* Add modem signal source, returning id of signal */ \ /* _q : multi-signal source object */ \ /* _ms : modulation scheme, e.g. LIQUID_MODEM_QPSK */ \ /* _m : filter delay (symbols), _m > 0 */ \ /* _beta : filter excess bandwidth, 0 < _beta <= 1 */ \ int MSOURCE(_add_modem)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain, \ int _ms, \ unsigned int _m, \ float _beta); \ \ /* Add frequency-shift keying modem signal source, returning id of */ \ /* signal */ \ /* _q : multi-signal source object */ \ /* _m : bits per symbol, _bps > 0 */ \ /* _k : samples/symbol, _k >= 2^_m */ \ int MSOURCE(_add_fsk)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain, \ unsigned int _m, \ unsigned int _k); \ \ /* Add GMSK modem signal source, returning id of signal */ \ /* _q : multi-signal source object */ \ /* _m : filter delay (symbols), _m > 0 */ \ /* _bt : filter bandwidth-time factor, 0 < _bt <= 1 */ \ int MSOURCE(_add_gmsk)(MSOURCE() _q, \ float _fc, \ float _bw, \ float _gain, \ unsigned int _m, \ float _bt); \ \ /* Remove signal with a particular id, returning 0 upon success */ \ /* _q : multi-signal source object */ \ /* _id : signal source id */ \ int MSOURCE(_remove)(MSOURCE() _q, \ int _id); \ \ /* Enable signal source with a particular id */ \ int MSOURCE(_enable)(MSOURCE() _q, \ int _id); \ \ /* Disable signal source with a particular id */ \ int MSOURCE(_disable)(MSOURCE() _q, \ int _id); \ \ /* Set gain in decibels on signal */ \ /* _q : msource object */ \ /* _id : source id */ \ /* _gain : signal gain [dB] */ \ int MSOURCE(_set_gain)(MSOURCE() _q, \ int _id, \ float _gain); \ \ /* Get gain in decibels on signal */ \ /* _q : msource object */ \ /* _id : source id */ \ /* _gain : signal gain output [dB] */ \ int MSOURCE(_get_gain)(MSOURCE() _q, \ int _id, \ float * _gain); \ \ /* Get number of samples generated by the object so far */ \ /* _q : msource object */ \ /* _return : number of time-domain samples generated */ \ unsigned long long int MSOURCE(_get_num_samples)(MSOURCE() _q); \ \ /* Set carrier offset to signal */ \ /* _q : msource object */ \ /* _id : source id */ \ /* _fc : normalized carrier frequency offset, -0.5 <= _fc <= 0.5 */ \ int MSOURCE(_set_frequency)(MSOURCE() _q, \ int _id, \ float _dphi); \ \ /* Get carrier offset to signal */ \ /* _q : msource object */ \ /* _id : source id */ \ /* _fc : normalized carrier frequency offset */ \ int MSOURCE(_get_frequency)(MSOURCE() _q, \ int _id, \ float * _dphi); \ \ /* Write block of samples to output buffer */ \ /* _q : synchronizer object */ \ /* _buf : output buffer, [size: _buf_len x 1] */ \ /* _buf_len: output buffer size */ \ int MSOURCE(_write_samples)(MSOURCE() _q, \ TO * _buf, \ unsigned int _buf_len); \ LIQUID_MSOURCE_DEFINE_API(LIQUID_MSOURCE_MANGLE_CFLOAT, liquid_float_complex) // // Symbol tracking: AGC > symsync > EQ > carrier recovery // #define LIQUID_SYMTRACK_MANGLE_RRRF(name) LIQUID_CONCAT(symtrack_rrrf,name) #define LIQUID_SYMTRACK_MANGLE_CCCF(name) LIQUID_CONCAT(symtrack_cccf,name) // large macro // SYMTRACK : name-mangling macro // T : data type, primitive // TO : data type, output // TC : data type, coefficients // TI : data type, input #define LIQUID_SYMTRACK_DEFINE_API(SYMTRACK,T,TO,TC,TI) \ \ /* Symbol synchronizer and tracking object */ \ typedef struct SYMTRACK(_s) * SYMTRACK(); \ \ /* Create symtrack object, specifying parameters for operation */ \ /* _ftype : filter type (e.g. LIQUID_FIRFILT_RRC) */ \ /* _k : samples per symbol, _k >= 2 */ \ /* _m : filter delay [symbols], _m > 0 */ \ /* _beta : excess bandwidth factor, 0 <= _beta <= 1 */ \ /* _ms : modulation scheme, _ms(LIQUID_MODEM_BPSK) */ \ SYMTRACK() SYMTRACK(_create)(int _ftype, \ unsigned int _k, \ unsigned int _m, \ float _beta, \ int _ms); \ \ /* Create symtrack object using default parameters. */ \ /* The default parameters are */ \ /* ftype = LIQUID_FIRFILT_ARKAISER (filter type), */ \ /* k = 2 (samples per symbol), */ \ /* m = 7 (filter delay), */ \ /* beta = 0.3 (excess bandwidth factor), and */ \ /* ms = LIQUID_MODEM_QPSK (modulation scheme) */ \ SYMTRACK() SYMTRACK(_create_default)(); \ \ /* Destroy symtrack object, freeing all internal memory */ \ int SYMTRACK(_destroy)(SYMTRACK() _q); \ \ /* Print symtrack object's parameters */ \ int SYMTRACK(_print)(SYMTRACK() _q); \ \ /* Reset symtrack internal state */ \ int SYMTRACK(_reset)(SYMTRACK() _q); \ \ /* Get symtrack filter type */ \ int SYMTRACK(_get_ftype)(SYMTRACK() _q); \ \ /* Get symtrack samples per symbol */ \ unsigned int SYMTRACK(_get_k)(SYMTRACK() _q); \ \ /* Get symtrack filter semi-length [symbols] */ \ unsigned int SYMTRACK(_get_m)(SYMTRACK() _q); \ \ /* Get symtrack filter excess bandwidth factor */ \ float SYMTRACK(_get_beta)(SYMTRACK() _q); \ \ /* Get symtrack modulation scheme */ \ int SYMTRACK(_get_modscheme)(SYMTRACK() _q); \ \ /* Set symtrack modulation scheme */ \ /* _q : symtrack object */ \ /* _ms : modulation scheme, _ms(LIQUID_MODEM_BPSK) */ \ int SYMTRACK(_set_modscheme)(SYMTRACK() _q, \ int _ms); \ \ /* Get symtrack internal bandwidth */ \ float SYMTRACK(_get_bandwidth)(SYMTRACK() _q); \ \ /* Set symtrack internal bandwidth */ \ /* _q : symtrack object */ \ /* _bw : tracking bandwidth, _bw > 0 */ \ int SYMTRACK(_set_bandwidth)(SYMTRACK() _q, \ float _bw); \ \ /* Adjust internal NCO by requested frequency */ \ /* _q : symtrack object */ \ /* _dphi : NCO phase adjustment [radians] */ \ int SYMTRACK(_adjust_frequency)(SYMTRACK() _q, \ T _dphi); \ \ /* Adjust internal NCO by requested phase */ \ /* _q : symtrack object */ \ /* _phi : NCO phase adjustment [radians] */ \ int SYMTRACK(_adjust_phase)(SYMTRACK() _q, \ T _phi); \ \ /* Set symtrack equalization strategy to constant modulus (default) */ \ int SYMTRACK(_set_eq_cm)(SYMTRACK() _q); \ \ /* Set symtrack equalization strategy to decision directed */ \ int SYMTRACK(_set_eq_dd)(SYMTRACK() _q); \ \ /* Disable symtrack equalization */ \ int SYMTRACK(_set_eq_off)(SYMTRACK() _q); \ \ /* Execute synchronizer on single input sample */ \ /* _q : synchronizer object */ \ /* _x : input data sample */ \ /* _y : output data array, [size: 2 x 1] */ \ /* _ny : number of samples written to output buffer (0, 1, or 2) */ \ int SYMTRACK(_execute)(SYMTRACK() _q, \ TI _x, \ TO * _y, \ unsigned int * _ny); \ \ /* execute synchronizer on input data array */ \ /* _q : synchronizer object */ \ /* _x : input data array */ \ /* _nx : number of input samples */ \ /* _y : output data array, [size: 2 _nx x 1] */ \ /* _ny : number of samples written to output buffer */ \ int SYMTRACK(_execute_block)(SYMTRACK() _q, \ TI * _x, \ unsigned int _nx, \ TO * _y, \ unsigned int * _ny); \ LIQUID_SYMTRACK_DEFINE_API(LIQUID_SYMTRACK_MANGLE_RRRF, float, float, float, float) LIQUID_SYMTRACK_DEFINE_API(LIQUID_SYMTRACK_MANGLE_CCCF, float, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // MODULE : math // // ln( Gamma(z) ) float liquid_lngammaf(float _z); // Gamma(z) float liquid_gammaf(float _z); // ln( gamma(z,alpha) ) : lower incomplete gamma function float liquid_lnlowergammaf(float _z, float _alpha); // ln( Gamma(z,alpha) ) : upper incomplete gamma function float liquid_lnuppergammaf(float _z, float _alpha); // gamma(z,alpha) : lower incomplete gamma function float liquid_lowergammaf(float _z, float _alpha); // Gamma(z,alpha) : upper incomplete gamma function float liquid_uppergammaf(float _z, float _alpha); // n! float liquid_factorialf(unsigned int _n); // ln(I_v(z)) : log Modified Bessel function of the first kind float liquid_lnbesselif(float _nu, float _z); // I_v(z) : Modified Bessel function of the first kind float liquid_besselif(float _nu, float _z); // I_0(z) : Modified Bessel function of the first kind (order zero) float liquid_besseli0f(float _z); // J_v(z) : Bessel function of the first kind float liquid_besseljf(float _nu, float _z); // J_0(z) : Bessel function of the first kind (order zero) float liquid_besselj0f(float _z); // Q function float liquid_Qf(float _z); // Marcum Q-function float liquid_MarcumQf(int _M, float _alpha, float _beta); // Marcum Q-function (M=1) float liquid_MarcumQ1f(float _alpha, float _beta); // sin(pi x) / (pi x) float sincf(float _x); // next power of 2 : y = ceil(log2(_x)) unsigned int liquid_nextpow2(unsigned int _x); // (n choose k) = n! / ( k! (n-k)! ) float liquid_nchoosek(unsigned int _n, unsigned int _k); // // Windowing functions // // number of window functions available, including "unknown" type #define LIQUID_WINDOW_NUM_FUNCTIONS (10) // prototypes typedef enum { LIQUID_WINDOW_UNKNOWN=0, // unknown/unsupported scheme LIQUID_WINDOW_HAMMING, // Hamming LIQUID_WINDOW_HANN, // Hann LIQUID_WINDOW_BLACKMANHARRIS, // Blackman-harris (4-term) LIQUID_WINDOW_BLACKMANHARRIS7, // Blackman-harris (7-term) LIQUID_WINDOW_KAISER, // Kaiser (beta factor unspecified) LIQUID_WINDOW_FLATTOP, // flat top (includes negative values) LIQUID_WINDOW_TRIANGULAR, // triangular LIQUID_WINDOW_RCOSTAPER, // raised-cosine taper (taper size unspecified) LIQUID_WINDOW_KBD, // Kaiser-Bessel derived window (beta factor unspecified) } liquid_window_type; // pretty names for window extern const char * liquid_window_str[LIQUID_WINDOW_NUM_FUNCTIONS][2]; // Print compact list of existing and available windowing functions void liquid_print_windows(); // returns window type based on input string liquid_window_type liquid_getopt_str2window(const char * _str); // generic window function given type // _type : window type, e.g. LIQUID_WINDOW_KAISER // _i : window index, _i in [0,_wlen-1] // _wlen : length of window // _arg : window-specific argument, if required float liquid_windowf(liquid_window_type _type, unsigned int _i, unsigned int _wlen, float _arg); // Kaiser window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length // _beta : Kaiser-Bessel window shape parameter float liquid_kaiser(unsigned int _i, unsigned int _wlen, float _beta); // Hamming window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length float liquid_hamming(unsigned int _i, unsigned int _wlen); // Hann window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length float liquid_hann(unsigned int _i, unsigned int _wlen); // Blackman-harris window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length float liquid_blackmanharris(unsigned int _i, unsigned int _wlen); // 7th order Blackman-harris window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length float liquid_blackmanharris7(unsigned int _i, unsigned int _wlen); // Flat-top window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length float liquid_flattop(unsigned int _i, unsigned int _wlen); // Triangular window // _i : window index, _i in [0,_wlen-1] // _wlen : full window length // _L : triangle length, _L in {_wlen-1, _wlen, _wlen+1} float liquid_triangular(unsigned int _i, unsigned int _wlen, unsigned int _L); // raised-cosine tapering window // _i : window index // _wlen : full window length // _t : taper length, _t in [0,_wlen/2] float liquid_rcostaper_window(unsigned int _i, unsigned int _wlen, unsigned int _t); // Kaiser-Bessel derived window (single sample) // _i : window index, _i in [0,_wlen-1] // _wlen : length of filter (must be even) // _beta : Kaiser window parameter (_beta > 0) float liquid_kbd(unsigned int _i, unsigned int _wlen, float _beta); // Kaiser-Bessel derived window (full window) // _wlen : full window length (must be even) // _beta : Kaiser window parameter (_beta > 0) // _w : window output buffer, [size: _wlen x 1] int liquid_kbd_window(unsigned int _wlen, float _beta, float * _w); // polynomials #define LIQUID_POLY_MANGLE_DOUBLE(name) LIQUID_CONCAT(poly, name) #define LIQUID_POLY_MANGLE_FLOAT(name) LIQUID_CONCAT(polyf, name) #define LIQUID_POLY_MANGLE_CDOUBLE(name) LIQUID_CONCAT(polyc, name) #define LIQUID_POLY_MANGLE_CFLOAT(name) LIQUID_CONCAT(polycf, name) // large macro // POLY : name-mangling macro // T : data type // TC : data type (complex) #define LIQUID_POLY_DEFINE_API(POLY,T,TC) \ \ /* Evaluate polynomial _p at value _x */ \ /* _p : polynomial coefficients [size _k x 1] */ \ /* _k : polynomial coefficients length, order is _k - 1 */ \ /* _x : input to evaluate polynomial */ \ T POLY(_val)(T * _p, \ unsigned int _k, \ T _x); \ \ /* Perform least-squares polynomial fit on data set */ \ /* _x : x-value sample set [size: _n x 1] */ \ /* _y : y-value sample set [size: _n x 1] */ \ /* _n : number of samples in _x and _y */ \ /* _p : polynomial coefficients output [size _k x 1] */ \ /* _k : polynomial coefficients length, order is _k - 1 */ \ int POLY(_fit)(T * _x, \ T * _y, \ unsigned int _n, \ T * _p, \ unsigned int _k); \ \ /* Perform Lagrange polynomial exact fit on data set */ \ /* _x : x-value sample set, size [_n x 1] */ \ /* _y : y-value sample set, size [_n x 1] */ \ /* _n : number of samples in _x and _y */ \ /* _p : polynomial coefficients output [size _n x 1] */ \ int POLY(_fit_lagrange)(T * _x, \ T * _y, \ unsigned int _n, \ T * _p); \ \ /* Perform Lagrange polynomial interpolation on data set without */ \ /* computing coefficients as an intermediate step. */ \ /* _x : x-value sample set [size: _n x 1] */ \ /* _y : y-value sample set [size: _n x 1] */ \ /* _n : number of samples in _x and _y */ \ /* _x0 : x-value to evaluate and compute interpolant */ \ T POLY(_interp_lagrange)(T * _x, \ T * _y, \ unsigned int _n, \ T _x0); \ \ /* Compute Lagrange polynomial fit in the barycentric form. */ \ /* _x : x-value sample set, size [_n x 1] */ \ /* _n : number of samples in _x */ \ /* _w : barycentric weights normalized so _w[0]=1, size [_n x 1] */ \ int POLY(_fit_lagrange_barycentric)(T * _x, \ unsigned int _n, \ T * _w); \ \ /* Perform Lagrange polynomial interpolation using the barycentric form */ \ /* of the weights. */ \ /* _x : x-value sample set [size: _n x 1] */ \ /* _y : y-value sample set [size: _n x 1] */ \ /* _w : barycentric weights [size: _n x 1] */ \ /* _x0 : x-value to evaluate and compute interpolant */ \ /* _n : number of samples in _x, _y, and _w */ \ T POLY(_val_lagrange_barycentric)(T * _x, \ T * _y, \ T * _w, \ T _x0, \ unsigned int _n); \ \ /* Perform binomial expansion on the polynomial */ \ /* \( P_n(x) = (1+x)^n \) */ \ /* as */ \ /* \( P_n(x) = p[0] + p[1]x + p[2]x^2 + ... + p[n]x^n \) */ \ /* NOTE: _p has order n (coefficients has length n+1) */ \ /* _n : polynomial order */ \ /* _p : polynomial coefficients [size: _n+1 x 1] */ \ int POLY(_expandbinomial)(unsigned int _n, \ T * _p); \ \ /* Perform positive/negative binomial expansion on the polynomial */ \ /* \( P_n(x) = (1+x)^m (1-x)^k \) */ \ /* as */ \ /* \( P_n(x) = p[0] + p[1]x + p[2]x^2 + ... + p[n]x^n \) */ \ /* NOTE: _p has order n=m+k (array is length n+1) */ \ /* _m : number of '1+x' terms */ \ /* _k : number of '1-x' terms */ \ /* _p : polynomial coefficients [size: _m+_k+1 x 1] */ \ int POLY(_expandbinomial_pm)(unsigned int _m, \ unsigned int _k, \ T * _p); \ \ /* Perform root expansion on the polynomial */ \ /* \( P_n(x) = (x-r[0]) (x-r[1]) ... (x-r[n-1]) \) */ \ /* as */ \ /* \( P_n(x) = p[0] + p[1]x + ... + p[n]x^n \) */ \ /* where \( r[0],r[1],...,r[n-1]\) are the roots of \( P_n(x) \). */ \ /* NOTE: _p has order _n (array is length _n+1) */ \ /* _r : roots of polynomial [size: _n x 1] */ \ /* _n : number of roots in polynomial */ \ /* _p : polynomial coefficients [size: _n+1 x 1] */ \ int POLY(_expandroots)(T * _r, \ unsigned int _n, \ T * _p); \ \ /* Perform root expansion on the polynomial */ \ /* \( P_n(x) = (xb[0]-a[0]) (xb[1]-a[1])...(xb[n-1]-a[n-1]) \) */ \ /* as */ \ /* \( P_n(x) = p[0] + p[1]x + ... + p[n]x^n \) */ \ /* NOTE: _p has order _n (array is length _n+1) */ \ /* _a : subtractant of polynomial rotos [size: _n x 1] */ \ /* _b : multiplicant of polynomial roots [size: _n x 1] */ \ /* _n : number of roots in polynomial */ \ /* _p : polynomial coefficients [size: _n+1 x 1] */ \ int POLY(_expandroots2)(T * _a, \ T * _b, \ unsigned int _n, \ T * _p); \ \ /* Find the complex roots of a polynomial. */ \ /* _p : polynomial coefficients [size: _n x 1] */ \ /* _k : polynomial length */ \ /* _roots : resulting complex roots [size: _k-1 x 1] */ \ int POLY(_findroots)(T * _poly, \ unsigned int _n, \ TC * _roots); \ \ /* Find the complex roots of the polynomial using the Durand-Kerner */ \ /* method */ \ /* _p : polynomial coefficients [size: _n x 1] */ \ /* _k : polynomial length */ \ /* _roots : resulting complex roots [size: _k-1 x 1] */ \ int POLY(_findroots_durandkerner)(T * _p, \ unsigned int _k, \ TC * _roots); \ \ /* Find the complex roots of the polynomial using Bairstow's method. */ \ /* _p : polynomial coefficients [size: _n x 1] */ \ /* _k : polynomial length */ \ /* _roots : resulting complex roots [size: _k-1 x 1] */ \ int POLY(_findroots_bairstow)(T * _p, \ unsigned int _k, \ TC * _roots); \ \ /* Expand the multiplication of two polynomials */ \ /* \( ( a[0] + a[1]x + a[2]x^2 + ...) (b[0] + b[1]x + b[]x^2 + ...) \) */ \ /* as */ \ /* \( c[0] + c[1]x + c[2]x^2 + ... + c[n]x^n \) */ \ /* where order(c) = order(a) + order(b) + 1 */ \ /* and therefore length(c) = length(a) + length(b) - 1 */ \ /* _a : 1st polynomial coefficients (length is _order_a+1) */ \ /* _order_a : 1st polynomial order */ \ /* _b : 2nd polynomial coefficients (length is _order_b+1) */ \ /* _order_b : 2nd polynomial order */ \ /* _c : output polynomial [size: _order_a+_order_b+1 x 1] */ \ int POLY(_mul)(T * _a, \ unsigned int _order_a, \ T * _b, \ unsigned int _order_b, \ T * _c); \ LIQUID_POLY_DEFINE_API(LIQUID_POLY_MANGLE_DOUBLE, double, liquid_double_complex) LIQUID_POLY_DEFINE_API(LIQUID_POLY_MANGLE_FLOAT, float, liquid_float_complex) LIQUID_POLY_DEFINE_API(LIQUID_POLY_MANGLE_CDOUBLE, liquid_double_complex, liquid_double_complex) LIQUID_POLY_DEFINE_API(LIQUID_POLY_MANGLE_CFLOAT, liquid_float_complex, liquid_float_complex) #if 0 // expands the polynomial: (1+x)^n void poly_binomial_expand(unsigned int _n, int * _c); // expands the polynomial: (1+x)^k * (1-x)^(n-k) void poly_binomial_expand_pm(unsigned int _n, unsigned int _k, int * _c); #endif // // modular arithmetic, etc. // // maximum number of factors #define LIQUID_MAX_FACTORS (40) // is number prime? int liquid_is_prime(unsigned int _n); // compute number's prime factors // _n : number to factor // _factors : pre-allocated array of factors [size: LIQUID_MAX_FACTORS x 1] // _num_factors: number of factors found, sorted ascending int liquid_factor(unsigned int _n, unsigned int * _factors, unsigned int * _num_factors); // compute number's unique prime factors // _n : number to factor // _factors : pre-allocated array of factors [size: LIQUID_MAX_FACTORS x 1] // _num_factors: number of unique factors found, sorted ascending int liquid_unique_factor(unsigned int _n, unsigned int * _factors, unsigned int * _num_factors); // compute greatest common divisor between to numbers P and Q unsigned int liquid_gcd(unsigned int _P, unsigned int _Q); // compute c = base^exp (mod n) unsigned int liquid_modpow(unsigned int _base, unsigned int _exp, unsigned int _n); // find smallest primitive root of _n unsigned int liquid_primitive_root(unsigned int _n); // find smallest primitive root of _n, assuming _n is prime unsigned int liquid_primitive_root_prime(unsigned int _n); // Euler's totient function unsigned int liquid_totient(unsigned int _n); // // MODULE : matrix // #define LIQUID_MATRIX_MANGLE_DOUBLE(name) LIQUID_CONCAT(matrix, name) #define LIQUID_MATRIX_MANGLE_FLOAT(name) LIQUID_CONCAT(matrixf, name) #define LIQUID_MATRIX_MANGLE_CDOUBLE(name) LIQUID_CONCAT(matrixc, name) #define LIQUID_MATRIX_MANGLE_CFLOAT(name) LIQUID_CONCAT(matrixcf, name) // large macro // MATRIX : name-mangling macro // T : data type #define LIQUID_MATRIX_DEFINE_API(MATRIX,T) \ \ /* Print array as matrix to stdout */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _r : rows in matrix */ \ /* _c : columns in matrix */ \ int MATRIX(_print)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Perform point-wise addition between two matrices \(\vec{X}\) */ \ /* and \(\vec{Y}\), saving the result in the output matrix \(\vec{Z}\). */ \ /* That is, \(\vec{Z}_{i,j}=\vec{X}_{i,j}+\vec{Y}_{i,j} \), */ \ /* \( \forall_{i \in r} \) and \( \forall_{j \in c} \) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _y : input matrix, [size: _r x _c] */ \ /* _z : output matrix, [size: _r x _c] */ \ /* _r : number of rows in each matrix */ \ /* _c : number of columns in each matrix */ \ int MATRIX(_add)(T * _x, \ T * _y, \ T * _z, \ unsigned int _r, \ unsigned int _c); \ \ /* Perform point-wise subtraction between two matrices \(\vec{X}\) */ \ /* and \(\vec{Y}\), saving the result in the output matrix \(\vec{Z}\) */ \ /* That is, \(\vec{Z}_{i,j}=\vec{X}_{i,j}-\vec{Y}_{i,j} \), */ \ /* \( \forall_{i \in r} \) and \( \forall_{j \in c} \) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _y : input matrix, [size: _r x _c] */ \ /* _z : output matrix, [size: _r x _c] */ \ /* _r : number of rows in each matrix */ \ /* _c : number of columns in each matrix */ \ int MATRIX(_sub)(T * _x, \ T * _y, \ T * _z, \ unsigned int _r, \ unsigned int _c); \ \ /* Perform point-wise multiplication between two matrices \(\vec{X}\) */ \ /* and \(\vec{Y}\), saving the result in the output matrix \(\vec{Z}\) */ \ /* That is, \(\vec{Z}_{i,j}=\vec{X}_{i,j} \vec{Y}_{i,j} \), */ \ /* \( \forall_{i \in r} \) and \( \forall_{j \in c} \) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _y : input matrix, [size: _r x _c] */ \ /* _z : output matrix, [size: _r x _c] */ \ /* _r : number of rows in each matrix */ \ /* _c : number of columns in each matrix */ \ int MATRIX(_pmul)(T * _x, \ T * _y, \ T * _z, \ unsigned int _r, \ unsigned int _c); \ \ /* Perform point-wise division between two matrices \(\vec{X}\) */ \ /* and \(\vec{Y}\), saving the result in the output matrix \(\vec{Z}\) */ \ /* That is, \(\vec{Z}_{i,j}=\vec{X}_{i,j}/\vec{Y}_{i,j} \), */ \ /* \( \forall_{i \in r} \) and \( \forall_{j \in c} \) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _y : input matrix, [size: _r x _c] */ \ /* _z : output matrix, [size: _r x _c] */ \ /* _r : number of rows in each matrix */ \ /* _c : number of columns in each matrix */ \ int MATRIX(_pdiv)(T * _x, \ T * _y, \ T * _z, \ unsigned int _r, \ unsigned int _c); \ \ /* Multiply two matrices \(\vec{X}\) and \(\vec{Y}\), storing the */ \ /* result in \(\vec{Z}\). */ \ /* NOTE: _rz = _rx, _cz = _cy, and _cx = _ry */ \ /* _x : input matrix, [size: _rx x _cx] */ \ /* _rx : number of rows in _x */ \ /* _cx : number of columns in _x */ \ /* _y : input matrix, [size: _ry x _cy] */ \ /* _ry : number of rows in _y */ \ /* _cy : number of columns in _y */ \ /* _z : output matrix, [size: _rz x _cz] */ \ /* _rz : number of rows in _z */ \ /* _cz : number of columns in _z */ \ int MATRIX(_mul)(T * _x, unsigned int _rx, unsigned int _cx, \ T * _y, unsigned int _ry, unsigned int _cy, \ T * _z, unsigned int _rz, unsigned int _cz); \ \ /* Solve \(\vec{X} = \vec{Y} \vec{Z}\) for \(\vec{Z}\) for square */ \ /* matrices of size \(n\) */ \ /* _x : input matrix, [size: _n x _n] */ \ /* _y : input matrix, [size: _n x _n] */ \ /* _z : output matrix, [size: _n x _n] */ \ /* _n : number of rows and columns in each matrix */ \ int MATRIX(_div)(T * _x, \ T * _y, \ T * _z, \ unsigned int _n); \ \ /* Compute the determinant of a square matrix \(\vec{X}\) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ T MATRIX(_det)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Compute the in-place transpose of the matrix \(\vec{X}\) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ int MATRIX(_trans)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Compute the in-place Hermitian transpose of the matrix \(\vec{X}\) */ \ /* _x : input matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ int MATRIX(_hermitian)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Compute \(\vec{X}\vec{X}^T\) on a \(m \times n\) matrix. */ \ /* The result is a \(m \times m\) matrix. */ \ /* _x : input matrix, [size: _m x _n] */ \ /* _m : input rows */ \ /* _n : input columns */ \ /* _xxT : output matrix, [size: _m x _m] */ \ int MATRIX(_mul_transpose)(T * _x, \ unsigned int _m, \ unsigned int _n, \ T * _xxT); \ \ /* Compute \(\vec{X}^T\vec{X}\) on a \(m \times n\) matrix. */ \ /* The result is a \(n \times n\) matrix. */ \ /* _x : input matrix, [size: _m x _n] */ \ /* _m : input rows */ \ /* _n : input columns */ \ /* _xTx : output matrix, [size: _n x _n] */ \ int MATRIX(_transpose_mul)(T * _x, \ unsigned int _m, \ unsigned int _n, \ T * _xTx); \ \ /* Compute \(\vec{X}\vec{X}^H\) on a \(m \times n\) matrix. */ \ /* The result is a \(m \times m\) matrix. */ \ /* _x : input matrix, [size: _m x _n] */ \ /* _m : input rows */ \ /* _n : input columns */ \ /* _xxH : output matrix, [size: _m x _m] */ \ int MATRIX(_mul_hermitian)(T * _x, \ unsigned int _m, \ unsigned int _n, \ T * _xxH); \ \ /* Compute \(\vec{X}^H\vec{X}\) on a \(m \times n\) matrix. */ \ /* The result is a \(n \times n\) matrix. */ \ /* _x : input matrix, [size: _m x _n] */ \ /* _m : input rows */ \ /* _n : input columns */ \ /* _xHx : output matrix, [size: _n x _n] */ \ int MATRIX(_hermitian_mul)(T * _x, \ unsigned int _m, \ unsigned int _n, \ T * _xHx); \ \ \ /* Augment two matrices \(\vec{X}\) and \(\vec{Y}\), storing the result */ \ /* in \(\vec{Z}\) */ \ /* NOTE: _rz = _rx = _ry, _rx = _ry, and _cz = _cx + _cy */ \ /* _x : input matrix, [size: _rx x _cx] */ \ /* _rx : number of rows in _x */ \ /* _cx : number of columns in _x */ \ /* _y : input matrix, [size: _ry x _cy] */ \ /* _ry : number of rows in _y */ \ /* _cy : number of columns in _y */ \ /* _z : output matrix, [size: _rz x _cz] */ \ /* _rz : number of rows in _z */ \ /* _cz : number of columns in _z */ \ int MATRIX(_aug)(T * _x, unsigned int _rx, unsigned int _cx, \ T * _y, unsigned int _ry, unsigned int _cy, \ T * _z, unsigned int _rz, unsigned int _cz); \ \ /* Compute the inverse of a square matrix \(\vec{X}\) */ \ /* _x : input/output matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ int MATRIX(_inv)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Generate the identity square matrix of size \(n\) */ \ /* _x : output matrix, [size: _n x _n] */ \ /* _n : dimensions of _x */ \ int MATRIX(_eye)(T * _x, \ unsigned int _n); \ \ /* Generate the all-ones matrix of size \(n\) */ \ /* _x : output matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ int MATRIX(_ones)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Generate the all-zeros matrix of size \(n\) */ \ /* _x : output matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ int MATRIX(_zeros)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Perform Gauss-Jordan elimination on matrix \(\vec{X}\) */ \ /* _x : input/output matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ int MATRIX(_gjelim)(T * _x, \ unsigned int _r, \ unsigned int _c); \ \ /* Pivot on element \(\vec{X}_{i,j}\) */ \ /* _x : output matrix, [size: _r x _c] */ \ /* _r : rows of _x */ \ /* _c : columns of _x */ \ /* _i : pivot row */ \ /* _j : pivot column */ \ int MATRIX(_pivot)(T * _x, \ unsigned int _r, \ unsigned int _c, \ unsigned int _i, \ unsigned int _j); \ \ /* Swap rows _r1 and _r2 of matrix \(\vec{X}\) */ \ /* _x : input/output matrix, [size: _r x _c] */ \ /* _r : rows of _x */ \ /* _c : columns of _x */ \ /* _r1 : first row to swap */ \ /* _r2 : second row to swap */ \ int MATRIX(_swaprows)(T * _x, \ unsigned int _r, \ unsigned int _c, \ unsigned int _r1, \ unsigned int _r2); \ \ /* Solve linear system of \(n\) equations: \(\vec{A}\vec{x} = \vec{b}\) */ \ /* _A : system matrix, [size: _n x _n] */ \ /* _n : system size */ \ /* _b : equality vector, [size: _n x 1] */ \ /* _x : solution vector, [size: _n x 1] */ \ /* _opts : options (ignored for now) */ \ int MATRIX(_linsolve)(T * _A, \ unsigned int _n, \ T * _b, \ T * _x, \ void * _opts); \ \ /* Solve linear system of equations using conjugate gradient method. */ \ /* _A : symmetric positive definite square matrix */ \ /* _n : system dimension */ \ /* _b : equality, [size: _n x 1] */ \ /* _x : solution estimate, [size: _n x 1] */ \ /* _opts : options (ignored for now) */ \ int MATRIX(_cgsolve)(T * _A, \ unsigned int _n, \ T * _b, \ T * _x, \ void * _opts); \ \ /* Perform L/U/P decomposition using Crout's method */ \ /* _x : input/output matrix, [size: _rx x _cx] */ \ /* _rx : rows of _x */ \ /* _cx : columns of _x */ \ /* _L : first row to swap */ \ /* _U : first row to swap */ \ /* _P : first row to swap */ \ int MATRIX(_ludecomp_crout)(T * _x, \ unsigned int _rx, \ unsigned int _cx, \ T * _L, \ T * _U, \ T * _P); \ \ /* Perform L/U/P decomposition, Doolittle's method */ \ /* _x : input/output matrix, [size: _rx x _cx] */ \ /* _rx : rows of _x */ \ /* _cx : columns of _x */ \ /* _L : first row to swap */ \ /* _U : first row to swap */ \ /* _P : first row to swap */ \ int MATRIX(_ludecomp_doolittle)(T * _x, \ unsigned int _rx, \ unsigned int _cx, \ T * _L, \ T * _U, \ T * _P); \ \ /* Perform orthnormalization using the Gram-Schmidt algorithm */ \ /* _A : input matrix, [size: _r x _c] */ \ /* _r : rows */ \ /* _c : columns */ \ /* _v : output matrix */ \ int MATRIX(_gramschmidt)(T * _A, \ unsigned int _r, \ unsigned int _c, \ T * _v); \ \ /* Perform Q/R decomposition using the Gram-Schmidt algorithm such that */ \ /* \( \vec{A} = \vec{Q} \vec{R} \) */ \ /* and \( \vec{Q}^T \vec{Q} = \vec{I}_n \) */ \ /* and \(\vec{R\}\) is a diagonal \(m \times m\) matrix */ \ /* NOTE: all matrices are square */ \ /* _A : input matrix, [size: _m x _m] */ \ /* _m : rows */ \ /* _n : columns (same as cols) */ \ /* _Q : output matrix, [size: _m x _m] */ \ /* _R : output matrix, [size: _m x _m] */ \ int MATRIX(_qrdecomp_gramschmidt)(T * _A, \ unsigned int _m, \ unsigned int _n, \ T * _Q, \ T * _R); \ \ /* Compute Cholesky decomposition of a symmetric/Hermitian */ \ /* positive-definite matrix as \( \vec{A} = \vec{L}\vec{L}^T \) */ \ /* _A : input square matrix, [size: _n x _n] */ \ /* _n : input matrix dimension */ \ /* _L : output lower-triangular matrix */ \ int MATRIX(_chol)(T * _A, \ unsigned int _n, \ T * _L); \ #define matrix_access(X,R,C,r,c) ((X)[(r)*(C)+(c)]) #define matrixc_access(X,R,C,r,c) matrix_access(X,R,C,r,c) #define matrixf_access(X,R,C,r,c) matrix_access(X,R,C,r,c) #define matrixcf_access(X,R,C,r,c) matrix_access(X,R,C,r,c) LIQUID_MATRIX_DEFINE_API(LIQUID_MATRIX_MANGLE_FLOAT, float) LIQUID_MATRIX_DEFINE_API(LIQUID_MATRIX_MANGLE_DOUBLE, double) LIQUID_MATRIX_DEFINE_API(LIQUID_MATRIX_MANGLE_CFLOAT, liquid_float_complex) LIQUID_MATRIX_DEFINE_API(LIQUID_MATRIX_MANGLE_CDOUBLE, liquid_double_complex) #define LIQUID_SMATRIX_MANGLE_BOOL(name) LIQUID_CONCAT(smatrixb, name) #define LIQUID_SMATRIX_MANGLE_FLOAT(name) LIQUID_CONCAT(smatrixf, name) #define LIQUID_SMATRIX_MANGLE_INT(name) LIQUID_CONCAT(smatrixi, name) // sparse 'alist' matrix type (similar to MacKay, Davey Lafferty convention) // large macro // SMATRIX : name-mangling macro // T : primitive data type #define LIQUID_SMATRIX_DEFINE_API(SMATRIX,T) \ \ /* Sparse matrix object (similar to MacKay, Davey, Lafferty convention) */ \ typedef struct SMATRIX(_s) * SMATRIX(); \ \ /* Create _M x _N sparse matrix, initialized with zeros */ \ SMATRIX() SMATRIX(_create)(unsigned int _M, \ unsigned int _N); \ \ /* Create _M x _N sparse matrix, initialized on array */ \ /* _x : input matrix, [size: _m x _n] */ \ /* _m : number of rows in input matrix */ \ /* _n : number of columns in input matrix */ \ SMATRIX() SMATRIX(_create_array)(T * _x, \ unsigned int _m, \ unsigned int _n); \ \ /* Destroy object, freeing all internal memory */ \ int SMATRIX(_destroy)(SMATRIX() _q); \ \ /* Print sparse matrix in compact form to stdout */ \ int SMATRIX(_print)(SMATRIX() _q); \ \ /* Print sparse matrix in expanded form to stdout */ \ int SMATRIX(_print_expanded)(SMATRIX() _q); \ \ /* Get size of sparse matrix (number of rows and columns) */ \ /* _q : sparse matrix object */ \ /* _m : number of rows in matrix */ \ /* _n : number of columns in matrix */ \ int SMATRIX(_size)(SMATRIX() _q, \ unsigned int * _m, \ unsigned int * _n); \ \ /* Zero all elements and retain allocated memory */ \ int SMATRIX(_clear)(SMATRIX() _q); \ \ /* Zero all elements and clear memory */ \ int SMATRIX(_reset)(SMATRIX() _q); \ \ /* Determine if value has been set (allocated memory) */ \ /* _q : sparse matrix object */ \ /* _m : row index of value to query */ \ /* _n : column index of value to query */ \ int SMATRIX(_isset)(SMATRIX() _q, \ unsigned int _m, \ unsigned int _n); \ \ /* Insert an element at index, allocating memory as necessary */ \ /* _q : sparse matrix object */ \ /* _m : row index of value to insert */ \ /* _n : column index of value to insert */ \ /* _v : value to insert */ \ int SMATRIX(_insert)(SMATRIX() _q, \ unsigned int _m, \ unsigned int _n, \ T _v); \ \ /* Delete an element at index, freeing memory */ \ /* _q : sparse matrix object */ \ /* _m : row index of value to delete */ \ /* _n : column index of value to delete */ \ int SMATRIX(_delete)(SMATRIX() _q, \ unsigned int _m, \ unsigned int _n); \ \ /* Set the value in matrix at specified row and column, allocating */ \ /* memory if needed */ \ /* _q : sparse matrix object */ \ /* _m : row index of value to set */ \ /* _n : column index of value to set */ \ /* _v : value to set in matrix */ \ int SMATRIX(_set)(SMATRIX() _q, \ unsigned int _m, \ unsigned int _n, \ T _v); \ \ /* Get the value from matrix at specified row and column */ \ /* _q : sparse matrix object */ \ /* _m : row index of value to get */ \ /* _n : column index of value to get */ \ T SMATRIX(_get)(SMATRIX() _q, \ unsigned int _m, \ unsigned int _n); \ \ /* Initialize to identity matrix; set all diagonal elements to 1, all */ \ /* others to 0. This is done with both square and non-square matrices. */ \ int SMATRIX(_eye)(SMATRIX() _q); \ \ /* Multiply two sparse matrices, \( \vec{Z} = \vec{X} \vec{Y} \) */ \ /* _x : sparse matrix object (input) */ \ /* _y : sparse matrix object (input) */ \ /* _z : sparse matrix object (output) */ \ int SMATRIX(_mul)(SMATRIX() _x, \ SMATRIX() _y, \ SMATRIX() _z); \ \ /* Multiply sparse matrix by vector */ \ /* _q : sparse matrix */ \ /* _x : input vector, [size: _n x 1] */ \ /* _y : output vector, [size: _m x 1] */ \ int SMATRIX(_vmul)(SMATRIX() _q, \ T * _x, \ T * _y); \ LIQUID_SMATRIX_DEFINE_API(LIQUID_SMATRIX_MANGLE_BOOL, unsigned char) LIQUID_SMATRIX_DEFINE_API(LIQUID_SMATRIX_MANGLE_FLOAT, float) LIQUID_SMATRIX_DEFINE_API(LIQUID_SMATRIX_MANGLE_INT, short int) // // smatrix cross methods // // multiply sparse binary matrix by floating-point matrix // _q : sparse matrix [size: A->M x A->N] // _x : input vector [size: mx x nx ] // _y : output vector [size: my x ny ] int smatrixb_mulf(smatrixb _A, float * _x, unsigned int _mx, unsigned int _nx, float * _y, unsigned int _my, unsigned int _ny); // multiply sparse binary matrix by floating-point vector // _q : sparse matrix // _x : input vector [size: _N x 1] // _y : output vector [size: _M x 1] int smatrixb_vmulf(smatrixb _q, float * _x, float * _y); // // MODULE : modem (modulator/demodulator) // // Maximum number of allowed bits per symbol #define MAX_MOD_BITS_PER_SYMBOL 8 // Modulation schemes available #define LIQUID_MODEM_NUM_SCHEMES (52) typedef enum { LIQUID_MODEM_UNKNOWN=0, // Unknown modulation scheme // Phase-shift keying (PSK) LIQUID_MODEM_PSK2, LIQUID_MODEM_PSK4, LIQUID_MODEM_PSK8, LIQUID_MODEM_PSK16, LIQUID_MODEM_PSK32, LIQUID_MODEM_PSK64, LIQUID_MODEM_PSK128, LIQUID_MODEM_PSK256, // Differential phase-shift keying (DPSK) LIQUID_MODEM_DPSK2, LIQUID_MODEM_DPSK4, LIQUID_MODEM_DPSK8, LIQUID_MODEM_DPSK16, LIQUID_MODEM_DPSK32, LIQUID_MODEM_DPSK64, LIQUID_MODEM_DPSK128, LIQUID_MODEM_DPSK256, // amplitude-shift keying LIQUID_MODEM_ASK2, LIQUID_MODEM_ASK4, LIQUID_MODEM_ASK8, LIQUID_MODEM_ASK16, LIQUID_MODEM_ASK32, LIQUID_MODEM_ASK64, LIQUID_MODEM_ASK128, LIQUID_MODEM_ASK256, // rectangular quadrature amplitude-shift keying (QAM) LIQUID_MODEM_QAM4, LIQUID_MODEM_QAM8, LIQUID_MODEM_QAM16, LIQUID_MODEM_QAM32, LIQUID_MODEM_QAM64, LIQUID_MODEM_QAM128, LIQUID_MODEM_QAM256, // amplitude phase-shift keying (APSK) LIQUID_MODEM_APSK4, LIQUID_MODEM_APSK8, LIQUID_MODEM_APSK16, LIQUID_MODEM_APSK32, LIQUID_MODEM_APSK64, LIQUID_MODEM_APSK128, LIQUID_MODEM_APSK256, // specific modem types LIQUID_MODEM_BPSK, // Specific: binary PSK LIQUID_MODEM_QPSK, // specific: quaternary PSK LIQUID_MODEM_OOK, // Specific: on/off keying LIQUID_MODEM_SQAM32, // 'square' 32-QAM LIQUID_MODEM_SQAM128, // 'square' 128-QAM LIQUID_MODEM_V29, // V.29 star constellation LIQUID_MODEM_ARB16OPT, // optimal 16-QAM LIQUID_MODEM_ARB32OPT, // optimal 32-QAM LIQUID_MODEM_ARB64OPT, // optimal 64-QAM LIQUID_MODEM_ARB128OPT, // optimal 128-QAM LIQUID_MODEM_ARB256OPT, // optimal 256-QAM LIQUID_MODEM_ARB64VT, // Virginia Tech logo // arbitrary modem type LIQUID_MODEM_ARB // arbitrary QAM } modulation_scheme; // structure for holding full modulation type descriptor struct modulation_type_s { const char * name; // short name (e.g. 'bpsk') const char * fullname; // full name (e.g. 'binary phase-shift keying') modulation_scheme scheme; // modulation scheme (e.g. LIQUID_MODEM_BPSK) unsigned int bps; // modulation depth (e.g. 1) }; // full modulation type descriptor extern const struct modulation_type_s modulation_types[LIQUID_MODEM_NUM_SCHEMES]; // Print compact list of existing and available modulation schemes int liquid_print_modulation_schemes(); // returns modulation_scheme based on input string modulation_scheme liquid_getopt_str2mod(const char * _str); // query basic modulation types int liquid_modem_is_psk(modulation_scheme _ms); int liquid_modem_is_dpsk(modulation_scheme _ms); int liquid_modem_is_ask(modulation_scheme _ms); int liquid_modem_is_qam(modulation_scheme _ms); int liquid_modem_is_apsk(modulation_scheme _ms); // useful functions // counts the number of different bits between two symbols unsigned int count_bit_errors(unsigned int _s1, unsigned int _s2); // counts the number of different bits between two arrays of symbols // _msg0 : original message [size: _n x 1] // _msg1 : copy of original message [size: _n x 1] // _n : message size unsigned int count_bit_errors_array(unsigned char * _msg0, unsigned char * _msg1, unsigned int _n); // converts binary-coded decimal (BCD) to gray, ensuring successive values // differ by exactly one bit unsigned int gray_encode(unsigned int symbol_in); // converts a gray-encoded symbol to binary-coded decimal (BCD) unsigned int gray_decode(unsigned int symbol_in); // pack soft bits into symbol // _soft_bits : soft input bits [size: _bps x 1] // _bps : bits per symbol // _sym_out : output symbol, value in [0,2^_bps) int liquid_pack_soft_bits(unsigned char * _soft_bits, unsigned int _bps, unsigned int * _sym_out); // unpack soft bits into symbol // _sym_in : input symbol, value in [0,2^_bps) // _bps : bits per symbol // _soft_bits : soft output bits [size: _bps x 1] int liquid_unpack_soft_bits(unsigned int _sym_in, unsigned int _bps, unsigned char * _soft_bits); // // Linear modem // #define LIQUID_MODEM_MANGLE_FLOAT(name) LIQUID_CONCAT(modemcf,name) // Macro : MODEM // MODEM : name-mangling macro // T : primitive data type // TC : primitive data type (complex) #define LIQUID_MODEM_DEFINE_API(MODEM,T,TC) \ \ /* Linear modulator/demodulator (modem) object */ \ typedef struct MODEM(_s) * MODEM(); \ \ /* Create digital modem object with a particular scheme */ \ /* _scheme : linear modulation scheme (e.g. LIQUID_MODEM_QPSK) */ \ MODEM() MODEM(_create)(modulation_scheme _scheme); \ \ /* Create linear digital modem object with arbitrary constellation */ \ /* points defined by an external table of symbols. Sample points are */ \ /* provided as complex float pairs and converted internally if needed. */ \ /* _table : array of complex constellation points, [size: _M x 1] */ \ /* _M : modulation order and table size, _M must be power of 2 */ \ MODEM() MODEM(_create_arbitrary)(liquid_float_complex * _table, \ unsigned int _M); \ \ /* Recreate modulation scheme, re-allocating memory as necessary */ \ /* _q : modem object */ \ /* _scheme : linear modulation scheme (e.g. LIQUID_MODEM_QPSK) */ \ MODEM() MODEM(_recreate)(MODEM() _q, \ modulation_scheme _scheme); \ \ /* Destroy modem object, freeing all allocated memory */ \ int MODEM(_destroy)(MODEM() _q); \ \ /* Print modem status to stdout */ \ int MODEM(_print)(MODEM() _q); \ \ /* Reset internal state of modem object; note that this is only */ \ /* relevant for modulation types that retain an internal state such as */ \ /* LIQUID_MODEM_DPSK4 as most linear modulation types are stateless */ \ int MODEM(_reset)(MODEM() _q); \ \ /* Generate random symbol for modulation */ \ unsigned int MODEM(_gen_rand_sym)(MODEM() _q); \ \ /* Get number of bits per symbol (bps) of modem object */ \ unsigned int MODEM(_get_bps)(MODEM() _q); \ \ /* Get modulation scheme of modem object */ \ modulation_scheme MODEM(_get_scheme)(MODEM() _q); \ \ /* Modulate input symbol (bits) and generate output complex sample */ \ /* _q : modem object */ \ /* _s : input symbol, 0 <= _s <= M-1 */ \ /* _y : output complex sample */ \ int MODEM(_modulate)(MODEM() _q, \ unsigned int _s, \ TC * _y); \ \ /* Demodulate input sample and provide maximum-likelihood estimate of */ \ /* symbol that would have generated it. */ \ /* The output is a hard decision value on the input sample. */ \ /* This is performed efficiently by taking advantage of symmetry on */ \ /* most modulation types. */ \ /* For example, square and rectangular quadrature amplitude modulation */ \ /* with gray coding can use a bisection search indepdently on its */ \ /* in-phase and quadrature channels. */ \ /* Arbitrary modulation schemes are relatively slow, however, for large */ \ /* modulation types as the demodulator must compute the distance */ \ /* between the received sample and all possible symbols to derive the */ \ /* optimal symbol. */ \ /* _q : modem object */ \ /* _x : input sample */ \ /* _s : output hard symbol, 0 <= _s <= M-1 */ \ int MODEM(_demodulate)(MODEM() _q, \ TC _x, \ unsigned int * _s); \ \ /* Demodulate input sample and provide (approximate) log-likelihood */ \ /* ratio (LLR, soft bits) as an output. */ \ /* Similarly to the hard-decision demodulation method, this is computed */ \ /* efficiently for most modulation types. */ \ /* _q : modem object */ \ /* _x : input sample */ \ /* _s : output hard symbol, 0 <= _s <= M-1 */ \ /* _soft_bits : output soft bits, [size: log2(M) x 1] */ \ int MODEM(_demodulate_soft)(MODEM() _q, \ TC _x, \ unsigned int * _s, \ unsigned char * _soft_bits); \ \ /* Get demodulator's estimated transmit sample */ \ int MODEM(_get_demodulator_sample)(MODEM() _q, \ TC * _x_hat); \ \ /* Get demodulator phase error */ \ float MODEM(_get_demodulator_phase_error)(MODEM() _q); \ \ /* Get demodulator error vector magnitude */ \ float MODEM(_get_demodulator_evm)(MODEM() _q); \ // define modem APIs LIQUID_MODEM_DEFINE_API(LIQUID_MODEM_MANGLE_FLOAT,float,liquid_float_complex) // // continuous-phase modulation // // gmskmod : GMSK modulator typedef struct gmskmod_s * gmskmod; // create gmskmod object // _k : samples/symbol // _m : filter delay (symbols) // _BT : excess bandwidth factor gmskmod gmskmod_create(unsigned int _k, unsigned int _m, float _BT); int gmskmod_destroy(gmskmod _q); int gmskmod_print(gmskmod _q); int gmskmod_reset(gmskmod _q); int gmskmod_modulate(gmskmod _q, unsigned int _sym, liquid_float_complex * _y); // gmskdem : GMSK demodulator typedef struct gmskdem_s * gmskdem; // create gmskdem object // _k : samples/symbol // _m : filter delay (symbols) // _BT : excess bandwidth factor gmskdem gmskdem_create(unsigned int _k, unsigned int _m, float _BT); int gmskdem_destroy(gmskdem _q); int gmskdem_print(gmskdem _q); int gmskdem_reset(gmskdem _q); int gmskdem_set_eq_bw(gmskdem _q, float _bw); int gmskdem_demodulate(gmskdem _q, liquid_float_complex * _y, unsigned int * _sym); // // continuous phase frequency-shift keying (CP-FSK) modems // // CP-FSK filter prototypes typedef enum { LIQUID_CPFSK_SQUARE=0, // square pulse LIQUID_CPFSK_RCOS_FULL, // raised-cosine (full response) LIQUID_CPFSK_RCOS_PARTIAL, // raised-cosine (partial response) LIQUID_CPFSK_GMSK, // Gauss minimum-shift keying pulse } liquid_cpfsk_filter; // CP-FSK modulator typedef struct cpfskmod_s * cpfskmod; // create cpfskmod object (frequency modulator) // _bps : bits per symbol, _bps > 0 // _h : modulation index, _h > 0 // _k : samples/symbol, _k > 1, _k even // _m : filter delay (symbols), _m > 0 // _beta : filter bandwidth parameter, _beta > 0 // _type : filter type (e.g. LIQUID_CPFSK_SQUARE) cpfskmod cpfskmod_create(unsigned int _bps, float _h, unsigned int _k, unsigned int _m, float _beta, int _type); //cpfskmod cpfskmod_create_msk(unsigned int _k); //cpfskmod cpfskmod_create_gmsk(unsigned int _k, float _BT); // destroy cpfskmod object int cpfskmod_destroy(cpfskmod _q); // print cpfskmod object internals int cpfskmod_print(cpfskmod _q); // reset state int cpfskmod_reset(cpfskmod _q); // get transmit delay [symbols] unsigned int cpfskmod_get_delay(cpfskmod _q); // modulate sample // _q : frequency modulator object // _s : input symbol // _y : output sample array [size: _k x 1] int cpfskmod_modulate(cpfskmod _q, unsigned int _s, liquid_float_complex * _y); // CP-FSK demodulator typedef struct cpfskdem_s * cpfskdem; // create cpfskdem object (frequency modulator) // _bps : bits per symbol, _bps > 0 // _h : modulation index, _h > 0 // _k : samples/symbol, _k > 1, _k even // _m : filter delay (symbols), _m > 0 // _beta : filter bandwidth parameter, _beta > 0 // _type : filter type (e.g. LIQUID_CPFSK_SQUARE) cpfskdem cpfskdem_create(unsigned int _bps, float _h, unsigned int _k, unsigned int _m, float _beta, int _type); //cpfskdem cpfskdem_create_msk(unsigned int _k); //cpfskdem cpfskdem_create_gmsk(unsigned int _k, float _BT); // destroy cpfskdem object int cpfskdem_destroy(cpfskdem _q); // print cpfskdem object internals int cpfskdem_print(cpfskdem _q); // reset state int cpfskdem_reset(cpfskdem _q); // get receive delay [symbols] unsigned int cpfskdem_get_delay(cpfskdem _q); #if 0 // demodulate array of samples // _q : continuous-phase frequency demodulator object // _y : input sample array [size: _n x 1] // _n : input sample array length // _s : output symbol array // _nw : number of output symbols written int cpfskdem_demodulate(cpfskdem _q, liquid_float_complex * _y, unsigned int _n, unsigned int * _s, unsigned int * _nw); #else // demodulate array of samples, assuming perfect timing // _q : continuous-phase frequency demodulator object // _y : input sample array [size: _k x 1] unsigned int cpfskdem_demodulate(cpfskdem _q, liquid_float_complex * _y); #endif // // M-ary frequency-shift keying (MFSK) modems // // FSK modulator typedef struct fskmod_s * fskmod; // create fskmod object (frequency modulator) // _m : bits per symbol, _bps > 0 // _k : samples/symbol, _k >= 2^_m // _bandwidth : total signal bandwidth, (0,0.5) fskmod fskmod_create(unsigned int _m, unsigned int _k, float _bandwidth); // destroy fskmod object int fskmod_destroy(fskmod _q); // print fskmod object internals int fskmod_print(fskmod _q); // reset state int fskmod_reset(fskmod _q); // modulate sample // _q : frequency modulator object // _s : input symbol // _y : output sample array [size: _k x 1] int fskmod_modulate(fskmod _q, unsigned int _s, liquid_float_complex * _y); // FSK demodulator typedef struct fskdem_s * fskdem; // create fskdem object (frequency demodulator) // _m : bits per symbol, _bps > 0 // _k : samples/symbol, _k >= 2^_m // _bandwidth : total signal bandwidth, (0,0.5) fskdem fskdem_create(unsigned int _m, unsigned int _k, float _bandwidth); // destroy fskdem object int fskdem_destroy(fskdem _q); // print fskdem object internals int fskdem_print(fskdem _q); // reset state int fskdem_reset(fskdem _q); // demodulate symbol, assuming perfect symbol timing // _q : fskdem object // _y : input sample array [size: _k x 1] unsigned int fskdem_demodulate(fskdem _q, liquid_float_complex * _y); // get demodulator frequency error float fskdem_get_frequency_error(fskdem _q); // get energy for a particular symbol within a certain range float fskdem_get_symbol_energy(fskdem _q, unsigned int _s, unsigned int _range); // // Analog frequency modulator // #define LIQUID_FREQMOD_MANGLE_FLOAT(name) LIQUID_CONCAT(freqmod,name) // Macro : FREQMOD (analog frequency modulator) // FREQMOD : name-mangling macro // T : primitive data type // TC : primitive data type (complex) #define LIQUID_FREQMOD_DEFINE_API(FREQMOD,T,TC) \ \ /* Analog frequency modulation object */ \ typedef struct FREQMOD(_s) * FREQMOD(); \ \ /* Create freqmod object with a particular modulation factor */ \ /* _kf : modulation factor */ \ FREQMOD() FREQMOD(_create)(float _kf); \ \ /* Destroy freqmod object, freeing all internal memory */ \ int FREQMOD(_destroy)(FREQMOD() _q); \ \ /* Print freqmod object internals to stdout */ \ int FREQMOD(_print)(FREQMOD() _q); \ \ /* Reset state */ \ int FREQMOD(_reset)(FREQMOD() _q); \ \ /* Modulate single sample, producing single output sample at complex */ \ /* baseband. */ \ /* _q : frequency modulator object */ \ /* _m : message signal \( m(t) \) */ \ /* _s : complex baseband signal \( s(t) \) */ \ int FREQMOD(_modulate)(FREQMOD() _q, \ T _m, \ TC * _s); \ \ /* Modulate block of samples */ \ /* _q : frequency modulator object */ \ /* _m : message signal \( m(t) \), [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _s : complex baseband signal \( s(t) \), [size: _n x 1] */ \ int FREQMOD(_modulate_block)(FREQMOD() _q, \ T * _m, \ unsigned int _n, \ TC * _s); \ // define freqmod APIs LIQUID_FREQMOD_DEFINE_API(LIQUID_FREQMOD_MANGLE_FLOAT,float,liquid_float_complex) // // Analog frequency demodulator // #define LIQUID_FREQDEM_MANGLE_FLOAT(name) LIQUID_CONCAT(freqdem,name) // Macro : FREQDEM (analog frequency modulator) // FREQDEM : name-mangling macro // T : primitive data type // TC : primitive data type (complex) #define LIQUID_FREQDEM_DEFINE_API(FREQDEM,T,TC) \ typedef struct FREQDEM(_s) * FREQDEM(); \ \ /* create freqdem object (frequency modulator) */ \ /* _kf : modulation factor */ \ FREQDEM() FREQDEM(_create)(float _kf); \ \ /* destroy freqdem object */ \ int FREQDEM(_destroy)(FREQDEM() _q); \ \ /* print freqdem object internals */ \ int FREQDEM(_print)(FREQDEM() _q); \ \ /* reset state */ \ int FREQDEM(_reset)(FREQDEM() _q); \ \ /* demodulate sample */ \ /* _q : frequency modulator object */ \ /* _r : received signal r(t) */ \ /* _m : output message signal m(t) */ \ int FREQDEM(_demodulate)(FREQDEM() _q, \ TC _r, \ T * _m); \ \ /* demodulate block of samples */ \ /* _q : frequency demodulator object */ \ /* _r : received signal r(t) [size: _n x 1] */ \ /* _n : number of input, output samples */ \ /* _m : message signal m(t), [size: _n x 1] */ \ int FREQDEM(_demodulate_block)(FREQDEM() _q, \ TC * _r, \ unsigned int _n, \ T * _m); \ // define freqdem APIs LIQUID_FREQDEM_DEFINE_API(LIQUID_FREQDEM_MANGLE_FLOAT,float,liquid_float_complex) // amplitude modulation types typedef enum { LIQUID_AMPMODEM_DSB=0, // double side-band LIQUID_AMPMODEM_USB, // single side-band (upper) LIQUID_AMPMODEM_LSB // single side-band (lower) } liquid_ampmodem_type; typedef struct ampmodem_s * ampmodem; // create ampmodem object // _m : modulation index // _type : AM type (e.g. LIQUID_AMPMODEM_DSB) // _suppressed_carrier : carrier suppression flag ampmodem ampmodem_create(float _mod_index, liquid_ampmodem_type _type, int _suppressed_carrier); // destroy ampmodem object int ampmodem_destroy(ampmodem _q); // print ampmodem object internals int ampmodem_print(ampmodem _q); // reset ampmodem object state int ampmodem_reset(ampmodem _q); // accessor methods unsigned int ampmodem_get_delay_mod (ampmodem _q); unsigned int ampmodem_get_delay_demod(ampmodem _q); // modulate sample int ampmodem_modulate(ampmodem _q, float _x, liquid_float_complex * _y); int ampmodem_modulate_block(ampmodem _q, float * _m, unsigned int _n, liquid_float_complex * _s); // demodulate sample int ampmodem_demodulate(ampmodem _q, liquid_float_complex _y, float * _x); int ampmodem_demodulate_block(ampmodem _q, liquid_float_complex * _r, unsigned int _n, float * _m); // // MODULE : multichannel // #define FIRPFBCH_NYQUIST 0 #define FIRPFBCH_ROOTNYQUIST 1 #define LIQUID_ANALYZER 0 #define LIQUID_SYNTHESIZER 1 // // Finite impulse response polyphase filterbank channelizer // #define LIQUID_FIRPFBCH_MANGLE_CRCF(name) LIQUID_CONCAT(firpfbch_crcf,name) #define LIQUID_FIRPFBCH_MANGLE_CCCF(name) LIQUID_CONCAT(firpfbch_cccf,name) // Macro: // FIRPFBCH : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FIRPFBCH_DEFINE_API(FIRPFBCH,TO,TC,TI) \ typedef struct FIRPFBCH(_s) * FIRPFBCH(); \ \ /* create finite impulse response polyphase filter-bank */ \ /* channelizer object from external coefficients */ \ /* _type : channelizer type, e.g. LIQUID_ANALYZER */ \ /* _M : number of channels */ \ /* _p : number of coefficients for each channel */ \ /* _h : coefficients [size: _M*_p x 1] */ \ FIRPFBCH() FIRPFBCH(_create)(int _type, \ unsigned int _M, \ unsigned int _p, \ TC * _h); \ \ /* create FIR polyphase filterbank channelizer object with */ \ /* prototype filter based on windowed Kaiser design */ \ /* _type : type (LIQUID_ANALYZER | LIQUID_SYNTHESIZER) */ \ /* _M : number of channels */ \ /* _m : filter delay (symbols) */ \ /* _As : stop-band attentuation [dB] */ \ FIRPFBCH() FIRPFBCH(_create_kaiser)(int _type, \ unsigned int _M, \ unsigned int _m, \ float _As); \ \ /* create FIR polyphase filterbank channelizer object with */ \ /* prototype root-Nyquist filter */ \ /* _type : type (LIQUID_ANALYZER | LIQUID_SYNTHESIZER) */ \ /* _M : number of channels */ \ /* _m : filter delay (symbols) */ \ /* _beta : filter excess bandwidth factor, in [0,1] */ \ /* _ftype : filter prototype (rrcos, rkaiser, etc.) */ \ FIRPFBCH() FIRPFBCH(_create_rnyquist)(int _type, \ unsigned int _M, \ unsigned int _m, \ float _beta, \ int _ftype); \ \ /* destroy firpfbch object */ \ int FIRPFBCH(_destroy)(FIRPFBCH() _q); \ \ /* clear/reset firpfbch internal state */ \ int FIRPFBCH(_reset)(FIRPFBCH() _q); \ \ /* print firpfbch internal parameters to stdout */ \ int FIRPFBCH(_print)(FIRPFBCH() _q); \ \ /* execute filterbank as synthesizer on block of samples */ \ /* _q : filterbank channelizer object */ \ /* _x : channelized input, [size: num_channels x 1] */ \ /* _y : output time series, [size: num_channels x 1] */ \ int FIRPFBCH(_synthesizer_execute)(FIRPFBCH() _q, \ TI * _x, \ TO * _y); \ \ /* execute filterbank as analyzer on block of samples */ \ /* _q : filterbank channelizer object */ \ /* _x : input time series, [size: num_channels x 1] */ \ /* _y : channelized output, [size: num_channels x 1] */ \ int FIRPFBCH(_analyzer_execute)(FIRPFBCH() _q, \ TI * _x, \ TO * _y); \ LIQUID_FIRPFBCH_DEFINE_API(LIQUID_FIRPFBCH_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) LIQUID_FIRPFBCH_DEFINE_API(LIQUID_FIRPFBCH_MANGLE_CCCF, liquid_float_complex, liquid_float_complex, liquid_float_complex) // // Finite impulse response polyphase filterbank channelizer // with output rate 2 Fs / M // #define LIQUID_FIRPFBCH2_MANGLE_CRCF(name) LIQUID_CONCAT(firpfbch2_crcf,name) // Macro: // FIRPFBCH2 : name-mangling macro // TO : output data type // TC : coefficients data type // TI : input data type #define LIQUID_FIRPFBCH2_DEFINE_API(FIRPFBCH2,TO,TC,TI) \ typedef struct FIRPFBCH2(_s) * FIRPFBCH2(); \ \ /* create firpfbch2 object */ \ /* _type : channelizer type (e.g. LIQUID_ANALYZER) */ \ /* _M : number of channels (must be even) */ \ /* _m : prototype filter semi-length, length=2*M*m */ \ /* _h : prototype filter coefficient array */ \ FIRPFBCH2() FIRPFBCH2(_create)(int _type, \ unsigned int _M, \ unsigned int _m, \ TC * _h); \ \ /* create firpfbch2 object using Kaiser window prototype */ \ /* _type : channelizer type (e.g. LIQUID_ANALYZER) */ \ /* _M : number of channels (must be even) */ \ /* _m : prototype filter semi-length, length=2*M*m+1 */ \ /* _As : filter stop-band attenuation [dB] */ \ FIRPFBCH2() FIRPFBCH2(_create_kaiser)(int _type, \ unsigned int _M, \ unsigned int _m, \ float _As); \ \ /* destroy firpfbch2 object, freeing internal memory */ \ int FIRPFBCH2(_destroy)(FIRPFBCH2() _q); \ \ /* reset firpfbch2 object internals */ \ int FIRPFBCH2(_reset)(FIRPFBCH2() _q); \ \ /* print firpfbch2 object internals */ \ int FIRPFBCH2(_print)(FIRPFBCH2() _q); \ \ /* get type, either LIQUID_ANALYZER or LIQUID_SYNTHESIZER */ \ int FIRPFBCH2(_get_type)(FIRPFBCH2() _q); \ \ /* get number of channels, M */ \ unsigned int FIRPFBCH2(_get_M)(FIRPFBCH2() _q); \ \ /* get prototype filter sem-length, m */ \ unsigned int FIRPFBCH2(_get_m)(FIRPFBCH2() _q); \ \ /* execute filterbank channelizer */ \ /* LIQUID_ANALYZER: input: M/2, output: M */ \ /* LIQUID_SYNTHESIZER: input: M, output: M/2 */ \ /* _x : channelizer input */ \ /* _y : channelizer output */ \ int FIRPFBCH2(_execute)(FIRPFBCH2() _q, \ TI * _x, \ TO * _y); \ LIQUID_FIRPFBCH2_DEFINE_API(LIQUID_FIRPFBCH2_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) // // Finite impulse response polyphase filterbank channelizer // with output rate Fs * P / M // #define LIQUID_FIRPFBCHR_MANGLE_CRCF(name) LIQUID_CONCAT(firpfbchr_crcf,name) #define LIQUID_FIRPFBCHR_DEFINE_API(FIRPFBCHR,TO,TC,TI) \ typedef struct FIRPFBCHR(_s) * FIRPFBCHR(); \ \ /* create rational rate resampling channelizer (firpfbchr) object by */ \ /* specifying filter coefficients directly */ \ /* _M : number of output channels in chanelizer */ \ /* _P : output decimation factor (output rate is 1/P the input) */ \ /* _m : prototype filter semi-length, length=2*M*m */ \ /* _h : prototype filter coefficient array, [size: 2*M*m x 1] */ \ FIRPFBCHR() FIRPFBCHR(_create)(unsigned int _M, \ unsigned int _P, \ unsigned int _m, \ TC * _h); \ \ /* create rational rate resampling channelizer (firpfbchr) object by */ \ /* specifying filter design parameters for Kaiser prototype */ \ /* _M : number of output channels in chanelizer */ \ /* _P : output decimation factor (output rate is 1/P the input) */ \ /* _m : prototype filter semi-length, length=2*M*m */ \ /* _As : filter stop-band attenuation [dB] */ \ FIRPFBCHR() FIRPFBCHR(_create_kaiser)(unsigned int _M, \ unsigned int _P, \ unsigned int _m, \ float _As); \ \ /* destroy firpfbchr object, freeing internal memory */ \ int FIRPFBCHR(_destroy)(FIRPFBCHR() _q); \ \ /* reset firpfbchr object internal state and buffers */ \ int FIRPFBCHR(_reset)(FIRPFBCHR() _q); \ \ /* print firpfbchr object internals to stdout */ \ int FIRPFBCHR(_print)(FIRPFBCHR() _q); \ \ /* get number of output channels to channelizer */ \ unsigned int FIRPFBCHR(_get_M)(FIRPFBCHR() _q); \ \ /* get decimation factor for channelizer */ \ unsigned int FIRPFBCHR(_get_P)(FIRPFBCHR() _q); \ \ /* get semi-length to channelizer filter prototype */ \ unsigned int FIRPFBCHR(_get_m)(FIRPFBCHR() _q); \ \ /* push buffer of samples into filter bank */ \ /* _q : channelizer object */ \ /* _x : channelizer input [size: P x 1] */ \ int FIRPFBCHR(_push)(FIRPFBCHR() _q, \ TI * _x); \ \ /* execute filterbank channelizer, writing complex baseband samples for */ \ /* each channel into output array */ \ /* _q : channelizer object */ \ /* _y : channelizer output [size: _M x 1] */ \ int FIRPFBCHR(_execute)(FIRPFBCHR() _q, \ TO * _y); \ LIQUID_FIRPFBCHR_DEFINE_API(LIQUID_FIRPFBCHR_MANGLE_CRCF, liquid_float_complex, float, liquid_float_complex) #define OFDMFRAME_SCTYPE_NULL 0 #define OFDMFRAME_SCTYPE_PILOT 1 #define OFDMFRAME_SCTYPE_DATA 2 // initialize default subcarrier allocation // _M : number of subcarriers // _p : output subcarrier allocation array, [size: _M x 1] int ofdmframe_init_default_sctype(unsigned int _M, unsigned char * _p); // initialize default subcarrier allocation // _M : number of subcarriers // _f0 : lower frequency band, _f0 in [-0.5,0.5] // _f1 : upper frequency band, _f1 in [-0.5,0.5] // _p : output subcarrier allocation array, [size: _M x 1] int ofdmframe_init_sctype_range(unsigned int _M, float _f0, float _f1, unsigned char * _p); // validate subcarrier type (count number of null, pilot, and data // subcarriers in the allocation) // _p : subcarrier allocation array, [size: _M x 1] // _M : number of subcarriers // _M_null : output number of null subcarriers // _M_pilot : output number of pilot subcarriers // _M_data : output number of data subcarriers int ofdmframe_validate_sctype(unsigned char * _p, unsigned int _M, unsigned int * _M_null, unsigned int * _M_pilot, unsigned int * _M_data); // print subcarrier allocation to screen // _p : output subcarrier allocation array, [size: _M x 1] // _M : number of subcarriers int ofdmframe_print_sctype(unsigned char * _p, unsigned int _M); // // OFDM frame (symbol) generator // typedef struct ofdmframegen_s * ofdmframegen; // create OFDM framing generator object // _M : number of subcarriers, >10 typical // _cp_len : cyclic prefix length // _taper_len : taper length (OFDM symbol overlap) // _p : subcarrier allocation (null, pilot, data), [size: _M x 1] ofdmframegen ofdmframegen_create(unsigned int _M, unsigned int _cp_len, unsigned int _taper_len, unsigned char * _p); int ofdmframegen_destroy(ofdmframegen _q); int ofdmframegen_print(ofdmframegen _q); int ofdmframegen_reset(ofdmframegen _q); // write first S0 symbol int ofdmframegen_write_S0a(ofdmframegen _q, liquid_float_complex *_y); // write second S0 symbol int ofdmframegen_write_S0b(ofdmframegen _q, liquid_float_complex *_y); // write S1 symbol int ofdmframegen_write_S1(ofdmframegen _q, liquid_float_complex *_y); // write data symbol int ofdmframegen_writesymbol(ofdmframegen _q, liquid_float_complex * _x, liquid_float_complex *_y); // write tail int ofdmframegen_writetail(ofdmframegen _q, liquid_float_complex * _x); // // OFDM frame (symbol) synchronizer // typedef int (*ofdmframesync_callback)(liquid_float_complex * _y, unsigned char * _p, unsigned int _M, void * _userdata); typedef struct ofdmframesync_s * ofdmframesync; // create OFDM framing synchronizer object // _M : number of subcarriers, >10 typical // _cp_len : cyclic prefix length // _taper_len : taper length (OFDM symbol overlap) // _p : subcarrier allocation (null, pilot, data), [size: _M x 1] // _callback : user-defined callback function // _userdata : user-defined data pointer ofdmframesync ofdmframesync_create(unsigned int _M, unsigned int _cp_len, unsigned int _taper_len, unsigned char * _p, ofdmframesync_callback _callback, void * _userdata); int ofdmframesync_destroy(ofdmframesync _q); int ofdmframesync_print(ofdmframesync _q); int ofdmframesync_reset(ofdmframesync _q); int ofdmframesync_is_frame_open(ofdmframesync _q); int ofdmframesync_execute(ofdmframesync _q, liquid_float_complex * _x, unsigned int _n); // query methods float ofdmframesync_get_rssi(ofdmframesync _q); // received signal strength indication float ofdmframesync_get_cfo(ofdmframesync _q); // carrier offset estimate // set methods int ofdmframesync_set_cfo(ofdmframesync _q, float _cfo); // set carrier offset estimate // debugging int ofdmframesync_debug_enable(ofdmframesync _q); int ofdmframesync_debug_disable(ofdmframesync _q); int ofdmframesync_debug_print(ofdmframesync _q, const char * _filename); // // MODULE : nco (numerically-controlled oscillator) // // oscillator type // LIQUID_NCO : numerically-controlled oscillator (fast) // LIQUID_VCO : "voltage"-controlled oscillator (precise) typedef enum { LIQUID_NCO=0, LIQUID_VCO } liquid_ncotype; #define LIQUID_NCO_MANGLE_FLOAT(name) LIQUID_CONCAT(nco_crcf, name) // large macro // NCO : name-mangling macro // T : primitive data type // TC : input/output data type #define LIQUID_NCO_DEFINE_API(NCO,T,TC) \ \ /* Numerically-controlled oscillator object */ \ typedef struct NCO(_s) * NCO(); \ \ /* Create nco object with either fixed-point or floating-point phase */ \ /* _type : oscillator type, _type in {LIQUID_NCO, LIQUID_VCO} */ \ NCO() NCO(_create)(liquid_ncotype _type); \ \ /* Destroy nco object, freeing all internally allocated memory */ \ int NCO(_destroy)(NCO() _q); \ \ /* Print nco object internals to stdout */ \ int NCO(_print)(NCO() _q); \ \ /* Set phase/frequency to zero and reset the phase-locked loop filter */ \ /* state */ \ int NCO(_reset)(NCO() _q); \ \ /* Get frequency of nco object in radians per sample */ \ T NCO(_get_frequency)(NCO() _q); \ \ /* Set frequency of nco object in radians per sample */ \ /* _q : nco object */ \ /* _dtheta : input frequency [radians/sample] */ \ int NCO(_set_frequency)(NCO() _q, \ T _dtheta); \ \ /* Adjust frequency of nco object by a step size in radians per sample */ \ /* _q : nco object */ \ /* _step : input frequency step [radians/sample] */ \ int NCO(_adjust_frequency)(NCO() _q, \ T _step); \ \ /* Get phase of nco object in radians */ \ T NCO(_get_phase)(NCO() _q); \ \ /* Set phase of nco object in radians */ \ /* _q : nco object */ \ /* _phi : input phase of nco object [radians] */ \ int NCO(_set_phase)(NCO() _q, \ T _phi); \ \ /* Adjust phase of nco object by a step of \(\Delta \phi\) radians */ \ /* _q : nco object */ \ /* _dphi : input nco object phase adjustment [radians] */ \ int NCO(_adjust_phase)(NCO() _q, \ T _dphi); \ \ /* Increment phase by internal phase step (frequency) */ \ int NCO(_step)(NCO() _q); \ \ /* Compute sine output given internal phase */ \ T NCO(_sin)(NCO() _q); \ \ /* Compute cosine output given internal phase */ \ T NCO(_cos)(NCO() _q); \ \ /* Compute sine and cosine outputs given internal phase */ \ /* _q : nco object */ \ /* _s : output sine component of phase */ \ /* _c : output cosine component of phase */ \ int NCO(_sincos)(NCO() _q, \ T * _s, \ T * _c); \ \ /* Compute complex exponential output given internal phase */ \ /* _q : nco object */ \ /* _y : output complex exponential */ \ int NCO(_cexpf)(NCO() _q, \ TC * _y); \ \ /* Set bandwidth of internal phase-locked loop */ \ /* _q : nco object */ \ /* _bw : input phase-locked loop bandwidth, _bw >= 0 */ \ int NCO(_pll_set_bandwidth)(NCO() _q, \ T _bw); \ \ /* Step internal phase-locked loop given input phase error, adjusting */ \ /* internal phase and frequency proportional to coefficients defined by */ \ /* internal PLL bandwidth */ \ /* _q : nco object */ \ /* _dphi : input phase-locked loop phase error */ \ int NCO(_pll_step)(NCO() _q, \ T _dphi); \ \ /* Rotate input sample up by nco angle. */ \ /* Note that this does not adjust the internal phase or frequency. */ \ /* _q : nco object */ \ /* _x : input complex sample */ \ /* _y : pointer to output sample location */ \ int NCO(_mix_up)(NCO() _q, \ TC _x, \ TC * _y); \ \ /* Rotate input sample down by nco angle. */ \ /* Note that this does not adjust the internal phase or frequency. */ \ /* _q : nco object */ \ /* _x : input complex sample */ \ /* _y : pointer to output sample location */ \ int NCO(_mix_down)(NCO() _q, \ TC _x, \ TC * _y); \ \ /* Rotate input vector up by NCO angle (stepping) */ \ /* Note that this *does* adjust the internal phase as the signal steps */ \ /* through each input sample. */ \ /* _q : nco object */ \ /* _x : array of input samples, [size: _n x 1] */ \ /* _y : array of output samples, [size: _n x 1] */ \ /* _n : number of input (and output) samples */ \ int NCO(_mix_block_up)(NCO() _q, \ TC * _x, \ TC * _y, \ unsigned int _n); \ \ /* Rotate input vector down by NCO angle (stepping) */ \ /* Note that this *does* adjust the internal phase as the signal steps */ \ /* through each input sample. */ \ /* _q : nco object */ \ /* _x : array of input samples, [size: _n x 1] */ \ /* _y : array of output samples, [size: _n x 1] */ \ /* _n : number of input (and output) samples */ \ int NCO(_mix_block_down)(NCO() _q, \ TC * _x, \ TC * _y, \ unsigned int _n); \ // Define nco APIs LIQUID_NCO_DEFINE_API(LIQUID_NCO_MANGLE_FLOAT, float, liquid_float_complex) // nco utilities // unwrap phase of array (basic) void liquid_unwrap_phase(float * _theta, unsigned int _n); // unwrap phase of array (advanced) void liquid_unwrap_phase2(float * _theta, unsigned int _n); #define SYNTH_MANGLE_FLOAT(name) LIQUID_CONCAT(synth_crcf, name) // large macro // SYNTH : name-mangling macro // T : primitive data type // TC : input/output data type #define LIQUID_SYNTH_DEFINE_API(SYNTH,T,TC) \ typedef struct SYNTH(_s) * SYNTH(); \ \ SYNTH() SYNTH(_create)(const TC *_table, unsigned int _length); \ void SYNTH(_destroy)(SYNTH() _q); \ \ void SYNTH(_reset)(SYNTH() _q); \ \ /* get/set/adjust internal frequency/phase */ \ T SYNTH(_get_frequency)( SYNTH() _q); \ void SYNTH(_set_frequency)( SYNTH() _q, T _f); \ void SYNTH(_adjust_frequency)(SYNTH() _q, T _df); \ T SYNTH(_get_phase)( SYNTH() _q); \ void SYNTH(_set_phase)( SYNTH() _q, T _phi); \ void SYNTH(_adjust_phase)( SYNTH() _q, T _dphi); \ \ unsigned int SYNTH(_get_length)(SYNTH() _q); \ TC SYNTH(_get_current)(SYNTH() _q); \ TC SYNTH(_get_half_previous)(SYNTH() _q); \ TC SYNTH(_get_half_next)(SYNTH() _q); \ \ void SYNTH(_step)(SYNTH() _q); \ \ /* pll : phase-locked loop */ \ void SYNTH(_pll_set_bandwidth)(SYNTH() _q, T _bandwidth); \ void SYNTH(_pll_step)(SYNTH() _q, T _dphi); \ \ /* Rotate input sample up by SYNTH angle (no stepping) */ \ void SYNTH(_mix_up)(SYNTH() _q, TC _x, TC *_y); \ \ /* Rotate input sample down by SYNTH angle (no stepping) */ \ void SYNTH(_mix_down)(SYNTH() _q, TC _x, TC *_y); \ \ /* Rotate input vector up by SYNTH angle (stepping) */ \ void SYNTH(_mix_block_up)(SYNTH() _q, \ TC *_x, \ TC *_y, \ unsigned int _N); \ \ /* Rotate input vector down by SYNTH angle (stepping) */ \ void SYNTH(_mix_block_down)(SYNTH() _q, \ TC *_x, \ TC *_y, \ unsigned int _N); \ \ void SYNTH(_spread)(SYNTH() _q, \ TC _x, \ TC *_y); \ \ void SYNTH(_despread)(SYNTH() _q, \ TC *_x, \ TC *_y); \ \ void SYNTH(_despread_triple)(SYNTH() _q, \ TC *_x, \ TC *_early, \ TC *_punctual, \ TC *_late); \ // Define synth APIs LIQUID_SYNTH_DEFINE_API(SYNTH_MANGLE_FLOAT, float, liquid_float_complex) // // MODULE : optimization // // utility function pointer definition typedef float (*utility_function)(void * _userdata, float * _v, unsigned int _n); // n-dimensional Rosenbrock utility function (minimum at _v = {1,1,1...} // _userdata : user-defined data structure (convenience) // _v : input vector [size: _n x 1] // _n : input vector size float liquid_rosenbrock(void * _userdata, float * _v, unsigned int _n); // n-dimensional inverse Gauss utility function (minimum at _v = {0,0,0...} // _userdata : user-defined data structure (convenience) // _v : input vector [size: _n x 1] // _n : input vector size float liquid_invgauss(void * _userdata, float * _v, unsigned int _n); // n-dimensional multimodal utility function (minimum at _v = {0,0,0...} // _userdata : user-defined data structure (convenience) // _v : input vector [size: _n x 1] // _n : input vector size float liquid_multimodal(void * _userdata, float * _v, unsigned int _n); // n-dimensional spiral utility function (minimum at _v = {0,0,0...} // _userdata : user-defined data structure (convenience) // _v : input vector [size: _n x 1] // _n : input vector size float liquid_spiral(void * _userdata, float * _v, unsigned int _n); // // Gradient search // #define LIQUID_OPTIM_MINIMIZE (0) #define LIQUID_OPTIM_MAXIMIZE (1) typedef struct gradsearch_s * gradsearch; // Create a gradient search object // _userdata : user data object pointer // _v : array of parameters to optimize // _num_parameters : array length (number of parameters to optimize) // _u : utility function pointer // _direction : search direction (e.g. LIQUID_OPTIM_MAXIMIZE) gradsearch gradsearch_create(void * _userdata, float * _v, unsigned int _num_parameters, utility_function _utility, int _direction); // Destroy a gradsearch object void gradsearch_destroy(gradsearch _q); // Prints current status of search void gradsearch_print(gradsearch _q); // Iterate once float gradsearch_step(gradsearch _q); // Execute the search float gradsearch_execute(gradsearch _q, unsigned int _max_iterations, float _target_utility); // quasi-Newton search typedef struct qnsearch_s * qnsearch; // Create a simple qnsearch object; parameters are specified internally // _userdata : userdata // _v : array of parameters to optimize // _num_parameters : array length // _get_utility : utility function pointer // _direction : search direction (e.g. LIQUID_OPTIM_MAXIMIZE) qnsearch qnsearch_create(void * _userdata, float * _v, unsigned int _num_parameters, utility_function _u, int _direction); // Destroy a qnsearch object int qnsearch_destroy(qnsearch _g); // Prints current status of search int qnsearch_print(qnsearch _g); // Resets internal state int qnsearch_reset(qnsearch _g); // Iterate once int qnsearch_step(qnsearch _g); // Execute the search float qnsearch_execute(qnsearch _g, unsigned int _max_iterations, float _target_utility); // // chromosome (for genetic algorithm search) // typedef struct chromosome_s * chromosome; // create a chromosome object, variable bits/trait chromosome chromosome_create(unsigned int * _bits_per_trait, unsigned int _num_traits); // create a chromosome object, all traits same resolution chromosome chromosome_create_basic(unsigned int _num_traits, unsigned int _bits_per_trait); // create a chromosome object, cloning a parent chromosome chromosome_create_clone(chromosome _parent); // copy existing chromosomes' internal traits (all other internal // parameters must be equal) int chromosome_copy(chromosome _parent, chromosome _child); // Destroy a chromosome object int chromosome_destroy(chromosome _c); // get number of traits in chromosome unsigned int chromosome_get_num_traits(chromosome _c); // Print chromosome values to screen (binary representation) int chromosome_print(chromosome _c); // Print chromosome values to screen (floating-point representation) int chromosome_printf(chromosome _c); // clear chromosome (set traits to zero) int chromosome_reset(chromosome _c); // initialize chromosome on integer values int chromosome_init(chromosome _c, unsigned int * _v); // initialize chromosome on floating-point values int chromosome_initf(chromosome _c, float * _v); // Mutates chromosome _c at _index int chromosome_mutate(chromosome _c, unsigned int _index); // Resulting chromosome _c is a crossover of parents _p1 and _p2 at _threshold int chromosome_crossover(chromosome _p1, chromosome _p2, chromosome _c, unsigned int _threshold); // Initializes chromosome to random value int chromosome_init_random(chromosome _c); // Returns integer representation of chromosome unsigned int chromosome_value(chromosome _c, unsigned int _index); // Returns floating-point representation of chromosome float chromosome_valuef(chromosome _c, unsigned int _index); // // genetic algorithm search // typedef struct gasearch_s * gasearch; typedef float (*gasearch_utility)(void * _userdata, chromosome _c); // Create a simple gasearch object; parameters are specified internally // _utility : chromosome fitness utility function // _userdata : user data, void pointer passed to _get_utility() callback // _parent : initial population parent chromosome, governs precision, etc. // _minmax : search direction gasearch gasearch_create(gasearch_utility _u, void * _userdata, chromosome _parent, int _minmax); // Create a gasearch object, specifying search parameters // _utility : chromosome fitness utility function // _userdata : user data, void pointer passed to _get_utility() callback // _parent : initial population parent chromosome, governs precision, etc. // _minmax : search direction // _population_size : number of chromosomes in population // _mutation_rate : probability of mutating chromosomes gasearch gasearch_create_advanced(gasearch_utility _utility, void * _userdata, chromosome _parent, int _minmax, unsigned int _population_size, float _mutation_rate); // Destroy a gasearch object int gasearch_destroy(gasearch _q); // print search parameter internals int gasearch_print(gasearch _q); // set mutation rate int gasearch_set_mutation_rate(gasearch _q, float _mutation_rate); // set population/selection size // _q : ga search object // _population_size : new population size (number of chromosomes) // _selection_size : selection size (number of parents for new generation) int gasearch_set_population_size(gasearch _q, unsigned int _population_size, unsigned int _selection_size); // Execute the search // _q : ga search object // _max_iterations : maximum number of iterations to run before bailing // _target_utility : target utility float gasearch_run(gasearch _q, unsigned int _max_iterations, float _target_utility); // iterate over one evolution of the search algorithm int gasearch_evolve(gasearch _q); // get optimal chromosome // _q : ga search object // _c : output optimal chromosome // _utility_opt : fitness of _c int gasearch_getopt(gasearch _q, chromosome _c, float * _utility_opt); // // MODULE : quantization // float compress_mulaw(float _x, float _mu); float expand_mulaw(float _x, float _mu); int compress_cf_mulaw(liquid_float_complex _x, float _mu, liquid_float_complex * _y); int expand_cf_mulaw(liquid_float_complex _y, float _mu, liquid_float_complex * _x); //float compress_alaw(float _x, float _a); //float expand_alaw(float _x, float _a); // inline quantizer: 'analog' signal in [-1, 1] unsigned int quantize_adc(float _x, unsigned int _num_bits); float quantize_dac(unsigned int _s, unsigned int _num_bits); // structured quantizer typedef enum { LIQUID_COMPANDER_NONE=0, LIQUID_COMPANDER_LINEAR, LIQUID_COMPANDER_MULAW, LIQUID_COMPANDER_ALAW } liquid_compander_type; #define LIQUID_QUANTIZER_MANGLE_FLOAT(name) LIQUID_CONCAT(quantizerf, name) #define LIQUID_QUANTIZER_MANGLE_CFLOAT(name) LIQUID_CONCAT(quantizercf, name) // large macro // QUANTIZER : name-mangling macro // T : data type #define LIQUID_QUANTIZER_DEFINE_API(QUANTIZER,T) \ \ /* Amplitude quantization object */ \ typedef struct QUANTIZER(_s) * QUANTIZER(); \ \ /* Create quantizer object given compander type, input range, and the */ \ /* number of bits to represent the output */ \ /* _ctype : compander type (linear, mulaw, alaw) */ \ /* _range : maximum abosolute input range (ignored for now) */ \ /* _num_bits : number of bits per sample */ \ QUANTIZER() QUANTIZER(_create)(liquid_compander_type _ctype, \ float _range, \ unsigned int _num_bits); \ \ /* Destroy object, freeing all internally-allocated memory. */ \ int QUANTIZER(_destroy)(QUANTIZER() _q); \ \ /* Print object properties to stdout, including compander type and */ \ /* number of bits per sample */ \ int QUANTIZER(_print)(QUANTIZER() _q); \ \ /* Execute quantizer as analog-to-digital converter, accepting input */ \ /* sample and returning digitized output bits */ \ /* _q : quantizer object */ \ /* _x : input sample */ \ /* _s : output bits */ \ int QUANTIZER(_execute_adc)(QUANTIZER() _q, \ T _x, \ unsigned int * _s); \ \ /* Execute quantizer as digital-to-analog converter, accepting input */ \ /* bits and returning representation of original input sample */ \ /* _q : quantizer object */ \ /* _s : input bits */ \ /* _x : output sample */ \ int QUANTIZER(_execute_dac)(QUANTIZER() _q, \ unsigned int _s, \ T * _x); \ LIQUID_QUANTIZER_DEFINE_API(LIQUID_QUANTIZER_MANGLE_FLOAT, float) LIQUID_QUANTIZER_DEFINE_API(LIQUID_QUANTIZER_MANGLE_CFLOAT, liquid_float_complex) // // MODULE : random (number generators) // // Uniform random number generator, [0,1) float randf(); float randf_pdf(float _x); float randf_cdf(float _x); // Uniform random number generator with arbitrary bounds, [a,b) float randuf(float _a, float _b); float randuf_pdf(float _x, float _a, float _b); float randuf_cdf(float _x, float _a, float _b); // Gauss random number generator, N(0,1) // f(x) = 1/sqrt(2*pi*sigma^2) * exp{-(x-eta)^2/(2*sigma^2)} // // where // eta = mean // sigma = standard deviation // float randnf(); void awgn(float *_x, float _nstd); void crandnf(liquid_float_complex *_y); void cawgn(liquid_float_complex *_x, float _nstd); float randnf_pdf(float _x, float _eta, float _sig); float randnf_cdf(float _x, float _eta, float _sig); // Exponential // f(x) = lambda exp{ -lambda x } // where // lambda = spread parameter, lambda > 0 // x >= 0 float randexpf(float _lambda); float randexpf_pdf(float _x, float _lambda); float randexpf_cdf(float _x, float _lambda); // Weibull // f(x) = (a/b) (x/b)^(a-1) exp{ -(x/b)^a } // where // a = alpha : shape parameter // b = beta : scaling parameter // g = gamma : location (threshold) parameter // float randweibf(float _alpha, float _beta, float _gamma); float randweibf_pdf(float _x, float _a, float _b, float _g); float randweibf_cdf(float _x, float _a, float _b, float _g); // Gamma // x^(a-1) exp(-x/b) // f(x) = ------------------- // Gamma(a) b^a // where // a = alpha : shape parameter, a > 0 // b = beta : scale parameter, b > 0 // Gamma(z) = regular gamma function // x >= 0 float randgammaf(float _alpha, float _beta); float randgammaf_pdf(float _x, float _alpha, float _beta); float randgammaf_cdf(float _x, float _alpha, float _beta); // Nakagami-m // f(x) = (2/Gamma(m)) (m/omega)^m x^(2m-1) exp{-(m/omega)x^2} // where // m : shape parameter, m >= 0.5 // omega : spread parameter, omega > 0 // Gamma(z): regular complete gamma function // x >= 0 float randnakmf(float _m, float _omega); float randnakmf_pdf(float _x, float _m, float _omega); float randnakmf_cdf(float _x, float _m, float _omega); // Rice-K // f(x) = (x/sigma^2) exp{ -(x^2+s^2)/(2sigma^2) } I0( x s / sigma^2 ) // where // s = sqrt( omega*K/(K+1) ) // sigma = sqrt(0.5 omega/(K+1)) // and // K = shape parameter // omega = spread parameter // I0 = modified Bessel function of the first kind // x >= 0 float randricekf(float _K, float _omega); float randricekf_cdf(float _x, float _K, float _omega); float randricekf_pdf(float _x, float _K, float _omega); // Data scrambler : whiten data sequence void scramble_data(unsigned char * _x, unsigned int _len); void unscramble_data(unsigned char * _x, unsigned int _len); void unscramble_data_soft(unsigned char * _x, unsigned int _len); // // MODULE : sequence // // Binary sequence (generic) typedef struct bsequence_s * bsequence; // Create a binary sequence of a specific length (number of bits) bsequence bsequence_create(unsigned int num_bits); // Free memory in a binary sequence int bsequence_destroy(bsequence _bs); // Clear binary sequence (set to 0's) int bsequence_reset(bsequence _bs); // initialize sequence on external array int bsequence_init(bsequence _bs, unsigned char * _v); // Print sequence to the screen int bsequence_print(bsequence _bs); // Push bit into to back of a binary sequence int bsequence_push(bsequence _bs, unsigned int _bit); // circular shift (left) int bsequence_circshift(bsequence _bs); // Correlate two binary sequences together int bsequence_correlate(bsequence _bs1, bsequence _bs2); // compute the binary addition of two bit sequences int bsequence_add(bsequence _bs1, bsequence _bs2, bsequence _bs3); // compute the binary multiplication of two bit sequences int bsequence_mul(bsequence _bs1, bsequence _bs2, bsequence _bs3); // accumulate the 1's in a binary sequence unsigned int bsequence_accumulate(bsequence _bs); // accessor functions unsigned int bsequence_get_length(bsequence _bs); unsigned int bsequence_index(bsequence _bs, unsigned int _i); // Complementary codes // intialize two sequences to complementary codes. sequences must // be of length at least 8 and a power of 2 (e.g. 8, 16, 32, 64,...) // _a : sequence 'a' (bsequence object) // _b : sequence 'b' (bsequence object) int bsequence_create_ccodes(bsequence _a, bsequence _b); // M-Sequence #define LIQUID_MAX_MSEQUENCE_LENGTH 32767 // default m-sequence generators: g (hex) m n g (oct) g (binary) #define LIQUID_MSEQUENCE_GENPOLY_M2 0x0007 // 2 3 7 111 #define LIQUID_MSEQUENCE_GENPOLY_M3 0x000B // 3 7 13 1011 #define LIQUID_MSEQUENCE_GENPOLY_M4 0x0013 // 4 15 23 10011 #define LIQUID_MSEQUENCE_GENPOLY_M5 0x0025 // 5 31 45 100101 #define LIQUID_MSEQUENCE_GENPOLY_M6 0x0043 // 6 63 103 1000011 #define LIQUID_MSEQUENCE_GENPOLY_M7 0x0089 // 7 127 211 10001001 #define LIQUID_MSEQUENCE_GENPOLY_M8 0x011D // 8 255 435 100101101 #define LIQUID_MSEQUENCE_GENPOLY_M9 0x0211 // 9 511 1021 1000010001 #define LIQUID_MSEQUENCE_GENPOLY_M10 0x0409 // 10 1023 2011 10000001001 #define LIQUID_MSEQUENCE_GENPOLY_M11 0x0805 // 11 2047 4005 100000000101 #define LIQUID_MSEQUENCE_GENPOLY_M12 0x1053 // 12 4095 10123 1000001010011 #define LIQUID_MSEQUENCE_GENPOLY_M13 0x201b // 13 8191 20033 10000000011011 #define LIQUID_MSEQUENCE_GENPOLY_M14 0x402b // 14 16383 40053 100000000101011 #define LIQUID_MSEQUENCE_GENPOLY_M15 0x8003 // 15 32767 100003 1000000000000011 typedef struct msequence_s * msequence; // create a maximal-length sequence (m-sequence) object with // an internal shift register length of _m bits. // _m : generator polynomial length, sequence length is (2^m)-1 // _g : generator polynomial, starting with most-significant bit // _a : initial shift register state, default: 000...001 msequence msequence_create(unsigned int _m, unsigned int _g, unsigned int _a); // create a maximal-length sequence (m-sequence) object from a generator polynomial msequence msequence_create_genpoly(unsigned int _g); // creates a default maximal-length sequence msequence msequence_create_default(unsigned int _m); // destroy an msequence object, freeing all internal memory int msequence_destroy(msequence _m); // prints the sequence's internal state to the screen int msequence_print(msequence _m); // advance msequence on shift register, returning output bit unsigned int msequence_advance(msequence _ms); // generate pseudo-random symbol from shift register by // advancing _bps bits and returning compacted symbol // _ms : m-sequence object // _bps : bits per symbol of output unsigned int msequence_generate_symbol(msequence _ms, unsigned int _bps); // reset msequence shift register to original state, typically '1' int msequence_reset(msequence _ms); // initialize a bsequence object on an msequence object // _bs : bsequence object // _ms : msequence object int bsequence_init_msequence(bsequence _bs, msequence _ms); // get the length of the sequence unsigned int msequence_get_length(msequence _ms); // get the internal state of the sequence unsigned int msequence_get_state(msequence _ms); // set the internal state of the sequence int msequence_set_state(msequence _ms, unsigned int _a); // // MODULE : utility // // pack binary array with symbol(s) // _src : source array [size: _n x 1] // _n : input source array length // _k : bit index to write in _src // _b : number of bits in input symbol // _sym_in : input symbol int liquid_pack_array(unsigned char * _src, unsigned int _n, unsigned int _k, unsigned int _b, unsigned char _sym_in); // unpack symbols from binary array // _src : source array [size: _n x 1] // _n : input source array length // _k : bit index to write in _src // _b : number of bits in output symbol // _sym_out : output symbol int liquid_unpack_array(unsigned char * _src, unsigned int _n, unsigned int _k, unsigned int _b, unsigned char * _sym_out); // pack one-bit symbols into bytes (8-bit symbols) // _sym_in : input symbols array [size: _sym_in_len x 1] // _sym_in_len : number of input symbols // _sym_out : output symbols // _sym_out_len : number of bytes allocated to output symbols array // _num_written : number of output symbols actually written int liquid_pack_bytes(unsigned char * _sym_in, unsigned int _sym_in_len, unsigned char * _sym_out, unsigned int _sym_out_len, unsigned int * _num_written); // unpack 8-bit symbols (full bytes) into one-bit symbols // _sym_in : input symbols array [size: _sym_in_len x 1] // _sym_in_len : number of input symbols // _sym_out : output symbols array // _sym_out_len : number of bytes allocated to output symbols array // _num_written : number of output symbols actually written int liquid_unpack_bytes(unsigned char * _sym_in, unsigned int _sym_in_len, unsigned char * _sym_out, unsigned int _sym_out_len, unsigned int * _num_written); // repack bytes with arbitrary symbol sizes // _sym_in : input symbols array [size: _sym_in_len x 1] // _sym_in_bps : number of bits per input symbol // _sym_in_len : number of input symbols // _sym_out : output symbols array // _sym_out_bps : number of bits per output symbol // _sym_out_len : number of bytes allocated to output symbols array // _num_written : number of output symbols actually written int liquid_repack_bytes(unsigned char * _sym_in, unsigned int _sym_in_bps, unsigned int _sym_in_len, unsigned char * _sym_out, unsigned int _sym_out_bps, unsigned int _sym_out_len, unsigned int * _num_written); // shift array to the left _b bits, filling in zeros // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bits to shift int liquid_lbshift(unsigned char * _src, unsigned int _n, unsigned int _b); // shift array to the right _b bits, filling in zeros // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bits to shift int liquid_rbshift(unsigned char * _src, unsigned int _n, unsigned int _b); // circularly shift array to the left _b bits // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bits to shift int liquid_lbcircshift(unsigned char * _src, unsigned int _n, unsigned int _b); // circularly shift array to the right _b bits // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bits to shift int liquid_rbcircshift(unsigned char * _src, unsigned int _n, unsigned int _b); // shift array to the left _b bytes, filling in zeros // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bytes to shift int liquid_lshift(unsigned char * _src, unsigned int _n, unsigned int _b); // shift array to the right _b bytes, filling in zeros // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bytes to shift int liquid_rshift(unsigned char * _src, unsigned int _n, unsigned int _b); // circular shift array to the left _b bytes // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bytes to shift int liquid_lcircshift(unsigned char * _src, unsigned int _n, unsigned int _b); // circular shift array to the right _b bytes // _src : source address [size: _n x 1] // _n : input data array size // _b : number of bytes to shift int liquid_rcircshift(unsigned char * _src, unsigned int _n, unsigned int _b); // Count the number of ones in an integer unsigned int liquid_count_ones(unsigned int _x); // count number of ones in an integer, modulo 2 unsigned int liquid_count_ones_mod2(unsigned int _x); // compute bindary dot-product between two integers unsigned int liquid_bdotprod(unsigned int _x, unsigned int _y); // Count leading zeros in an integer unsigned int liquid_count_leading_zeros(unsigned int _x); // Most-significant bit index unsigned int liquid_msb_index(unsigned int _x); // Print string of bits to stdout int liquid_print_bitstring(unsigned int _x, unsigned int _n); // reverse byte, word, etc. unsigned char liquid_reverse_byte( unsigned char _x); unsigned int liquid_reverse_uint16(unsigned int _x); unsigned int liquid_reverse_uint24(unsigned int _x); unsigned int liquid_reverse_uint32(unsigned int _x); // get scale for constant, particularly for plotting purposes // _val : input value (e.g. 100e6) // _unit : output unit character (e.g. 'M') // _scale : output scale (e.g. 1e-6) int liquid_get_scale(float _val, char * _unit, float * _scale); // // MODULE : vector // #define LIQUID_VECTOR_MANGLE_RF(name) LIQUID_CONCAT(liquid_vectorf, name) #define LIQUID_VECTOR_MANGLE_CF(name) LIQUID_CONCAT(liquid_vectorcf,name) // large macro // VECTOR : name-mangling macro // T : data type // TP : data type (primitive) #define LIQUID_VECTOR_DEFINE_API(VECTOR,T,TP) \ \ /* Initialize vector with scalar: x[i] = c (scalar) */ \ void VECTOR(_init)(T _c, \ T * _x, \ unsigned int _n); \ \ /* Add each element pointwise: z[i] = x[i] + y[i] */ \ void VECTOR(_add)(T * _x, \ T * _y, \ unsigned int _n, \ T * _z); \ \ /* Add scalar to each element: y[i] = x[i] + c */ \ void VECTOR(_addscalar)(T * _x, \ unsigned int _n, \ T _c, \ T * _y); \ \ /* Multiply each element pointwise: z[i] = x[i] * y[i] */ \ void VECTOR(_mul)(T * _x, \ T * _y, \ unsigned int _n, \ T * _z); \ \ /* Multiply each element with scalar: y[i] = x[i] * c */ \ void VECTOR(_mulscalar)(T * _x, \ unsigned int _n, \ T _c, \ T * _y); \ \ /* Compute complex phase rotation: x[i] = exp{j theta[i]} */ \ void VECTOR(_cexpj)(TP * _theta, \ unsigned int _n, \ T * _x); \ \ /* Compute angle of each element: theta[i] = arg{ x[i] } */ \ void VECTOR(_carg)(T * _x, \ unsigned int _n, \ TP * _theta); \ \ /* Compute absolute value of each element: y[i] = |x[i]| */ \ void VECTOR(_abs)(T * _x, \ unsigned int _n, \ TP * _y); \ \ /* Compute sum of squares: sum{ |x|^2 } */ \ TP VECTOR(_sumsq)(T * _x, \ unsigned int _n); \ \ /* Compute l-2 norm: sqrt{ sum{ |x|^2 } } */ \ TP VECTOR(_norm)(T * _x, \ unsigned int _n); \ \ /* Compute l-p norm: { sum{ |x|^p } }^(1/p) */ \ TP VECTOR(_pnorm)(T * _x, \ unsigned int _n, \ TP _p); \ \ /* Scale vector elements by l-2 norm: y[i] = x[i]/norm(x) */ \ void VECTOR(_normalize)(T * _x, \ unsigned int _n, \ T * _y); \ LIQUID_VECTOR_DEFINE_API(LIQUID_VECTOR_MANGLE_RF, float, float) LIQUID_VECTOR_DEFINE_API(LIQUID_VECTOR_MANGLE_CF, liquid_float_complex, float) // // mixed types // #if 0 void liquid_vectorf_add(float * _a, float * _b, unsigned int _n, float * _c); #endif #ifdef __cplusplus } //extern "C" #endif // __cplusplus #ifdef _MSC_VER #pragma warning( pop ) #endif #endif // __LIQUID_H__