Provided by: libcw6-dev_3.4.2-1build1_amd64 
NAME
libcw - general purpose Morse code functions library
SYNOPSIS
#include <libcw.h>
int cw_generator_new(int audio_system, const char *device)
void cw_generator_delete(void)
int cw_generator_start(void)
void cw_generator_stop(void)
int cw_set_send_speed(int new_value)
int cw_set_frequency(int new_value)
int cw_set_volume(int new_value)
int cw_set_gap(int new_value)
int cw_set_weighting(int new_value)
int cw_get_send_speed(void)
int cw_get_frequency(void)
int cw_get_volume(void)
int cw_get_gap(void)
int cw_get_weighting(void)
void cw_get_send_parameters(int *dot_usecs, int *dash_usecs,
int *end_of_element_usecs,
int *end_of_character_usecs, int *end_of_word_usecs,
int *additional_usecs, int *adjustment_usecs)
int cw_send_dot(void)
int cw_send_dash(void)
int cw_send_character_space(void)
int cw_send_word_space(void)
int cw_send_representation(const char *representation)
int cw_send_representation_partial(const char *representation)
int cw_send_character(char c)
int cw_send_character_partial(char c)
int cw_send_string(const char *string)
void cw_reset_send_receive_parameters(void)
const char *cw_get_console_device(void)
const char *cw_get_soundcard_device(void)
const char *cw_generator_get_audio_system_label(void)
int cw_register_tone_queue_low_callback(void (*callback_func)(void*), void *callback_arg,
int level)
bool cw_is_tone_busy(void)
int cw_wait_for_tone(void)
int cw_wait_for_tone_queue(void)
int cw_wait_for_tone_queue_critical(int level)
bool cw_is_tone_queue_full(void)
int cw_get_tone_queue_capacity(void)
int cw_get_tone_queue_length(void)
void cw_flush_tone_queue(void)
void cw_reset_tone_queue(void)
int cw_queue_tone(int usecs, int frequency)
int cw_set_receive_speed(int new_value)
int cw_get_receive_speed(void)
int cw_set_tolerance(int new_value)
int cw_get_tolerance(void)
void cw_get_receive_parameters(int *dot_usecs, int *dash_usecs,
int *dot_min_usecs, int *dot_max_usecs,
int *dash_min_usecs, int *dash_max_usecs,
int *end_of_element_min_usecs,
int *end_of_element_max_usecs,
int *end_of_element_ideal_usecs,
int *end_of_character_min_usecs,
int *end_of_character_max_usecs,
int *end_of_character_ideal_usecs,
int *adaptive_threshold)
int cw_set_noise_spike_threshold(int new_value)
int cw_get_noise_spike_threshold(void)
void cw_get_receive_statistics(double *dot_sd, double *dash_sd,
double *element_end_sd, double *character_end_sd)
void cw_reset_receive_statistics(void)
void cw_enable_adaptive_receive(void)
void cw_disable_adaptive_receive(void)
bool cw_get_adaptive_receive_state(void)
int cw_start_receive_tone(const struct timeval *timestamp)
int cw_end_receive_tone(const struct timeval *timestamp)
int cw_receive_buffer_dot(const struct timeval *timestamp)
int cw_receive_buffer_dash(const struct timeval *timestamp)
int cw_receive_representation(const struct timeval *timestamp,
/* out */ char *representation,
/* out */ bool *is_end_of_word,
/* out */ bool *is_error)
int cw_receive_character(const struct timeval *timestamp,
/* out */ char *c,
/* out */ bool *is_end_of_word,
/* out */ bool *is_error)
void cw_clear_receive_buffer(void)
int cw_get_receive_buffer_capacity(void)
int cw_get_receive_buffer_length(void)
void cw_reset_receive(void)
void cw_register_keying_callback(void (*callback_func)(void*, int), void *callback_arg)
void cw_enable_iambic_curtis_mode_b(void)
void cw_disable_iambic_curtis_mode_b(void)
int cw_get_iambic_curtis_mode_b_state(void)
int cw_notify_keyer_paddle_event(int dot_paddle_state, int dash_paddle_state)
int cw_notify_keyer_dot_paddle_event(int dot_paddle_state)
int cw_notify_keyer_dash_paddle_event(int dash_paddle_state)
void cw_get_keyer_paddles(int *dot_paddle_state, int *dash_paddle_state)
void cw_get_keyer_paddle_latches(int *dot_paddle_latch_state, int
*dash_paddle_latch_state)
bool cw_is_keyer_busy(void)
int cw_wait_for_keyer_element(void)
int cw_wait_for_keyer(void)
void cw_reset_keyer(void)
int cw_notify_straight_key_event(int key_state)
int cw_get_straight_key_state(void)
bool cw_is_straight_key_busy(void)
void cw_reset_straight_key(void)
bool cw_is_alsa_possible(const char *device)
bool cw_is_console_possible(const char *device)
int cw_console_write(cw_gen_t *gen, cw_tone_t *tone)
int cw_get_character_count(void)
void cw_list_characters(char *list)
int cw_get_maximum_representation_length(void)
int cw_lookup_character(char c, char *representation)
char *cw_character_to_representation(int c)
int cw_check_representation(const char *representation)
bool cw_representation_is_valid(const char *representation)
int cw_lookup_representation(const char *representation, char *c)
int cw_representation_to_character(const char *representation)
int cw_get_procedural_character_count(void)
void cw_list_procedural_characters(char *list)
int cw_get_maximum_procedural_expansion_length(void)
int cw_lookup_procedural_character(char c, char *expansion, int *is_usually_expanded)
int cw_get_maximum_phonetic_length(void)
int cw_lookup_phonetic(char c, char *phonetic)
bool cw_character_is_valid(char c)
bool cw_string_is_valid(const char *string)
void cw_debug_flush(cw_debug_t *debug)
void cw_set_debug_flags(uint32_t flags)
void cw_debug_set_flags(cw_debug_t *debug_object, uint32_t flags)
uint32_t cw_get_debug_flags(void)
uint32_t cw_debug_get_flags(cw_debug_t *debug_object)
bool cw_debug_has_flag(cw_debug_t *debug_object, uint32_t flag)
int cw_generator_set_tone_slope(cw_gen_t *gen, int slope_shape, int slope_len)
bool cw_is_oss_possible(const char *device)
bool cw_is_pa_possible(const char *device)
void cw_block_callback(int block)
int cw_register_signal_handler(int signal_number, void (*callback_func)(int))
int cw_unregister_signal_handler(int signal_number)
int cw_version(void)
void cw_license(void)
const char *cw_get_audio_system_label(int audio_system)
void cw_get_speed_limits(int *min_speed, int *max_speed)
void cw_get_frequency_limits(int *min_frequency, int *max_frequency)
void cw_get_volume_limits(int *min_volume, int *max_volume)
void cw_get_gap_limits(int *min_gap, int *max_gap)
void cw_get_tolerance_limits(int *min_tolerance, int *max_tolerance)
void cw_get_weighting_limits(int *min_weighting, int *max_weighting)
void cw_complete_reset(void)
DESCRIPTION
libcw is a general purpose CW (Morse code) functions library. It contains routines for
converting characters into Morse code representations and back again, for sending Morse
code characters, and for receiving characters. It also contains routines to emulate an
Iambic Morse keyer, and a straight key.
The library can be included in any program that wishes to make use of these features. It
forms the heart of three Morse code tutor applications that accompany the package in which
it is distributed.
See the cw(7) man page for information on Morse code timings, and the dot and dash
representations for the various Morse characters.
TONE QUEUE
libcw contains an inbuilt tone queue. The queue is emptied by background processing,
using SIGALRM calls and itimers, so a caller program can continue with other tasks while
the library sends tones and keys any external device.
As well as being used by the library functions that sound Morse code characters and
provide a keyer sidetone, the primitive tone queue functions are publicly available to
caller programs.
CONTROLLING AN EXTERNAL DEVICE
libcw may be passed the address of a function that controls external keying. This
function is called each time the library changes the keying state, either as a result of
sending a Morse character or representation, or as a result of an iambic keyer or straight
key state change. The argument passed is a single integer, TRUE for key-down, and FALSE
for key-up.
libcw calls the external keying function only when the keying state changes. A call is
likely each time a tone is taken off the tone queue.
SENDING CW CHARACTERS AND STRINGS
libcw offers several functions that send individual characters and character strings as
Morse code. It also offers functions that allow specialized 'representations' to be sent.
A 'representation' is an ASCII string that consists of only the characters '.' and '-'.
Characters and strings are converted into representations, and then the correct tones for
the dots and dashes in these representations are queued on the tone queue, for action by
the background queue emptying process.
RECEIVING CW CHARACTERS AND REPRESENTATIONS
libcw contains functions to allow it to receive Morse code. To receive, the library must
be told when a tone start is detected, and when a tone end is detected. It then
determines whether the tone was a dot or a dash depending on the timing difference between
the two. After the required silence gap has passed, the library may be queried to see
what the received representation or character was.
Errors in receiving may be detected by means of the flags passed back on receive character
functions.
IAMBIC KEYER
libcw offers functions to simulate an Iambic Morse keyer. The caller program needs to
tell the library of paddle state changes. Iambic keyer functions are mutually exclusive
with character send and straight key functions.
STRAIGHT KEY
libcw offers simple functions to allow effective pass-through of straight key information.
The caller program needs to tell the library of key state changes. Straight key functions
are mutually exclusive with character send and iambic keyer functions.
RETURN CODES
Some of the library's function return a return code of type int. The return code has two
values, as defined in libcw.h: CW_SUCCESS or CW_FAILURE. The two symbolic constants are
guaranteed to be identical to boolean true and false.
FUNCTIONS
The following list describes the functions available to a libcw caller:
int cw_generator_new(int audio_system, const char *device)
Brief: Create new generator
Allocate memory for new generator data structure, set up default values of some of the
generator's properties. The function does not start the generator (generator does not
produce a sound), you have to use cw_generator_start() for this.
Notice that the function doesn't return a generator variable. There is at most one
generator variable at any given time. You can't have two generators. In some future
version of the library the function will return pointer to newly allocated generator, and
then you could have as many of them as you want, but not yet.
audio_system can be one of following: NULL, console, OSS, ALSA, PulseAudio, soundcard. See
"enum cw_audio_systems" in libcw.h for exact names of symbolic constants.
Parameter: audio_system - audio system to be used by the generator
Parameter: device - name of audio device to be used; if NULL then library will use default
device.
void cw_generator_delete(void)
Brief: Deallocate generator
Deallocate/destroy generator data structure created with call to cw_generator_new(). You
can't start nor use the generator after the call to this function.
int cw_generator_start(void)
Brief: Start a generator
Start producing tones using generator created with cw_generator_new(). The source of tones
is a tone queue associated with the generator. If the tone queue is empty, the generator
will wait for new tones to be queued.
Returns: CW_FAILURE on errors
Returns: CW_SUCCESS on success
void cw_generator_stop(void)
Brief: Shut down a generator
Silence tone generated by generator (level of generated sine wave is set to zero, with
falling slope), and shut the generator down.
The shutdown does not erase generator's configuration.
If you want to have this generator running again, you have to call cw_generator_start().
int cw_set_send_speed(int new_value)
Brief: Set sending speed of generator
See libcw.h/CW_SPEED_{INITIAL|MIN|MAX} for initial/minimal/maximal value of send speed.
errno is set to EINVAL if new_value is out of range.
Parameter: new_value - new value of send speed to be assigned to generator
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_set_frequency(int new_value)
Brief: Set frequency of generator
Set frequency of sound wave generated by generator. The frequency must be within limits
marked by CW_FREQUENCY_MIN and CW_FREQUENCY_MAX.
See libcw.h/CW_FREQUENCY_{INITIAL|MIN|MAX} for initial/minimal/maximal value of frequency.
errno is set to EINVAL if new_value is out of range.
Parameter: new_value - new value of frequency to be assigned to generator
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_set_volume(int new_value)
Brief: Set volume of generator
Set volume of sound wave generated by generator. The volume must be within limits marked
by CW_VOLUME_MIN and CW_VOLUME_MAX.
Note that volume settings are not fully possible for the console speaker. In this case,
volume settings greater than zero indicate console speaker sound is on, and setting volume
to zero will turn off console speaker sound.
See libcw.h/CW_VOLUME_{INITIAL|MIN|MAX} for initial/minimal/maximal value of volume.
errno is set to EINVAL if new_value is out of range.
Parameter: new_value - new value of volume to be assigned to generator
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_set_gap(int new_value)
Brief: Set sending gap of generator
See libcw.h/CW_GAP_{INITIAL|MIN|MAX} for initial/minimal/maximal value of gap. errno is
set to EINVAL if new_value is out of range.
Notice that this function also sets the same gap value for library's receiver.
Parameter: new_value - new value of gap to be assigned to generator
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_set_weighting(int new_value)
Brief: Set sending weighting for generator
See libcw.h/CW_WEIGHTING_{INITIAL|MIN|MAX} for initial/minimal/maximal value of weighting.
errno is set to EINVAL if new_value is out of range.
Parameter: new_value - new value of weighting to be assigned for generator
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_get_send_speed(void)
Brief: Get sending speed from generator
Returns: current value of the generator's send speed
int cw_get_frequency(void)
Brief: Get frequency from generator
Function returns "frequency" parameter of generator, even if the generator is stopped, or
volume of generated sound is zero.
Returns: current value of generator's frequency
int cw_get_volume(void)
Brief: Get sound volume from generator
Function returns "volume" parameter of generator, even if the generator is stopped.
Returns: current value of generator's sound volume
int cw_get_gap(void)
Brief: Get sending gap from generator
Returns: current value of generator's sending gap
int cw_get_weighting(void)
Brief: Get sending weighting from generator
Returns: current value of generator's sending weighting
void cw_get_send_parameters(int *dot_usecs, int *dash_usecs,
int *end_of_element_usecs,
int *end_of_character_usecs, int *end_of_word_usecs,
int *additional_usecs, int *adjustment_usecs)
Brief: Get timing parameters for sending
Return the low-level timing parameters calculated from the speed, gap, tolerance, and
weighting set. Parameter values are returned in microseconds.
Use NULL for the pointer argument to any parameter value not required.
Parameter: dot_usecs
Parameter: dash_usecs
Parameter: end_of_element_usecs
Parameter: end_of_character_usecs
Parameter: end_of_word_usecs
Parameter: additional_usecs
Parameter: adjustment_usecs
int cw_send_dot(void)
Brief: Low-level primitive for sending a dot mark
Low-level primitive function able to play/send single dot mark. The function appends to a
tone queue a normal inter-mark gap after the dot mark.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_dash(void)
Brief: Low-level primitive for sending a dash mark
Low-level primitive function able to play/send single dash mark. The function appends to
a tone queue a normal inter-mark gap after the dash mark.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_character_space(void)
The function plays space timed to exclude the expected prior dot/dash inter-mark gap.
FIXME: fix this description.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_word_space(void)
The function sends space timed to exclude both the expected prior dot/dash inter-mark gap
and the prior end of character space. FIXME: fix this description.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_representation(const char *representation)
Brief: Check, then send the given string as dots and dashes.
The representation passed in is assumed to be a complete Morse character; that is, all
post-character delays will be added when the character is sent.
On success, the routine returns CW_SUCCESS. On failure, it returns CW_FAILURE, with errno
set to EINVAL if any character of the representation is invalid, EBUSY if the sound card,
console speaker, or keying system is busy, or EAGAIN if the tone queue is full, or if
there is insufficient space to queue the tones or the representation.
Parameter: representation - representation to send
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_representation_partial(const char *representation)
Brief: Check, then send the given string as dots and dashes
The representation passed in is assumed to be only part of a larger Morse representation;
that is, no post-character delays will be added when the character is sent.
On success, the routine returns CW_SUCCESS. On failure, it returns CW_FAILURE, with errno
set to EINVAL if any character of the representation is invalid, EBUSY if the sound card,
console speaker, or keying system is busy, or EAGAIN if the tone queue is full, or if
there is insufficient space to queue the tones for the representation.
int cw_send_character(char c)
Brief: Look up and send a given ASCII character as Morse
The end of character delay is appended to the Morse sent.
On success the routine returns CW_SUCCESS. On failure the function returns CW_FAILURE and
sets errno.
errno is set to ENOENT if the given character c is not a valid Morse character. errno is
set to EBUSY if current audio sink or keying system is busy. errno is set to EAGAIN if
the generator's tone queue is full, or if there is insufficient space to queue the tones
for the character.
This routine returns as soon as the character has been successfully queued for sending;
that is, almost immediately. The actual sending happens in background processing. See
cw_wait_for_tone() and cw_wait_for_tone_queue() for ways to check the progress of sending.
Parameter: c - character to send
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_character_partial(char c)
Brief: Look up and send a given ASCII character as Morse code
"partial" means that the "end of character" delay is not appended to the Morse code sent
by the function, to support the formation of combination characters.
On success the function returns CW_SUCCESS. On failure the function returns CW_FAILURE
and sets errno.
errno is set to ENOENT if the given character c is not a valid Morse character. errno is
set to EBUSY if the audio sink or keying system is busy. errno is set to EAGAIN if the
tone queue is full, or if there is insufficient space to queue the tones for the
character.
This routine queues its arguments for background processing. See cw_wait_for_tone() and
cw_wait_for_tone_queue() for ways to check the progress of sending.
Parameter: c - character to send
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_send_string(const char *string)
Brief: Send a given ASCII string in Morse code
errno is set to ENOENT if any character in the string is not a valid Morse character.
errno is set to EBUSY if audio sink or keying system is busy.
errno is set to EAGAIN if the tone queue is full or if the tone queue runs out of space
part way through queueing the string. However, an indeterminate number of the characters
from the string will have already been queued.
For safety, clients can ensure the tone queue is empty before queueing a string, or use
cw_send_character() if they need finer control.
This routine queues its arguments for background processing, the actual sending happens in
background processing. See cw_wait_for_tone() and cw_wait_for_tone_queue() for ways to
check the progress of sending.
Parameter: string - string to send
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
void cw_reset_send_receive_parameters(void)
Brief: Reset send/receive parameters
Reset the library speed, frequency, volume, gap, tolerance, weighting, adaptive receive,
and noise spike threshold to their initial default values: send/receive speed 12 WPM,
volume 70 %, frequency 800 Hz, gap 0 dots, tolerance 50 %, and weighting 50 %.
const char *cw_get_console_device(void)
Brief: Return char string with console device path
Returned pointer is owned by library.
Returns: char string with current console device path
const char *cw_get_soundcard_device(void)
Brief: Return char string with soundcard device name/path
Returned pointer is owned by library.
Returns: char string with current soundcard device name or device path
const char *cw_generator_get_audio_system_label(void)
Brief: Get a readable label of current audio system
The function returns one of following strings: None, Null, Console, OSS, ALSA, PulseAudio,
Soundcard
Returns: audio system's label
int cw_register_tone_queue_low_callback(void (*callback_func)(void*), void *callback_arg,
int level)
Brief: Register callback for low queue state
Register a function to be called automatically by the dequeue routine whenever the tone
queue falls to a given level. To be more precise: the callback is called by queue manager
if, after dequeueing a tone, the manager notices that tone queue length has become equal
or less than level.
callback_arg may be used to give a value passed back on callback calls. A NULL function
pointer suppresses callbacks. On success, the routine returns CW_SUCCESS.
If level is invalid, the routine returns CW_FAILURE with errno set to EINVAL. Any
callback supplied will be called in signal handler context.
Parameter: callback_func - callback function to be registered
Parameter: callback_arg - argument for callback_func to pass return value
Parameter: level - low level of queue triggering callback call
Returns: CW_SUCCESS on successful registration
Returns: CW_FAILURE on failure
bool cw_is_tone_busy(void)
Brief: Check if tone sender is busy
Indicate if the tone sender is busy.
Returns: true if there are still entries in the tone queue
Returns: false if the queue is empty
int cw_wait_for_tone(void)
Brief: Wait for the current tone to complete
The routine returns CW_SUCCESS on success. If called with SIGALRM blocked, the routine
returns CW_FAILURE, with errno set to EDEADLK, to avoid indefinite waits.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_wait_for_tone_queue(void)
Brief: Wait for the tone queue to drain
The routine returns CW_SUCCESS on success. If called with SIGALRM blocked, the routine
returns false, with errno set to EDEADLK, to avoid indefinite waits.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_wait_for_tone_queue_critical(int level)
Brief: Wait for the tone queue to drain until only as many tones as given in level remain
queued
This routine is for use by programs that want to optimize themselves to avoid the cleanup
that happens when the tone queue drains completely; such programs have a short time in
which to add more tones to the queue.
The routine returns CW_SUCCESS on success. If called with SIGALRM blocked, the routine
returns false, with errno set to EDEADLK, to avoid indefinite waits.
Parameter: level - low level in queue, at which to return
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
bool cw_is_tone_queue_full(void)
Brief: Indicate if the tone queue is full
Returns: true if tone queue is full
Returns: false if tone queue is not full
int cw_get_tone_queue_capacity(void)
Brief: Return the number of entries the tone queue can accommodate
int cw_get_tone_queue_length(void)
Brief: Return the number of entries currently pending in the tone queue
void cw_flush_tone_queue(void)
Brief: Cancel all pending queued tones, and return to silence.
If there is a tone in progress, the function will wait until this last one has completed,
then silence the tones.
This function may be called with SIGALRM blocked, in which case it will empty the queue as
best it can, then return without waiting for the final tone to complete. In this case, it
may not be possible to guarantee silence after the call.
void cw_reset_tone_queue(void)
Cancel all pending queued tones, reset any queue low callback registered, and return to
silence. This function is suitable for calling from an application exit handler.
int cw_queue_tone(int usecs, int frequency)
Brief: Primitive access to simple tone generation
This routine queues a tone of given duration and frequency. The routine returns
CW_SUCCESS on success. If usec or frequency are invalid, it returns CW_FAILURE with errno
set to EINVAL. If the sound card, console speaker, or keying function are busy, it
returns CW_FAILURE with errno set to EBUSY. If the tone queue is full, it returns false
with errno set to EAGAIN.
Parameter: usecs - duration of queued tone, in microseconds
Parameter: frequency - frequency of queued tone
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_set_receive_speed(int new_value)
Brief: Set receiving speed of receiver
See documentation of cw_set_send_speed() for more information.
See libcw.h/CW_SPEED_{INITIAL|MIN|MAX} for initial/minimal/maximal value of receive speed.
errno is set to EINVAL if new_value is out of range. errno is set to EPERM if adaptive
receive speed tracking is enabled.
Parameter: new_value - new value of receive speed to be assigned to receiver
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_get_receive_speed(void)
Brief: Get receiving speed from receiver
Returns: current value of the receiver's receive speed
int cw_set_tolerance(int new_value)
Brief: Set tolerance for receiver
See libcw.h/CW_TOLERANCE_{INITIAL|MIN|MAX} for initial/minimal/maximal value of tolerance.
errno is set to EINVAL if new_value is out of range.
Parameter: new_value - new value of tolerance to be assigned to receiver
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_get_tolerance(void)
Brief: Get tolerance from receiver
Returns: current value of receiver's tolerance
void cw_get_receive_parameters(int *dot_usecs, int *dash_usecs,
int *dot_min_usecs, int *dot_max_usecs,
int *dash_min_usecs, int *dash_max_usecs,
int *end_of_element_min_usecs,
int *end_of_element_max_usecs,
int *end_of_element_ideal_usecs,
int *end_of_character_min_usecs,
int *end_of_character_max_usecs,
int *end_of_character_ideal_usecs,
int *adaptive_threshold)
Brief: Get timing parameters for receiving, and adaptive threshold
Return the low-level timing parameters calculated from the speed, gap, tolerance, and
weighting set. Parameter values are returned in microseconds.
Use NULL for the pointer argument to any parameter value not required.
Parameter: dot_usecs
Parameter: dash_usecs
Parameter: dot_min_usecs
Parameter: dot_max_usecs
Parameter: dash_min_usecs
Parameter: dash_max_usecs
Parameter: end_of_element_min_usecs
Parameter: end_of_element_max_usecs
Parameter: end_of_element_ideal_usecs
Parameter: end_of_character_min_usecs
Parameter: end_of_character_max_usecs
Parameter: end_of_character_ideal_usecs
Parameter: adaptive_threshold
int cw_set_noise_spike_threshold(int new_value)
Brief: Set noise spike threshold for receiver
Set the period shorter than which, on receive, received marks are ignored. This allows
the "receive mark" functions to apply noise canceling for very short apparent marks. For
useful results the value should never exceed the dot length of a dot at maximum speed:
20000 microseconds (the dot length at 60WPM). Setting a noise threshold of zero turns off
receive mark noise canceling.
The default noise spike threshold is 10000 microseconds.
errno is set to EINVAL if new_value is out of range.
Parameter: new_value - new value of noise spike threshold to be assigned to receiver
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_get_noise_spike_threshold(void)
Brief: Get noise spike threshold from receiver
See documentation of cw_set_noise_spike_threshold() for more information
Returns: current value of receiver's threshold
void cw_get_receive_statistics(double *dot_sd, double *dash_sd,
double *element_end_sd, double *character_end_sd)
Brief: Calculate and return receiver's timing statistics
These statistics may be used to obtain a measure of the accuracy of received CW. The
values dot_sd and dot_sd contain the standard deviation of dot and dash lengths from the
ideal values, and element_end_sd and element_end_sd the deviations for inter element and
inter character spacing. Statistics are held for all timings in a 256 element circular
buffer. If any statistic cannot be calculated, because no records for it exist, the
returned value is 0.0. Use NULL for the pointer argument to any statistic not required.
Parameter: dot_sd
Parameter: dash_sd
Parameter: element_end_sd
Parameter: character_end_sd
void cw_reset_receive_statistics(void)
Brief: Clear the receive statistics buffer
Clear the receive statistics buffer by removing all records from it and returning it to
its initial default state.
void cw_enable_adaptive_receive(void)
Brief: Enable adaptive receive speed tracking
If adaptive speed tracking is enabled, the receive functions will attempt to automatically
adjust the receive speed setting to match the speed of the incoming Morse code. If it is
disabled, the receive functions will use fixed speed settings, and reject incoming Morse
which is not at the expected speed.
Adaptive speed tracking uses a moving average length of the past N marks as its baseline
for tracking speeds. The default state is adaptive speed tracking disabled.
void cw_disable_adaptive_receive(void)
Brief: Disable adaptive receive speed tracking
See documentation of cw_enable_adaptive_receive() for more information
bool cw_get_adaptive_receive_state(void)
Brief: Get adaptive receive speed tracking flag
The function returns state of "adaptive receive enabled" flag. See documentation of
cw_enable_adaptive_receive() for more information
Returns: true if adaptive speed tracking is enabled
Returns: false otherwise
int cw_start_receive_tone(const struct timeval *timestamp)
Brief: Signal beginning of receive mark
Called on the start of a receive mark. If the timestamp is NULL, the current timestamp is
used as beginning of mark.
The function should be called by client application when pressing a key down (closing a
circuit) has been detected by client application.
On error the function returns CW_FAILURE, with errno set to ERANGE if the call is directly
after another cw_start_receive_tone() call or if an existing received character has not
been cleared from the buffer, or EINVAL if the timestamp passed in is invalid.
Parameter: timestamp - time stamp of "key down" event
Returns: CW_SUCCESS on success
Returns: CW_FAILURE otherwise (with errno set)
int cw_end_receive_tone(const struct timeval *timestamp)
Brief: Signal end of mark
The function should be called by client application when releasing a key (opening a
circuit) has been detected by client application.
If the timestamp is NULL, the current time is used as timestamp of end of mark.
On success, the routine adds a dot or dash to the receiver's representation buffer, and
returns CW_SUCCESS.
On failure, it returns CW_FAIURE, with errno set to: ERANGE if the call was not preceded
by a cw_start_receive_tone() call, EINVAL if the timestamp passed in is not valid, ENOENT
if the mark length was out of bounds for the permissible dot and dash lengths and fixed
speed receiving is selected, ENOMEM if the receiver's representation buffer is full,
EAGAIN if the mark was shorter than the threshold for noise and was therefore ignored.
Parameter: timestamp - time stamp of "key up" event
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_receive_buffer_dot(const struct timeval *timestamp)
Brief: Add a dot to the receiver's representation buffer
Documentation for both cw_receive_buffer_dot() and cw_receive_buffer_dash():
Since we can't add a mark to the buffer without any accompanying timing information, the
functions accepts timestamp of the "end of mark" event. If the timestamp is NULL, the
current timestamp is used.
These routines are for client code that has already determined whether a dot or dash was
received by a method other than calling the routines cw_start_receive_tone() and
cw_end_receive_tone().
On success, the relevant mark is added to the receiver's representation buffer.
On failure, the routines return CW_FAILURE, with errno set to ERANGE if preceded by a
cw_start_receive_tone() call with no matching cw_end_receive_tone() or if an error
condition currently exists within the receiver's buffer, or ENOMEM if the receiver's
representation buffer is full.
Parameter: timestamp - timestamp of "end of dot" event
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_receive_buffer_dash(const struct timeval *timestamp)
Brief: Add a dash to the receiver's representation buffer
See documentation of cw_receive_buffer_dot() for more information.
Parameter: timestamp - timestamp of "end of dash" event
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_receive_representation(const struct timeval *timestamp,
/* out */ char *representation,
/* out */ bool *is_end_of_word,
/* out */ bool *is_error)
Brief: Get the current buffered representation from the receiver's representation buffer
On success the function fills in representation with the contents of the current
representation buffer and returns CW_SUCCESS.
On failure, it returns CW_FAILURE and sets errno to: ERANGE if not preceded by a
cw_end_receive_tone() call, a prior successful cw_receive_representation call, or a prior
cw_receive_buffer_dot or cw_receive_buffer_dash, EINVAL if the timestamp passed in is
invalid, EAGAIN if the call is made too early to determine whether a complete
representation has yet been placed in the buffer (that is, less than the end-of-character
gap period elapsed since the last cw_end_receive_tone() or cw_receive_buffer_dot/dash
call). This is not a *hard* error, just an information that the caller should try to get
the representation later.
is_end_of_word indicates that the space after the last mark received is longer that the
end-of-character gap, so it must be qualified as end-of-word gap.
is_error indicates that the representation was terminated by an error condition.
TODO: the function should be called cw_receiver_poll_representation().
The function is called periodically (poll()-like function) by client code in hope that at
some attempt receiver will be ready to pass representation. The attempt succeeds only if
data stream is in "space" state. To mark end of the space, client code has to provide a
timestamp (or pass NULL timestamp, the function will get time stamp at function call). The
receiver needs to know the "end of space" event - thus the timestamp parameter.
Parameter: timestamp - timestamp of event that ends "end-of-character" gap or "end-of-
word" gap
Parameter: representation - buffer for representation (output parameter)
Parameter: is_end_of_word - buffer for "is end of word" state (output parameter)
Parameter: is_error - buffer for "error" state (output parameter)
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_receive_character(const struct timeval *timestamp,
/* out */ char *c,
/* out */ bool *is_end_of_word,
/* out */ bool *is_error)
Brief: Get a current character
Function returns the character currently stored in receiver's representation buffer.
On success the function returns CW_SUCCESS, and fills c with the contents of the current
representation buffer, translated into a character.
On failure the function returns CW_FAILURE, with errno set to:
ERANGE if not preceded by a cw_end_receive_tone() call, a prior successful
cw_receive_character() call, or a cw_receive_buffer_dot() or cw_receive_buffer_dash()
call, EINVAL if the timestamp passed in is invalid, or EAGAIN if the call is made too
early to determine whether a complete character has yet been placed in the buffer (that
is, less than the end-of-character gap period elapsed since the last cw_end_receive_tone()
or cw_receive_buffer_dot/dash call). ENOENT if character stored in receiver cannot be
recognized as valid
is_end_of_word indicates that the space after the last mark received is longer that the
end-of-character gap, so it must be qualified as end-of-word gap.
is_error indicates that the character was terminated by an error condition.
Parameter: timestamp - timestamp of event that ends end-of-character gap or end-of-word
gap
Parameter: c - buffer for character (output parameter)
Parameter: is_end_of_word - buffer for "is end of word" state (output parameter)
Parameter: is_error - buffer for "error" state (output parameter)
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
void cw_clear_receive_buffer(void)
Brief: Clear receiver's representation buffer
Clears the receiver's representation buffer, resets receiver's internal state. This
prepares the receiver to receive marks and spaces again.
This routine must be called after successful, or terminating, cw_receive_representation()
or cw_receive_character() calls, to clear the states and prepare the buffer to receive
more marks and spaces.
int cw_get_receive_buffer_capacity(void)
Brief: Get the number of elements (dots/dashes) the receiver's buffer can accommodate
The maximum number of elements written out by cw_receive_representation() is the capacity
+ 1, the extra character being used for the terminating NUL.
Returns: number of elements that can be stored in receiver's representation buffer
int cw_get_receive_buffer_length(void)
Brief: Get the number of elements (dots/dashes) currently pending in the cw_receiver's
representation buffer
Returns: number of elements in receiver's representation buffer
void cw_reset_receive(void)
Brief: Clear receive data
Clear the receiver's representation buffer, statistics, and any retained receiver's state.
This function is suitable for calling from an application exit handler.
void cw_register_keying_callback(void (*callback_func)(void*, int), void *callback_arg)
Brief: Register external callback function for keying
Register a callback_func function that should be called when a state of a key changes from
"key open" to "key closed", or vice-versa.
The first argument passed to the registered callback function is the supplied
callback_arg, if any. The second argument passed to registered callback function is the
key state: CW_KEY_STATE_CLOSED (one/true) for "key closed", and CW_KEY_STATE_OPEN
(zero/false) for "key open".
Calling this routine with a NULL function address disables keying callbacks. Any callback
supplied will be called in signal handler context (??).
Parameter: callback_func - callback function to be called on key state changes
Parameter: callback_arg - first argument to callback_func
void cw_enable_iambic_curtis_mode_b(void)
Brief: Enable iambic Curtis mode B
Normally, the iambic keying functions will emulate Curtis 8044 Keyer mode A. In this
mode, when both paddles are pressed together, the last dot or dash being sent on release
is completed, and nothing else is sent. In mode B, when both paddles are pressed together,
the last dot or dash being sent on release is completed, then an opposite element is also
sent. Some operators prefer mode B, but timing is more critical in this mode. The default
mode is Curtis mode A.
void cw_disable_iambic_curtis_mode_b(void)
See documentation of cw_enable_iambic_curtis_mode_b() for more information
int cw_get_iambic_curtis_mode_b_state(void)
See documentation of cw_enable_iambic_curtis_mode_b() for more information
int cw_notify_keyer_paddle_event(int dot_paddle_state, int dash_paddle_state)
Brief: Inform about changed state of iambic keyer's paddles
Function informs the library that the iambic keyer paddles have changed state. The new
paddle states are recorded, and if either transition from false to true, paddle latches,
for iambic functions, are also set.
On success, the routine returns CW_SUCCESS. On failure, it returns CW_FAILURE, with errno
set to EBUSY if the tone queue or straight key are using the sound card, console speaker,
or keying system.
If appropriate, this routine starts the keyer functions sending the relevant element.
Element send and timing occurs in the background, so this routine returns almost
immediately. See cw_keyer_element_wait() and cw_keyer_wait() for details about how to
check the current status of iambic keyer background processing.
Parameter: dot_paddle_state
Parameter: dash_paddle_state
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_notify_keyer_dot_paddle_event(int dot_paddle_state)
Brief: Change state of dot paddle
Alter the state of just one of the two iambic keyer paddles. The other paddle state of
the paddle pair remains unchanged.
See cw_notify_keyer_paddle_event() for details of iambic keyer background processing, and
how to check its status.
Parameter: dot_paddle_state
int cw_notify_keyer_dash_paddle_event(int dash_paddle_state)
See documentation of cw_notify_keyer_dot_paddle_event() for more information
void cw_get_keyer_paddles(int *dot_paddle_state, int *dash_paddle_state)
Brief: Get the current saved states of the two paddles
Parameter: dot_paddle_state
Parameter: dash_paddle_state
void cw_get_keyer_paddle_latches(int *dot_paddle_latch_state, int
*dash_paddle_latch_state)
Brief: Get the current states of paddle latches
Function returns the current saved states of the two paddle latches. A paddle latches is
set to true when the paddle state becomes true, and is cleared if the paddle state is
false when the element finishes sending.
Parameter: dot_paddle_latch_state
Parameter: dash_paddle_latch_state
bool cw_is_keyer_busy(void)
Brief: Check if a keyer is busy
Returns: true if keyer is busy
Returns: false if keyer is not busy
int cw_wait_for_keyer_element(void)
Brief: Wait for end of element from the keyer
Waits until the end of the current element, dot or dash, from the keyer.
On error the function returns CW_FAILURE, with errno set to EDEADLK if SIGALRM is blocked.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_wait_for_keyer(void)
Brief: Wait for the current keyer cycle to complete
The routine returns CW_SUCCESS on success. On error, it returns CW_FAILURE, with errno
set to EDEADLK if SIGALRM is blocked or if either paddle state is true.
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
void cw_reset_keyer(void)
Brief: Reset iambic keyer data
Clear all latches and paddle states of iambic keyer, return to Curtis 8044 Keyer mode A,
and return to silence. This function is suitable for calling from an application exit
handler.
int cw_notify_straight_key_event(int key_state)
Brief: Inform the library that the straight key has changed state
This routine returns CW_SUCCESS on success. On error, it returns CW_FAILURE, with errno
set to EBUSY if the tone queue or iambic keyer are using the sound card, console speaker,
or keying control system. If key_state indicates no change of state, the call is ignored.
key_state may be either CW_KEY_STATE_OPEN (false) or CW_KEY_STATE_CLOSED (true).
Parameter: key_state - state of straight key
int cw_get_straight_key_state(void)
Brief: Get saved state of straight key
Returns the current saved state of the straight key.
Returns: CW_KEY_STATE_CLOSED (true) if the key is down
Returns: CW_KEY_STATE_OPEN (false) if the key up
bool cw_is_straight_key_busy(void)
Brief: Check if the straight key is busy
This routine is just a pseudonym for cw_get_straight_key_state(), and exists to fill a
hole in the API naming conventions.
Returns: true if the straight key is busy
Returns: false if the straight key is not busy
void cw_reset_straight_key(void)
Brief: Clear the straight key state, and return to silence
This function is suitable for calling from an application exit handler.
bool cw_is_alsa_possible(const char *device)
Brief: Check if it is possible to open ALSA output
Function first tries to load ALSA library, and then does a test opening of ALSA output,
but it closes it before returning.
Parameter: device - name of ALSA device to be used; if NULL then library will use default
device.
Returns: true if opening ALSA output succeeded;
Returns: false if opening ALSA output failed;
bool cw_is_console_possible(const char *device)
Brief: Check if it is possible to open console output
Function does a test opening and test writing to console device, but it closes it before
returning.
The function tests that the given console file exists, and that it will accept the
KIOCSOUND ioctl. It unconditionally returns false on platforms that do no support the
KIOCSOUND ioctl.
Call to ioctl will fail if calling code doesn't have root privileges.
This is the only place where we ask if KIOCSOUND is defined, so client code must call this
function whenever it wants to use console output, as every other function called to
perform console operations will happily assume that it is allowed to perform such
operations.
Parameter: device - name of console device to be used; if NULL then library will use
default device.
Returns: true if opening console output succeeded;
Returns: false if opening console output failed;
int cw_console_write(cw_gen_t *gen, cw_tone_t *tone)
Brief: Pseudo-device for playing sound with console
Function behaving like a device, to which one does a blocking write. It generates sound
with parameters (frequency and duration) specified in tone.. After playing X microseconds
of tone it returns. It is intended to behave like a blocking write() function.
Parameter: gen - current generator
Parameter: tone - tone to play with generator
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_get_character_count(void)
Brief: Return the number of characters present in character lookup table
Return the number of characters that are known to libcw. The number includes:
•
ASCII 7bit letters,
•
numerals,
•
punctuation,
•
ISO 8859-1 accented characters,
•
ISO 8859-2 accented characters,
•
non-standard procedural signal extensions to standard CW characters.
Returns: number of characters known to libcw
void cw_list_characters(char *list)
Brief: Get list of characters present in character lookup table
Function provides a string containing all of the characters represented in library's
lookup table.
The list includes:
•
ASCII 7bit letters,
•
numerals,
•
punctuation,
•
ISO 8859-1 accented characters,
•
ISO 8859-2 accented characters,
•
non-standard procedural signal extensions to standard CW characters.
list should be allocated and managed by caller. The length of list must be at least one
greater than the number of characters represented in the character lookup table, returned
by cw_get_character_count().
Parameter: list - pointer to space to be filled by function
int cw_get_maximum_representation_length(void)
Brief: Get length of the longest representation
Function returns the string length of the longest representation in the character lookup
table.
Returns: a positive number - length of the longest representation
int cw_lookup_character(char c, char *representation)
Brief: Get representation of a given character
The function is depreciated, use cw_character_to_representation() instead.
Return the string representation (shape) of a given Morse code character c.
The routine returns CW_SUCCESS on success, and fills in the string pointer
(representation) passed in. On failure, it returns CW_FAILURE and sets errno to ENOENT,
indicating that the character c could not be found.
The length of representation buffer must be at least one greater than the length of
longest representation held in the character lookup table. The largest value of length is
returned by cw_get_maximum_representation_length().
Parameter: c - character to look up
Parameter: representation - pointer to space for representation of character
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
char *cw_character_to_representation(int c)
Brief: Get representation of a given character
On success return representation of a given character. Returned pointer is owned by
caller of the function.
On failure function returns NULL and sets errno: ENOENT indicates that the character could
not be found. ENOMEM indicates that character has been found, but function failed to
strdup() representation.
Parameter: c - character to look up
Returns: pointer to freshly allocated representation on success
Returns: NULL on failure
int cw_check_representation(const char *representation)
Brief: Check if representation of a character is valid
This function is depreciated, use cw_representation_is_valid() instead.
Check that the given string is a valid Morse representation. A valid string is one
composed of only "." and "-" characters.
If representation is invalid, function returns CW_FAILURE and sets errno to EINVAL.
Parameter: representation - representation of a character to check
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
bool cw_representation_is_valid(const char *representation)
Brief: Check if representation of a character is valid
Check that the given string is a valid Morse representation. A valid string is one
composed of only "." and "-" characters. This means that the function checks only if
representation is error-free, and not whether the representation represents
existing/defined character.
If representation is invalid, function returns false and sets errno to EINVAL.
Parameter: representation - representation of a character to check
Returns: true on success
Returns: false on failure
int cw_lookup_representation(const char *representation, char *c)
Brief: Get the character represented by a given Morse representation
This function is depreciated, use cw_representation_to_character() instead.
Function checks representation, and if it is valid and represents a known character,
function returns CW_SUCCESS. Additionally, if c is non-NULL, function puts the looked up
character in c.
c should be allocated by caller. Function assumes that c being NULL pointer is a valid
situation, and can return CW_SUCCESS in such situation.
On error, function returns CW_FAILURE. errno is set to EINVAL if any character of the
representation is invalid, or ENOENT to indicate that the character represented by
representation could not be found.
Parameter: representation - representation of a character to look up
Parameter: c - location where to put looked up character
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
int cw_representation_to_character(const char *representation)
Brief: Return the character represented by a given Morse representation
Function checks representation, and if it is valid and represents a known character,
function returns the character (a non-zero value).
On error, function returns zero. errno is set to EINVAL if any character of the
representation is invalid, or ENOENT to indicate that the character represented by
representation could not be found.
Parameter: representation - representation of a character to look up
Returns: non-zero character on success
Returns: zero on failure
int cw_get_procedural_character_count(void)
Brief: Get number of procedural signals
Returns: the number of characters represented in the procedural signal expansion lookup
table
void cw_list_procedural_characters(char *list)
Brief: Get list of characters for which procedural expansion is available
Function returns into list a string containing all of the Morse characters for which
procedural expansion is available. The length of list must be at least by one greater
than the number of characters represented in the procedural signal expansion lookup table,
returned by cw_get_procedural_character_count().
list is managed by caller
Parameter: list - space for returned characters
int cw_get_maximum_procedural_expansion_length(void)
Brief: Get length of the longest procedural expansion
Function returns the string length of the longest expansion in the procedural signal
expansion table.
Returns: length
int cw_lookup_procedural_character(char c, char *expansion, int *is_usually_expanded)
Brief: Get the string expansion of a given Morse code procedural signal character
On success the function - fills expansion with the string expansion of a given Morse code
procedural signal character c; - sets is_usuall_expanded to true as a display hint for the
caller; - returns CW_SUCCESS.
Both expansion and expansion must be allocated and managed by caller. They can be NULL,
then the function won't attempt to use them.
The length of expansion must be at least by one greater than the longest expansion held in
the procedural signal character lookup table, as returned by
cw_get_maximum_procedural_expansion_length().
If procedural signal character c cannot be found, the function sets errno to ENOENT and
returns CW_FAILURE.
Parameter: c - character to look up
Parameter: expansion - output, space to fill with expansion of the character
Parameter: is_usually_expanded - visual hint
Returns: CW_FAILURE on failure (errno is set to ENOENT)
Returns: CW_SUCCESS on success
int cw_get_maximum_phonetic_length(void)
Brief: Get maximum length of a phonetic
Returns: the string length of the longest phonetic in the phonetics lookup table
int cw_lookup_phonetic(char c, char *phonetic)
Brief: Get the phonetic of a given character
On success the routine fills in the string pointer passed in with the phonetic of given
character c.
The length of phonetic must be at least one greater than the longest phonetic held in the
phonetic lookup table, as returned by cw_get_maximum_phonetic_length().
If character cannot be found, the function sets errno to ENOENT.
Parameter: c - character to look up
Parameter: phonetic - output, space for phonetic of a character
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
bool cw_character_is_valid(char c)
Brief: Checks that the given character is validly sendable in Morse
Function sets errno to ENOENT on failure.
Parameter: c - character to check
Returns: CW_SUCCESS if character is valid
Returns: CW_FAILURE if character is invalid
bool cw_string_is_valid(const char *string)
Brief: Validate a string
Check that each character in the given string is valid and can be sent by libcw as a Morse
character.
Function sets errno to EINVAL on failure
Parameter: string - string to check
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
void cw_debug_flush(cw_debug_t *debug)
Brief: Write all events from the debug object to a file
Function writes all events stored in the debug object to file associated with the object,
and removes the events.
List of events is preceded with "FLUSH START0 line, and followed by "FLUSH END0 line.
Parameter: debug - debug object
void cw_set_debug_flags(uint32_t flags)
Brief: Set a value of internal debug flags variable
Assign specified value to library's internal debug flags variable. Note that this
function doesn't *append* given flag to the variable, it erases existing value and assigns
new one. Use cw_get_debug_flags() if you want to OR new flag with existing ones.
Parameter: new_value - new value to be assigned to the library
void cw_debug_set_flags(cw_debug_t *debug_object, uint32_t flags)
uint32_t cw_get_debug_flags(void)
Brief: Get current library's debug flags
Function returns value of library's internal debug variable.
Returns: value of library's debug flags variable
uint32_t cw_debug_get_flags(cw_debug_t *debug_object)
bool cw_debug_has_flag(cw_debug_t *debug_object, uint32_t flag)
Brief: Check if given debug flag is set
Function checks if a specified debug flag is set in internal variable of libcw library.
Parameter: flag - flag to be checked.
Returns: true if given flag is set
Returns: false if given flag is not set
int cw_generator_set_tone_slope(cw_gen_t *gen, int slope_shape, int slope_len)
Brief: Set parameters of tones generated by generator
Most of variables related to slope of tones is in tone data type, but there are still some
variables that are generator-specific, as they are common for all tones. This function
sets two of these variables.
A: If you pass to function conflicting values of slope_shape and slope_len, the function
will return CW_FAILURE. These conflicting values are rectangular slope shape and larger
than zero slope length. You just can't have rectangular slopes that have non-zero length.
B: If you pass to function '-1' as value of both slope_shape and slope_len, the function
won't change any of the related two generator's parameters.
C1: If you pass to function '-1' as value of either slope_shape or slope_len, the function
will attempt to set only this generator's parameter that is different than '-1'.
C2: However, if selected slope shape is rectangular, function will set generator's slope
length to zero, even if value of
slope_len is '-1'.
D: Notice that the function allows non-rectangular slope shape with zero length of the
slopes. The slopes will be non-rectangular, but just unusually short.
The function should be called every time one of following parameters change:
•
shape of slope,
•
length of slope,
•
generator's sample rate,
•
generator's volume.
There are four supported shapes of slopes:
•
linear (the only one supported by libcw until version 4.1.1),
•
raised cosine (supposedly the most desired shape),
•
sine,
•
rectangular.
Use CW_TONE_SLOPE_SHAPE_* symbolic names as values of slope_shape.
FIXME: first argument of this public function is gen, but no function provides access to
generator variable.
Parameter: gen - generator for which to set tone slope parameters
Parameter: slope_shape - shape of slope: linear, raised cosine, sine, rectangular
Parameter: slope_len - length of slope [microseconds]
Returns: CW_SUCCESS on success
Returns: CW_FAILURE on failure
bool cw_is_oss_possible(const char *device)
Brief: Check if it is possible to open OSS output
Function does a test opening and test configuration of OSS output, but it closes it before
returning.
Parameter: device - name of OSS device to be used; if NULL then library will use default
device.
Returns: true if opening OSS output succeeded;
Returns: false if opening OSS output failed;
bool cw_is_pa_possible(const char *device)
Brief: Check if it is possible to open PulseAudio output
Function first tries to load PulseAudio library, and then does a test opening of
PulseAudio output, but it closes it before returning.
Parameter: device - sink device, NULL for default PulseAudio device
Returns: true if opening PulseAudio output succeeded;
Returns: false if opening PulseAudio output failed;
void cw_block_callback(int block)
Brief: Block the callback from being called
Function blocks the callback from being called for a critical section of caller code if
block is true, and unblocks the callback if block is false.
Function works by blocking SIGALRM; a block should always be matched by an unblock,
otherwise the tone queue will suspend forever.
Parameter: block - pass 1 to block SIGALRM, and 0 to unblock it
int cw_register_signal_handler(int signal_number, void (*callback_func)(int))
Brief: Register a signal handler and optional callback function for given signal number
On receipt of that signal, all library features will be reset to their default states.
Following the reset, if callback_func is a function pointer, the function is called; if it
is SIG_DFL, the library calls exit(); and if it is SIG_IGN, the library returns from the
signal handler.
This is a convenience function for clients that need to clean up library on signals, with
either exit, continue, or an additional function call; in effect, a wrapper round a
restricted form of sigaction.
The signal_number argument indicates which signal to catch.
On problems errno is set to EINVAL if signal_number is invalid or if a handler is already
installed for that signal, or to the sigaction error code.
Parameter: signal_number
Parameter: callback_func
Returns: CW_SUCCESS - if the signal handler installs correctly
Returns: CW_FAILURE - on errors or problems
int cw_unregister_signal_handler(int signal_number)
Brief: Unregister a signal handler interception
Function removes a signal handler interception previously registered with
cw_register_signal_handler().
Parameter: signal_number
Returns: true if the signal handler uninstalls correctly
Returns: false otherwise (with errno set to EINVAL or to the sigaction error code)
int cw_version(void)
Brief: Return version number of libcw library
Return the version number of the library. Version numbers (major and minor) are returned
as an int, composed of major_version << 16 | minor_version.
Returns: library's major and minor version number encoded as single int
void cw_license(void)
Brief: Print libcw's license text to stdout
Function prints information about libcw version, followed by short text presenting libcw's
copyright and license notice.
const char *cw_get_audio_system_label(int audio_system)
Brief: Get a readable label of given audio system
The function returns one of following strings: None, Null, Console, OSS, ALSA, PulseAudio,
Soundcard
Returned pointer is owned and managed by the library.
TODO: change the declaration to "const char *const cw_get_audio_system_label(...)"?
Parameter: audio_system - ID of audio system
Returns: audio system's label
void cw_get_speed_limits(int *min_speed, int *max_speed)
Brief: Get speed limits
Get (through function's arguments) limits on speed of morse code that can be generated by
generator.
See CW_SPEED_MIN and CW_SPEED_MAX in libcw.h for values.
Parameter: min_speed - minimal allowed speed
Parameter: max_speed - maximal allowed speed
void cw_get_frequency_limits(int *min_frequency, int *max_frequency)
Brief: Get frequency limits
Get (through function's arguments) limits on frequency that can be generated by generator.
See CW_FREQUENCY_MIN and CW_FREQUENCY_MAX in libcw.h for values.
Parameter: min_frequency - minimal allowed frequency
Parameter: max_frequency - maximal allowed frequency
void cw_get_volume_limits(int *min_volume, int *max_volume)
Brief: Get volume limits
Get (through function's arguments) limits on volume of sound generated by generator.
See CW_VOLUME_MIN and CW_VOLUME_MAX in libcw.h for values.
Parameter: min_volume - minimal allowed volume
Parameter: max_volume - maximal allowed volume
void cw_get_gap_limits(int *min_gap, int *max_gap)
Brief: Get gap limits
Get (through function's arguments) limits on gap in cw signal generated by generator.
See CW_GAP_MIN and CW_GAP_MAX in libcw.h for values.
Parameter: min_gap - minimal allowed gap
Parameter: max_gap - maximal allowed gap
void cw_get_tolerance_limits(int *min_tolerance, int *max_tolerance)
Brief: Get tolerance limits
Get (through function's arguments) limits on "tolerance" parameter of generator.
See CW_TOLERANCE_MIN and CW_TOLERANCE_MAX in libcw.h for values.
Parameter: min_tolerance - minimal allowed tolerance
Parameter: max_tolerance - maximal allowed tolerance
void cw_get_weighting_limits(int *min_weighting, int *max_weighting)
Brief: Get weighting limits
Get (through function's arguments) limits on "weighting" parameter of generator.
See CW_WEIGHTING_MIN and CW_WEIGHTING_MAX in libcw.h for values.
Parameter: min_weighting - minimal allowed weighting
Parameter: max_weighting - maximal allowed weighting
void cw_complete_reset(void)
Brief: Reset all library features to their default states
Clears the tone queue, receive buffers and retained state information, any current keyer
activity, and any straight key activity, returns to silence, and closes soundcard and
console devices. This function is suitable for calling from an application exit handler.
NOTES
Despite the fact that this manual page constantly and consistently refers to Morse code
elements as dots and dashes, DO NOT think in these terms when trying to learn Morse code.
Always think of them as 'dit's and 'dah's.
libcw uses system itimers for its internal timing. On most UNIX flavours, itimers are not
guaranteed to signal a program exactly at the specified time, and they generally offer a
resolution only as good as the normal system 'clock tick' resolution. An itimer SIGALRM
usually falls on a system clock tick, making it accurate to no better than 10mS on a
typical 100Hz kernel.
The effect of this is that an itimer period is generally either exactly as specified, or,
more likely, slightly longer. At higher WPM settings, the cumulative effect of this
affects timing accuracy, because at higher speeds, there are fewer 10mS clock ticks in a
dot period. For example, at 12 WPM, the dot length is 100mS, enough to contain five
kernel clock ticks; at 60 WPM, the dot length is 20mS, or just two kernel clock ticks. So
at higher speeds, the effect of itimer resolutions becomes more pronounced.
SEE ALSO
Man pages for cw(7,LOCAL), cw(1,LOCAL), cwgen(1,LOCAL), cwcp(1,LOCAL), and xcwcp(1,LOCAL).