/* * This file is part of the libsigrok project. * * Copyright (C) 2013 Bert Vermeulen * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #ifndef LIBSIGROK_SIGROK_H #define LIBSIGROK_SIGROK_H #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif /** * @file * * The public libsigrok header file to be used by frontends. * * This is the only file that libsigrok users (frontends) are supposed to * use and \#include. There are other header files which get installed with * libsigrok, but those are not meant to be used directly by frontends. * * The correct way to get/use the libsigrok API functions is: * * @code{.c} * #include * @endcode */ /* * All possible return codes of libsigrok functions must be listed here. * Functions should never return hardcoded numbers as status, but rather * use these enum values. All error codes are negative numbers. * * The error codes are globally unique in libsigrok, i.e. if one of the * libsigrok functions returns a "malloc error" it must be exactly the same * return value as used by all other functions to indicate "malloc error". * There must be no functions which indicate two different errors via the * same return code. * * Also, for compatibility reasons, no defined return codes are ever removed * or reused for different errors later. You can only add new entries and * return codes, but never remove or redefine existing ones. */ /** Status/error codes returned by libsigrok functions. */ enum { SR_OK = 0, /**< No error. */ SR_ERR = -1, /**< Generic/unspecified error. */ SR_ERR_MALLOC = -2, /**< Malloc/calloc/realloc error. */ SR_ERR_ARG = -3, /**< Function argument error. */ SR_ERR_BUG = -4, /**< Errors hinting at internal bugs. */ SR_ERR_SAMPLERATE = -5, /**< Incorrect samplerate. */ SR_ERR_NA = -6, /**< Not applicable. */ SR_ERR_DEV_CLOSED = -7, /**< Device is closed, but needs to be open. */ }; #define SR_MAX_NUM_PROBES 64 /* Limited by uint64_t. */ #define SR_MAX_PROBENAME_LEN 32 /* Handy little macros */ #define SR_HZ(n) (n) #define SR_KHZ(n) ((n) * (uint64_t)(1000ULL)) #define SR_MHZ(n) ((n) * (uint64_t)(1000000ULL)) #define SR_GHZ(n) ((n) * (uint64_t)(1000000000ULL)) #define SR_HZ_TO_NS(n) ((uint64_t)(1000000000ULL) / (n)) /** libsigrok loglevels. */ enum { SR_LOG_NONE = 0, /**< Output no messages at all. */ SR_LOG_ERR = 1, /**< Output error messages. */ SR_LOG_WARN = 2, /**< Output warnings. */ SR_LOG_INFO = 3, /**< Output informational messages. */ SR_LOG_DBG = 4, /**< Output debug messages. */ SR_LOG_SPEW = 5, /**< Output very noisy debug messages. */ }; /* * Use SR_API to mark public API symbols, and SR_PRIV for private symbols. * * Variables and functions marked 'static' are private already and don't * need SR_PRIV. However, functions which are not static (because they need * to be used in other libsigrok-internal files) but are also not meant to * be part of the public libsigrok API, must use SR_PRIV. * * This uses the 'visibility' feature of gcc (requires gcc >= 4.0). * * This feature is not available on MinGW/Windows, as it is a feature of * ELF files and MinGW/Windows uses PE files. * * Details: http://gcc.gnu.org/wiki/Visibility */ /* Marks public libsigrok API symbols. */ #ifndef _WIN32 #define SR_API __attribute__((visibility("default"))) #else #define SR_API #endif /* Marks private, non-public libsigrok symbols (not part of the API). */ #ifndef _WIN32 #define SR_PRIV __attribute__((visibility("hidden"))) #else #define SR_PRIV #endif typedef int (*sr_receive_data_callback_t)(int fd, int revents, void *cb_data); /** Data types used by sr_config_info(). */ enum { SR_T_UINT64 = 10000, SR_T_CHAR, SR_T_BOOL, SR_T_FLOAT, SR_T_RATIONAL_PERIOD, SR_T_RATIONAL_VOLT, SR_T_KEYVALUE, }; /** Rational number data type, containing numerator and denominator values. */ struct sr_rational { /** Numerator of the rational number. */ uint64_t p; /** Denominator of the rational number. */ uint64_t q; }; /** Value for sr_datafeed_packet.type. */ enum { SR_DF_HEADER = 10000, SR_DF_END, SR_DF_META, SR_DF_TRIGGER, SR_DF_LOGIC, SR_DF_ANALOG, SR_DF_FRAME_BEGIN, SR_DF_FRAME_END, }; /** Values for sr_datafeed_analog.mq. */ enum { SR_MQ_VOLTAGE = 10000, SR_MQ_CURRENT, SR_MQ_RESISTANCE, SR_MQ_CAPACITANCE, SR_MQ_TEMPERATURE, SR_MQ_FREQUENCY, SR_MQ_DUTY_CYCLE, SR_MQ_CONTINUITY, SR_MQ_PULSE_WIDTH, SR_MQ_CONDUCTANCE, /** Electrical power, usually in W, or dBm. */ SR_MQ_POWER, /** Gain (a transistor's gain, or hFE, for example). */ SR_MQ_GAIN, /** Logarithmic representation of sound pressure relative to a * reference value. */ SR_MQ_SOUND_PRESSURE_LEVEL, SR_MQ_CARBON_MONOXIDE, SR_MQ_RELATIVE_HUMIDITY, }; /** Values for sr_datafeed_analog.unit. */ enum { SR_UNIT_VOLT = 10000, SR_UNIT_AMPERE, SR_UNIT_OHM, SR_UNIT_FARAD, SR_UNIT_KELVIN, SR_UNIT_CELSIUS, SR_UNIT_FAHRENHEIT, SR_UNIT_HERTZ, SR_UNIT_PERCENTAGE, SR_UNIT_BOOLEAN, SR_UNIT_SECOND, /** Unit of conductance, the inverse of resistance. */ SR_UNIT_SIEMENS, /** * An absolute measurement of power, in decibels, referenced to * 1 milliwatt (dBu). */ SR_UNIT_DECIBEL_MW, /** Voltage in decibel, referenced to 1 volt (dBV). */ SR_UNIT_DECIBEL_VOLT, /** * Measurements that intrinsically do not have units attached, such * as ratios, gains, etc. Specifically, a transistor's gain (hFE) is * a unitless quantity, for example. */ SR_UNIT_UNITLESS, /** Sound pressure level relative so 20 micropascals. */ SR_UNIT_DECIBEL_SPL, /** * Normalized (0 to 1) concentration of a substance or compound with 0 * representing a concentration of 0%, and 1 being 100%. This is * represented as the fraction of number of particles of the substance. */ SR_UNIT_CONCENTRATION, }; /** Values for sr_datafeed_analog.flags. */ enum { /** Voltage measurement is alternating current (AC). */ SR_MQFLAG_AC = 0x01, /** Voltage measurement is direct current (DC). */ SR_MQFLAG_DC = 0x02, /** This is a true RMS measurement. */ SR_MQFLAG_RMS = 0x04, /** Value is voltage drop across a diode, or NAN. */ SR_MQFLAG_DIODE = 0x08, /** Device is in "hold" mode (repeating the last measurement). */ SR_MQFLAG_HOLD = 0x10, /** Device is in "max" mode, only updating upon a new max value. */ SR_MQFLAG_MAX = 0x20, /** Device is in "min" mode, only updating upon a new min value. */ SR_MQFLAG_MIN = 0x40, /** Device is in autoranging mode. */ SR_MQFLAG_AUTORANGE = 0x80, /** Device is in relative mode. */ SR_MQFLAG_RELATIVE = 0x100, /** Sound pressure level is A-weighted in the frequency domain, * according to IEC 61672:2003. */ SR_MQFLAG_SPL_FREQ_WEIGHT_A = 0x200, /** Sound pressure level is C-weighted in the frequency domain, * according to IEC 61672:2003. */ SR_MQFLAG_SPL_FREQ_WEIGHT_C = 0x400, /** Sound pressure level is Z-weighted (i.e. not at all) in the * frequency domain, according to IEC 61672:2003. */ SR_MQFLAG_SPL_FREQ_WEIGHT_Z = 0x800, /** Sound pressure level is not weighted in the frequency domain, * albeit without standards-defined low and high frequency limits. */ SR_MQFLAG_SPL_FREQ_WEIGHT_FLAT = 0x1000, /** Sound pressure level measurement is S-weighted (1s) in the * time domain. */ SR_MQFLAG_SPL_TIME_WEIGHT_S = 0x2000, /** Sound pressure level measurement is F-weighted (125ms) in the * time domain. */ SR_MQFLAG_SPL_TIME_WEIGHT_F = 0x4000, /** Sound pressure level is time-averaged (LAT), also known as * Equivalent Continuous A-weighted Sound Level (LEQ). */ SR_MQFLAG_SPL_LAT = 0x8000, /** Sound pressure level represented as a percentage of measurements * that were over a preset alarm level. */ SR_MQFLAG_SPL_PCT_OVER_ALARM = 0x10000, }; struct sr_context; struct sr_datafeed_packet { uint16_t type; const void *payload; }; struct sr_datafeed_header { int feed_version; struct timeval starttime; }; struct sr_datafeed_meta { GSList *config; }; struct sr_datafeed_logic { uint64_t length; uint16_t unitsize; void *data; }; struct sr_datafeed_analog { /** The probes for which data is included in this packet. */ GSList *probes; int num_samples; /** Measured quantity (voltage, current, temperature, and so on). */ int mq; /** Unit in which the MQ is measured. */ int unit; /** Bitmap with extra information about the MQ. */ uint64_t mqflags; /** The analog value(s). The data is interleaved according to * the probes list. */ float *data; }; /** Input (file) format struct. */ struct sr_input { /** * A pointer to this input format's 'struct sr_input_format'. * The frontend can use this to call the module's callbacks. */ struct sr_input_format *format; GHashTable *param; struct sr_dev_inst *sdi; void *internal; }; struct sr_input_format { /** The unique ID for this input format. Must not be NULL. */ char *id; /** * A short description of the input format, which can (for example) * be displayed to the user by frontends. Must not be NULL. */ char *description; /** * Check if this input module can load and parse the specified file. * * @param filename The name (and path) of the file to check. * * @return TRUE if this module knows the format, FALSE if it doesn't. */ int (*format_match) (const char *filename); /** * Initialize the input module. * * @param in A pointer to a valid 'struct sr_input' that the caller * has to allocate and provide to this function. It is also * the responsibility of the caller to free it later. * @param filename The name (and path) of the file to use. * * @return SR_OK upon success, a negative error code upon failure. */ int (*init) (struct sr_input *in, const char *filename); /** * Load a file, parsing the input according to the file's format. * * This function will send datafeed packets to the session bus, so * the calling frontend must have registered its session callbacks * beforehand. * * The packet types sent across the session bus by this function must * include at least SR_DF_HEADER, SR_DF_END, and an appropriate data * type such as SR_DF_LOGIC. It may also send a SR_DF_TRIGGER packet * if appropriate. * * @param in A pointer to a valid 'struct sr_input' that the caller * has to allocate and provide to this function. It is also * the responsibility of the caller to free it later. * @param filename The name (and path) of the file to use. * * @return SR_OK upon success, a negative error code upon failure. */ int (*loadfile) (struct sr_input *in, const char *filename); }; /** Output (file) format struct. */ struct sr_output { /** * A pointer to this output format's 'struct sr_output_format'. * The frontend can use this to call the module's callbacks. */ struct sr_output_format *format; /** * The device for which this output module is creating output. This * can be used by the module to find out probe names and numbers. */ struct sr_dev_inst *sdi; /** * An optional parameter which the frontend can pass in to the * output module. How the string is interpreted is entirely up to * the module. */ char *param; /** * A generic pointer which can be used by the module to keep internal * state between calls into its callback functions. * * For example, the module might store a pointer to a chunk of output * there, and only flush it when it reaches a certain size. */ void *internal; }; struct sr_output_format { /** * A unique ID for this output format. Must not be NULL. * * It can be used by frontends to select this output format for use. * * For example, calling sigrok-cli with -O hex will * select the hexadecimal text output format. */ char *id; /** * A short description of the output format. Must not be NULL. * * This can be displayed by frontends, e.g. when selecting the output * format for saving a file. */ char *description; int df_type; /** * This function is called once, at the beginning of an output stream. * * The device struct will be available in the output struct passed in, * as well as the param field -- which may be NULL or an empty string, * if no parameter was passed. * * The module can use this to initialize itself, create a struct for * keeping state and storing it in the internal field. * * @param o Pointer to the respective 'struct sr_output'. * * @return SR_OK upon success, a negative error code otherwise. */ int (*init) (struct sr_output *o); /** * Whenever a chunk of data comes in, it will be passed to the * output module via this function. The data_in and * length_in values refers to this data; the module * must not alter or g_free() this buffer. * * The function must allocate a buffer for storing its output, and * pass along a pointer to this buffer in the data_out * parameter, as well as storing the length of the buffer in * length_out. The calling frontend will g_free() * this buffer when it's done with it. * * IMPORTANT: The memory allocation much happen using a glib memory * allocation call (not a "normal" malloc) since g_free() will be * used to free the memory! * * If there is no output, this function MUST store NULL in the * data_out parameter, so the caller knows not to try * and g_free() it. * * Note: This API call is obsolete, use recv() instead. * * @param o Pointer to the respective 'struct sr_output'. * @param data_in Pointer to the input data buffer. * @param length_in Length of the input. * @param data_out Pointer to the allocated output buffer. * @param length_out Length (in bytes) of the output. * * @return SR_OK upon success, a negative error code otherwise. */ int (*data) (struct sr_output *o, const uint8_t *data_in, uint64_t length_in, uint8_t **data_out, uint64_t *length_out); /** * This function is called when an event occurs in the datafeed * which the output module may need to be aware of. No data is * passed in, only the fact that the event occurs. The following * events can currently be passed in: * * - SR_DF_TRIGGER: At this point in the datafeed, the trigger * matched. The output module may mark this in some way, e.g. by * plotting a red line on a graph. * * - SR_DF_END: This marks the end of the datafeed. No more calls * into the output module will be done, so this is a good time to * free up any memory used to keep state, for example. * * Any output generated by this function must have a reference to * it stored in the data_out and length_out * parameters, or NULL if no output was generated. * * Note: This API call is obsolete, use recv() instead. * * @param o Pointer to the respective 'struct sr_output'. * @param event_type Type of event that occured. * @param data_out Pointer to the allocated output buffer. * @param length_out Length (in bytes) of the output. * * @return SR_OK upon success, a negative error code otherwise. */ int (*event) (struct sr_output *o, int event_type, uint8_t **data_out, uint64_t *length_out); GString *(*recv) (struct sr_output *o, const struct sr_dev_inst *sdi, const struct sr_datafeed_packet *packet); int (*cleanup) (struct sr_output *o); }; enum { SR_PROBE_LOGIC = 10000, SR_PROBE_ANALOG, }; struct sr_probe { /* The index field will go: use g_slist_length(sdi->probes) instead. */ int index; int type; gboolean enabled; char *name; char *trigger; }; struct sr_config { int key; GVariant *data; }; struct sr_config_info { int key; int datatype; char *id; char *name; char *description; }; enum { /*--- Device classes ------------------------------------------------*/ /** The device can act as logic analyzer. */ SR_CONF_LOGIC_ANALYZER = 10000, /** The device can act as an oscilloscope. */ SR_CONF_OSCILLOSCOPE, /** The device can act as a multimeter. */ SR_CONF_MULTIMETER, /** The device is a demo device. */ SR_CONF_DEMO_DEV, /** The device can act as a sound level meter. */ SR_CONF_SOUNDLEVELMETER, /** The device can measure temperature. */ SR_CONF_THERMOMETER, /** The device can measure humidity. */ SR_CONF_HYGROMETER, /*--- Driver scan options -------------------------------------------*/ /** * Specification on how to connect to a device. * * In combination with SR_CONF_SERIALCOMM, this is a serial port in * the form which makes sense to the OS (e.g., /dev/ttyS0). * Otherwise this specifies a USB device, either in the form of * @verbatim .
@endverbatim (decimal, e.g. 1.65) or * @verbatim . @endverbatim * (hexadecimal, e.g. 1d6b.0001). */ SR_CONF_CONN = 20000, /** * Serial communication specification, in the form: * * @verbatim / @endverbatim * * Example: 9600/8n1 * * The string may also be followed by one or more special settings, * in the form "/key=value". Supported keys and their values are: * * rts 0,1 set the port's RTS pin to low or high * dtr 0,1 set the port's DTR pin to low or high * flow 0 no flow control * 1 hardware-based (RTS/CTS) flow control * 2 software-based (XON/XOFF) flow control * * This is always an optional parameter, since a driver typically * knows the speed at which the device wants to communicate. */ SR_CONF_SERIALCOMM, /*--- Device configuration ------------------------------------------*/ /** The device supports setting its samplerate, in Hz. */ SR_CONF_SAMPLERATE = 30000, /** The device supports setting a pre/post-trigger capture ratio. */ SR_CONF_CAPTURE_RATIO, /** The device supports setting a pattern (pattern generator mode). */ SR_CONF_PATTERN_MODE, /** The device supports Run Length Encoding. */ SR_CONF_RLE, /** The device supports setting trigger slope. */ SR_CONF_TRIGGER_SLOPE, /** Trigger source. */ SR_CONF_TRIGGER_SOURCE, /** Horizontal trigger position. */ SR_CONF_HORIZ_TRIGGERPOS, /** Buffer size. */ SR_CONF_BUFFERSIZE, /** Time base. */ SR_CONF_TIMEBASE, /** Filter. */ SR_CONF_FILTER, /** Volts/div. */ SR_CONF_VDIV, /** Coupling. */ SR_CONF_COUPLING, /** Trigger types. */ SR_CONF_TRIGGER_TYPE, /** The device supports setting its sample interval, in ms. */ SR_CONF_SAMPLE_INTERVAL, /** Number of timebases, as related to SR_CONF_TIMEBASE. */ SR_CONF_NUM_TIMEBASE, /** Number of vertical divisions, as related to SR_CONF_VDIV. */ SR_CONF_NUM_VDIV, /*--- Special stuff -------------------------------------------------*/ /** Scan options supported by the driver. */ SR_CONF_SCAN_OPTIONS = 40000, /** Device options for a particular device. */ SR_CONF_DEVICE_OPTIONS, /** Session filename. */ SR_CONF_SESSIONFILE, /** The device supports specifying a capturefile to inject. */ SR_CONF_CAPTUREFILE, /** The device supports specifying the capturefile unit size. */ SR_CONF_CAPTURE_UNITSIZE, /** The device supports setting the number of probes. */ SR_CONF_CAPTURE_NUM_PROBES, /*--- Acquisition modes ---------------------------------------------*/ /** * The device supports setting a sample time limit (how long * the sample acquisition should run, in ms). */ SR_CONF_LIMIT_MSEC = 50000, /** * The device supports setting a sample number limit (how many * samples should be acquired). */ SR_CONF_LIMIT_SAMPLES, /** * The device supports setting a frame limit (how many * frames should be acquired). */ SR_CONF_LIMIT_FRAMES, /** * The device supports continuous sampling. Neither a time limit * nor a sample number limit has to be supplied, it will just acquire * samples continuously, until explicitly stopped by a certain command. */ SR_CONF_CONTINUOUS, /** The device has internal storage, into which data is logged. This * starts or stops the internal logging. */ SR_CONF_DATALOG, }; struct sr_dev_inst { struct sr_dev_driver *driver; int index; int status; int inst_type; char *vendor; char *model; char *version; GSList *probes; void *conn; void *priv; }; /** Types of device instances (sr_dev_inst). */ enum { /** Device instance type for USB devices. */ SR_INST_USB = 10000, /** Device instance type for serial port devices. */ SR_INST_SERIAL, }; /** Device instance status. */ enum { /** The device instance was not found. */ SR_ST_NOT_FOUND = 10000, /** The device instance was found, but is still booting. */ SR_ST_INITIALIZING, /** The device instance is live, but not in use. */ SR_ST_INACTIVE, /** The device instance is actively in use in a session. */ SR_ST_ACTIVE, /** The device is winding down its session. */ SR_ST_STOPPING, }; struct sr_dev_driver { /* Driver-specific */ char *name; char *longname; int api_version; int (*init) (struct sr_context *sr_ctx); int (*cleanup) (void); GSList *(*scan) (GSList *options); GSList *(*dev_list) (void); int (*dev_clear) (void); int (*config_get) (int id, GVariant **data, const struct sr_dev_inst *sdi); int (*config_set) (int id, GVariant *data, const struct sr_dev_inst *sdi); int (*config_list) (int info_id, GVariant **data, const struct sr_dev_inst *sdi); /* Device-specific */ int (*dev_open) (struct sr_dev_inst *sdi); int (*dev_close) (struct sr_dev_inst *sdi); int (*dev_acquisition_start) (const struct sr_dev_inst *sdi, void *cb_data); int (*dev_acquisition_stop) (struct sr_dev_inst *sdi, void *cb_data); /* Dynamic */ void *priv; }; struct sr_session { /** List of struct sr_dev pointers. */ GSList *devs; /** List of struct datafeed_callback pointers. */ GSList *datafeed_callbacks; GTimeVal starttime; unsigned int num_sources; /* * Both "sources" and "pollfds" are of the same size and contain pairs * of descriptor and callback function. We can not embed the GPollFD * into the source struct since we want to be able to pass the array * of all poll descriptors to g_poll(). */ struct source *sources; GPollFD *pollfds; int source_timeout; /* * These are our synchronization primitives for stopping the session in * an async fashion. We need to make sure the session is stopped from * within the session thread itself. */ GMutex stop_mutex; gboolean abort_session; }; #include "proto.h" #include "version.h" #ifdef __cplusplus } #endif #endif