diff options
Diffstat (limited to 'irmp/irmp-main-sharedlib.c')
| -rw-r--r-- | irmp/irmp-main-sharedlib.c | 212 |
1 files changed, 138 insertions, 74 deletions
diff --git a/irmp/irmp-main-sharedlib.c b/irmp/irmp-main-sharedlib.c index 824a05a..baa65c9 100644 --- a/irmp/irmp-main-sharedlib.c +++ b/irmp/irmp-main-sharedlib.c @@ -1,5 +1,5 @@ -/*--------------------------------------------------------------------------------------------------------------------------------------------------- - * irmpharedLib.h +/* + * irmp-main-sharedlib.c * * Copyright (c) 2009-2019 Frank Meyer - frank(at)fli4l.de * Copyright (c) 2009-2019 René Staffen - r.staffen(at)gmx.de @@ -8,98 +8,162 @@ * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. - *--------------------------------------------------------------------------------------------------------------------------------------------------- */ +/* + * Declare the library's public API first. Prove it's consistent and + * complete as a standalone header file. + */ +#include "irmp-main-sharedlib.h" +#include <stdlib.h> +#include <string.h> + +/* + * Include the IRMP core logic. This approach is required because of + * static variables which hold internal state. The core logic started + * as an MCU project where resources are severely constrained. + */ #include "irmp.h" #include "irmp.c" +/* + * The remaining source code implements the PC library, which accepts + * sample data from API callers, and provides detector results as they + * become available after seeing input data. + * + * TODO items, known constraints + * - Counters in the IRMP core logic and the library wrapper are 32bit + * only. In the strictest sense they only need to cover the span of + * an IR frame. In the PC side library case they need to cover "a + * detection phase", which happens to be under calling applications' + * control. The library shall not mess with the core's internal state, + * and may even not be able to reliably tell whether detection of a + * frame started in the core. Fortunately the 32bit counters only roll + * over after some 2.5 days at the highest available sample rate. So + * this limitation is not a blocker. + * - The IRMP core keeps internal state in global variables. Which is + * appropriate for MCU configurations. For the PC library use case + * this constraint prevents concurrency, only a single data stream + * can get processed at any time. This limitation can get addressed + * later, making the flexible and featureful IRMP detection available + * in the first place is considered highly desirable, and is a great + * improvement in itself. + * - The detection of IR frames from buffered data is both limited and + * complicated at the same time. The routine re-uses the caller's + * buffer _and_ internal state across multiple calls. Thus windowed + * operation over a larger set of input data is not available. The + * API lacks a flag for failed detection, thus applications need to + * guess from always returned payload data. + * - Is it worth adding a "detection in progress" query to the API? Is + * the information available to the library wrapper, and reliable? + * Shall applications be able to "poll" the started, and completed + * state for streamed operation including periodic state resets which + * won't interfere with pending detection? (It's assumed that this + * is only required when feeding single values in individual calls is + * found to be rather expensive. + * - Some of the result data reflects the core's internal presentation + * while there is no declaration in the library's API. This violates + * API layers, and needs to get addressed properly. + * - The IRMP core logic (strictly speaking the specific details of + * preprocessor symbol arrangements in the current implementation) + * appears to assume either to run on an MCU and capture IR signals + * from hardware pins, falling back to AVR if no other platform got + * detected. Or assumes to run on a (desktop) PC, and automatically + * enables ANALYZE mode, which results in lots of stdio traffic that + * is undesirable for application code which uses the shared library + * for strict detection purposes but no further analysis or research. + * It's a pity that turning off ANALYZE switches to MCU mode, and that + * keeping ANALYZE enabled but silencing the output is rather messy + * and touches the innards of the core logic (the irmp.c source file + * and its dependency header files). + */ -#ifndef IRMP_DLLEXPORT - -#if defined WIN32 && defined _MSC_VER -# define IRMP_DLLEXPORT __declspec(dllexport) -#else -# define IRMP_DLLEXPORT +#ifndef ARRAY_SIZE +# define ARRAY_SIZE(x) (sizeof(x) / sizeof(x[0])) #endif -#endif // !IRMP_DLLEXPORT - -#include "irmp-main-sharedlib.h" - +static uint32_t s_end_sample; -static uint32_t s_endSample = 0; - -uint32_t IRMP_GetSampleRate(void) { - return F_INTERRUPTS; +IRMP_DLLEXPORT uint32_t irmp_get_sample_rate(void) +{ + return F_INTERRUPTS; } - -void IRMP_Reset(void) { - IRMP_PIN = 0xff; - IRMP_DATA data; - int i; - for (i = 0; i < (int)(( F_INTERRUPTS )); i++) // long pause of 1s - { - (void)irmp_ISR(); - } - (void)irmp_get_data(&data); - time_counter = 0; - s_startBitSample = 0; - s_curSample = 0; - s_endSample = 0; +IRMP_DLLEXPORT void irmp_reset_state(void) +{ + size_t i; + IRMP_DATA data; + + /* + * Provide the equivalent of 1s idle input signal level. Then + * drain any potentially accumulated result data. This clears + * the internal decoder state. + */ + IRMP_PIN = 0xff; + i = F_INTERRUPTS; + while (i-- > 0) { + (void)irmp_ISR(); + } + (void)irmp_get_data(&data); + + time_counter = 0; + s_startBitSample = 0; + s_curSample = 0; + s_end_sample = 0; } +IRMP_DLLEXPORT int irmp_add_one_sample(int sample) +{ + int ret; -uint32_t IRMP_AddSample(const uint8_t i_sample) { - IRMP_PIN = i_sample; - uint_fast8_t r = irmp_ISR(); - if (r) { - s_endSample = s_curSample; - return 1; - } - s_curSample++; - return 0; + IRMP_PIN = sample ? 0xff : 0x00; + ret = irmp_ISR() ? 1 : 0; + s_end_sample = s_curSample++; + return ret; } - -uint32_t IRMP_GetData(IRMP_DataExt* o_data) { - - IRMP_DATA d; - if (irmp_get_data(&d)) - { - o_data->address = d.address; - o_data->command = d.command; - o_data->protocol = d.protocol; - o_data->protocolName = IRMP_GetProtocolName(d.protocol); - o_data->flags = d.flags; - o_data->startSample = s_startBitSample; - o_data->endSample = s_endSample; - return TRUE; - } - return FALSE; +IRMP_DLLEXPORT int irmp_get_result_data(struct irmp_result_data *data) +{ + IRMP_DATA d; + + if (!irmp_get_data(&d)) + return 0; + + data->address = d.address; + data->command = d.command; + data->protocol = d.protocol; + data->protocol_name = irmp_get_protocol_name(d.protocol); + data->flags = d.flags; + data->start_sample = s_startBitSample; + data->end_sample = s_end_sample; + return 1; } - -IRMP_DataExt IRMP_Detect(const uint8_t* i_buff, uint32_t i_len) { - IRMP_DataExt ret = { 0 }; - while (s_curSample < i_len) { - if (IRMP_AddSample(i_buff[s_curSample])) { - IRMP_GetData(&ret); - return ret; - } - } - return ret; +#if WITH_IRMP_DETECT_BUFFER +IRMP_DLLEXPORT struct irmp_result_data irmp_detect_buffer(const uint8_t *buff, size_t len) +{ + struct irmp_result_data ret; + + memset(&ret, 0, sizeof(ret)); + while (s_curSample < len) { + if (irmp_add_one_sample(buff[s_curSample])) { + irmp_get_result_data(&ret); + return ret; + } + } + return ret; } +#endif +IRMP_DLLEXPORT const char *irmp_get_protocol_name(uint32_t protocol) +{ + const char *name; -const char* IRMP_GetProtocolName(uint32_t i_protocol) { - if (i_protocol < IRMP_N_PROTOCOLS) { - return irmp_protocol_names[i_protocol]; - } - else { - return "unknown"; - } + if (protocol >= ARRAY_SIZE(irmp_protocol_names)) + return "unknown"; + name = irmp_protocol_names[protocol]; + if (!name || !*name) + return "unknown"; + return name; } - |