Tasmota/lib/IRremoteESP8266-2.5.2.03/src/ir_Aiwa.cpp

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// Copyright 2017 David Conran
#include "IRrecv.h"
#include "IRsend.h"
// AAA IIIII W W AAA
// A A I W W A A
// AAAAA I W W W AAAAA
// A A I W W W A A
// A A IIIII WWW A A
// Based off the RC-T501 RCU
// Added by David Conran. (Inspired by IRremoteESP8266's implementation:
// https://github.com/z3t0/Arduino-IRremote)
const uint16_t kAiwaRcT501PreBits = 26;
const uint16_t kAiwaRcT501PostBits = 1;
// NOTE: These are the compliment (inverted) of lirc values as
// lirc uses a '0' for a mark, and a '1' for a space.
const uint64_t kAiwaRcT501PreData = 0x1D8113FULL; // 26-bits
const uint64_t kAiwaRcT501PostData = 1ULL;
#if SEND_AIWA_RC_T501
// Send an Aiwa RC T501 formatted message.
//
// Args:
// data: The message to be sent.
// nbits: The number of bits of the message to be sent.
// Typically kAiwaRcT501Bits. Max is 37 = (64 - 27)
// repeat: The number of times the command is to be repeated.
//
// Status: BETA / Should work.
//
// Ref:
// http://lirc.sourceforge.net/remotes/aiwa/RC-T501
void IRsend::sendAiwaRCT501(uint64_t data, uint16_t nbits, uint16_t repeat) {
// Appears to be an extended NEC1 protocol. i.e. 42 bits instead of 32 bits.
// So use sendNEC instead, however the twist is it has a fixed 26 bit
// prefix, and a fixed postfix bit.
uint64_t new_data = ((kAiwaRcT501PreData << (nbits + kAiwaRcT501PostBits)) |
(data << kAiwaRcT501PostBits) | kAiwaRcT501PostData);
nbits += kAiwaRcT501PreBits + kAiwaRcT501PostBits;
if (nbits > sizeof(new_data) * 8)
return; // We are overflowing. Abort, and don't send.
sendNEC(new_data, nbits, repeat);
}
#endif
#if DECODE_AIWA_RC_T501
// Decode the supplied Aiwa RC T501 message.
//
// Args:
// results: Ptr to the data to decode and where to store the decode result.
// nbits: The number of data bits to expect. Typically kAiwaRcT501Bits.
// strict: Flag indicating if we should perform strict matching.
// Returns:
// boolean: True if it can decode it, false if it can't.
//
// Status: BETA / Should work.
//
// Notes:
// Aiwa RC T501 appears to be a 42 bit variant of the NEC1 protocol.
// However, we historically (original Arduino IRremote project) treats it as
// a 15 bit (data) protocol. So, we expect nbits to typically be 15, and we
// will remove the prefix and postfix from the raw data, and use that as
// the result.
//
// Ref:
// http://www.sbprojects.com/knowledge/ir/nec.php
bool IRrecv::decodeAiwaRCT501(decode_results *results, uint16_t nbits,
bool strict) {
// Compliance
if (strict && nbits != kAiwaRcT501Bits)
return false; // Doesn't match our protocol defn.
// Add on the pre & post bits to our requested bit length.
uint16_t expected_nbits = nbits + kAiwaRcT501PreBits + kAiwaRcT501PostBits;
uint64_t new_data;
if (expected_nbits > sizeof(new_data) * 8)
return false; // We can't possibly match something that big.
// Decode it as a much bigger (non-standard) NEC message, so we have to turn
// off strict mode checking for NEC.
if (!decodeNEC(results, expected_nbits, false))
return false; // The NEC decode had a problem, so we should too.
uint16_t actual_bits = results->bits;
new_data = results->value;
if (actual_bits < expected_nbits)
return false; // The data we caught was undersized. Throw it back.
if ((new_data & 0x1ULL) != kAiwaRcT501PostData)
return false; // The post data doesn't match, so it can't be this protocol.
// Trim off the post data bit.
new_data >>= kAiwaRcT501PostBits;
actual_bits -= kAiwaRcT501PostBits;
// Extract out our likely new value and put it back in the results.
actual_bits -= kAiwaRcT501PreBits;
results->value = new_data & ((1ULL << actual_bits) - 1);
// Check the prefix data matches.
new_data >>= actual_bits; // Trim off the new data to expose the prefix.
if (new_data != kAiwaRcT501PreData) // Check the prefix.
return false;
// Compliance
if (strict && results->bits != expected_nbits) return false;
// Success
results->decode_type = AIWA_RC_T501;
results->bits = actual_bits;
results->address = 0;
results->command = 0;
return true;
}
#endif