980 lines
33 KiB
C
980 lines
33 KiB
C
#include "mp1.h"
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#include "hardware.h"
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#include "config.h"
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#include <stdlib.h> // Used for random
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#include <string.h>
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#include <drv/ser.h>
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#include <drv/timer.h> // Timer driver from BertOS
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#include "compression/heatshrink_encoder.h"
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#include "compression/heatshrink_decoder.h"
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// We need an indicator to tell us whether we
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// should send a parity byte. This happens
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// whenever two normal bytes of data has been
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// sent. We also keep the last sent byte in
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// memory because we need it to calculate the
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// parity byte.
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static bool sendParityBlock = false;
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static uint8_t lastByte = 0x00;
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// We also need a buffer for compressing and
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// decompressing packet data.
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static uint8_t compressionBuffer[MP1_MAX_FRAME_LENGTH+10];
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// An int to hold amount of free RAM updated
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// by the FREE_RAM function;
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static int FREE_RAM;
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// The GET_BIT macro is used in the interleaver
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// and deinterleaver to access single bits of a
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// byte.
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INLINE bool GET_BIT(uint8_t byte, int n) { return (byte & (1 << (8-n))) == (1 << (8-n)); }
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// This function calculates and returns a parity
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// byte for two input bytes. The parity byte is
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// used for correcting errors in the transmission.
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// The error correction algorithm is a standard
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// (12,8) Hamming code.
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INLINE bool BIT(uint8_t byte, int n) { return ((byte & BV(n-1))>>(n-1)); }
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static uint8_t mp1ParityBlock(uint8_t first, uint8_t other) {
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uint8_t parity = 0x00;
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parity = ((BIT(first, 1) ^ BIT(first, 2) ^ BIT(first, 4) ^ BIT(first, 5) ^ BIT(first, 7))) +
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((BIT(first, 1) ^ BIT(first, 3) ^ BIT(first, 4) ^ BIT(first, 6) ^ BIT(first, 7))<<1) +
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((BIT(first, 2) ^ BIT(first, 3) ^ BIT(first, 4) ^ BIT(first, 8))<<2) +
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((BIT(first, 5) ^ BIT(first, 6) ^ BIT(first, 7) ^ BIT(first, 8))<<3) +
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((BIT(other, 1) ^ BIT(other, 2) ^ BIT(other, 4) ^ BIT(other, 5) ^ BIT(other, 7))<<4) +
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((BIT(other, 1) ^ BIT(other, 3) ^ BIT(other, 4) ^ BIT(other, 6) ^ BIT(other, 7))<<5) +
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((BIT(other, 2) ^ BIT(other, 3) ^ BIT(other, 4) ^ BIT(other, 8))<<6) +
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((BIT(other, 5) ^ BIT(other, 6) ^ BIT(other, 7) ^ BIT(other, 8))<<7);
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return parity;
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}
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// This decode function retrieves the buffer of
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// received, deinterleaved and error-corrected
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// bytes, inspects the header and determines
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// whether there is padding to be removed, and
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// whether the packet is compressed. If it is
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// it is decompressed before being passed to
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// the registered callback.
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static void mp1Decode(MP1 *mp1) {
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MP1Packet packet; // A decoded packet struct
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uint8_t *buffer = mp1->buffer; // Get the buffer from the protocol context
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// Get the header and "remove" it from the buffer
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uint8_t header = buffer[0];
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buffer++;
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// If header indicates a padded packet, remove
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// padding
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uint8_t padding = header >> 4;
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if (header & MP1_HEADER_PADDED) {
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for (int i = 0; i < padding; i++) {
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buffer++;
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}
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}
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if (SERIAL_DEBUG) kprintf("[TS=%d] ", mp1->packetLength);
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// Set the payload length of the packet to the counted
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// length minus 1, so we remove the checksum
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packet.dataLength = mp1->packetLength - 2 - (header & MP1_HEADER_PADDED)*padding;
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// Check if we have received a compressed packet
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if (header & MP1_HEADER_COMPRESSION) {
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// If we have, we decompress it and use the
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// decompressed data for the packet
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if (SERIAL_DEBUG) kprintf("[CS=%d] ", packet.dataLength);
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size_t decompressedSize = decompress(buffer, packet.dataLength);
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if (SERIAL_DEBUG) kprintf("[DS=%d]", decompressedSize);
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packet.dataLength = decompressedSize;
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memcpy(mp1->buffer, compressionBuffer, decompressedSize);
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} else {
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// If the packet was not compressed, we shift
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// the data in our buffer back down to the actual
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// beginning of the buffer array, since we incremented
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// the pointer address for removing the header and
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// padding.
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for (unsigned long i = 0; i < packet.dataLength; i++) {
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mp1->buffer[i] = buffer[i];
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}
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}
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// Set the data field of the packet to our buffer
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packet.data = mp1->buffer;
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// If a callback have been specified, let's
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// call it and pass the decoded packet
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if (mp1->callback) mp1->callback(&packet);
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}
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////////////////////////////////////////////////////////////
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// The Poll function reads data from the modem, handles //
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// frame recognition and passes data on to higher layers //
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// if valid packets are found //
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////////////////////////////////////////////////////////////
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void mp1Poll(MP1 *mp1) {
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int byte; // A place to store our read byte
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sendParityBlock = false; // Reset our parity tx indicator
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// Read bytes from the modem until we reach EOF
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while ((byte = kfile_getc(mp1->modem)) != EOF) {
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// We read something from the modem, so we
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// set the settleTimer
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mp1->settleTimer = timer_clock();
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/////////////////////////////////////////////
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// This following block handles forward //
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// error correction using an interleaved //
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// (12,8) Hamming code //
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/////////////////////////////////////////////
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// If we have started reading (received an
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// HDLC_FLAG), we will start looking at the
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// incoming data and perform forward error
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// correction on it.
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if ((mp1->reading && (byte != AX25_ESC )) || (mp1->reading && (mp1->escape && (byte == AX25_ESC || byte == HDLC_FLAG || byte == HDLC_RESET)))) {
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// We have a byte, increment our read counter
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mp1->readLength++;
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// Check if we have read three bytes. If we
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// have, we should now have a block of two
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// data bytes and a parity byte. This block
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if (mp1->readLength % MP1_INTERLEAVE_SIZE == 0) {
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// If the last character in the block
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// looks like a control character, we
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// need to set the escape indicator to
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// false, since the next byte will be
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// read immediately after the FEC
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// routine, and thus, the normal reading
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// code will not reset the indicator.
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if (byte == AX25_ESC || byte == HDLC_FLAG || byte == HDLC_RESET) mp1->escape = false;
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// The block is interleaved, so we will
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// first put the received bytes in the
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// deinterleaving buffer
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for (int i = 1; i < MP1_INTERLEAVE_SIZE; i++) {
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mp1->interleaveIn[i-1] = mp1->buffer[mp1->packetLength-(MP1_INTERLEAVE_SIZE-i)];
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}
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mp1->interleaveIn[MP1_INTERLEAVE_SIZE-1] = byte;
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// We then deinterleave the block
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mp1Deinterleave(mp1);
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// Adjust the packet length, since we will get
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// parity bytes in the data buffer with block
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// sizes larger than 3
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mp1->packetLength -= MP1_INTERLEAVE_SIZE/3 - 1;
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// For each 3-byte block in the deinterleaved
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// bytes, we apply forward error correction
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for (int i = 0; i < MP1_INTERLEAVE_SIZE; i+=3) {
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// We now calculate a parity byte on the
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// received data.
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// Deinterleaved data bytes
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uint8_t a = mp1->interleaveIn[i];
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uint8_t b = mp1->interleaveIn[i+1];
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// Deinterleaved parity byte
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uint8_t p = mp1->interleaveIn[i+2];
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mp1->calculatedParity = mp1ParityBlock(a, b);
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// By XORing the calculated parity byte
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// with the received parity byte, we get
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// what is called the "syndrome". This
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// number will tell us if we had any
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// errors during transmission, and if so
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// where they are. Using Hamming code, we
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// can only detect single bit errors in a
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// byte though, which is why we interleave
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// the data, since most errors will usually
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// occur in bursts of more than one bit.
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// With 2 data byte interleaving we can
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// correct 2 consecutive bit errors.
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uint8_t syndrome = mp1->calculatedParity ^ p;
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if (syndrome == 0x00) {
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// If the syndrome equals 0, we either
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// don't have any errors, or the error
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// is unrecoverable, so we don't do
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// anything
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} else {
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// If the syndrome is not equal to 0,
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// there is a problem, and we will try
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// to correct it. We first need to split
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// the syndrome byte up into the two
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// actual syndrome numbers, one for
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// each data byte.
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uint8_t syndromes[2];
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syndromes[0] = syndrome & 0x0f;
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syndromes[1] = (syndrome & 0xf0) >> 4;
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// Then we look at each syndrome number
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// to determine what bit in the data
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// bytes to correct.
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for (int i = 0; i < 2; i++) {
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uint8_t s = syndromes[i];
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uint8_t correction = 0x00;
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if (s == 1 || s == 2 || s == 4 || s == 8) {
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// This signifies an error in the
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// parity block, so we actually
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// don't need any correction
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continue;
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}
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// The following determines what
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// bit to correct according to
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// the syndrome value.
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if (s == 3) correction = 0x01;
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if (s == 5) correction = 0x02;
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if (s == 6) correction = 0x04;
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if (s == 7) correction = 0x08;
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if (s == 9) correction = 0x10;
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if (s == 10) correction = 0x20;
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if (s == 11) correction = 0x40;
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if (s == 12) correction = 0x80;
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// And finally we apply the correction
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if (i == 1) a ^= correction;
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if (i == 0) b ^= correction;
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// This is just for testing purposes.
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// Nice to know when corrections were
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// actually made.
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if (s != 0) mp1->correctionsMade += 1;
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}
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}
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// We now update the checksum of the packet
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// with the deinterleaved and possibly
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// corrected bytes.
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mp1->checksum_in ^= a;
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mp1->checksum_in ^= b;
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mp1->buffer[mp1->packetLength-(MP1_DATA_BLOCK_SIZE)+((i/3)*2)] = a;
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mp1->buffer[mp1->packetLength-(MP1_DATA_BLOCK_SIZE-1)+((i/3)*2)] = b;
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}
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continue;
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}
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}
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/////////////////////////////////////////////
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// End of forward error correction block //
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/////////////////////////////////////////////
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// This next part of the poll function handles
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// the reading from the modem, and looks for
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// starts and ends of transmissions. It also
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// handles escape characters by discarding them
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// so they don't get put into the output data.
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// Let's first check if we have read an HDLC_FLAG.
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if (!mp1->escape && byte == HDLC_FLAG) {
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// We are not in an escape sequence and we
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// found a HDLC_FLAG. This can mean two things:
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if (mp1->readLength >= MP1_MIN_FRAME_LENGTH) {
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// We already have more data than the minimum
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// frame length, which means the flag signifies
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// the end of the packet. Pass control to the
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// decoder.
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//
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// We also set the settle timer to indicate
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// the time the frame completed reading.
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mp1->settleTimer = timer_clock();
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if ((mp1->checksum_in & 0xff) == 0x00) {
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if (SERIAL_DEBUG) kprintf("[CHK-OK] [C=%d] ", mp1->correctionsMade);
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mp1Decode(mp1);
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} else {
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// Checksum was incorrect, we don't do anything,
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// but you can enable the decode anyway, if you
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// need it for testing or debugging
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if (PASSALL) {
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if (SERIAL_DEBUG) kprintf("[CHK-ER] [C=%d] ", mp1->correctionsMade);
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mp1Decode(mp1);
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}
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}
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}
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// If the above is not the case, this must be the
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// beginning of a frame
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mp1->reading = true;
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mp1->packetLength = 0;
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mp1->readLength = 0;
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mp1->checksum_in = MP1_CHECKSUM_INIT;
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mp1->correctionsMade = 0;
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// We have indicated that we are reading,
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// and reset the length counter. Now we'll
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// continue to the next byte.
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continue;
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}
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if (!mp1->escape && byte == HDLC_RESET) {
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// Not good, we got a reset. The transmitting
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// party may have encountered an error. We'll
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// stop receiving this packet immediately.
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mp1->reading = false;
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continue;
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}
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if (!mp1->escape && byte == AX25_ESC) {
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// We found an escape character. We'll set
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// the escape seqeunce indicator so we don't
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// interpret the next byte as a reset or flag
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mp1->escape = true;
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// We then continue reading the next byte.
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continue;
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}
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// Now let's get to the actual reading of the data
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if (mp1->reading) {
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if (mp1->packetLength < MP1_MAX_FRAME_LENGTH) {
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// If the length of the current incoming frame is
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// still less than our max length, put the incoming
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// byte in the buffer. When we have collected 3
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// bytes, they will be processed by the error
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// correction part above.
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mp1->buffer[mp1->packetLength++] = byte;
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} else {
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// If not, we have a problem: The buffer has overrun
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// We need to stop receiving, and the packet will be
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// dropped :(
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mp1->reading = false;
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}
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}
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// We need to set the escape sequence indicator back
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// to false after each byte.
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mp1->escape = false;
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}
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if (kfile_error(mp1->modem)) {
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// If there was an error from the modem, we'll be rude
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// and just reset it. No error handling is done for now.
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kfile_clearerr(mp1->modem);
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}
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}
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// This is called to actually send the bytes
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// after they have been interleaved
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static void mp1WriteByte(MP1 *mp1, uint8_t byte) {
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// If we are sending something that looks
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// like an HDLC special byte, send an escape
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// character first
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if (byte == HDLC_FLAG ||
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byte == HDLC_RESET ||
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byte == AX25_ESC) {
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kfile_putc(AX25_ESC, mp1->modem);
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}
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kfile_putc(byte, mp1->modem);
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}
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// This is an intermediary function that
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// receives outgoing bytes, and adds
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// interleaving and a parity byte to the
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// outgoing data in blocks of two data
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// bytes. The actual transmitted block will
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// be 3 bytes long due to the added parity
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// byte.
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static void mp1Putbyte(MP1 *mp1, uint8_t byte) {
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mp1Interleave(mp1, byte);
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if (sendParityBlock) {
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uint8_t p = mp1ParityBlock(lastByte, byte);
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mp1Interleave(mp1, p);
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}
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lastByte = byte;
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sendParityBlock ^= true;
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}
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// This function accepts a buffer with data
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// to be transmitted, and structures it into
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// a valid packet.
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void mp1Send(MP1 *mp1, void *_buffer, size_t length) {
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// Open transmitter and wait for MP1_TXDELAY msecs
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AFSK_HW_PTT_ON();
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ticks_t start = timer_clock();
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while (timer_clock() - start < ms_to_ticks(MP1_TXDELAY)) {
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cpu_relax();
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}
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// Get the transmit data buffer
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uint8_t *buffer = (uint8_t *)_buffer;
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// Initialize checksum to zero
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mp1->checksum_out = MP1_CHECKSUM_INIT;
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// We also reset the interleave counter to zero
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mp1->interleaveCounter = 0;
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// We start out assuming we should not use
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// compression.
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bool packetCompression = false;
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// We then try to compress the data to see
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// if we can save some space with compression.
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size_t compressedSize = compress(buffer, length);
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if (compressedSize != 0 && compressedSize < length) {
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// Compression saved us some space, we'll
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// send the paket compressed
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packetCompression = true;
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// Write the compressed data into the
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// outgoing data buffer
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memcpy(buffer, compressionBuffer, compressedSize);
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// Make sure to set the length of the
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// data to the new (compressed) length
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length = compressedSize;
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} else {
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// We are not going to use compression,
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// so we don't do anything.
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}
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// Transmit the HDLC_FLAG to signify start of TX
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kfile_putc(HDLC_FLAG, mp1->modem);
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// We now need to construct a header, that
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// can tell the receiving end whether the
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// packet is compressed. Since a packet must
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// have an even number of total payload bytes
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// (including the header), we check the length
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// of the outgoing data, and if it is not even,
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// we add a single byte of padding to the
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// packet. Remember that we also send a single
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// byte checksum at the end of the packet, so
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// the header and checksum bytes together don't
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// change whether the payload length is even
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// or not. The payload length needs to be even
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// since we are sending a parity byte for every
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// two data bytes sent, and because interleaving
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// happens in blocks of three bytes.
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uint8_t header = 0x00;
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// If we are using compression, set the
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// appropriate header flag to true.
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if (packetCompression) header ^= MP1_HEADER_COMPRESSION;
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// We check if the data length matches our
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// required block size
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uint8_t padding = (length+2) % MP1_DATA_BLOCK_SIZE;
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if (padding != 0) {
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// If it does not, we set the appropriate
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// header flag to indicate that we are
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// padding this packet.
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header ^= MP1_HEADER_PADDED;
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// And calculate how much padding we need
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padding = MP1_DATA_BLOCK_SIZE - padding;
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// And put the amount of padding we are
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// going to append in the header
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header ^= (padding << 4);
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// We then update the checksum with the
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// header byte and queue it for transmit
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mp1->checksum_out = mp1->checksum_out ^ header;
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mp1Putbyte(mp1, header);
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// We now update the checksum with the
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// padding bytes, and queue these for
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// transmission as well.
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for (int i = 0; i < padding; i++) {
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mp1->checksum_out = mp1->checksum_out ^ MP1_PADDING;
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mp1Putbyte(mp1, MP1_PADDING);
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}
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} else {
|
|
// If the length already matches, we
|
|
// just update the checksum with the
|
|
// header byte and queue it.
|
|
mp1->checksum_out = mp1->checksum_out ^ header;
|
|
mp1Putbyte(mp1, header);
|
|
}
|
|
|
|
// Now we'll transmit the actual data of
|
|
// the packet. We continously increment the
|
|
// pointer address of the buffer while
|
|
// passing it to the intermediary output
|
|
// function. Everytime the interleaving
|
|
// counter reaches 3, a block will be
|
|
// transmitted.
|
|
while (length--) {
|
|
mp1->checksum_out = mp1->checksum_out ^ *buffer;
|
|
mp1Putbyte(mp1, *buffer++);
|
|
}
|
|
|
|
// Finally we write the checksum to the
|
|
// end of the packet.
|
|
mp1Putbyte(mp1, mp1->checksum_out);
|
|
|
|
// And transmit a HDLC_FLAG to signify
|
|
// end of the transmission.
|
|
kfile_putc(HDLC_FLAG, mp1->modem);
|
|
|
|
// Turn off manual PTT
|
|
AFSK_HW_PTT_OFF();
|
|
}
|
|
|
|
// This function will simply initialize
|
|
// the protocol context and allocate the
|
|
// needed memory.
|
|
void mp1Init(MP1 *mp1, KFile *modem, mp1_callback_t callback) {
|
|
// Allocate memory for our protocol "object"
|
|
memset(mp1, 0, sizeof(*mp1));
|
|
// Set references to our modem "object" and
|
|
// a callback for when a packet has been decoded
|
|
mp1->modem = modem;
|
|
mp1->callback = callback;
|
|
mp1->settleTimer = timer_clock();
|
|
mp1->randomSeed = 0;
|
|
}
|
|
|
|
// A simple form of P-persistent CSMA.
|
|
// Everytime we have heard activity
|
|
// on the channel, we wait at least
|
|
// MP1_SETTLE_TIME milliseconds after the
|
|
// activity has ceased. We then pick a random
|
|
// number, and if it is less than
|
|
// MP1_P_PERSISTENCE, we transmit.
|
|
bool mp1CarrierSense(MP1 *mp1) {
|
|
if (MP1_ENABLE_CSMA) {
|
|
if (mp1->randomSeed == 0) {
|
|
mp1->randomSeed = timer_clock();
|
|
srand(mp1->randomSeed);
|
|
}
|
|
|
|
if (timer_clock() - mp1->settleTimer > ms_to_ticks(MP1_SETTLE_TIME)) {
|
|
uint8_t r = rand() % 255;
|
|
if (r < MP1_P_PERSISTENCE) {
|
|
return false;
|
|
} else {
|
|
mp1->settleTimer = timer_clock();
|
|
return true;
|
|
}
|
|
} else {
|
|
return true;
|
|
}
|
|
} else {
|
|
return false;
|
|
}
|
|
}
|
|
|
|
// A handy debug function that can determine
|
|
// how much available memory we have left.
|
|
int freeRam(void) {
|
|
extern int __heap_start, *__brkval;
|
|
int v;
|
|
FREE_RAM = (int) &v - (__brkval == 0 ? (int) &__heap_start : (int) __brkval);
|
|
return FREE_RAM;
|
|
}
|
|
|
|
// This function compresses data using
|
|
// the Heatshrink library
|
|
size_t compress(uint8_t *input, size_t length) {
|
|
heatshrink_encoder *hse = heatshrink_encoder_alloc(8, 4);
|
|
if (hse == NULL) {
|
|
if (SERIAL_DEBUG) kprintf("Could not allocate compressor\n");
|
|
return 0;
|
|
}
|
|
|
|
size_t written = 0;
|
|
size_t sunk = 0;
|
|
heatshrink_encoder_sink(hse, input, length, &sunk);
|
|
int status = heatshrink_encoder_finish(hse);
|
|
|
|
if (sunk < length) {
|
|
heatshrink_encoder_free(hse);
|
|
return 0;
|
|
} else {
|
|
if (status == HSER_FINISH_MORE) {
|
|
heatshrink_encoder_poll(hse, compressionBuffer, MP1_MAX_FRAME_LENGTH, &written);
|
|
}
|
|
}
|
|
|
|
heatshrink_encoder_free(hse);
|
|
return written;
|
|
}
|
|
|
|
// This function decompresses data using
|
|
// the Heatshrink library
|
|
size_t decompress(uint8_t *input, size_t length) {
|
|
heatshrink_decoder *hsd = heatshrink_decoder_alloc(MP1_MAX_FRAME_LENGTH, 8, 4);
|
|
if (hsd == NULL) {
|
|
if (SERIAL_DEBUG) kprintf("Could not allocate decompressor\n");
|
|
return 0;
|
|
}
|
|
|
|
size_t written = 0;
|
|
size_t sunk = 0;
|
|
heatshrink_decoder_sink(hsd, input, length, &sunk);
|
|
int status = heatshrink_decoder_finish(hsd);
|
|
|
|
if (sunk < length) {
|
|
heatshrink_decoder_free(hsd);
|
|
return 0;
|
|
} else {
|
|
if (status == HSER_FINISH_MORE) {
|
|
heatshrink_decoder_poll(hsd, compressionBuffer, MP1_MAX_FRAME_LENGTH, &written);
|
|
}
|
|
}
|
|
|
|
heatshrink_decoder_free(hsd);
|
|
return written;
|
|
}
|
|
|
|
|
|
// Following is the functions responsible
|
|
// for interleaving and deinterleaving
|
|
// blocks of data. The interleaving table
|
|
// for 3-byte interleaving is also included.
|
|
// The table for 12-byte is much simpler,
|
|
// and should be inferable from looking
|
|
// at the function.
|
|
|
|
///////////////////////////////
|
|
// Interleave-table (3-byte) //
|
|
///////////////////////////////
|
|
//
|
|
// Non-interleaved:
|
|
// aaaaaaaa bbbbbbbb cccccccc
|
|
// 12345678 12345678 12345678
|
|
// M L
|
|
// S S
|
|
// B B
|
|
//
|
|
// Interleaved:
|
|
// abcabcab cabcabca bcabcabc
|
|
// 11144477 22255578 63336688
|
|
//
|
|
///////////////////////////////
|
|
|
|
void mp1Interleave(MP1 *mp1, uint8_t byte) {
|
|
mp1->interleaveOut[mp1->interleaveCounter] = byte;
|
|
mp1->interleaveCounter++;
|
|
if (mp1->interleaveCounter == MP1_INTERLEAVE_SIZE) {
|
|
// We have the bytes we need for interleaving
|
|
// in the buffer and are ready to interleave them.
|
|
#if MP1_INTERLEAVE_SIZE == 3
|
|
// This is for 3-byte interleaving
|
|
uint8_t a = (GET_BIT(mp1->interleaveOut[0], 1) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 1) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[2], 1) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[0], 4) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[1], 4) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[2], 4) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[0], 7) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[1], 7));
|
|
mp1WriteByte(mp1, a);
|
|
|
|
uint8_t b = (GET_BIT(mp1->interleaveOut[2], 2) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[0], 2) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[1], 2) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[2], 5) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[0], 5) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[1], 5) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[2], 7) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[0], 8));
|
|
mp1WriteByte(mp1, b);
|
|
|
|
uint8_t c = (GET_BIT(mp1->interleaveOut[1], 6) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[2], 3) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[0], 3) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[1], 3) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[2], 6) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[0], 6) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[1], 8) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[2], 8));
|
|
|
|
mp1WriteByte(mp1, c);
|
|
#elif MP1_INTERLEAVE_SIZE == 12
|
|
// This is for 12-byte interleaving
|
|
uint8_t a = (GET_BIT(mp1->interleaveOut[0], 1) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 1) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 1) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 1) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 1) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 1) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 1) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],1));
|
|
mp1WriteByte(mp1, a);
|
|
|
|
uint8_t b = (GET_BIT(mp1->interleaveOut[0], 2) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 2) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 2) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 2) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 2) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 2) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 2) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],2));
|
|
mp1WriteByte(mp1, b);
|
|
|
|
uint8_t c = (GET_BIT(mp1->interleaveOut[0], 3) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 3) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 3) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 3) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 3) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 3) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 3) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],3));
|
|
mp1WriteByte(mp1, c);
|
|
|
|
uint8_t d = (GET_BIT(mp1->interleaveOut[0], 4) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 4) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 4) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 4) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 4) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 4) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 4) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],4));
|
|
mp1WriteByte(mp1, d);
|
|
|
|
uint8_t e = (GET_BIT(mp1->interleaveOut[0], 5) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 5) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 5) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 5) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 5) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 5) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 5) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],5));
|
|
mp1WriteByte(mp1, e);
|
|
|
|
uint8_t f = (GET_BIT(mp1->interleaveOut[0], 6) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 6) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 6) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 6) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 6) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 6) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 6) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],6));
|
|
mp1WriteByte(mp1, f);
|
|
|
|
uint8_t g = (GET_BIT(mp1->interleaveOut[0], 7) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 7) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 7) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 7) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 7) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 7) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 7) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],7));
|
|
mp1WriteByte(mp1, g);
|
|
|
|
uint8_t h = (GET_BIT(mp1->interleaveOut[0], 8) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[1], 8) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[3], 8) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[4], 8) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[6], 8) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[7], 8) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[9], 8) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[10],8));
|
|
mp1WriteByte(mp1, h);
|
|
|
|
uint8_t p = (GET_BIT(mp1->interleaveOut[2], 1) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[2], 5) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[5], 1) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[5], 5) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[8], 1) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[8], 5) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[11],1) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[11],5));
|
|
mp1WriteByte(mp1, p);
|
|
|
|
uint8_t q = (GET_BIT(mp1->interleaveOut[2], 2) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[2], 6) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[5], 2) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[5], 6) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[8], 2) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[8], 6) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[11],2) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[11],6));
|
|
mp1WriteByte(mp1, q);
|
|
|
|
uint8_t s = (GET_BIT(mp1->interleaveOut[2], 3) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[2], 7) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[5], 3) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[5], 7) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[8], 3) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[8], 7) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[11],3) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[11],7));
|
|
mp1WriteByte(mp1, s);
|
|
|
|
uint8_t t = (GET_BIT(mp1->interleaveOut[2], 4) << 7) +
|
|
(GET_BIT(mp1->interleaveOut[2], 8) << 6) +
|
|
(GET_BIT(mp1->interleaveOut[5], 4) << 5) +
|
|
(GET_BIT(mp1->interleaveOut[5], 8) << 4) +
|
|
(GET_BIT(mp1->interleaveOut[8], 4) << 3) +
|
|
(GET_BIT(mp1->interleaveOut[8], 8) << 2) +
|
|
(GET_BIT(mp1->interleaveOut[11],4) << 1) +
|
|
(GET_BIT(mp1->interleaveOut[11],8));
|
|
mp1WriteByte(mp1, t);
|
|
|
|
#endif
|
|
|
|
mp1->interleaveCounter = 0;
|
|
}
|
|
}
|
|
|
|
|
|
void mp1Deinterleave(MP1 *mp1) {
|
|
#if MP1_INTERLEAVE_SIZE == 3
|
|
uint8_t a = (GET_BIT(mp1->interleaveIn[0], 1) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 2) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 3) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[0], 4) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[1], 5) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[2], 6) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[0], 7) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[1], 8));
|
|
|
|
uint8_t b = (GET_BIT(mp1->interleaveIn[0], 2) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 3) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 4) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[0], 5) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[1], 6) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[2], 1) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[0], 8) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[2], 7));
|
|
|
|
uint8_t c = (GET_BIT(mp1->interleaveIn[0], 3) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 1) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 2) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[0], 6) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[1], 4) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[2], 5) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[1], 7) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[2], 8));
|
|
|
|
mp1->interleaveIn[0] = a;
|
|
mp1->interleaveIn[1] = b;
|
|
mp1->interleaveIn[2] = c;
|
|
#elif MP1_INTERLEAVE_SIZE == 12
|
|
uint8_t a = (GET_BIT(mp1->interleaveIn[0], 1) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 1) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 1) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 1) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 1) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 1) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 1) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 1));
|
|
|
|
uint8_t b = (GET_BIT(mp1->interleaveIn[0], 2) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 2) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 2) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 2) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 2) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 2) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 2) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 2));
|
|
|
|
uint8_t p = (GET_BIT(mp1->interleaveIn[8], 1) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[9], 1) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[10],1) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[11],1) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[8], 2) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[9], 2) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[10],2) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[11],2));
|
|
|
|
uint8_t c = (GET_BIT(mp1->interleaveIn[0], 3) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 3) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 3) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 3) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 3) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 3) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 3) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 3));
|
|
|
|
uint8_t d = (GET_BIT(mp1->interleaveIn[0], 4) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 4) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 4) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 4) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 4) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 4) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 4) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 4));
|
|
|
|
uint8_t q = (GET_BIT(mp1->interleaveIn[8], 3) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[9], 3) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[10],3) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[11],3) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[8], 4) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[9], 4) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[10],4) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[11],4));
|
|
|
|
uint8_t e = (GET_BIT(mp1->interleaveIn[0], 5) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 5) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 5) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 5) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 5) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 5) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 5) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 5));
|
|
|
|
uint8_t f = (GET_BIT(mp1->interleaveIn[0], 6) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 6) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 6) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 6) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 6) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 6) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 6) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 6));
|
|
|
|
uint8_t s = (GET_BIT(mp1->interleaveIn[8], 5) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[9], 5) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[10],5) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[11],5) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[8], 6) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[9], 6) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[10],6) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[11],6));
|
|
|
|
uint8_t g = (GET_BIT(mp1->interleaveIn[0], 7) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 7) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 7) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 7) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 7) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 7) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 7) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 7));
|
|
|
|
uint8_t h = (GET_BIT(mp1->interleaveIn[0], 8) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[1], 8) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[2], 8) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[3], 8) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[4], 8) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[5], 8) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[6], 8) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[7], 8));
|
|
|
|
uint8_t t = (GET_BIT(mp1->interleaveIn[8], 7) << 7) +
|
|
(GET_BIT(mp1->interleaveIn[9], 7) << 6) +
|
|
(GET_BIT(mp1->interleaveIn[10],7) << 5) +
|
|
(GET_BIT(mp1->interleaveIn[11],7) << 4) +
|
|
(GET_BIT(mp1->interleaveIn[8], 8) << 3) +
|
|
(GET_BIT(mp1->interleaveIn[9], 8) << 2) +
|
|
(GET_BIT(mp1->interleaveIn[10],8) << 1) +
|
|
(GET_BIT(mp1->interleaveIn[11],8));
|
|
|
|
mp1->interleaveIn[0] = a;
|
|
mp1->interleaveIn[1] = b;
|
|
mp1->interleaveIn[2] = p;
|
|
mp1->interleaveIn[3] = c;
|
|
mp1->interleaveIn[4] = d;
|
|
mp1->interleaveIn[5] = q;
|
|
mp1->interleaveIn[6] = e;
|
|
mp1->interleaveIn[7] = f;
|
|
mp1->interleaveIn[8] = s;
|
|
mp1->interleaveIn[9] = g;
|
|
mp1->interleaveIn[10] = h;
|
|
mp1->interleaveIn[11] = t;
|
|
|
|
#endif
|
|
} |