Performance tweaking for AGC.
Apparently enabling AGC produces samples with quite different characteristics, and ends up eating a lot more CPU as the previous heuristics would generate a lot of false positives. Tweaking the parameters and a bit of optimization seems to bring this back down to usable levels without losing many potential messages.
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mode_s.c
50
mode_s.c
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@ -1955,20 +1955,36 @@ void detectModeS(uint16_t *m, uint32_t mlen) {
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// nb: the correlation functions sum to zero, so we do not need to adjust for the DC offset in the input signal
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// (adding any constant value to all of m[0..3] does not change the result)
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static inline int slice_phase0(uint16_t *m) {
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return 5 * m[0] - 3 * m[1] - 2 * m[2];
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}
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static inline int slice_phase1(uint16_t *m) {
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return 4 * m[0] - m[1] - 3 * m[2];
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}
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static inline int slice_phase2(uint16_t *m) {
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return 3 * m[0] + m[1] - 4 * m[2];
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}
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static inline int slice_phase3(uint16_t *m) {
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return 2 * m[0] + 3 * m[1] - 5 * m[2];
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}
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static inline int slice_phase4(uint16_t *m) {
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return m[0] + 5 * m[1] - 5 * m[2] - m[3];
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}
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static inline int correlate_phase0(uint16_t *m) {
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return (5 * m[0] - 3 * m[1] - 2 * m[2]) * 30 / 19;
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return slice_phase0(m) * 3;
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}
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static inline int correlate_phase1(uint16_t *m) {
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return (4 * m[0] - 1 * m[1] - 3 * m[2]) * 30 / 13;
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return slice_phase1(m) * 4;
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}
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static inline int correlate_phase2(uint16_t *m) {
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return (3 * m[0] + 1 * m[1] - 4 * m[2]) * 30 / 13;
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return slice_phase2(m) * 4;
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}
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static inline int correlate_phase3(uint16_t *m) {
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return (2 * m[0] + 3 * m[1] - 5 * m[2]) * 30 / 19;
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return slice_phase3(m) * 3;
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}
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static inline int correlate_phase4(uint16_t *m) {
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return (1 * m[0] + 5 * m[1] - 5 * m[2] - 1 * m[3]) * 30 / 26;
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return slice_phase4(m) * 2;
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}
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//
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@ -2025,7 +2041,7 @@ static inline int correlate_check_4(uint16_t *m) {
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static int best_phase(uint16_t *m) {
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int test;
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int best = -1;
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int bestval = 50; // minimum correlation quality we will accept
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int bestval = 10000; // minimum correlation quality we will accept
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// empirical testing suggests that 4..8 is the best range to test for here
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// (testing a wider range runs the danger of picking the wrong phase for
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@ -2139,14 +2155,20 @@ void detectModeS_oversample(uint16_t *m, uint32_t mlen) {
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continue;
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}
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// Check that the "quiet" bits 6,7,15,16,17 are actually quiet
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// Check for enough signal
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if (sigLevel < 2 * noiseLevel)
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continue;
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if (preamble[6] >= high ||
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// Check that the "quiet" bits 6,7,15,16,17 are actually quiet
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if (preamble[5] >= high ||
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preamble[6] >= high ||
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preamble[7] >= high ||
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preamble[8] >= high ||
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preamble[14] >= high ||
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preamble[15] >= high ||
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preamble[16] >= high ||
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preamble[17] >= high) {
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preamble[17] >= high ||
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preamble[18] >= high) {
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++Modes.stat_preamble_not_quiet;
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continue;
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}
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@ -2183,31 +2205,31 @@ void detectModeS_oversample(uint16_t *m, uint32_t mlen) {
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switch (phase) {
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case 0:
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test = correlate_phase0(pPtr);
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test = slice_phase0(pPtr);
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phase = 2;
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pPtr += 2;
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break;
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case 1:
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test = correlate_phase1(pPtr);
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test = slice_phase1(pPtr);
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phase = 3;
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pPtr += 2;
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break;
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case 2:
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test = correlate_phase2(pPtr);
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test = slice_phase2(pPtr);
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phase = 4;
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pPtr += 2;
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break;
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case 3:
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test = correlate_phase3(pPtr);
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test = slice_phase3(pPtr);
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phase = 0;
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pPtr += 3;
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break;
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case 4:
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test = correlate_phase4(pPtr);
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test = slice_phase4(pPtr);
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// A phase-4 bit exactly straddles a sample boundary.
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// Here's what a 1-0 bit with phase 4 looks like:
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