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-rw-r--r--src/statistical.c459
1 files changed, 459 insertions, 0 deletions
diff --git a/src/statistical.c b/src/statistical.c
new file mode 100644
index 000000000..807bc25ea
--- /dev/null
+++ b/src/statistical.c
@@ -0,0 +1,459 @@
+#include "common.h"
+
+// --------------------------------------------------------------------------------------------------------------------
+
+inline long double sum_and_count(long double *series, size_t entries, size_t *count) {
+ if(unlikely(entries == 0)) {
+ if(likely(count))
+ *count = 0;
+
+ return NAN;
+ }
+
+ if(unlikely(entries == 1)) {
+ if(likely(count))
+ *count = (isnan(series[0])?0:1);
+
+ return series[0];
+ }
+
+ size_t i, c = 0;
+ long double sum = 0;
+
+ for(i = 0; i < entries ; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+ c++;
+ sum += value;
+ }
+
+ if(likely(count))
+ *count = c;
+
+ if(unlikely(c == 0))
+ return NAN;
+
+ return sum;
+}
+
+inline long double sum(long double *series, size_t entries) {
+ return sum_and_count(series, entries, NULL);
+}
+
+inline long double average(long double *series, size_t entries) {
+ size_t count = 0;
+ long double sum = sum_and_count(series, entries, &count);
+
+ if(unlikely(count == 0))
+ return NAN;
+
+ return sum / (long double)count;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+long double moving_average(long double *series, size_t entries, size_t period) {
+ if(unlikely(period <= 0))
+ return 0.0;
+
+ size_t i, count;
+ long double sum = 0, avg = 0;
+ long double p[period];
+
+ for(count = 0; count < period ; count++)
+ p[count] = 0.0;
+
+ for(i = 0, count = 0; i < entries; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+
+ if(unlikely(count < period)) {
+ sum += value;
+ avg = (count == period - 1) ? sum / (long double)period : 0;
+ }
+ else {
+ sum = sum - p[count % period] + value;
+ avg = sum / (long double)period;
+ }
+
+ p[count % period] = value;
+ count++;
+ }
+
+ return avg;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+static int qsort_compare(const void *a, const void *b) {
+ long double *p1 = (long double *)a, *p2 = (long double *)b;
+ long double n1 = *p1, n2 = *p2;
+
+ if(unlikely(isnan(n1) || isnan(n2))) {
+ if(isnan(n1) && !isnan(n2)) return -1;
+ if(!isnan(n1) && isnan(n2)) return 1;
+ return 0;
+ }
+ if(unlikely(isinf(n1) || isinf(n2))) {
+ if(!isinf(n1) && isinf(n2)) return -1;
+ if(isinf(n1) && !isinf(n2)) return 1;
+ return 0;
+ }
+
+ if(unlikely(n1 < n2)) return -1;
+ if(unlikely(n1 > n2)) return 1;
+ return 0;
+}
+
+inline void sort_series(long double *series, size_t entries) {
+ qsort(series, entries, sizeof(long double), qsort_compare);
+}
+
+inline long double *copy_series(long double *series, size_t entries) {
+ long double *copy = mallocz(sizeof(long double) * entries);
+ memcpy(copy, series, sizeof(long double) * entries);
+ return copy;
+}
+
+long double median_on_sorted_series(long double *series, size_t entries) {
+ if(unlikely(entries == 0))
+ return NAN;
+
+ if(unlikely(entries == 1))
+ return series[0];
+
+ if(unlikely(entries == 2))
+ return (series[0] + series[1]) / 2;
+
+ long double avg;
+ if(entries % 2 == 0) {
+ size_t m = entries / 2;
+ avg = (series[m] + series[m + 1]) / 2;
+ }
+ else {
+ avg = series[entries / 2];
+ }
+
+ return avg;
+}
+
+long double median(long double *series, size_t entries) {
+ if(unlikely(entries == 0))
+ return NAN;
+
+ if(unlikely(entries == 1))
+ return series[0];
+
+ if(unlikely(entries == 2))
+ return (series[0] + series[1]) / 2;
+
+ long double *copy = copy_series(series, entries);
+ sort_series(copy, entries);
+
+ long double avg = median_on_sorted_series(copy, entries);
+
+ freez(copy);
+ return avg;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+long double moving_median(long double *series, size_t entries, size_t period) {
+ if(entries <= period)
+ return median(series, entries);
+
+ long double *data = copy_series(series, entries);
+
+ size_t i;
+ for(i = period; i < entries; i++) {
+ data[i - period] = median(&series[i - period], period);
+ }
+
+ long double avg = median(data, entries - period);
+ freez(data);
+ return avg;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+// http://stackoverflow.com/a/15150143/4525767
+long double running_median_estimate(long double *series, size_t entries) {
+ long double median = 0.0f;
+ long double average = 0.0f;
+ size_t i;
+
+ for(i = 0; i < entries ; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+
+ average += ( value - average ) * 0.1f; // rough running average.
+ median += copysignl( average * 0.01, value - median );
+ }
+
+ return median;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+long double standard_deviation(long double *series, size_t entries) {
+ if(unlikely(entries < 1))
+ return NAN;
+
+ if(unlikely(entries == 1))
+ return series[0];
+
+ size_t i, count = 0;
+ long double sum = 0;
+
+ for(i = 0; i < entries ; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+
+ count++;
+ sum += value;
+ }
+
+ if(unlikely(count == 0))
+ return NAN;
+
+ if(unlikely(count == 1))
+ return sum;
+
+ long double average = sum / (long double)count;
+
+ for(i = 0, count = 0, sum = 0; i < entries ; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+
+ count++;
+ sum += powl(value - average, 2);
+ }
+
+ if(unlikely(count == 0))
+ return NAN;
+
+ if(unlikely(count == 1))
+ return average;
+
+ long double variance = sum / (long double)(count - 1); // remove -1 to have a population stddev
+
+ long double stddev = sqrtl(variance);
+ return stddev;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+long double single_exponential_smoothing(long double *series, size_t entries, long double alpha) {
+ size_t i, count = 0;
+ long double level = 0, sum = 0;
+
+ if(unlikely(isnan(alpha)))
+ alpha = 0.3;
+
+ for(i = 0; i < entries ; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+ count++;
+
+ sum += value;
+
+ long double last_level = level;
+ level = alpha * value + (1.0 - alpha) * last_level;
+ }
+
+ return level;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+// http://grisha.org/blog/2016/02/16/triple-exponential-smoothing-forecasting-part-ii/
+long double double_exponential_smoothing(long double *series, size_t entries, long double alpha, long double beta, long double *forecast) {
+ size_t i, count = 0;
+ long double level = series[0], trend, sum;
+
+ if(unlikely(isnan(alpha)))
+ alpha = 0.3;
+
+ if(unlikely(isnan(beta)))
+ beta = 0.05;
+
+ if(likely(entries > 1))
+ trend = series[1] - series[0];
+ else
+ trend = 0;
+
+ sum = series[0];
+
+ for(i = 1; i < entries ; i++) {
+ long double value = series[i];
+ if(unlikely(isnan(value) || isinf(value))) continue;
+ count++;
+
+ sum += value;
+
+ long double last_level = level;
+
+ level = alpha * value + (1.0 - alpha) * (level + trend);
+ trend = beta * (level - last_level) + (1.0 - beta) * trend;
+ }
+
+ if(forecast)
+ *forecast = level + trend;
+
+ return level;
+}
+
+// --------------------------------------------------------------------------------------------------------------------
+
+/*
+ * Based on th R implementation
+ *
+ * a: level component
+ * b: trend component
+ * s: seasonal component
+ *
+ * Additive:
+ *
+ * Yhat[t+h] = a[t] + h * b[t] + s[t + 1 + (h - 1) mod p],
+ * a[t] = α (Y[t] - s[t-p]) + (1-α) (a[t-1] + b[t-1])
+ * b[t] = β (a[t] - a[t-1]) + (1-β) b[t-1]
+ * s[t] = γ (Y[t] - a[t]) + (1-γ) s[t-p]
+ *
+ * Multiplicative:
+ *
+ * Yhat[t+h] = (a[t] + h * b[t]) * s[t + 1 + (h - 1) mod p],
+ * a[t] = α (Y[t] / s[t-p]) + (1-α) (a[t-1] + b[t-1])
+ * b[t] = β (a[t] - a[t-1]) + (1-β) b[t-1]
+ * s[t] = γ (Y[t] / a[t]) + (1-γ) s[t-p]
+ */
+static int __HoltWinters(
+ long double *series,
+ int entries, // start_time + h
+
+ long double alpha, // alpha parameter of Holt-Winters Filter.
+ long double beta, // beta parameter of Holt-Winters Filter. If set to 0, the function will do exponential smoothing.
+ long double gamma, // gamma parameter used for the seasonal component. If set to 0, an non-seasonal model is fitted.
+
+ int *seasonal,
+ int *period,
+ long double *a, // Start value for level (a[0]).
+ long double *b, // Start value for trend (b[0]).
+ long double *s, // Vector of start values for the seasonal component (s_1[0] ... s_p[0])
+
+ /* return values */
+ long double *SSE, // The final sum of squared errors achieved in optimizing
+ long double *level, // Estimated values for the level component (size entries - t + 2)
+ long double *trend, // Estimated values for the trend component (size entries - t + 2)
+ long double *season // Estimated values for the seasonal component (size entries - t + 2)
+)
+{
+ if(unlikely(entries < 4))
+ return 0;
+
+ int start_time = 2;
+
+ long double res = 0, xhat = 0, stmp = 0;
+ int i, i0, s0;
+
+ /* copy start values to the beginning of the vectors */
+ level[0] = *a;
+ if(beta > 0) trend[0] = *b;
+ if(gamma > 0) memcpy(season, s, *period * sizeof(long double));
+
+ for(i = start_time - 1; i < entries; i++) {
+ /* indices for period i */
+ i0 = i - start_time + 2;
+ s0 = i0 + *period - 1;
+
+ /* forecast *for* period i */
+ xhat = level[i0 - 1] + (beta > 0 ? trend[i0 - 1] : 0);
+ stmp = gamma > 0 ? season[s0 - *period] : (*seasonal != 1);
+ if (*seasonal == 1)
+ xhat += stmp;
+ else
+ xhat *= stmp;
+
+ /* Sum of Squared Errors */
+ res = series[i] - xhat;
+ *SSE += res * res;
+
+ /* estimate of level *in* period i */
+ if (*seasonal == 1)
+ level[i0] = alpha * (series[i] - stmp)
+ + (1 - alpha) * (level[i0 - 1] + trend[i0 - 1]);
+ else
+ level[i0] = alpha * (series[i] / stmp)
+ + (1 - alpha) * (level[i0 - 1] + trend[i0 - 1]);
+
+ /* estimate of trend *in* period i */
+ if (beta > 0)
+ trend[i0] = beta * (level[i0] - level[i0 - 1])
+ + (1 - beta) * trend[i0 - 1];
+
+ /* estimate of seasonal component *in* period i */
+ if (gamma > 0) {
+ if (*seasonal == 1)
+ season[s0] = gamma * (series[i] - level[i0])
+ + (1 - gamma) * stmp;
+ else
+ season[s0] = gamma * (series[i] / level[i0])
+ + (1 - gamma) * stmp;
+ }
+ }
+
+ return 1;
+}
+
+long double holtwinters(long double *series, size_t entries, long double alpha, long double beta, long double gamma, long double *forecast) {
+ if(unlikely(isnan(alpha)))
+ alpha = 0.3;
+
+ if(unlikely(isnan(beta)))
+ beta = 0.05;
+
+ if(unlikely(isnan(gamma)))
+ gamma = 0;
+
+ int seasonal = 0;
+ int period = 0;
+ long double a0 = series[0];
+ long double b0 = 0;
+ long double s[] = {};
+
+ long double errors = 0.0;
+ size_t nb_computations = entries;
+ long double *estimated_level = callocz(nb_computations, sizeof(long double));
+ long double *estimated_trend = callocz(nb_computations, sizeof(long double));
+ long double *estimated_season = callocz(nb_computations, sizeof(long double));
+
+ int ret = __HoltWinters(
+ series,
+ (int)entries,
+ alpha,
+ beta,
+ gamma,
+ &seasonal,
+ &period,
+ &a0,
+ &b0,
+ s,
+ &errors,
+ estimated_level,
+ estimated_trend,
+ estimated_season
+ );
+
+ long double value = estimated_level[nb_computations - 1];
+
+ if(forecast)
+ *forecast = 0.0;
+
+ freez(estimated_level);
+ freez(estimated_trend);
+ freez(estimated_season);
+
+ if(!ret)
+ return 0.0;
+
+ return value;
+}
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