Revert "Merge branch 'master' into quickselect"

This reverts commit c77fa34410, reversing changes made to ffd6e5dcbb.
2023-11-29 23:17:41 +00:00 · 2023-11-29 23:17:41 +00:00 · 4d218468cf
commit 4d218468cf
parent c77fa34410
40 changed files with 274 additions and 294 deletions
--- a/examples/core/00_example_template/example
+++ b/examples/core/00_example_template/example
--- a/examples/core/01_one_sample/example
+++ b/examples/core/01_one_sample/example
--- a/examples/core/02_time_to_botec/example
+++ b/examples/core/02_time_to_botec/example
--- a/examples/core/02_time_to_botec/example.c
+++ b/examples/core/02_time_to_botec/example.c
@ -12,10 +12,10 @@ int main()
    double p_b = 0.5;
    double p_c = p_a * p_b;
-    double sample_0(uint64_t * seed) { return 0; }
+    double sample_0(uint64_t* seed){ return 0; }
-    double sample_1(uint64_t * seed) { return 1; }
+    double sample_1(uint64_t* seed) { return 1; } 
-    double sample_few(uint64_t * seed) { return sample_to(1, 3, seed); }
+    double sample_few(uint64_t* seed) { return sample_to(1, 3, seed); } 
-    double sample_many(uint64_t * seed) { return sample_to(2, 10, seed); }
+    double sample_many(uint64_t* seed) { return sample_to(2, 10, seed); } 
    int n_dists = 4;
    double weights[] = { 1 - p_c, p_c / 2, p_c / 4, p_c / 4 };
--- a/examples/core/03_gcc_nested_function/example
+++ b/examples/core/03_gcc_nested_function/example
--- a/examples/core/04_gamma_beta/example
+++ b/examples/core/04_gamma_beta/example
--- a/examples/core/05_hundred_lognormals/example
+++ b/examples/core/05_hundred_lognormals/example
--- a/examples/more/00_example_template/example
+++ b/examples/more/00_example_template/example
--- a/examples/more/01_sample_from_cdf/example
+++ b/examples/more/01_sample_from_cdf/example
--- a/examples/more/02_sample_from_cdf_beta/example
+++ b/examples/more/02_sample_from_cdf_beta/example
--- a/examples/more/03_ci_beta/example
+++ b/examples/more/03_ci_beta/example
--- a/examples/more/03_ci_beta/example.c
+++ b/examples/more/03_ci_beta/example.c
@ -15,9 +15,8 @@ int main()
    uint64_t* seed = malloc(sizeof(uint64_t));
    *seed = 1000; // xorshift can't start with 0
-    ci beta_1_2_ci_90 = sampler_get_90_ci(beta_1_2_sampler, 1000000, seed);
+    ci beta_1_2_ci_90 = get_90_confidence_interval(beta_1_2_sampler, seed);
    printf("90%% confidence interval of beta(1,2) is [%f, %f]\n", beta_1_2_ci_90.low, beta_1_2_ci_90.high);
    printf("You can check this in <https://nunosempere.com/blog/2023/03/15/fit-beta/>\n");
    free(seed);
 }
--- a/examples/more/04_nuclear_war/example
+++ b/examples/more/04_nuclear_war/example
--- a/examples/more/04_nuclear_war/example.c
+++ b/examples/more/04_nuclear_war/example.c
@ -60,7 +60,7 @@ int main()
    }
    printf("... ]\n");
-    ci ci_90 = sampler_get_90_ci(mixture, 1000000, seed);
+    ci ci_90 = get_90_confidence_interval(mixture, seed);
    printf("mean: %f\n", array_mean(mixture_result, n));
    printf("90%% confidence interval: [%f, %f]\n", ci_90.low, ci_90.high);
--- a/examples/more/04_nuclear_war/scratchpad/example
+++ b/examples/more/04_nuclear_war/scratchpad/example
--- a/examples/more/05_burn_10kg_fat/example
+++ b/examples/more/05_burn_10kg_fat/example
--- a/examples/more/05_burn_10kg_fat/example.c
+++ b/examples/more/05_burn_10kg_fat/example.c
@ -41,7 +41,7 @@ int main()
    }
    printf("... ]\n");
-    ci ci_90 = sampler_get_90_ci(sample_minutes_per_day_jumping_rope_needed_to_burn_10kg, 1000000, seed);
+    ci ci_90 = get_90_confidence_interval(sample_minutes_per_day_jumping_rope_needed_to_burn_10kg, seed);
    printf("90%% confidence interval: [%f, %f]\n", ci_90.low, ci_90.high);
    free(seed);
--- a/examples/more/06_nuclear_recovery/example
+++ b/examples/more/06_nuclear_recovery/example
--- a/examples/more/06_nuclear_recovery/example.c
+++ b/examples/more/06_nuclear_recovery/example.c
@ -50,7 +50,7 @@ int main()
    // Before a first nuclear collapse
    printf("## Before the first nuclear collapse\n");
-    ci ci_90_2023 = sampler_get_90_ci(yearly_probability_nuclear_collapse_2023, 1000000, seed);
+    ci ci_90_2023 = get_90_confidence_interval(yearly_probability_nuclear_collapse_2023, seed);
    printf("90%% confidence interval: [%f, %f]\n", ci_90_2023.low, ci_90_2023.high);
    double* yearly_probability_nuclear_collapse_2023_samples = malloc(sizeof(double) * num_samples);
@ -61,7 +61,7 @@ int main()
    // After the first nuclear collapse
    printf("\n## After the first nuclear collapse\n");
-    ci ci_90_2070 = sampler_get_90_ci(yearly_probability_nuclear_collapse_after_recovery_example, 1000000, seed);
+    ci ci_90_2070 = get_90_confidence_interval(yearly_probability_nuclear_collapse_after_recovery_example, seed);
    printf("90%% confidence interval: [%f, %f]\n", ci_90_2070.low, ci_90_2070.high);
    double* yearly_probability_nuclear_collapse_after_recovery_samples = malloc(sizeof(double) * num_samples);
@ -72,7 +72,7 @@ int main()
    // After the first nuclear collapse (antiinductive)
    printf("\n## After the first nuclear collapse (antiinductive)\n");
-    ci ci_90_antiinductive = sampler_get_90_ci(yearly_probability_nuclear_collapse_after_recovery_antiinductive, 1000000, seed);
+    ci ci_90_antiinductive = get_90_confidence_interval(yearly_probability_nuclear_collapse_after_recovery_antiinductive, seed);
    printf("90%% confidence interval: [%f, %f]\n", ci_90_antiinductive.low, ci_90_antiinductive.high);
    double* yearly_probability_nuclear_collapse_after_recovery_antiinductive_samples = malloc(sizeof(double) * num_samples);
--- a/examples/more/07_algebra/example
+++ b/examples/more/07_algebra/example
--- a/examples/more/08_algebra_and_conversion/example
+++ b/examples/more/08_algebra_and_conversion/example
--- a/examples/more/09_ergonomic_algebra/example
+++ b/examples/more/09_ergonomic_algebra/example
--- a/examples/more/10_twitter_thread_example/example
+++ b/examples/more/10_twitter_thread_example/example
--- a/examples/more/11_billion_lognormals_paralell/example
+++ b/examples/more/11_billion_lognormals_paralell/example
--- a/examples/more/11_billion_lognormals_paralell/example.c
+++ b/examples/more/11_billion_lognormals_paralell/example.c
@ -9,22 +9,21 @@ int main()
    // set randomness seed
    // uint64_t* seed = malloc(sizeof(uint64_t));
    // *seed = 1000; // xorshift can't start with 0
-    // ^ not necessary, because sampler_parallel takes care of the seed.
+    // ^ not necessary, because parallel_sampler takes care of the seed.
    int n_samples = 1000 * 1000 * 1000;
    int n_threads = 16;
-    double sampler(uint64_t * seed)
+    double sampler(uint64_t* seed){
    {
        return sample_lognormal(0, 10, seed);
    }
    double* results = malloc(n_samples * sizeof(double));
-    sampler_parallel(sampler, results, n_threads, n_samples);
+    parallel_sampler(sampler, results, n_threads, n_samples);
-    double avg = array_sum(results, n_samples) / n_samples;
+    double avg = array_sum(results, n_samples)/n_samples;
    printf("Average of 1B lognormal(0,10): %f", avg);
    free(results);
    // free(seed);
-    // ^ not necessary, because sampler_parallel takes care of the seed.
+    // ^ not necessary, because parallel_sampler takes care of the seed.
 }
--- a/examples/more/12_time_to_botec_parallel/example
+++ b/examples/more/12_time_to_botec_parallel/example
--- a/examples/more/12_time_to_botec_parallel/example.c
+++ b/examples/more/12_time_to_botec_parallel/example.c
@ -9,22 +9,21 @@ int main()
    double p_b = 0.5;
    double p_c = p_a * p_b;
-    double sample_0(uint64_t * seed) { return 0; }
+    double sample_0(uint64_t* seed){ return 0; }
-    double sample_1(uint64_t * seed) { return 1; }
+    double sample_1(uint64_t* seed) { return 1; } 
-    double sample_few(uint64_t * seed) { return sample_to(1, 3, seed); }
+    double sample_few(uint64_t* seed) { return sample_to(1, 3, seed); } 
-    double sample_many(uint64_t * seed) { return sample_to(2, 10, seed); }
+    double sample_many(uint64_t* seed) { return sample_to(2, 10, seed); } 
    int n_dists = 4;
    double weights[] = { 1 - p_c, p_c / 2, p_c / 4, p_c / 4 };
    double (*samplers[])(uint64_t*) = { sample_0, sample_1, sample_few, sample_many };
-    double sampler_result(uint64_t * seed)
+    double sampler_result(uint64_t* seed) { 
    {
        return sample_mixture(samplers, weights, n_dists, seed);
-    }
+    } 
    int n_samples = 1000 * 1000, n_threads = 16;
    double* results = malloc(n_samples * sizeof(double));
-    sampler_parallel(sampler_result, results, n_threads, n_samples);
+    parallel_sampler(sampler_result, results, n_threads, n_samples);
-    printf("Avg: %f\n", array_sum(results, n_samples) / n_samples);
+    printf("Avg: %f\n", array_sum(results, n_samples)/n_samples);
    free(results);
 }
--- a/examples/more/13_parallelize_min/example
+++ b/examples/more/13_parallelize_min/example
--- a/examples/more/13_parallelize_min/example.c
+++ b/examples/more/13_parallelize_min/example.c
@ -13,58 +13,57 @@ int main()
    /* Option 1: parallelize taking from n samples */
    // Question being asked: what is the distribution of sampling 1000 times and taking the min?
-    double sample_min_of_n(uint64_t * seed, int n)
+    double sample_min_of_n(uint64_t* seed, int n){
    {
        double min = sample_normal(5, 2, seed);
-        for (int i = 0; i < (n - 2); i++) {
+        for(int i=0; i<(n-1); i++){
            double sample = sample_normal(5, 2, seed);
-            if (sample < min) {
+            if(sample < min){
                min = sample;
            }
        }
        return min;
    }
-    double sample_min_of_1000(uint64_t * seed)
+    double sampler_min_of_1000(uint64_t* seed) { 
    {
        return sample_min_of_n(seed, 1000);
-    }
+    } 
-    int n_samples = 1000000, n_threads = 16;
+    int n_samples = 10000, n_threads = 16;
    double* results = malloc(n_samples * sizeof(double));
-    sampler_parallel(sample_min_of_1000, results, n_threads, n_samples);
+    parallel_sampler(sampler_min_of_1000, results, n_threads, n_samples);
    printf("Mean of the distribution of (taking the min of 1000 samples of a normal(5,2)): %f\n", array_mean(results, n_samples));
    free(results);
    /* Option 2: take the min from n samples cleverly using parallelism */
    // Question being asked: can we take the min of n samples cleverly?
-    double sample_n_parallel(int n)
+    double sample_n_parallel(int n){
    {
        int n_threads = 16;
        int quotient = n / 16;
        int remainder = n % 16;
-        uint64_t seed = 1000;
+        uint64_t seed = 100;
        double result_remainder = sample_min_of_n(&seed, remainder);
-
+        
-        double sample_min_of_quotient(uint64_t * seed)
+        double sample_min_of_quotient(uint64_t* seed) { 
-        {
+            double result = sample_min_of_n(seed, quotient);
-            return sample_min_of_n(seed, quotient);
+            // printf("Result: %f\n", result);
            return result;
        }
-        double* results_quotient = malloc(quotient * sizeof(double));
+        double* results = malloc(n_threads * sizeof(double));
-        sampler_parallel(sample_min_of_quotient, results_quotient, n_threads, quotient);
+        parallel_sampler(sample_min_of_quotient, results, n_threads, n_threads);
-        double min = results_quotient[0];
+        double min = results[0];
-        for (int i = 1; i < quotient; i++) {
+        for(int i=1; i<n_threads; i++){
-            if (min > results_quotient[i]) {
+            if(min > results[i]){
-                min = results_quotient[i];
+                min = results[i];
            }
        }
-        if (min > result_remainder) {
+        if(min > result_remainder){
            min = result_remainder;
        }
-        free(results_quotient);
+        free(results);
        return min;
    }
-    printf("Minimum of 1M samples of normal(5,2): %f\n", sample_n_parallel(1000000));
+    printf("Minimum of 10M samples of normal(5,2): %f\n", sample_n_parallel(1000 * 1000));
 }
--- a/examples/more/14_check_confidence_interval/example
+++ b/examples/more/14_check_confidence_interval/example
--- a/examples/more/14_check_confidence_interval/example.c
+++ b/examples/more/14_check_confidence_interval/example.c
@ -1,21 +0,0 @@
 #include "../../../squiggle.h"
 #include "../../../squiggle_more.h"
 #include <stdio.h>
 #include <stdlib.h>
 int main()
 {
    // set randomness seed
    uint64_t* seed = malloc(sizeof(uint64_t));
    *seed = 1000; // xorshift can't start with a seed of 0
    int n = 1000000;
    double* xs = malloc(sizeof(double) * n);
    for (int i = 0; i < n; i++) {
        xs[i] = sample_to(10, 100, seed);
    }
    ci ci_90 = array_get_90_ci(xs, n);
    printf("Recovering confidence interval of sample_to(10, 100):\n  low: %f, high: %f\n", ci_90.low, ci_90.high);
    free(seed);
 }
--- a/examples/more/makefile
+++ b/examples/more/makefile
@ -48,8 +48,7 @@ all:
 	$(CC) $(OPTIMIZED) $(DEBUG) 10_twitter_thread_example/$(SRC)       $(DEPS) -o 10_twitter_thread_example/$(OUTPUT)
 	$(CC) $(OPTIMIZED) $(DEBUG) 11_billion_lognormals_paralell/$(SRC)  $(DEPS) -o 11_billion_lognormals_paralell/$(OUTPUT)
 	$(CC) $(OPTIMIZED) $(DEBUG) 12_time_to_botec_parallel/$(SRC)       $(DEPS) -o 12_time_to_botec_parallel/$(OUTPUT)
-	$(CC) $(OPTIMIZED) $(DEBUG) 13_parallelize_min/$(SRC)              $(DEPS) -o 13_parallelize_min/$(OUTPUT)
+	$(CC) $(OPTIMIZED) $(DEBUG) 13_parallelize_min/$(SRC)       $(DEPS) -o 13_parallelize_min/$(OUTPUT)
 	$(CC) $(OPTIMIZED) $(DEBUG) 14_check_confidence_interval/$(SRC)    $(DEPS) -o 14_check_confidence_interval/$(OUTPUT)
 format-all:
 	$(FORMATTER) 00_example_template/$(SRC)
@ -66,7 +65,6 @@ format-all:
 	$(FORMATTER) 11_billion_lognormals_paralell/$(SRC)
 	$(FORMATTER) 12_time_to_botec_parallel/$(SRC)
 	$(FORMATTER) 13_parallelize_min/$(SRC)
 	$(FORMATTER) 14_check_confidence_interval/$(SRC)
 run-all:
 	00_example_template/$(OUTPUT)
@ -83,7 +81,6 @@ run-all:
 	11_billion_lognormals_paralell/$(OUTPUT)
 	12_time_to_botec_parallel/$(OUTPUT)
 	13_parallelize_min/$(OUTPUT)
 	14_check_confidence_interval/$(OUTPUT)
 ## make one DIR=06_nuclear_recovery
 one: $(DIR)/$(SRC)
--- a/4
+++ b/4
@ -13,8 +13,8 @@ format-examples:
 	cd examples/more && make format-all
 format: squiggle.c squiggle.h
-	$(FORMATTER) squiggle.c squiggle.h
+	$(FORMATTER) squiggle.c
-	$(FORMATTER) squiggle_more.c squiggle_more.h
+	$(FORMATTER) squiggle.h
 lint:
 	clang-tidy squiggle.c -- -lm
--- a/scratchpad/core.c
+++ b/scratchpad/core.c
@ -0,0 +1,27 @@
 uint64_t xorshift64(uint64_t* seed)
 {
    // Algorithm "xor" from p. 4 of Marsaglia, "Xorshift RNGs"
    // <https://en.wikipedia.org/wiki/Xorshift>
    uint64_t x = *seed;
    x ^= x << 13;
    x ^= x >> 7;
    x ^= x << 17;
    return *seed = x;
 }
 double sample_unit_uniform(uint64_t* seed)
 {
    // samples uniform from [0,1] interval.
    return ((double)xorshift64(seed)) / ((double)UINT64_MAX);
 }
 double sample_unit_normal(uint64_t* seed)
 {
    // // See: <https://en.wikipedia.org/wiki/Box%E2%80%93Muller_transform>
    double u1 = sample_unit_uniform(seed);
    double u2 = sample_unit_uniform(seed);
    double z = sqrtf(-2.0 * log(u1)) * sin(2 * PI * u2);
    return z;
 }
--- a/scratchpad/plotting/src/example
+++ b/scratchpad/plotting/src/example
--- a/scratchpad/scratchpad
+++ b/scratchpad/scratchpad
--- a/scratchpad/scratchpad.c
+++ b/scratchpad/scratchpad.c
@ -10,14 +10,25 @@ int main()
    // set randomness seed
    uint64_t* seed = malloc(sizeof(uint64_t));
    *seed = 1000; // xorshift can't start with a seed of 0
    /*
    for (int i = 0; i < 100; i++) {
        double draw = sample_unit_uniform(seed);
        printf("%f\n", draw);
    }*/
    // Test division
    // printf("\n%d\n", 10 % 3);
    //
-    int n = 1000000;
+    int n_samples = 100, n_threads = 16;
-    double* xs = malloc(sizeof(double) * n);
+    double* results = malloc(n_samples * sizeof(double));
-    for (int i = 0; i < n; i++) {
+    double sampler_scratchpad(uint64_t* seed){
-        xs[i] = sample_to(10, 100, seed);
+        return 1;
    }
    parallel_sampler(sampler_scratchpad, results, n_threads, n_samples);
    for(int i=0; i<n_samples; i++){
        printf("Sample %d: %f\n", i, results[i]);
    }
    ci ci_90 = array_get_90_ci(xs, n);
    printf("Recovering confidence interval of sample_to(10, 100):\n  low: %f, high: %f\n", ci_90.low, ci_90.high);
    free(seed);
 }
--- a/squiggle.c
+++ b/squiggle.c
@ -8,7 +8,7 @@
 #define NORMAL90CONFIDENCE 1.6448536269514727
 // Pseudo Random number generator
-static uint64_t xorshift32(uint32_t* seed)
+uint64_t xorshift32(uint32_t* seed)
 {
    // Algorithm "xor" from p. 4 of Marsaglia, "Xorshift RNGs"
    // See:
@ -24,7 +24,7 @@ static uint64_t xorshift32(uint32_t* seed)
    return *seed = x;
 }
-static uint64_t xorshift64(uint64_t* seed)
+uint64_t xorshift64(uint64_t* seed)
 {
    // same as above, but for generating doubles instead of floats
    uint64_t x = *seed;
--- a/squiggle_more.c
+++ b/squiggle_more.c
@ -1,195 +1,67 @@
 #include "squiggle.h"
 #include <float.h>
 #include <limits.h>
 #include <math.h>
 #include <limits.h>
 #include <omp.h>
 #include <stdint.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include "squiggle.h"
-/* Parallel sampler */
+/* Math constants */
-void sampler_parallel(double (*sampler)(uint64_t* seed), double* results, int n_threads, int n_samples)
+#define PI 3.14159265358979323846 // M_PI in gcc gnu99
-{
+#define NORMAL90CONFIDENCE 1.6448536269514727
    if ((n_samples % n_threads) != 0) {
        fprintf(stderr, "Number of samples isn't divisible by number of threads, aborting\n");
        exit(1);
    }
    uint64_t** seeds = malloc(n_threads * sizeof(uint64_t*));
    for (uint64_t i = 0; i < n_threads; i++) {
        seeds[i] = malloc(sizeof(uint64_t));
        *seeds[i] = i + 1; // xorshift can't start with 0
    }
-    int i;
+/* Some error niceties */
-#pragma omp parallel private(i)
+// These won't be used until later 
-    {
+#define MAX_ERROR_LENGTH 500
-#pragma omp for
+#define EXIT_ON_ERROR 0
-        for (i = 0; i < n_threads; i++) {
+#define PROCESS_ERROR(error_msg) process_error(error_msg, EXIT_ON_ERROR, __FILE__, __LINE__)
            int lower_bound = i * (n_samples / n_threads);
            int upper_bound = ((i + 1) * (n_samples / n_threads)) - 1;
            // printf("Lower bound: %d, upper bound: %d\n", lower_bound, upper_bound);
            for (int j = lower_bound; j < upper_bound; j++) {
                results[j] = sampler(seeds[i]);
            }
        }
    }
    for (uint64_t i = 0; i < n_threads; i++) {
        free(seeds[i]);
    }
    free(seeds);
 }
 /* Get confidence intervals, given a sampler */
 // Not in core yet because I'm not sure how much I like the struct
 // and the built-in 100k samples
 // to do: add n to function parameters and document
 typedef struct ci_t {
-    double low;
+    float low;
-    double high;
+    float high;
 } ci;
-
+int compare_doubles(const void* p, const void* q)
 static void swp(int i, int j, double xs[])
 {
-    double tmp = xs[i];
+    // https://wikiless.esmailelbob.xyz/wiki/Qsort?lang=en
-    xs[i] = xs[j];
+    double x = *(const double*)p;
-    xs[j] = tmp;
+    double y = *(const double*)q;
    /* Avoid returning x - y, which can cause undefined behaviour
       because of signed integer overflow. */
    if (x < y)
        return -1; // Return -1 if you want ascending, 1 if you want descending order.
    else if (x > y)
        return 1; // Return 1 if you want ascending, -1 if you want descending order.
    return 0;
 }
-
+ci get_90_confidence_interval(double (*sampler)(uint64_t*), uint64_t* seed)
 static int partition(int low, int high, double xs[], int length)
 {
-    // To understand this function:
+    int n = 100 * 1000;
-    // - see the note after gt variable definition
+    double* samples_array = malloc(n * sizeof(double));
    // - go to commit 578bfa27 and the scratchpad/ folder in it, which has printfs sprinkled throughout
    int pivot = low + floor((high - low) / 2);
    double pivot_value = xs[pivot];
    swp(pivot, high, xs);
    int gt = low; /* This pointer will iterate until finding an element which is greater than the pivot. Then it will move elements that are smaller before it--more specifically, it will move elements to its position and then increment. As a result all elements between gt and i will be greater than the pivot. */
    for (int i = low; i < high; i++) {
        if (xs[i] < pivot_value) {
            swp(gt, i, xs);
            gt++;
        }
    }
    swp(high, gt, xs);
    return gt;
 }
 static double quickselect(int k, double xs[], int n)
 {
    // https://en.wikipedia.org/wiki/Quickselect
    int low = 0;
    int high = n - 1;
    for (;;) {
        if (low == high) {
            return xs[low];
        }
        int pivot = partition(low, high, xs, n);
        if (pivot == k) {
            return xs[pivot];
        } else if (k < pivot) {
            high = pivot - 1;
        } else {
            low = pivot + 1;
        }
    }
 }
 ci array_get_ci(ci interval, double* xs, int n)
 {
    int low_k = floor(interval.low * n);
    int high_k = ceil(interval.high * n);
    ci result = {
        .low = quickselect(low_k, xs, n),
        .high = quickselect(high_k, xs, n),
    };
    return result;
 }
 ci array_get_90_ci(double xs[], int n)
 {
    return array_get_ci((ci) { .low = 0.05, .high = 0.95 }, xs, n);
 }
 ci sampler_get_ci(ci interval, double (*sampler)(uint64_t*), int n, uint64_t* seed)
 {
    double* xs = malloc(n * sizeof(double));
    for (int i = 0; i < n; i++) {
-        xs[i] = sampler(seed);
+        samples_array[i] = sampler(seed);
    }
-    ci result = array_get_ci(interval, xs, n);
+    qsort(samples_array, n, sizeof(double), compare_doubles);
    free(xs);
    return result;
 }
 ci sampler_get_90_ci(double (*sampler)(uint64_t*), int n, uint64_t* seed)
 {
    return sampler_get_ci((ci) { .low = 0.05, .high = 0.95 }, sampler, n, seed);
 }
-/* Algebra manipulations */
+    ci result = {
-// here I discover named structs,
+        .low = samples_array[5000],
-// which mean that I don't have to be typing
+        .high = samples_array[94999],
 // struct blah all the time.
 #define NORMAL90CONFIDENCE 1.6448536269514727
 typedef struct normal_params_t {
    double mean;
    double std;
 } normal_params;
 normal_params algebra_sum_normals(normal_params a, normal_params b)
 {
    normal_params result = {
        .mean = a.mean + b.mean,
        .std = sqrt((a.std * a.std) + (b.std * b.std)),
    };
-    return result;
+    free(samples_array);
 }
 typedef struct lognormal_params_t {
    double logmean;
    double logstd;
 } lognormal_params;
 lognormal_params algebra_product_lognormals(lognormal_params a, lognormal_params b)
 {
    lognormal_params result = {
        .logmean = a.logmean + b.logmean,
        .logstd = sqrt((a.logstd * a.logstd) + (b.logstd * b.logstd)),
    };
    return result;
 }
 lognormal_params convert_ci_to_lognormal_params(ci x)
 {
    double loghigh = logf(x.high);
    double loglow = logf(x.low);
    double logmean = (loghigh + loglow) / 2.0;
    double logstd = (loghigh - loglow) / (2.0 * NORMAL90CONFIDENCE);
    lognormal_params result = { .logmean = logmean, .logstd = logstd };
    return result;
 }
 ci convert_lognormal_params_to_ci(lognormal_params y)
 {
    double h = y.logstd * NORMAL90CONFIDENCE;
    double loghigh = y.logmean + h;
    double loglow = y.logmean - h;
    ci result = { .low = exp(loglow), .high = exp(loghigh) };
    return result;
 }
 /* Scaffolding to handle errors */
-// We will sample from an arbitrary cdf
+// We are building towards sample from an arbitrary cdf
 // and that operation might fail
 // so we build some scaffolding here
 #define MAX_ERROR_LENGTH 500
 #define EXIT_ON_ERROR 0
 #define PROCESS_ERROR(error_msg) process_error(error_msg, EXIT_ON_ERROR, __FILE__, __LINE__)
 struct box {
    int empty;
    double content;
@ -276,7 +148,7 @@ struct box inverse_cdf_double(double cdf(double), double p)
    }
 }
-// Version #2:
+// Version #2: 
 // - input: (cdf: double => Box(number|error), p)
 // - output: Box(number|error)
 struct box inverse_cdf_box(struct box cdf_box(double), double p)
@ -374,21 +246,122 @@ double sampler_cdf_danger(struct box cdf(double), uint64_t* seed)
 {
    double p = sample_unit_uniform(seed);
    struct box result = inverse_cdf_box(cdf, p);
-    if (result.empty) {
+	if(result.empty){
-        exit(1);
+	    exit(1);
-    } else {
+	}else{
-        return result.content;
+		return result.content;
-    }
+	}
 }
-/* array print: potentially useful for debugging */
+/* Algebra manipulations */
 // here I discover named structs,
 // which mean that I don't have to be typing
 // struct blah all the time.
 typedef struct normal_params_t {
    double mean;
    double std;
 } normal_params;
-void array_print(double xs[], int n)
+normal_params algebra_sum_normals(normal_params a, normal_params b)
 {
-    printf("[");
+    normal_params result = {
-    for (int i = 0; i < n - 1; i++) {
+        .mean = a.mean + b.mean,
-        printf("%f, ", xs[i]);
+        .std = sqrt((a.std * a.std) + (b.std * b.std)),
-    }
+    };
-    printf("%f", xs[n - 1]);
+    return result;
-    printf("]\n");
+}
 typedef struct lognormal_params_t {
    double logmean;
    double logstd;
 } lognormal_params;
 lognormal_params algebra_product_lognormals(lognormal_params a, lognormal_params b)
 {
    lognormal_params result = {
        .logmean = a.logmean + b.logmean,
        .logstd = sqrt((a.logstd * a.logstd) + (b.logstd * b.logstd)),
    };
    return result;
 }
 lognormal_params convert_ci_to_lognormal_params(ci x)
 {
    double loghigh = logf(x.high);
    double loglow = logf(x.low);
    double logmean = (loghigh + loglow) / 2.0;
    double logstd = (loghigh - loglow) / (2.0 * NORMAL90CONFIDENCE);
    lognormal_params result = { .logmean = logmean, .logstd = logstd };
    return result;
 }
 ci convert_lognormal_params_to_ci(lognormal_params y)
 {
    double h = y.logstd * NORMAL90CONFIDENCE;
    double loghigh = y.logmean + h;
    double loglow = y.logmean - h;
    ci result = { .low = exp(loglow), .high = exp(loghigh) };
    return result;
 }
 /* Parallel sampler */
 void parallel_sampler(double (*sampler)(uint64_t* seed), double* results, int n_threads, int n_samples){
    // Division terminology:
    // a =  b * quotient + reminder
    // a = (a/b)*b + (a%b)
    // dividend: a
    // divisor: b
    // quotient = a / b
    // reminder = a % b
    // "divisor's multiple" := (a/b)*b
    // now, we have n_samples and n_threads
    // to make our life easy, each thread will have a number of samples of: a/b (quotient)
    // and we'll compute the remainder of samples separately
    // to possibly do by Jorge: improve so that the remainder is included in the threads
    int quotient = n_samples / n_threads;
    int remainder = n_samples % n_threads;
    int divisor_multiple = quotient * n_threads; 
    uint64_t** seeds = malloc(n_threads * sizeof(uint64_t*));
    // printf("UINT64_MAX: %lu\n", UINT64_MAX);
    srand(1);
    for (uint64_t i = 0; i < n_threads; i++) {
        seeds[i] = malloc(sizeof(uint64_t));
        // Constraints: 
        // - xorshift can't start with 0
        // - the seeds should be reasonably separated and not correlated
        *seeds[i] = (uint64_t) rand() * (UINT64_MAX / RAND_MAX);
        // printf("#%ld: %lu\n",i, *seeds[i]);
        // Other initializations tried:
        // *seeds[i] = 1 + i;
        // *seeds[i] = (i + 0.5)*(UINT64_MAX/n_threads);
        // *seeds[i] = (i + 0.5)*(UINT64_MAX/n_threads) + constant * i;
    }
    int i;
    #pragma omp parallel private(i)
        {
        #pragma omp for
        for (i = 0; i < n_threads; i++) {
            int lower_bound_inclusive = i * quotient;
            int upper_bound_not_inclusive = ((i+1) * quotient); // note the < in the for loop below, 
            // printf("Lower bound: %d, upper bound: %d\n", lower_bound, upper_bound);
            for (int j = lower_bound_inclusive; j < upper_bound_not_inclusive; j++) {
                results[j] = sampler(seeds[i]);
            }
        }
    }
    for(int j=divisor_multiple; j<n_samples; j++){
        results[j] = sampler(seeds[0]);
        // we can just reuse a seed, this isn't problematic because we are not doing multithreading
    }
    for (uint64_t i = 0; i < n_threads; i++) {
        free(seeds[i]);
    }
    free(seeds);
 }
--- a/squiggle_more.h
+++ b/squiggle_more.h
@ -1,20 +1,35 @@
 #ifndef SQUIGGLE_C_EXTRA
-#define SQUIGGLE_C_EXTRA
+#define SQUIGGLE_C_EXTRA 
-/* Parallel sampling */
+// Box
-void sampler_parallel(double (*sampler)(uint64_t* seed), double* results, int n_threads, int n_samples);
+struct box {
    int empty;
    double content;
    char* error_msg;
 };
-/* Get 90% confidence interval */
+// Macros to handle errors
 #define MAX_ERROR_LENGTH 500
 #define EXIT_ON_ERROR 0
 #define PROCESS_ERROR(error_msg) process_error(error_msg, EXIT_ON_ERROR, __FILE__, __LINE__)
 struct box process_error(const char* error_msg, int should_exit, char* file, int line);
 // Inverse cdf
 struct box inverse_cdf_double(double cdf(double), double p);
 struct box inverse_cdf_box(struct box cdf_box(double), double p);
 // Samplers from cdf
 struct box sampler_cdf_double(double cdf(double), uint64_t* seed);
 struct box sampler_cdf_box(struct box cdf(double), uint64_t* seed);
 // Get 90% confidence interval
 typedef struct ci_t {
-    double low;
+    float low;
-    double high;
+    float high;
 } ci;
-ci array_get_ci(ci interval, double* xs, int n);
+ci get_90_confidence_interval(double (*sampler)(uint64_t*), uint64_t* seed);
 ci array_get_90_ci(double xs[], int n);
 ci sampler_get_ci(ci interval, double (*sampler)(uint64_t*), int n, uint64_t* seed);
 ci sampler_get_90_ci(double (*sampler)(uint64_t*), int n, uint64_t* seed);
-/* Algebra manipulations */
+// small algebra manipulations
 typedef struct normal_params_t {
    double mean;
@ -29,26 +44,8 @@ typedef struct lognormal_params_t {
 lognormal_params algebra_product_lognormals(lognormal_params a, lognormal_params b);
 lognormal_params convert_ci_to_lognormal_params(ci x);
-ci convert_lognormal_params_to_ci(lognormal_params y);
+ci               convert_lognormal_params_to_ci(lognormal_params y);
-/* Error handling */
+void parallel_sampler(double (*sampler)(uint64_t* seed), double* results, int n_threads, int n_samples);
 struct box {
    int empty;
    double content;
    char* error_msg;
 };
 #define MAX_ERROR_LENGTH 500
 #define EXIT_ON_ERROR 0
 #define PROCESS_ERROR(error_msg) process_error(error_msg, EXIT_ON_ERROR, __FILE__, __LINE__)
 struct box process_error(const char* error_msg, int should_exit, char* file, int line);
 void array_print(double* array, int length);
 /* Inverse cdf */
 struct box inverse_cdf_double(double cdf(double), double p);
 struct box inverse_cdf_box(struct box cdf_box(double), double p);
 /* Samplers from cdf */
 struct box sampler_cdf_double(double cdf(double), uint64_t* seed);
 struct box sampler_cdf_box(struct box cdf(double), uint64_t* seed);
 #endif