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@@ -10,11 +10,9 @@ Rand :: struct {
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_GLOBAL_SEED_DATA := 1234567890;
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@(private, static)
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global_rand := create(u64(uintptr(&_GLOBAL_SEED_DATA)));
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-@(private, static)
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-global_rand_ptr := &global_rand;
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set_global_seed :: proc(seed: u64) {
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- init(global_rand_ptr, seed);
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+ init(&global_rand, seed);
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}
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create :: proc(seed: u64) -> Rand {
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@@ -32,6 +30,12 @@ init :: proc(r: ^Rand, seed: u64) {
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}
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_random :: proc(r: ^Rand) -> u32 {
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+ r := r;
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+ if r == nil {
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+ // NOTE(bill, 2020-09-07): Do this so that people can
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+ // enforce the global random state if necessary with `nil`
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+ r = &global_rand;
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+ }
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old_state := r.state;
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r.state = old_state * 6364136223846793005 + (r.inc|1);
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xor_shifted := u32(((old_state>>18) ~ old_state) >> 27);
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@@ -39,15 +43,15 @@ _random :: proc(r: ^Rand) -> u32 {
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return (xor_shifted >> rot) | (xor_shifted << ((-rot) & 31));
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}
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-uint32 :: proc(r: ^Rand = global_rand_ptr) -> u32 { return _random(r); }
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+uint32 :: proc(r: ^Rand = nil) -> u32 { return _random(r); }
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-uint64 :: proc(r: ^Rand = global_rand_ptr) -> u64 {
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+uint64 :: proc(r: ^Rand = nil) -> u64 {
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a := u64(_random(r));
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b := u64(_random(r));
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return (a<<32) | b;
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}
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-uint128 :: proc(r: ^Rand = global_rand_ptr) -> u128 {
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+uint128 :: proc(r: ^Rand = nil) -> u128 {
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a := u128(_random(r));
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b := u128(_random(r));
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c := u128(_random(r));
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@@ -55,11 +59,11 @@ uint128 :: proc(r: ^Rand = global_rand_ptr) -> u128 {
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return (a<<96) | (b<<64) | (c<<32) | d;
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}
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-int31 :: proc(r: ^Rand = global_rand_ptr) -> i32 { return i32(uint32(r) << 1 >> 1); }
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-int63 :: proc(r: ^Rand = global_rand_ptr) -> i64 { return i64(uint64(r) << 1 >> 1); }
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-int127 :: proc(r: ^Rand = global_rand_ptr) -> i128 { return i128(uint128(r) << 1 >> 1); }
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+int31 :: proc(r: ^Rand = nil) -> i32 { return i32(uint32(r) << 1 >> 1); }
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+int63 :: proc(r: ^Rand = nil) -> i64 { return i64(uint64(r) << 1 >> 1); }
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+int127 :: proc(r: ^Rand = nil) -> i128 { return i128(uint128(r) << 1 >> 1); }
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-int31_max :: proc(n: i32, r: ^Rand = global_rand_ptr) -> i32 {
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+int31_max :: proc(n: i32, r: ^Rand = nil) -> i32 {
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if n <= 0 do panic("Invalid argument to int31_max");
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if n&(n-1) == 0 {
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return int31(r) & (n-1);
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@@ -72,7 +76,7 @@ int31_max :: proc(n: i32, r: ^Rand = global_rand_ptr) -> i32 {
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return v % n;
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}
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-int63_max :: proc(n: i64, r: ^Rand = global_rand_ptr) -> i64 {
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+int63_max :: proc(n: i64, r: ^Rand = nil) -> i64 {
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if n <= 0 do panic("Invalid argument to int63_max");
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if n&(n-1) == 0 {
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return int63(r) & (n-1);
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@@ -85,7 +89,7 @@ int63_max :: proc(n: i64, r: ^Rand = global_rand_ptr) -> i64 {
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return v % n;
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}
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-int127_max :: proc(n: i128, r: ^Rand = global_rand_ptr) -> i128 {
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+int127_max :: proc(n: i128, r: ^Rand = nil) -> i128 {
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if n <= 0 do panic("Invalid argument to int63_max");
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if n&(n-1) == 0 {
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return int127(r) & (n-1);
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@@ -98,7 +102,7 @@ int127_max :: proc(n: i128, r: ^Rand = global_rand_ptr) -> i128 {
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return v % n;
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}
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-int_max :: proc(n: int, r: ^Rand = global_rand_ptr) -> int {
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+int_max :: proc(n: int, r: ^Rand = nil) -> int {
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if n <= 0 do panic("Invalid argument to int_max");
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when size_of(int) == 4 {
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return int(int31_max(i32(n), r));
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@@ -107,14 +111,14 @@ int_max :: proc(n: int, r: ^Rand = global_rand_ptr) -> int {
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}
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}
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-float64 :: proc(r: ^Rand = global_rand_ptr) -> f64 { return f64(int63_max(1<<53, r)) / (1 << 53); }
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-float32 :: proc(r: ^Rand = global_rand_ptr) -> f32 { return f32(float64(r)); }
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+float64 :: proc(r: ^Rand = nil) -> f64 { return f64(int63_max(1<<53, r)) / (1 << 53); }
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+float32 :: proc(r: ^Rand = nil) -> f32 { return f32(float64(r)); }
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-float64_range :: proc(lo, hi: f64, r: ^Rand = global_rand_ptr) -> f64 { return (hi-lo)*float64(r) + lo; }
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-float32_range :: proc(lo, hi: f32, r: ^Rand = global_rand_ptr) -> f32 { return (hi-lo)*float32(r) + lo; }
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+float64_range :: proc(lo, hi: f64, r: ^Rand = nil) -> f64 { return (hi-lo)*float64(r) + lo; }
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+float32_range :: proc(lo, hi: f32, r: ^Rand = nil) -> f32 { return (hi-lo)*float32(r) + lo; }
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-read :: proc(p: []byte, r: ^Rand = global_rand_ptr) -> (n: int) {
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+read :: proc(p: []byte, r: ^Rand = nil) -> (n: int) {
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pos := i8(0);
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val := i64(0);
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for n = 0; n < len(p); n += 1 {
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@@ -130,10 +134,10 @@ read :: proc(p: []byte, r: ^Rand = global_rand_ptr) -> (n: int) {
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}
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// perm returns a slice of n ints in a pseudo-random permutation of integers in the range [0, n)
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-perm :: proc(n: int, r: ^Rand = global_rand_ptr) -> []int {
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+perm :: proc(n: int, r: ^Rand = nil) -> []int {
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m := make([]int, n);
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for i := 0; i < n; i += 1 {
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- j := int_max(i+1);
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+ j := int_max(i+1, r);
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m[i] = m[j];
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m[j] = i;
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}
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@@ -141,7 +145,7 @@ perm :: proc(n: int, r: ^Rand = global_rand_ptr) -> []int {
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}
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-shuffle :: proc(array: $T/[]$E, r: ^Rand = global_rand_ptr) {
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+shuffle :: proc(array: $T/[]$E, r: ^Rand = nil) {
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n := i64(len(array));
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if n < 2 do return;
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gingerBill