d8076b9333
Surface rename of the signed integer family: s1..s64 become i1..i64
(u1..u64, usize, isize unchanged). 'string' keeps the s-prefix arm in
name classification; width parsing moves to the i-prefix arm next to
isize.
Internal TypeId tags follow the surface (.s8/.s16/.s32/.s64 ->
.i8/.i16/.i32/.i64), as do mono-key mangle fragments (ptr_i64,
tu_i64_bool) and all display/diagnostic formatting (i{d}).
Migrated in the same sweep: stdlib + examples + issue repros + FFI C
companions (shared symbol names like ffi_id_i64), expected
stdout/stderr/ir snapshots, specs.md, readme.md, CLAUDE.md/AGENTS.md,
implementation_plan.md, docs/, issue writeups. Vendored stb_image and
historical flow state left untouched.
zig build test: 426/426; examples suite: 595/595.
95 lines
4.9 KiB
Plaintext
95 lines
4.9 KiB
Plaintext
// Float numeric-limit accessors: `f32`/`f64` expose `.min` / `.max` (sibling of
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// the integer `.min`/`.max`, NL.1) plus the float-only `.epsilon`,
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// `.min_positive`, `.true_min`, `.inf`, and `.nan`. Each folds, at compile time,
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// to a constant of the QUERIED float type via the same `lowerNumericLimit`
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// intercept as the integer case (`builder.constFloat` + the `std.math`
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// constants), driven by `TypeResolver.floatLimitFor`.
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//
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// The lexer has no exponent notation and the default float formatter is crude
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// (issue 0090), so these limits can be pinned NEITHER by literal comparison NOR
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// by printing. Every accessor is asserted instead by reinterpreting its bits
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// through an untagged union and comparing against the exact IEEE-754 hex
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// pattern — plus the defining-property checks that no other value could satisfy.
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//
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// Semantics (Agra-ruled, consistent with the integer accessors):
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// .min = most-NEGATIVE finite (= -max), NOT C's DBL_MIN
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// .max = largest finite
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// .epsilon = ULP of 1.0 (next f after 1.0 minus 1.0), NOT C#'s denormal Epsilon
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// .min_positive = smallest positive NORMAL (= C DBL_MIN / Rust MIN_POSITIVE)
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// .true_min = smallest positive SUBNORMAL (next value above 0.0)
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// .inf = +infinity
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// .nan = a quiet NaN
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//
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// Regression (issue 0091): `f64.nan != f64.nan` is true — native float `!=`
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// lowers UNORDERED, so a NaN compares unequal to everything including itself.
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#import "modules/std.sx";
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// `bits` mirrors each float's raw IEEE-754 storage. f64 needs 64 bits, f32 32.
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// The f64 union's `bits` (u64) view reads the all-ones-ish positive patterns as
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// their true magnitude; its `s` (i64) view pins the negative `f64.min` pattern
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// (0xFFEF…), whose unsigned form overflows the u64 literal parser, by comparing
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// the signed reinterpret to -4503599627370497.
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Uf64 :: union { f: f64; bits: u64; s: i64; }
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Uf32 :: union { f: f32; bits: u32; }
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main :: () -> i32 {
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o : Uf64 = ---;
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// Read `.true_min` (a subnormal) FIRST and through the union only — never via
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// arithmetic. Under flush-to-zero / denormals-are-zero CPU modes a subnormal
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// can flush to 0.0 on the first arithmetic op, so the bit reinterpret is the
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// only reliable channel for it.
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o.f = f64.true_min;
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print("f64.true_min {}\n", o.bits == 0x0000000000000001); // true
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o.f = f64.max;
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print("f64.max {}\n", o.bits == 0x7FEFFFFFFFFFFFFF); // true
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// f64.min = -max; its bit pattern 0xFFEFFFFFFFFFFFFF overflows an unsigned u64
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// literal, so it is pinned directly via the SIGNED i64 view: -4503599627370497.
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o.f = f64.min;
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print("f64.min {}\n", o.s == -4503599627370497); // true (bits 0xFFEFFFFFFFFFFFFF)
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o.f = f64.epsilon;
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print("f64.epsilon {}\n", o.bits == 0x3CB0000000000000); // true
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o.f = f64.min_positive;
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print("f64.min_positive {}\n", o.bits == 0x0010000000000000); // true
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o.f = f64.inf;
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print("f64.inf {}\n", o.bits == 0x7FF0000000000000); // true
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p : Uf32 = ---;
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p.f = f32.true_min;
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print("f32.true_min {}\n", p.bits == 0x00000001); // true
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p.f = f32.max;
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print("f32.max {}\n", p.bits == 0x7F7FFFFF); // true
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p.f = f32.min;
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print("f32.min {}\n", p.bits == 0xFF7FFFFF); // true
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p.f = f32.epsilon;
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print("f32.epsilon {}\n", p.bits == 0x34000000); // true
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p.f = f32.min_positive;
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print("f32.min_positive {}\n", p.bits == 0x00800000); // true
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p.f = f32.inf;
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print("f32.inf {}\n", p.bits == 0x7F800000); // true
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// Defining-property checks — true epsilon is the ULP of 1.0: adding it to 1.0
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// changes the value, adding half of it does not (round-to-nearest-even).
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print("(1+eps)!=1 {}\n", (1.0 + f64.epsilon) != 1.0); // true
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print("(1+eps/2)==1 {}\n", (1.0 + f64.epsilon/2.0) == 1.0); // true
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print("inf>max {}\n", f64.inf > f64.max); // true
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// f64.min = -max (the 0xFFEF… bit pattern overflows the i64 literal parser).
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print("min==-max {}\n", f64.min == -f64.max); // true
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print("true_min<min_pos {}\n", f64.true_min < f64.min_positive); // true
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print("true_min>0 {}\n", f64.true_min > 0.0); // true
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// Quiet NaN: unequal to everything, itself included (mantissa bits not pinned).
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print("nan!=nan {}\n", f64.nan != f64.nan); // true
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// Result carries the QUERIED type: each binding is declared with the float
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// type and round-trips, so a mistyped fold (boxed as Any / wrong width) would
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// not type-check here.
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e64 : f64 = f64.epsilon;
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e32 : f32 = f32.epsilon;
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q : Uf64 = ---; q.f = e64;
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r : Uf32 = ---; r.f = e32;
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print("typed eps bits {}\n", q.bits == 0x3CB0000000000000 and r.bits == 0x34000000); // true
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return 0;
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}
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