// Unified float→int narrowing rule (F0.11), NEGATIVE side: a NON-INTEGRAL float
// implicitly narrowing to an integer-typed binding is a COMPILE ERROR — not a
// silent truncation. The rule fires at a typed LOCAL initializer, a function
// PARAM default, a struct FIELD default, AND an array DIMENSION; each emits a
// narrowing diagnostic at the offending float and aborts (exit 1). It fires
// whether the float is a LITERAL (`1.5`), an INT-const-expression (`M + 0.5`,
// with `M :: 2`), a FLOAT-const-leaf expression (`F + 0.25`, with `F : f64 : 2.5`,
// = 2.75), a builtin FLOAT numeric-limit leaf inside an expression
// (`f64.true_min + 0.5` = 0.5), or a float `%` whose remainder is non-integral
// (`5.5 % 2.0` = 1.5) — all of these are the core of issue 0095, which previously
// slipped through and truncated. The fix is the integral-fold / non-integral-error
// rule shared across all five sites (local, field, param, const, and array
// dimension), applied to ANY compile-time-constant float expression (literal,
// int-const leaf, float-const leaf, numeric-limit leaf, `+ - * / %`, and
// combinations) — the compile-time float evaluator is at parity with the integer
// one, so no float leaf shape escapes. The array-dimension site phrases the same
// rejection as "must be an integer".
//
// The escape hatch stays open: `y : i64 = xx 1.5` (or `cast(i64) 1.5`)
// truncates with no error — exercised on the POSITIVE side (example 0168).
//
// Regression (issue 0095): `y : i64 = 1.5` silently truncated to 1,
// `y : i64 = M + 0.5` to 2, and `y : i64 = F + 0.25` (float-const leaf) to 2.
#import "modules/std.sx";

M :: 2;          // int module const, for the INT-const-EXPRESSION cases
F : f64 : 2.5;   // float module const, for the FLOAT-const-LEAF cases

Bad :: struct {
    f  : i64 = 3.5;       // non-integral float LITERAL field default → error
    fe : i64 = M + 0.5;   // non-integral int-const-EXPR field default → error
    ff : i64 = F + 0.25;  // non-integral float-const-LEAF field default → error
}

badLit  :: (x : i64 = 2.5)      -> i64 { return x; }   // non-integral LITERAL param default → error
badExpr :: (x : i64 = M + 0.5)  -> i64 { return x; }   // non-integral int-const-EXPR param default → error
badFlt  :: (x : i64 = F + 0.25) -> i64 { return x; }   // non-integral float-const-LEAF param default → error

main :: () {
    y  : i64 = 1.5;       // non-integral float LITERAL local → error
    ye : i64 = M + 0.5;   // non-integral int-const-EXPRESSION local → error
    yf : i64 = F + 0.25;  // non-integral float-const-LEAF local → error
    yn : i64 = f64.true_min + 0.5;  // non-integral numeric-limit float expr → error
    ym : i64 = 5.5 % 2.0;           // non-integral float `%` remainder (1.5) → error
    ad : [F + 0.25]i64 = ---;  // non-integral float-const-LEAF array DIMENSION → error
    b := Bad.{};
    print("{} {} {}\n", b.f, b.fe, b.ff);
    print("{} {} {}\n", badLit(), badExpr(), badFlt());
    print("{} {} {} {} {} {}\n", y, ye, yf, yn, ym, ad.len);
}