path: root/src/type.cff

import "cffc.hff";
import "util.hff";
import "common.hff";
import "set.hff";

struct TypeTraits {
   fn hash(ty *const Type) u32 {
      let h = FNV1A_INI;
      h = fnv1a_i(h, as(int)ty.u.#tag);
      h *= as(int)ty.konst + 2;

      switch ty.u {
      case Void;

      case Bool;
         h = fnv1a_i(h, ty.size);

      case Flo;
         h = fnv1a_i(h, ty.size);

      case Int i;
         h = fnv1a_i(h, i.sgn ? 1 : 0);
         h = fnv1a_i(h, ty.size);

      case Ptr child;
         h = fnv1a_i(h, child.id);

      case Arr arr;
         h = fnv1a_i(h, arr.child.id);
         h = fnv1a_i(h, arr.length);

      case Slice child;
         h = fnv1a_i(h, child.id);

      case Fn f;
         h = fnv1a_i(h, f.ret.id);
         foreach(p, _, f.params) {
            h = fnv1a_i(h, p.id);
         }

      case Agg agg;
         h = fnv1a_i(h, agg.id);

      case Enum enu;
         h = fnv1a_i(h, enu.id);
      }

      return h;
   }

   fn eq(a *const Type, b *const Type) bool {
      if a.u.#tag != b.u.#tag or a.konst != b.konst {
         return #f;
      }
      switch a.u {
      case Void;
      case Bool;
         return a.size == b.size;
      case Flo;
         return a.size == b.size;

      case Int i;
         return a.size == b.size and i.sgn == b.u.Int.sgn;

      case Ptr child;
         return child == b.u.Ptr;

      case Arr arr;
         let brr = b.u.Arr;
         return arr.length == brr.length and arr.child == brr.child;

      case Slice child;
         return child == b.u.Slice;

      case Fn f0;
         let f1 = b.u.Fn;
         if f0.variadic != f1.variadic {
            return #f;
         }
         if f0.ret != f1.ret {
            return #f;
         }
         if f0.params.#len != f1.params.#len {
            return #f;
         }
         foreach(p, i, f0.params) {
            if p != f1.params[i] {
               return #f;
            }
         }
         return #t;

      case Agg agg;
         let bgg = b.u.Agg;
         return agg.id == bgg.id;

      case Enum enu;
         return enu.id == b.u.Enum.id;
      }
      return #f;
   }

   fn dup(ty *const Type) *const Type {
      let p *Type = xmalloc(sizeof Type);
      static id int = 0;
      *p = *ty;
      p.id = id++;
      switch p.u {
      case Fn *f;
        let params = f.params;
        f.params = (as(**const Type)xmalloc(params.#len * sizeof *Type))[0::params.#len];
        memcpy(f.params.#ptr, params.#ptr, params.#len * sizeof *Type);
      }
      return p;
   }
}

static types_set Set<*const Type, TypeTraits> = {};
extern fn interntype(ty0 Type) *const Type {
   if ty0.align == 0 {
      ty0.align = ty0.size;
   }

   return *types_set->intern(&ty0);
}

extern fn completetype(ty *const Type) bool {
   if ty.konst {
      return completetype(unconstify(ty));
   }
   switch ty.u {
   case Void; return #f;
   case Fn; return #f;
   case Arr a; return a.length >= 0 and completetype(a.child);
   case Agg agg; return !agg.fwd;
   }
   return #t;
}

extern static ty_void     *const Type = {},
              ty_bool     *const Type = {},
              ty_intbool  *const Type = {},
              ty_i8       *const Type = {},
              ty_u8       *const Type = {},
              ty_i16      *const Type = {},
              ty_u16      *const Type = {},
              ty_i32      *const Type = {},
              ty_u32      *const Type = {},
              ty_int      *const Type = {},
              ty_uint     *const Type = {},
              ty_i64      *const Type = {},
              ty_u64      *const Type = {},
              ty_isize    *const Type = {},
              ty_usize    *const Type = {},
              ty_iptrint  *const Type = {},
              ty_uptrint  *const Type = {},
              ty_f32      *const Type = {},
              ty_f64      *const Type = {},
              ty_voidptr  *const Type = {},
              ty_c_char   *const Type = {},
              ty_c_long   *const Type = {},
              ty_c_ulong  *const Type = {},
              ty_c_llong  *const Type = {},
              ty_c_ullong *const Type = {},
              ty_c_valist *const Type = {};

extern fn putprimtypes(env *Env) void {
   let types []struct { name *const u8, gty **const Type, ty Type } = {
      { "void",   &ty_void, { .size: 0, .align: 1, .u: :Void }},
      { "bool",   &ty_bool, { .size: 1, .align: 1, .u: :Bool }},
      { "f32",    &ty_f32,  { .size: 4, .u: :Flo }},
      { "f64",    &ty_f64,  { .size: 8, g_targ.f64align, .u: :Flo }},
      { "i8",     &ty_i8,   { .size: 1, .u: :Int { .sgn: #t }}},
      { "u8",     &ty_u8,   { .size: 1, .u: :Int { .sgn: #f }}},
      { "i16",    &ty_i16,  { .size: 2, .u: :Int { .sgn: #t }}},
      { "u16",    &ty_u16,  { .size: 2, .u: :Int { .sgn: #f }}},
      { "i32",    &ty_i32,  { .size: 4, .u: :Int { .sgn: #t }}},
      { "u32",    &ty_u32,  { .size: 4, .u: :Int { .sgn: #f }}},
      { "int",    &ty_int,  { g_targ.intsize, .u: :Int { .sgn: #t }}},
      { "uint",   &ty_uint, { g_targ.intsize, .u: :Int { .sgn: #f }}},
      { "intbool",&ty_intbool,{ .size: g_targ.intsize, .u: :Bool }},
      { "isize",  &ty_isize,{ g_targ.sizesize, .u: :Int { .sgn: #t }}},
      { "usize",  &ty_usize,{ g_targ.sizesize, .u: :Int { .sgn: #f }}},
      { "i64",    &ty_i64,  { .size: 8, g_targ.i64align, .u: :Int { .sgn: #t }}},
      { "u64",    &ty_u64,  { .size: 8, g_targ.i64align, .u: :Int { .sgn: #f }}},
      { "iptrint",&ty_iptrint, { g_targ.ptrsize, .u: :Int { .sgn: #t }}},
      { "uptrint",&ty_uptrint, { g_targ.ptrsize, .u: :Int { .sgn: #f }}},
      { "c_char", &ty_c_char, { .size: 1, .u: :Int { .sgn: g_targ.charsigned }}},
      { "c_long", &ty_c_long, { g_targ.longsize, g_targ.longalign, .u: :Int { .sgn : #t }}},
      { "c_ulong",&ty_c_ulong, { g_targ.longsize, g_targ.longalign, .u: :Int { .sgn : #f }}},
      { "c_llong",&ty_c_llong, { g_targ.llongsize, g_targ.llongalign, .u: :Int { .sgn : #t }}},
      { "c_ullong",&ty_c_ullong,{ g_targ.llongsize, g_targ.llongalign, .u: :Int { .sgn : #f }}},
      { "va_list",&ty_c_valist,{ g_targ.valistsize, g_targ.valistalign, .u: :VaList }},
   };

   foreach(type, _, types[0::]) {
      envput(env, { type.name, .u: :Ty(*type.gty = interntype(type.ty)) }, #null);      
   }
   ty_voidptr = interntype({ .size: g_targ.ptrsize, .u: :Ptr(ty_void) });
}

extern fn mkslicetype(child *const Type) *const Type {
   let align = MAX(g_targ.ptrsize, g_targ.sizesize);
   return interntype({
      ALIGNUP(g_targ.ptrsize + g_targ.sizesize, align), align,
      .u: :Slice(child)
   });
}

fn numtype2rank(ty *const Type) int {
   ty = unconstify(ty);
   switch {
   case ty->is(:Enum);
      assert(ty.u.Enum.lax, "lax");
      return numtype2rank(ty.u.Enum.intty);
   case ty->is(:Int) and (ty == ty_int or ty.size < ty_int.size);
      return 0;
   case ty == ty_uint; return 1;
   case ty == ty_i32;  return 2;
   case ty == ty_u32;  return 3;
   case ty == ty_i64;  return 4;
   case ty == ty_u64;  return 5;
   case ty == ty_f32;  return 6;
   case ty == ty_f64;  return 7;
   }
   return -1;
}

fn rank2numtype(r int) *const Type {
   static const types []**const Type = {
      &ty_int, &ty_uint, &ty_i32, &ty_u32,
      &ty_i64, &ty_u64, &ty_f32, &ty_f64,
   };
   assert(r >= 0 and r < types.#len, "rank");
   return *types[r];
}

fn arraydecay(ty *const Type) *const Type {
   switch ty.u {
   case Arr arr; return mkptrtype(arr.child);
   case else; return ty;
   }
}

fn constifychild(ty *const Type) *const Type {
   let ty2 = *ty;
   switch ty.u {
   case Ptr child;
      let cchild = constify(child);
      if child == cchild { return ty; }
      ty2.u.Ptr = child;
      return interntype(ty2);
   case Slice child;
      let cchild = constify(child);
      if child == cchild { return ty; }
      ty2.u.Slice = child;
      return interntype(ty2);
   case else;
      assert(#f, "constifychild: not ptr or slice");
   }
}

extern fn typeof2(a *const Type, b *const Type) *const Type {
   if a == b and !a->is(:Int) {
      return a;
   }
   if isnumtype(a) and isnumtype(b) {
      let ra = numtype2rank(a),
          rb = numtype2rank(b);
      return rank2numtype(MAX(ra, rb));
   }
   if unconstify(a) == b {
      return a;
   }
   if a == unconstify(b) {
      return b;
   }
   if a->is(:Bool) and b->is(:Bool) {
      return a.size > b.size ? a : b;
   }
   if a->is(:Arr) and b->is(:Arr) {
      a = arraydecay(a);
   }
   if a->is(:Ptr) and b->is(:Arr) {
      b = arraydecay(b);
   }
   if a->is(:Arr) and b->is(:Ptr) {
      a = arraydecay(a);
   }
   if a.u.#tag == b.u.#tag and (a->is(:Ptr) or a->is(:Slice)) {
      let akonst = a.u.Ptr.konst,
          bkonst = b.u.Ptr.konst,
          uac = unconstify(a.u.Ptr),
          ubc = unconstify(b.u.Ptr);
      if uac == ubc {
         return akonst ? a : b;
      }
      if uac->is(:Void) {
         if !bkonst and akonst { return constifychild(b); }
         return b;
      }
      if ubc->is(:Void) {
         if !akonst and bkonst { return constifychild(a); }
         return a;
      }
   }
   return #null;
}

extern fn types_to_llvm() void {
   set_each(ty, types_set) {
      llvm_addtype(ty);
   }
}