/* Copyright (C) 2019, 2020 Leo Tenenbaum. This file is part of toc. toc is distributed under version 3 of the GNU General Public License, without any warranty whatsoever. You should have received a copy of the GNU General Public License along with toc. If not, see . */ static void cgen_create(CGenerator *g, FILE *out, Identifiers *ids, Allocator *allocr) { g->outc = out; g->ident_counter = 0; g->lbl_counter = 0; g->main_ident = ident_get(ids, "main"); g->will_indent = true; g->indent_lvl = 0; g->globals = ids; g->allocr = allocr; g->nms_prefixes = NULL; } static void cgen_stmt(CGenerator *g, Statement *s); enum { CGEN_BLOCK_NOBRACES = 0x01 /* should it use braces? */ }; static void cgen_block(CGenerator *g, Block *b, const char *ret_name, uint16_t flags); static void cgen_expr_pre(CGenerator *g, Expression *e); static void cgen_expr(CGenerator *g, Expression *e); static void cgen_set(CGenerator *g, Expression *set_expr, const char *set_str, Expression *to_expr, const char *to_str); static void cgen_set_tuple(CGenerator *g, Expression *exprs, Identifier *idents, const char *prefix, Expression *to); static void cgen_type_pre(CGenerator *g, Type *t); static void cgen_type_post(CGenerator *g, Type *t); static void cgen_decl(CGenerator *g, Declaration *d); static void cgen_ret(CGenerator *g, Block *returning_from, Expression *ret_expr); /* yes, these do need to take pointers, and furthermore they must be the same pointer (because of slices) */ static void cgen_val(CGenerator *g, Value *v, Type *t); static void cgen_val_pre(CGenerator *g, Value *v, Type *t); static void cgen_val_ptr(CGenerator *g, void *v, Type *t); static void cgen_defs_block(CGenerator *g, Block *b); static void cgen_defs_decl(CGenerator *g, Declaration *d); #define cgen_recurse_subexprs_fn_simple(fn, decl_f, block_f) \ if (!(fn->flags & FN_EXPR_FOREIGN)) { \ FnExpr *prev_fn = g->f##n; \ g->f##n = fn; \ arr_foreach(fn->params, Declaration, param) \ decl_f(g, param); \ arr_foreach(fn->ret_decls, Declaration, r) \ decl_f(g, r); \ block_f(g, &fn->body); \ g->f##n = prev_fn; \ } /* calls f on every sub-expression of e, block_f on every sub-block, and decl_f on every sub-declaration. */ #define cgen_recurse_subexprs(g, e, f, block_f, decl_f) \ switch (e->kind) { \ case EXPR_TYPE: \ case EXPR_VAL: \ case EXPR_C: \ case EXPR_BUILTIN: \ case EXPR_IDENT: \ case EXPR_LITERAL_BOOL: \ case EXPR_LITERAL_INT: \ case EXPR_LITERAL_STR: \ case EXPR_LITERAL_CHAR: \ case EXPR_LITERAL_FLOAT: \ break; \ case EXPR_UNARY_OP: \ f(g, e->unary.of); \ break; \ case EXPR_BINARY_OP: \ f(g, e->binary.lhs); \ if (e->binary.op != BINARY_DOT) \ f(g, e->binary.rhs); \ break; \ case EXPR_CAST: \ f(g, e->cast.expr); \ break; \ case EXPR_CALL: \ f(g, e->call.fn); \ arr_foreach(e->call.arg_exprs, Expression, arg) \ f(g, arg); \ break; \ case EXPR_BLOCK: \ block_f(g, e->block); \ break; \ case EXPR_NMS: { \ Namespace *prev = g->nms; \ g->nms = e->nms; \ block_f(g, &e->nms->body); \ g->nms = prev; \ } break; \ case EXPR_IF: { \ IfExpr *i = e->if_; \ if (i->cond) \ f(g, i->cond); \ block_f(g, &i->body); \ if (i->next_elif) \ f(g, i->next_elif); \ } break; \ case EXPR_WHILE: { \ WhileExpr *w = e->while_; \ if (w->cond) \ f(g, w->cond); \ block_f(g, &w->body); \ } break; \ case EXPR_FOR: { \ ForExpr *fo = e->for_; \ if (fo->flags & FOR_IS_RANGE) { \ f(g, fo->range.from); \ if (fo->range.to) f(g, fo->range.to); \ /* step is a value, not an expression */ \ } else { \ f(g, fo->of); \ } \ block_f(g, &fo->body); \ } break; \ case EXPR_TUPLE: \ arr_foreach(e->tuple, Expression, x) \ f(g, x); \ break; \ case EXPR_SLICE: \ f(g, e->slice.of); \ if (e->slice.from) f(g, e->slice.from); \ if (e->slice.to) f(g, e->slice.to); \ break; \ case EXPR_FN: { \ FnExpr *fn = e->fn; \ if (fn_has_instances(fn)) { \ Instance **data = fn->instances->data; \ for (U64 i = 0; i < fn->instances->cap; ++i) { \ if (fn->instances->occupied[i]) { \ cgen_recurse_subexprs_fn_simple(((*data)->fn), decl_f, block_f); \ } \ ++data; \ } \ } else { \ cgen_recurse_subexprs_fn_simple(fn, decl_f, block_f); \ } \ } break; \ } #define cgen_recurse_subtypes(f, g, type) \ switch (type->kind) { \ case TYPE_STRUCT: \ /* don't descend into fields */ \ break; \ case TYPE_FN: \ if (type->kind == TYPE_FN && (type->fn.constness || fn_type_has_varargs(&type->fn))) { \ /* we don't want to do this, because it's a template-y thing */ \ } \ else { \ arr_foreach(type->fn.types, Type, sub) { \ f(g, sub); \ } \ } \ break; \ case TYPE_TUPLE: \ arr_foreach(type->tuple, Type, sub) \ f(g, sub); \ break; \ case TYPE_ARR: \ f(g, type->arr.of); \ break; \ case TYPE_SLICE: \ f(g, type->slice); \ break; \ case TYPE_PTR: \ f(g, type->ptr); \ break; \ case TYPE_VOID: \ case TYPE_BUILTIN: \ case TYPE_UNKNOWN: \ break; \ case TYPE_EXPR: assert(0); \ } static inline FILE *cgen_writing_to(CGenerator *g) { return g->outc; /* for now */ } static inline void *cgen_malloc(CGenerator *g, size_t sz) { return allocr_malloc(g->allocr, sz); } /* indent iff needed */ static inline void cgen_indent(CGenerator *g) { if (g->will_indent) { for (unsigned i = 0; i < g->indent_lvl; ++i) fprintf(cgen_writing_to(g), "\t"); g->will_indent = false; } } static inline void cgen_write(CGenerator *g, const char *fmt, ...) { va_list args; cgen_indent(g); va_start(args, fmt); vfprintf(cgen_writing_to(g), fmt, args); va_end(args); #ifdef TOC_DEBUG fflush(cgen_writing_to(g)); #endif } static inline void cgen_nl(CGenerator *g) { fprintf(cgen_writing_to(g), "\n"); g->will_indent = true; } static inline char *cgen_ident_to_str(Identifier i) { return ident_to_str_reduced_charset(i); } static inline void cgen_ident_id(CGenerator *g, IdentID id) { cgen_write(g, "a%lu_", (unsigned long)id); } static inline void cgen_lbl(CGenerator *g, IdentID lbl) { cgen_write(g, "lbl%lu_", (unsigned long)lbl); } /* used for fields */ static inline void cgen_ident_simple(CGenerator *g, Identifier i) { cgen_indent(g); fprint_ident_reduced_charset(cgen_writing_to(g), i); } static void cgen_ident(CGenerator *g, Identifier i) { if (i->nms) { cgen_write(g, "%s", i->nms->c.prefix); } if (i == g->main_ident && i->decl_kind == IDECL_DECL && ident_scope(i) == NULL) { /* don't conflict with C's main! */ cgen_write(g, "main_"); } else { cgen_ident_simple(g, i); } } #define CGEN_IDENT_ID_STR_SIZE 32 /* buffer should be at least CGEN_IDENT_ID_STR_SIZE bytes */ static inline void cgen_ident_id_to_str(char *buffer, IdentID id) { snprintf(buffer, CGEN_IDENT_ID_STR_SIZE, "a%lu_", (unsigned long)id); } static inline void cgen_writeln(CGenerator *g, const char *fmt, ...) { va_list args; cgen_indent(g); va_start(args, fmt); vfprintf(cgen_writing_to(g), fmt, args); va_end(args); cgen_nl(g); } /* should this declaration be a direct function declaration C? (as opposed to using a function pointer or not being a function) */ static bool cgen_fn_is_direct(CGenerator *g, Declaration *d) { return g->fn == NULL && (d->flags & DECL_HAS_EXPR) && d->expr.kind == EXPR_FN && arr_len(d->idents) == 1; } static bool fn_has_instances(FnExpr *f) { if (fn_has_any_const_params(f)) return true; if (!arr_len(f->params)) return false; return type_is_builtin(&((Declaration *)arr_last(f->params))->type, BUILTIN_VARARGS); } static bool cgen_uses_ptr(Type *t) { assert(t->flags & TYPE_IS_RESOLVED); switch (t->kind) { case TYPE_TUPLE: case TYPE_STRUCT: case TYPE_ARR: return true; case TYPE_BUILTIN: case TYPE_PTR: case TYPE_FN: case TYPE_SLICE: case TYPE_VOID: case TYPE_UNKNOWN: return false; case TYPE_EXPR: break; } assert(0); return false; } static void cgen_struct_name(CGenerator *g, StructDef *sdef) { if (sdef->name) { cgen_ident(g, sdef->name); } else { assert(sdef->c.id); cgen_ident_id(g, sdef->c.id); } if (sdef->instance_id) { possibly_static_assert(sizeof sdef->instance_id == 8); cgen_write(g, U64_FMT "_", sdef->instance_id); } } static void cgen_type_pre(CGenerator *g, Type *t) { assert(t->flags & TYPE_IS_RESOLVED); switch (t->kind) { case TYPE_BUILTIN: switch (t->builtin) { case BUILTIN_I8: cgen_write(g, "i8"); break; case BUILTIN_I16: cgen_write(g, "i16"); break; case BUILTIN_I32: cgen_write(g, "i32"); break; case BUILTIN_I64: cgen_write(g, "i64"); break; case BUILTIN_U8: cgen_write(g, "u8"); break; case BUILTIN_U16: cgen_write(g, "u16"); break; case BUILTIN_U32: cgen_write(g, "u32"); break; case BUILTIN_U64: cgen_write(g, "u64"); break; case BUILTIN_CHAR: cgen_write(g, "char"); break; case BUILTIN_BOOL: cgen_write(g, "bool"); break; case BUILTIN_F32: cgen_write(g, "f32"); break; case BUILTIN_F64: cgen_write(g, "f64"); break; case BUILTIN_NMS: case BUILTIN_TYPE: case BUILTIN_VARARGS: assert(0); break; } break; case TYPE_PTR: if (t->ptr->kind == TYPE_UNKNOWN) cgen_write(g, "void"); /* #C &"foo", for example */ else cgen_type_pre(g, t->ptr); cgen_write(g, "(*"); break; case TYPE_ARR: cgen_type_pre(g, t->arr.of); cgen_write(g, "("); break; case TYPE_FN: if (cgen_uses_ptr(&t->fn.types[0])) { cgen_write(g, "void"); } else { cgen_type_pre(g, &t->fn.types[0]); } cgen_write(g, " (*"); break; case TYPE_SLICE: cgen_write(g, "slice_"); break; case TYPE_VOID: cgen_write(g, "void"); break; case TYPE_STRUCT: cgen_write(g, "struct "); cgen_struct_name(g, t->struc); break; case TYPE_TUPLE: case TYPE_EXPR: case TYPE_UNKNOWN: /* We should never try to generate this type */ assert(0); break; } } static void cgen_type_post(CGenerator *g, Type *t) { assert(t->flags & TYPE_IS_RESOLVED); switch (t->kind) { case TYPE_PTR: cgen_write(g, ")"); cgen_type_post(g, t->ptr); break; case TYPE_ARR: assert(t->flags & TYPE_IS_RESOLVED); cgen_write(g, "[%lu])", (unsigned long)t->arr.n); cgen_type_post(g, t->arr.of); break; case TYPE_FN: { bool out_param = cgen_uses_ptr(&t->fn.types[0]); cgen_write(g, ")("); for (size_t i = 1; i < arr_len(t->fn.types); ++i) { if (i != 1) cgen_write(g, ", "); cgen_type_pre(g, &t->fn.types[i]); if (cgen_uses_ptr(&t->fn.types[i])) cgen_write(g, "(*)"); cgen_type_post(g, &t->fn.types[i]); } if (out_param) { Type *ret_type = &t->fn.types[0]; if (arr_len(t->fn.types) > 1) cgen_write(g, ", "); if (ret_type->kind == TYPE_TUPLE) { arr_foreach(ret_type->tuple, Type, x) { cgen_type_pre(g, x); cgen_write(g, "(*)"); cgen_type_post(g, x); if (x != arr_last(ret_type->tuple)) { cgen_write(g, ", "); } } } else { cgen_type_pre(g, ret_type); cgen_write(g, "(*)"); cgen_type_post(g, ret_type); } } if (arr_len(t->fn.types) == 1 && !out_param) cgen_write(g, "void"); cgen_write(g, ")"); if (!out_param) cgen_type_post(g, &t->fn.types[0]); } break; case TYPE_BUILTIN: case TYPE_VOID: case TYPE_UNKNOWN: case TYPE_TUPLE: case TYPE_SLICE: case TYPE_STRUCT: break; case TYPE_EXPR: assert(0); break; } } static void cgen_ctype(CGenerator *g, CType *c) { if (c->kind & CTYPE_UNSIGNED) { c->kind &= (CTypeKind)~(CTypeKind)CTYPE_UNSIGNED; cgen_write(g, "unsigned "); } switch (c->kind) { case CTYPE_CHAR: cgen_write(g, "char"); break; case CTYPE_SIGNED_CHAR: cgen_write(g, "signed char"); break; case CTYPE_SHORT: cgen_write(g, "short"); break; case CTYPE_INT: cgen_write(g, "int"); break; case CTYPE_LONG: cgen_write(g, "long"); break; case CTYPE_LONGLONG: cgen_write(g, "long long"); break; case CTYPE_PTR: cgen_write(g, "%s *", c->points_to); break; case CTYPE_FLOAT: cgen_write(g, "float"); break; case CTYPE_DOUBLE: cgen_write(g, "double"); break; case CTYPE_SIZE_T: cgen_write(g, "size_t"); break; case CTYPE_VARARGS: cgen_write(g, "..."); break; default: assert(0); break; } } static inline void cgen_fn_name(CGenerator *g, FnExpr *f) { if (f->c.name) { cgen_ident(g, f->c.name); } else { cgen_ident_id(g, f->c.id); } } static inline void cgen_fn_instance_number(CGenerator *g, U64 instance) { cgen_write(g, U64_FMT "_", instance); } /* should we generate this function? (or is it just meant for compile time) */ static bool cgen_should_gen_fn(FnExpr *f) { if (f->flags & FN_EXPR_FOREIGN) return true; else if (f->ret_decls) { arr_foreach(f->ret_decls, Declaration, decl) if (type_is_compileonly(&decl->type)) return false; return true; } else { return !type_is_compileonly(&f->ret_type); } } static void cgen_full_fn_name(CGenerator *g, FnExpr *f) { cgen_fn_name(g, f); if (f->instance_id) { cgen_fn_instance_number(g, f->instance_id); } } static void cgen_val_ptr_pre(CGenerator *g, void *v, Type *t) { assert(t->flags & TYPE_IS_RESOLVED); switch (t->kind) { case TYPE_SLICE: { Slice *s = (Slice *)v; for (I64 i = 0; i < s->n; ++i) { cgen_val_ptr_pre(g, (char *)s->data + (U64)i * compiler_sizeof(t->slice), t->slice); } cgen_type_pre(g, t->slice); cgen_write(g, "(d%p_[])", v); /* TODO: improve this somehow? */ cgen_type_post(g, t->slice); cgen_write(g, " = {"); for (I64 i = 0; i < s->n; ++i) { if (i) cgen_write(g, ", "); cgen_val_ptr(g, (char *)s->data + (U64)i * compiler_sizeof(t->slice), t->slice); } cgen_write(g, "};"); cgen_nl(g); } break; case TYPE_ARR: for (size_t i = 0; i < t->arr.n; ++i) { cgen_val_ptr_pre(g, (char *)*(void **)v + i * compiler_sizeof(t->arr.of), t->arr.of); } break; case TYPE_FN: case TYPE_UNKNOWN: case TYPE_TUPLE: case TYPE_VOID: case TYPE_BUILTIN: case TYPE_PTR: case TYPE_STRUCT: break; case TYPE_EXPR: assert(0); break; } } /* generate a value from a pointer */ static void cgen_val_ptr(CGenerator *g, void *v, Type *t) { assert(t->flags & TYPE_IS_RESOLVED); switch (t->kind) { case TYPE_TUPLE: case TYPE_VOID: case TYPE_EXPR: case TYPE_UNKNOWN: assert(0); return; case TYPE_ARR: cgen_write(g, "{"); for (size_t i = 0; i < t->arr.n; ++i) { if (i) cgen_write(g, ", "); cgen_val_ptr(g, (char *)v + i * compiler_sizeof(t->arr.of), t->arr.of); } cgen_write(g, "}"); break; case TYPE_SLICE: cgen_write(g, "{d%p_, %lu}", v, ((Slice *)v)->n); break; case TYPE_STRUCT: cgen_write(g, "{"); arr_foreach(t->struc->fields, Field, f) { if (f != t->struc->fields) cgen_write(g, ", "); cgen_val_ptr(g, (char *)v + f->offset, f->type); } cgen_write(g, "}"); break; case TYPE_FN: cgen_fn_name(g, *(FnExpr **)v); break; case TYPE_PTR: /* You can't have a constant pointer. */ assert(0); break; case TYPE_BUILTIN: switch (t->builtin) { case BUILTIN_I8: cgen_write(g, I8_FMT, *(I8 *)v); break; case BUILTIN_U8: cgen_write(g, U8_FMT, *(U8 *)v); break; case BUILTIN_I16: cgen_write(g, I16_FMT, *(I16 *)v); break; case BUILTIN_U16: cgen_write(g, U16_FMT, *(U16 *)v); break; case BUILTIN_I32: cgen_write(g, I32_FMT, *(I32 *)v); break; case BUILTIN_U32: cgen_write(g, U32_FMT, *(U32 *)v); break; case BUILTIN_I64: cgen_write(g, I64_FMT, *(I64 *)v); break; case BUILTIN_U64: cgen_write(g, U64_FMT, *(U64 *)v); break; case BUILTIN_F32: cgen_write(g, F32_FMT "f", *(F32 *)v); break; case BUILTIN_F64: cgen_write(g, F64_FMT, *(F64 *)v); break; case BUILTIN_CHAR: cgen_write(g, "'\\x%02x'", *(char *)v); break; case BUILTIN_BOOL: cgen_write(g, "%s", *(bool *)v ? "true" : "false"); break; case BUILTIN_TYPE: case BUILTIN_NMS: case BUILTIN_VARARGS: assert(0); break; } break; } } static void cgen_val_pre(CGenerator *g, Value *v, Type *t) { cgen_val_ptr_pre(g, val_get_ptr(v, t), t); } /* generates a value fit for use as an initializer */ static void cgen_val(CGenerator *g, Value *v, Type *t) { cgen_val_ptr(g, val_get_ptr(v, t), t); } /* can the value generated by cgen_val for this type be used directly (as opposed to being stored in a variable)? */ static inline bool cgen_is_type_simple(Type *t) { return t->kind == TYPE_BUILTIN || t->kind == TYPE_FN; } static void cgen_fn_params(CGenerator *g, FnExpr *f, U64 which_are_const) { bool out_param = cgen_uses_ptr(&f->ret_type); cgen_write(g, "("); int semi_const_idx = 0; bool any_params = false; arr_foreach(f->params, Declaration, d) { if (d->flags & DECL_IS_CONST) continue; if (type_is_builtin(&d->type, BUILTIN_VARARGS)) { int idx = 0; arr_foreach(d->val.varargs, VarArg, varg) { if (any_params) cgen_write(g, ", "); any_params = true; cgen_type_pre(g, varg->type); cgen_write(g, " "); cgen_ident_simple(g, d->idents[0]); cgen_write(g, "%d_", idx); cgen_type_post(g, varg->type); ++idx; } } else if ((d->flags & DECL_SEMI_CONST) && (which_are_const & (((U64)1) << semi_const_idx++))) { /* semi constant argument is constant */ } else { int idx = 0; arr_foreach(d->idents, Identifier, i) { if (any_params) cgen_write(g, ", "); any_params = true; Type *type = d->type.kind == TYPE_TUPLE ? &d->type.tuple[idx++] : &d->type; cgen_type_pre(g, type); cgen_write(g, " "); cgen_ident_simple(g, *i); cgen_type_post(g, type); } } } if (out_param) { if (f->ret_type.kind == TYPE_TUPLE) { /* multiple return variables */ for (size_t i = 0; i < arr_len(f->ret_type.tuple); ++i) { Type *x = &f->ret_type.tuple[i]; if (any_params || i > 0) cgen_write(g, ", "); cgen_type_pre(g, x); cgen_write(g, "(*ret__%lu)", (unsigned long)i); cgen_type_post(g, x); } } else { if (any_params) cgen_write(g, ", "); cgen_type_pre(g, &f->ret_type); cgen_write(g, " (*ret__)"); cgen_type_post(g, &f->ret_type); } any_params = true; } if (!any_params) cgen_write(g, "void"); cgen_write(g, ")"); } static inline void cgen_arg_pre(CGenerator *g, Expression *arg) { cgen_expr_pre(g, arg); if (arg->type.kind == TYPE_ARR) { /* create copy of array */ IdentID copy = ++g->ident_counter; cgen_type_pre(g, &arg->type); char s[CGEN_IDENT_ID_STR_SIZE]; cgen_ident_id_to_str(s, copy); cgen_write(g, " %s", s); cgen_type_post(g, &arg->type); cgen_write(g, "; "); cgen_set(g, NULL, s, arg, NULL); arg->cgen.id = copy; } } static inline void cgen_arg(CGenerator *g, Expression *arg) { if (arg->type.kind == TYPE_ARR) { cgen_ident_id(g, arg->cgen.id); } else { cgen_expr(g, arg); } } /* unless f has const/semi-const args, which_are_const can be set to 0 */ static void cgen_fn_header(CGenerator *g, FnExpr *f, U64 which_are_const) { assert(!(f->flags & FN_EXPR_FOREIGN)); bool out_param = cgen_uses_ptr(&f->ret_type); assert(cgen_should_gen_fn(f)); if (!(f->flags & FN_EXPR_EXPORT)) cgen_write(g, "static "); if (out_param) { cgen_write(g, "void "); } else { cgen_type_pre(g, &f->ret_type); cgen_write(g, " "); } cgen_full_fn_name(g, f); cgen_fn_params(g, f, which_are_const); if (!out_param) { cgen_type_post(g, &f->ret_type); } } static inline void cgen_deferred_from_block(CGenerator *g, Block *from) { arr_foreach(from->deferred, StatementPtr, s) { cgen_stmt(g, *s); } } /* generates deferred statements in g->block, g->block->parent, ..., to) */ static inline void cgen_deferred_up_to(CGenerator *g, Block *to) { for (Block *b = g->block; b; b = b == to ? NULL : b->parent) { cgen_deferred_from_block(g, b); } } /* same as cgen_deferred_up_to but doesn't generate to->deferred */ static inline void cgen_deferred_up_to_not_including(CGenerator *g, Block *to) { for (Block *b = g->block; b != to; b = b->parent) cgen_deferred_from_block(g, b); } /* Either set_expr or set_str should be NULL and either to_expr or to_str should be NULL Also, set_str and/or to_str should be NULL this DOES NOT call cgen_expr_pre for set_expr or to_expr */ static void cgen_set(CGenerator *g, Expression *set_expr, const char *set_str, Expression *to_expr, const char *to_str) { Type *type; if (set_expr) { type = &set_expr->type; } else { assert(to_expr); type = &to_expr->type; } switch (type->kind) { case TYPE_BUILTIN: case TYPE_FN: case TYPE_PTR: case TYPE_SLICE: case TYPE_STRUCT: case TYPE_UNKNOWN: if (set_expr) { cgen_expr(g, set_expr); } else { cgen_write(g, set_str); } cgen_write(g, " = "); if (to_expr) { cgen_expr(g, to_expr); } else { cgen_write(g, to_str); } cgen_write(g, ";"); break; case TYPE_ARR: cgen_write(g, "{"); cgen_nl(g); cgen_write(g, "size_t i;"); cgen_type_pre(g, type->arr.of); cgen_write(g, "(*arr__in)"); cgen_type_post(g, type->arr.of); cgen_write(g, " = "); if (to_expr) { cgen_expr(g, to_expr); } else { cgen_write(g, to_str); } cgen_write(g, "; "); cgen_type_pre(g, type->arr.of); cgen_write(g, "(*arr__out)"); cgen_type_post(g, type->arr.of); cgen_write(g, " = "); if (set_expr) { cgen_expr(g, set_expr); } else { cgen_write(g, set_str); } cgen_write(g, ";"); cgen_nl(g); cgen_write(g, "for (i = 0; i < %lu; ++i) arr__out[i] = arr__in[i];", (unsigned long)type->arr.n); cgen_nl(g); cgen_write(g, "}"); break; case TYPE_TUPLE: assert(set_expr); assert(to_expr); assert(set_expr->kind == EXPR_TUPLE); cgen_set_tuple(g, set_expr->tuple, NULL, NULL, to_expr); break; case TYPE_VOID: case TYPE_EXPR: assert(0); break; } } /* one of exprs, idents, and prefix should be NULL. does NOT call cgen_expr_pre for to/exprs */ static void cgen_set_tuple(CGenerator *g, Expression *exprs, Identifier *idents, const char *prefix, Expression *to) { switch (to->kind) { case EXPR_VAL: assert(0); /* never needed at the moment */ break; case EXPR_TUPLE: /* e.g. a, b = 3, 5; */ if (exprs) { for (size_t i = 0; i < arr_len(to->tuple); ++i) { cgen_expr_pre(g, &exprs[i]); } } for (size_t i = 0; i < arr_len(to->tuple); ++i) { char *s = NULL, buf[64]; Expression *e = NULL; if (idents) s = cgen_ident_to_str(idents[i]); else if (exprs) e = &exprs[i]; else { snprintf(buf, sizeof buf, "(%s%lu)", prefix, (unsigned long)i); s = buf; } cgen_set(g, e, s, &to->tuple[i], NULL); if (s != buf) free(s); } break; case EXPR_CALL: { FnType *fn_type = &to->call.fn->type.fn; Type *ret_type = &fn_type->types[0]; Constness *constness = fn_type->constness; int i = 0; IdentID *underscore_ids = NULL; int nout_params = (int)(exprs ? arr_len(exprs) : arr_len(idents)); if (idents) { for (i = 0; i < nout_params; ++i) { if (ident_eq_str(idents[i], "_")) { Type *type = &ret_type->tuple[i]; IdentID id = ++g->ident_counter; cgen_type_pre(g, type); cgen_write(g, " "); cgen_ident_id(g, id); cgen_type_post(g, type); cgen_write(g, "; "); *(IdentID *)arr_add(&underscore_ids) = id; } } } /* e.g. a, b = fn_which_returns_tuple(); */ arr_foreach(to->call.arg_exprs, Expression, arg) { if (!constness || !arg_is_const(arg, constness[i])) { cgen_arg_pre(g, arg); } } cgen_expr_pre(g, to->call.fn); cgen_expr(g, to->call.fn); if (to->call.instance) cgen_fn_instance_number(g, to->call.instance->fn->instance_id); cgen_write(g, "("); bool any_args = false; i = 0; arr_foreach(to->call.arg_exprs, Expression, arg) { if (!constness || !arg_is_const(arg, constness[i])) { if (any_args) cgen_write(g, ", "); any_args = true; cgen_arg(g, arg); } ++i; } /* out params */ IdentID *u = underscore_ids; for (i = 0; i < (int)nout_params; ++i) { if (any_args || i > 0) cgen_write(g, ", "); if (exprs) { cgen_write(g, "&"); cgen_expr(g, &exprs[i]); } else if (idents) { cgen_write(g, "&"); if (ident_eq_str(idents[i], "_")) cgen_ident_id(g, *u++); else cgen_ident(g, idents[i]); } else { cgen_write(g, "&(%s%d_)", prefix, i); } } arr_clear(&underscore_ids); cgen_writeln(g, "); "); } break; case EXPR_IF: case EXPR_BLOCK: { IdentID prefix_id = to->cgen.id = ++g->ident_counter; if (exprs) { for (size_t i = 0; i < arr_len(to->type.tuple); ++i) { cgen_expr_pre(g, &exprs[i]); } } for (unsigned long i = 0; i < (unsigned long)arr_len(to->type.tuple); ++i) { cgen_write(g, "("); if (exprs) { cgen_expr(g, &exprs[i]); } else if (idents) { cgen_ident(g, idents[i]); } else { cgen_write(g, "%s%lu", prefix, i); } cgen_write(g, ") = "); cgen_ident_id(g, prefix_id); cgen_write(g, "%lu", i); cgen_write(g, "; "); } } break; /* things which can never be tuples */ case EXPR_SLICE: case EXPR_IDENT: case EXPR_WHILE: case EXPR_FOR: case EXPR_LITERAL_INT: case EXPR_LITERAL_CHAR: case EXPR_LITERAL_BOOL: case EXPR_LITERAL_STR: case EXPR_LITERAL_FLOAT: case EXPR_UNARY_OP: case EXPR_BINARY_OP: case EXPR_FN: case EXPR_CAST: case EXPR_C: case EXPR_BUILTIN: case EXPR_TYPE: case EXPR_NMS: assert(0); break; } } static void cgen_expr_pre(CGenerator *g, Expression *e) { IdentID id = 0; char ret_name[CGEN_IDENT_ID_STR_SIZE+20]; switch (e->kind) { case EXPR_IF: case EXPR_BLOCK: { id = ++g->ident_counter; cgen_ident_id_to_str(ret_name, id); char *p = ret_name + strlen(ret_name); if (e->type.kind != TYPE_VOID) { if (e->type.kind == TYPE_TUPLE) { for (unsigned long i = 0; i < arr_len(e->type.tuple); ++i) { sprintf(p, "%lu", i); cgen_type_pre(g, &e->type.tuple[i]); cgen_write(g, " %s", ret_name); cgen_type_post(g, &e->type.tuple[i]); cgen_write(g, "; "); } } else { cgen_type_pre(g, &e->type); cgen_write(g, " %s", ret_name); cgen_type_post(g, &e->type); cgen_write(g, ";"); cgen_nl(g); } } *p = 0; /* clear tuple suffixes */ } break; default: break; } switch (e->kind) { case EXPR_IF: { IfExpr *curr = e->if_; e->cgen.id = id; while (1) { if (curr->cond) { cgen_write(g, "if ("); cgen_expr(g, curr->cond); cgen_write(g, ") "); } cgen_block(g, &curr->body, ret_name, 0); if (curr->next_elif) { cgen_write(g, " else "); curr = curr->next_elif->if_; } else break; } } break; case EXPR_BLOCK: e->cgen.id = id; cgen_block(g, e->block, ret_name, 0); break; case EXPR_CALL: { cgen_expr_pre(g, e->call.fn); size_t i = 0; Constness *constness = e->call.fn->type.fn.constness; size_t nparams = arr_len(e->call.fn->type.fn.types)-1; arr_foreach(e->call.arg_exprs, Expression, arg) { if (!constness || !arg_is_const(arg, constness[i])) { cgen_arg_pre(g, arg); } if (i < nparams-1) /* necessary for varargs */ ++i; } if (e->type.kind == TYPE_TUPLE) { Type *t = &e->type; size_t ntypes = arr_len(t->tuple); IdentID *ids = err_malloc(ntypes * sizeof *ids); for (i = 0; i < ntypes; ++i) { ids[i] = ++g->ident_counter; cgen_type_pre(g, &t->tuple[i]); cgen_write(g, " "); cgen_ident_id(g, ids[i]); cgen_type_post(g, &t->tuple[i]); cgen_write(g, "; "); } cgen_expr(g, e->call.fn); if (e->call.instance) { cgen_fn_instance_number(g, e->call.instance->fn->instance_id); } cgen_write(g, "("); bool any_args = false; i = 0; arr_foreach(e->call.arg_exprs, Expression, arg) { if (!constness || !arg_is_const(arg, constness[i])) { if (any_args) cgen_write(g, ", "); any_args = true; cgen_arg(g, arg); } ++i; } for (i = 0; i < ntypes; ++i) { if (any_args) cgen_write(g, ", "); any_args = true; cgen_write(g, "&"); cgen_ident_id(g, ids[i]); } cgen_write(g, ");"); } else if (cgen_uses_ptr(&e->type)) { e->cgen.id = id = ++g->ident_counter; cgen_type_pre(g, &e->type); cgen_write(g, " "); cgen_ident_id(g, id); cgen_type_post(g, &e->type); cgen_write(g, ";"); cgen_nl(g); cgen_expr(g, e->call.fn); if (e->call.instance) { cgen_fn_instance_number(g, e->call.instance->fn->instance_id); } cgen_write(g, "("); bool any_args = false; i = 0; arr_foreach(e->call.arg_exprs, Expression, arg) { if (!constness || !arg_is_const(arg, constness[i])) { if (any_args) cgen_write(g, ", "); any_args = true; cgen_arg(g, arg); } ++i; } if (any_args) { cgen_write(g, ", "); } cgen_write(g, "&"); cgen_ident_id(g, e->cgen.id); cgen_write(g, ");"); cgen_nl(g); } } break; case EXPR_UNARY_OP: cgen_expr_pre(g, e->unary.of); break; case EXPR_BINARY_OP: cgen_expr_pre(g, e->binary.lhs); if (e->binary.op != BINARY_DOT) cgen_expr_pre(g, e->binary.rhs); break; case EXPR_CAST: cgen_expr_pre(g, e->cast.expr); break; case EXPR_SLICE: { SliceExpr *s = &e->slice; IdentID s_id = e->slice.c.id = ++g->ident_counter; IdentID from_id = ++g->ident_counter; cgen_expr_pre(g, s->of); if (s->from) cgen_expr_pre(g, s->from); if (s->to) cgen_expr_pre(g, s->to); cgen_write(g, "slice_ "); cgen_ident_id(g, s_id); cgen_write(g, "; { slice_ of__ = "); if (s->of->type.kind == TYPE_SLICE) { cgen_expr(g, s->of); } else { assert(s->of->type.kind == TYPE_ARR); cgen_write(g, "mkslice_("); cgen_expr(g, s->of); cgen_write(g, ", " U64_FMT, s->of->type.arr.n); cgen_write(g, ")"); } cgen_write(g, "; i64 "); cgen_ident_id(g, from_id); cgen_write(g, " = "); if (s->from) { cgen_expr(g, s->from); } else { cgen_write(g, "0"); } cgen_write(g, "; "); cgen_ident_id(g, s_id); cgen_write(g, ".data = ("); cgen_type_pre(g, e->type.slice); cgen_write(g, "(*)"); cgen_type_post(g, e->type.slice); cgen_write(g, ")(of__"); cgen_write(g, ".data"); cgen_write(g, ") + "); cgen_ident_id(g, from_id); cgen_write(g, "; "); cgen_ident_id(g, s_id); cgen_write(g, ".n = "); if (s->to) { cgen_expr(g, s->to); } else { cgen_write(g, "of__.n"); } cgen_write(g, " - "); cgen_ident_id(g, from_id); cgen_write(g, "; }"); cgen_nl(g); } break; case EXPR_VAL: /* TODO: don't make a variable for this if it's not needed */ if (type_is_compileonly(&e->type)) break; if (!cgen_is_type_simple(&e->type)) { cgen_val_pre(g, &e->val, &e->type); cgen_type_pre(g, &e->type); e->cgen.id = ++g->ident_counter; cgen_write(g, " "); cgen_ident_id(g, e->cgen.id); cgen_type_post(g, &e->type); cgen_write(g, " = "); cgen_val(g, &e->val, &e->type); cgen_writeln(g, ";"); } break; case EXPR_TUPLE: arr_foreach(e->tuple, Expression, x) cgen_expr_pre(g, x); break; case EXPR_BUILTIN: switch (e->builtin.which.val) { case BUILTIN_STDOUT: cgen_write(g, "extern void *stdout;"); cgen_nl(g); break; case BUILTIN_STDERR: cgen_write(g, "extern void *stderr;"); cgen_nl(g); break; case BUILTIN_STDIN: cgen_write(g, "extern void *stdin;"); cgen_nl(g); break; default: break; } break; case EXPR_LITERAL_INT: case EXPR_LITERAL_FLOAT: case EXPR_LITERAL_BOOL: case EXPR_LITERAL_CHAR: case EXPR_LITERAL_STR: case EXPR_IDENT: case EXPR_FN: case EXPR_C: case EXPR_TYPE: case EXPR_NMS: case EXPR_FOR: case EXPR_WHILE: break; } } static void cgen_expr(CGenerator *g, Expression *e) { assert(e->flags & EXPR_FOUND_TYPE); switch (e->kind) { case EXPR_LITERAL_FLOAT: cgen_write(g, "%.16Lf", (long double)e->floatl); break; case EXPR_LITERAL_INT: cgen_write(g, U64_FMT, e->intl); break; case EXPR_LITERAL_STR: { char *p = e->strl.str; cgen_write(g, "mkslice_(\""); for (size_t i = 0; i < e->strl.len; ++i, ++p) { if (isprint(*p) && *p != '"') cgen_write(g, "%c", *p); else cgen_write(g, "\\x%02x", *p); } cgen_write(g, "\", %lu)", (unsigned long)e->strl.len); } break; case EXPR_LITERAL_BOOL: cgen_write(g, e->booll ? "true" : "false"); break; case EXPR_LITERAL_CHAR: cgen_write(g, "((char)%d)", e->charl); break; case EXPR_IDENT: { bool handled = false; if (e->type.kind == TYPE_FN) { /* generate the right function name, because it might be anonymous */ Identifier i = e->ident; if (i->decl_kind == IDECL_DECL) { Declaration *d = i->decl; if (d->flags & DECL_IS_CONST) { int index = decl_ident_index(d, i); Value fn_val = *decl_val_at_index(d, index); FnExpr *fn = fn_val.fn; Expression fn_expr; /* TODO: is this all really necessary? */ fn_expr.kind = EXPR_FN; fn_expr.fn = allocr_malloc(g->allocr, sizeof *fn_expr.fn); *fn_expr.fn = *fn; fn_expr.flags = EXPR_FOUND_TYPE; fn_expr.type = *decl_type_at_index(d, index); cgen_expr(g, &fn_expr); handled = true; } } } if (!handled) { cgen_ident(g, e->ident); } } break; case EXPR_BINARY_OP: { const char *s = ""; Expression *lhs = e->binary.lhs, *rhs = e->binary.rhs; bool handled = false; switch (e->binary.op) { case BINARY_SUB: s = "-"; break; case BINARY_ADD: s = "+"; break; case BINARY_MUL: s = "*"; break; case BINARY_DIV: s = "/"; break; case BINARY_MOD: s = "%"; break; case BINARY_SET: cgen_set(g, lhs, NULL, rhs, NULL); handled = true; break; case BINARY_GT: s = ">"; break; case BINARY_LT: s = "<"; break; case BINARY_GE: s = ">="; break; case BINARY_LE: s = "<="; break; case BINARY_EQ: s = "=="; break; case BINARY_NE: s = "!="; break; case BINARY_SET_ADD: s = "+="; break; case BINARY_SET_SUB: s = "-="; break; case BINARY_SET_MUL: s = "*="; break; case BINARY_SET_DIV: s = "/="; break; case BINARY_SET_MOD: s = "%="; break; case BINARY_AT_INDEX: { Type *lhs_type = &lhs->type; cgen_write(g, "("); switch (lhs_type->kind) { case TYPE_ARR: cgen_expr(g, lhs); cgen_write(g, "["); cgen_expr(g, rhs); cgen_write(g, "]"); break; case TYPE_SLICE: cgen_write(g, "(("); cgen_type_pre(g, &e->type); cgen_write(g, "(*)"); cgen_type_post(g, &e->type); cgen_write(g, ")("); cgen_expr(g, lhs); cgen_write(g, ".data))["); cgen_expr(g, rhs); cgen_write(g, "]"); break; case TYPE_BUILTIN: if (lhs_type->builtin == BUILTIN_VARARGS) { assert(lhs->kind == EXPR_IDENT); assert(rhs->kind == EXPR_VAL); assert(type_is_builtin(&rhs->type, BUILTIN_I64)); I64 i = rhs->val.i64; cgen_ident(g, lhs->ident); cgen_write(g, I64_FMT "_", i); } else assert(0); break; default: assert(0); break; } cgen_write(g, ")"); handled = true; } break; case BINARY_DOT: { Type *struct_type = &lhs->type; if (struct_type->kind == TYPE_PTR) struct_type = struct_type->ptr; if (struct_type->kind == TYPE_STRUCT) { cgen_write(g, "("); cgen_expr(g, lhs); bool is_ptr = lhs->type.kind == TYPE_PTR; cgen_write(g, is_ptr ? "->" :"."); cgen_ident_simple(g, e->binary.dot.field->name); cgen_write(g, ")"); } else if (struct_type->kind == TYPE_SLICE) { /* access slice data */ cgen_expr(g, lhs); bool is_ptr = lhs->type.kind == TYPE_PTR; cgen_write(g, is_ptr ? "->" :"."); cgen_write(g, "data"); } else { assert(type_is_builtin(struct_type, BUILTIN_NMS)); char *prefix = lhs->val.nms->c.prefix; cgen_write(g, "%s", prefix); cgen_ident_simple(g, rhs->ident); } handled = true; } break; } if (handled) break; cgen_write(g, "("); cgen_expr(g, lhs); cgen_write(g, "%s", s); cgen_expr(g, rhs); cgen_write(g, ")"); } break; case EXPR_UNARY_OP: { const char *s = ""; bool handled = false; Type *of_type = &e->unary.of->type; switch (e->unary.op) { case UNARY_MINUS: s = "-"; break; case UNARY_DEREF: s = "*"; break; case UNARY_ADDRESS: s = "&"; break; case UNARY_NOT: s = "!"; break; case UNARY_SIZEOF: case UNARY_ALIGNOF: cgen_write(g, "%s(", e->unary.op == UNARY_SIZEOF ? "sizeof" : "_Alignof"); assert(e->unary.of->kind == EXPR_VAL); cgen_type_pre(g, e->unary.of->val.type); cgen_type_post(g, e->unary.of->val.type); cgen_write(g, ")"); handled = true; break; case UNARY_LEN: { bool is_ptr = of_type->kind == TYPE_PTR; if (is_ptr) { of_type = of_type->ptr; } switch (of_type->kind) { case TYPE_SLICE: cgen_expr(g, e->unary.of); cgen_write(g, "%sn", is_ptr ? "->" : "."); break; case TYPE_ARR: cgen_write(g, "%lu", (unsigned long)of_type->arr.n); break; default: assert(0); break; } handled = true; } break; case UNARY_TYPEOF: case UNARY_DSIZEOF: case UNARY_DALIGNOF: assert(0); return; } if (handled) break; cgen_write(g, "("); cgen_write(g, "%s", s); cgen_expr(g, e->unary.of); cgen_write(g, ")"); } break; case EXPR_WHILE: { WhileExpr *w = e->while_; cgen_write(g, "while ("); if (w->cond) { cgen_expr(g, w->cond); } else { cgen_write(g, "true"); } cgen_write(g, ") "); cgen_block(g, &w->body, NULL, 0); } break; case EXPR_FOR: { ForExpr *fo = e->for_; int is_range = fo->flags & FOR_IS_RANGE; if (is_range) { cgen_expr_pre(g, fo->range.from); if (fo->range.to) cgen_expr_pre(g, fo->range.to); } else { cgen_expr_pre(g, fo->of); } cgen_write(g, "{"); if (is_range) { if (fo->range.to) { /* pre generate to */ cgen_type_pre(g, &fo->type); cgen_write(g, " to_"); cgen_type_post(g, &fo->type); cgen_write(g, " = "); cgen_expr(g, fo->range.to); cgen_write(g, "; "); } /* set value to from */ if (fo->value) { cgen_type_pre(g, &fo->type); cgen_write(g, " "); cgen_ident(g, fo->value); cgen_type_post(g, &fo->type); cgen_write(g, "; "); Expression val_expr; val_expr.flags = EXPR_FOUND_TYPE; val_expr.kind = EXPR_IDENT; val_expr.ident = fo->value; val_expr.type = fo->type; cgen_set(g, &val_expr, NULL, fo->range.from, NULL); } else { cgen_type_pre(g, &fo->type); cgen_write(g, " val_"); cgen_type_post(g, &fo->type); cgen_write(g, "; "); cgen_set(g, NULL, "val_", fo->range.from, NULL); } } else { /* pre-generate of */ cgen_type_pre(g, &fo->of->type); cgen_write(g, " of_"); cgen_type_post(g, &fo->of->type); cgen_write(g, "; "); cgen_set(g, NULL, "of_", fo->of, NULL); } cgen_write(g, "for ("); if (fo->index || !is_range) { cgen_write(g, "i64 "); if (fo->index) cgen_ident(g, fo->index); else cgen_write(g, "i_"); cgen_write(g, " = 0"); } cgen_write(g, "; "); bool uses_ptr = false; Type *of_type = NULL; if (!(is_range && !fo->range.to)) { /* if it's finite */ if (is_range) { if (fo->value) cgen_ident(g, fo->value); else cgen_write(g, "val_"); bool positive_step = fo->range.stepval == NULL || val_is_nonnegative(*fo->range.stepval, &fo->type); cgen_write(g, " %c= to_", positive_step ? '<' : '>'); } else { if (fo->index) cgen_ident(g, fo->index); else cgen_write(g, "i_"); cgen_write(g, " < "); of_type = &fo->of->type; uses_ptr = of_type->kind == TYPE_PTR; if (uses_ptr) { of_type = of_type->ptr; } switch (of_type->kind) { case TYPE_ARR: cgen_write(g, "%lu", (unsigned long)of_type->arr.n); break; case TYPE_SLICE: cgen_write(g, "of_%sn", uses_ptr ? "->" : "."); break; default: assert(0); break; } } } cgen_write(g, "; "); if (is_range) { if (fo->range.stepval) { cgen_val_pre(g, fo->range.stepval, &fo->type); } if (fo->value) cgen_ident(g, fo->value); else cgen_write(g, "val_"); cgen_write(g, " += "); if (fo->range.stepval) { cgen_val(g, fo->range.stepval, &fo->type); } else { cgen_write(g, "1"); } if (fo->index) cgen_write(g, ", "); } if (fo->index || !is_range) { if (fo->index) cgen_ident(g, fo->index); else cgen_write(g, "i_"); cgen_write(g, "++"); } cgen_write(g, ") {"); cgen_nl(g); if (fo->value) { if (!is_range) { /* necessary for iterating over, e.g., an array of arrays */ cgen_type_pre(g, &fo->type); if (uses_ptr) cgen_write(g, " p_"); else cgen_write(g, "(*p_)"); cgen_type_post(g, &fo->type); cgen_write(g, " = "); if (of_type->kind == TYPE_SLICE) { cgen_write(g, "(("); cgen_type_pre(g, &fo->type); if (!uses_ptr) cgen_write(g, "(*)"); cgen_type_post(g, &fo->type); cgen_write(g, ")of_%sdata) + ", uses_ptr ? "->" : "."); if (fo->index) cgen_ident(g, fo->index); else cgen_write(g, "i_"); } else { cgen_write(g, "&%sof_%s[", uses_ptr ? "(*" : "", uses_ptr ? ")" : ""); if (fo->index) cgen_ident(g, fo->index); else cgen_write(g, "i_"); cgen_write(g, "]"); } cgen_write(g, "; "); cgen_type_pre(g, &fo->type); cgen_write(g, " "); cgen_ident(g, fo->value); cgen_type_post(g, &fo->type); cgen_write(g, "; "); if (uses_ptr) { cgen_ident(g, fo->value); cgen_write(g, " = p_;"); cgen_nl(g); } else { Expression set_expr; set_expr.kind = EXPR_IDENT; set_expr.ident = fo->value; set_expr.type = fo->type; set_expr.flags = EXPR_FOUND_TYPE; cgen_set(g, &set_expr, NULL, NULL, "(*p_)"); } } } cgen_block(g, &fo->body, NULL, CGEN_BLOCK_NOBRACES); cgen_deferred_from_block(g, &fo->body); cgen_write(g, "}}"); if (fo->body.c.break_lbl) { cgen_lbl(g, fo->body.c.break_lbl); cgen_writeln(g, ":;"); } } break; case EXPR_BLOCK: case EXPR_IF: if (e->type.kind != TYPE_VOID) cgen_ident_id(g, e->cgen.id); break; case EXPR_CALL: if (e->type.kind == TYPE_TUPLE) { /* the only situation in which this could happen is if the return value doesn't matter */ } else if (cgen_uses_ptr(&e->type)) { cgen_ident_id(g, e->cgen.id); } else { FnType *fn_type = &e->call.fn->type.fn; cgen_write(g, "("); cgen_expr(g, e->call.fn); if (e->call.instance) { cgen_fn_instance_number(g, e->call.instance->fn->instance_id); } cgen_write(g, "("); bool first_arg = true; size_t i = 0; size_t nparams = arr_len(fn_type->types)-1; arr_foreach(e->call.arg_exprs, Expression, arg) { if (!fn_type->constness || !arg_is_const(arg, fn_type->constness[i])) { if (!first_arg) cgen_write(g, ", "); first_arg = false; cgen_arg(g, arg); } if (i < nparams-1) ++i; } cgen_write(g, "))"); } break; case EXPR_C: { Expression *code = e->c.code; assert(code->kind == EXPR_VAL); cgen_indent(g); fwrite(code->val.slice.data, 1, (size_t)code->val.slice.n, cgen_writing_to(g)); } break; case EXPR_BUILTIN: switch (e->builtin.which.val) { case BUILTIN_STDOUT: cgen_write(g, "stdout"); break; case BUILTIN_STDERR: cgen_write(g, "stderr"); break; case BUILTIN_STDIN: cgen_write(g, "stdin"); break; case BUILTIN_COMPILING: cgen_write(g, "false"); break; case BUILTIN_SIZEOF_SHORT: case BUILTIN_SIZEOF_INT: case BUILTIN_SIZEOF_LONG: case BUILTIN_SIZEOF_LONG_LONG: case BUILTIN_SIZEOF_FLOAT: case BUILTIN_SIZEOF_DOUBLE: case BUILTIN_SIZEOF_LONG_DOUBLE: case BUILTIN_TSIZEOF_SHORT: case BUILTIN_TSIZEOF_INT: case BUILTIN_TSIZEOF_LONG: case BUILTIN_TSIZEOF_LONG_LONG: case BUILTIN_TSIZEOF_FLOAT: case BUILTIN_TSIZEOF_DOUBLE: case BUILTIN_TSIZEOF_LONG_DOUBLE: case BUILTIN_SIZEOF_SIZE_T: case BUILTIN_TSIZEOF_SIZE_T: { Value val = get_builtin_val(e->builtin.which.val); cgen_write(g, I64_FMT, val.i64); } break; } break; case EXPR_CAST: { Type *from = &e->cast.expr->type; Type *to = &e->cast.type; if (to->kind == TYPE_ARR) { /* can't cast to array type */ cgen_expr(g, e->cast.expr); } else { CType *ctype = &e->cast.ctype; cgen_write(g, "(("); if (ctype->kind != CTYPE_NONE) { cgen_ctype(g, ctype); } else { cgen_type_pre(g, to); cgen_type_post(g, to); } cgen_write(g, ")("); cgen_expr(g, e->cast.expr); cgen_write(g, ")"); if (from->kind == TYPE_SLICE /* casting from a slice to a non-slice */ && to->kind != TYPE_SLICE) cgen_write(g, ".data"); cgen_write(g, ")"); } } break; case EXPR_TUPLE: /* the only time this should happen is if you're stating a tuple, e.g. 3, 5;, but we've errored about that before */ case EXPR_TYPE: assert(0); break; case EXPR_FN: { FnExpr *f = e->fn; cgen_fn_name(g, f); } break; case EXPR_SLICE: cgen_ident_id(g, e->slice.c.id); break; case EXPR_VAL: { Type *t = &e->type; if (cgen_is_type_simple(t)) { cgen_val(g, &e->val, t); } else { cgen_ident_id(g, e->cgen.id); } } break; case EXPR_NMS: break; } } /* ret_name = variable to store block return value in; NULL for none. NOTE: functions always call with NULL as ret_name, even if they use out params, for now at least. */ static void cgen_block(CGenerator *g, Block *b, const char *ret_name, U16 flags) { Block *prev_block = g->block; g->block = b; b->deferred = NULL; ++g->indent_lvl; if (!(flags & CGEN_BLOCK_NOBRACES)) { cgen_writeln(g, "{"); } arr_foreach(b->stmts, Statement, s) cgen_stmt(g, s); if (b->ret_expr && ret_name) { cgen_expr_pre(g, b->ret_expr); if (b->ret_expr->type.kind == TYPE_TUPLE) { cgen_set_tuple(g, NULL, NULL, ret_name, b->ret_expr); } else { cgen_set(g, NULL, ret_name, b->ret_expr, NULL); } cgen_nl(g); } if (b->c.cont_lbl) { cgen_lbl(g, b->c.cont_lbl); cgen_writeln(g, ":;"); } --g->indent_lvl; if (!(flags & CGEN_BLOCK_NOBRACES)) { cgen_deferred_from_block(g, b); arr_clear(&b->deferred); cgen_write(g, "}"); if (b->c.break_lbl) { cgen_lbl(g, b->c.break_lbl); cgen_writeln(g, ":;"); } } g->block = prev_block; } static void cgen_zero_value(CGenerator *g, Type *t) { assert(t->flags & TYPE_IS_RESOLVED); switch (t->kind) { case TYPE_BUILTIN: cgen_write(g, "0"); break; case TYPE_PTR: case TYPE_FN: cgen_write(g, "NULL"); break; case TYPE_SLICE: cgen_write(g, "{NULL, 0}"); break; case TYPE_ARR: case TYPE_STRUCT: cgen_write(g, "{0}"); break; case TYPE_VOID: case TYPE_UNKNOWN: case TYPE_TUPLE: case TYPE_EXPR: assert(0); break; } } /* pass NULL for compile_time_args if there are no compile time arguments. compile_time_args is needed because we can't determine which_are_const from just f. */ static void cgen_fn(CGenerator *g, FnExpr *f, Value *compile_time_args) { if (f->flags & FN_EXPR_FOREIGN) return; /* handled by decls_cgen */ /* see also cgen_defs_expr */ FnExpr *prev_fn = g->fn; U64 which_are_const = compile_time_args ? compile_time_args->u64 : 0; if (!cgen_should_gen_fn(f)) return; cgen_fn_header(g, f, which_are_const); g->fn = f; cgen_write(g, " {"); cgen_nl(g); if (compile_time_args) { ++compile_time_args; /* move past which_are_const */ int semi_const_idx = 0; arr_foreach(f->params, Declaration, param) { if ((param->flags & DECL_IS_CONST) || ((param->flags & DECL_SEMI_CONST) && (which_are_const & (((U64)1) << semi_const_idx++)))) { int i = 0; if (type_is_builtin(¶m->type, BUILTIN_VARARGS)) { VarArg *vararg = param->val.varargs; size_t nvarargs = arr_len(vararg); for (size_t v = 0; v < nvarargs; ++v, ++vararg) { Type *type = vararg->type; Value *arg = &vararg->val; if (!type_is_compileonly(type)) { cgen_val_pre(g, arg, type); cgen_type_pre(g, type); cgen_write(g, " const "); assert(arr_len(param->idents) == 1); cgen_ident(g, param->idents[0]); cgen_write(g, "%lu_", (unsigned long)v); cgen_type_post(g, type); cgen_write(g, " = "); cgen_val(g, arg, type); cgen_writeln(g, ";"); } } } else { arr_foreach(param->idents, Identifier, ident) { Type *type = decl_type_at_index(param, i); Value *arg = decl_val_at_index(param, i); if (!type_is_compileonly(type)) { cgen_val_pre(g, arg, type); cgen_type_pre(g, type); cgen_write(g, " const "); cgen_ident(g, *ident); cgen_type_post(g, type); cgen_write(g, " = "); cgen_val(g, arg, type); cgen_writeln(g, ";"); } ++i; } } } } } /* retdecls need to be after compile time arguments to allow fn(x::int) y := x */ arr_foreach(f->ret_decls, Declaration, d) { cgen_decl(g, d); } cgen_block(g, &f->body, NULL, CGEN_BLOCK_NOBRACES); Block *prev = g->block; g->block = &f->body; /* cgen_ret needs to think it's in the function body */ cgen_ret(g, &f->body, f->body.ret_expr); g->block = prev; cgen_writeln(g, "}"); g->fn = prev_fn; cgen_nl(g); cgen_nl(g); } static void cgen_decl(CGenerator *g, Declaration *d) { if (g->block == NULL && g->fn == NULL) return; /* already dealt with */ int has_expr = d->flags & DECL_HAS_EXPR; if (cgen_fn_is_direct(g, d)) return; /* dealt with in cgen_defs_ */ if (d->flags & DECL_FOUND_VAL) { /* declarations where we use a value */ for (int idx = 0, nidents = (int)arr_len(d->idents); idx < nidents; ++idx) { Identifier i = d->idents[idx]; Type *type = decl_type_at_index(d, idx); if (type_is_compileonly(&d->type)) { continue; } Value *val = decl_val_at_index(d, idx); if (has_expr) { cgen_val_pre(g, val, type); } cgen_type_pre(g, type); cgen_write(g, " "); cgen_ident(g, i); cgen_type_post(g, type); if (has_expr) { cgen_write(g, " = "); cgen_val(g, val, type); } else { cgen_write(g, " = "); cgen_zero_value(g, type); } cgen_write(g, ";"); cgen_nl(g); } } else { /* declarations where we use an expression */ int nidents = (int)arr_len(d->idents); for (int idx = 0; idx < nidents; ++idx) { Identifier i = d->idents[idx]; if (ident_eq_str(i, "_")) continue; Type *type = decl_type_at_index(d, idx); cgen_type_pre(g, type); cgen_write(g, " "); cgen_ident(g, i); cgen_type_post(g, type); if (!has_expr) { cgen_write(g, " = "); cgen_zero_value(g, type); } cgen_write(g, "; "); } if (has_expr) { assert((g->block || g->fn) && !(d->flags & DECL_IS_CONST)); if (d->expr.type.kind == TYPE_TUPLE) { cgen_set_tuple(g, NULL, d->idents, NULL, &d->expr); } else { cgen_expr_pre(g, &d->expr); if (nidents > 1) { /* set expr__ first to make sure side effects don't happen twice */ cgen_write(g, "{"); cgen_nl(g); cgen_type_pre(g, &d->type); cgen_write(g, " expr_"); cgen_type_post(g, &d->type); cgen_write(g, "; "); cgen_set(g, NULL, "expr_", &d->expr, NULL); arr_foreach(d->idents, Identifier, i) { Expression e; e.flags = EXPR_FOUND_TYPE; e.kind = EXPR_IDENT; e.type = d->type; e.ident = *i; cgen_set(g, &e, NULL, NULL, "expr_"); } cgen_write(g, "}"); } else { /* set it directly */ Expression e = {0}; e.kind = EXPR_IDENT; e.type = d->type; e.flags = EXPR_FOUND_TYPE; e.ident = d->idents[0]; cgen_set(g, &e, NULL, &d->expr, NULL); } } } cgen_nl(g); } } static void cgen_ret(CGenerator *g, Block *returning_from, Expression *ret_expr) { FnExpr *f = g->fn; if (ret_expr) { cgen_expr_pre(g, ret_expr); if (cgen_uses_ptr(&f->ret_type)) { if (f->ret_type.kind == TYPE_TUPLE) { cgen_set_tuple(g, NULL, NULL, "*ret__", ret_expr); } else { cgen_set(g, NULL, "*ret__", ret_expr, NULL); } } else { /* set ret_ to ret_expr */ cgen_type_pre(g, &ret_expr->type); cgen_write(g, " ret_"); cgen_type_post(g, &ret_expr->type); cgen_write(g, "; "); cgen_set(g, NULL, "ret_", ret_expr, NULL); cgen_nl(g); } } cgen_deferred_up_to(g, returning_from); if (f->ret_decls) { if (f->ret_type.kind == TYPE_TUPLE) { Expression tuple_expr = {0}; tuple_expr.flags = EXPR_FOUND_TYPE; tuple_expr.type = f->ret_type; tuple_expr.kind = EXPR_TUPLE; tuple_expr.tuple = NULL; arr_set_len(&tuple_expr.tuple, arr_len(f->ret_type.tuple)); int idx = 0; arr_foreach(f->ret_decls, Declaration, d) { arr_foreach(d->idents, Identifier, ident) { Expression *e = &tuple_expr.tuple[idx]; e->flags = EXPR_FOUND_TYPE; e->type = f->ret_type.tuple[idx]; e->kind = EXPR_IDENT; e->ident = *ident; ++idx; } } cgen_set_tuple(g, NULL, NULL, "*ret__", &tuple_expr); arr_clear(&tuple_expr.tuple); } else if (cgen_uses_ptr(&f->ret_type)) { Expression expr = {0}; expr.flags = EXPR_FOUND_TYPE; expr.type = f->ret_type; expr.kind = EXPR_IDENT; expr.ident = f->ret_decls[0].idents[0]; cgen_set(g, NULL, "*ret__", &expr, NULL); cgen_writeln(g, ";"); cgen_writeln(g, "return;"); } else { cgen_write(g, "return "); cgen_ident(g, f->ret_decls[0].idents[0]); cgen_writeln(g, ";"); } return; } if (cgen_uses_ptr(&f->ret_type)) { #if 0 Expression ret = {0}; ret.kind = EXPR_IDENT; ret.ident = ident_get(g->globals, "ret_"); ret.flags = EXPR_FOUND_TYPE; ret.type = f->ret_type; #endif cgen_writeln(g, " return;"); } else if (f->ret_type.kind == TYPE_VOID) { cgen_writeln(g, "return;"); } else { cgen_writeln(g, "return ret_;"); } } static void cgen_stmt(CGenerator *g, Statement *s) { #ifdef CGEN_EMIT_LINE_NUMBER_COMMENTS /* TODO: add compiler option for this */ cgen_write(g, "/* %s:%d */", s->where.ctx->filename, s->where.line); #endif switch (s->kind) { case STMT_DECL: cgen_decl(g, s->decl); break; case STMT_EXPR: { Expression *e = s->expr; if ((g->block != NULL || e->kind == EXPR_C) && !type_is_compileonly(&e->type)) { cgen_expr_pre(g, e); cgen_expr(g, e); if (e->kind != EXPR_C) cgen_writeln(g, ";"); } } break; case STMT_RET: { Return *r = s->ret; unsigned has_expr = r->flags & RET_HAS_EXPR; cgen_ret(g, r->referring_to, has_expr ? &r->expr : NULL); } break; case STMT_INCLUDE: { Include *i = s->inc; if (i->inc_file && (i->inc_file->flags & INC_FILE_CGEND)){ /* already generated */ } else { if (i->inc_file) i->inc_file->flags |= INC_FILE_CGEND; arr_foreach(i->stmts, Statement, sub) cgen_stmt(g, sub); } } break; case STMT_BREAK: { Block *b = s->referring_to; cgen_deferred_up_to(g, b); cgen_write(g, "goto "); cgen_lbl(g, b->c.break_lbl); cgen_writeln(g, ";"); } break; case STMT_CONT: { Block *b = s->referring_to; cgen_deferred_up_to_not_including(g, b); cgen_write(g, "goto "); cgen_lbl(g, b->c.cont_lbl); cgen_writeln(g, ";"); } break; case STMT_DEFER: *(Statement **)arr_add(&g->block->deferred) = s->defer; break; case STMT_USE: case STMT_MESSAGE: break; } } static void cgen_defs_fn(CGenerator *g, FnExpr *f) { if (fn_has_instances(f)) { HashTable *instances = f->instances; /* generate each instance */ Instance **is = instances->data; for (U64 i = 0; i < instances->cap; ++i) { if (instances->occupied[i]) { /* generate this instance */ cgen_fn(g, is[i]->fn, is[i]->val.tuple); } } } else { cgen_fn(g, f, NULL); } } static void cgen_defs_expr(CGenerator *g, Expression *e) { if (e->kind == EXPR_FN) { cgen_defs_fn(g, e->fn); } cgen_recurse_subexprs(g, e, cgen_defs_expr, cgen_defs_block, cgen_defs_decl); } static void cgen_defs_decl(CGenerator *g, Declaration *d) { if (d->flags & DECL_HAS_EXPR) { cgen_defs_expr(g, &d->expr); } } static void cgen_defs_stmt(CGenerator *g, Statement *s) { switch (s->kind) { case STMT_DECL: cgen_defs_decl(g, s->decl); break; case STMT_EXPR: cgen_defs_expr(g, s->expr); break; case STMT_RET: if (s->ret->flags & RET_HAS_EXPR) cgen_defs_expr(g, &s->ret->expr); break; case STMT_INCLUDE: { Include *i = s->inc; if (i->inc_file && (i->inc_file->flags & INC_FILE_CGEND_DEFS)) { /* already generated */ } else { if (i->inc_file) i->inc_file->flags |= INC_FILE_CGEND_DEFS; arr_foreach(i->stmts, Statement, sub) cgen_defs_stmt(g, sub); } } break; case STMT_BREAK: case STMT_CONT: case STMT_MESSAGE: break; case STMT_DEFER: cgen_defs_stmt(g, s->defer); break; case STMT_USE: cgen_defs_expr(g, &s->use->expr); break; } } static void cgen_defs_block(CGenerator *g, Block *b) { /* NOTE: since we exit as soon as there's an error for cgen, we don't need to make sure we set g->block to the previous block if there's an error */ Block *prev_block = g->block; g->block = b; b->deferred = NULL; arr_foreach(b->stmts, Statement, s) { cgen_defs_stmt(g, s); } if (b->ret_expr) cgen_defs_expr(g, b->ret_expr); g->block = prev_block; } static void cgen_file(CGenerator *g, ParsedFile *f) { g->block = NULL; g->nms = NULL; g->fn = NULL; g->file = f; cgen_write(g, "#include \n" "#include \n" "typedef int8_t i8;\n" "typedef int16_t i16;\n" "typedef int32_t i32;\n" "typedef int64_t i64;\n" "typedef uint8_t u8;\n" "typedef uint16_t u16;\n" "typedef uint32_t u32;\n" "typedef uint64_t u64;\n" "typedef float f32;\n" "typedef double f64;\n" "typedef u8 bool;\n" "typedef struct { void *data; i64 n; } slice_;\n" "#define false ((bool)0)\n" "#define true ((bool)1)\n" "static slice_ mkslice_(void *data, i64 n) { slice_ ret; ret.data = data; ret.n = n; return ret; }\n"); cgen_sdecls_file(g, f); cgen_decls_file(g, f); cgen_write(g, "/* code */\n"); cgen_write(g, "int main() {\n\tmain_();\n\treturn 0;\n}\n\n"); arr_foreach(f->stmts, Statement, s) { cgen_defs_stmt(g, s); } arr_foreach(f->stmts, Statement, s) { cgen_stmt(g, s); } }