#include #include #include #include #include #include #include #include "alloc.h" #include "common.h" #include "errors.h" #include "parser.h" #include "strview.h" #if DEBUG # define AST_DFLT_CAP (8) # define AUX_DFLT_CAP (8) #else # define AST_DFLT_CAP (2048) # define AUX_DFLT_CAP (128) #endif #define SIZE_WDTH (sizeof(size_t) * CHAR_BIT) typedef idx_t parsefn(ast_t *, aux_t *, lexemes_t) __attribute__((nonnull)); static parsefn parseblk, parseexpr, parsefunc, parseproto, parsestmt, parsetype; static idx_t parsedecl(ast_t *, aux_t *, lexemes_t, bool) __attribute__((nonnull)); static ast_t mkast(void); /* Return a new index in AST where a node can be stored. This function automatically resizes AST if it runs out of capacity. */ static idx_t astalloc(ast_t *ast) __attribute__((nonnull)); /* Resize AST to the next power-of-2 capacity */ static void astresz(ast_t *ast) __attribute__((nonnull)); /* TODO: Make thread-local? */ static size_t toksidx; idx_t fwdnode(ast_t ast, idx_t i) { while (likely(i < ast.len)) { switch (ast.kinds[i]) { case ASTBLK: i = ast.kids[i].lhs == AST_EMPTY ? i + 1 : ast.kids[i].rhs; break; case ASTDECL: i = ast.kids[i].rhs == AST_EMPTY ? ast.kids[i].lhs : ast.kids[i].rhs; break; case ASTRET: if (ast.kids[i].rhs == AST_EMPTY) return i + 1; i = ast.kids[i].rhs; break; case ASTBINADD: case ASTBINSUB: case ASTCDECL: case ASTFN: i = ast.kids[i].rhs; break; case ASTIDENT: case ASTNUMLIT: case ASTTYPE: return i + 1; case ASTFNPROTO: assert("analyzer: Not reachable"); __builtin_unreachable(); } } return i; } ast_t parsetoks(lexemes_t toks, aux_t *aux) { ast_t ast = mkast(); aux->buf = bufalloc(NULL, aux->cap = AUX_DFLT_CAP, sizeof(*aux->buf)); for (;;) { (void)parsedecl(&ast, aux, toks, true); if (toks.kinds[toksidx] == LEXEOF) break; } return ast; } idx_t parseblk(ast_t *ast, aux_t *aux, lexemes_t toks) { idx_t i = astalloc(ast); ast->lexemes[i] = toksidx; ast->kinds[i] = ASTBLK; ast->kids[i].lhs = AST_EMPTY; ast->kids[i].rhs = 0; if (toks.kinds[toksidx++] != LEXLBRACE) err("parser: Expected left brace"); if (toks.kinds[toksidx] != LEXRBRACE) { idx_t stmt = parsestmt(ast, aux, toks); ast->kids[i].lhs = ast->kids[i].rhs = stmt; } while (toks.kinds[toksidx] != LEXRBRACE) { idx_t stmt = parsestmt(ast, aux, toks); ast->kids[i].rhs = stmt; } toksidx++; /* Eat rbrace */ return i; } idx_t parsedecl(ast_t *ast, aux_t *aux, lexemes_t toks, bool toplvl) { idx_t i = astalloc(ast), j = aux->len++; if (aux->len > aux->cap) { aux->cap *= 2; aux->buf = bufalloc(aux->buf, aux->cap, sizeof(*aux->buf)); } aux->buf[j].decl.isstatic = toplvl; if (toplvl && toks.kinds[toksidx] == LEXIDENT && strview_eq(SV("pub"), toks.strs[toksidx])) { aux->buf[j].decl.ispub = true; ast->lexemes[i] = ++toksidx; } else { aux->buf[j].decl.ispub = false; ast->lexemes[i] = toksidx; } if (toks.kinds[toksidx++] != LEXIDENT) err("parser: Expected identifier"); if (toks.kinds[toksidx++] != LEXCOLON) err("parser: Expected colon"); aux->buf[j].decl.type = toks.kinds[toksidx] == LEXIDENT ? parsetype(ast, aux, toks) : AST_EMPTY; ast->kids[i].lhs = j; switch (toks.kinds[toksidx++]) { case LEXSEMI: if (aux->buf[j].decl.type == AST_EMPTY) err("parser: No type provided in non-assigning declaration"); ast->kinds[i] = ASTDECL; ast->kids[i].rhs = AST_EMPTY; return i; case LEXCOLON: ast->kinds[i] = ASTCDECL; break; case LEXEQ: ast->kinds[i] = ASTDECL; break; default: err("parser: Expected colon, equals, or semicolon"); } bool func = toks.kinds[toksidx] == LEXLPAR; if (func && ast->kinds[i] == ASTDECL) err("Cannot assign function to mutable variable"); idx_t rhs = (func ? parsefunc : parseexpr)(ast, aux, toks); ast->kids[i].rhs = rhs; if (!func && toks.kinds[toksidx++] != LEXSEMI) err("parser: Expected semicolon"); return i; } idx_t parsefunc(ast_t *ast, aux_t *aux, lexemes_t toks) { idx_t i = astalloc(ast); ast->lexemes[i] = toksidx; assert(toks.kinds[toksidx] == LEXLPAR); ast->kinds[i] = ASTFN; idx_t lhs = parseproto(ast, aux, toks); idx_t rhs = parseblk(ast, aux, toks); ast->kids[i].lhs = lhs; ast->kids[i].rhs = rhs; return i; } idx_t parseexpr(ast_t *ast, aux_t *aux, lexemes_t toks) { (void)aux; idx_t i = astalloc(ast); ast->lexemes[i] = toksidx; switch (toks.kinds[toksidx]) { case LEXNUM: toksidx++; ast->kinds[i] = ASTNUMLIT; break; case LEXIDENT: toksidx++; ast->kinds[i] = ASTIDENT; break; default: err("parser: Expected expression"); } return i; } idx_t parseproto(ast_t *ast, aux_t *aux, lexemes_t toks) { idx_t i = astalloc(ast); ast->lexemes[i] = toksidx; ast->kinds[i] = ASTFNPROTO; ast->kids[i].lhs = AST_EMPTY; if (toks.kinds[toksidx++] != LEXLPAR) err("parser: Expected left parenthesis"); if (toks.kinds[toksidx++] != LEXRPAR) err("parser: Expected right parenthesis"); idx_t rhs = toks.kinds[toksidx] == LEXIDENT ? parsetype(ast, aux, toks) : AST_EMPTY; ast->kids[i].rhs = rhs; return i; } idx_t parsestmt(ast_t *ast, aux_t *aux, lexemes_t toks) { idx_t i; if (toks.kinds[toksidx] != LEXIDENT) err("parser: Expected identifier"); strview_t sv = toks.strs[toksidx]; if (strview_eq(SV("return"), sv)) { i = astalloc(ast); ast->lexemes[i] = toksidx++; ast->kinds[i] = ASTRET; idx_t rhs = toks.kinds[toksidx] != LEXSEMI ? parseexpr(ast, aux, toks) : AST_EMPTY; ast->kids[i].rhs = rhs; if (toks.kinds[toksidx++] != LEXSEMI) err("parser: Expected semicolon"); } else if (toks.kinds[toksidx + 1] == LEXCOLON) { i = parsedecl(ast, aux, toks, false); } else { err("parser: Invalid statement"); } return i; } idx_t parsetype(ast_t *ast, aux_t *aux, lexemes_t toks) { (void)aux; idx_t i = astalloc(ast); ast->kinds[i] = ASTTYPE; ast->lexemes[i] = toksidx; if (toks.kinds[toksidx++] != LEXIDENT) err("parser: Expected type"); return i; } ast_t mkast(void) { ast_t soa; static_assert(AST_DFLT_CAP * sizeof(*soa.kinds) % alignof(idx_t) == 0, "Additional padding is required to properly align LEXEMES"); static_assert(AST_DFLT_CAP * (sizeof(*soa.kinds) + sizeof(*soa.lexemes)) % alignof(pair_t) == 0, "Additional padding is required to properly align KIDS"); soa.len = 0; soa.cap = AST_DFLT_CAP; soa.kinds = bufalloc(NULL, soa.cap, AST_SOA_BLKSZ); soa.lexemes = (void *)((char *)soa.kinds + soa.cap * sizeof(*soa.kinds)); soa.kids = (void *)((char *)soa.lexemes + soa.cap * sizeof(*soa.lexemes)); return soa; } void astresz(ast_t *soa) { size_t ncap, pad1, pad2, newsz; ptrdiff_t lexemes_off, kids_off; lexemes_off = (char *)soa->lexemes - (char *)soa->kinds; kids_off = (char *)soa->kids - (char *)soa->kinds; /* The capacity is always going to be a power of 2, so checking for overflow becomes pretty trivial */ if (unlikely((soa->cap >> (SIZE_WDTH - 1)) != 0)) { errno = ENOMEM; err("%s:", __func__); } ncap = soa->cap << 1; /* Ensure that soa->lexemes is properly aligned */ pad1 = alignof(idx_t) - ncap % alignof(idx_t); if (pad1 == alignof(idx_t)) pad1 = 0; /* Ensure that soa->kids is properly aligned */ pad2 = alignof(pair_t) - (ncap * (1 + sizeof(idx_t)) + pad1) % alignof(pair_t); if (pad2 == alignof(pair_t)) pad2 = 0; newsz = ncap * AST_SOA_BLKSZ + pad1 + pad2; soa->kinds = bufalloc(soa->kinds, newsz, 1); soa->lexemes = (void *)((char *)soa->kinds + ncap * sizeof(*soa->kinds) + pad1); soa->kids = (void *)((char *)soa->lexemes + ncap * sizeof(*soa->lexemes) + pad2); memmove(soa->kids, (char *)soa->kinds + kids_off, soa->len * sizeof(*soa->kids)); memmove(soa->lexemes, (char *)soa->kinds + lexemes_off, soa->len * sizeof(*soa->lexemes)); soa->cap = ncap; } idx_t astalloc(ast_t *soa) { if (unlikely(soa->len == soa->cap)) astresz(soa); return soa->len++; }