761 lines
22 KiB
C
761 lines
22 KiB
C
#include "parse.h"
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#include <stdbool.h>
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#include "map.h"
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#include "runtime.h"
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static BuiltinFunc *bf;
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typedef struct Scope {
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struct Scope *parent;
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size_t mem_addr;
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bool has_idents;
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Map ident_addrs;
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} Scope;
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typedef struct ExprRet {
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enum {
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ExprRetVal,
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ExprRetIdent,
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ExprRetLastInstr,
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} kind;
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union {
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IRTok LastInstr;
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};
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} ExprRet;
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static void mark_err(const Tok *t);
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static void set_irtok_dest_addr(IRTok *t, size_t addr);
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static size_t get_ident_addr(const Scope *sc, const char *name, const Tok *errpos);
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static IRParam tok_to_irparam(Scope *sc, Tok *t);
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static Scope make_scope(Scope *parent, bool with_idents);
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static void term_scope(Scope *sc);
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static bool expr_flush_ir_and_maybe_return(IRToks *out_ir, TokList *toks, IRTok instr, TokListItem *expr_start, Scope *expr_scope, TokListItem *t, ExprRet *out_ret);
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static ExprRet expr(IRToks *out_ir, TokList *toks, Map *funcs, Scope *parent_sc, TokListItem *t);
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static void expr_into_addr(IRToks *out_ir, TokList *toks, Map *funcs, Scope *parent_sc, TokListItem *t, size_t addr);
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static IRParam expr_into_irparam(IRToks *out_ir, TokList *toks, Map *funcs, Scope *parent_sc, TokListItem *t);
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static void skip_newlns(TokList *toks, TokListItem *from);
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static void stmt(IRToks *out_ir, TokList *toks, Map *funcs, Scope *sc, TokListItem *t);
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static void mark_err(const Tok *t) {
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err_ln = t->ln;
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err_col = t->col;
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}
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static void set_irtok_dest_addr(IRTok *t, size_t addr) {
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switch (t->instr) {
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case IRSet:
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case IRNeg:
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case IRNot:
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t->Unary.addr = addr;
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break;
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case IRAdd:
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case IRSub:
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case IRMul:
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case IRDiv:
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case IREq:
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case IRNeq:
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case IRLt:
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case IRLe:
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case IRAnd:
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case IROr:
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t->Binary.addr = addr;
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break;
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case IRCallInternal:
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t->CallI.ret_addr = addr;
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break;
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default:
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ASSERT_UNREACHED();
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}
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}
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static size_t get_ident_addr(const Scope *sc, const char *name, const Tok *errpos) {
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size_t addr;
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bool exists = false;
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for (const Scope *i = sc; i != NULL; i = i->parent) {
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if (!i->has_idents)
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continue;
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exists = map_get(&i->ident_addrs, name, &addr);
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if (exists)
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break;
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}
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if (!exists) {
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mark_err(errpos);
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set_err("Identifier '%s' not recognized in this scope", name);
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return 0;
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}
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return addr;
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}
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static IRParam tok_to_irparam(Scope *sc, Tok *t) {
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if (t->kind == TokIdent) {
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size_t addr;
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if (t->Ident.kind == IdentName) {
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TRY_RET(addr = get_ident_addr(sc, t->Ident.Name, t), (IRParam){0});
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} else if (t->Ident.kind == IdentAddr)
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addr = t->Ident.Addr;
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else
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ASSERT_UNREACHED();
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return (IRParam){
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.kind = IRParamAddr,
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.Addr = addr,
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};
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} else if (t->kind == TokVal) {
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return (IRParam){
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.kind = IRParamLiteral,
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.Literal = t->Val,
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};
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} else
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ASSERT_UNREACHED();
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}
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/* term_scope doesn't have to be called if with_idents is set to false. */
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static Scope make_scope(Scope *parent, bool with_idents) {
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Scope s = { .parent = parent, .mem_addr = parent ? parent->mem_addr : 0, .has_idents = with_idents };
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if (with_idents)
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map_init(&s.ident_addrs, sizeof(size_t));
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return s;
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}
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static void term_scope(Scope *sc) {
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if (sc->has_idents)
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map_term(&sc->ident_addrs);
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}
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/* If ir_tok is the underlying expr() call's last evaluation, this function
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* deletes t from toks, sets *out_ret and tells the caller it can return
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* *out_ret by returning true.
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*
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* If ir_tok is not the expression's last instruction, ir_tok is written to
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* out_ir and t is replaced by a pointer to the result's memory address.
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* */
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static bool expr_flush_ir_and_maybe_return(IRToks *out_ir, TokList *toks, IRTok ir_tok, TokListItem *expr_start, Scope *expr_scope, TokListItem *t, ExprRet *out_ret) {
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if (t == expr_start && t->next->tok.kind == TokOp && op_prec[t->next->tok.Op] == PREC_DELIM) {
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/* ir_tok was the expression's last IR instruction. */
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toklist_del(toks, t, t);
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*out_ret = (ExprRet){
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.kind = ExprRetLastInstr,
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.LastInstr = ir_tok,
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};
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return true;
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} else {
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/* ir_tok was not the expression's last IR instruction. */
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size_t dest_addr = expr_scope->mem_addr++;
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set_irtok_dest_addr(&ir_tok, dest_addr);
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irtoks_app(out_ir, ir_tok);
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t->tok = (Tok){
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.kind = TokIdent,
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.Ident = {
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.kind = IdentAddr,
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.Addr = dest_addr,
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},
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};
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return false;
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}
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}
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/* The job of this function is to reduce the expression to the most simple form
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* writing the least IR instructions possible (without overanalyzing).
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* This means that the only IR instructions it will be writing are those for
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* calculating intermediate values.
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* In the case of ExprRetVal and ExprRetIdent, the value isn't 'returned' in
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* the traditional sense, but rather the result is left in the token stream.
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* The 'return' value can be of 3 different types:
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* - ExprRetVal: The expression yields a constant value as a result.
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* Examples: '5', '5 + 2 * 3' or '5 + (2 + 1) * 3'
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* - ExprRetIdent: The expression yields an identifier as a result.
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* Examples: 'a' or '(((a)))'
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* - ExprRetLastInstr: The expression is a more complex sequence of
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* instructions. Here the last instruction is returned so the caller can
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* manually set the destination address.
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* Examples: 'a + 1', '2 + a * b' or '2 + 4 * (b * b) / 5'
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*
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* Here is also a simplified example of how the operator precedence parsing works:
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* ________________________________
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* Where t points to (between l_op and r_op in each step)
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* |
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* v
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* 5 + 2 * 2 \n
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* ^ ^
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* | |
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* l_op r_op
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* precedence of '+' is higher than that of the front delimiter => move forward
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* ________________________________
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* 5 + 2 * 2 \n
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* ^ ^
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* | |
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* l_op r_op
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* precedence of '*' is higher than that of '+' => move forward
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* ________________________________
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* 5 + 2 * 2 \n
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* ^ ^
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* | |
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* l_op r_op
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* precedence of '\n' (a delimiter) is lower than that of '*' => evaluate and move l_op 2 back
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* ________________________________
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* 5 + 4 \n
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* ^ ^
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* | |
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* l_op r_op
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* precedence of '\n' (a delimiter) is lower than that of '+' => evaluate and move l_op 2 back
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* ________________________________
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* 9 \n
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* ^ ^
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* | |
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* l_op r_op
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* both l_op and r_op are delimiters (their precedence is PREC_DELIM) => done
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*/
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static ExprRet expr(IRToks *out_ir, TokList *toks, Map *funcs, Scope *parent_sc, TokListItem *t) {
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TokListItem *start = t;
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Scope sc = make_scope(parent_sc, false);
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for (;;) {
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/* Prepare to collapse unary operation. */
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bool perform_unary = false;
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IRInstr unary_op;
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if (t->tok.kind == TokOp) {
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if (t->tok.Op == OpSub) {
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t = t->next;
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perform_unary = true;
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unary_op = IRNeg;
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} else if (t->tok.Op == OpNot) {
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t = t->next;
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perform_unary = true;
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unary_op = IRNot;
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}
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}
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/* Delete newline if we're definitely expecting an operand. */
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if (t->tok.kind == TokOp && t->tok.Op == OpNewLn) {
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if (t == start)
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start = t->next;
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t = t->next;
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toklist_del(toks, t->prev, t->prev);
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}
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/* Collapse parentheses. */
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if (t->tok.kind == TokOp && t->tok.Op == OpLParen) {
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ExprRet r;
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TRY_RET(r = expr(out_ir, toks, funcs, &sc, t->next), (ExprRet){0});
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if (r.kind == ExprRetLastInstr) {
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size_t res_addr = sc.mem_addr++;
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set_irtok_dest_addr(&r.LastInstr, res_addr);
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irtoks_app(out_ir, r.LastInstr);
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t->tok = (Tok){
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.ln = t->tok.ln,
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.col = t->tok.col,
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.kind = TokIdent,
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.Ident = {
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.kind = IdentAddr,
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.Addr = res_addr,
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},
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};
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} else if (r.kind == ExprRetVal || r.kind == ExprRetIdent) {
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t->tok = t->next->tok;
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toklist_del(toks, t->next, t->next);
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} else
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ASSERT_UNREACHED();
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toklist_del(toks, t->next, t->next);
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}
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/* Collapse function call. */
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else if (t->tok.kind == TokIdent && t->tok.Ident.kind == IdentName && t->next->tok.kind == TokOp && t->next->tok.Op == OpLParen) {
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/* get function */
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BuiltinFunc func;
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bool exists = map_get(funcs, t->tok.Ident.Name, &func);
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if (!exists) {
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mark_err(&t->tok);
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set_err("Unrecognized function: %s()", t->tok.Ident.Name);
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return (ExprRet){0};
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}
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TokListItem *func_ident = t;
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t = func_ident->next;
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/* we want to try to eliminate function calls at runtime if possible */
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bool eval_func_in_place = !func.side_effects;
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size_t args_len = 0;
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IRParam *args = NULL;
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if (t->next->tok.kind == TokOp && t->next->tok.Op == OpRParen) {
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/* no args */
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toklist_del(toks, t->next, t->next); /* delete right parenthesis */
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} else {
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/* go through the arguments, evaluate them and put them into the args array */
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size_t args_cap = 16;
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args = xmalloc(sizeof(IRParam) * args_cap);
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for (;;) {
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if (args_len+1 > args_cap)
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args = xrealloc(args, (args_cap *= 2));
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IRParam a;
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TRY_RET_ELSE(a = expr_into_irparam(out_ir, toks, funcs, &sc, t->next), (ExprRet){0}, free(args));
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args[args_len++] = a;
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if (a.kind != IRParamLiteral)
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eval_func_in_place = false;
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if (t->next->tok.kind == TokOp) {
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if (t->next->tok.Op == OpComma) {
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toklist_del(toks, t->next, t->next); /* delete right parenthesis */
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continue;
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} else if (t->next->tok.Op == OpRParen) {
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toklist_del(toks, t->next, t->next); /* delete right parenthesis */
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break;
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}
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}
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mark_err(&t->next->tok);
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set_err("Expected ',' or ')' after function argument");
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free(args);
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return (ExprRet){0};
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}
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}
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t = func_ident;
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toklist_del(toks, t->next, t->next); /* delete left parenthesis */
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if (func.n_args != args_len) {
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mark_err(&func_ident->tok);
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const char *plural = func.n_args == 1 ? "" : "s";
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set_err("Function %s() takes %zu argument%s but got %zu", func.name, func.n_args, plural, args_len);
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if (args)
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free(args);
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return (ExprRet){0};
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}
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if (eval_func_in_place) {
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/* evaluate the function in place */
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Value *arg_vals = args_len ? xmalloc(sizeof(Value) * args_len) : NULL;
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for (size_t i = 0; i < args_len; i++)
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arg_vals[i] = args[i].Literal;
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mark_err(&func_ident->tok);
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func_ident->tok = (Tok) {
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.kind = TokVal,
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.Val = func.func(arg_vals),
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};
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if (arg_vals)
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free(arg_vals);
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if (args)
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free(args);
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} else {
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/* function call IR instruction */
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IRTok ir_tok = {
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.ln = func_ident->tok.ln,
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.col = func_ident->tok.col,
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.instr = IRCallInternal,
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.CallI = {
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.ret_addr = 0,
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.fid = func.fid,
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.args = args,
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},
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};
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/* return if we've just evaluated the last instruction */
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ExprRet ret;
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if (expr_flush_ir_and_maybe_return(out_ir, toks, ir_tok, start, &sc, func_ident, &ret))
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return ret;
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}
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}
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/* Collapse unary operation. */
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if (perform_unary) {
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Tok *v = &t->tok; /* what we want to perform the operation on */
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t = t->prev; /* go back to the '-' sign */
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toklist_del(toks, t->next, t->next); /* again, just removing the reference */
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if (v->kind == TokVal) {
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/* immediately perform operation */
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t->tok.kind = TokVal;
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mark_err(&t->tok);
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TRY_RET(t->tok.Val = eval_unary(unary_op, &v->Val), (ExprRet){0});
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} else {
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/* unary IR instruction */
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IRParam v_irparam;
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TRY_RET(v_irparam = tok_to_irparam(&sc, v), (ExprRet){0});
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IRTok ir_tok = {
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.ln = t->tok.ln,
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.col = t->tok.col,
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.instr = unary_op,
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.Unary = {
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.addr = 0,
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.val = v_irparam,
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},
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};
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/* return if we've just evaluated the last instruction */
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ExprRet ret;
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if (expr_flush_ir_and_maybe_return(out_ir, toks, ir_tok, start, &sc, t, &ret))
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return ret;
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}
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}
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/* Find out operator precedence of l_op and r_op. */
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int8_t l_op_prec;
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Tok *l_op;
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if (t == start) {
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l_op_prec = PREC_DELIM;
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l_op = NULL;
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} else {
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l_op = &t->prev->tok;
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if (l_op->kind != TokOp) {
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mark_err(l_op);
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set_err("Expected operator");
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return (ExprRet){0};
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}
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l_op_prec = op_prec[l_op->Op];
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}
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int8_t r_op_prec;
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Tok *r_op = &t->next->tok;
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if (r_op->kind != TokOp) {
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mark_err(r_op);
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set_err("Expected operator");
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return (ExprRet){0};
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}
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r_op_prec = op_prec[r_op->Op];
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/* If l_op and r_op are both delimiters, we don't have to evaluate
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* anything. */
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if (l_op_prec == PREC_DELIM && r_op_prec == PREC_DELIM) {
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if (t->tok.kind == TokIdent) {
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return (ExprRet){ .kind = ExprRetIdent };
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} else if (t->tok.kind == TokVal) {
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return (ExprRet){ .kind = ExprRetVal };
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} else {
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mark_err(&t->tok);
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set_err("Expected literal or identifier");
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return (ExprRet){0};
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}
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}
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/* This is the operator precedence parser described above. */
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if (r_op_prec > l_op_prec)
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t = t->next->next;
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else {
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Tok *rhs = &t->tok;
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if (rhs->kind != TokVal && rhs->kind != TokIdent) {
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mark_err(rhs);
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set_err("Expected literal or identifier");
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return (ExprRet){0};
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}
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t = t->prev->prev;
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Tok *lhs = &t->tok;
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if (lhs->kind != TokVal && lhs->kind != TokIdent) {
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mark_err(lhs);
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set_err("Expected literal or identifier");
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return (ExprRet){0};
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}
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/* delete the tokens that fall away from collapsing the expression
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* (NOTE: only their references are deleted here, that's important
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* because we're still using their values later on) */
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toklist_del(toks, t->next, t->next->next);
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bool swap_operands = false;
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IRInstr instr;
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switch (l_op->Op) {
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case OpAdd: instr = IRAdd; break;
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case OpSub: instr = IRSub; break;
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case OpMul: instr = IRMul; break;
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case OpDiv: instr = IRDiv; break;
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case OpEq: instr = IREq; break;
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case OpNeq: instr = IRNeq; break;
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case OpLt: instr = IRLt; break;
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case OpLe: instr = IRLe; break;
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case OpGt: instr = IRLt; swap_operands = true; break;
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case OpGe: instr = IRLe; swap_operands = true; break;
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case OpAnd: instr = IRAnd; break;
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case OpOr: instr = IROr; break;
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default:
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mark_err(l_op);
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set_err("Unknown operation: '%s'", op_str[l_op->Op]);
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return (ExprRet){0};
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}
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if (lhs->kind == TokVal && rhs->kind == TokVal) {
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/* evaluate the constant expression immediately */
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Value *lhs_val = swap_operands ? &rhs->Val : &lhs->Val;
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Value *rhs_val = swap_operands ? &lhs->Val : &rhs->Val;
|
|
lhs->kind = TokVal;
|
|
mark_err(l_op);
|
|
TRY_RET(lhs->Val = eval_binary(instr, lhs_val, rhs_val), (ExprRet){0});
|
|
} else {
|
|
IRParam lhs_irparam, rhs_irparam;
|
|
TRY_RET(lhs_irparam = tok_to_irparam(&sc, lhs), (ExprRet){0});
|
|
TRY_RET(rhs_irparam = tok_to_irparam(&sc, rhs), (ExprRet){0});
|
|
|
|
/* binary IR instruction */
|
|
IRTok ir_tok = {
|
|
.ln = l_op->ln,
|
|
.col = l_op->col,
|
|
.instr = instr,
|
|
.Binary = {
|
|
.addr = 0,
|
|
.lhs = swap_operands ? rhs_irparam : lhs_irparam,
|
|
.rhs = swap_operands ? lhs_irparam : rhs_irparam,
|
|
},
|
|
};
|
|
|
|
/* return if we've just evaluated the last instruction */
|
|
ExprRet ret;
|
|
if (expr_flush_ir_and_maybe_return(out_ir, toks, ir_tok, start, &sc, t, &ret))
|
|
return ret;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
static void expr_into_addr(IRToks *out_ir, TokList *toks, Map *funcs, Scope *parent_sc, TokListItem *t, size_t addr) {
|
|
ExprRet r;
|
|
TRY(r = expr(out_ir, toks, funcs, parent_sc, t));
|
|
if (r.kind == ExprRetLastInstr) {
|
|
set_irtok_dest_addr(&r.LastInstr, addr);
|
|
irtoks_app(out_ir, r.LastInstr);
|
|
t->tok = (Tok){
|
|
.ln = t->tok.ln,
|
|
.col = t->tok.col,
|
|
.kind = TokIdent,
|
|
.Ident = {
|
|
.kind = IdentAddr,
|
|
.Addr = addr,
|
|
},
|
|
};
|
|
} else if (r.kind == ExprRetVal || r.kind == ExprRetIdent) {
|
|
IRParam res;
|
|
TRY(res = tok_to_irparam(parent_sc, &t->tok));
|
|
irtoks_app(out_ir, (IRTok){
|
|
.ln = t->tok.ln,
|
|
.col = t->tok.col,
|
|
.instr = IRSet,
|
|
.Unary = {
|
|
.addr = addr,
|
|
.val = res,
|
|
},
|
|
});
|
|
toklist_del(toks, t, t);
|
|
} else
|
|
ASSERT_UNREACHED();
|
|
}
|
|
|
|
static IRParam expr_into_irparam(IRToks *out_ir, TokList *toks, Map *funcs, Scope *parent_sc, TokListItem *t) {
|
|
ExprRet r;
|
|
TRY_RET(r = expr(out_ir, toks, funcs, parent_sc, t), (IRParam){0});
|
|
if (r.kind == ExprRetLastInstr) {
|
|
Scope sc = make_scope(parent_sc, false);
|
|
size_t addr = sc.mem_addr++;
|
|
set_irtok_dest_addr(&r.LastInstr, addr);
|
|
irtoks_app(out_ir, r.LastInstr);
|
|
return (IRParam){
|
|
.kind = IRParamAddr,
|
|
.Addr = addr,
|
|
};
|
|
} else if (r.kind == ExprRetVal || r.kind == ExprRetIdent) {
|
|
IRParam ret;
|
|
TRY_RET(ret = tok_to_irparam(parent_sc, &t->tok), (IRParam){0});
|
|
toklist_del(toks, t, t);
|
|
return ret;
|
|
} else
|
|
ASSERT_UNREACHED();
|
|
}
|
|
|
|
/* This WILL invalidate *from, so the caller should only call it on a
|
|
* TokListItem after any ones that are in use (e.g. skip_newlns(t->next)). */
|
|
static void skip_newlns(TokList *toks, TokListItem *from) {
|
|
TokListItem *curr = from;
|
|
while (curr->tok.kind == TokOp && curr->tok.Op == OpNewLn)
|
|
curr = curr->next;
|
|
if (curr != from)
|
|
toklist_del(toks, from, curr->prev);
|
|
}
|
|
|
|
static void stmt(IRToks *out_ir, TokList *toks, Map *funcs, Scope *sc, TokListItem *t) {
|
|
TokListItem *start = t;
|
|
if (t->tok.kind == TokIdent && t->tok.Ident.kind == IdentName && (t->next->tok.kind == TokDeclare || t->next->tok.kind == TokAssign)) {
|
|
char *name = t->tok.Ident.Name;
|
|
t = t->next;
|
|
if (t->tok.kind == TokDeclare) {
|
|
size_t addr = sc->mem_addr++;
|
|
bool replaced = map_insert(&sc->ident_addrs, name, &addr);
|
|
if (replaced) {
|
|
mark_err(&start->tok);
|
|
set_err("'%s' already declared in this scope", name);
|
|
return;
|
|
}
|
|
TRY(expr_into_addr(out_ir, toks, funcs, sc, t->next, addr));
|
|
} else if (t->tok.kind == TokAssign) {
|
|
size_t addr;
|
|
TRY(addr = get_ident_addr(sc, name, &start->tok));
|
|
TRY(expr_into_addr(out_ir, toks, funcs, sc, t->next, addr));
|
|
} else
|
|
ASSERT_UNREACHED();
|
|
} else if (t->tok.kind == TokOp && t->tok.Op == OpLCurl) {
|
|
Scope inner_sc = make_scope(sc, true);
|
|
for (;;) {
|
|
skip_newlns(toks, t->next);
|
|
if (t->next->tok.kind == TokOp) {
|
|
if (t->next->tok.Op == OpEOF) {
|
|
term_scope(&inner_sc);
|
|
mark_err(&start->tok);
|
|
set_err("Unclosed '{'");
|
|
return;
|
|
}
|
|
if (t->next->tok.Op == OpRCurl)
|
|
break;
|
|
}
|
|
TRY_ELSE(stmt(out_ir, toks, funcs, &inner_sc, t->next), term_scope(&inner_sc));
|
|
}
|
|
term_scope(&inner_sc);
|
|
t = t->next;
|
|
} else if (t->tok.kind == TokWhile) {
|
|
/* How while is generally implemented in IR:
|
|
* 0: jmp to 3
|
|
* 1: some_code
|
|
* 2: some_code
|
|
* 3: some stuff evaluating condition xyz
|
|
* 4: jmp to 1 if condition xyz is met
|
|
* */
|
|
|
|
/* add initial jmp instruction */
|
|
size_t jmp_instr_iaddr = out_ir->len;
|
|
irtoks_app(out_ir, (IRTok){
|
|
.ln = t->tok.ln,
|
|
.col = t->tok.col,
|
|
.instr = IRJmp,
|
|
.Jmp = {
|
|
.iaddr = 0, /* unknown for now */
|
|
},
|
|
});
|
|
|
|
/* parse condition */
|
|
IRToks cond_ir;
|
|
irtoks_init_short(&cond_ir);
|
|
IRParam cond;
|
|
TRY_ELSE(cond = expr_into_irparam(&cond_ir, toks, funcs, sc, t->next), irtoks_term(&cond_ir));
|
|
|
|
/* parse loop body */
|
|
skip_newlns(toks, t->next);
|
|
TRY_ELSE(stmt(out_ir, toks, funcs, sc, t->next), irtoks_term(&cond_ir));
|
|
|
|
/* finally we know where the jmp from the beginning has to jump to */
|
|
out_ir->toks[jmp_instr_iaddr].Jmp.iaddr = out_ir->len;
|
|
|
|
/* append condition IR to program IR, then terminate condition IR stream */
|
|
irtoks_eat_irtoks(out_ir, &cond_ir, out_ir->len-1);
|
|
|
|
/* add conditional jump */
|
|
irtoks_app(out_ir, (IRTok){
|
|
.ln = t->next->tok.ln,
|
|
.col = t->next->tok.col,
|
|
.instr = IRJnz,
|
|
.CJmp = {
|
|
.iaddr = jmp_instr_iaddr + 1,
|
|
.condition = cond,
|
|
},
|
|
});
|
|
|
|
t = t->next;
|
|
} else if (t->tok.kind == TokIf) {
|
|
/* How if is generally implemented in IR:
|
|
* 0: some stuff evaluating condition xyz
|
|
* 1: jmp to 5 if condition xyz is met
|
|
* 2: some_code in else
|
|
* 4: jmp to 6
|
|
* 5: some_code in if
|
|
* */
|
|
|
|
/* parse condition */
|
|
IRParam cond;
|
|
TRY(cond = expr_into_irparam(out_ir, toks, funcs, sc, t->next));
|
|
|
|
/* add conditional jmp instruction */
|
|
size_t if_cjmp_instr_iaddr = out_ir->len;
|
|
irtoks_app(out_ir, (IRTok){
|
|
.ln = t->tok.ln,
|
|
.col = t->tok.col,
|
|
.instr = IRJnz,
|
|
.CJmp = {
|
|
.iaddr = 0, /* unknown for now */
|
|
.condition = cond,
|
|
},
|
|
});
|
|
|
|
/* parse if body */
|
|
skip_newlns(toks, t->next);
|
|
IRToks if_body;
|
|
irtoks_init_short(&if_body);
|
|
TRY_ELSE(stmt(&if_body, toks, funcs, sc, t->next), irtoks_term(&if_body));
|
|
|
|
skip_newlns(toks, t->next);
|
|
if (t->next->tok.kind == TokElse) {
|
|
toklist_del(toks, t->next, t->next);
|
|
|
|
/* parse and add else body */
|
|
skip_newlns(toks, t->next);
|
|
TRY_ELSE(stmt(out_ir, toks, funcs, sc, t->next), irtoks_term(&if_body));
|
|
}
|
|
|
|
/* add jmp instruction to jump back to common code */
|
|
size_t else_jmp_instr_iaddr = out_ir->len;
|
|
irtoks_app(out_ir, (IRTok){
|
|
.ln = t->tok.ln,
|
|
.col = t->tok.col,
|
|
.instr = IRJmp,
|
|
.Jmp = {
|
|
.iaddr = 0, /* unknown for now */
|
|
},
|
|
});
|
|
|
|
/* set if condition jmp target */
|
|
out_ir->toks[if_cjmp_instr_iaddr].CJmp.iaddr = out_ir->len;
|
|
|
|
/* add if body */
|
|
irtoks_eat_irtoks(out_ir, &if_body, out_ir->len-1);
|
|
|
|
/* set else jmp target */
|
|
out_ir->toks[else_jmp_instr_iaddr].CJmp.iaddr = out_ir->len;
|
|
} else {
|
|
/* assume expression */
|
|
TRY(expr_into_irparam(out_ir, toks, funcs, sc, t));
|
|
return;
|
|
}
|
|
toklist_del(toks, start, t);
|
|
}
|
|
|
|
IRToks parse(TokList *toks, BuiltinFunc *builtin_funcs, size_t n_builtin_funcs) {
|
|
bf = builtin_funcs;
|
|
|
|
Map funcs;
|
|
map_init(&funcs, sizeof(BuiltinFunc));
|
|
for (size_t i = 0; i < n_builtin_funcs; i++) {
|
|
builtin_funcs[i].fid = i;
|
|
bool replaced = map_insert(&funcs, builtin_funcs[i].name, &builtin_funcs[i]);
|
|
if (replaced) {
|
|
err_ln = 0; err_col = 0;
|
|
set_err("Builtin function %s() declared more than once", builtin_funcs[i].name);
|
|
map_term(&funcs);
|
|
return (IRToks){0};
|
|
}
|
|
}
|
|
|
|
IRToks ir;
|
|
irtoks_init_long(&ir);
|
|
Scope global_scope = make_scope(NULL, true);
|
|
for (;;) {
|
|
skip_newlns(toks, toks->begin);
|
|
if (toks->begin->tok.kind == TokOp && toks->begin->tok.Op == OpEOF)
|
|
break;
|
|
TRY_RET_ELSE(stmt(&ir, toks, &funcs, &global_scope, toks->begin), ir,
|
|
{ term_scope(&global_scope); map_term(&funcs); });
|
|
}
|
|
term_scope(&global_scope);
|
|
map_term(&funcs);
|
|
return ir;
|
|
}
|