self->expression.codegen = codegen;
self->expression.vtype = TYPE_VOID;
self->expression.next = NULL;
+ MEM_VECTOR_INIT(&self->expression, params);
}
static void ast_expression_delete(ast_expression *self)
{
+ size_t i;
if (self->expression.next)
ast_delete(self->expression.next);
+ for (i = 0; i < self->expression.params_count; ++i) {
+ ast_delete(self->expression.params[i]);
+ }
+ MEM_VECTOR_CLEAR(&self->expression, params);
}
static void ast_expression_delete_full(ast_expression *self)
mem_d(self);
}
+MEM_VEC_FUNCTIONS(ast_expression_common, ast_value*, params)
+
+static ast_expression* ast_type_copy(lex_ctx ctx, const ast_expression *ex);
+static ast_value* ast_value_copy(const ast_value *self)
+{
+ ast_value *cp = ast_value_new(self->expression.node.context, self->name, self->expression.vtype);
+ if (self->expression.next) {
+ cp->expression.next = ast_type_copy(self->expression.node.context, self->expression.next);
+ if (!cp->expression.next) {
+ ast_value_delete(cp);
+ return NULL;
+ }
+ }
+ return cp;
+}
+
static ast_expression* ast_type_copy(lex_ctx ctx, const ast_expression *ex)
{
- const ast_expression_common *cpex;
+ size_t i;
+ const ast_expression_common *fromex;
ast_expression_common *selfex;
if (!ex)
{
ast_instantiate(ast_expression, ctx, ast_expression_delete_full);
- cpex = &ex->expression;
+ fromex = &ex->expression;
selfex = &self->expression;
- selfex->vtype = cpex->vtype;
- if (cpex->next)
+ /* This may never be codegen()d */
+ selfex->codegen = NULL;
+
+ selfex->vtype = fromex->vtype;
+ if (fromex->next)
{
- selfex->next = ast_type_copy(ctx, cpex->next);
+ selfex->next = ast_type_copy(ctx, fromex->next);
if (!selfex->next) {
- mem_d(self);
+ ast_expression_delete_full(self);
return NULL;
}
}
else
selfex->next = NULL;
- /* This may never be codegen()d */
- selfex->codegen = NULL;
+ for (i = 0; i < fromex->params_count; ++i) {
+ ast_value *v = ast_value_copy(fromex->params[i]);
+ if (!v || !ast_expression_common_params_add(selfex, v)) {
+ ast_expression_delete_full(self);
+ return NULL;
+ }
+ }
+
return self;
}
}
self->name = name ? util_strdup(name) : NULL;
self->expression.vtype = t;
self->expression.next = NULL;
- MEM_VECTOR_INIT(self, params);
self->isconst = false;
memset(&self->constval, 0, sizeof(self->constval));
return self;
}
-MEM_VEC_FUNCTIONS(ast_value, ast_value*, params)
void ast_value_delete(ast_value* self)
{
- size_t i;
if (self->name)
mem_d((void*)self->name);
- for (i = 0; i < self->params_count; ++i)
- ast_value_delete(self->params[i]); /* delete, the ast_function is expected to die first */
- MEM_VECTOR_CLEAR(self, params);
if (self->isconst) {
switch (self->expression.vtype)
{
mem_d(self);
}
+bool GMQCC_WARN ast_value_params_add(ast_value *self, ast_value *p)
+{
+ return ast_expression_common_params_add(&self->expression, p);
+}
+
bool ast_value_set_name(ast_value *self, const char *name)
{
if (self->name)
mem_d(self);
}
+ast_unary* ast_unary_new(lex_ctx ctx, int op,
+ ast_expression *expr)
+{
+ ast_instantiate(ast_unary, ctx, ast_unary_delete);
+ ast_expression_init((ast_expression*)self, (ast_expression_codegen*)&ast_unary_codegen);
+
+ self->op = op;
+ self->operand = expr;
+
+ return self;
+}
+
+void ast_unary_delete(ast_unary *self)
+{
+ ast_unref(self->operand);
+ ast_expression_delete((ast_expression*)self);
+ mem_d(self);
+}
+
+ast_return* ast_return_new(lex_ctx ctx, ast_expression *expr)
+{
+ ast_instantiate(ast_return, ctx, ast_return_delete);
+ ast_expression_init((ast_expression*)self, (ast_expression_codegen*)&ast_return_codegen);
+
+ self->operand = expr;
+
+ return self;
+}
+
+void ast_return_delete(ast_return *self)
+{
+ ast_unref(self->operand);
+ ast_expression_delete((ast_expression*)self);
+ mem_d(self);
+}
+
ast_entfield* ast_entfield_new(lex_ctx ctx, ast_expression *entity, ast_expression *field)
{
const ast_expression *outtype;
mem_d(self);
}
+ast_call* ast_call_new(lex_ctx ctx,
+ ast_expression *funcexpr)
+{
+ ast_instantiate(ast_call, ctx, ast_call_delete);
+ ast_expression_init((ast_expression*)self, (ast_expression_codegen*)&ast_call_codegen);
+
+ MEM_VECTOR_INIT(self, params);
+
+ self->func = funcexpr;
+
+ return self;
+}
+MEM_VEC_FUNCTIONS(ast_call, ast_expression*, params)
+
+void ast_call_delete(ast_call *self)
+{
+ size_t i;
+ for (i = 0; i < self->params_count; ++i)
+ ast_unref(self->params[i]);
+ MEM_VECTOR_CLEAR(self, params);
+
+ if (self->func)
+ ast_unref(self->func);
+
+ ast_expression_delete((ast_expression*)self);
+ mem_d(self);
+}
+
ast_store* ast_store_new(lex_ctx ctx, int op,
ast_value *dest, ast_expression *source)
{
mem_d(self);
}
+bool ast_block_set_type(ast_block *self, ast_expression *from)
+{
+ if (self->expression.next)
+ ast_delete(self->expression.next);
+ self->expression.vtype = from->expression.vtype;
+ if (from->expression.next) {
+ self->expression.next = ast_type_copy(self->expression.node.context, from->expression.next);
+ if (!self->expression.next)
+ return false;
+ }
+ return true;
+}
+
ast_function* ast_function_new(lex_ctx ctx, const char *name, ast_value *vtype)
{
ast_instantiate(ast_function, ctx, ast_function_delete);
MEM_VECTOR_INIT(self, blocks);
self->labelcount = 0;
+ self->builtin = 0;
self->ir_func = NULL;
self->curblock = NULL;
* and the ast-user should take care of ast_global_codegen to be used
* on all the globals.
*/
- if (!self->ir_v)
+ if (!self->ir_v) {
+ printf("ast_value used before generated (%s)\n", self->name);
return false;
+ }
*out = self->ir_v;
return true;
}
ir_value *v = NULL;
if (self->isconst && self->expression.vtype == TYPE_FUNCTION)
{
- ir_function *func = ir_builder_create_function(ir, self->name);
+ ir_function *func = ir_builder_create_function(ir, self->name, self->expression.next->expression.vtype);
if (!func)
return false;
self->constval.vfunc->ir_func = func;
+ self->ir_v = func->value;
/* The function is filled later on ast_function_codegen... */
return true;
}
goto error;
break;
case TYPE_FUNCTION:
+ printf("global of type function not properly generated\n");
+ goto error;
/* Cannot generate an IR value for a function,
* need a pointer pointing to a function rather.
*/
- goto error;
default:
printf("TODO: global constant type %i\n", self->expression.vtype);
break;
return false;
}
-bool ast_local_codegen(ast_value *self, ir_function *func)
+bool ast_local_codegen(ast_value *self, ir_function *func, bool param)
{
ir_value *v = NULL;
if (self->isconst && self->expression.vtype == TYPE_FUNCTION)
return false;
}
- v = ir_function_create_local(func, self->name, self->expression.vtype);
+ v = ir_function_create_local(func, self->name, self->expression.vtype, param);
if (!v)
return false;
{
ir_function *irf;
ir_value *dummy;
+ ast_expression_common *ec;
size_t i;
irf = self->ir_func;
return false;
}
+ /* fill the parameter list */
+ ec = &self->vtype->expression;
+ for (i = 0; i < ec->params_count; ++i)
+ {
+ if (!ir_function_params_add(irf, ec->params[i]->expression.vtype))
+ return false;
+ if (!self->builtin) {
+ if (!ast_local_codegen(ec->params[i], self->ir_func, true))
+ return false;
+ }
+ }
+
+ if (self->builtin) {
+ irf->builtin = self->builtin;
+ return true;
+ }
+
self->curblock = ir_function_create_block(irf, "entry");
if (!self->curblock)
return false;
{
if (!self->vtype->expression.next ||
self->vtype->expression.next->expression.vtype == TYPE_VOID)
+ {
return ir_block_create_return(self->curblock, NULL);
+ }
else
{
/* error("missing return"); */
/* generate locals */
for (i = 0; i < self->locals_count; ++i)
{
- if (!ast_local_codegen(self->locals[i], func->ir_func))
+ if (!ast_local_codegen(self->locals[i], func->ir_func, false))
return false;
}
return true;
}
+bool ast_unary_codegen(ast_unary *self, ast_function *func, bool lvalue, ir_value **out)
+{
+ ast_expression_codegen *cgen;
+ ir_value *operand;
+
+ /* In the context of a unary operation, we can disregard
+ * the lvalue flag.
+ */
+ (void)lvalue;
+
+ cgen = self->operand->expression.codegen;
+ /* lvalue! */
+ if (!(*cgen)((ast_expression*)(self->operand), func, false, &operand))
+ return false;
+
+ *out = ir_block_create_unary(func->curblock, ast_function_label(func, "unary"),
+ self->op, operand);
+ if (!*out)
+ return false;
+
+ return true;
+}
+
+bool ast_return_codegen(ast_return *self, ast_function *func, bool lvalue, ir_value **out)
+{
+ ast_expression_codegen *cgen;
+ ir_value *operand;
+
+ /* In the context of a return operation, we can disregard
+ * the lvalue flag.
+ */
+ (void)lvalue;
+
+ cgen = self->operand->expression.codegen;
+ /* lvalue! */
+ if (!(*cgen)((ast_expression*)(self->operand), func, false, &operand))
+ return false;
+
+ if (!ir_block_create_return(func->curblock, operand))
+ return false;
+
+ return true;
+}
+
bool ast_entfield_codegen(ast_entfield *self, ast_function *func, bool lvalue, ir_value **out)
{
ast_expression_codegen *cgen;
return true;
}
+
+bool ast_call_codegen(ast_call *self, ast_function *func, bool lvalue, ir_value **out)
+{
+ ast_expression_codegen *cgen;
+ ir_value_vector params;
+ ir_instr *callinstr;
+ size_t i;
+
+ ir_value *funval = NULL;
+
+ /* return values are never rvalues */
+ (void)lvalue;
+
+ cgen = self->func->expression.codegen;
+ if (!(*cgen)((ast_expression*)(self->func), func, false, &funval))
+ return false;
+ if (!funval)
+ return false;
+
+ MEM_VECTOR_INIT(¶ms, v);
+
+ /* parameters */
+ for (i = 0; i < self->params_count; ++i)
+ {
+ ir_value *param;
+ ast_expression *expr = self->params[i];
+
+ cgen = expr->expression.codegen;
+ if (!(*cgen)(expr, func, false, ¶m))
+ goto error;
+ if (!param)
+ goto error;
+ if (!ir_value_vector_v_add(¶ms, param))
+ goto error;
+ }
+
+ callinstr = ir_block_create_call(func->curblock, ast_function_label(func, "call"), funval);
+ if (!callinstr)
+ goto error;
+
+ for (i = 0; i < params.v_count; ++i) {
+ if (!ir_call_param(callinstr, params.v[i]))
+ goto error;
+ }
+
+ *out = ir_call_value(callinstr);
+
+ MEM_VECTOR_CLEAR(¶ms, v);
+ return true;
+error:
+ MEM_VECTOR_CLEAR(¶ms, v);
+ return false;
+}
typedef struct ast_ifthen_s ast_ifthen;
typedef struct ast_ternary_s ast_ternary;
typedef struct ast_loop_s ast_loop;
+typedef struct ast_call_s ast_call;
+typedef struct ast_unary_s ast_unary;
+typedef struct ast_return_s ast_return;
/* Node interface with common components
*/
ast_expression_codegen *codegen;
int vtype;
ast_expression *next;
+ MEM_VECTOR_MAKE(ast_value*, params);
} ast_expression_common;
+MEM_VECTOR_PROTO(ast_expression_common, ast_value*, params);
/* Value
*
} constval;
ir_value *ir_v;
-
- /* if vtype is qc_function, params contain parameters, and
- * 'next' the return type.
- */
- MEM_VECTOR_MAKE(ast_value*, params);
};
+
ast_value* ast_value_new(lex_ctx ctx, const char *name, int qctype);
/* This will NOT delete an underlying ast_function */
void ast_value_delete(ast_value*);
bool ast_value_set_name(ast_value*, const char *name);
bool ast_value_codegen(ast_value*, ast_function*, bool lvalue, ir_value**);
-bool ast_local_codegen(ast_value *self, ir_function *func);
+bool ast_local_codegen(ast_value *self, ir_function *func, bool isparam);
bool ast_global_codegen(ast_value *self, ir_builder *ir);
+bool GMQCC_WARN ast_value_params_add(ast_value*, ast_value*);
+
/* Binary
*
* A value-returning binary expression.
bool ast_binary_codegen(ast_binary*, ast_function*, bool lvalue, ir_value**);
+/* Unary
+ *
+ * Regular unary expressions: not,neg
+ */
+struct ast_unary_s
+{
+ ast_expression_common expression;
+
+ int op;
+ ast_expression *operand;
+};
+ast_unary* ast_unary_new(lex_ctx ctx,
+ int op,
+ ast_expression *expr);
+void ast_unary_delete(ast_unary*);
+
+bool ast_unary_codegen(ast_unary*, ast_function*, bool lvalue, ir_value**);
+
+/* Return
+ *
+ * Make sure 'return' only happens at the end of a block, otherwise the IR
+ * will refuse to create further instructions.
+ * This should be honored by the parser.
+ */
+struct ast_return_s
+{
+ ast_expression_common expression;
+ ast_expression *operand;
+};
+ast_return* ast_return_new(lex_ctx ctx,
+ ast_expression *expr);
+void ast_return_delete(ast_return*);
+
+bool ast_return_codegen(ast_return*, ast_function*, bool lvalue, ir_value**);
+
/* Entity-field
*
* This must do 2 things:
bool ast_loop_codegen(ast_loop*, ast_function*, bool lvalue, ir_value**);
+/* CALL node
+ *
+ * Contains an ast_expression as target, rather than an ast_function/value.
+ * Since it's how QC works, every ast_function has an ast_value
+ * associated anyway - in other words, the VM contains function
+ * pointers for every function anyway. Thus, this node will call
+ * expression.
+ * Additionally it contains a list of ast_expressions as parameters.
+ * Since calls can return values, an ast_call is also an ast_expression.
+ */
+struct ast_call_s
+{
+ ast_expression_common expression;
+ ast_expression *func;
+ MEM_VECTOR_MAKE(ast_expression*, params);
+};
+ast_call* ast_call_new(lex_ctx ctx,
+ ast_expression *funcexpr);
+void ast_call_delete(ast_call*);
+bool ast_call_codegen(ast_call*, ast_function*, bool lvalue, ir_value**);
+
+MEM_VECTOR_PROTO(ast_call, ast_expression*, params);
+
/* Blocks
*
*/
};
ast_block* ast_block_new(lex_ctx ctx);
void ast_block_delete(ast_block*);
+bool ast_block_set_type(ast_block*, ast_expression *from);
MEM_VECTOR_PROTO(ast_block, ast_value*, locals);
MEM_VECTOR_PROTO(ast_block, ast_expression*, exprs);
ast_value *vtype;
const char *name;
+ int builtin;
+
ir_function *ir_func;
ir_block *curblock;
ir_block *breakblock;
* This is a hack to silent clang regarding empty
* body if statements.
*/
-#define GMQCC_SUPRESS_EMPTY_BODY do { } while (0)
+#define GMQCC_SUPPRESS_EMPTY_BODY do { } while (0)
/*
* Inline is not supported in < C90, however some compilers
};
extern size_t type_sizeof[TYPE_COUNT];
+extern uint16_t type_store_instr[TYPE_COUNT];
+/* could use type_store_instr + INSTR_STOREP_F - INSTR_STORE_F
+ * but this breaks when TYPE_INTEGER is added, since with the enhanced
+ * instruction set, the old ones are left untouched, thus the _I instructions
+ * are at a seperate place.
+ */
+extern uint16_t type_storep_instr[TYPE_COUNT];
typedef struct {
uint32_t offset; /* Offset in file of where data begins */
{ "EQ_V" , 0, 4 },
{ "EQ_S" , 0, 4 },
{ "EQ_E" , 0, 4 },
- { "ES_FNC" , 0, 6 },
+ { "EQ_FNC" , 0, 6 },
{ "NE_F" , 0, 4 },
{ "NE_V" , 0, 4 },
{ "NE_S" , 0, 4 },
size_t name##_count; \
size_t name##_alloc
-#define _MEM_VEC_FUN_ADD(Tself, Twhat, mem) \
+#define MEM_VEC_FUN_ADD(Tself, Twhat, mem) \
bool GMQCC_WARN Tself##_##mem##_add(Tself *self, Twhat f) \
{ \
Twhat *reall; \
return true; \
}
-#define _MEM_VEC_FUN_REMOVE(Tself, Twhat, mem) \
+#define MEM_VEC_FUN_REMOVE(Tself, Twhat, mem) \
bool GMQCC_WARN Tself##_##mem##_remove(Tself *self, size_t idx) \
{ \
size_t i; \
return true; \
}
-#define _MEM_VEC_FUN_FIND(Tself, Twhat, mem) \
+#define MEM_VEC_FUN_FIND(Tself, Twhat, mem) \
bool GMQCC_WARN Tself##_##mem##_find(Tself *self, Twhat obj, size_t *idx) \
{ \
size_t i; \
return false; \
}
-#define _MEM_VEC_FUN_APPEND(Tself, Twhat, mem) \
+#define MEM_VEC_FUN_APPEND(Tself, Twhat, mem) \
bool GMQCC_WARN Tself##_##mem##_append(Tself *s, Twhat *p, size_t c) \
{ \
Twhat *reall; \
return true; \
}
-#define _MEM_VEC_FUN_RESIZE(Tself, Twhat, mem) \
+#define MEM_VEC_FUN_RESIZE(Tself, Twhat, mem) \
bool GMQCC_WARN Tself##_##mem##_resize(Tself *s, size_t c) \
{ \
Twhat *reall; \
return true; \
}
-#define _MEM_VEC_FUN_CLEAR(Tself, mem) \
+#define MEM_VEC_FUN_CLEAR(Tself, mem) \
void Tself##_##mem##_clear(Tself *self) \
{ \
if (!self->mem) \
}
#define MEM_VEC_FUNCTIONS(Tself, Twhat, mem) \
-_MEM_VEC_FUN_REMOVE(Tself, Twhat, mem) \
-_MEM_VEC_FUN_ADD(Tself, Twhat, mem)
+MEM_VEC_FUN_REMOVE(Tself, Twhat, mem) \
+MEM_VEC_FUN_ADD(Tself, Twhat, mem)
#define MEM_VEC_FUNCTIONS_ALL(Tself, Twhat, mem) \
MEM_VEC_FUNCTIONS(Tself, Twhat, mem) \
-_MEM_VEC_FUN_CLEAR(Tself, mem) \
-_MEM_VEC_FUN_FIND(Tself, Twhat, mem)
+MEM_VEC_FUN_CLEAR(Tself, mem) \
+MEM_VEC_FUN_FIND(Tself, Twhat, mem)
enum store_types {
store_global,
store_local, /* local, assignable for now, should get promoted later */
- store_value /* unassignable */
+ store_param, /* parameters, they are locals with a fixed position */
+ store_value, /* unassignable */
+ store_return /* unassignable, at OFS_RETURN */
};
typedef struct {
3, /* TYPE_VARIANT */
};
+uint16_t type_store_instr[TYPE_COUNT] = {
+ INSTR_STORE_F, /* should use I when having integer support */
+ INSTR_STORE_S,
+ INSTR_STORE_F,
+ INSTR_STORE_V,
+ INSTR_STORE_ENT,
+ INSTR_STORE_FLD,
+ INSTR_STORE_FNC,
+ INSTR_STORE_ENT, /* should use I */
+#if 0
+ INSTR_STORE_ENT, /* integer type */
+#endif
+ INSTR_STORE_V, /* variant, should never be accessed */
+};
+
+uint16_t type_storep_instr[TYPE_COUNT] = {
+ INSTR_STOREP_F, /* should use I when having integer support */
+ INSTR_STOREP_S,
+ INSTR_STOREP_F,
+ INSTR_STOREP_V,
+ INSTR_STOREP_ENT,
+ INSTR_STOREP_FLD,
+ INSTR_STOREP_FNC,
+ INSTR_STOREP_ENT, /* should use I */
+#if 0
+ INSTR_STOREP_ENT, /* integer type */
+#endif
+ INSTR_STOREP_V, /* variant, should never be accessed */
+};
+
+MEM_VEC_FUNCTIONS(ir_value_vector, ir_value*, v)
+
/***********************************************************************
*IR Builder
*/
return NULL;
}
-ir_function* ir_builder_create_function(ir_builder *self, const char *name)
+ir_function* ir_builder_create_function(ir_builder *self, const char *name, int outtype)
{
ir_function *fn = ir_builder_get_function(self, name);
if (fn) {
return NULL;
}
- fn = ir_function_new(self);
+ fn = ir_function_new(self, outtype);
if (!ir_function_set_name(fn, name) ||
!ir_builder_functions_add(self, fn) )
{
ir_function_delete(fn);
return NULL;
}
+
+ fn->value = ir_builder_create_global(self, fn->name, TYPE_FUNCTION);
+ if (!fn->value) {
+ ir_function_delete(fn);
+ return NULL;
+ }
+
+ fn->value->isconst = true;
+ fn->value->outtype = outtype;
+ fn->value->constval.vfunc = fn;
+ fn->value->context = fn->context;
+
return fn;
}
bool ir_function_calculate_liferanges(ir_function*);
bool ir_function_allocate_locals(ir_function*);
-ir_function* ir_function_new(ir_builder* owner)
+ir_function* ir_function_new(ir_builder* owner, int outtype)
{
ir_function *self;
self = (ir_function*)mem_a(sizeof(*self));
self->owner = owner;
self->context.file = "<@no context>";
self->context.line = 0;
- self->retype = TYPE_VOID;
+ self->outtype = outtype;
+ self->value = NULL;
+ self->builtin = 0;
MEM_VECTOR_INIT(self, params);
MEM_VECTOR_INIT(self, blocks);
MEM_VECTOR_INIT(self, values);
MEM_VEC_FUNCTIONS(ir_function, ir_value*, values)
MEM_VEC_FUNCTIONS(ir_function, ir_block*, blocks)
MEM_VEC_FUNCTIONS(ir_function, ir_value*, locals)
+MEM_VEC_FUNCTIONS(ir_function, int, params)
bool ir_function_set_name(ir_function *self, const char *name)
{
ir_value_delete(self->locals[i]);
MEM_VECTOR_CLEAR(self, locals);
+ /* self->value is deleted by the builder */
+
mem_d(self);
}
bool ir_function_finalize(ir_function *self)
{
+ if (self->builtin)
+ return true;
+
if (!ir_function_naive_phi(self))
return false;
return NULL;
}
-ir_value* ir_function_create_local(ir_function *self, const char *name, int vtype)
+ir_value* ir_function_create_local(ir_function *self, const char *name, int vtype, bool param)
{
ir_value *ve = ir_function_get_local(self, name);
if (ve) {
return NULL;
}
- ve = ir_value_var(name, store_local, vtype);
+ if (param &&
+ self->locals_count &&
+ self->locals[self->locals_count-1]->store != store_param) {
+ printf("cannot add parameters after adding locals\n");
+ return NULL;
+ }
+
+ ve = ir_value_var(name, (param ? store_param : store_local), vtype);
if (!ir_function_locals_add(self, ve)) {
ir_value_delete(ve);
return NULL;
self->bops[0] = NULL;
self->bops[1] = NULL;
MEM_VECTOR_INIT(self, phi);
+ MEM_VECTOR_INIT(self, params);
self->eid = 0;
return self;
}
MEM_VEC_FUNCTIONS(ir_instr, ir_phi_entry_t, phi)
+MEM_VEC_FUNCTIONS(ir_instr, ir_value*, params)
void ir_instr_delete(ir_instr *self)
{
for (i = 0; i < self->phi_count; ++i) {
size_t idx;
if (ir_value_writes_find(self->phi[i].value, self, &idx))
- if (ir_value_writes_remove(self->phi[i].value, idx)) GMQCC_SUPRESS_EMPTY_BODY;
+ if (ir_value_writes_remove(self->phi[i].value, idx)) GMQCC_SUPPRESS_EMPTY_BODY;
if (ir_value_reads_find(self->phi[i].value, self, &idx))
- if (ir_value_reads_remove (self->phi[i].value, idx)) GMQCC_SUPRESS_EMPTY_BODY;
+ if (ir_value_reads_remove (self->phi[i].value, idx)) GMQCC_SUPPRESS_EMPTY_BODY;
}
MEM_VECTOR_CLEAR(self, phi);
- if (ir_instr_op(self, 0, NULL, false)) GMQCC_SUPRESS_EMPTY_BODY;
- if (ir_instr_op(self, 1, NULL, false)) GMQCC_SUPRESS_EMPTY_BODY;
- if (ir_instr_op(self, 2, NULL, false)) GMQCC_SUPRESS_EMPTY_BODY;
+ for (i = 0; i < self->params_count; ++i) {
+ size_t idx;
+ if (ir_value_writes_find(self->params[i], self, &idx))
+ if (ir_value_writes_remove(self->params[i], idx)) GMQCC_SUPPRESS_EMPTY_BODY;
+ if (ir_value_reads_find(self->params[i], self, &idx))
+ if (ir_value_reads_remove (self->params[i], idx)) GMQCC_SUPPRESS_EMPTY_BODY;
+ }
+ MEM_VECTOR_CLEAR(self, params);
+ if (ir_instr_op(self, 0, NULL, false)) GMQCC_SUPPRESS_EMPTY_BODY;
+ if (ir_instr_op(self, 1, NULL, false)) GMQCC_SUPPRESS_EMPTY_BODY;
+ if (ir_instr_op(self, 2, NULL, false)) GMQCC_SUPPRESS_EMPTY_BODY;
mem_d(self);
}
self = (ir_value*)mem_a(sizeof(*self));
self->vtype = vtype;
self->fieldtype = TYPE_VOID;
+ self->outtype = TYPE_VOID;
self->store = storetype;
MEM_VECTOR_INIT(self, reads);
MEM_VECTOR_INIT(self, writes);
return true;
}
+bool ir_value_set_func(ir_value *self, int f)
+{
+ if (self->vtype != TYPE_FUNCTION)
+ return false;
+ self->constval.vint = f;
+ self->isconst = true;
+ return true;
+}
+
bool ir_value_set_vector(ir_value *self, vector v)
{
if (self->vtype != TYPE_VECTOR)
else
vtype = target->vtype;
- switch (vtype) {
- case TYPE_FLOAT:
-#if 0
- if (what->vtype == TYPE_INTEGER)
- op = INSTR_CONV_ITOF;
- else
-#endif
- op = INSTR_STORE_F;
- break;
- case TYPE_VECTOR:
- op = INSTR_STORE_V;
- break;
- case TYPE_ENTITY:
- op = INSTR_STORE_ENT;
- break;
- case TYPE_STRING:
- op = INSTR_STORE_S;
- break;
- case TYPE_FIELD:
- op = INSTR_STORE_FLD;
- break;
#if 0
- case TYPE_INTEGER:
- if (what->vtype == TYPE_INTEGER)
- op = INSTR_CONV_FTOI;
- else
- op = INSTR_STORE_I;
- break;
+ if (vtype == TYPE_FLOAT && what->vtype == TYPE_INTEGER)
+ op = INSTR_CONV_ITOF;
+ else if (vtype == TYPE_INTEGER && what->vtype == TYPE_FLOAT)
+ op = INSTR_CONV_FTOI;
#endif
- case TYPE_POINTER:
-#if 0
- op = INSTR_STORE_I;
-#else
- op = INSTR_STORE_ENT;
-#endif
- break;
- default:
- /* Unknown type */
- return false;
- }
+ op = type_store_instr[vtype];
+
return ir_block_create_store_op(self, op, target, what);
}
*/
vtype = what->vtype;
- switch (vtype) {
- case TYPE_FLOAT:
- op = INSTR_STOREP_F;
- break;
- case TYPE_VECTOR:
- op = INSTR_STOREP_V;
- break;
- case TYPE_ENTITY:
- op = INSTR_STOREP_ENT;
- break;
- case TYPE_STRING:
- op = INSTR_STOREP_S;
- break;
- case TYPE_FIELD:
- op = INSTR_STOREP_FLD;
- break;
-#if 0
- case TYPE_INTEGER:
- op = INSTR_STOREP_I;
- break;
-#endif
- case TYPE_POINTER:
-#if 0
- op = INSTR_STOREP_I;
-#else
- op = INSTR_STOREP_ENT;
-#endif
- break;
- default:
- /* Unknown type */
- return false;
- }
+ op = type_storep_instr[vtype];
+
return ir_block_create_store_op(self, op, target, what);
}
return ir_instr_phi_add(self, pe);
}
+/* call related code */
+ir_instr* ir_block_create_call(ir_block *self, const char *label, ir_value *func)
+{
+ ir_value *out;
+ ir_instr *in;
+ in = ir_instr_new(self, INSTR_CALL0);
+ if (!in)
+ return NULL;
+ out = ir_value_out(self->owner, label, store_return, func->outtype);
+ if (!out) {
+ ir_instr_delete(in);
+ return NULL;
+ }
+ if (!ir_instr_op(in, 0, out, true) ||
+ !ir_instr_op(in, 1, func, false) ||
+ !ir_block_instr_add(self, in))
+ {
+ ir_instr_delete(in);
+ ir_value_delete(out);
+ return NULL;
+ }
+ return in;
+}
+
+ir_value* ir_call_value(ir_instr *self)
+{
+ return self->_ops[0];
+}
+
+bool ir_call_param(ir_instr* self, ir_value *v)
+{
+ if (!ir_instr_params_add(self, v))
+ return false;
+ if (!ir_value_reads_add(v, self)) {
+ if (!ir_instr_params_remove(self, self->params_count-1))
+ GMQCC_SUPPRESS_EMPTY_BODY;
+ return false;
+ }
+ return true;
+}
+
/* binary op related code */
ir_value* ir_block_create_binop(ir_block *self,
return ir_block_create_general_instr(self, label, opcode, left, right, ot);
}
+ir_value* ir_block_create_unary(ir_block *self,
+ const char *label, int opcode,
+ ir_value *operand)
+{
+ int ot = TYPE_FLOAT;
+ switch (opcode) {
+ case INSTR_NOT_F:
+ case INSTR_NOT_V:
+ case INSTR_NOT_S:
+ case INSTR_NOT_ENT:
+ case INSTR_NOT_FNC:
+#if 0
+ case INSTR_NOT_I:
+#endif
+ ot = TYPE_FLOAT;
+ break;
+ /* QC doesn't have other unary operations. We expect extensions to fill
+ * the above list, otherwise we assume out-type = in-type, eg for an
+ * unary minus
+ */
+ default:
+ ot = operand->vtype;
+ break;
+ };
+ if (ot == TYPE_VOID) {
+ /* The AST or parser were supposed to check this! */
+ return NULL;
+ }
+
+ /* let's use the general instruction creator and pass NULL for OPB */
+ return ir_block_create_general_instr(self, label, opcode, operand, NULL, ot);
+}
+
ir_value* ir_block_create_general_instr(ir_block *self, const char *label,
int op, ir_value *a, ir_value *b, int outype)
{
if (v->writes[w]->_ops[0] == v)
v->writes[w]->_ops[0] = instr->_ops[0];
- if (old->store != store_value && old->store != store_local)
+ if (old->store != store_value && old->store != store_local && old->store != store_param)
{
/* If it originally wrote to a global we need to store the value
* there as welli
function_allocator alloc;
+ if (!self->locals_count)
+ return true;
+
MEM_VECTOR_INIT(&alloc, locals);
MEM_VECTOR_INIT(&alloc, sizes);
MEM_VECTOR_INIT(&alloc, positions);
if (!function_allocator_positions_add(&alloc, 0))
goto error;
+ if (alloc.sizes_count)
+ pos = alloc.positions[0] + alloc.sizes[0];
+ else
+ pos = 0;
for (i = 1; i < alloc.sizes_count; ++i)
{
pos = alloc.positions[i-1] + alloc.sizes[i-1];
value = instr->_ops[o];
/* We only care about locals */
+ /* we also calculate parameter liferanges so that locals
+ * can take up parameter slots */
if (value->store != store_value &&
- value->store != store_local)
+ value->store != store_local &&
+ value->store != store_param)
continue;
/* read operands */
}
if (instr->opcode >= INSTR_CALL0 && instr->opcode <= INSTR_CALL8) {
- printf("TODO: call instruction\n");
- return false;
+ /* Trivial call translation:
+ * copy all params to OFS_PARM*
+ * if the output's storetype is not store_return,
+ * add append a STORE instruction!
+ *
+ * NOTES on how to do it better without much trouble:
+ * -) The liferanges!
+ * Simply check the liferange of all parameters for
+ * other CALLs. For each param with no CALL in its
+ * liferange, we can store it in an OFS_PARM at
+ * generation already. This would even include later
+ * reuse.... probably... :)
+ */
+ size_t p;
+ ir_value *retvalue;
+
+ for (p = 0; p < instr->params_count; ++p)
+ {
+ ir_value *param = instr->params[p];
+
+ stmt.opcode = INSTR_STORE_F;
+ stmt.o3.u1 = 0;
+
+ stmt.opcode = type_store_instr[param->vtype];
+ stmt.o1.u1 = param->code.globaladdr;
+ stmt.o2.u1 = OFS_PARM0 + 3 * p;
+ if (code_statements_add(stmt) < 0)
+ return false;
+ }
+ stmt.opcode = INSTR_CALL0 + instr->params_count;
+ if (stmt.opcode > INSTR_CALL8)
+ stmt.opcode = INSTR_CALL8;
+ stmt.o1.u1 = instr->_ops[1]->code.globaladdr;
+ stmt.o2.u1 = 0;
+ stmt.o3.u1 = 0;
+ if (code_statements_add(stmt) < 0)
+ return false;
+
+ retvalue = instr->_ops[0];
+ if (retvalue && retvalue->store != store_return && retvalue->life_count)
+ {
+ /* not to be kept in OFS_RETURN */
+ stmt.opcode = type_store_instr[retvalue->vtype];
+ stmt.o1.u1 = OFS_RETURN;
+ stmt.o2.u1 = retvalue->code.globaladdr;
+ stmt.o3.u1 = 0;
+ if (code_statements_add(stmt) < 0)
+ return false;
+ }
+ continue;
}
if (instr->opcode == INSTR_STATE) {
stmt.o1.u1 = stmt.o3.u1;
stmt.o3.u1 = 0;
}
- else if ((stmt.opcode >= INSTR_STORE_F &&
- stmt.opcode <= INSTR_STORE_FNC) ||
- (stmt.opcode >= INSTR_NOT_F &&
- stmt.opcode <= INSTR_NOT_FNC))
+ else if (stmt.opcode >= INSTR_STORE_F &&
+ stmt.opcode <= INSTR_STORE_FNC)
{
/* 2-operand instructions with A -> B */
stmt.o2.u1 = stmt.o3.u1;
static bool gen_function_code(ir_function *self)
{
ir_block *block;
+ prog_section_statement stmt;
/* Starting from entry point, we generate blocks "as they come"
* for now. Dead blocks will not be translated obviously.
printf("failed to generate blocks for '%s'\n", self->name);
return false;
}
+
+ /* otherwise code_write crashes since it debug-prints functions until AINSTR_END */
+ stmt.opcode = AINSTR_END;
+ stmt.o1.u1 = 0;
+ stmt.o2.u1 = 0;
+ stmt.o3.u1 = 0;
+ if (code_statements_add(stmt) < 0)
+ return false;
return true;
}
size_t i;
size_t local_var_end;
- if (!global->isconst ||
- !global->constval.vfunc)
+ if (!global->isconst || (!global->constval.vfunc))
{
printf("Invalid state of function-global: not constant: %s\n", global->name);
return false;
for (i = 0;i < 8; ++i) {
if (i >= fun.nargs)
fun.argsize[i] = 0;
- else if (irfun->params[i] == TYPE_VECTOR)
- fun.argsize[i] = 3;
else
- fun.argsize[i] = 1;
+ fun.argsize[i] = type_sizeof[irfun->params[i]];
}
fun.firstlocal = code_globals_elements;
code_globals_add(0);
}
- fun.entry = code_statements_elements;
- if (!gen_function_code(irfun)) {
- printf("Failed to generate code for function %s\n", irfun->name);
- return false;
+ if (irfun->builtin)
+ fun.entry = irfun->builtin;
+ else {
+ fun.entry = code_statements_elements;
+ if (!gen_function_code(irfun)) {
+ printf("Failed to generate code for function %s\n", irfun->name);
+ return false;
+ }
}
return (code_functions_add(fun) >= 0);
static bool ir_builder_gen_global(ir_builder *self, ir_value *global)
{
+ size_t i;
int32_t *iptr;
prog_section_def def;
}
case TYPE_VECTOR:
{
+ size_t d;
if (code_defs_add(def) < 0)
return false;
if (global->isconst) {
iptr = (int32_t*)&global->constval.vvec;
global->code.globaladdr = code_globals_add(iptr[0]);
- if (code_globals_add(iptr[1]) < 0 || code_globals_add(iptr[2]) < 0)
+ if (global->code.globaladdr < 0)
return false;
+ for (d = 1; d < type_sizeof[global->vtype]; ++d)
+ {
+ if (code_globals_add(iptr[d]) < 0)
+ return false;
+ }
} else {
global->code.globaladdr = code_globals_add(0);
- if (code_globals_add(0) < 0 || code_globals_add(0) < 0)
+ if (global->code.globaladdr < 0)
return false;
+ for (d = 1; d < type_sizeof[global->vtype]; ++d)
+ {
+ if (code_globals_add(0) < 0)
+ return false;
+ }
}
return global->code.globaladdr >= 0;
}
case TYPE_FUNCTION:
if (code_defs_add(def) < 0)
return false;
+ global->code.globaladdr = code_globals_elements;
code_globals_add(code_functions_elements);
return gen_global_function(self, global);
case TYPE_VARIANT:
/* assume biggest type */
global->code.globaladdr = code_globals_add(0);
- code_globals_add(0);
- code_globals_add(0);
+ for (i = 1; i < type_sizeof[TYPE_VARIANT]; ++i)
+ code_globals_add(0);
return true;
default:
/* refuse to create 'void' type or any other fancy business. */
code_init();
- /* FIXME: generate TYPE_FUNCTION globals and link them
- * to their ir_function.
- */
-
- for (i = 0; i < self->functions_count; ++i)
- {
- ir_value *funval;
- ir_function *fun = self->functions[i];
-
- funval = ir_builder_create_global(self, fun->name, TYPE_FUNCTION);
- funval->isconst = true;
- funval->constval.vfunc = fun;
- funval->context = fun->context;
- }
-
for (i = 0; i < self->globals_count; ++i)
{
if (!ir_builder_gen_global(self, self->globals[i])) {
int (*oprintf)(const char*, ...))
{
size_t i;
+ if (f->builtin != 0) {
+ oprintf("%sfunction %s = builtin %i\n", ind, f->name, -f->builtin);
+ return;
+ }
oprintf("%sfunction %s\n", ind, f->name);
strncat(ind, "\t", IND_BUFSZ);
if (f->locals_count)
lex_ctx context;
/* even the IR knows the subtype of a field */
int fieldtype;
+ /* and the output type of a function */
+ int outtype;
MEM_VECTOR_MAKE(struct ir_instr_s*, reads);
MEM_VECTOR_MAKE(struct ir_instr_s*, writes);
MEM_VECTOR_PROTO_ALL(ir_value, struct ir_instr_s*, writes);
bool GMQCC_WARN ir_value_set_float(ir_value*, float f);
+bool GMQCC_WARN ir_value_set_func(ir_value*, int f);
#if 0
bool GMQCC_WARN ir_value_set_int(ir_value*, int i);
#endif
void ir_value_dump(ir_value*, int (*oprintf)(const char*,...));
void ir_value_dump_life(ir_value *self, int (*oprintf)(const char*,...));
+/* A vector of IR values */
+typedef struct {
+ MEM_VECTOR_MAKE(ir_value*, v);
+} ir_value_vector;
+MEM_VECTOR_PROTO(ir_value_vector, ir_value*, v);
+
+/* PHI data */
typedef struct ir_phi_entry_s
{
ir_value *value;
struct ir_block_s* (bops[2]);
MEM_VECTOR_MAKE(ir_phi_entry_t, phi);
+ MEM_VECTOR_MAKE(ir_value*, params);
/* For the temp-allocation */
size_t eid;
MEM_VECTOR_PROTO(ir_value, ir_phi_entry_t, phi);
bool GMQCC_WARN ir_instr_op(ir_instr*, int op, ir_value *value, bool writing);
+MEM_VECTOR_PROTO(ir_value, ir_value*, params);
+
void ir_instr_dump(ir_instr* in, char *ind, int (*oprintf)(const char*,...));
/* block */
ir_value* ir_block_create_binop(ir_block*, const char *label, int op,
ir_value *left, ir_value *right);
+ir_value* ir_block_create_unary(ir_block*, const char *label, int op,
+ ir_value *operand);
bool GMQCC_WARN ir_block_create_store_op(ir_block*, int op, ir_value *target, ir_value *what);
bool GMQCC_WARN ir_block_create_store(ir_block*, ir_value *target, ir_value *what);
bool GMQCC_WARN ir_block_create_storep(ir_block*, ir_value *target, ir_value *what);
ir_instr* ir_block_create_phi(ir_block*, const char *label, int vtype);
ir_value* ir_phi_value(ir_instr*);
bool GMQCC_WARN ir_phi_add(ir_instr*, ir_block *b, ir_value *v);
+ir_instr* ir_block_create_call(ir_block*, const char *label, ir_value *func);
+ir_value* ir_call_value(ir_instr*);
+bool GMQCC_WARN ir_call_param(ir_instr*, ir_value*);
bool GMQCC_WARN ir_block_create_return(ir_block*, ir_value *opt_value);
typedef struct ir_function_s
{
char *name;
- int retype;
+ int outtype;
MEM_VECTOR_MAKE(int, params);
MEM_VECTOR_MAKE(ir_block*, blocks);
+ int builtin;
+
+ ir_value *value;
+
/* values generated from operations
* which might get optimized away, so anything
* in there needs to be deleted in the dtor.
struct ir_builder_s *owner;
} ir_function;
-ir_function* ir_function_new(struct ir_builder_s *owner);
+ir_function* ir_function_new(struct ir_builder_s *owner, int returntype);
void ir_function_delete(ir_function*);
bool GMQCC_WARN ir_function_collect_value(ir_function*, ir_value *value);
MEM_VECTOR_PROTO(ir_function, ir_block*, blocks);
ir_value* ir_function_get_local(ir_function *self, const char *name);
-ir_value* ir_function_create_local(ir_function *self, const char *name, int vtype);
+ir_value* ir_function_create_local(ir_function *self, const char *name, int vtype, bool param);
bool GMQCC_WARN ir_function_finalize(ir_function*);
/*
MEM_VECTOR_PROTO(ir_builder, ir_value*, globals);
ir_function* ir_builder_get_function(ir_builder*, const char *fun);
-ir_function* ir_builder_create_function(ir_builder*, const char *name);
+ir_function* ir_builder_create_function(ir_builder*, const char *name, int outtype);
ir_value* ir_builder_get_global(ir_builder*, const char *fun);
ir_value* ir_builder_create_global(ir_builder*, const char *name, int vtype);
MKGLOBAL(name); \
} while(0)
+#define MKCONSTSTRING(name, value) \
+do { \
+ name->isconst = true; \
+ name->constval.vstring = util_strdup(value); \
+ MKGLOBAL(name); \
+} while(0)
+
#define STATE(a) \
do { \
ast_expression *exp = (ast_expression*)(a); \
#define BIN(op, a, b) \
(ast_expression*)ast_binary_new(ctx, INSTR_##op, (ast_expression*)(a), (ast_expression*)(b))
+#define CALL(what) \
+do { \
+ ast_call *call = ast_call_new(ctx, (ast_expression*)what); \
+
+#define CALLPARAM(x) \
+ assert(ast_call_params_add(call, (ast_expression*)x));
+
+#define ENDCALL() \
+ STATE(call); \
+} while(0)
+
#define WHILE(cond) \
do { \
ast_expression *wh_cond = (ast_expression*)(cond); \
STATE(loop); \
} while(0)
-#define FUNCTION(name) \
-do { \
- ast_function *func_##name; \
- ast_block *my_funcblock; \
- DEFVAR(var_##name); \
- VARnamed(TYPE_FUNCTION, var_##name, name); \
- MKGLOBAL(var_##name); \
- func_##name = ast_function_new(ctx, #name, var_##name); \
- assert(functions_add(func_##name) >= 0); \
- my_funcblock = ast_block_new(ctx); \
- assert(my_funcblock); \
- assert(ast_function_blocks_add(func_##name, my_funcblock)); \
+#define BUILTIN(name, outtype, number) \
+do { \
+ ast_function *func_##name; \
+ ast_value *thisfuncval; \
+ ast_function *thisfunc; \
+ DEFVAR(return_##name); \
+ VARnamed(TYPE_FUNCTION, name, name); \
+ VARnamed(outtype, return_##name, "#returntype"); \
+ name->expression.next = (ast_expression*)return_##name; \
+ MKGLOBAL(name); \
+ func_##name = ast_function_new(ctx, #name, name); \
+ thisfunc = func_##name; \
+ (void)thisfunc; \
+ thisfuncval = name; \
+ (void)thisfuncval; \
+ assert(functions_add(func_##name) >= 0); \
+ func_##name->builtin = number;
+
+#define ENDBUILTIN() } while(0)
+
+#define PARAM(ptype, name) \
+do { \
+ DEFVAR(parm); \
+ VARnamed(ptype, parm, name); \
+ assert(ast_value_params_add(thisfuncval, parm)); \
+} while(0)
+
+#define FUNCTION(name, outtype) \
+do { \
+ ast_function *thisfunc; \
+ ast_function *func_##name; \
+ ast_block *my_funcblock; \
+ DEFVAR(var_##name); \
+ DEFVAR(return_##name); \
+ VARnamed(TYPE_FUNCTION, var_##name, name); \
+ VARnamed(outtype, return_##name, "#returntype"); \
+ var_##name->expression.next = (ast_expression*)return_##name; \
+ MKGLOBAL(var_##name); \
+ func_##name = ast_function_new(ctx, #name, var_##name); \
+ thisfunc = func_##name; \
+ (void)thisfunc; \
+ assert(functions_add(func_##name) >= 0); \
+ my_funcblock = ast_block_new(ctx); \
+ assert(my_funcblock); \
+ assert(ast_function_blocks_add(func_##name, my_funcblock)); \
curblock = my_funcblock;
#define MKLOCAL(var) \
DEFVAR(f0);
DEFVAR(f1);
DEFVAR(f5);
+ DEFVAR(sHello);
+ DEFVAR(print);
+
+ /* opts_debug = true; */
+
+BUILTIN(print, TYPE_VOID, -1);
+PARAM(TYPE_STRING, text);
+ENDBUILTIN();
TESTINIT();
VAR(TYPE_FLOAT, f0);
VAR(TYPE_FLOAT, f1);
VAR(TYPE_FLOAT, f5);
+VAR(TYPE_STRING, sHello);
MKCONSTFLOAT(f0, 0.0);
MKCONSTFLOAT(f1, 1.0);
MKCONSTFLOAT(f5, 5.0);
+MKCONSTSTRING(sHello, "Hello, World\n");
+
+FUNCTION(foo, TYPE_VOID);
+ENDFUNCTION(foo);
+
+FUNCTION(main, TYPE_VOID);
-FUNCTION(main);
+ VAR(TYPE_FLOAT, vi);
+ VAR(TYPE_FLOAT, vx);
-VAR(TYPE_FLOAT, vi);
-VAR(TYPE_FLOAT, vx);
+ MKLOCAL(vi);
+ MKLOCAL(vx);
-MKLOCAL(vi);
-MKLOCAL(vx);
+ STATE(ASSIGN(STORE_F, vi, f0));
+ WHILE(BIN(LT, vi, f5));
+ STATE(ASSIGN(STORE_F, vx, BIN(MUL_F, vi, f5)));
+ STATE(ASSIGN(STORE_F, vi, BIN(ADD_F, vi, f1)));
+ ENDWHILE();
-STATE(ASSIGN(STORE_F, vi, f0));
-WHILE(BIN(LT, vi, f5));
-STATE(ASSIGN(STORE_F, vx, BIN(MUL_F, vi, f5)));
-STATE(ASSIGN(STORE_F, vi, BIN(ADD_F, vi, f1)));
-ENDWHILE();
+ CALL(print)
+ CALLPARAM(sHello)
+ ENDCALL();
ENDFUNCTION(main);