https://github.com/JuliaLang/julia
Tip revision: 5af191ecb431aa9a75d5adb06fb65a21e4479d9d authored by Keno Fischer on 02 April 2018, 21:42:56 UTC
WIP for XLA demo
WIP for XLA demo
Tip revision: 5af191e
subtype.c
// This file is a part of Julia. License is MIT: https://julialang.org/license
/*
subtyping predicate
Uses the algorithm described in section 4.2.2 of https://github.com/JeffBezanson/phdthesis/
This code adds the following features to the core algorithm:
- Type variables can be restricted to range over only concrete types.
This is done by returning false if such a variable's lower bound is not concrete.
- Diagonal rule: a type variable is concrete if it occurs more than once in
covariant position, and never in invariant position. This sounds like a syntactic
property, but actually isn't since it depends on which occurrences of a type
variable the algorithm actually uses.
- Unconstrained type vars (Bottom<:T<:Any) can match non-type values.
- Vararg types have an int-valued length parameter N (in `Vararg{T,N}`).
- Type{T}<:S if isa(T,S). Existing code assumes this, but it's not strictly
correct since a type can equal `T` without having the same representation.
- Free type variables are tolerated. This can hopefully be removed after a
deprecation period.
*/
#include <stdlib.h>
#include <string.h>
#ifdef _OS_WINDOWS_
#include <malloc.h>
#endif
#include "julia.h"
#include "julia_internal.h"
#include "julia_assert.h"
#ifdef __cplusplus
extern "C" {
#endif
// stack of bits to keep track of which combination of Union components we are
// looking at (0 for Union.a, 1 for Union.b). forall_exists_subtype and
// exists_subtype loop over all combinations by updating a binary count in
// this structure.
// Union type decision points are discovered while the algorithm works.
// If a new Union decision is encountered, the `more` flag is set to tell
// the forall/exists loop to grow the stack.
// TODO: the stack probably needs to be artifically large because of some
// deeper problem (see #21191) and could be shrunk once that is fixed
typedef struct {
int depth;
int more;
uint32_t stack[100]; // stack of bits represented as a bit vector
} jl_unionstate_t;
// Linked list storing the type variable environment. A new jl_varbinding_t
// is pushed for each UnionAll type we encounter. `lb` and `ub` are updated
// during the computation.
// Most of the complexity is due to the "diagonal rule", requiring us to
// identify which type vars range over only concrete types.
typedef struct _varbinding {
jl_tvar_t *var;
jl_value_t *lb;
jl_value_t *ub;
int8_t right; // whether this variable came from the right side of `A <: B`
// if another var that this one depends on is found to be concrete, store it
// here for reference in case that var is popped from the environment before this one.
// TODO: generalize this to multiple variables
jl_tvar_t *concretevar;
int8_t occurs_inv; // occurs in invariant position
int8_t occurs_cov; // # of occurrences in covariant position
int8_t concrete; // 1 if another variable has a constraint forcing this one to be concrete
// in covariant position, we need to try constraining a variable in different ways:
// 0 - unconstrained
// 1 - less than
// 2 - greater than
// 3 - inexpressible - occurs when the var has non-trivial overlap with another type,
// and we would need to return `intersect(var,other)`. in this case
// we choose to over-estimate the intersection by returning the var.
int8_t constraintkind;
int depth0; // # of invariant constructors nested around the UnionAll type for this var
// when this variable's integer value is compared to that of another,
// it equals `other + offset`. used by vararg length parameters.
int offset;
// array of typevars that our bounds depend on, whose UnionAlls need to be
// moved outside ours.
jl_array_t *innervars;
struct _varbinding *prev;
} jl_varbinding_t;
// subtype algorithm state
typedef struct {
jl_varbinding_t *vars; // type variable environment
jl_unionstate_t Lunions; // union state for unions on the left of A <: B
jl_unionstate_t Runions; // union state for unions on the right
jl_value_t **envout; // for passing caller the computed bounds of right-side variables
int envsz; // length of envout
int envidx; // current index in envout
int invdepth; // current number of invariant constructors we're nested in
int ignore_free; // treat free vars as black boxes; used during intersection
int intersection; // true iff subtype is being called from intersection
int emptiness_only; // true iff intersection only needs to test for emptiness
} jl_stenv_t;
// state manipulation utilities
// look up a type variable in an environment
static jl_varbinding_t *lookup(jl_stenv_t *e, jl_tvar_t *v)
{
jl_varbinding_t *b = e->vars;
while (b != NULL) {
if (b->var == v) return b;
b = b->prev;
}
return b;
}
static int statestack_get(jl_unionstate_t *st, int i)
{
assert(i >= 0 && i < sizeof(st->stack) * 8);
// get the `i`th bit in an array of 32-bit words
return (st->stack[i>>5] & (1<<(i&31))) != 0;
}
static void statestack_set(jl_unionstate_t *st, int i, int val)
{
assert(i >= 0 && i < sizeof(st->stack) * 8);
if (val)
st->stack[i>>5] |= (1<<(i&31));
else
st->stack[i>>5] &= ~(1<<(i&31));
}
typedef struct {
int8_t *buf;
int rdepth;
} jl_savedenv_t;
static void save_env(jl_stenv_t *e, jl_value_t **root, jl_savedenv_t *se)
{
jl_varbinding_t *v = e->vars;
int len=0;
while (v != NULL) {
len++;
v = v->prev;
}
*root = (jl_value_t*)jl_alloc_svec(len*3);
se->buf = (int8_t*)(len ? malloc(len*2) : NULL);
int i=0, j=0; v = e->vars;
while (v != NULL) {
jl_svecset(*root, i++, v->lb);
jl_svecset(*root, i++, v->ub);
jl_svecset(*root, i++, (jl_value_t*)v->innervars);
se->buf[j++] = v->occurs_inv;
se->buf[j++] = v->occurs_cov;
v = v->prev;
}
se->rdepth = e->Runions.depth;
}
static void restore_env(jl_stenv_t *e, jl_value_t *root, jl_savedenv_t *se)
{
jl_varbinding_t *v = e->vars;
int i = 0, j = 0;
while (v != NULL) {
if (root) v->lb = jl_svecref(root, i);
i++;
if (root) v->ub = jl_svecref(root, i);
i++;
if (root) v->innervars = (jl_array_t*)jl_svecref(root, i);
i++;
v->occurs_inv = se->buf[j++];
v->occurs_cov = se->buf[j++];
v = v->prev;
}
e->Runions.depth = se->rdepth;
if (e->envout && e->envidx < e->envsz)
memset(&e->envout[e->envidx], 0, (e->envsz - e->envidx)*sizeof(void*));
}
// type utilities
// quickly test that two types are identical
static int obviously_egal(jl_value_t *a, jl_value_t *b)
{
if (a == b) return 1;
if (jl_typeof(a) != jl_typeof(b)) return 0;
if (jl_is_datatype(a)) {
jl_datatype_t *ad = (jl_datatype_t*)a, *bd = (jl_datatype_t*)b;
if (ad->name != bd->name) return 0;
size_t i, np = jl_nparams(ad);
if (np != jl_nparams(bd)) return 0;
for(i=0; i < np; i++) {
if (!obviously_egal(jl_tparam(ad,i), jl_tparam(bd,i)))
return 0;
}
return 1;
}
if (jl_is_uniontype(a)) {
return obviously_egal(((jl_uniontype_t*)a)->a, ((jl_uniontype_t*)b)->a) &&
obviously_egal(((jl_uniontype_t*)a)->b, ((jl_uniontype_t*)b)->b);
}
if (jl_is_unionall(a)) {
return ((jl_unionall_t*)a)->var == ((jl_unionall_t*)b)->var &&
obviously_egal(((jl_unionall_t*)a)->body, ((jl_unionall_t*)b)->body);
}
if (jl_is_typevar(a)) return 0;
return !jl_is_type(a) && jl_egal(a,b);
}
static int obviously_unequal(jl_value_t *a, jl_value_t *b)
{
if (a == b)
return 0;
if (jl_is_concrete_type(a) || jl_is_concrete_type(b))
return 1;
if (jl_is_unionall(a)) a = jl_unwrap_unionall(a);
if (jl_is_unionall(b)) b = jl_unwrap_unionall(b);
if (jl_is_datatype(a)) {
if (b == jl_bottom_type) return 1;
if (jl_is_datatype(b)) {
jl_datatype_t *ad = (jl_datatype_t*)a, *bd = (jl_datatype_t*)b;
if (ad->name != bd->name)
return 1;
size_t i, np = jl_nparams(ad);
if (np != jl_nparams(bd)) return 1;
for(i=0; i < np; i++) {
if (obviously_unequal(jl_tparam(ad,i), jl_tparam(bd,i)))
return 1;
}
}
}
else if (a == jl_bottom_type && jl_is_datatype(b)) {
return 1;
}
if (jl_is_typevar(a) && jl_is_typevar(b) && obviously_unequal(((jl_tvar_t*)a)->ub, ((jl_tvar_t*)b)->ub))
return 1;
if (jl_is_long(a)) {
if (jl_is_long(b) && jl_unbox_long(a) != jl_unbox_long(b))
return 1;
}
else if (jl_is_long(b)) return 1;
if ((jl_is_symbol(a) || jl_is_symbol(b)) && a != b)
return 1;
return 0;
}
int jl_obviously_unequal(jl_value_t *a, jl_value_t *b)
{
return obviously_unequal(a, b);
}
static int obviously_disjoint(jl_value_t *a, jl_value_t *b, int specificity)
{
if (a == b || a == (jl_value_t*)jl_any_type || b == (jl_value_t*)jl_any_type)
return 0;
if (jl_is_concrete_type(a) && jl_is_concrete_type(b) &&
// TODO: remove these 2 lines if and when Tuple{Union{}} === Union{}
(((jl_datatype_t*)a)->name != jl_tuple_typename ||
((jl_datatype_t*)b)->name != jl_tuple_typename))
return 1;
if (jl_is_unionall(a)) a = jl_unwrap_unionall(a);
if (jl_is_unionall(b)) b = jl_unwrap_unionall(b);
if (jl_is_datatype(a) && jl_is_datatype(b)) {
jl_datatype_t *ad = (jl_datatype_t*)a, *bd = (jl_datatype_t*)b;
if (ad->name != bd->name) {
jl_datatype_t *temp = ad;
while (temp != jl_any_type && temp->name != bd->name)
temp = temp->super;
if (temp == jl_any_type) {
temp = bd;
while (temp != jl_any_type && temp->name != ad->name)
temp = temp->super;
if (temp == jl_any_type)
return 1;
bd = temp;
}
else {
ad = temp;
}
if (specificity) {
// account for declared subtypes taking priority (issue #21710)
return 0;
}
}
int istuple = (ad->name == jl_tuple_typename);
size_t np;
if (istuple) {
size_t na = jl_nparams(ad), nb = jl_nparams(bd);
if (jl_is_va_tuple(ad)) {
na -= 1;
if (jl_is_va_tuple(bd))
nb -= 1;
}
else if (jl_is_va_tuple(bd)) {
nb -= 1;
}
else if (!specificity && na != nb) {
// note: some disjoint types (e.g. tuples of different lengths) can be more specific
return 1;
}
np = na < nb ? na : nb;
}
else {
np = jl_nparams(ad);
}
size_t i;
for(i=0; i < np; i++) {
jl_value_t *ai = jl_tparam(ad,i);
jl_value_t *bi = jl_tparam(bd,i);
if (jl_is_typevar(ai) || jl_is_typevar(bi))
continue;
if (jl_is_type(ai)) {
if (jl_is_type(bi)) {
if (istuple && (ai == jl_bottom_type || bi == jl_bottom_type))
; // TODO: this can return 1 if and when Tuple{Union{}} === Union{}
else if (obviously_disjoint(ai, bi, specificity))
return 1;
}
else if (!specificity) {
// Tuple{1} is more specific than Tuple{Any}
return 1;
}
}
else if (jl_is_type(bi)) {
if (!specificity)
return 1;
}
else if (!jl_egal(ai, bi)) {
return 1;
}
}
}
else if (a == jl_bottom_type || b == jl_bottom_type) {
return 1;
}
return 0;
}
static int in_union(jl_value_t *u, jl_value_t *x)
{
if (u == x) return 1;
if (!jl_is_uniontype(u)) return 0;
return in_union(((jl_uniontype_t*)u)->a, x) || in_union(((jl_uniontype_t*)u)->b, x);
}
// compute a least upper bound of `a` and `b`
static jl_value_t *simple_join(jl_value_t *a, jl_value_t *b)
{
if (a == jl_bottom_type || b == (jl_value_t*)jl_any_type || obviously_egal(a,b))
return b;
if (b == jl_bottom_type || a == (jl_value_t*)jl_any_type)
return a;
if (!(jl_is_type(a) || jl_is_typevar(a)) || !(jl_is_type(b) || jl_is_typevar(b)))
return (jl_value_t*)jl_any_type;
if (jl_is_uniontype(a) && in_union(a, b))
return a;
if (jl_is_uniontype(b) && in_union(b, a))
return b;
if (jl_is_kind(a) && jl_is_type_type(b) && jl_typeof(jl_tparam0(b)) == a)
return a;
if (jl_is_kind(b) && jl_is_type_type(a) && jl_typeof(jl_tparam0(a)) == b)
return b;
if (jl_is_typevar(a) && obviously_egal(b, ((jl_tvar_t*)a)->lb))
return a;
if (jl_is_typevar(b) && obviously_egal(a, ((jl_tvar_t*)b)->lb))
return b;
if (!jl_has_free_typevars(a) && !jl_has_free_typevars(b)) {
if (jl_subtype(a, b)) return b;
if (jl_subtype(b, a)) return a;
}
return jl_new_struct(jl_uniontype_type, a, b);
}
static jl_unionall_t *rename_unionall(jl_unionall_t *u)
{
jl_tvar_t *v = jl_new_typevar(u->var->name, u->var->lb, u->var->ub);
jl_value_t *t = NULL;
JL_GC_PUSH2(&v, &t);
t = jl_instantiate_unionall(u, (jl_value_t*)v);
t = jl_new_struct(jl_unionall_type, v, t);
JL_GC_POP();
return (jl_unionall_t*)t;
}
// main subtyping algorithm
static int subtype(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int param);
static jl_value_t *pick_union_element(jl_value_t *u, jl_stenv_t *e, int8_t R)
{
jl_unionstate_t *state = R ? &e->Runions : &e->Lunions;
do {
int ui = statestack_get(state, state->depth);
state->depth++;
if (ui == 0) {
state->more = state->depth; // memorize that this was the deepest available choice
u = ((jl_uniontype_t*)u)->a;
}
else {
u = ((jl_uniontype_t*)u)->b;
}
} while (jl_is_uniontype(u));
return u;
}
// compare the current component of `u` to `t`. `R==1` means `u` came from the right side.
static int subtype_union(jl_value_t *t, jl_uniontype_t *u, jl_stenv_t *e, int8_t R, int param)
{
jl_value_t *choice = pick_union_element((jl_value_t*)u, e, R);
return R ? subtype(t, choice, e, param) : subtype(choice, t, e, param);
}
// subtype(), but taking apart unions before handling vars
static int subtype_ufirst(jl_value_t *x, jl_value_t *y, jl_stenv_t *e)
{
if (jl_is_uniontype(x) && jl_is_typevar(y))
return subtype_union(y, (jl_uniontype_t*)x, e, 0, 0);
if (jl_is_typevar(x) && jl_is_uniontype(y))
return (x == ((jl_uniontype_t*)y)->a || x == ((jl_uniontype_t*)y)->b ||
subtype_union(x, (jl_uniontype_t*)y, e, 1, 0));
return subtype(x, y, e, 0);
}
// use the current context to record where a variable occurred, for the purpose
// of determining whether the variable is concrete.
static void record_var_occurrence(jl_varbinding_t *vb, jl_stenv_t *e, int param)
{
if (vb != NULL && param) {
// saturate counters at 2; we don't need values bigger than that
if (param == 2 && e->invdepth > vb->depth0 && vb->occurs_inv < 2)
vb->occurs_inv++;
else if (vb->occurs_cov < 2)
vb->occurs_cov++;
}
}
// is var x's quantifier outside y's in nesting order
static int var_outside(jl_stenv_t *e, jl_tvar_t *x, jl_tvar_t *y)
{
jl_varbinding_t *btemp = e->vars;
while (btemp != NULL) {
if (btemp->var == x) return 0;
if (btemp->var == y) return 1;
btemp = btemp->prev;
}
return 0;
}
static jl_value_t *intersect_ufirst(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int depth);
// check that type var `b` is <: `a`, and update b's upper bound.
static int var_lt(jl_tvar_t *b, jl_value_t *a, jl_stenv_t *e, int param)
{
jl_varbinding_t *bb = lookup(e, b);
if (bb == NULL)
return e->ignore_free || subtype_ufirst(b->ub, a, e);
record_var_occurrence(bb, e, param);
if (!bb->right) // check ∀b . b<:a
return subtype_ufirst(bb->ub, a, e);
if (bb->ub == a)
return 1;
if (!((bb->lb == jl_bottom_type && !jl_is_type(a) && !jl_is_typevar(a)) || subtype_ufirst(bb->lb, a, e)))
return 0;
// for contravariance we would need to compute a meet here, but
// because of invariance bb.ub ⊓ a == a here always. however for this
// to work we need to compute issub(left,right) before issub(right,left),
// since otherwise the issub(a, bb.ub) check in var_gt becomes vacuous.
if (e->intersection) {
jl_value_t *ub = intersect_ufirst(bb->ub, a, e, bb->depth0);
if (ub != (jl_value_t*)b)
bb->ub = ub;
}
else {
bb->ub = a; // meet(bb->ub, a)
}
assert(bb->ub != (jl_value_t*)b);
if (jl_is_typevar(a)) {
jl_varbinding_t *aa = lookup(e, (jl_tvar_t*)a);
if (aa && !aa->right && in_union(bb->lb, a) && bb->depth0 != aa->depth0 && var_outside(e, b, (jl_tvar_t*)a)) {
// an "exists" var cannot equal a "forall" var inside it unless the forall
// var has equal bounds.
return subtype_ufirst(aa->ub, aa->lb, e);
}
}
return 1;
}
// check that type var `b` is >: `a`, and update b's lower bound.
static int var_gt(jl_tvar_t *b, jl_value_t *a, jl_stenv_t *e, int param)
{
jl_varbinding_t *bb = lookup(e, b);
if (bb == NULL)
return e->ignore_free || subtype_ufirst(a, b->lb, e);
record_var_occurrence(bb, e, param);
if (!bb->right) // check ∀b . b>:a
return subtype_ufirst(a, bb->lb, e);
if (bb->lb == bb->ub) {
if (jl_is_typevar(bb->lb) && !jl_is_type(a) && !jl_is_typevar(a))
return var_gt((jl_tvar_t*)bb->lb, a, e, param);
if (jl_is_typevar(a) && !jl_is_type(bb->lb) && !jl_is_typevar(bb->lb))
return var_lt((jl_tvar_t*)a, bb->lb, e, param);
}
if (!((bb->ub == (jl_value_t*)jl_any_type && !jl_is_type(a) && !jl_is_typevar(a)) || subtype_ufirst(a, bb->ub, e)))
return 0;
bb->lb = simple_join(bb->lb, a);
assert(bb->lb != (jl_value_t*)b);
return 1;
}
// check that a type is concrete or quasi-concrete (Type{T}).
// this is used to check concrete typevars:
// issubtype is false if the lower bound of a concrete type var is not concrete.
static int is_leaf_bound(jl_value_t *v)
{
if (v == jl_bottom_type)
return 1;
if (jl_is_datatype(v)) {
if (((jl_datatype_t*)v)->abstract) {
if (jl_is_type_type(v))
return 1;//!jl_has_free_typevars(jl_tparam0(v));
return 0;
}
return ((jl_datatype_t*)v)->isconcretetype;
}
return !jl_is_type(v) && !jl_is_typevar(v);
}
static int is_leaf_typevar(jl_value_t *v)
{
if (jl_is_typevar(v))
return is_leaf_typevar(((jl_tvar_t*)v)->lb);
return is_leaf_bound(v);
}
static jl_value_t *widen_Type(jl_value_t *t)
{
if (jl_is_type_type(t) && !jl_is_typevar(jl_tparam0(t)))
return jl_typeof(jl_tparam0(t));
if (jl_is_uniontype(t)) {
jl_value_t *a = widen_Type(((jl_uniontype_t*)t)->a);
jl_value_t *b = widen_Type(((jl_uniontype_t*)t)->b);
if (a == b)
return a;
}
return t;
}
JL_DLLEXPORT jl_array_t *jl_find_free_typevars(jl_value_t *v);
// convert a type with free variables to a typevar bounded by a UnionAll-wrapped
// version of that type.
// TODO: This loses some inference precision. For example in a case where a
// variable bound is `Vector{_}`, we could potentially infer `Type{Vector{_}} where _`,
// but this causes us to infer the larger `Type{T} where T<:Vector` instead.
// However this is needed because many contexts check `isa(sp, TypeVar)` to determine
// when a static parameter value is not known exactly.
static jl_value_t *fix_inferred_var_bound(jl_tvar_t *var, jl_value_t *ty)
{
if (!jl_is_typevar(ty) && jl_has_free_typevars(ty)) {
jl_value_t *ans = ty;
jl_array_t *vs = jl_find_free_typevars(ty);
JL_GC_PUSH2(&ans, &vs);
int i;
for (i = 0; i < jl_array_len(vs); i++) {
ans = jl_type_unionall((jl_tvar_t*)jl_array_ptr_ref(vs, i), ans);
}
ans = (jl_value_t*)jl_new_typevar(var->name, jl_bottom_type, ans);
JL_GC_POP();
return ans;
}
return ty;
}
static int var_occurs_inside(jl_value_t *v, jl_tvar_t *var, int inside, int want_inv);
// compare UnionAll type `u` to `t`. `R==1` if `u` came from the right side of A <: B.
static int subtype_unionall(jl_value_t *t, jl_unionall_t *u, jl_stenv_t *e, int8_t R, int param)
{
jl_varbinding_t *btemp = e->vars;
// if the var for this unionall (based on identity) already appears somewhere
// in the environment, rename to get a fresh var.
while (btemp != NULL) {
if (btemp->var == u->var ||
// outer var can only refer to inner var if bounds changed
(btemp->lb != btemp->var->lb && jl_has_typevar(btemp->lb, u->var)) ||
(btemp->ub != btemp->var->ub && jl_has_typevar(btemp->ub, u->var))) {
u = rename_unionall(u);
break;
}
btemp = btemp->prev;
}
jl_varbinding_t vb = { u->var, u->var->lb, u->var->ub, R, NULL, 0, 0, 0, 0, e->invdepth, 0, NULL, e->vars };
JL_GC_PUSH3(&u, &vb.lb, &vb.ub);
e->vars = &vb;
int ans;
if (R) {
e->envidx++;
ans = subtype(t, u->body, e, param);
e->envidx--;
// widen Type{x} to typeof(x) in argument position
if (!vb.occurs_inv)
vb.lb = widen_Type(vb.lb);
// fill variable values into `envout` up to `envsz`
if (e->envidx < e->envsz) {
jl_value_t *val;
if (!vb.occurs_inv && vb.lb != jl_bottom_type)
val = is_leaf_bound(vb.lb) ? vb.lb : (jl_value_t*)jl_new_typevar(u->var->name, jl_bottom_type, vb.lb);
else if (vb.lb == vb.ub)
val = vb.lb;
else if (vb.lb != jl_bottom_type)
// TODO: for now return the least solution, which is what
// method parameters expect.
val = vb.lb;
else if (vb.lb == u->var->lb && vb.ub == u->var->ub)
val = (jl_value_t*)u->var;
else
val = (jl_value_t*)jl_new_typevar(u->var->name, vb.lb, vb.ub);
jl_value_t *oldval = e->envout[e->envidx];
// if we try to assign different variable values (due to checking
// multiple union members), consider the value unknown.
if (oldval && !jl_egal(oldval, val))
e->envout[e->envidx] = (jl_value_t*)u->var;
else
e->envout[e->envidx] = fix_inferred_var_bound(u->var, val);
// TODO: substitute the value (if any) of this variable into previous envout entries
}
}
else {
ans = subtype(u->body, t, e, param);
}
// handle the "diagonal dispatch" rule, which says that a type var occurring more
// than once, and only in covariant position, is constrained to concrete types. E.g.
// ( Tuple{Int, Int} <: Tuple{T, T} where T) but
// !( Tuple{Int, String} <: Tuple{T, T} where T)
// Then check concreteness by checking that the lower bound is not an abstract type.
int diagonal = !vb.occurs_inv && vb.occurs_cov > 1;
if (ans && (vb.concrete || (diagonal && is_leaf_typevar((jl_value_t*)u->var)))) {
if (vb.concrete && !diagonal && !is_leaf_bound(vb.ub)) {
// a non-diagonal var can only be a subtype of a diagonal var if its
// upper bound is concrete.
ans = 0;
}
else if (jl_is_typevar(vb.lb)) {
jl_tvar_t *v = (jl_tvar_t*)vb.lb;
jl_varbinding_t *vlb = lookup(e, v);
if (vlb)
vlb->concrete = 1;
//else // TODO handle multiple variables in vb.concretevar
// ans = (v == vb.concretevar);
}
else if (!is_leaf_bound(vb.lb)) {
ans = 0;
}
if (ans) {
// if we occur as another var's lower bound, record the fact that we
// were concrete so that subtype can return true for that var.
/*
btemp = vb.prev;
while (btemp != NULL) {
if (btemp->lb == (jl_value_t*)u->var)
btemp->concretevar = u->var;
btemp = btemp->prev;
}
*/
}
}
e->vars = vb.prev;
btemp = e->vars;
if (vb.lb != vb.ub) {
while (btemp != NULL) {
jl_value_t *vu = btemp->ub;
jl_value_t *vl = btemp->lb;
// TODO: this takes a significant amount of time
if (btemp->depth0 != vb.depth0 &&
((vu != (jl_value_t*)vb.var && btemp->var->ub != vu && var_occurs_inside(vu, vb.var, 0, 1)) ||
(vl != (jl_value_t*)vb.var && btemp->var->lb != vl && var_occurs_inside(vl, vb.var, 0, 1)))) {
ans = 0; break;
}
btemp = btemp->prev;
}
}
JL_GC_POP();
return ans;
}
// unwrap <=2 layers of UnionAlls, leaving the vars in *p1 and *p2 and returning the body
static jl_value_t *unwrap_2_unionall(jl_value_t *t, jl_tvar_t **p1, jl_tvar_t **p2)
{
if (jl_is_unionall(t)) {
*p1 = ((jl_unionall_t*)t)->var;
t = ((jl_unionall_t*)t)->body;
if (jl_is_unionall(t)) {
*p2 = ((jl_unionall_t*)t)->var;
t = ((jl_unionall_t*)t)->body;
}
}
return t;
}
// check n <: (length of vararg type v)
static int check_vararg_length(jl_value_t *v, ssize_t n, jl_stenv_t *e)
{
jl_tvar_t *va_p1=NULL, *va_p2=NULL;
jl_value_t *tail = unwrap_2_unionall(v, &va_p1, &va_p2);
assert(jl_is_datatype(tail));
jl_value_t *N = jl_tparam1(tail);
// only do the check if N is free in the tuple type's last parameter
if (N != (jl_value_t*)va_p1 && N != (jl_value_t*)va_p2) {
jl_value_t *nn = jl_box_long(n);
JL_GC_PUSH1(&nn);
e->invdepth++;
int ans = subtype(nn, N, e, 2) && subtype(N, nn, e, 0);
e->invdepth--;
JL_GC_POP();
if (!ans)
return 0;
}
return 1;
}
static int subtype_tuple(jl_datatype_t *xd, jl_datatype_t *yd, jl_stenv_t *e, int param)
{
size_t lx = jl_nparams(xd), ly = jl_nparams(yd);
if (lx == 0 && ly == 0)
return 1;
size_t i=0, j=0;
int vx=0, vy=0, vvx = (lx > 0 && jl_is_vararg_type(jl_tparam(xd, lx-1)));
int vvy = (ly > 0 && jl_is_vararg_type(jl_tparam(yd, ly-1)));
if (vvx) {
if ((vvy && ly > lx) || (!vvy && ly < lx-1))
return 0;
}
else if ((vvy && ly > lx+1) || (!vvy && lx != ly)) {
return 0;
}
param = (param == 0 ? 1 : param);
jl_value_t *lastx=NULL, *lasty=NULL;
while (i < lx) {
jl_value_t *xi = jl_tparam(xd, i);
if (i == lx-1 && vvx) vx = 1;
jl_value_t *yi = NULL;
if (j < ly) {
yi = jl_tparam(yd, j);
if (j == ly-1 && vvy) vy = 1;
}
if (vx && !vy) {
if (!check_vararg_length(xi, ly+1-lx, e))
return 0;
jl_tvar_t *p1=NULL, *p2=NULL;
xi = unwrap_2_unionall(xi, &p1, &p2);
jl_value_t *N = jl_tparam1(xi);
if (N == (jl_value_t*)p1 || N == (jl_value_t*)p2)
return 0;
if (j >= ly) return 1;
xi = jl_tparam0(xi);
}
else if (j >= ly) {
return 0;
}
if (!vx && vy) {
jl_tvar_t *p1=NULL, *p2=NULL;
yi = jl_tparam0(unwrap_2_unionall(yi, &p1, &p2));
if (yi == (jl_value_t*)p1 || yi == (jl_value_t*)p2)
yi = ((jl_tvar_t*)yi)->ub;
if (!vvx && yi == (jl_value_t*)jl_any_type)
break; // if y ends in `Vararg{Any}` skip checking everything
}
if (vx && vy) {
// skip testing element type if vararg lengths are 0
if (jl_is_datatype(xi)) {
jl_value_t *xl = jl_tparam1(xi);
if (jl_is_typevar(xl)) {
jl_varbinding_t *xlv = lookup(e, (jl_tvar_t*)xl);
if (xlv && jl_is_long(xlv->lb) && jl_unbox_long(xlv->lb) == 0)
break;
}
}
if (jl_is_datatype(yi)) {
jl_value_t *yl = jl_tparam1(yi);
if (jl_is_typevar(yl)) {
jl_varbinding_t *ylv = lookup(e, (jl_tvar_t*)yl);
if (ylv && jl_is_long(ylv->lb) && jl_unbox_long(ylv->lb) == 0)
break;
}
}
}
if (xi == lastx &&
((yi == lasty && !jl_has_free_typevars(xi) && !jl_has_free_typevars(yi)) ||
(yi == lasty && !vx && vy && jl_is_concrete_type(xi)))) {
// fast path for repeated elements
}
else if (e->Runions.depth == 0 && e->Lunions.depth == 0 && !jl_has_free_typevars(xi) && !jl_has_free_typevars(yi)) {
// fast path for separable sub-formulas
if (!jl_subtype(xi, yi))
return 0;
}
else if (!subtype(xi, yi, e, param)) {
return 0;
}
if (vx && vy) break;
lastx = xi; lasty = yi;
if (i < lx-1 || !vx)
i++;
if (j < ly-1 || !vy)
j++;
}
// TODO: handle Vararg with explicit integer length parameter
vy = vy || (j < ly && jl_is_vararg_type(jl_tparam(yd,j)));
if (vy && !vx && lx+1 >= ly) {
// in Tuple{...,tn} <: Tuple{...,Vararg{T,N}}, check (lx+1-ly) <: N
if (!check_vararg_length(jl_tparam(yd,ly-1), lx+1-ly, e))
return 0;
}
return (lx==ly && vx==vy) || (vy && (lx >= (vx ? ly : (ly-1))));
}
static int forall_exists_equal(jl_value_t *x, jl_value_t *y, jl_stenv_t *e);
// `param` means we are currently looking at a parameter of a type constructor
// (as opposed to being outside any type constructor, or comparing variable bounds).
// this is used to record the positions where type variables occur for the
// diagonal rule (record_var_occurrence).
static int subtype(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int param)
{
if (jl_is_uniontype(x)) {
if (x == y) return 1;
x = pick_union_element(x, e, 0);
}
if (jl_is_uniontype(y)) {
if (x == ((jl_uniontype_t*)y)->a || x == ((jl_uniontype_t*)y)->b)
return 1;
if (jl_is_unionall(x))
return subtype_unionall(y, (jl_unionall_t*)x, e, 0, param);
int ui = 1;
if (jl_is_typevar(x)) {
// The `convert(Type{T},T)` pattern, where T is a Union, required changing priority
// of unions and vars: if matching `typevar <: union`, first try to match the whole
// union against the variable before trying to take it apart to see if there are any
// variables lurking inside.
jl_unionstate_t *state = &e->Runions;
ui = statestack_get(state, state->depth);
state->depth++;
if (ui == 0)
state->more = state->depth; // memorize that this was the deepest available choice
}
if (ui == 1)
y = pick_union_element(y, e, 1);
}
if (jl_is_typevar(x)) {
if (jl_is_typevar(y)) {
if (x == y) return 1;
jl_varbinding_t *xx = lookup(e, (jl_tvar_t*)x);
jl_varbinding_t *yy = lookup(e, (jl_tvar_t*)y);
jl_value_t *xub = xx ? xx->ub : ((jl_tvar_t*)x)->ub;
jl_value_t *ylb = yy ? yy->lb : ((jl_tvar_t*)y)->lb;
if (e->intersection) {
jl_value_t *xlb = xx ? xx->lb : ((jl_tvar_t*)x)->lb;
jl_value_t *yub = yy ? yy->ub : ((jl_tvar_t*)y)->ub;
// find equivalence class for typevars during intersection
if (xub == xlb && jl_is_typevar(xub))
return subtype(xub, y, e, param);
if (yub == ylb && jl_is_typevar(yub))
return subtype(x, yub, e, param);
}
int xr = xx && xx->right; // treat free variables as "forall" (left)
int yr = yy && yy->right;
if (xr) {
if (yy) record_var_occurrence(yy, e, param);
if (yr) {
if (xx) record_var_occurrence(xx, e, param);
return subtype(xx->lb, yy->ub, e, 0);
}
return var_lt((jl_tvar_t*)x, y, e, param);
}
else if (yr) {
if (xx) record_var_occurrence(xx, e, param);
return var_gt((jl_tvar_t*)y, x, e, param);
}
// check ∀x,y . x<:y
// the bounds of left-side variables never change, and can only lead
// to other left-side variables, so using || here is safe.
return subtype(xub, y, e, param) || subtype(x, ylb, e, param);
}
return var_lt((jl_tvar_t*)x, y, e, param);
}
if (jl_is_typevar(y))
return var_gt((jl_tvar_t*)y, x, e, param);
if (y == (jl_value_t*)jl_any_type && !jl_has_free_typevars(x))
return 1;
// handle forall ("left") vars first
if (jl_is_unionall(x)) {
if (x == y && !(e->envidx < e->envsz))
return 1;
return subtype_unionall(y, (jl_unionall_t*)x, e, 0, param);
}
if (jl_is_unionall(y))
return subtype_unionall(x, (jl_unionall_t*)y, e, 1, param);
if (jl_is_datatype(x) && jl_is_datatype(y)) {
if (x == y) return 1;
if (y == (jl_value_t*)jl_any_type) return 1;
jl_datatype_t *xd = (jl_datatype_t*)x, *yd = (jl_datatype_t*)y;
if (jl_is_type_type(x) && !jl_is_type_type(y)) {
jl_value_t *tp0 = jl_tparam0(xd);
if (!jl_is_typevar(tp0)) {
// TODO this is not strictly correct, but we don't yet have any other way for
// e.g. the argument `Int` to match a `::DataType` slot. Most correct would be:
// Int isa DataType, Int isa Type{Int}, Type{Int} more specific than DataType,
// !(Type{Int} <: DataType), !isleaftype(Type{Int}), because non-DataTypes can
// be type-equal to `Int`.
return jl_typeof(tp0) == (jl_value_t*)yd;
}
return 0;
}
if (jl_is_type_type(y) && !jl_is_type_type(x) && x != (jl_value_t*)jl_typeofbottom_type) {
jl_value_t *tp0 = jl_tparam0(yd);
if (!jl_is_typevar(tp0) || !jl_is_kind(x))
return 0;
return subtype((jl_value_t*)jl_type_type, y, e, param);
}
while (xd != jl_any_type && xd->name != yd->name) {
if (xd->super == NULL)
jl_errorf("circular type parameter constraint in definition of %s", jl_symbol_name(xd->name->name));
xd = xd->super;
}
if (xd == jl_any_type) return 0;
if (xd->name == jl_tuple_typename)
return subtype_tuple(xd, yd, e, param);
if (xd->name == jl_vararg_typename) {
// Vararg: covariant in first parameter, invariant in second
jl_value_t *xp1=jl_tparam0(xd), *xp2=jl_tparam1(xd), *yp1=jl_tparam0(yd), *yp2=jl_tparam1(yd);
// in Vararg{T1} <: Vararg{T2}, need to check subtype twice to
// simulate the possibility of multiple arguments, which is needed
// to implement the diagonal rule correctly.
if (!subtype(xp1, yp1, e, 1)) return 0;
if (!subtype(xp1, yp1, e, 1)) return 0;
// Vararg{T,N} <: Vararg{T2,N2}; equate N and N2
e->invdepth++;
int ans = forall_exists_equal(xp2, yp2, e);
e->invdepth--;
return ans;
}
size_t i, np = jl_nparams(xd);
int ans = 1;
e->invdepth++;
for (i=0; i < np; i++) {
jl_value_t *xi = jl_tparam(xd, i), *yi = jl_tparam(yd, i);
if (!(xi == yi || forall_exists_equal(xi, yi, e))) {
ans = 0; break;
}
}
e->invdepth--;
return ans;
}
if (jl_is_type(y))
return x == jl_bottom_type;
return x == y || jl_egal(x, y);
}
static int forall_exists_subtype(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int param);
static int forall_exists_equal(jl_value_t *x, jl_value_t *y, jl_stenv_t *e)
{
if (obviously_egal(x, y)) return 1;
jl_unionstate_t oldLunions = e->Lunions;
memset(e->Lunions.stack, 0, sizeof(e->Lunions.stack));
int sub;
if (!jl_has_free_typevars(x) || !jl_has_free_typevars(y)) {
jl_unionstate_t oldRunions = e->Runions;
memset(e->Runions.stack, 0, sizeof(e->Runions.stack));
e->Runions.depth = 0;
e->Runions.more = 0;
e->Lunions.depth = 0;
e->Lunions.more = 0;
sub = forall_exists_subtype(x, y, e, 2);
e->Runions = oldRunions;
}
else {
int lastset = 0;
while (1) {
e->Lunions.more = 0;
e->Lunions.depth = 0;
sub = subtype(x, y, e, 2);
int set = e->Lunions.more;
if (!sub || !set)
break;
for (int i = set; i <= lastset; i++)
statestack_set(&e->Lunions, i, 0);
lastset = set - 1;
statestack_set(&e->Lunions, lastset, 1);
}
}
e->Lunions = oldLunions;
return sub && subtype(y, x, e, 0);
}
static int exists_subtype(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, jl_value_t *saved, jl_savedenv_t *se, int param)
{
memset(e->Runions.stack, 0, sizeof(e->Runions.stack));
int lastset = 0;
while (1) {
e->Runions.depth = 0;
e->Runions.more = 0;
e->Lunions.depth = 0;
e->Lunions.more = 0;
if (subtype(x, y, e, param))
return 1;
restore_env(e, saved, se);
int set = e->Runions.more;
if (!set)
return 0;
for (int i = set; i <= lastset; i++)
statestack_set(&e->Runions, i, 0);
lastset = set - 1;
statestack_set(&e->Runions, lastset, 1);
}
}
static int forall_exists_subtype(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int param)
{
// The depth recursion has the following shape, after simplification:
// ∀₁
// ∃₁
assert(e->Runions.depth == 0);
assert(e->Lunions.depth == 0);
jl_value_t *saved=NULL; jl_savedenv_t se;
JL_GC_PUSH1(&saved);
save_env(e, &saved, &se);
memset(e->Lunions.stack, 0, sizeof(e->Lunions.stack));
int lastset = 0;
int sub;
while (1) {
sub = exists_subtype(x, y, e, saved, &se, param);
int set = e->Lunions.more;
if (!sub || !set)
break;
for (int i = set; i <= lastset; i++)
statestack_set(&e->Lunions, i, 0);
lastset = set - 1;
statestack_set(&e->Lunions, lastset, 1);
}
free(se.buf);
JL_GC_POP();
return sub;
}
static void init_stenv(jl_stenv_t *e, jl_value_t **env, int envsz)
{
e->vars = NULL;
assert(env != NULL || envsz == 0);
e->envsz = envsz;
e->envout = env;
if (envsz)
memset(env, 0, envsz*sizeof(void*));
e->envidx = 0;
e->invdepth = 0;
e->ignore_free = 0;
e->intersection = 0;
e->emptiness_only = 0;
e->Lunions.depth = 0; e->Runions.depth = 0;
e->Lunions.more = 0; e->Runions.more = 0;
}
// subtyping entry points
JL_DLLEXPORT int jl_subtype_env_size(jl_value_t *t)
{
int sz = 0;
while (jl_is_unionall(t)) {
sz++;
t = ((jl_unionall_t*)t)->body;
}
return sz;
}
// `env` is NULL if no typevar information is requested, or otherwise
// points to a rooted array of length `jl_subtype_env_size(y)`.
// This will be populated with the values of variables from unionall
// types at the outer level of `y`.
JL_DLLEXPORT int jl_subtype_env(jl_value_t *x, jl_value_t *y, jl_value_t **env, int envsz)
{
jl_stenv_t e;
if (envsz == 0 && (y == (jl_value_t*)jl_any_type || x == jl_bottom_type || x == y))
return 1;
init_stenv(&e, env, envsz);
return forall_exists_subtype(x, y, &e, 0);
}
static int subtype_in_env(jl_value_t *x, jl_value_t *y, jl_stenv_t *e)
{
jl_stenv_t e2;
init_stenv(&e2, NULL, 0);
e2.vars = e->vars;
e2.intersection = e->intersection;
e2.ignore_free = e->ignore_free;
e2.envsz = e->envsz;
e2.envout = e->envout;
e2.envidx = e->envidx;
return forall_exists_subtype(x, y, &e2, 0);
}
JL_DLLEXPORT int jl_subtype(jl_value_t *x, jl_value_t *y)
{
return jl_subtype_env(x, y, NULL, 0);
}
JL_DLLEXPORT int jl_types_equal(jl_value_t *a, jl_value_t *b)
{
if (obviously_egal(a, b)) return 1;
if (obviously_unequal(a, b)) return 0;
return jl_subtype(a, b) && jl_subtype(b, a);
}
int jl_tuple_isa(jl_value_t **child, size_t cl, jl_datatype_t *pdt)
{
if (jl_is_tuple_type(pdt) && !jl_is_va_tuple(pdt)) {
if (cl != jl_nparams(pdt))
return 0;
size_t i;
for(i=0; i < cl; i++) {
if (!jl_isa(child[i], jl_tparam(pdt,i)))
return 0;
}
return 1;
}
jl_value_t *tu = (jl_value_t*)arg_type_tuple(child, cl);
int ans;
JL_GC_PUSH1(&tu);
ans = jl_subtype(tu, (jl_value_t*)pdt);
JL_GC_POP();
return ans;
}
// returns true if the intersection of `t` and `Type` is non-empty and not a kind
// this is sufficient to determine if `isa(x, T)` can instead simply check for `typeof(x) <: T`
int jl_has_intersect_type_not_kind(jl_value_t *t)
{
t = jl_unwrap_unionall(t);
if (t == (jl_value_t*)jl_any_type)
return 1;
if (jl_is_uniontype(t)) {
return jl_has_intersect_type_not_kind(((jl_uniontype_t*)t)->a) ||
jl_has_intersect_type_not_kind(((jl_uniontype_t*)t)->b);
}
if (jl_is_typevar(t)) {
return jl_has_intersect_type_not_kind(((jl_tvar_t*)t)->ub);
}
if (jl_is_datatype(t)) {
if (((jl_datatype_t*)t)->name == jl_type_typename)
return 1;
}
return 0;
}
JL_DLLEXPORT int jl_isa(jl_value_t *x, jl_value_t *t)
{
if (jl_typeis(x,t) || t == (jl_value_t*)jl_any_type)
return 1;
if (jl_is_type(x)) {
if (t == (jl_value_t*)jl_type_type)
return 1;
if (!jl_has_free_typevars(x)) {
if (jl_is_concrete_type(t))
return 0;
if (jl_is_type_type(t))
return jl_types_equal(x, jl_tparam0(t));
jl_value_t *t2 = jl_unwrap_unionall(t);
if (jl_is_datatype(t2)) {
if (((jl_datatype_t*)t2)->name == jl_type_typename) {
jl_value_t *tp = jl_tparam0(t2);
if (jl_is_typevar(tp)) {
while (jl_is_typevar(tp))
tp = ((jl_tvar_t*)tp)->ub;
if (!jl_has_free_typevars(tp))
return jl_subtype(x, tp);
}
}
else {
return 0;
}
}
if (jl_subtype(jl_typeof(x), t))
return 1;
if (jl_has_intersect_type_not_kind(t2)) {
JL_GC_PUSH1(&x);
x = (jl_value_t*)jl_wrap_Type(x); // TODO jb/subtype avoid jl_wrap_Type
int ans = jl_subtype(x, t);
JL_GC_POP();
return ans;
}
return 0;
}
}
if (jl_is_concrete_type(t))
return 0;
return jl_subtype(jl_typeof(x), t);
}
// type intersection
static jl_value_t *intersect(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int param);
static jl_value_t *intersect_union(jl_value_t *x, jl_uniontype_t *u, jl_stenv_t *e, int8_t R, int param)
{
if (param == 2 || (!jl_has_free_typevars(x) && !jl_has_free_typevars((jl_value_t*)u))) {
jl_value_t *a=NULL, *b=NULL, *save=NULL; jl_savedenv_t se;
JL_GC_PUSH3(&a, &b, &save);
save_env(e, &save, &se);
a = R ? intersect(x, u->a, e, param) : intersect(u->a, x, e, param);
restore_env(e, NULL, &se);
b = R ? intersect(x, u->b, e, param) : intersect(u->b, x, e, param);
free(se.buf);
jl_value_t *i = simple_join(a,b);
JL_GC_POP();
return i;
}
jl_value_t *choice = pick_union_element((jl_value_t*)u, e, 1);
// try all possible choices in covariant position; union them all together at the top level
return R ? intersect(x, choice, e, param) : intersect(choice, x, e, param);
}
static jl_value_t *intersect_ufirst(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int depth)
{
jl_value_t *res;
int savedepth = e->invdepth;
e->invdepth = depth;
if (jl_is_uniontype(x) && jl_is_typevar(y))
res = intersect_union(y, (jl_uniontype_t*)x, e, 0, 0);
else if (jl_is_typevar(x) && jl_is_uniontype(y))
res = intersect_union(x, (jl_uniontype_t*)y, e, 1, 0);
else
res = intersect(x, y, e, 0);
e->invdepth = savedepth;
return res;
}
// set a variable to a non-type constant
static jl_value_t *set_var_to_const(jl_varbinding_t *bb, jl_value_t *v, jl_varbinding_t *othervar)
{
int offset = bb->offset;
if (othervar && offset == 0)
offset = -othervar->offset;
assert(!othervar || othervar->offset == -offset);
if (bb->lb == jl_bottom_type && bb->ub == (jl_value_t*)jl_any_type) {
if (jl_is_long(v))
v = jl_box_long(jl_unbox_long(v) + offset);
bb->lb = bb->ub = v;
}
else if (jl_is_long(v) && jl_is_long(bb->lb)) {
if (jl_unbox_long(v) + offset != jl_unbox_long(bb->lb))
return jl_bottom_type;
}
else if (!jl_egal(v, bb->lb)) {
return jl_bottom_type;
}
return v;
}
static int try_subtype_in_env(jl_value_t *a, jl_value_t *b, jl_stenv_t *e)
{
jl_value_t *root=NULL; jl_savedenv_t se; int ret=0;
JL_GC_PUSH1(&root);
save_env(e, &root, &se);
if (subtype_in_env(a, b, e))
ret = 1;
else
restore_env(e, root, &se);
free(se.buf);
JL_GC_POP();
return ret;
}
static jl_value_t *intersect_var(jl_tvar_t *b, jl_value_t *a, jl_stenv_t *e, int8_t R, int param)
{
jl_varbinding_t *bb = lookup(e, b);
if (bb == NULL)
return R ? intersect_ufirst(a, b->ub, e, 0) : intersect_ufirst(b->ub, a, e, 0);
if (bb->lb == bb->ub && jl_is_typevar(bb->lb))
return intersect(a, bb->lb, e, param);
if (!jl_is_type(a) && !jl_is_typevar(a))
return set_var_to_const(bb, a, NULL);
int d = bb->depth0;
jl_value_t *root=NULL; jl_savedenv_t se;
if (param == 2) {
jl_value_t *ub = R ? intersect_ufirst(a, bb->ub, e, d) : intersect_ufirst(bb->ub, a, e, d);
JL_GC_PUSH2(&ub, &root);
save_env(e, &root, &se);
int issub = subtype_in_env(bb->lb, ub, e);
restore_env(e, root, &se);
free(se.buf);
if (!issub) {
JL_GC_POP();
return jl_bottom_type;
}
if (ub != (jl_value_t*)b) {
if (jl_has_free_typevars(ub)) {
// constraint X == Ref{X} is unsatisfiable. also check variables set equal to X.
if (var_occurs_inside(ub, b, 0, 0)) {
JL_GC_POP();
return jl_bottom_type;
}
jl_varbinding_t *btemp = e->vars;
while (btemp != NULL) {
if (btemp->lb == (jl_value_t*)b && btemp->ub == (jl_value_t*)b &&
var_occurs_inside(ub, btemp->var, 0, 0)) {
JL_GC_POP();
return jl_bottom_type;
}
btemp = btemp->prev;
}
}
bb->ub = ub;
bb->lb = ub;
}
JL_GC_POP();
return ub;
}
else if (bb->constraintkind == 0) {
if (!jl_is_typevar(bb->ub) && !jl_is_typevar(a)) {
if (try_subtype_in_env(bb->ub, a, e))
return (jl_value_t*)b;
}
return R ? intersect_ufirst(a, bb->ub, e, d) : intersect_ufirst(bb->ub, a, e, d);
}
else if (bb->concrete || bb->constraintkind == 1) {
jl_value_t *ub = R ? intersect_ufirst(a, bb->ub, e, d) : intersect_ufirst(bb->ub, a, e, d);
JL_GC_PUSH1(&ub);
if (ub == jl_bottom_type || !subtype_in_env(bb->lb, a, e)) {
JL_GC_POP();
return jl_bottom_type;
}
if (ub != (jl_value_t*)b)
bb->ub = ub;
JL_GC_POP();
return (jl_value_t*)b;
}
else if (bb->constraintkind == 2) {
if (!subtype_in_env(a, bb->ub, e))
return jl_bottom_type;
jl_value_t *lb = simple_join(bb->lb, a);
if (lb != (jl_value_t*)b)
bb->lb = lb;
return a;
}
assert(bb->constraintkind == 3);
jl_value_t *ub = R ? intersect_ufirst(a, bb->ub, e, d) : intersect_ufirst(bb->ub, a, e, d);
if (ub == jl_bottom_type)
return jl_bottom_type;
if (jl_is_typevar(a))
return (jl_value_t*)b;
if (ub == a) {
if (bb->lb == jl_bottom_type ||
// if the var has an equality constraint then make sure bounds stay consistent.
// TODO: try to use this check in more cases
bb->ub != bb->lb || try_subtype_in_env(bb->lb, ub, e)) {
bb->ub = ub;
return (jl_value_t*)b;
}
return ub;
}
else if (bb->ub == bb->lb) {
return ub;
}
root = NULL;
JL_GC_PUSH2(&root, &ub);
save_env(e, &root, &se);
jl_value_t *ii = R ? intersect_ufirst(a, bb->lb, e, d) : intersect_ufirst(bb->lb, a, e, d);
if (ii == jl_bottom_type) {
restore_env(e, root, &se);
ii = (jl_value_t*)b;
if (ub != (jl_value_t*)b)
bb->ub = ub;
}
free(se.buf);
JL_GC_POP();
return ii;
}
// test whether `var` occurs inside constructors. `want_inv` tests only inside
// invariant constructors. `inside` means we are currently inside a constructor of the
// requested kind.
static int var_occurs_inside(jl_value_t *v, jl_tvar_t *var, int inside, int want_inv)
{
if (v == (jl_value_t*)var) {
return inside;
}
else if (jl_is_uniontype(v)) {
return var_occurs_inside(((jl_uniontype_t*)v)->a, var, inside, want_inv) ||
var_occurs_inside(((jl_uniontype_t*)v)->b, var, inside, want_inv);
}
else if (jl_is_unionall(v)) {
jl_unionall_t *ua = (jl_unionall_t*)v;
if (ua->var == var)
return 0;
if (var_occurs_inside(ua->var->lb, var, inside, want_inv) || var_occurs_inside(ua->var->ub, var, inside, want_inv))
return 1;
return var_occurs_inside(ua->body, var, inside, want_inv);
}
else if (jl_is_datatype(v)) {
size_t i;
int ins = inside || !want_inv || !jl_is_tuple_type(v);
for (i=0; i < jl_nparams(v); i++) {
if (var_occurs_inside(jl_tparam(v,i), var, ins, want_inv))
return 1;
}
}
return 0;
}
// Caller might not have rooted `res`
static jl_value_t *finish_unionall(jl_value_t *res, jl_varbinding_t *vb, jl_stenv_t *e)
{
jl_value_t *varval = NULL;
jl_tvar_t *newvar = vb->var;
JL_GC_PUSH2(&res, &newvar);
// try to reduce var to a single value
if (obviously_egal(vb->lb, vb->ub)) {
// given x<:T<:x, substitute x for T
varval = vb->ub;
}
else if (!var_occurs_inside(res, vb->var, 0, 1) && is_leaf_bound(vb->ub)) {
// replace T<:x with x in covariant position when possible
varval = vb->ub;
}
if (!varval && (vb->lb != vb->var->lb || vb->ub != vb->var->ub))
newvar = jl_new_typevar(vb->var->name, vb->lb, vb->ub);
// remove/replace/rewrap free occurrences of this var in the environment
jl_varbinding_t *btemp = e->vars;
int wrap = 1;
while (btemp != NULL) {
if (jl_has_typevar(btemp->lb, vb->var)) {
if (vb->lb == (jl_value_t*)btemp->var) {
JL_GC_POP();
return jl_bottom_type;
}
if (varval) {
JL_TRY {
btemp->lb = jl_substitute_var(btemp->lb, vb->var, varval);
}
JL_CATCH {
res = jl_bottom_type;
}
}
else if (btemp->lb == (jl_value_t*)vb->var)
btemp->lb = vb->lb;
else if (btemp->depth0 == vb->depth0 && !jl_has_typevar(vb->lb, btemp->var) &&
!jl_has_typevar(vb->ub, btemp->var) && jl_has_typevar(btemp->ub, vb->var)) {
// if our variable is T, and some outer variable has constraint S = Ref{T},
// move the `where T` outside `where S` instead of putting it here. issue #21243.
if (btemp->innervars == NULL)
btemp->innervars = jl_alloc_array_1d(jl_array_any_type, 0);
if (newvar != vb->var) {
btemp->lb = jl_substitute_var(btemp->lb, vb->var, (jl_value_t*)newvar);
btemp->ub = jl_substitute_var(btemp->ub, vb->var, (jl_value_t*)newvar);
}
jl_array_ptr_1d_push(btemp->innervars, (jl_value_t*)newvar);
wrap = 0;
btemp = btemp->prev;
continue;
}
else
btemp->lb = jl_new_struct(jl_unionall_type, vb->var, btemp->lb);
assert((jl_value_t*)btemp->var != btemp->lb);
}
if (jl_has_typevar(btemp->ub, vb->var)) {
if (vb->ub == (jl_value_t*)btemp->var) {
JL_GC_POP();
return jl_bottom_type;
}
if (varval) {
JL_TRY {
btemp->ub = jl_substitute_var(btemp->ub, vb->var, varval);
}
JL_CATCH {
res = jl_bottom_type;
}
}
else if (btemp->ub == (jl_value_t*)vb->var)
btemp->ub = vb->ub;
else
btemp->ub = jl_new_struct(jl_unionall_type, vb->var, btemp->ub);
assert((jl_value_t*)btemp->var != btemp->ub);
}
btemp = btemp->prev;
}
// if `v` still occurs, re-wrap body in `UnionAll v` or eliminate the UnionAll
if (jl_has_typevar(res, vb->var)) {
if (varval) {
JL_TRY {
// you can construct `T{x} where x` even if T's parameter is actually
// limited. in that case we might get an invalid instantiation here.
res = jl_substitute_var(res, vb->var, varval);
}
JL_CATCH {
res = jl_bottom_type;
}
}
else {
if (newvar != vb->var)
res = jl_substitute_var(res, vb->var, (jl_value_t*)newvar);
varval = (jl_value_t*)newvar;
if (wrap)
res = jl_new_struct(jl_unionall_type, (jl_tvar_t*)newvar, res);
}
}
if (res != jl_bottom_type && vb->innervars != NULL) {
int i;
for(i=0; i < jl_array_len(vb->innervars); i++) {
jl_tvar_t *var = (jl_tvar_t*)jl_arrayref(vb->innervars, i);
if (jl_has_typevar(res, var))
res = jl_new_struct(jl_unionall_type, (jl_tvar_t*)var, res);
}
}
if (vb->right && e->envidx < e->envsz) {
jl_value_t *oldval = e->envout[e->envidx];
if (!varval || (!is_leaf_bound(varval) && !vb->occurs_inv))
e->envout[e->envidx] = (jl_value_t*)vb->var;
else if (!(oldval && jl_is_typevar(oldval) && jl_is_long(varval)))
e->envout[e->envidx] = fix_inferred_var_bound(vb->var, varval);
}
JL_GC_POP();
return res;
}
static jl_value_t *intersect_unionall_(jl_value_t *t, jl_unionall_t *u, jl_stenv_t *e, int8_t R, int param, jl_varbinding_t *vb)
{
jl_varbinding_t *btemp = e->vars;
// if the var for this unionall (based on identity) already appears somewhere
// in the environment, rename to get a fresh var.
// TODO: might need to look inside types in btemp->lb and btemp->ub
while (btemp != NULL) {
if (btemp->var == u->var || btemp->lb == (jl_value_t*)u->var ||
btemp->ub == (jl_value_t*)u->var) {
u = rename_unionall(u);
break;
}
btemp = btemp->prev;
}
JL_GC_PUSH1(&u);
vb->var = u->var;
e->vars = vb;
jl_value_t *res;
if (R) {
e->envidx++;
res = intersect(t, u->body, e, param);
e->envidx--;
}
else {
res = intersect(u->body, t, e, param);
}
vb->concrete |= (!vb->occurs_inv && vb->occurs_cov > 1 && is_leaf_typevar((jl_value_t*)u->var));
// handle the "diagonal dispatch" rule, which says that a type var occurring more
// than once, and only in covariant position, is constrained to concrete types. E.g.
// ( Tuple{Int, Int} <: Tuple{T, T} where T) but
// !( Tuple{Int, String} <: Tuple{T, T} where T)
// Then check concreteness by checking that the lower bound is not an abstract type.
if (res != jl_bottom_type && vb->concrete) {
if (jl_is_typevar(vb->lb)) {
}
else if (!is_leaf_bound(vb->lb)) {
res = jl_bottom_type;
}
}
e->vars = vb->prev;
if (res != jl_bottom_type) {
// fail on circular constraints
if (jl_has_typevar(vb->lb, u->var) || jl_has_typevar(vb->ub, u->var))
res = jl_bottom_type;
// T=Bottom in covariant position
if (vb->ub == jl_bottom_type && vb->occurs_cov)
res = jl_bottom_type;
}
if (res != jl_bottom_type)
// res is rooted by callee
res = finish_unionall(res, vb, e);
JL_GC_POP();
return res;
}
static jl_value_t *intersect_unionall(jl_value_t *t, jl_unionall_t *u, jl_stenv_t *e, int8_t R, int param)
{
jl_value_t *res=NULL, *res2=NULL, *save=NULL, *save2=NULL;
jl_savedenv_t se, se2;
jl_varbinding_t vb = { u->var, u->var->lb, u->var->ub, R, NULL, 0, 0, 0, 0, e->invdepth, 0, NULL, e->vars };
JL_GC_PUSH6(&res, &save2, &vb.lb, &vb.ub, &save, &vb.innervars);
save_env(e, &save, &se);
res = intersect_unionall_(t, u, e, R, param, &vb);
if (res != jl_bottom_type) {
if (vb.concrete || vb.occurs_inv>1 || (vb.occurs_inv && vb.occurs_cov)) {
restore_env(e, NULL, &se);
vb.occurs_cov = vb.occurs_inv = 0;
vb.constraintkind = 3;
res = intersect_unionall_(t, u, e, R, param, &vb);
}
else if (vb.occurs_cov) {
save_env(e, &save2, &se2);
restore_env(e, save, &se);
vb.occurs_cov = vb.occurs_inv = 0;
vb.lb = u->var->lb; vb.ub = u->var->ub;
vb.constraintkind = 2;
res2 = intersect_unionall_(t, u, e, R, param, &vb);
if (res2 == jl_bottom_type) {
restore_env(e, save, &se);
vb.occurs_cov = vb.occurs_inv = 0;
vb.lb = u->var->lb; vb.ub = u->var->ub;
vb.constraintkind = 1;
res2 = intersect_unionall_(t, u, e, R, param, &vb);
if (res2 == jl_bottom_type)
restore_env(e, save2, &se2);
}
if (res2 != jl_bottom_type)
res = res2;
free(se2.buf);
}
}
free(se.buf);
JL_GC_POP();
return res;
}
// check n = (length of vararg type v)
static int intersect_vararg_length(jl_value_t *v, ssize_t n, jl_stenv_t *e, int8_t R)
{
jl_tvar_t *va_p1=NULL, *va_p2=NULL;
jl_value_t *tail = unwrap_2_unionall(v, &va_p1, &va_p2);
assert(jl_is_datatype(tail));
jl_value_t *N = jl_tparam1(tail);
// only do the check if N is free in the tuple type's last parameter
if (jl_is_typevar(N) && N != (jl_value_t*)va_p1 && N != (jl_value_t*)va_p2) {
jl_value_t *len = jl_box_long(n);
jl_value_t *il = R ? intersect(len, N, e, 2) : intersect(N, len, e, 2);
if (il == jl_bottom_type)
return 0;
}
return 1;
}
static jl_value_t *intersect_tuple(jl_datatype_t *xd, jl_datatype_t *yd, jl_stenv_t *e, int param)
{
size_t lx = jl_nparams(xd), ly = jl_nparams(yd);
if (lx == 0 && ly == 0)
return (jl_value_t*)yd;
int vx=0, vy=0, vvx = (lx > 0 && jl_is_vararg_type(jl_tparam(xd, lx-1)));
int vvy = (ly > 0 && jl_is_vararg_type(jl_tparam(yd, ly-1)));
if (!vvx && !vvy && lx != ly)
return jl_bottom_type;
jl_svec_t *params = jl_alloc_svec(lx > ly ? lx : ly);
jl_value_t *res=NULL;
JL_GC_PUSH1(¶ms);
size_t i=0, j=0;
jl_value_t *xi, *yi;
while (1) {
xi = i < lx ? jl_tparam(xd, i) : NULL;
yi = j < ly ? jl_tparam(yd, j) : NULL;
if (xi == NULL && yi == NULL) {
assert(i == j && i == jl_svec_len(params));
break;
}
if (xi && jl_is_vararg_type(xi)) vx = 1;
if (yi && jl_is_vararg_type(yi)) vy = 1;
if (xi == NULL || yi == NULL) {
res = jl_bottom_type;
if (vx && intersect_vararg_length(xi, ly+1-lx, e, 0))
res = (jl_value_t*)jl_apply_tuple_type_v(jl_svec_data(params), j);
if (vy && intersect_vararg_length(yi, lx+1-ly, e, 1))
res = (jl_value_t*)jl_apply_tuple_type_v(jl_svec_data(params), i);
break;
}
if (vx && !vy)
xi = jl_unwrap_vararg(xi);
if (vy && !vx)
yi = jl_unwrap_vararg(yi);
jl_varbinding_t *xb=NULL, *yb=NULL;
if (vx && vy) {
// {A^n...,Vararg{T,N}} ∩ {Vararg{S,M}} = {(A∩S)^n...,Vararg{T∩S,N}} plus N = M-n
jl_value_t *xlen = jl_tparam1(jl_unwrap_unionall(xi));
if (jl_is_typevar(xlen)) {
xb = lookup(e, (jl_tvar_t*)xlen);
if (xb)
xb->offset = ly-lx;
}
jl_value_t *ylen = jl_tparam1(jl_unwrap_unionall(yi));
if (jl_is_typevar(ylen)) {
yb = lookup(e, (jl_tvar_t*)ylen);
if (yb)
yb->offset = lx-ly;
}
}
jl_value_t *ii = intersect(xi, yi, e, param == 0 ? 1 : param);
if (xb) xb->offset = 0;
if (yb) yb->offset = 0;
if (ii == jl_bottom_type) {
if (vx && vy) {
int len = i > j ? i : j;
if ((xb && jl_is_long(xb->lb) && lx-1+jl_unbox_long(xb->lb) != len) ||
(yb && jl_is_long(yb->lb) && ly-1+jl_unbox_long(yb->lb) != len)) {
res = jl_bottom_type;
}
else if (param == 2 && jl_is_unionall(xi) != jl_is_unionall(yi)) {
res = jl_bottom_type;
}
else {
if (xb) set_var_to_const(xb, jl_box_long(len-lx+1), yb);
if (yb) set_var_to_const(yb, jl_box_long(len-ly+1), xb);
res = (jl_value_t*)jl_apply_tuple_type_v(jl_svec_data(params), len);
}
}
else {
res = jl_bottom_type;
}
break;
}
jl_svecset(params, (i > j ? i : j), ii);
if (vx && vy)
break;
if (i < lx-1 || !vx) i++;
if (j < ly-1 || !vy) j++;
}
// TODO: handle Vararg with explicit integer length parameter
if (res == NULL)
res = (jl_value_t*)jl_apply_tuple_type(params);
JL_GC_POP();
return res;
}
static void flip_vars(jl_stenv_t *e)
{
jl_varbinding_t *btemp = e->vars;
while (btemp != NULL) {
btemp->right = !btemp->right;
btemp = btemp->prev;
}
}
// intersection where xd nominally inherits from yd
static jl_value_t *intersect_sub_datatype(jl_datatype_t *xd, jl_datatype_t *yd, jl_stenv_t *e, int R, int param)
{
jl_value_t *isuper = R ? intersect((jl_value_t*)yd, (jl_value_t*)xd->super, e, param) :
intersect((jl_value_t*)xd->super, (jl_value_t*)yd, e, param);
if (isuper == jl_bottom_type) return jl_bottom_type;
if (jl_nparams(xd) == 0 || jl_nparams(xd->super) == 0)
return (jl_value_t*)xd;
jl_value_t *super_pattern=NULL;
JL_GC_PUSH2(&isuper, &super_pattern);
jl_value_t *wrapper = xd->name->wrapper;
super_pattern = jl_rewrap_unionall((jl_value_t*)((jl_datatype_t*)jl_unwrap_unionall(wrapper))->super,
wrapper);
int envsz = jl_subtype_env_size(super_pattern);
jl_value_t *ii = jl_bottom_type;
{
jl_value_t **env;
JL_GC_PUSHARGS(env, envsz);
jl_stenv_t tempe;
init_stenv(&tempe, env, envsz);
tempe.ignore_free = 1;
if (subtype_in_env(isuper, super_pattern, &tempe)) {
jl_value_t *wr = wrapper;
int i;
for(i=0; i<envsz; i++) {
// if a parameter is not constrained by the supertype, use the original
// parameter value from `x`. this is detected by the value in `env` being
// the exact typevar from the type's `wrapper`, or a free typevar.
jl_value_t *ei = env[i];
if (ei == (jl_value_t*)((jl_unionall_t*)wr)->var ||
(jl_is_typevar(ei) && lookup(e, (jl_tvar_t*)ei) == NULL))
env[i] = jl_tparam(xd,i);
wr = ((jl_unionall_t*)wr)->body;
}
JL_TRY {
ii = jl_apply_type(wrapper, env, envsz);
}
JL_CATCH {
ii = jl_bottom_type;
}
}
JL_GC_POP();
}
JL_GC_POP();
return ii;
}
static jl_value_t *intersect_invariant(jl_value_t *x, jl_value_t *y, jl_stenv_t *e)
{
if (!jl_has_free_typevars(x) && !jl_has_free_typevars(y)) {
return (jl_subtype(x,y) && jl_subtype(y,x)) ? y : NULL;
}
e->invdepth++;
jl_value_t *ii = intersect(x, y, e, 2);
e->invdepth--;
if (jl_is_typevar(x) && jl_is_typevar(y) && (jl_is_typevar(ii) || !jl_is_type(ii)))
return ii;
if (ii == jl_bottom_type) {
if (!subtype_in_env(x, ii, e))
return NULL;
flip_vars(e);
if (!subtype_in_env(y, ii, e))
ii = NULL;
flip_vars(e);
return ii;
}
/*
TODO: This is a band-aid for issue #23685. A better solution would be to
first normalize types so that all `where` expressions in covariant position
are pulled out to the top level.
*/
if ((jl_is_typevar(x) && !jl_is_typevar(y) && lookup(e, (jl_tvar_t*)x) == NULL) ||
(jl_is_typevar(y) && !jl_is_typevar(x) && lookup(e, (jl_tvar_t*)y) == NULL))
return ii;
jl_value_t *root=NULL;
jl_savedenv_t se;
JL_GC_PUSH2(&ii, &root);
save_env(e, &root, &se);
if (!subtype_in_env(x, y, e)) {
ii = NULL;
}
else {
flip_vars(e);
if (!subtype_in_env(y, x, e))
ii = NULL;
flip_vars(e);
}
restore_env(e, root, &se);
free(se.buf);
JL_GC_POP();
return ii;
}
// intersection where x == Type{...} and y is not
static jl_value_t *intersect_type_type(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int8_t R)
{
jl_value_t *p0 = jl_tparam0(x);
if (!jl_is_typevar(p0))
return (jl_typeof(p0) == y) ? x : jl_bottom_type;
if (!jl_is_kind(y)) return jl_bottom_type;
if (y == (jl_value_t*)jl_typeofbottom_type && ((jl_tvar_t*)p0)->lb == jl_bottom_type)
return (jl_value_t*)jl_wrap_Type(jl_bottom_type);
if (((jl_tvar_t*)p0)->ub == (jl_value_t*)jl_any_type)
return y;
return x;
/*
jl_value_t *ii = R ? intersect_invariant(y, jl_tparam0(x), e) : intersect_invariant(jl_tparam0(x), y, e);
// NOTE: we cannot express e.g. DataType ∩ (UnionAll T<:Integer Type{T}), so returning `x`
// here is a conservative over-estimate.
if (ii == NULL || ii == jl_bottom_type) return x;
if (ii == y) return ii;
return (jl_value_t*)jl_wrap_Type(ii);
*/
}
// `param` means we are currently looking at a parameter of a type constructor
// (as opposed to being outside any type constructor, or comparing variable bounds).
// this is used to record the positions where type variables occur for the
// diagonal rule (record_var_occurrence).
static jl_value_t *intersect(jl_value_t *x, jl_value_t *y, jl_stenv_t *e, int param)
{
if (x == y) return y;
if (jl_is_typevar(x)) {
if (jl_is_typevar(y)) {
jl_varbinding_t *xx = lookup(e, (jl_tvar_t*)x);
jl_varbinding_t *yy = lookup(e, (jl_tvar_t*)y);
int R = 0;
if (xx && yy && var_outside(e, (jl_tvar_t*)x, (jl_tvar_t*)y)) {
// to preserve variable identities correctly, always accumulate bounds
// on the outer variable, return the outer variable, and set the inner
// variable equal to the outer variable.
jl_value_t *temp; jl_varbinding_t *tvb;
temp = x; x = y; y = temp;
tvb = xx; xx = yy; yy = tvb;
R = 1;
}
if (param == 2) {
jl_value_t *xlb = xx ? xx->lb : ((jl_tvar_t*)x)->lb;
jl_value_t *xub = xx ? xx->ub : ((jl_tvar_t*)x)->ub;
jl_value_t *ylb = yy ? yy->lb : ((jl_tvar_t*)y)->lb;
jl_value_t *yub = yy ? yy->ub : ((jl_tvar_t*)y)->ub;
record_var_occurrence(xx, e, param);
if (xx && yy && xx->depth0 != yy->depth0) {
record_var_occurrence(yy, e, param);
return subtype_in_env(yy->ub, yy->lb, e) ? y : jl_bottom_type;
}
if (xub == xlb && jl_is_typevar(xub)) {
if (y == xub) {
record_var_occurrence(yy, e, param);
return y;
}
return intersect(y, xub, e, param);
}
record_var_occurrence(yy, e, param);
if (!jl_is_type(ylb) && !jl_is_typevar(ylb)) {
if (xx)
return set_var_to_const(xx, ylb, yy);
if ((xlb == jl_bottom_type && xub == (jl_value_t*)jl_any_type) || jl_egal(xlb, ylb))
return ylb;
return jl_bottom_type;
}
if (!jl_is_type(xlb) && !jl_is_typevar(xlb)) {
if (yy)
return set_var_to_const(yy, xlb, xx);
if (ylb == jl_bottom_type && yub == (jl_value_t*)jl_any_type)
return xlb;
return jl_bottom_type;
}
if (!(subtype_in_env(xlb, yub, e) && subtype_in_env(ylb, xub, e)))
return jl_bottom_type;
jl_value_t *ub=NULL, *lb=NULL;
JL_GC_PUSH2(&lb, &ub);
ub = intersect_ufirst(xub, yub, e, xx ? xx->depth0 : 0);
lb = simple_join(xlb, ylb);
if (yy) {
if (lb != y)
yy->lb = lb;
if (ub != y)
yy->ub = ub;
assert(yy->ub != y);
assert(yy->lb != y);
}
if (xx) {
xx->lb = y;
xx->ub = y;
assert(xx->ub != x);
}
JL_GC_POP();
return y;
}
record_var_occurrence(xx, e, param);
record_var_occurrence(yy, e, param);
if (xx && yy && xx->concrete && !yy->concrete) {
return intersect_var((jl_tvar_t*)x, y, e, R, param);
}
return intersect_var((jl_tvar_t*)y, x, e, !R, param);
}
record_var_occurrence(lookup(e, (jl_tvar_t*)x), e, param);
return intersect_var((jl_tvar_t*)x, y, e, 0, param);
}
if (jl_is_typevar(y)) {
record_var_occurrence(lookup(e, (jl_tvar_t*)y), e, param);
return intersect_var((jl_tvar_t*)y, x, e, 1, param);
}
if (!jl_has_free_typevars(x) && !jl_has_free_typevars(y)) {
if (jl_subtype(x, y)) return x;
if (jl_subtype(y, x)) return y;
}
if (jl_is_uniontype(x)) {
if (y == ((jl_uniontype_t*)x)->a || y == ((jl_uniontype_t*)x)->b)
return y;
return intersect_union(y, (jl_uniontype_t*)x, e, 0, param);
}
if (jl_is_uniontype(y)) {
if (x == ((jl_uniontype_t*)y)->a || x == ((jl_uniontype_t*)y)->b)
return x;
if (jl_is_unionall(x) && (jl_has_free_typevars(x) || jl_has_free_typevars(y)))
return intersect_unionall(y, (jl_unionall_t*)x, e, 0, param);
return intersect_union(x, (jl_uniontype_t*)y, e, 1, param);
}
if (y == (jl_value_t*)jl_any_type) return x;
if (x == (jl_value_t*)jl_any_type) return y;
if (jl_is_unionall(x)) {
if (jl_is_unionall(y)) {
jl_value_t *a=NULL, *b=jl_bottom_type, *res=NULL;
JL_GC_PUSH2(&a,&b);
jl_value_t *unused; jl_savedenv_t se;
save_env(e, &unused, &se);
a = intersect_unionall(y, (jl_unionall_t*)x, e, 0, param);
if (jl_is_unionall(a)) {
jl_unionall_t *ua = (jl_unionall_t*)a;
if (jl_is_unionall(ua->body)) {
jl_unionall_t *ub = (jl_unionall_t*)ua->body;
if (jl_has_typevar(ub->var->ub, ua->var) ||
jl_has_typevar(ub->var->lb, ua->var)) {
restore_env(e, NULL, &se); // restore counts
b = intersect_unionall(x, (jl_unionall_t*)y, e, 1, param);
}
}
}
free(se.buf);
if (!jl_has_free_typevars(a) && !jl_has_free_typevars(b)) {
if (jl_subtype(a, b))
res = b;
else if (jl_subtype(b, a))
res = a;
}
if (!res) res = simple_join(a, b);
JL_GC_POP();
return res;
}
return intersect_unionall(y, (jl_unionall_t*)x, e, 0, param);
}
if (jl_is_unionall(y))
return intersect_unionall(x, (jl_unionall_t*)y, e, 1, param);
if (jl_is_datatype(x) && jl_is_datatype(y)) {
jl_datatype_t *xd = (jl_datatype_t*)x, *yd = (jl_datatype_t*)y;
if (param < 2) {
if (jl_is_type_type(x)) {
if (!jl_is_type_type(y))
return intersect_type_type(x, y, e, 0);
}
else if (jl_is_type_type(y)) {
return intersect_type_type(y, x, e, 1);
}
}
if (xd->name == yd->name) {
if (jl_is_tuple_type(xd))
return intersect_tuple(xd, yd, e, param);
if (jl_is_vararg_type(x)) {
// Vararg: covariant in first parameter, invariant in second
jl_value_t *xp1=jl_tparam0(xd), *xp2=jl_tparam1(xd), *yp1=jl_tparam0(yd), *yp2=jl_tparam1(yd);
// in Vararg{T1} <: Vararg{T2}, need to check subtype twice to
// simulate the possibility of multiple arguments, which is needed
// to implement the diagonal rule correctly.
if (intersect(xp1, yp1, e, param==0 ? 1 : param) == jl_bottom_type)
return jl_bottom_type;
jl_value_t *i2=NULL, *ii = intersect(xp1, yp1, e, 1);
if (ii == jl_bottom_type) return jl_bottom_type;
if (jl_is_typevar(xp1)) {
jl_varbinding_t *xb = lookup(e, (jl_tvar_t*)xp1);
if (xb && is_leaf_typevar((jl_value_t*)xb->var)) xb->concrete = 1;
}
if (jl_is_typevar(yp1)) {
jl_varbinding_t *yb = lookup(e, (jl_tvar_t*)yp1);
if (yb && is_leaf_typevar((jl_value_t*)yb->var)) yb->concrete = 1;
}
JL_GC_PUSH2(&ii, &i2);
// Vararg{T,N} <: Vararg{T2,N2}; equate N and N2
i2 = intersect_invariant(xp2, yp2, e);
if (i2 == NULL || i2 == jl_bottom_type || (jl_is_long(i2) && jl_unbox_long(i2) < 0))
ii = jl_bottom_type;
else
ii = jl_apply_type2((jl_value_t*)jl_vararg_type, ii, i2);
JL_GC_POP();
return ii;
}
size_t i, np = jl_nparams(xd);
jl_value_t **newparams;
JL_GC_PUSHARGS(newparams, np);
for (i=0; i < np; i++) {
jl_value_t *xi = jl_tparam(xd, i), *yi = jl_tparam(yd, i);
jl_value_t *ii = intersect_invariant(xi, yi, e);
if (ii == NULL)
break;
newparams[i] = ii;
}
jl_value_t *res;
if (i < np)
res = jl_bottom_type;
else
res = jl_apply_type(xd->name->wrapper, newparams, np);
JL_GC_POP();
return res;
}
if (param == 2) return jl_bottom_type;
while (xd != jl_any_type && xd->name != yd->name)
xd = xd->super;
if (xd == jl_any_type) {
xd = (jl_datatype_t*)x;
while (yd != jl_any_type && yd->name != xd->name)
yd = yd->super;
if (yd == jl_any_type)
return jl_bottom_type;
return intersect_sub_datatype((jl_datatype_t*)y, xd, e, 1, param);
}
return intersect_sub_datatype((jl_datatype_t*)x, yd, e, 0, param);
}
if (jl_egal(x, y)) return y;
return jl_bottom_type;
}
static jl_value_t *intersect_all(jl_value_t *x, jl_value_t *y, jl_stenv_t *e)
{
e->Runions.depth = 0;
e->Runions.more = 0;
memset(e->Runions.stack, 0, sizeof(e->Runions.stack));
jl_value_t **is;
JL_GC_PUSHARGS(is, 2);
int lastset = 0, niter = 0, total_iter = 0;
jl_value_t *ii = intersect(x, y, e, 0);
while (e->Runions.more) {
if (e->emptiness_only && ii != jl_bottom_type) {
JL_GC_POP();
return ii;
}
e->Runions.depth = 0;
int set = e->Runions.more - 1;
e->Runions.more = 0;
statestack_set(&e->Runions, set, 1);
for (int i = set + 1; i <= lastset; i++)
statestack_set(&e->Runions, i, 0);
lastset = set;
is[0] = ii;
is[1] = intersect(x, y, e, 0);
if (is[0] == jl_bottom_type)
ii = is[1];
else if (is[1] == jl_bottom_type)
ii = is[0];
else {
// TODO: the repeated subtype checks in here can get expensive
ii = jl_type_union(is, 2);
niter++;
}
total_iter++;
if (niter > 3 || total_iter > 400000) {
JL_GC_POP();
return y;
}
}
JL_GC_POP();
return ii;
}
// type intersection entry points
static jl_value_t *intersect_types(jl_value_t *x, jl_value_t *y, int emptiness_only)
{
jl_stenv_t e;
if (obviously_disjoint(x, y, 0))
return jl_bottom_type;
init_stenv(&e, NULL, 0);
e.intersection = 1;
e.emptiness_only = emptiness_only;
return intersect_all(x, y, &e);
}
JL_DLLEXPORT jl_value_t *jl_intersect_types(jl_value_t *x, jl_value_t *y)
{
return intersect_types(x, y, 0);
}
// TODO: this can probably be done more efficiently
JL_DLLEXPORT int jl_has_empty_intersection(jl_value_t *x, jl_value_t *y)
{
return intersect_types(x, y, 1) == jl_bottom_type;
}
// return a SimpleVector of all vars from UnionAlls wrapping a given type
jl_svec_t *jl_outer_unionall_vars(jl_value_t *u)
{
int ntvars = jl_subtype_env_size((jl_value_t*)u);
jl_svec_t *vec = jl_alloc_svec_uninit(ntvars);
JL_GC_PUSH1(&vec);
jl_unionall_t *ua = (jl_unionall_t*)u;
int i;
for(i=0; i < ntvars; i++) {
assert(jl_is_unionall(ua));
jl_svecset(vec, i, ua->var);
ua = (jl_unionall_t*)ua->body;
}
JL_GC_POP();
return vec;
}
// sets *issubty to 1 iff `a` is a subtype of `b`
jl_value_t *jl_type_intersection_env_s(jl_value_t *a, jl_value_t *b, jl_svec_t **penv, int *issubty)
{
if (issubty) *issubty = 0;
if (obviously_disjoint(a, b, 0)) {
if (issubty && a == jl_bottom_type) *issubty = 1;
return jl_bottom_type;
}
int szb = jl_subtype_env_size(b);
int sz = 0, i = 0;
jl_value_t **env, **ans;
JL_GC_PUSHARGS(env, szb+1);
ans = &env[szb]; *ans = jl_bottom_type;
if (jl_subtype_env(a, b, env, szb)) {
*ans = a; sz = szb;
if (issubty) *issubty = 1;
}
else if (jl_subtype(b, a)) {
*ans = b;
}
else {
int lta = jl_is_concrete_type(a);
int ltb = jl_is_concrete_type(b);
if (lta && ltb)
goto bot;
jl_stenv_t e;
init_stenv(&e, NULL, 0);
e.intersection = 1;
e.envout = env;
if (szb)
memset(env, 0, szb*sizeof(void*));
e.envsz = szb;
*ans = intersect_all(a, b, &e);
if (*ans == jl_bottom_type) goto bot;
// TODO: don't yet use the types returned by `intersect`, since it returns
// Unions of Tuples and other code can only handle direct Tuples.
if (!jl_is_datatype(jl_unwrap_unionall(*ans))) {
*ans = b;
}
else {
sz = szb;
// TODO: compute better `env` directly during intersection.
// for now, we attempt to compute env by using subtype on the intersection result
if (szb > 0 && !jl_types_equal(b, (jl_value_t*)jl_type_type)) {
if (!jl_subtype_env(*ans, b, env, szb)) {
sz = 0;
}
}
}
}
if (sz == 0 && szb > 0) {
while (jl_is_unionall(b)) {
env[i++] = (jl_value_t*)((jl_unionall_t*)b)->var;
b = ((jl_unionall_t*)b)->body;
}
sz = szb;
}
if (penv) {
jl_svec_t *e = jl_alloc_svec(sz);
*penv = e;
for(i=0; i < sz; i++)
jl_svecset(e, i, env[i]);
}
bot:
JL_GC_POP();
return *ans;
}
jl_value_t *jl_type_intersection_env(jl_value_t *a, jl_value_t *b, jl_svec_t **penv)
{
return jl_type_intersection_env_s(a, b, penv, NULL);
}
JL_DLLEXPORT jl_value_t *jl_type_intersection(jl_value_t *a, jl_value_t *b)
{
return jl_type_intersection_env(a, b, NULL);
}
JL_DLLEXPORT jl_svec_t *jl_type_intersection_with_env(jl_value_t *a, jl_value_t *b)
{
jl_svec_t *env = jl_emptysvec;
jl_value_t *ti = NULL;
JL_GC_PUSH2(&env, &ti);
ti = jl_type_intersection_env(a, b, &env);
jl_svec_t *pair = jl_svec2(ti, env);
JL_GC_POP();
return pair;
}
int jl_subtype_matching(jl_value_t *a, jl_value_t *b, jl_svec_t **penv)
{
int szb = penv ? jl_subtype_env_size(b) : 0;
if (szb == 0)
return jl_subtype_env(a, b, NULL, szb);
jl_value_t **env;
JL_GC_PUSHARGS(env, szb);
int sub = jl_subtype_env(a, b, env, szb);
if (sub) {
// copy env to svec for return
int i = 0;
jl_svec_t *e = jl_alloc_svec(szb);
*penv = e;
for (i = 0; i < szb; i++)
jl_svecset(e, i, env[i]);
}
JL_GC_POP();
return sub;
}
// specificity comparison
static int eq_msp(jl_value_t *a, jl_value_t *b, jl_typeenv_t *env)
{
if (!(jl_is_type(a) || jl_is_typevar(a)) ||
!(jl_is_type(b) || jl_is_typevar(b)))
return jl_egal(a, b);
JL_GC_PUSH2(&a, &b);
jl_typeenv_t *e = env;
while (e != NULL) {
a = jl_type_unionall(e->var, a);
b = jl_type_unionall(e->var, b);
e = e->prev;
}
int eq = jl_types_equal(a, b);
JL_GC_POP();
return eq;
}
static int sub_msp(jl_value_t *a, jl_value_t *b, jl_typeenv_t *env)
{
JL_GC_PUSH2(&a, &b);
while (env != NULL) {
a = jl_type_unionall(env->var, a);
b = jl_type_unionall(env->var, b);
env = env->prev;
}
int sub = jl_subtype(a, b);
JL_GC_POP();
return sub;
}
static int type_morespecific_(jl_value_t *a, jl_value_t *b, int invariant, jl_typeenv_t *env);
static int num_occurs(jl_tvar_t *v, jl_typeenv_t *env);
static jl_value_t *nth_tuple_elt(jl_datatype_t *t, size_t i)
{
size_t len = jl_field_count(t);
if (len == 0)
return NULL;
if (i < len-1)
return jl_tparam(t, i);
jl_value_t *last = jl_unwrap_unionall(jl_tparam(t, len-1));
if (jl_is_vararg_type(last)) {
jl_value_t *n = jl_tparam1(last);
if (jl_is_long(n) && i >= len-1+jl_unbox_long(n))
return NULL;
return jl_tparam0(last);
}
if (i == len-1)
return jl_tparam(t, i);
return NULL;
}
static int tuple_morespecific(jl_datatype_t *cdt, jl_datatype_t *pdt, int invariant, jl_typeenv_t *env)
{
size_t plen = jl_nparams(pdt);
if (plen == 0) return 0;
size_t clen = jl_nparams(cdt);
if (clen == 0) return 1;
int i = 0;
jl_vararg_kind_t ckind = jl_vararg_kind(jl_tparam(cdt,clen-1));
int cva = ckind > JL_VARARG_INT;
int pva = jl_vararg_kind(jl_tparam(pdt,plen-1)) > JL_VARARG_INT;
int cdiag = 0, pdiag = 0;
int some_morespecific = 0;
while (1) {
if (cva && pva && i >= clen && i >= plen)
break;
jl_value_t *ce = nth_tuple_elt(cdt, i);
jl_value_t *pe = nth_tuple_elt(pdt, i);
if (ce == NULL) {
if (pe == NULL) break;
return 1;
}
if (pe == NULL) {
if (!cva && !some_morespecific)
return 0;
break;
}
if (type_morespecific_(pe, ce, invariant, env)) {
assert(!type_morespecific_(ce, pe, invariant, env));
return 0;
}
if (!cdiag && jl_is_typevar(ce) && num_occurs((jl_tvar_t*)ce,env) > 1)
cdiag = 1;
if (!pdiag && jl_is_typevar(pe) && num_occurs((jl_tvar_t*)pe,env) > 1)
pdiag = 1;
// in Tuple{a,b...} and Tuple{c,d...} allow b and d to be disjoint
if (cva && pva && i >= clen-1 && i >= plen-1 && (some_morespecific || (cdiag && !pdiag)))
return 1;
int cms = type_morespecific_(ce, pe, invariant, env);
int eqv = !cms && eq_msp(ce, pe, env);
if (!cms && !eqv) {
/*
A bound vararg tuple can be more specific despite disjoint elements in order to
preserve transitivity. For example in
A = Tuple{Array{T,N}, Vararg{Int,N}} where {T,N}
B = Tuple{Array, Int}
C = Tuple{AbstractArray, Int, Array}
we need A < B < C and A < C.
*/
return some_morespecific && cva && ckind == JL_VARARG_BOUND;
}
// Tuple{..., T} not more specific than Tuple{..., Vararg{S}} if S is diagonal
if (eqv && i == clen-1 && clen == plen && !cva && pva && jl_is_typevar(ce) && jl_is_typevar(pe) && !cdiag && pdiag)
return 0;
if (cms) some_morespecific = 1;
i++;
}
if (cva && pva && clen > plen && (!pdiag || cdiag))
return 1;
if (cva && !pva && !some_morespecific)
return 0;
return some_morespecific || (cdiag && !pdiag);
}
static size_t tuple_full_length(jl_value_t *t)
{
size_t n = jl_nparams(t);
if (n == 0) return 0;
jl_value_t *last = jl_unwrap_unionall(jl_tparam(t,n-1));
if (jl_is_vararg_type(last)) {
jl_value_t *N = jl_tparam1(last);
if (jl_is_long(N))
n += jl_unbox_long(N)-1;
}
return n;
}
// Called when a is a bound-vararg and b is not a vararg. Sets the vararg length
// in a to match b, as long as this makes some earlier argument more specific.
static int args_morespecific_fix1(jl_value_t *a, jl_value_t *b, int swap, jl_typeenv_t *env)
{
size_t n = jl_nparams(a);
int taillen = tuple_full_length(b)-n+1;
if (taillen <= 0)
return -1;
assert(jl_is_va_tuple((jl_datatype_t*)a));
jl_datatype_t *new_a = NULL;
jl_value_t *e[2] = { jl_tparam1(jl_unwrap_unionall(jl_tparam(a, n-1))), jl_box_long(taillen) };
JL_GC_PUSH2(&new_a, &e[1]);
new_a = (jl_datatype_t*)jl_instantiate_type_with((jl_value_t*)a, e, 1);
int changed = 0;
for (size_t i = 0; i < n-1; i++) {
if (jl_tparam(a, i) != jl_tparam(new_a, i)) {
changed = 1;
break;
}
}
int ret = -1;
if (changed) {
if (eq_msp(b, (jl_value_t*)new_a, env))
ret = swap;
else if (swap)
ret = type_morespecific_(b, (jl_value_t*)new_a, 0, env);
else
ret = type_morespecific_((jl_value_t*)new_a, b, 0, env);
}
JL_GC_POP();
return ret;
}
static int partially_morespecific(jl_value_t *a, jl_value_t *b, int invariant, jl_typeenv_t *env)
{
if (jl_is_uniontype(b)) {
jl_uniontype_t *u = (jl_uniontype_t*)b;
if (type_morespecific_(a, u->a, invariant, env) ||
type_morespecific_(a, u->b, invariant, env))
return 1;
return 0;
}
return type_morespecific_(a, b, invariant, env);
}
static int count_occurs(jl_value_t *t, jl_tvar_t *v)
{
if (t == (jl_value_t*)v)
return 1;
if (jl_is_uniontype(t)) {
int a = count_occurs(((jl_uniontype_t*)t)->a, v);
int b = count_occurs(((jl_uniontype_t*)t)->b, v);
return a > b ? a : b;
}
if (jl_is_unionall(t)) {
if (((jl_unionall_t*)t)->var == v)
return 0;
return count_occurs(((jl_unionall_t*)t)->body, v);
}
if (jl_is_datatype(t)) {
int i, c=0;
for(i=0; i < jl_nparams(t); i++)
c += count_occurs(jl_tparam(t,i), v);
return c;
}
return 0;
}
static int num_occurs(jl_tvar_t *v, jl_typeenv_t *env)
{
while (env != NULL) {
if (env->var == v)
return (int)(ssize_t)env->val;
env = env->prev;
}
return 0;
}
static int type_morespecific_(jl_value_t *a, jl_value_t *b, int invariant, jl_typeenv_t *env)
{
if (a == b)
return 0;
if (jl_is_unionall(a)) {
jl_unionall_t *ua = (jl_unionall_t*)a;
jl_typeenv_t newenv = { ua->var, 0x0, env };
newenv.val = (jl_value_t*)(intptr_t)count_occurs(ua->body, ua->var);
return type_morespecific_(ua->body, b, invariant, &newenv);
}
if (jl_is_unionall(b)) {
jl_unionall_t *ub = (jl_unionall_t*)b;
jl_typeenv_t newenv = { ub->var, 0x0, env };
newenv.val = (jl_value_t*)(intptr_t)count_occurs(ub->body, ub->var);
return type_morespecific_(a, ub->body, invariant, &newenv);
}
if (jl_is_tuple_type(a) && jl_is_tuple_type(b)) {
// When one is JL_VARARG_BOUND and the other has fixed length,
// allow the argument length to fix the tvar
jl_vararg_kind_t akind = jl_va_tuple_kind((jl_datatype_t*)a);
jl_vararg_kind_t bkind = jl_va_tuple_kind((jl_datatype_t*)b);
int ans = -1;
if (akind == JL_VARARG_BOUND && bkind < JL_VARARG_BOUND) {
ans = args_morespecific_fix1(a, b, 0, env);
if (ans == 1) return 1;
}
if (bkind == JL_VARARG_BOUND && akind < JL_VARARG_BOUND) {
ans = args_morespecific_fix1(b, a, 1, env);
if (ans == 0) return 0;
}
return tuple_morespecific((jl_datatype_t*)a, (jl_datatype_t*)b, invariant, env);
}
if (jl_is_uniontype(a)) {
// Union a is more specific than b if some element of a is more specific than b, but
// not vice-versa.
jl_uniontype_t *u = (jl_uniontype_t*)a;
return ((partially_morespecific(u->a, b, invariant, env) || partially_morespecific(u->b, b, invariant, env)) &&
!partially_morespecific(b, a, invariant, env));
}
if (jl_is_type_type(a) && !invariant) {
if (b == (jl_value_t*)jl_typeofbottom_type)
return 0;
jl_value_t *tp0a = jl_tparam0(a);
if (jl_is_typevar(tp0a)) {
jl_value_t *ub = ((jl_tvar_t*)tp0a)->ub;
if (jl_is_kind(b) && !sub_msp((jl_value_t*)jl_any_type, ub, env))
return 1;
}
else if (tp0a == jl_bottom_type) {
if (sub_msp(b, (jl_value_t*)jl_type_type, env))
return 1;
}
else if (b == (jl_value_t*)jl_datatype_type || b == (jl_value_t*)jl_unionall_type ||
b == (jl_value_t*)jl_uniontype_type) {
return 1;
}
}
if (jl_is_uniontype(b)) {
jl_uniontype_t *u = (jl_uniontype_t*)b;
if (type_morespecific_(a, u->a, invariant, env) || type_morespecific_(a, u->b, invariant, env))
return !type_morespecific_(b, a, invariant, env);
return 0;
}
if (!invariant) {
if ((jl_datatype_t*)a == jl_any_type) return 0;
if ((jl_datatype_t*)b == jl_any_type) return 1;
}
if (jl_is_datatype(a) && jl_is_datatype(b)) {
jl_datatype_t *tta = (jl_datatype_t*)a, *ttb = (jl_datatype_t*)b;
int super = 0;
while (tta != jl_any_type) {
if (tta->name == ttb->name) {
if (super) {
if (tta->name != jl_type_typename) return 1;
jl_value_t *tp0 = jl_tparam0(b);
if (jl_is_typevar(tp0)) {
if (sub_msp((jl_value_t*)jl_any_type, ((jl_tvar_t*)tp0)->ub, env))
return 1;
}
}
assert(jl_nparams(tta) == jl_nparams(ttb));
int ascore=0, bscore=0, ascore1=0, bscore1=0, adiag=0, bdiag=0;
for(size_t i=0; i < jl_nparams(tta); i++) {
jl_value_t *apara = jl_tparam(tta,i);
jl_value_t *bpara = jl_tparam(ttb,i);
if (!jl_has_free_typevars(apara) && !jl_has_free_typevars(bpara) &&
!jl_types_equal(apara, bpara))
return 0;
if (type_morespecific_(apara, bpara, 1, env))
ascore += 1;
else if (type_morespecific_(bpara, apara, 1, env))
bscore += 1;
if (jl_is_typevar(bpara) && !jl_is_typevar(apara) && !jl_is_type(apara))
ascore1 = 1;
else if (jl_is_typevar(apara) && !jl_is_typevar(bpara) && !jl_is_type(bpara))
bscore1 = 1;
if (!adiag && jl_is_typevar(apara)) {
for(int j=i+1; j < jl_nparams(tta); j++) {
if (jl_has_typevar(jl_tparam(tta,j), (jl_tvar_t*)apara)) {
adiag = 1; break;
}
}
}
if (!bdiag && jl_is_typevar(bpara)) {
for(int j=i+1; j < jl_nparams(ttb); j++) {
if (jl_has_typevar(jl_tparam(ttb,j), (jl_tvar_t*)bpara)) {
bdiag = 1; break;
}
}
}
}
if (ascore1 > bscore1)
return 1;
if (bscore1 > ascore1 || bscore > ascore || bdiag > adiag)
return 0;
return ascore > bscore || adiag > bdiag;
}
else if (invariant) {
return 0;
}
tta = tta->super; super = 1;
}
return 0;
}
if (jl_is_typevar(a)) {
if (jl_is_typevar(b)) {
return (( type_morespecific_((jl_value_t*)((jl_tvar_t*)a)->ub,
(jl_value_t*)((jl_tvar_t*)b)->ub, 0, env) &&
!type_morespecific_((jl_value_t*)((jl_tvar_t*)a)->lb,
(jl_value_t*)((jl_tvar_t*)b)->lb, 0, env)) ||
( type_morespecific_((jl_value_t*)((jl_tvar_t*)b)->lb,
(jl_value_t*)((jl_tvar_t*)a)->lb, 0, env) &&
!type_morespecific_((jl_value_t*)((jl_tvar_t*)b)->ub,
(jl_value_t*)((jl_tvar_t*)a)->ub, 0, env)));
}
if (!jl_is_type(b))
return 0;
if (invariant) {
if (eq_msp(((jl_tvar_t*)a)->ub, b, env))
return num_occurs((jl_tvar_t*)a, env) >= 2;
return 0;
}
return type_morespecific_((jl_value_t*)((jl_tvar_t*)a)->ub, b, 0, env);
}
if (jl_is_typevar(b)) {
if (!jl_is_type(a))
return 1;
if (invariant) {
if (eq_msp(((jl_tvar_t*)b)->ub, a, env))
return num_occurs((jl_tvar_t*)b, env) < 2;
}
return type_morespecific_(a, (jl_value_t*)((jl_tvar_t*)b)->ub, 0, env);
}
return 0;
}
JL_DLLEXPORT int jl_type_morespecific(jl_value_t *a, jl_value_t *b)
{
if (obviously_disjoint(a, b, 1))
return 0;
if (jl_subtype(b, a))
return 0;
if (jl_subtype(a, b))
return 1;
return type_morespecific_(a, b, 0, NULL);
}
JL_DLLEXPORT int jl_type_morespecific_no_subtype(jl_value_t *a, jl_value_t *b)
{
return type_morespecific_(a, b, 0, NULL);
}
#ifdef __cplusplus
}
#endif