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lean4-htt/src/runtime/object.cpp
Leonardo de Moura ee050431e0 feat(runtime): add primitive hash functions
2019-04-03 04:01:36 -07:00

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/*
Copyright (c) 2018 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Author: Leonardo de Moura
*/
#include <limits>
#include <iostream>
#include <string>
#include <algorithm>
#include <map>
#include <vector>
#include <utility>
#include <unordered_set>
#include <deque>
#include "runtime/stackinfo.h"
#include "runtime/object.h"
#include "runtime/utf8.h"
#include "runtime/apply.h"
#include "runtime/flet.h"
#include "runtime/interrupt.h"
#include "runtime/hash.h"
#include "runtime/alloc.h"
#define LEAN_MAX_PRIO 8
namespace lean {
// =======================================
// External objects
struct external_object_class {
external_object_finalize_proc m_finalize;
external_object_foreach_proc m_foreach;
};
static std::vector<external_object_class*> * g_ext_classes;
static mutex * g_ext_classes_mutex;
external_object_class * register_external_object_class(external_object_finalize_proc p1, external_object_foreach_proc p2) {
unique_lock<mutex> lock(*g_ext_classes_mutex);
external_object_class * cls = new external_object_class{p1, p2};
g_ext_classes->push_back(cls);
return cls;
}
void initialize_object() {
g_ext_classes = new std::vector<external_object_class*>();
g_ext_classes_mutex = new mutex();
}
void finalize_object() {
for (external_object_class * cls : *g_ext_classes) delete cls;
delete g_ext_classes;
delete g_ext_classes_mutex;
}
// =======================================
// Object
size_t obj_byte_size(object * o) {
switch (get_kind(o)) {
case object_kind::Constructor: return cnstr_byte_size(o);
case object_kind::Closure: return closure_byte_size(o);
case object_kind::Array: return array_byte_size(o);
case object_kind::ScalarArray: return sarray_byte_size(o);
case object_kind::String: return string_byte_size(o);
case object_kind::MPZ: return sizeof(mpz_object);
case object_kind::Thunk: return sizeof(thunk_object);
case object_kind::Task: return sizeof(task_object);
case object_kind::PArrayRoot: return sizeof(parray_object);
case object_kind::PArraySet: return sizeof(parray_object);
case object_kind::PArrayPush: return sizeof(parray_object);
case object_kind::PArrayPop: return sizeof(parray_object);
case object_kind::Ref: return sizeof(ref_object);
case object_kind::External: lean_unreachable();
}
lean_unreachable();
}
size_t obj_header_size(object * o) {
switch (get_kind(o)) {
case object_kind::Constructor: return sizeof(constructor_object);
case object_kind::Closure: return sizeof(closure_object);
case object_kind::Array: return sizeof(array_object);
case object_kind::ScalarArray: return sizeof(sarray_object);
case object_kind::String: return sizeof(string_object);
case object_kind::MPZ: return sizeof(mpz_object);
case object_kind::Thunk: return sizeof(thunk_object);
case object_kind::Task: return sizeof(task_object);
case object_kind::PArrayRoot: return sizeof(parray_object);
case object_kind::PArraySet: return sizeof(parray_object);
case object_kind::PArrayPush: return sizeof(parray_object);
case object_kind::PArrayPop: return sizeof(parray_object);
case object_kind::Ref: return sizeof(ref_object);
case object_kind::External: lean_unreachable();
}
lean_unreachable();
}
/* We use the RC memory to implement a linked list of lean objects to be deleted.
This hack is safe because rc_type is uintptr_t. */
static_assert(sizeof(atomic<rc_type>) == sizeof(object*), "unexpected atomic<rc_type> size, the object GC assumes these two types have the same size"); // NOLINT
#ifdef LEAN_LAZY_RC
LEAN_THREAD_PTR(object, g_to_free);
#endif
inline object * get_next(object * o) {
return *reinterpret_cast<object**>(st_rc_addr(o));
}
inline void set_next(object * o, object * n) {
*reinterpret_cast<object**>(st_rc_addr(o)) = n;
}
inline void push_back(object * & todo, object * v) {
set_next(v, todo);
todo = v;
}
inline object * pop_back(object * & todo) {
object * r = todo;
todo = get_next(todo);
return r;
}
inline void dec_ref(object * o, object* & todo) {
if (dec_ref_core(o))
push_back(todo, o);
}
inline void dec(object * o, object* & todo) {
if (!is_scalar(o) && dec_ref_core(o))
push_back(todo, o);
}
void deactivate_task(task_object * t);
static size_t parray_data_capacity(object ** data) {
return reinterpret_cast<size_t*>(data)[-1];
}
static object ** alloc_parray_data(size_t c) {
size_t * mem = static_cast<size_t*>(malloc(sizeof(object*)*c + sizeof(size_t)));
*mem = c;
mem++;
return reinterpret_cast<object**>(mem);
}
static void dealloc_parray_data(object ** data) {
size_t * mem = reinterpret_cast<size_t*>(data);
mem--;
free(mem);
}
#ifdef LEAN_SMALL_ALLOCATOR
static inline void free_heap_obj_core(object * o, size_t sz) {
#else
static inline void free_heap_obj_core(object * o) {
#endif
#ifdef LEAN_FAKE_FREE
// Set kinds to invalid values, which should trap any further accesses in debug mode.
// Make sure object kind is recoverable for printing deleted objects
if (o->m_mem_kind != 42) {
o->m_kind = -o->m_kind;
o->m_mem_kind = 42;
}
#else
#ifdef LEAN_SMALL_ALLOCATOR
dealloc(reinterpret_cast<char *>(o) - sizeof(rc_type), sz);
#else
free(reinterpret_cast<char *>(o) - sizeof(rc_type));
#endif
#endif
}
#ifdef LEAN_SMALL_ALLOCATOR
#define FREE_OBJ(o, sz) free_heap_obj_core(o, sz)
#else
#define FREE_OBJ(o, sz) free_heap_obj_core(o)
#endif
void free_heap_obj(object * o) {
FREE_OBJ(o, obj_byte_size(o) + sizeof(rc_type));
}
static inline void free_cnstr_obj(object * o) {
FREE_OBJ(o, cnstr_byte_size(o) + sizeof(rc_type));
}
static inline void free_closure_obj_core(object * o) {
FREE_OBJ(o, closure_byte_size(o) + sizeof(rc_type));
}
void free_closure_obj(object * o) {
return free_closure_obj_core(o);
}
static inline void free_array_obj(object * o) {
FREE_OBJ(o, array_byte_size(o) + sizeof(rc_type));
}
static inline void free_sarray_obj(object * o) {
FREE_OBJ(o, sarray_byte_size(o) + sizeof(rc_type));
}
static inline void free_string_obj(object * o) {
FREE_OBJ(o, string_byte_size(o) + sizeof(rc_type));
}
inline void free_mpz_obj(object * o) {
FREE_OBJ(o, sizeof(mpz_object) + sizeof(rc_type));
}
static inline void free_thunk_obj(object * o) {
FREE_OBJ(o, sizeof(thunk_object) + sizeof(rc_type));
}
static inline void free_ref_obj(object * o) {
FREE_OBJ(o, sizeof(ref_object) + sizeof(rc_type));
}
static inline void free_task_obj(object * o) {
FREE_OBJ(o, sizeof(task_object) + sizeof(rc_type));
}
static inline void free_parray_obj(object * o) {
FREE_OBJ(o, sizeof(parray_object) + sizeof(rc_type));
}
static inline void free_external_obj(object * o) {
FREE_OBJ(o, sizeof(external_object) + sizeof(rc_type));
}
static void del_core(object * o, object * & todo) {
lean_assert(is_heap_obj(o));
LEAN_RUNTIME_STAT_CODE(g_num_del++);
switch (get_kind(o)) {
case object_kind::Constructor: {
object ** it = cnstr_obj_cptr(o);
object ** end = it + cnstr_num_objs(o);
for (; it != end; ++it) dec(*it, todo);
free_cnstr_obj(o);
break;
}
case object_kind::Closure: {
object ** it = closure_arg_cptr(o);
object ** end = it + closure_num_fixed(o);
for (; it != end; ++it) dec(*it, todo);
free_closure_obj_core(o);
break;
}
case object_kind::Array: {
object ** it = array_cptr(o);
object ** end = it + array_size(o);
for (; it != end; ++it) dec(*it, todo);
free_array_obj(o);
break;
}
case object_kind::ScalarArray:
free_sarray_obj(o); break;
case object_kind::String:
free_string_obj(o); break;
case object_kind::MPZ:
dealloc_mpz(o); break;
case object_kind::Thunk:
if (object * c = to_thunk(o)->m_closure) dec(c, todo);
if (object * v = to_thunk(o)->m_value) dec(v, todo);
free_thunk_obj(o);
break;
case object_kind::Ref:
if (object * v = to_ref(o)->m_value) dec(v, todo);
free_ref_obj(o);
break;
case object_kind::Task:
deactivate_task(to_task(o));
break;
case object_kind::PArrayPop:
dec_ref(to_parray(o)->m_next, todo);
free_parray_obj(o);
break;
case object_kind::PArrayPush:
case object_kind::PArraySet:
dec(to_parray(o)->m_elem, todo);
dec_ref(to_parray(o)->m_next, todo);
free_parray_obj(o);
break;
case object_kind::PArrayRoot: {
object ** it = to_parray(o)->m_data;
object ** end = it + to_parray(o)->m_size;
for (; it != end; ++it) dec(*it, todo);
dealloc_parray_data(to_parray(o)->m_data);
free_parray_obj(o);
break;
}
case object_kind::External:
to_external(o)->m_class->m_finalize(to_external(o)->m_data);
free_external_obj(o);
break;
}
}
void del(object * o) {
#ifdef LEAN_LAZY_RC
push_back(g_to_free, o);
#else
object * todo = nullptr;
while (true) {
lean_assert(is_heap_obj(o));
del_core(o, todo);
if (todo == nullptr)
return;
o = pop_back(todo);
}
#endif
}
void * alloc_heap_object(size_t sz) {
#ifdef LEAN_LAZY_RC
if (g_to_free) {
object * o = pop_back(g_to_free);
del_core(o, g_to_free);
}
#endif
#ifdef LEAN_SMALL_ALLOCATOR
void * r = alloc(sizeof(rc_type) + sz);
#else
void * r = malloc(sizeof(rc_type) + sz);
#endif
if (r == nullptr) throw std::bad_alloc();
*static_cast<rc_type *>(r) = 1;
return static_cast<char *>(r) + sizeof(rc_type);
}
// =======================================
// Scalar arrays
#if 0
static object * sarray_ensure_capacity(object * o, size_t extra) {
lean_assert(!is_exclusive(o));
size_t sz = sarray_size(o);
size_t cap = sarray_capacity(o);
if (sz + extra > cap) {
unsigned esize = sarray_elem_size(o);
object * new_o = alloc_sarray(esize, sz, cap + sz + extra);
lean_assert(sarray_capacity(new_o) >= sz + extra);
memcpy(sarray_cptr<char>(new_o), sarray_cptr<char>(o), esize * sz);
free_heap_obj(o);
return new_o;
} else {
return o;
}
}
#endif
// =======================================
// Persistent arrays
static object ** parray_data_expand(object ** data, size_t sz) {
size_t curr_capacity = parray_data_capacity(data);
size_t new_capacity = curr_capacity == 0 ? 2 : (3 * curr_capacity + 1) >> 1;
object ** new_data = alloc_parray_data(new_capacity);
memcpy(new_data, data, sizeof(object*)*sz);
dealloc_parray_data(data);
return new_data;
}
/* Given `c -> ... -> root`,
revert links and make `c` to be the new root:
`c <- ... <- root` */
static void parray_reroot(object * c) {
lean_assert(get_kind(c) != object_kind::PArrayRoot);
parray_object * it = to_parray(c);
parray_object * prev = nullptr;
/* invert links */
while (get_kind(it) != object_kind::PArrayRoot) {
/* c <- ... <- prev, it -> it_next -> ... -> root
c <- ... <- prev <- it, it_next -> ... -> root */
parray_object * it_next = it->m_next;
it->m_next = prev;
prev = it;
it = it_next;
}
lean_assert(prev != nullptr);
lean_assert(get_kind(it) == object_kind::PArrayRoot);
lean_assert(it != c);
object * old_root = it;
it->m_next = prev;
object ** data = it->m_data;
size_t sz = it->m_size;
prev = it;
it = it->m_next;
/* move array to `c` */
while (true) {
lean_assert(prev != nullptr && it != prev);
switch (get_kind(it)) {
case object_kind::PArraySet:
prev->m_kind = static_cast<unsigned>(object_kind::PArraySet);
prev->m_idx = it->m_idx;
prev->m_elem = data[it->m_idx];
data[it->m_idx] = it->m_elem;
break;
case object_kind::PArrayPush:
if (sz == parray_data_capacity(data))
data = parray_data_expand(data, sz);
prev->m_kind = static_cast<unsigned>(object_kind::PArrayPop);
data[sz] = it->m_elem;
sz++;
break;
case object_kind::PArrayPop:
--sz;
prev->m_kind = static_cast<unsigned>(object_kind::PArrayPush);
prev->m_elem = data[sz];
break;
default:
lean_unreachable();
}
if (it == c)
break;
prev = it;
it = it->m_next;
}
lean_assert(it == c);
it->m_kind = static_cast<unsigned>(object_kind::PArrayRoot);
it->m_data = data;
it->m_size = sz;
dec_ref(old_root);
inc_ref(c);
}
static parray_object * move_parray_root(parray_object * src) {
lean_assert(src->m_kind == static_cast<unsigned>(object_kind::PArrayRoot));
lean_assert(get_rc(src) > 1);
dec_ref(src);
parray_object * r = new (alloc_heap_object(sizeof(parray_object))) parray_object();
r->m_data = src->m_data;
r->m_size = src->m_size;
return r;
}
obj_res alloc_parray(size_t capacity) {
parray_object * r = new (alloc_heap_object(sizeof(parray_object))) parray_object();
r->m_data = alloc_parray_data(capacity);
r->m_size = 0;
return r;
}
size_t parray_size(b_obj_arg o) {
if (get_kind(o) != object_kind::PArrayRoot)
parray_reroot(o);
return to_parray(o)->m_size;
}
b_obj_res parray_get(b_obj_arg o, size_t i) {
if (get_kind(o) != object_kind::PArrayRoot)
parray_reroot(o);
return to_parray(o)->m_data[i];
}
obj_res parray_set(obj_arg o, size_t i, obj_arg v) {
if (get_kind(o) != object_kind::PArrayRoot)
parray_reroot(o);
parray_object * p = to_parray(o);
if (get_rc(p) == 1) {
dec(p->m_data[i]);
p->m_data[i] = v;
return p;
} else {
parray_object * r = move_parray_root(p);
p->m_kind = static_cast<unsigned>(object_kind::PArraySet);
p->m_idx = i;
p->m_elem = r->m_data[i];
p->m_next = r;
inc_ref(r);
r->m_data[i] = v;
return r;
}
}
obj_res parray_push(obj_arg o, obj_arg v) {
if (get_kind(o) != object_kind::PArrayRoot)
parray_reroot(o);
parray_object * p = to_parray(o);
if (p->m_size == parray_data_capacity(p->m_data))
p->m_data = parray_data_expand(p->m_data, p->m_size);
if (get_rc(p) == 1) {
p->m_data[p->m_size] = v;
p->m_size++;
return p;
} else {
parray_object * r = move_parray_root(p);
p->m_kind = static_cast<unsigned>(object_kind::PArrayPop);
p->m_next = r;
inc_ref(r);
r->m_data[r->m_size] = v;
r->m_size++;
return r;
}
}
obj_res parray_pop(obj_arg o) {
if (get_kind(o) != object_kind::PArrayRoot)
parray_reroot(o);
parray_object * p = to_parray(o);
if (get_rc(p) == 1) {
p->m_size--;
dec(p->m_data[p->m_size]);
return p;
} else {
parray_object * r = move_parray_root(p);
r->m_size--;
p->m_kind = static_cast<unsigned>(object_kind::PArrayPush);
p->m_elem = r->m_data[r->m_size];
p->m_next = r;
inc_ref(r);
return r;
}
}
obj_res parray_copy(b_obj_arg o) {
if (get_kind(o) != object_kind::PArrayRoot)
parray_reroot(o);
size_t sz = to_parray(o)->m_size;
object ** data = to_parray(o)->m_data;
parray_object * r = new (alloc_heap_object(sizeof(parray_object))) parray_object();
r->m_size = sz;
r->m_data = alloc_parray_data(parray_data_capacity(data));
memcpy(r->m_data, data, sz);
for (size_t i = 0; i < sz; i++)
inc(data[i]);
return r;
}
// =======================================
// Closures
typedef object * (*lean_cfun2)(object *, object *); // NOLINT
typedef object * (*lean_cfun3)(object *, object *, object *); // NOLINT
static obj_res mk_closure_2_1(lean_cfun2 fn, obj_arg a) {
object * c = alloc_closure(fn, 1);
closure_set(c, 0, a);
return c;
}
static obj_res mk_closure_3_2(lean_cfun3 fn, obj_arg a1, obj_arg a2) {
object * c = alloc_closure(fn, 2);
closure_set(c, 0, a1);
closure_set(c, 1, a2);
return c;
}
// =======================================
// Thunks
static obj_res mk_thunk_3_2(lean_cfun3 fn, obj_arg a1, obj_arg a2) {
return mk_thunk(mk_closure_3_2(fn, a1, a2));
}
b_obj_res thunk_get_core(b_obj_arg t) {
object * c = to_thunk(t)->m_closure.exchange(nullptr);
if (c != nullptr) {
/* Recall that a closure uses the standard calling convention.
`thunk_get` "consumes" the result `r` by storing it at `to_thunk(t)->m_value`.
Then, it returns a reference to this result to the caller.
The behavior is compatible with `cnstr_obj` with also returns a reference
to be object stored in the constructor object.
Recall that `apply_1` also consumes `c`'s RC. */
object * r = apply_1(c, box(0));
lean_assert(r != nullptr); /* Closure must return a valid lean object */
lean_assert(to_thunk(t)->m_value == nullptr);
to_thunk(t)->m_value = r;
return r;
} else {
lean_assert(c == nullptr);
/* There is another thread executing the closure. We keep waiting for the m_value to be
set by another thread. */
while (!to_thunk(t)->m_value) {
this_thread::yield();
}
return to_thunk(t)->m_value;
}
}
static obj_res thunk_map_fn_closure(obj_arg f, obj_arg t, obj_arg /* u */) {
b_obj_res v = thunk_get(t);
inc(v);
obj_res r = apply_1(f, v);
dec(v);
return r;
}
obj_res thunk_map(obj_arg f, obj_arg t) {
lean_assert(is_closure(f));
lean_assert(is_thunk(t));
return mk_thunk_3_2(thunk_map_fn_closure, f, t);
}
static obj_res thunk_bind_fn_closure(obj_arg x, obj_arg f, obj_arg /* u */) {
b_obj_res v = thunk_get(x);
inc(v);
obj_res r = apply_1(f, v);
dec(x);
return r;
}
obj_res thunk_bind(obj_arg x, obj_arg f) {
return mk_thunk_3_2(thunk_bind_fn_closure, x, f);
}
// =======================================
// Tasks
LEAN_THREAD_PTR(task_object, g_current_task_object);
void dealloc_task(task_object * t) {
if (t->m_imp) delete t->m_imp;
free_task_obj(t);
}
struct scoped_current_task_object : flet<task_object *> {
scoped_current_task_object(task_object * t):flet(g_current_task_object, t) {}
};
class task_manager {
struct worker_info {
std::unique_ptr<lthread> m_thread;
task_object * m_task;
};
typedef std::vector<worker_info *> workers;
mutex m_mutex;
unsigned m_workers_to_be_created;
workers m_workers;
std::deque<task_object *> m_queues[LEAN_MAX_PRIO+1];
unsigned m_queues_size{0};
unsigned m_max_prio{0};
condition_variable m_queue_cv;
condition_variable m_task_finished_cv;
bool m_shutting_down{false};
task_object * dequeue() {
lean_assert(m_queues_size != 0);
std::deque<task_object *> & q = m_queues[m_max_prio];
lean_assert(!q.empty());
task_object * result = q.front();
q.pop_front();
m_queues_size--;
if (q.empty()) {
while (m_max_prio > 0) {
--m_max_prio;
if (!m_queues[m_max_prio].empty())
break;
}
}
return result;
}
void enqueue_core(task_object * t) {
lean_assert(t->m_imp);
unsigned prio = t->m_imp->m_prio;
if (prio > LEAN_MAX_PRIO)
prio = LEAN_MAX_PRIO;
if (prio > m_max_prio)
m_max_prio = prio;
m_queues[prio].push_back(t);
m_queues_size++;
if (m_workers_to_be_created > 0)
spawn_worker();
else
m_queue_cv.notify_one();
}
void spawn_worker() {
lean_assert(m_workers_to_be_created > 0);
worker_info * this_worker = new worker_info();
m_workers.push_back(this_worker);
m_workers_to_be_created--;
this_worker->m_thread.reset(new lthread([this, this_worker]() {
save_stack_info(false);
unique_lock<mutex> lock(m_mutex);
while (true) {
if (m_shutting_down) {
break;
}
if (m_queues_size == 0) {
m_queue_cv.wait(lock);
continue;
}
task_object * t = dequeue();
lean_assert(t->m_imp);
if (t->m_imp->m_deleted) {
dealloc_task(t);
continue;
}
reset_heartbeat();
object * v = nullptr;
{
flet<task_object *> update_task(this_worker->m_task, t);
scoped_current_task_object scope_cur_task(t);
object * c = t->m_imp->m_closure;
t->m_imp->m_closure = nullptr;
lock.unlock();
v = apply_1(c, box(0));
lock.lock();
}
lean_assert(t->m_imp);
if (t->m_imp->m_deleted) {
if (v) dec(v);
dealloc_task(t);
} else if (v != nullptr) {
lean_assert(t->m_imp->m_closure == nullptr);
handle_finished(t);
t->m_value = v;
/* After the task has been finished and we propagated
dependecies, we can release `m_imp` and keep just the value */
delete t->m_imp;
t->m_imp = nullptr;
m_task_finished_cv.notify_all();
}
reset_heartbeat();
}
run_thread_finalizers();
run_post_thread_finalizers();
}));
}
void handle_finished(task_object * t) {
task_object * it = t->m_imp->m_head_dep;
t->m_imp->m_head_dep = nullptr;
while (it) {
if (t->m_imp->m_interrupted)
it->m_imp->m_interrupted = true;
task_object * next_it = it->m_imp->m_next_dep;
it->m_imp->m_next_dep = nullptr;
if (it->m_imp->m_deleted) {
dealloc_task(it);
} else {
enqueue_core(it);
}
it = next_it;
}
}
object * wait_any_check(object * task_list) {
object * it = task_list;
while (!is_scalar(it)) {
object * head = cnstr_get(it, 0);
lean_assert(is_thunk(head) || is_task(head));
if (is_thunk(head) || to_task(head)->m_value)
return head;
it = cnstr_get(it, 1);
}
return nullptr;
}
public:
task_manager(unsigned num_workers):
m_workers_to_be_created(num_workers) {
}
~task_manager() {
unique_lock<mutex> lock(m_mutex);
for (worker_info * info : m_workers) {
if (info->m_task) {
lean_assert(info->m_task->m_imp);
info->m_task->m_imp->m_interrupted = true;
}
}
m_shutting_down = true;
m_queue_cv.notify_all();
lock.unlock();
for (worker_info * w : m_workers) {
w->m_thread->join();
delete w;
}
for (std::deque<task_object *> const & q : m_queues) {
for (task_object * o : q) {
lean_assert(o->m_imp && o->m_imp->m_deleted);
dealloc_task(o);
}
}
}
void enqueue(task_object * t) {
unique_lock<mutex> lock(m_mutex);
enqueue_core(t);
}
void add_dep(task_object * t1, task_object * t2) {
lean_assert(t2->m_value == nullptr);
if (t1->m_value) {
enqueue(t2);
return;
}
unique_lock<mutex> lock(m_mutex);
lean_assert(t2->m_value == nullptr);
if (t1->m_value) {
enqueue_core(t2);
return;
}
t2->m_imp->m_next_dep = t1->m_imp->m_head_dep;
t1->m_imp->m_head_dep = t2;
}
void wait_for(task_object * t) {
if (t->m_value)
return;
unique_lock<mutex> lock(m_mutex);
if (t->m_value)
return;
m_task_finished_cv.wait(lock, [&]() { return t->m_value != nullptr; });
}
object * wait_any(object * task_list) {
if (object * t = wait_any_check(task_list))
return t;
unique_lock<mutex> lock(m_mutex);
while (true) {
if (object * t = wait_any_check(task_list))
return t;
m_task_finished_cv.wait(lock);
}
}
void deactivate_task(task_object * t) {
unique_lock<mutex> lock(m_mutex);
if (object * v = t->m_value) {
lean_assert(t->m_imp == nullptr);
lock.unlock();
dec(v);
free_task_obj(t);
return;
} else {
lean_assert(t->m_imp);
object * c = t->m_imp->m_closure;
task_object * it = t->m_imp->m_head_dep;
t->m_imp->m_closure = nullptr;
t->m_imp->m_head_dep = nullptr;
t->m_imp->m_interrupted = true;
t->m_imp->m_deleted = true;
lock.unlock();
while (it) {
lean_assert(it->m_imp->m_deleted);
task_object * next_it = it->m_imp->m_next_dep;
dealloc_task(it);
it = next_it;
}
if (c) dec_ref(c);
}
}
void request_interrupt(task_object * t) {
unique_lock<mutex> lock(m_mutex);
if (t->m_imp)
t->m_imp->m_interrupted = true;
}
};
static task_manager * g_task_manager = nullptr;
scoped_task_manager::scoped_task_manager(unsigned num_workers) {
lean_assert(g_task_manager == nullptr);
#if defined(LEAN_MULTI_THREAD)
g_task_manager = new task_manager(num_workers);
#endif
}
scoped_task_manager::~scoped_task_manager() {
if (g_task_manager) {
delete g_task_manager;
g_task_manager = nullptr;
}
}
void deactivate_task(task_object * t) {
lean_assert(g_task_manager);
g_task_manager->deactivate_task(t);
}
void mark_mt(object * o);
static obj_res mark_mt_fn(obj_arg o) {
mark_mt(o);
dec(o);
return box(0);
}
void mark_mt(object * o) {
#ifndef LEAN_MULTI_THREAD
return;
#endif
if (is_scalar(o) || !is_st_heap_obj(o)) return;
o->m_mem_kind = static_cast<unsigned>(object_memory_kind::MTHeap);
switch (get_kind(o)) {
case object_kind::ScalarArray:
case object_kind::String:
case object_kind::MPZ:
return;
case object_kind::PArrayPop:
case object_kind::PArrayPush:
case object_kind::PArraySet:
case object_kind::PArrayRoot:
/* `mark_mt` cannot be used with parray. They must be copied when used in multiple threads. */
lean_unreachable();
return;
case object_kind::External: {
object * fn = alloc_closure(reinterpret_cast<void*>(mark_mt_fn), 1, 0);
to_external(o)->m_class->m_foreach(to_external(o)->m_data, fn);
dec(fn);
return;
}
case object_kind::Task:
mark_mt(task_get(o));
return;
case object_kind::Constructor: {
object ** it = cnstr_obj_cptr(o);
object ** end = it + cnstr_num_objs(o);
for (; it != end; ++it) mark_mt(*it);
return;
}
case object_kind::Closure: {
object ** it = closure_arg_cptr(o);
object ** end = it + closure_num_fixed(o);
for (; it != end; ++it) mark_mt(*it);
return;
}
case object_kind::Array: {
object ** it = array_cptr(o);
object ** end = it + array_size(o);
for (; it != end; ++it) mark_mt(*it);
return;
}
case object_kind::Thunk:
if (object * c = to_thunk(o)->m_closure) mark_mt(c);
if (object * v = to_thunk(o)->m_value) mark_mt(v);
return;
case object_kind::Ref:
if (object * v = to_ref(o)->m_value) mark_mt(v);
return;
}
}
task_object::task_object(obj_arg c, unsigned prio):
object(object_kind::Task, object_memory_kind::MTHeap), m_value(nullptr), m_imp(new imp(c, prio)) {
lean_assert(is_closure(c));
mark_mt(c);
}
task_object::task_object(obj_arg v):
object(object_kind::Task, object_memory_kind::STHeap), m_value(v), m_imp(nullptr) {
}
static task_object * alloc_task(obj_arg c, unsigned prio) {
LEAN_RUNTIME_STAT_CODE(g_num_task++);
return new (alloc_heap_object(sizeof(task_object))) task_object(c, prio); // NOLINT
}
static task_object * alloc_task(obj_arg v) {
LEAN_RUNTIME_STAT_CODE(g_num_task++);
return new (alloc_heap_object(sizeof(task_object))) task_object(v); // NOLINT
}
obj_res mk_task(obj_arg c, unsigned prio) {
if (!g_task_manager) {
return mk_thunk(c);
} else {
task_object * new_task = alloc_task(c, prio);
g_task_manager->enqueue(new_task);
return new_task;
}
}
obj_res task_pure(obj_arg a) {
if (!g_task_manager) {
return thunk_pure(a);
} else {
return alloc_task(a);
}
}
static obj_res task_map_fn(obj_arg f, obj_arg t, obj_arg) {
lean_assert(is_thunk(t) || is_task(t));
b_obj_res v;
if (is_thunk(t)) v = thunk_get(t); else v = to_task(t)->m_value;
lean_assert(v != nullptr);
inc(v);
dec_ref(t);
return apply_1(f, v);
}
obj_res task_map(obj_arg f, obj_arg t, unsigned prio) {
if (!g_task_manager) {
lean_assert(is_thunk(t));
return thunk_map(f, t);
} else {
task_object * new_task = alloc_task(mk_closure_3_2(task_map_fn, f, t), prio);
if (is_thunk(t))
g_task_manager->enqueue(new_task);
else
g_task_manager->add_dep(to_task(t), new_task);
return new_task;
}
}
b_obj_res task_get(b_obj_arg t) {
if (is_thunk(t)) {
return thunk_get(t);
} else {
if (object * v = to_task(t)->m_value)
return v;
g_task_manager->wait_for(to_task(t));
lean_assert(to_task(t)->m_value != nullptr);
object * r = to_task(t)->m_value;
return r;
}
}
static obj_res task_bind_fn2(obj_arg t, obj_arg) {
lean_assert(to_task(t)->m_value);
b_obj_res v = to_task(t)->m_value;
inc(v);
dec_ref(t);
return v;
}
static obj_res task_bind_fn1(obj_arg x, obj_arg f, obj_arg) {
lean_assert(is_thunk(x) || is_task(x));
b_obj_res v;
if (is_thunk(x)) v = thunk_get(x); else v = to_task(x)->m_value;
lean_assert(v != nullptr);
inc(v);
dec_ref(x);
obj_res new_task = apply_1(f, v);
lean_assert(is_thunk(new_task) || is_task(new_task));
if (is_thunk(new_task)) {
b_obj_res r = thunk_get(new_task);
inc(r);
dec_ref(new_task);
return r;
} else {
lean_assert(is_task(new_task));
lean_assert(g_current_task_object->m_imp);
lean_assert(g_current_task_object->m_imp->m_closure == nullptr);
g_current_task_object->m_imp->m_closure = mk_closure_2_1(task_bind_fn2, new_task);
g_task_manager->add_dep(to_task(new_task), g_current_task_object);
return nullptr; /* notify queue that task did not finish yet. */
}
}
obj_res task_bind(obj_arg x, obj_arg f, unsigned prio) {
lean_assert(is_thunk(x) || is_task(x));
if (!g_task_manager) {
return thunk_bind(x, f);
} else {
task_object * new_task = alloc_task(mk_closure_3_2(task_bind_fn1, x, f), prio);
if (is_thunk(x))
g_task_manager->enqueue(new_task);
else
g_task_manager->add_dep(to_task(x), new_task);
return new_task;
}
}
bool io_check_interrupt_core() {
if (task_object * t = g_current_task_object) {
lean_assert(t->m_imp); // task is being executed
return t->m_imp->m_interrupted;
}
return false;
}
void io_request_interrupt_core(b_obj_arg t) {
lean_assert(is_thunk(t) || is_task(t));
if (is_thunk(t) || to_task(t)->m_value)
return;
g_task_manager->request_interrupt(to_task(t));
}
bool io_has_finished_core(b_obj_arg t) {
lean_assert(is_thunk(t) || is_task(t));
return is_thunk(t) || to_task(t)->m_value != nullptr;
}
b_obj_res io_wait_any_core(b_obj_arg task_list) {
return g_task_manager->wait_any(task_list);
}
void mark_persistent(object * o);
static obj_res mark_persistent_fn(obj_arg o) {
mark_persistent(o);
return box(0);
}
void mark_persistent(object * o) {
if (is_scalar(o) || !is_heap_obj(o)) return;
o->m_mem_kind = static_cast<unsigned>(object_memory_kind::Persistent);
switch (get_kind(o)) {
case object_kind::ScalarArray:
case object_kind::String:
case object_kind::MPZ:
return;
case object_kind::PArrayPop:
mark_persistent(to_parray(o)->m_next);
return;
case object_kind::PArrayPush:
case object_kind::PArraySet:
mark_persistent(to_parray(o)->m_elem);
mark_persistent(to_parray(o)->m_next);
return;
case object_kind::PArrayRoot: {
object ** it = to_parray(o)->m_data;
object ** end = it + to_parray(o)->m_size;
for (; it != end; ++it) mark_persistent(*it);
return;
}
case object_kind::External: {
object * fn = alloc_closure(reinterpret_cast<void*>(mark_persistent_fn), 1, 0);
to_external(o)->m_class->m_foreach(to_external(o)->m_data, fn);
dec(fn);
return;
}
case object_kind::Task:
mark_persistent(task_get(o));
return;
case object_kind::Constructor: {
object ** it = cnstr_obj_cptr(o);
object ** end = it + cnstr_num_objs(o);
for (; it != end; ++it) mark_persistent(*it);
return;
}
case object_kind::Closure: {
object ** it = closure_arg_cptr(o);
object ** end = it + closure_num_fixed(o);
for (; it != end; ++it) mark_persistent(*it);
return;
}
case object_kind::Array: {
object ** it = array_cptr(o);
object ** end = it + array_size(o);
for (; it != end; ++it) mark_persistent(*it);
return;
}
case object_kind::Thunk:
if (object * c = to_thunk(o)->m_closure) mark_persistent(c);
if (object * v = to_thunk(o)->m_value) mark_persistent(v);
return;
case object_kind::Ref:
if (object * v = to_ref(o)->m_value) mark_persistent(v);
return;
}
}
// =======================================
// Natural numbers
size_t size_t_of_nat(b_obj_arg n) {
if (is_scalar(n)) {
return unbox(n);
} else if (mpz_value(n).is_unsigned_long_int()) {
return static_cast<size_t>(mpz_value(n).get_unsigned_long_int());
} else {
return std::numeric_limits<size_t>::max();
}
}
object * nat_big_add(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1))
return mk_nat_obj_core(unbox(a1) + mpz_value(a2));
else if (is_scalar(a2))
return mk_nat_obj_core(mpz_value(a1) + unbox(a2));
else
return mk_nat_obj_core(mpz_value(a1) + mpz_value(a2));
}
object * nat_big_sub(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1)) {
lean_assert(unbox(a1) < mpz_value(a2));
return box(0);
} else if (is_scalar(a2)) {
lean_assert(mpz_value(a1) > unbox(a2));
return mk_nat_obj(mpz_value(a1) - unbox(a2));
} else {
if (mpz_value(a1) < mpz_value(a2))
return box(0);
else
return mk_nat_obj(mpz_value(a1) - mpz_value(a2));
}
}
object * nat_big_mul(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1))
return mk_nat_obj_core(unbox(a1) * mpz_value(a2));
else if (is_scalar(a2))
return mk_nat_obj_core(mpz_value(a1) * unbox(a2));
else
return mk_nat_obj_core(mpz_value(a1) * mpz_value(a2));
}
object * nat_big_div(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1)) {
lean_assert(mpz_value(a2) != 0);
lean_assert(unbox(a1) / mpz_value(a2) == 0);
return box(0);
} else if (is_scalar(a2)) {
usize n2 = unbox(a2);
return n2 == 0 ? a2 : mk_nat_obj(mpz_value(a1) / mpz(n2));
} else {
lean_assert(mpz_value(a2) != 0);
return mk_nat_obj(mpz_value(a1) / mpz_value(a2));
}
}
object * nat_big_mod(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1)) {
lean_assert(mpz_value(a2) != 0);
return a1;
} else if (is_scalar(a2)) {
usize n2 = unbox(a2);
return n2 == 0 ? a2 : box((mpz_value(a1) % mpz(n2)).get_unsigned_int());
} else {
lean_assert(mpz_value(a2) != 0);
return mk_nat_obj(mpz_value(a1) % mpz_value(a2));
}
}
bool nat_big_eq(object * a1, object * a2) {
if (is_scalar(a1)) {
lean_assert(unbox(a1) != mpz_value(a2))
return false;
} else if (is_scalar(a2)) {
lean_assert(mpz_value(a1) != unbox(a2))
return false;
} else {
return mpz_value(a1) == mpz_value(a2);
}
}
bool nat_big_le(object * a1, object * a2) {
if (is_scalar(a1)) {
lean_assert(unbox(a1) < mpz_value(a2))
return true;
} else if (is_scalar(a2)) {
lean_assert(mpz_value(a1) > unbox(a2));
return false;
} else {
return mpz_value(a1) <= mpz_value(a2);
}
}
bool nat_big_lt(object * a1, object * a2) {
if (is_scalar(a1)) {
lean_assert(unbox(a1) < mpz_value(a2));
return true;
} else if (is_scalar(a2)) {
lean_assert(mpz_value(a1) > unbox(a2));
return false;
} else {
return mpz_value(a1) < mpz_value(a2);
}
}
object * nat_big_land(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1))
return mk_nat_obj(mpz(unbox(a1)) & mpz_value(a2));
else if (is_scalar(a2))
return mk_nat_obj(mpz_value(a1) & mpz(unbox(a2)));
else
return mk_nat_obj(mpz_value(a1) & mpz_value(a2));
}
object * nat_big_lor(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1))
return mk_nat_obj(mpz(unbox(a1)) | mpz_value(a2));
else if (is_scalar(a2))
return mk_nat_obj(mpz_value(a1) | mpz(unbox(a2)));
else
return mk_nat_obj(mpz_value(a1) | mpz_value(a2));
}
object * nat_big_lxor(object * a1, object * a2) {
lean_assert(!is_scalar(a1) || !is_scalar(a2));
if (is_scalar(a1))
return mk_nat_obj(mpz(unbox(a1)) ^ mpz_value(a2));
else if (is_scalar(a2))
return mk_nat_obj(mpz_value(a1) ^ mpz(unbox(a2)));
else
return mk_nat_obj(mpz_value(a1) ^ mpz_value(a2));
}
// =======================================
// Integers
object * int_big_add(object * a1, object * a2) {
if (is_scalar(a1))
return mk_int_obj(int2int(a1) + mpz_value(a2));
else if (is_scalar(a2))
return mk_int_obj(mpz_value(a1) + int2int(a2));
else
return mk_int_obj(mpz_value(a1) + mpz_value(a2));
}
object * int_big_sub(object * a1, object * a2) {
if (is_scalar(a1))
return mk_int_obj(int2int(a1) - mpz_value(a2));
else if (is_scalar(a2))
return mk_int_obj(mpz_value(a1) - int2int(a2));
else
return mk_int_obj(mpz_value(a1) - mpz_value(a2));
}
object * int_big_mul(object * a1, object * a2) {
if (is_scalar(a1))
return mk_int_obj(int2int(a1) * mpz_value(a2));
else if (is_scalar(a2))
return mk_int_obj(mpz_value(a1) * int2int(a2));
else
return mk_int_obj(mpz_value(a1) * mpz_value(a2));
}
object * int_big_div(object * a1, object * a2) {
if (is_scalar(a1))
return mk_int_obj(int2int(a1) / mpz_value(a2));
else if (is_scalar(a2))
return mk_int_obj(mpz_value(a1) / int2int(a2));
else
return mk_int_obj(mpz_value(a1) / mpz_value(a2));
}
object * int_big_mod(object * a1, object * a2) {
if (is_scalar(a1))
return mk_int_obj(mpz(int2int(a1)) % mpz_value(a2));
else if (is_scalar(a2))
return mk_int_obj(mpz_value(a1) % mpz(int2int(a2)));
else
return mk_int_obj(mpz_value(a1) % mpz_value(a2));
}
bool int_big_eq(object * a1, object * a2) {
if (is_scalar(a1)) {
lean_assert(int2int(a1) != mpz_value(a2))
return false;
} else if (is_scalar(a2)) {
lean_assert(mpz_value(a1) != int2int(a2))
return false;
} else {
return mpz_value(a1) == mpz_value(a2);
}
}
bool int_big_le(object * a1, object * a2) {
if (is_scalar(a1)) {
return int2int(a1) <= mpz_value(a2);
} else if (is_scalar(a2)) {
return mpz_value(a1) <= int2int(a2);
} else {
return mpz_value(a1) <= mpz_value(a2);
}
}
bool int_big_lt(object * a1, object * a2) {
if (is_scalar(a1)) {
return int2int(a1) < mpz_value(a2);
} else if (is_scalar(a2)) {
return mpz_value(a1) < int2int(a2);
} else {
return mpz_value(a1) < mpz_value(a2);
}
}
// =======================================
// UInt
uint8 uint8_of_big_nat(b_obj_arg a) {
mpz r;
mod2k(r, mpz_value(a), 8);
return static_cast<uint8>(r.get_unsigned_int());
}
uint16 uint16_of_big_nat(b_obj_arg a) {
mpz r;
mod2k(r, mpz_value(a), 16);
return static_cast<uint16>(r.get_unsigned_int());
}
uint32 uint32_of_big_nat(b_obj_arg a) {
mpz r;
mod2k(r, mpz_value(a), 32);
return static_cast<uint32>(r.get_unsigned_int());
}
uint64 uint64_of_big_nat(b_obj_arg a) {
mpz r;
mod2k(r, mpz_value(a), 64);
if (sizeof(void*) == 8) {
// 64 bit
return static_cast<uint64>(r.get_unsigned_long_int());
} else {
// 32 bit
mpz l;
mod2k(l, r, 32);
mpz h;
div2k(h, r, 32);
return (static_cast<uint64>(h.get_unsigned_int()) << 32) + static_cast<uint64>(l.get_unsigned_int());
}
}
usize usize_of_big_nat(b_obj_arg a) {
if (sizeof(void*) == 8)
return uint64_of_big_nat(a);
else
return uint32_of_big_nat(a);
}
usize usize_mix_hash(usize a1, usize a2) {
if (sizeof(void*) == 8)
return hash(static_cast<uint64>(a1), static_cast<uint64>(a2));
else
return hash(static_cast<uint32>(a1), static_cast<uint32>(a2));
}
// =======================================
// Strings
static inline char * w_string_cstr(object * o) { lean_assert(is_string(o)); return reinterpret_cast<char *>(o) + sizeof(string_object); }
static object * string_ensure_capacity(object * o, size_t extra) {
lean_assert(is_exclusive(o));
size_t sz = string_size(o);
size_t cap = string_capacity(o);
if (sz + extra > cap) {
object * new_o = alloc_string(sz, cap + sz + extra, string_len(o));
lean_assert(string_capacity(new_o) >= sz + extra);
memcpy(w_string_cstr(new_o), string_cstr(o), sz);
free_string_obj(o);
return new_o;
} else {
return o;
}
}
object * mk_string(char const * s) {
size_t sz = strlen(s);
size_t len = utf8_strlen(s);
size_t rsz = sz + 1;
object * r = alloc_string(rsz, rsz, len);
memcpy(w_string_cstr(r), s, sz+1);
return r;
}
object * mk_string(std::string const & s) {
size_t sz = s.size();
size_t len = utf8_strlen(s);
size_t rsz = sz + 1;
object * r = alloc_string(rsz, rsz, len);
memcpy(w_string_cstr(r), s.data(), sz);
w_string_cstr(r)[sz] = 0;
return r;
}
std::string string_to_std(b_obj_arg o) {
lean_assert(string_size(o) > 0);
return std::string(w_string_cstr(o), string_size(o) - 1);
}
static size_t mk_capacity(size_t sz) {
return sz*2;
}
object * string_push(object * s, unsigned c) {
size_t sz = string_size(s);
size_t len = string_len(s);
object * r;
if (!is_exclusive(s)) {
r = alloc_string(sz, mk_capacity(sz+5), len);
memcpy(w_string_cstr(r), string_cstr(s), sz - 1);
dec_ref(s);
} else {
r = string_ensure_capacity(s, 5);
}
unsigned consumed = push_unicode_scalar(w_string_cstr(r) + sz - 1, c);
to_string(r)->m_size = sz + consumed;
to_string(r)->m_length++;
w_string_cstr(r)[sz + consumed - 1] = 0;
return r;
}
object * string_append(object * s1, object * s2) {
size_t sz1 = string_size(s1);
size_t sz2 = string_size(s2);
size_t len1 = string_len(s1);
size_t len2 = string_len(s2);
size_t new_len = len1 + len2;
unsigned new_sz = sz1 + sz2 - 1;
object * r;
if (!is_exclusive(s1)) {
r = alloc_string(new_sz, mk_capacity(new_sz), new_len);
memcpy(w_string_cstr(r), string_cstr(s1), sz1 - 1);
dec_ref(s1);
} else {
lean_assert(s1 != s2);
r = string_ensure_capacity(s1, sz2-1);
}
memcpy(w_string_cstr(r) + sz1 - 1, string_cstr(s2), sz2 - 1);
to_string(r)->m_size = new_sz;
to_string(r)->m_length = new_len;
w_string_cstr(r)[new_sz - 1] = 0;
return r;
}
bool string_eq(object * s1, char const * s2) {
if (string_size(s1) != strlen(s2) + 1)
return false;
return std::memcmp(string_cstr(s1), s2, string_size(s1)) == 0;
}
bool string_lt(object * s1, object * s2) {
size_t sz1 = string_size(s1) - 1; // ignore null char in the end
size_t sz2 = string_size(s2) - 1; // ignore null char in the end
int r = std::memcmp(string_cstr(s1), string_cstr(s2), std::min(sz1, sz2));
return r < 0 || (r == 0 && sz1 < sz2);
}
static std::string list_as_string(b_obj_arg lst) {
std::string s;
b_obj_arg o = lst;
while (!is_scalar(o)) {
push_unicode_scalar(s, unbox(cnstr_get(o, 0)));
o = cnstr_get(o, 1);
}
return s;
}
static obj_res string_to_list_core(std::string const & s, bool reverse = false) {
buffer<unsigned> tmp;
utf8_decode(s, tmp);
if (reverse)
std::reverse(tmp.begin(), tmp.end());
obj_res r = box(0);
unsigned i = tmp.size();
while (i > 0) {
--i;
obj_res new_r = alloc_cnstr(1, 2, 0);
cnstr_set(new_r, 0, box(tmp[i]));
cnstr_set(new_r, 1, r);
r = new_r;
}
return r;
}
obj_res string_mk(obj_arg cs) {
std::string s = list_as_string(cs);
dec(cs);
return mk_string(s);
}
obj_res string_data(obj_arg s) {
std::string tmp = string_to_std(s);
dec_ref(s);
return string_to_list_core(tmp);
}
uint32 string_utf8_get(b_obj_arg s, b_obj_arg i0) {
if (!is_scalar(i0)) {
/* If `i0` is not a scalar, then it must be > LEAN_MAX_SMALL_NAT,
and should not be a valid index.
Recall that LEAN_MAX_SMALL_NAT is 2^31-1 in 32-bit machines and
2^63 - 1 in 64-bit ones.
`i0` would only be a valid index if `s` had more than `LEAN_MAX_SMALL_NAT`
bytes which is unlikely.
For example, Linux for 64-bit machines can address at most 256 Tb which
is less than 2^63 - 1.
*/
return char_default_value();
}
usize i = unbox(i0);
char const * str = string_cstr(s);
usize size = string_size(s) - 1;
if (i >= string_size(s) - 1)
return char_default_value();
unsigned c = static_cast<unsigned char>(str[i]);
/* zero continuation (0 to 127) */
if ((c & 0x80) == 0) {
i++;
return c;
}
/* one continuation (128 to 2047) */
if ((c & 0xe0) == 0xc0 && i + 1 < size) {
unsigned c1 = static_cast<unsigned char>(str[i+1]);
unsigned r = ((c & 0x1f) << 6) | (c1 & 0x3f);
if (r >= 128) {
i += 2;
return r;
}
}
/* two continuations (2048 to 55295 and 57344 to 65535) */
if ((c & 0xf0) == 0xe0 && i + 2 < size) {
unsigned c1 = static_cast<unsigned char>(str[i+1]);
unsigned c2 = static_cast<unsigned char>(str[i+2]);
unsigned r = ((c & 0x0f) << 12) | ((c1 & 0x3f) << 6) | (c2 & 0x3f);
if (r >= 2048 && (r < 55296 || r > 57343)) {
i += 3;
return r;
}
}
/* three continuations (65536 to 1114111) */
if ((c & 0xf8) == 0xf0 && i + 3 < size) {
unsigned c1 = static_cast<unsigned char>(str[i+1]);
unsigned c2 = static_cast<unsigned char>(str[i+2]);
unsigned c3 = static_cast<unsigned char>(str[i+3]);
unsigned r = ((c & 0x07) << 18) | ((c1 & 0x3f) << 12) | ((c2 & 0x3f) << 6) | (c3 & 0x3f);
if (r >= 65536 && r <= 1114111) {
i += 4;
return r;
}
}
/* invalid UTF-8 encoded string */
return char_default_value();
}
/* The reference implementation is:
```
def next (s : @& String) (p : @& Pos) : Ppos :=
let c := get s p in
p + csize c
```
*/
obj_res string_utf8_next(b_obj_arg s, b_obj_arg i0) {
if (!is_scalar(i0)) {
/* See comment at string_utf8_get */
return nat_add(i0, box(1));
}
usize i = unbox(i0);
char const * str = string_cstr(s);
usize size = string_size(s) - 1;
/* `csize c` is 1 when `i` is not a valid position in the reference implementation. */
if (i >= size) return box(i+1);
unsigned c = static_cast<unsigned char>(str[i]);
if ((c & 0x80) == 0) return box(i+1);
if ((c & 0xe0) == 0xc0) return box(i+2);
if ((c & 0xf0) == 0xe0) return box(i+3);
if ((c & 0xf8) == 0xf0) return box(i+4);
/* invalid UTF-8 encoded string */
return box(i+1);
}
static inline bool is_utf8_first_byte(unsigned char c) {
return (c & 0x80) == 0 || (c & 0xe0) == 0xc0 || (c & 0xf0) == 0xe0 || (c & 0xf8) == 0xf0;
}
obj_res string_utf8_extract(b_obj_arg s, b_obj_arg b0, b_obj_arg e0) {
if (!is_scalar(b0) || !is_scalar(e0)) {
/* See comment at string_utf8_get */
return s;
}
usize b = unbox(b0);
usize e = unbox(e0);
char const * str = string_cstr(s);
usize sz = string_size(s) - 1;
if (b >= e || b >= sz) return mk_string("");
/* In the reference implementation if `b` is not pointing to a valid UTF8
character start position, the result is the empty string. */
if (!is_utf8_first_byte(str[b])) return mk_string("");
if (e > sz) e = sz;
lean_assert(b < e);
lean_assert(e > 0);
/* In the reference implementation if `e` is not pointing to a valid UTF8
character start position, it is assumed to be at the end. */
if (e < sz && !is_utf8_first_byte(str[e])) e = sz;
usize new_sz = e - b;
lean_assert(new_sz > 0);
obj_res r = alloc_string(new_sz+1, new_sz+1, 0);
memcpy(w_string_cstr(r), string_cstr(s) + b, new_sz);
w_string_cstr(r)[new_sz] = 0;
to_string(r)->m_length = utf8_strlen(w_string_cstr(r), new_sz);
return r;
}
obj_res string_utf8_prev(b_obj_arg s, b_obj_arg i0) {
if (!is_scalar(i0)) {
/* See comment at string_utf8_get */
return nat_sub(i0, box(1));
}
usize i = unbox(i0);
usize sz = string_size(s) - 1;
if (i == 0 || i > sz) return box(0);
i--;
char const * str = string_cstr(s);
while (!is_utf8_first_byte(str[i])) {
lean_assert(i > 0);
i--;
}
return box(i);
}
static unsigned get_utf8_char_size_at(std::string const & s, usize i) {
if (auto sz = get_utf8_first_byte_opt(s[i])) {
return *sz;
} else {
return 1;
}
}
obj_res string_utf8_set(obj_arg s, b_obj_arg i0, uint32 c) {
if (!is_scalar(i0)) {
/* See comment at string_utf8_get */
return s;
}
usize i = unbox(i0);
usize sz = string_size(s) - 1;
if (i >= sz) return s;
char * str = w_string_cstr(s);
if (is_exclusive(s)) {
if (static_cast<unsigned char>(str[i]) < 128 && c < 128) {
str[i] = c;
return s;
}
}
if (!is_utf8_first_byte(str[i])) return s;
/* TODO(Leo): improve performance of other special cases.
Example: is_exclusive(s) and new and old characters have the same size; etc. */
std::string tmp;
push_unicode_scalar(tmp, c);
std::string new_s = string_to_std(s);
new_s.replace(i, get_utf8_char_size_at(new_s, i), tmp);
return mk_string(new_s);
}
usize string_hash(b_obj_arg s) {
usize sz = string_size(s) - 1;
char const * str = string_cstr(s);
return hash_str(sz, str, 11);
}
// =======================================
// array functions for generated code
object * mk_array(obj_arg n, obj_arg v) {
size_t sz;
if (is_scalar(n)) {
sz = unbox(n);
} else {
mpz const & v = mpz_value(n);
if (!v.is_unsigned_long_int()) throw std::bad_alloc(); // we will run out of memory
sz = v.get_unsigned_long_int();
dec(n);
}
object * r = alloc_array(sz, sz);
object ** it = array_cptr(r);
object ** end = it + sz;
for (; it != end; ++it) {
*it = v;
}
if (sz > 1) inc(v, sz - 1);
return r;
}
obj_res copy_array(obj_arg a, bool expand) {
size_t sz = array_size(a);
size_t cap = array_capacity(a);
lean_assert(cap >= sz);
if (expand) cap = (cap + 1) * 2;
lean_assert(!expand || cap > sz);
object * r = alloc_array(sz, cap);
object ** it = array_cptr(a);
object ** end = it + sz;
object ** dest = array_cptr(r);
for (; it != end; ++it, ++dest) {
*dest = *it;
inc(*it);
}
dec(a);
return r;
}
object * array_push(obj_arg a, obj_arg v) {
object * r;
if (is_exclusive(a)) {
if (array_capacity(a) > array_size(a))
r = a;
else
r = copy_array(a, true);
} else {
r = copy_array(a, array_capacity(a) < 2*array_size(a) + 1);
}
lean_assert(array_capacity(r) > array_size(r));
size_t & sz = to_array(r)->m_size;
object ** it = array_cptr(r) + sz;
*it = v;
sz++;
return r;
}
// =======================================
// fixpoint
static inline object * ptr_to_weak_ptr(object * p) {
return reinterpret_cast<object*>(reinterpret_cast<uintptr_t>(p) | 1);
}
static inline object * weak_ptr_to_ptr(object * w) {
return reinterpret_cast<object*>((reinterpret_cast<uintptr_t>(w) >> 1) << 1);
}
obj_res fixpoint_aux(obj_arg rec, obj_arg weak_k, obj_arg a) {
object * k = weak_ptr_to_ptr(weak_k);
inc(k);
return apply_2(rec, k, a);
}
obj_res fixpoint(obj_arg rec, obj_arg a) {
object * k = alloc_closure(fixpoint_aux, 2);
inc(rec);
closure_set(k, 0, rec);
closure_set(k, 1, ptr_to_weak_ptr(k));
object * r = apply_2(rec, k, a);
return r;
}
obj_res fixpoint_aux2(obj_arg rec, obj_arg weak_k, obj_arg a1, obj_arg a2) {
object * k = weak_ptr_to_ptr(weak_k);
inc(k);
return apply_3(rec, k, a1, a2);
}
obj_res fixpoint2(obj_arg rec, obj_arg a1, obj_arg a2) {
object * k = alloc_closure(fixpoint_aux2, 2);
inc(rec);
closure_set(k, 0, rec);
closure_set(k, 1, ptr_to_weak_ptr(k));
object * r = apply_3(rec, k, a1, a2);
return r;
}
obj_res fixpoint_aux3(obj_arg rec, obj_arg weak_k, obj_arg a1, obj_arg a2, obj_arg a3) {
object * k = weak_ptr_to_ptr(weak_k);
inc(k);
return apply_4(rec, k, a1, a2, a3);
}
obj_res fixpoint3(obj_arg rec, obj_arg a1, obj_arg a2, obj_arg a3) {
object * k = alloc_closure(fixpoint_aux3, 2);
inc(rec);
closure_set(k, 0, rec);
closure_set(k, 1, ptr_to_weak_ptr(k));
object * r = apply_4(rec, k, a1, a2, a3);
return r;
}
obj_res fixpoint_aux4(obj_arg rec, obj_arg weak_k, obj_arg a1, obj_arg a2, obj_arg a3, obj_arg a4) {
object * k = weak_ptr_to_ptr(weak_k);
inc(k);
return apply_5(rec, k, a1, a2, a3, a4);
}
obj_res fixpoint4(obj_arg rec, obj_arg a1, obj_arg a2, obj_arg a3, obj_arg a4) {
object * k = alloc_closure(fixpoint_aux4, 2);
inc(rec);
closure_set(k, 0, rec);
closure_set(k, 1, ptr_to_weak_ptr(k));
object * r = apply_5(rec, k, a1, a2, a3, a4);
return r;
}
obj_res fixpoint_aux5(obj_arg rec, obj_arg weak_k, obj_arg a1, obj_arg a2, obj_arg a3, obj_arg a4, obj_arg a5) {
object * k = weak_ptr_to_ptr(weak_k);
inc(k);
return apply_6(rec, k, a1, a2, a3, a4, a5);
}
obj_res fixpoint5(obj_arg rec, obj_arg a1, obj_arg a2, obj_arg a3, obj_arg a4, obj_arg a5) {
object * k = alloc_closure(fixpoint_aux5, 2);
inc(rec);
closure_set(k, 0, rec);
closure_set(k, 1, ptr_to_weak_ptr(k));
object * r = apply_6(rec, k, a1, a2, a3, a4, a5);
return r;
}
obj_res fixpoint_aux6(obj_arg rec, obj_arg weak_k, obj_arg a1, obj_arg a2, obj_arg a3, obj_arg a4, obj_arg a5, obj_arg a6) {
object * k = weak_ptr_to_ptr(weak_k);
inc(k);
return apply_7(rec, k, a1, a2, a3, a4, a5, a6);
}
obj_res fixpoint6(obj_arg rec, obj_arg a1, obj_arg a2, obj_arg a3, obj_arg a4, obj_arg a5, obj_arg a6) {
object * k = alloc_closure(fixpoint_aux6, 2);
inc(rec);
closure_set(k, 0, rec);
closure_set(k, 1, ptr_to_weak_ptr(k));
object * r = apply_7(rec, k, a1, a2, a3, a4, a5, a6);
return r;
}
// =======================================
// Debugging helper functions
void dbg_print_str(object * o) {
lean_assert(is_string(o));
std::cout << string_cstr(o) << "\n";
}
void dbg_print_num(object * o) {
if (is_scalar(o)) {
std::cout << unbox(o) << "\n";
} else {
std::cout << mpz_value(o) << "\n";
}
}
static mutex g_dbg_mutex;
object * dbg_trace(obj_arg s, obj_arg fn) {
{
unique_lock<mutex> lock(g_dbg_mutex);
std::cout << string_cstr(s) << std::endl;
}
dec(s);
return apply_1(fn, box(0));
}
object * dbg_sleep(uint32 ms, obj_arg fn) {
chrono::milliseconds c(ms);
this_thread::sleep_for(c);
return apply_1(fn, box(0));
}
// =======================================
// Statistics
#ifdef LEAN_RUNTIME_STATS
atomic<uint64> g_num_ctor(0);
atomic<uint64> g_num_closure(0);
atomic<uint64> g_num_string(0);
atomic<uint64> g_num_array(0);
atomic<uint64> g_num_thunk(0);
atomic<uint64> g_num_task(0);
atomic<uint64> g_num_ext(0);
atomic<uint64> g_num_st_inc(0);
atomic<uint64> g_num_mt_inc(0);
atomic<uint64> g_num_st_dec(0);
atomic<uint64> g_num_mt_dec(0);
atomic<uint64> g_num_del(0);
struct runtime_stats {
~runtime_stats() {
std::cerr << "num. constructors: " << g_num_ctor << "\n";
std::cerr << "num. closures: " << g_num_closure << "\n";
std::cerr << "num. strings: " << g_num_string << "\n";
std::cerr << "num. array: " << g_num_array << "\n";
std::cerr << "num. thunk: " << g_num_thunk << "\n";
std::cerr << "num. task: " << g_num_task << "\n";
std::cerr << "num. external: " << g_num_ext << "\n";
std::cerr << "num. ST inc: " << g_num_st_inc << "\n";
std::cerr << "num. MT inc: " << g_num_mt_inc << "\n";
std::cerr << "num. ST dec: " << g_num_st_dec << "\n";
std::cerr << "num. MT dec: " << g_num_mt_dec << "\n";
std::cerr << "num. del: " << g_num_del << "\n";
}
};
runtime_stats g_runtime_stats;
#endif
}
extern "C" void lean_dbg_print_str(lean::object* o) { lean::dbg_print_str(o); }
extern "C" void lean_dbg_print_num(lean::object* o) { lean::dbg_print_num(o); }
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