# Copyright: Ankitects Pty Ltd and contributors # License: GNU AGPL, version 3 or later; http://www.gnu.org/licenses/agpl.html import copy import os import time from typing import Tuple import pytest from anki import hooks from anki.consts import * from anki.lang import without_unicode_isolation from anki.scheduler import UnburyDeck from anki.utils import intTime from tests.shared import getEmptyCol as getEmptyColOrig # This file is used to exercise both the legacy Python 2.1 scheduler, # and the experimental new one in Rust. Most tests run on both, but a few # tests have been implemented separately where the behaviour differs. def is_2021() -> bool: return "2021" in os.getenv("PYTEST_CURRENT_TEST") def getEmptyCol(): col = getEmptyColOrig() col.upgrade_to_v2_scheduler() if is_2021(): col.set_v3_scheduler(True) return col def test_clock(): col = getEmptyCol() if (col.sched.dayCutoff - intTime()) < 10 * 60: raise Exception("Unit tests will fail around the day rollover.") def checkRevIvl(col, c, targetIvl): min, max = col.sched._fuzzIvlRange(targetIvl) assert min <= c.ivl <= max def test_basics(): col = getEmptyCol() col.reset() assert not col.sched.getCard() def test_new(): col = getEmptyCol() col.reset() assert col.sched.newCount == 0 # add a note note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) col.reset() assert col.sched.newCount == 1 # fetch it c = col.sched.getCard() assert c assert c.queue == QUEUE_TYPE_NEW assert c.type == CARD_TYPE_NEW # if we answer it, it should become a learn card t = intTime() col.sched.answerCard(c, 1) assert c.queue == QUEUE_TYPE_LRN assert c.type == CARD_TYPE_LRN assert c.due >= t # disabled for now, as the learn fudging makes this randomly fail # # the default order should ensure siblings are not seen together, and # # should show all cards # m = col.models.current(); mm = col.models # t = mm.new_template("Reverse") # t['qfmt'] = "{{Back}}" # t['afmt'] = "{{Front}}" # mm.add_template(m, t) # mm.save(m) # note = col.newNote() # note['Front'] = u"2"; note['Back'] = u"2" # col.addNote(note) # note = col.newNote() # note['Front'] = u"3"; note['Back'] = u"3" # col.addNote(note) # col.reset() # qs = ("2", "3", "2", "3") # for n in range(4): # c = col.sched.getCard() # assert qs[n] in c.question() # col.sched.answerCard(c, 2) def test_newLimits(): col = getEmptyCol() # add some notes deck2 = col.decks.id("Default::foo") for i in range(30): note = col.newNote() note["Front"] = str(i) if i > 4: note.note_type()["did"] = deck2 col.addNote(note) # give the child deck a different configuration c2 = col.decks.add_config_returning_id("new conf") col.decks.set_config_id_for_deck_dict(col.decks.get(deck2), c2) col.reset() # both confs have defaulted to a limit of 20 assert col.sched.newCount == 20 # first card we get comes from parent c = col.sched.getCard() assert c.did == 1 # limit the parent to 10 cards, meaning we get 10 in total conf1 = col.decks.config_dict_for_deck_id(1) conf1["new"]["perDay"] = 10 col.decks.save(conf1) col.reset() assert col.sched.newCount == 10 # if we limit child to 4, we should get 9 conf2 = col.decks.config_dict_for_deck_id(deck2) conf2["new"]["perDay"] = 4 col.decks.save(conf2) col.reset() assert col.sched.newCount == 9 def test_newBoxes(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) col.reset() c = col.sched.getCard() conf = col.sched._cardConf(c) conf["new"]["delays"] = [1, 2, 3, 4, 5] col.decks.save(conf) col.sched.answerCard(c, 2) # should handle gracefully conf["new"]["delays"] = [1] col.decks.save(conf) col.sched.answerCard(c, 2) def test_learn(): col = getEmptyCol() # add a note note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) # set as a new card and rebuild queues col.db.execute(f"update cards set queue={QUEUE_TYPE_NEW}, type={CARD_TYPE_NEW}") col.reset() # sched.getCard should return it, since it's due in the past c = col.sched.getCard() assert c conf = col.sched._cardConf(c) conf["new"]["delays"] = [0.5, 3, 10] col.decks.save(conf) # fail it col.sched.answerCard(c, 1) # it should have three reps left to graduation assert c.left % 1000 == 3 # it should be due in 30 seconds t = round(c.due - time.time()) assert t >= 25 and t <= 40 # pass it once col.sched.answerCard(c, 3) # it should be due in 3 minutes dueIn = c.due - time.time() assert 178 <= dueIn <= 180 * 1.25 assert c.left % 1000 == 2 # check log is accurate log = col.db.first("select * from revlog order by id desc") assert log[3] == 3 assert log[4] == -180 assert log[5] == -30 # pass again col.sched.answerCard(c, 3) # it should be due in 10 minutes dueIn = c.due - time.time() assert 599 <= dueIn <= 600 * 1.25 assert c.left % 1000 == 1 # the next pass should graduate the card assert c.queue == QUEUE_TYPE_LRN assert c.type == CARD_TYPE_LRN col.sched.answerCard(c, 3) assert c.queue == QUEUE_TYPE_REV assert c.type == CARD_TYPE_REV # should be due tomorrow, with an interval of 1 assert c.due == col.sched.today + 1 assert c.ivl == 1 # or normal removal c.type = CARD_TYPE_NEW c.queue = QUEUE_TYPE_LRN c.flush() col.sched.reset() col.sched.answerCard(c, 4) assert c.type == CARD_TYPE_REV assert c.queue == QUEUE_TYPE_REV checkRevIvl(col, c, 4) # revlog should have been updated each time assert col.db.scalar("select count() from revlog where type = 0") == 5 def test_relearn(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] c.ivl = 100 c.due = col.sched.today c.queue = CARD_TYPE_REV c.type = QUEUE_TYPE_REV c.flush() # fail the card col.reset() c = col.sched.getCard() col.sched.answerCard(c, 1) assert c.queue == QUEUE_TYPE_LRN assert c.type == CARD_TYPE_RELEARNING assert c.ivl == 1 # immediately graduate it col.sched.answerCard(c, 4) assert c.queue == CARD_TYPE_REV and c.type == QUEUE_TYPE_REV assert c.ivl == 2 assert c.due == col.sched.today + c.ivl def test_relearn_no_steps(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] c.ivl = 100 c.due = col.sched.today c.queue = CARD_TYPE_REV c.type = QUEUE_TYPE_REV c.flush() conf = col.decks.config_dict_for_deck_id(1) conf["lapse"]["delays"] = [] col.decks.save(conf) # fail the card col.reset() c = col.sched.getCard() col.sched.answerCard(c, 1) assert c.queue == CARD_TYPE_REV and c.type == QUEUE_TYPE_REV def test_learn_collapsed(): col = getEmptyCol() # add 2 notes note = col.newNote() note["Front"] = "1" col.addNote(note) note = col.newNote() note["Front"] = "2" col.addNote(note) # set as a new card and rebuild queues col.db.execute(f"update cards set queue={QUEUE_TYPE_NEW}, type={CARD_TYPE_NEW}") col.reset() # should get '1' first c = col.sched.getCard() assert c.question().endswith("1") # pass it so it's due in 10 minutes col.sched.answerCard(c, 3) # get the other card c = col.sched.getCard() assert c.question().endswith("2") # fail it so it's due in 1 minute col.sched.answerCard(c, 1) # we shouldn't get the same card again c = col.sched.getCard() assert not c.question().endswith("2") def test_learn_day(): col = getEmptyCol() # add a note note = col.newNote() note["Front"] = "one" col.addNote(note) note = col.newNote() note["Front"] = "two" col.addNote(note) col.sched.reset() c = col.sched.getCard() conf = col.sched._cardConf(c) conf["new"]["delays"] = [1, 10, 1440, 2880] col.decks.save(conf) # pass it col.sched.answerCard(c, 3) # two reps to graduate, 1 more today assert c.left % 1000 == 3 assert col.sched.counts() == (1, 1, 0) c.load() ni = col.sched.nextIvl assert ni(c, 3) == 86400 # answer the other dummy card col.sched.answerCard(col.sched.getCard(), 4) # answering the first one will place it in queue 3 c = col.sched.getCard() col.sched.answerCard(c, 3) assert c.due == col.sched.today + 1 assert c.queue == QUEUE_TYPE_DAY_LEARN_RELEARN assert not col.sched.getCard() # for testing, move it back a day c.due -= 1 c.flush() col.reset() if is_2021(): # it appears in the review queue assert col.sched.counts() == (0, 0, 1) else: assert col.sched.counts() == (0, 1, 0) c = col.sched.getCard() # nextIvl should work assert ni(c, 3) == 86400 * 2 # if we fail it, it should be back in the correct queue col.sched.answerCard(c, 1) assert c.queue == QUEUE_TYPE_LRN if is_2021(): col.undo() else: col.undo_legacy() col.reset() c = col.sched.getCard() col.sched.answerCard(c, 3) # simulate the passing of another two days c.due -= 2 c.flush() col.reset() # the last pass should graduate it into a review card assert ni(c, 3) == 86400 col.sched.answerCard(c, 3) assert c.queue == CARD_TYPE_REV and c.type == QUEUE_TYPE_REV # if the lapse step is tomorrow, failing it should handle the counts # correctly c.due = 0 c.flush() col.reset() assert col.sched.counts() == (0, 0, 1) conf = col.sched._cardConf(c) conf["lapse"]["delays"] = [1440] col.decks.save(conf) c = col.sched.getCard() col.sched.answerCard(c, 1) assert c.queue == QUEUE_TYPE_DAY_LEARN_RELEARN assert col.sched.counts() == (0, 0, 0) def test_reviews(): col = getEmptyCol() # add a note note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) # set the card up as a review card, due 8 days ago c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.due = col.sched.today - 8 c.factor = STARTING_FACTOR c.reps = 3 c.lapses = 1 c.ivl = 100 c.start_timer() c.flush() # save it for later use as well cardcopy = copy.copy(c) # try with an ease of 2 ################################################## c = copy.copy(cardcopy) c.flush() col.reset() col.sched.answerCard(c, 2) assert c.queue == QUEUE_TYPE_REV # the new interval should be (100) * 1.2 = 120 checkRevIvl(col, c, 120) assert c.due == col.sched.today + c.ivl # factor should have been decremented assert c.factor == 2350 # check counters assert c.lapses == 1 assert c.reps == 4 # ease 3 ################################################## c = copy.copy(cardcopy) c.flush() col.sched.answerCard(c, 3) # the new interval should be (100 + 8/2) * 2.5 = 260 checkRevIvl(col, c, 260) assert c.due == col.sched.today + c.ivl # factor should have been left alone assert c.factor == STARTING_FACTOR # ease 4 ################################################## c = copy.copy(cardcopy) c.flush() col.sched.answerCard(c, 4) # the new interval should be (100 + 8) * 2.5 * 1.3 = 351 checkRevIvl(col, c, 351) assert c.due == col.sched.today + c.ivl # factor should have been increased assert c.factor == 2650 # leech handling ################################################## conf = col.decks.get_config(1) conf["lapse"]["leechAction"] = LEECH_SUSPEND col.decks.save(conf) c = copy.copy(cardcopy) c.lapses = 7 c.flush() # setup hook hooked = [] def onLeech(card): hooked.append(1) hooks.card_did_leech.append(onLeech) col.sched.answerCard(c, 1) if not is_2021(): assert hooked assert c.queue == QUEUE_TYPE_SUSPENDED c.load() assert c.queue == QUEUE_TYPE_SUSPENDED assert "leech" in c.note().tags def review_limits_setup() -> Tuple[anki.collection.Collection, Dict]: col = getEmptyCol() parent = col.decks.get(col.decks.id("parent")) child = col.decks.get(col.decks.id("parent::child")) pconf = col.decks.get_config(col.decks.add_config_returning_id("parentConf")) cconf = col.decks.get_config(col.decks.add_config_returning_id("childConf")) pconf["rev"]["perDay"] = 5 col.decks.update_config(pconf) col.decks.set_config_id_for_deck_dict(parent, pconf["id"]) cconf["rev"]["perDay"] = 10 col.decks.update_config(cconf) col.decks.set_config_id_for_deck_dict(child, cconf["id"]) m = col.models.current() m["did"] = child["id"] col.models.save(m, updateReqs=False) # add some cards for i in range(20): note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) # make them reviews c = note.cards()[0] c.queue = CARD_TYPE_REV c.type = QUEUE_TYPE_REV c.due = 0 c.flush() return col, child def test_review_limits(): col, child = review_limits_setup() tree = col.sched.deck_due_tree().children # (('parent', 1514457677462, 5, 0, 0, (('child', 1514457677463, 5, 0, 0, ()),))) assert tree[0].review_count == 5 # parent assert tree[0].children[0].review_count == 10 # child # .counts() should match col.decks.select(child["id"]) col.sched.reset() assert col.sched.counts() == (0, 0, 10) # answering a card in the child should decrement parent count c = col.sched.getCard() col.sched.answerCard(c, 3) assert col.sched.counts() == (0, 0, 9) tree = col.sched.deck_due_tree().children assert tree[0].review_count == 4 # parent assert tree[0].children[0].review_count == 9 # child def test_button_spacing(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) # 1 day ivl review card due now c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.due = col.sched.today c.reps = 1 c.ivl = 1 c.start_timer() c.flush() col.reset() ni = col.sched.nextIvlStr wo = without_unicode_isolation assert wo(ni(c, 2)) == "2d" assert wo(ni(c, 3)) == "3d" assert wo(ni(c, 4)) == "4d" # if hard factor is <= 1, then hard may not increase conf = col.decks.config_dict_for_deck_id(1) conf["rev"]["hardFactor"] = 1 col.decks.save(conf) assert wo(ni(c, 2)) == "1d" def test_overdue_lapse(): # disabled in commit 3069729776990980f34c25be66410e947e9d51a2 return col = getEmptyCol() # pylint: disable=unreachable # add a note note = col.newNote() note["Front"] = "one" col.addNote(note) # simulate a review that was lapsed and is now due for its normal review c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_LRN c.due = -1 c.odue = -1 c.factor = STARTING_FACTOR c.left = 2002 c.ivl = 0 c.flush() # checkpoint col.save() col.sched.reset() assert col.sched.counts() == (0, 2, 0) c = col.sched.getCard() col.sched.answerCard(c, 3) # it should be due tomorrow assert c.due == col.sched.today + 1 # revert to before col.rollback() # with the default settings, the overdue card should be removed from the # learning queue col.sched.reset() assert col.sched.counts() == (0, 0, 1) def test_nextIvl(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) col.reset() conf = col.decks.config_dict_for_deck_id(1) conf["new"]["delays"] = [0.5, 3, 10] conf["lapse"]["delays"] = [1, 5, 9] col.decks.save(conf) c = col.sched.getCard() # new cards ################################################## ni = col.sched.nextIvl assert ni(c, 1) == 30 assert ni(c, 2) == (30 + 180) // 2 assert ni(c, 3) == 180 assert ni(c, 4) == 4 * 86400 col.sched.answerCard(c, 1) # cards in learning ################################################## assert ni(c, 1) == 30 assert ni(c, 2) == (30 + 180) // 2 assert ni(c, 3) == 180 assert ni(c, 4) == 4 * 86400 col.sched.answerCard(c, 3) assert ni(c, 1) == 30 assert ni(c, 2) == (180 + 600) // 2 assert ni(c, 3) == 600 assert ni(c, 4) == 4 * 86400 col.sched.answerCard(c, 3) # normal graduation is tomorrow assert ni(c, 3) == 1 * 86400 assert ni(c, 4) == 4 * 86400 # lapsed cards ################################################## c.type = CARD_TYPE_RELEARNING c.ivl = 100 c.factor = STARTING_FACTOR c.flush() assert ni(c, 1) == 60 assert ni(c, 3) == 100 * 86400 assert ni(c, 4) == 101 * 86400 # review cards ################################################## c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.ivl = 100 c.factor = STARTING_FACTOR c.flush() # failing it should put it at 60s assert ni(c, 1) == 60 # or 1 day if relearn is false conf["lapse"]["delays"] = [] col.decks.save(conf) assert ni(c, 1) == 1 * 86400 # (* 100 1.2 86400)10368000.0 assert ni(c, 2) == 10368000 # (* 100 2.5 86400)21600000.0 assert ni(c, 3) == 21600000 # (* 100 2.5 1.3 86400)28080000.0 assert ni(c, 4) == 28080000 assert without_unicode_isolation(col.sched.nextIvlStr(c, 4)) == "10.8mo" def test_bury(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] note = col.newNote() note["Front"] = "two" col.addNote(note) c2 = note.cards()[0] # burying col.sched.bury_cards([c.id], manual=True) # pylint: disable=unexpected-keyword-arg c.load() assert c.queue == QUEUE_TYPE_MANUALLY_BURIED col.sched.bury_cards( [c2.id], manual=False ) # pylint: disable=unexpected-keyword-arg c2.load() assert c2.queue == QUEUE_TYPE_SIBLING_BURIED col.reset() assert not col.sched.getCard() col.sched.unbury_deck(deck_id=col.decks.get_current_id(), mode=UnburyDeck.USER_ONLY) c.load() assert c.queue == QUEUE_TYPE_NEW c2.load() assert c2.queue == QUEUE_TYPE_SIBLING_BURIED col.sched.unbury_deck( deck_id=col.decks.get_current_id(), mode=UnburyDeck.SCHED_ONLY ) c2.load() assert c2.queue == QUEUE_TYPE_NEW col.sched.bury_cards([c.id, c2.id]) col.sched.unbury_deck(deck_id=col.decks.get_current_id()) col.reset() assert col.sched.counts() == (2, 0, 0) def test_suspend(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] # suspending col.reset() assert col.sched.getCard() col.sched.suspend_cards([c.id]) col.reset() assert not col.sched.getCard() # unsuspending col.sched.unsuspend_cards([c.id]) col.reset() assert col.sched.getCard() # should cope with rev cards being relearnt c.due = 0 c.ivl = 100 c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.flush() col.reset() c = col.sched.getCard() col.sched.answerCard(c, 1) assert c.due >= time.time() due = c.due assert c.queue == QUEUE_TYPE_LRN assert c.type == CARD_TYPE_RELEARNING col.sched.suspend_cards([c.id]) col.sched.unsuspend_cards([c.id]) c.load() assert c.queue == QUEUE_TYPE_LRN assert c.type == CARD_TYPE_RELEARNING assert c.due == due # should cope with cards in cram decks c.due = 1 c.flush() did = col.decks.new_filtered("tmp") col.sched.rebuild_filtered_deck(did) c.load() assert c.due != 1 assert c.did != 1 col.sched.suspend_cards([c.id]) c.load() assert c.due != 1 assert c.did != 1 assert c.odue == 1 def test_filt_reviewing_early_normal(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] c.ivl = 100 c.queue = CARD_TYPE_REV c.type = QUEUE_TYPE_REV # due in 25 days, so it's been waiting 75 days c.due = col.sched.today + 25 c.mod = 1 c.factor = STARTING_FACTOR c.start_timer() c.flush() col.reset() assert col.sched.counts() == (0, 0, 0) # create a dynamic deck and refresh it did = col.decks.new_filtered("Cram") col.sched.rebuild_filtered_deck(did) col.reset() # should appear as normal in the deck list assert sorted(col.sched.deck_due_tree().children)[0].review_count == 1 # and should appear in the counts assert col.sched.counts() == (0, 0, 1) # grab it and check estimates c = col.sched.getCard() assert col.sched.answerButtons(c) == 4 assert col.sched.nextIvl(c, 1) == 600 assert col.sched.nextIvl(c, 2) == int(75 * 1.2) * 86400 assert col.sched.nextIvl(c, 3) == int(75 * 2.5) * 86400 assert col.sched.nextIvl(c, 4) == int(75 * 2.5 * 1.15) * 86400 # answer 'good' col.sched.answerCard(c, 3) checkRevIvl(col, c, int(75 * 2.5)) assert c.due == col.sched.today + c.ivl assert not c.odue # should not be in learning assert c.queue == QUEUE_TYPE_REV # should be logged as a cram rep assert col.db.scalar("select type from revlog order by id desc limit 1") == 3 # due in 75 days, so it's been waiting 25 days c.ivl = 100 c.due = col.sched.today + 75 c.flush() col.sched.rebuild_filtered_deck(did) col.reset() c = col.sched.getCard() assert col.sched.nextIvl(c, 2) == 60 * 86400 assert col.sched.nextIvl(c, 3) == 100 * 86400 assert col.sched.nextIvl(c, 4) == 114 * 86400 def test_filt_keep_lrn_state(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) # fail the card outside filtered deck c = col.sched.getCard() conf = col.sched._cardConf(c) conf["new"]["delays"] = [1, 10, 61] col.decks.save(conf) col.sched.answerCard(c, 1) assert c.type == CARD_TYPE_LRN and c.queue == QUEUE_TYPE_LRN assert c.left % 1000 == 3 col.sched.answerCard(c, 3) assert c.type == CARD_TYPE_LRN and c.queue == QUEUE_TYPE_LRN # create a dynamic deck and refresh it did = col.decks.new_filtered("Cram") col.sched.rebuild_filtered_deck(did) col.reset() # card should still be in learning state c.load() assert c.type == CARD_TYPE_LRN and c.queue == QUEUE_TYPE_LRN assert c.left % 1000 == 2 # should be able to advance learning steps col.sched.answerCard(c, 3) # should be due at least an hour in the future assert c.due - intTime() > 60 * 60 # emptying the deck preserves learning state col.sched.empty_filtered_deck(did) c.load() assert c.type == CARD_TYPE_LRN and c.queue == QUEUE_TYPE_LRN assert c.left % 1000 == 1 assert c.due - intTime() > 60 * 60 def test_preview(): # add cards col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] orig = copy.copy(c) note2 = col.newNote() note2["Front"] = "two" col.addNote(note2) # cram deck did = col.decks.new_filtered("Cram") cram = col.decks.get(did) cram["resched"] = False col.decks.save(cram) col.sched.rebuild_filtered_deck(did) col.reset() # grab the first card c = col.sched.getCard() if is_2021(): passing_grade = 4 else: passing_grade = 2 assert col.sched.answerButtons(c) == passing_grade assert col.sched.nextIvl(c, 1) == 600 assert col.sched.nextIvl(c, passing_grade) == 0 # failing it will push its due time back due = c.due col.sched.answerCard(c, 1) assert c.due != due # the other card should come next c2 = col.sched.getCard() assert c2.id != c.id # passing it will remove it col.sched.answerCard(c2, passing_grade) assert c2.queue == QUEUE_TYPE_NEW assert c2.reps == 0 assert c2.type == CARD_TYPE_NEW # the other card should appear again c = col.sched.getCard() assert c.id == orig.id # emptying the filtered deck should restore card col.sched.empty_filtered_deck(did) c.load() assert c.queue == QUEUE_TYPE_NEW assert c.reps == 0 assert c.type == CARD_TYPE_NEW def test_ordcycle(): col = getEmptyCol() # add two more templates and set second active m = col.models.current() mm = col.models t = mm.new_template("Reverse") t["qfmt"] = "{{Back}}" t["afmt"] = "{{Front}}" mm.add_template(m, t) t = mm.new_template("f2") t["qfmt"] = "{{Front}}2" t["afmt"] = "{{Back}}" mm.add_template(m, t) mm.save(m) # create a new note; it should have 3 cards note = col.newNote() note["Front"] = "1" note["Back"] = "1" col.addNote(note) assert col.card_count() == 3 conf = col.decks.get_config(1) conf["new"]["bury"] = False col.decks.save(conf) col.reset() # ordinals should arrive in order for i in range(3): c = col.sched.getCard() assert c.ord == i col.sched.answerCard(c, 4) def test_counts_idx(): if is_2021(): pytest.skip("old sched only") col = getEmptyCol() note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) col.reset() assert col.sched.counts() == (1, 0, 0) c = col.sched.getCard() # counter's been decremented but idx indicates 1 assert col.sched.counts() == (0, 0, 0) assert col.sched.countIdx(c) == 0 # answer to move to learn queue col.sched.answerCard(c, 1) assert col.sched.counts() == (0, 1, 0) # fetching again will decrement the count c = col.sched.getCard() assert col.sched.counts() == (0, 0, 0) assert col.sched.countIdx(c) == 1 # answering should add it back again col.sched.answerCard(c, 1) assert col.sched.counts() == (0, 1, 0) def test_counts_idx_new(): if not is_2021(): pytest.skip("new sched only") col = getEmptyCol() note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) note = col.newNote() note["Front"] = "two" note["Back"] = "two" col.addNote(note) col.reset() assert col.sched.counts() == (2, 0, 0) c = col.sched.getCard() # getCard does not decrement counts assert col.sched.counts() == (2, 0, 0) assert col.sched.countIdx(c) == 0 # answer to move to learn queue col.sched.answerCard(c, 1) assert col.sched.counts() == (1, 1, 0) assert col.sched.countIdx(c) == 1 # fetching next will not decrement the count c = col.sched.getCard() assert col.sched.counts() == (1, 1, 0) assert col.sched.countIdx(c) == 0 def test_repCounts(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) note = col.newNote() note["Front"] = "two" col.addNote(note) col.reset() # lrnReps should be accurate on pass/fail assert col.sched.counts() == (2, 0, 0) col.sched.answerCard(col.sched.getCard(), 1) assert col.sched.counts() == (1, 1, 0) col.sched.answerCard(col.sched.getCard(), 1) assert col.sched.counts() == (0, 2, 0) col.sched.answerCard(col.sched.getCard(), 3) assert col.sched.counts() == (0, 2, 0) col.sched.answerCard(col.sched.getCard(), 1) assert col.sched.counts() == (0, 2, 0) col.sched.answerCard(col.sched.getCard(), 3) assert col.sched.counts() == (0, 1, 0) col.sched.answerCard(col.sched.getCard(), 4) assert col.sched.counts() == (0, 0, 0) note = col.newNote() note["Front"] = "three" col.addNote(note) note = col.newNote() note["Front"] = "four" col.addNote(note) col.reset() # initial pass and immediate graduate should be correct too assert col.sched.counts() == (2, 0, 0) col.sched.answerCard(col.sched.getCard(), 3) assert col.sched.counts() == (1, 1, 0) col.sched.answerCard(col.sched.getCard(), 4) assert col.sched.counts() == (0, 1, 0) col.sched.answerCard(col.sched.getCard(), 4) assert col.sched.counts() == (0, 0, 0) # and failing a review should too note = col.newNote() note["Front"] = "five" col.addNote(note) c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.due = col.sched.today c.flush() note = col.newNote() note["Front"] = "six" col.addNote(note) col.reset() assert col.sched.counts() == (1, 0, 1) col.sched.answerCard(col.sched.getCard(), 1) assert col.sched.counts() == (1, 1, 0) def test_timing(): col = getEmptyCol() # add a few review cards, due today for i in range(5): note = col.newNote() note["Front"] = "num" + str(i) col.addNote(note) c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.due = 0 c.flush() # fail the first one col.reset() c = col.sched.getCard() col.sched.answerCard(c, 1) # the next card should be another review c2 = col.sched.getCard() assert c2.queue == QUEUE_TYPE_REV # if the failed card becomes due, it should show first c.due = intTime() - 1 c.flush() col.reset() c = col.sched.getCard() assert c.queue == QUEUE_TYPE_LRN def test_collapse(): col = getEmptyCol() # add a note note = col.newNote() note["Front"] = "one" col.addNote(note) # and another, so we don't get the same twice in a row note = col.newNote() note["Front"] = "two" col.addNote(note) col.reset() # first note c = col.sched.getCard() col.sched.answerCard(c, 1) # second note c2 = col.sched.getCard() assert c2.nid != c.nid col.sched.answerCard(c2, 1) # first should become available again, despite it being due in the future c3 = col.sched.getCard() assert c3.due > intTime() col.sched.answerCard(c3, 4) # answer other c4 = col.sched.getCard() col.sched.answerCard(c4, 4) assert not col.sched.getCard() def test_deckDue(): col = getEmptyCol() # add a note with default deck note = col.newNote() note["Front"] = "one" col.addNote(note) # and one that's a child note = col.newNote() note["Front"] = "two" default1 = note.note_type()["did"] = col.decks.id("Default::1") col.addNote(note) # make it a review card c = note.cards()[0] c.queue = QUEUE_TYPE_REV c.due = 0 c.flush() # add one more with a new deck note = col.newNote() note["Front"] = "two" note.note_type()["did"] = col.decks.id("foo::bar") col.addNote(note) # and one that's a sibling note = col.newNote() note["Front"] = "three" note.note_type()["did"] = col.decks.id("foo::baz") col.addNote(note) col.reset() assert len(col.decks.all_names_and_ids()) == 5 tree = col.sched.deck_due_tree().children assert tree[0].name == "Default" # sum of child and parent assert tree[0].deck_id == 1 assert tree[0].review_count == 1 assert tree[0].new_count == 1 # child count is just review child = tree[0].children[0] assert child.name == "1" assert child.deck_id == default1 assert child.review_count == 1 assert child.new_count == 0 # code should not fail if a card has an invalid deck c.did = 12345 c.flush() col.sched.deck_due_tree() def test_deckTree(): col = getEmptyCol() col.decks.id("new::b::c") col.decks.id("new2") # new should not appear twice in tree names = [x.name for x in col.sched.deck_due_tree().children] names.remove("new") assert "new" not in names def test_deckFlow(): col = getEmptyCol() # add a note with default deck note = col.newNote() note["Front"] = "one" col.addNote(note) # and one that's a child note = col.newNote() note["Front"] = "two" note.note_type()["did"] = col.decks.id("Default::2") col.addNote(note) # and another that's higher up note = col.newNote() note["Front"] = "three" default1 = note.note_type()["did"] = col.decks.id("Default::1") col.addNote(note) col.reset() assert col.sched.counts() == (3, 0, 0) if is_2021(): # cards arrive in position order by default for i in "one", "two", "three": c = col.sched.getCard() assert c.note()["Front"] == i col.sched.answerCard(c, 3) else: # should get top level one first, then ::1, then ::2 for i in "one", "three", "two": c = col.sched.getCard() assert c.note()["Front"] == i col.sched.answerCard(c, 3) def test_reorder(): col = getEmptyCol() # add a note with default deck note = col.newNote() note["Front"] = "one" col.addNote(note) note2 = col.newNote() note2["Front"] = "two" col.addNote(note2) assert note2.cards()[0].due == 2 found = False # 50/50 chance of being reordered for i in range(20): col.sched.randomizeCards(1) if note.cards()[0].due != note.id: found = True break assert found col.sched.orderCards(1) assert note.cards()[0].due == 1 # shifting note3 = col.newNote() note3["Front"] = "three" col.addNote(note3) note4 = col.newNote() note4["Front"] = "four" col.addNote(note4) assert note.cards()[0].due == 1 assert note2.cards()[0].due == 2 assert note3.cards()[0].due == 3 assert note4.cards()[0].due == 4 col.sched.reposition_new_cards( [note3.cards()[0].id, note4.cards()[0].id], starting_from=1, shift_existing=True, step_size=1, randomize=False, ) assert note.cards()[0].due == 3 assert note2.cards()[0].due == 4 assert note3.cards()[0].due == 1 assert note4.cards()[0].due == 2 def test_forget(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] c.queue = QUEUE_TYPE_REV c.type = CARD_TYPE_REV c.ivl = 100 c.due = 0 c.flush() col.reset() assert col.sched.counts() == (0, 0, 1) col.sched.forgetCards([c.id]) col.reset() assert col.sched.counts() == (1, 0, 0) def test_resched(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] col.sched.set_due_date([c.id], "0") c.load() assert c.due == col.sched.today assert c.ivl == 1 assert c.queue == QUEUE_TYPE_REV and c.type == CARD_TYPE_REV # make it due tomorrow col.sched.set_due_date([c.id], "1") c.load() assert c.due == col.sched.today + 1 assert c.ivl == 1 def test_norelearn(): col = getEmptyCol() # add a note note = col.newNote() note["Front"] = "one" col.addNote(note) c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.due = 0 c.factor = STARTING_FACTOR c.reps = 3 c.lapses = 1 c.ivl = 100 c.start_timer() c.flush() col.reset() col.sched.answerCard(c, 1) col.sched._cardConf(c)["lapse"]["delays"] = [] col.sched.answerCard(c, 1) def test_failmult(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) c = note.cards()[0] c.type = CARD_TYPE_REV c.queue = QUEUE_TYPE_REV c.ivl = 100 c.due = col.sched.today - c.ivl c.factor = STARTING_FACTOR c.reps = 3 c.lapses = 1 c.start_timer() c.flush() conf = col.sched._cardConf(c) conf["lapse"]["mult"] = 0.5 col.decks.save(conf) c = col.sched.getCard() col.sched.answerCard(c, 1) assert c.ivl == 50 col.sched.answerCard(c, 1) assert c.ivl == 25 # cards with a due date earlier than the collection should retain # their due date when removed def test_negativeDueFilter(): col = getEmptyCol() # card due prior to collection date note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) c = note.cards()[0] c.due = -5 c.queue = QUEUE_TYPE_REV c.ivl = 5 c.flush() # into and out of filtered deck did = col.decks.new_filtered("Cram") col.sched.rebuild_filtered_deck(did) col.sched.empty_filtered_deck(did) col.reset() c.load() assert c.due == -5 # hard on the first step should be the average of again and good, # and it should be logged properly def test_initial_repeat(): col = getEmptyCol() note = col.newNote() note["Front"] = "one" note["Back"] = "two" col.addNote(note) col.reset() c = col.sched.getCard() col.sched.answerCard(c, 2) # should be due in ~ 5.5 mins expected = time.time() + 5.5 * 60 assert expected - 10 < c.due < expected * 1.25 ivl = col.db.scalar("select ivl from revlog") assert ivl == -5.5 * 60