#!/usr/bin/env python
#
# Tests for shrinking images
#
# Copyright (c) 2016-2017 Parallels International GmbH
#
# This program is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 2 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program.  If not, see <http://www.gnu.org/licenses/>.
#

import os, random, iotests, struct, qcow2
from iotests import qemu_img, qemu_io, image_size

test_img = os.path.join(iotests.test_dir, 'test.img')
check_img = os.path.join(iotests.test_dir, 'check.img')

def size_to_int(str):
    suff = ['B', 'K', 'M', 'G', 'T']
    return int(str[:-1]) * 1024**suff.index(str[-1:])

class ShrinkBaseClass(iotests.QMPTestCase):
    image_len = '128M'
    shrink_size = '10M'
    chunk_size = '16M'
    refcount_bits = '16'

    def __qcow2_check(self, filename):
        entry_bits = 3
        entry_size = 1 << entry_bits
        l1_mask = 0x00fffffffffffe00
        div_roundup = lambda n, d: (n + d - 1) / d

        def split_by_n(data, n):
            for x in xrange(0, len(data), n):
                yield struct.unpack('>Q', data[x:x + n])[0] & l1_mask

        def check_l1_table(h, l1_data):
            l1_list = list(split_by_n(l1_data, entry_size))
            real_l1_size = div_roundup(h.size,
                                       1 << (h.cluster_bits*2 - entry_size))
            used, unused = l1_list[:real_l1_size], l1_list[real_l1_size:]

            self.assertTrue(len(used) != 0, "Verifying l1 table content")
            self.assertFalse(any(unused), "Verifying l1 table content")

        def check_reftable(fd, h, reftable):
            for offset in split_by_n(reftable, entry_size):
                if offset != 0:
                    fd.seek(offset)
                    cluster = fd.read(1 << h.cluster_bits)
                    self.assertTrue(any(cluster), "Verifying reftable content")

        with open(filename, "rb") as fd:
            h = qcow2.QcowHeader(fd)

            fd.seek(h.l1_table_offset)
            l1_table = fd.read(h.l1_size << entry_bits)

            fd.seek(h.refcount_table_offset)
            reftable = fd.read(h.refcount_table_clusters << h.cluster_bits)

            check_l1_table(h, l1_table)
            check_reftable(fd, h, reftable)

    def __raw_check(self, filename):
        pass

    image_check = {
        'qcow2' : __qcow2_check,
        'raw' : __raw_check
    }

    def setUp(self):
        if iotests.imgfmt == 'raw':
            qemu_img('create', '-f', iotests.imgfmt, test_img, self.image_len)
            qemu_img('create', '-f', iotests.imgfmt, check_img,
                     self.shrink_size)
        else:
            qemu_img('create', '-f', iotests.imgfmt,
                     '-o', 'cluster_size=' + self.cluster_size +
                     ',refcount_bits=' + self.refcount_bits,
                     test_img, self.image_len)
            qemu_img('create', '-f', iotests.imgfmt,
                     '-o', 'cluster_size=%s'% self.cluster_size,
                     check_img, self.shrink_size)
        qemu_io('-c', 'write -P 0xff 0 ' + self.shrink_size, check_img)

    def tearDown(self):
        os.remove(test_img)
        os.remove(check_img)

    def image_verify(self):
        self.assertEqual(image_size(test_img), image_size(check_img),
                         "Verifying image size")
        self.image_check[iotests.imgfmt](self, test_img)

        if iotests.imgfmt == 'raw':
            return
        self.assertEqual(qemu_img('check', test_img), 0,
                         "Verifying image corruption")

    def test_empty_image(self):
        qemu_img('resize',  '-f', iotests.imgfmt, '--shrink', test_img,
                 self.shrink_size)

        self.assertEqual(
            qemu_io('-c', 'read -P 0x00 %s'%self.shrink_size, test_img),
            qemu_io('-c', 'read -P 0x00 %s'%self.shrink_size, check_img),
            "Verifying image content")

        self.image_verify()

    def test_sequential_write(self):
        for offs in range(0, size_to_int(self.image_len),
                          size_to_int(self.chunk_size)):
            qemu_io('-c', 'write -P 0xff %d %s' % (offs, self.chunk_size),
                    test_img)

        qemu_img('resize',  '-f', iotests.imgfmt, '--shrink', test_img,
                 self.shrink_size)

        self.assertEqual(qemu_img("compare", test_img, check_img), 0,
                         "Verifying image content")

        self.image_verify()

    def test_random_write(self):
        offs_list = range(0, size_to_int(self.image_len),
                          size_to_int(self.chunk_size))
        random.shuffle(offs_list)
        for offs in offs_list:
            qemu_io('-c', 'write -P 0xff %d %s' % (offs, self.chunk_size),
                    test_img)

        qemu_img('resize',  '-f', iotests.imgfmt, '--shrink', test_img,
                 self.shrink_size)

        self.assertEqual(qemu_img("compare", test_img, check_img), 0,
                         "Verifying image content")

        self.image_verify()

class TestShrink512(ShrinkBaseClass):
    image_len = '3M'
    shrink_size = '1M'
    chunk_size = '256K'
    cluster_size = '512'
    refcount_bits = '64'

class TestShrink64K(ShrinkBaseClass):
    cluster_size = '64K'

class TestShrink1M(ShrinkBaseClass):
    cluster_size = '1M'
    refcount_bits = '1'

ShrinkBaseClass = None

if __name__ == '__main__':
    iotests.main(supported_fmts=['raw', 'qcow2'])