/* * Copyright (c) 2018-2020, Andreas Kling * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #pragma once #include #include #include #include #include #include #include namespace AK { class Bitmap { AK_MAKE_NONCOPYABLE(Bitmap); public: // NOTE: A wrapping Bitmap won't try to free the wrapped data. static Bitmap wrap(u8* data, size_t size) { return Bitmap(data, size); } static Bitmap create(size_t size, bool default_value = 0) { return Bitmap(size, default_value); } static Bitmap create() { return Bitmap(); } Bitmap(Bitmap&& other) { m_owned = exchange(other.m_owned, false); m_data = exchange(other.m_data, nullptr); m_size = exchange(other.m_size, 0); } Bitmap& operator=(Bitmap&& other) { if (this != &other) { if (m_owned) kfree(m_data); m_owned = exchange(other.m_owned, false); m_data = exchange(other.m_data, nullptr); m_size = exchange(other.m_size, 0); } return *this; } ~Bitmap() { if (m_owned) kfree(m_data); m_data = nullptr; } size_t size() const { return m_size; } bool get(size_t index) const { ASSERT(index < m_size); return 0 != (m_data[index / 8] & (1u << (index % 8))); } void set(size_t index, bool value) const { ASSERT(index < m_size); if (value) m_data[index / 8] |= static_cast((1u << (index % 8))); else m_data[index / 8] &= static_cast(~(1u << (index % 8))); } size_t count_slow(bool value) const { return count_in_range(0, m_size, value); } size_t count_in_range(size_t start, size_t len, bool value) const { ASSERT(start < m_size); ASSERT(start + len <= m_size); if (len == 0) return 0; static const u8 bitmask_first_byte[8] = { 0xFF, 0xFE, 0xFC, 0xF8, 0xF0, 0xE0, 0xC0, 0x80 }; static const u8 bitmask_last_byte[8] = { 0x0, 0x1, 0x3, 0x7, 0xF, 0x1F, 0x3F, 0x7F }; size_t count; const u8* first = &m_data[start / 8]; const u8* last = &m_data[(start + len) / 8]; u8 byte = *first; byte &= bitmask_first_byte[start % 8]; if (first == last) { byte &= bitmask_last_byte[(start + len) % 8]; count = __builtin_popcount(byte); } else { count = __builtin_popcount(byte); byte = *last; byte &= bitmask_last_byte[(start + len) % 8]; count += __builtin_popcount(byte); if (++first < last) { const u32* ptr32 = (const u32*)(((FlatPtr)first + sizeof(u32) - 1) & ~(sizeof(u32) - 1)); if ((const u8*)ptr32 > last) ptr32 = (const u32*)last; while (first < (const u8*)ptr32) { count += __builtin_popcount(*first); first++; } const u32* last32 = (const u32*)((FlatPtr)last & ~(sizeof(u32) - 1)); while (ptr32 < last32) { count += __builtin_popcountl(*ptr32); ptr32++; } for (first = (const u8*)ptr32; first < last; first++) count += __builtin_popcount(*first); } } if (!value) count = len - count; return count; } u8* data() { return m_data; } const u8* data() const { return m_data; } void grow(size_t size, bool default_value) { ASSERT(m_owned); ASSERT(size > m_size); auto previous_size_bytes = size_in_bytes(); auto previous_size = m_size; auto previous_data = m_data; m_size = size; m_data = reinterpret_cast(kmalloc(size_in_bytes())); fill(default_value); if (previous_data != nullptr) { __builtin_memcpy(m_data, previous_data, previous_size_bytes); if (previous_size % 8) set_range(previous_size, 8 - previous_size % 8, default_value); kfree(previous_data); } } template void set_range(size_t start, size_t len) { ASSERT(start < m_size); ASSERT(start + len <= m_size); if (len == 0) return; static const u8 bitmask_first_byte[8] = { 0xFF, 0xFE, 0xFC, 0xF8, 0xF0, 0xE0, 0xC0, 0x80 }; static const u8 bitmask_last_byte[8] = { 0x0, 0x1, 0x3, 0x7, 0xF, 0x1F, 0x3F, 0x7F }; u8* first = &m_data[start / 8]; u8* last = &m_data[(start + len) / 8]; u8 byte_mask = bitmask_first_byte[start % 8]; if (first == last) { byte_mask &= bitmask_last_byte[(start + len) % 8]; if constexpr (VALUE) *first |= byte_mask; else *first &= ~byte_mask; } else { if constexpr (VALUE) *first |= byte_mask; else *first &= ~byte_mask; byte_mask = bitmask_last_byte[(start + len) % 8]; if constexpr (VALUE) *last |= byte_mask; else *last &= ~byte_mask; if (++first < last) { if constexpr (VALUE) __builtin_memset(first, 0xFF, last - first); else __builtin_memset(first, 0x0, last - first); } } } void set_range(size_t start, size_t len, bool value) { if (value) set_range(start, len); else set_range(start, len); } void fill(bool value) { __builtin_memset(m_data, value ? 0xff : 0x00, size_in_bytes()); } template Optional find_one_anywhere(size_t hint = 0) const { ASSERT(hint < m_size); const u8* end = &m_data[m_size / 8]; for (;;) { // We will use hint as what it is: a hint. Because we try to // scan over entire 32 bit words, we may start searching before // the hint! const u32* ptr32 = (const u32*)((FlatPtr)&m_data[hint / 8] & ~(sizeof(u32) - 1)); if ((const u8*)ptr32 < &m_data[0]) { ptr32++; // m_data isn't aligned, check first bytes size_t start_ptr32 = (const u8*)ptr32 - &m_data[0]; size_t i = 0; u8 byte = VALUE ? 0x00 : 0xff; while (i < start_ptr32 && m_data[i] == byte) i++; if (i < start_ptr32) { byte = m_data[i]; if constexpr (!VALUE) byte = ~byte; ASSERT(byte != 0); return i * 8 + __builtin_ffs(byte) - 1; } } u32 val32 = VALUE ? 0x0 : 0xffffffff; const u32* end32 = (const u32*)((FlatPtr)end & ~(sizeof(u32) - 1)); while (ptr32 < end32 && *ptr32 == val32) ptr32++; if (ptr32 == end32) { // We didn't find anything, check the remaining few bytes (if any) u8 byte = VALUE ? 0x00 : 0xff; size_t i = (const u8*)ptr32 - &m_data[0]; size_t byte_count = m_size / 8; ASSERT(i <= byte_count); while (i < byte_count && m_data[i] == byte) i++; if (i == byte_count) { if (hint <= 8) return {}; // We already checked from the beginning // Try scanning before the hint end = (const u8*)((FlatPtr)&m_data[hint / 8] & ~(sizeof(u32) - 1)); hint = 0; continue; } byte = m_data[i]; if constexpr (!VALUE) byte = ~byte; ASSERT(byte != 0); return i * 8 + __builtin_ffs(byte) - 1; } // NOTE: We don't really care about byte ordering. We found *one* // free bit, just calculate the position and return it val32 = *ptr32; if constexpr (!VALUE) val32 = ~val32; ASSERT(val32 != 0); return ((const u8*)ptr32 - &m_data[0]) * 8 + __builtin_ffsl(val32) - 1; } } Optional find_one_anywhere_set(size_t hint = 0) const { return find_one_anywhere(hint); } Optional find_one_anywhere_unset(size_t hint = 0) const { return find_one_anywhere(hint); } template Optional find_first() const { size_t byte_count = m_size / 8; size_t i = 0; u8 byte = VALUE ? 0x00 : 0xff; while (i < byte_count && m_data[i] == byte) i++; if (i == byte_count) return {}; byte = m_data[i]; if constexpr (!VALUE) byte = ~byte; ASSERT(byte != 0); return i * 8 + __builtin_ffs(byte) - 1; } Optional find_first_set() const { return find_first(); } Optional find_first_unset() const { return find_first(); } // The function will return the next range of unset bits starting from the // @from value. // @from: the postition from which the search starts. The var will be // changed and new value is the offset of the found block. // @min_length: minimum size of the range which will be returned. // @max_length: maximum size of the range which will be returned. // This is used to increase performance, since the range of // unset bits can be long, and we don't need the while range, // so we can stop when we've reached @max_length. inline Optional find_next_range_of_unset_bits(size_t& from, size_t min_length = 1, size_t max_length = max_size) const { if (min_length > max_length) { return {}; } u32* bitmap32 = (u32*)m_data; // Calculating the start offset. size_t start_bucket_index = from / 32; size_t start_bucket_bit = from % 32; size_t* start_of_free_chunks = &from; size_t free_chunks = 0; for (size_t bucket_index = start_bucket_index; bucket_index < m_size / 32; ++bucket_index) { if (bitmap32[bucket_index] == 0xffffffff) { // Skip over completely full bucket of size 32. if (free_chunks >= min_length) { return min(free_chunks, max_length); } free_chunks = 0; start_bucket_bit = 0; continue; } if (bitmap32[bucket_index] == 0x0) { // Skip over completely empty bucket of size 32. if (free_chunks == 0) { *start_of_free_chunks = bucket_index * 32; } free_chunks += 32; if (free_chunks >= max_length) { return max_length; } start_bucket_bit = 0; continue; } u32 bucket = bitmap32[bucket_index]; u8 viewed_bits = start_bucket_bit; u32 trailing_zeroes = 0; bucket >>= viewed_bits; start_bucket_bit = 0; while (viewed_bits < 32) { if (bucket == 0) { if (free_chunks == 0) { *start_of_free_chunks = bucket_index * 32 + viewed_bits; } free_chunks += 32 - viewed_bits; viewed_bits = 32; } else { trailing_zeroes = count_trailing_zeroes_32(bucket); bucket >>= trailing_zeroes; if (free_chunks == 0) { *start_of_free_chunks = bucket_index * 32 + viewed_bits; } free_chunks += trailing_zeroes; viewed_bits += trailing_zeroes; if (free_chunks >= min_length) { return min(free_chunks, max_length); } // Deleting trailing ones. u32 trailing_ones = count_trailing_zeroes_32(~bucket); bucket >>= trailing_ones; viewed_bits += trailing_ones; free_chunks = 0; } } } if (free_chunks < min_length) { size_t first_trailing_bit = (m_size / 32) * 32; size_t trailing_bits = size() % 32; for (size_t i = 0; i < trailing_bits; ++i) { if (!get(first_trailing_bit + i)) { if (!free_chunks) *start_of_free_chunks = first_trailing_bit + i; if (++free_chunks >= min_length) return min(free_chunks, max_length); } else { free_chunks = 0; } } return {}; } return min(free_chunks, max_length); } Optional find_longest_range_of_unset_bits(size_t max_length, size_t& found_range_size) const { size_t start = 0; size_t max_region_start = 0; size_t max_region_size = 0; while (true) { // Look for the next block which is bigger than currunt. auto length_of_found_range = find_next_range_of_unset_bits(start, max_region_size + 1, max_length); if (length_of_found_range.has_value()) { max_region_start = start; max_region_size = length_of_found_range.value(); start += max_region_size; } else { // No ranges which are bigger than current were found. break; } } found_range_size = max_region_size; if (max_region_size) { return max_region_start; } return {}; } Optional find_first_fit(size_t minimum_length) const { size_t start = 0; auto length_of_found_range = find_next_range_of_unset_bits(start, minimum_length, minimum_length); if (length_of_found_range.has_value()) { return start; } return {}; } Optional find_best_fit(size_t minimum_length) const { size_t start = 0; size_t best_region_start = 0; size_t best_region_size = max_size; bool found = false; while (true) { // Look for the next block which is bigger than requested length. auto length_of_found_range = find_next_range_of_unset_bits(start, minimum_length, best_region_size); if (length_of_found_range.has_value()) { if (best_region_size > length_of_found_range.value() || !found) { best_region_start = start; best_region_size = length_of_found_range.value(); found = true; } start += length_of_found_range.value(); } else { // There are no ranges which can fit requested length. break; } } if (found) { return best_region_start; } return {}; } Bitmap() : m_size(0) , m_owned(true) { m_data = nullptr; } Bitmap(size_t size, bool default_value) : m_size(size) , m_owned(true) { ASSERT(m_size != 0); m_data = reinterpret_cast(kmalloc(size_in_bytes())); fill(default_value); } Bitmap(u8* data, size_t size) : m_data(data) , m_size(size) , m_owned(false) { } static constexpr u32 max_size = 0xffffffff; private: size_t size_in_bytes() const { return ceil_div(m_size, static_cast(8)); } u8* m_data { nullptr }; size_t m_size { 0 }; bool m_owned { false }; }; } using AK::Bitmap;