diff options
Diffstat (limited to 'abseil-cpp/absl/strings/cord_buffer.h')
| -rw-r--r-- | abseil-cpp/absl/strings/cord_buffer.h | 572 |
1 files changed, 572 insertions, 0 deletions
diff --git a/abseil-cpp/absl/strings/cord_buffer.h b/abseil-cpp/absl/strings/cord_buffer.h new file mode 100644 index 0000000..bc0e4e4 --- /dev/null +++ b/abseil-cpp/absl/strings/cord_buffer.h @@ -0,0 +1,572 @@ +// Copyright 2021 The Abseil Authors +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// https://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. +// +// ----------------------------------------------------------------------------- +// File: cord_buffer.h +// ----------------------------------------------------------------------------- +// +// This file defines an `absl::CordBuffer` data structure to hold data for +// eventual inclusion within an existing `Cord` data structure. Cord buffers are +// useful for building large Cords that may require custom allocation of its +// associated memory. +// +#ifndef ABSL_STRINGS_CORD_BUFFER_H_ +#define ABSL_STRINGS_CORD_BUFFER_H_ + +#include <algorithm> +#include <cassert> +#include <cstddef> +#include <cstdint> +#include <memory> +#include <utility> + +#include "absl/base/config.h" +#include "absl/base/macros.h" +#include "absl/numeric/bits.h" +#include "absl/strings/internal/cord_internal.h" +#include "absl/strings/internal/cord_rep_flat.h" +#include "absl/types/span.h" + +namespace absl { +ABSL_NAMESPACE_BEGIN + +class Cord; +class CordBufferTestPeer; + +// CordBuffer +// +// CordBuffer manages memory buffers for purposes such as zero-copy APIs as well +// as applications building cords with large data requiring granular control +// over the allocation and size of cord data. For example, a function creating +// a cord of random data could use a CordBuffer as follows: +// +// absl::Cord CreateRandomCord(size_t length) { +// absl::Cord cord; +// while (length > 0) { +// CordBuffer buffer = CordBuffer::CreateWithDefaultLimit(length); +// absl::Span<char> data = buffer.available_up_to(length); +// FillRandomValues(data.data(), data.size()); +// buffer.IncreaseLengthBy(data.size()); +// cord.Append(std::move(buffer)); +// length -= data.size(); +// } +// return cord; +// } +// +// CordBuffer instances are by default limited to a capacity of `kDefaultLimit` +// bytes. `kDefaultLimit` is currently just under 4KiB, but this default may +// change in the future and/or for specific architectures. The default limit is +// aimed to provide a good trade-off between performance and memory overhead. +// Smaller buffers typically incur more compute cost while larger buffers are +// more CPU efficient but create significant memory overhead because of such +// allocations being less granular. Using larger buffers may also increase the +// risk of memory fragmentation. +// +// Applications create a buffer using one of the `CreateWithDefaultLimit()` or +// `CreateWithCustomLimit()` methods. The returned instance will have a non-zero +// capacity and a zero length. Applications use the `data()` method to set the +// contents of the managed memory, and once done filling the buffer, use the +// `IncreaseLengthBy()` or 'SetLength()' method to specify the length of the +// initialized data before adding the buffer to a Cord. +// +// The `CreateWithCustomLimit()` method is intended for applications needing +// larger buffers than the default memory limit, allowing the allocation of up +// to a capacity of `kCustomLimit` bytes minus some minimum internal overhead. +// The usage of `CreateWithCustomLimit()` should be limited to only those use +// cases where the distribution of the input is relatively well known, and/or +// where the trade-off between the efficiency gains outweigh the risk of memory +// fragmentation. See the documentation for `CreateWithCustomLimit()` for more +// information on using larger custom limits. +// +// The capacity of a `CordBuffer` returned by one of the `Create` methods may +// be larger than the requested capacity due to rounding, alignment and +// granularity of the memory allocator. Applications should use the `capacity` +// method to obtain the effective capacity of the returned instance as +// demonstrated in the provided example above. +// +// CordBuffer is a move-only class. All references into the managed memory are +// invalidated when an instance is moved into either another CordBuffer instance +// or a Cord. Writing to a location obtained by a previous call to `data()` +// after an instance was moved will lead to undefined behavior. +// +// A `moved from` CordBuffer instance will have a valid, but empty state. +// CordBuffer is thread compatible. +class CordBuffer { + public: + // kDefaultLimit + // + // Default capacity limits of allocated CordBuffers. + // See the class comments for more information on allocation limits. + static constexpr size_t kDefaultLimit = cord_internal::kMaxFlatLength; + + // kCustomLimit + // + // Maximum size for CreateWithCustomLimit() allocated buffers. + // Note that the effective capacity may be slightly less + // because of internal overhead of internal cord buffers. + static constexpr size_t kCustomLimit = 64U << 10; + + // Constructors, Destructors and Assignment Operators + + // Creates an empty CordBuffer. + CordBuffer() = default; + + // Destroys this CordBuffer instance and, if not empty, releases any memory + // managed by this instance, invalidating previously returned references. + ~CordBuffer(); + + // CordBuffer is move-only + CordBuffer(CordBuffer&& rhs) noexcept; + CordBuffer& operator=(CordBuffer&&) noexcept; + CordBuffer(const CordBuffer&) = delete; + CordBuffer& operator=(const CordBuffer&) = delete; + + // CordBuffer::MaximumPayload() + // + // Returns the guaranteed maximum payload for a CordBuffer returned by the + // `CreateWithDefaultLimit()` method. While small, each internal buffer inside + // a Cord incurs an overhead to manage the length, type and reference count + // for the buffer managed inside the cord tree. Applications can use this + // method to get approximate number of buffers required for a given byte + // size, etc. + // + // For example: + // const size_t payload = absl::CordBuffer::MaximumPayload(); + // const size_t buffer_count = (total_size + payload - 1) / payload; + // buffers.reserve(buffer_count); + static constexpr size_t MaximumPayload(); + + // Overload to the above `MaximumPayload()` except that it returns the + // maximum payload for a CordBuffer returned by the `CreateWithCustomLimit()` + // method given the provided `block_size`. + static constexpr size_t MaximumPayload(size_t block_size); + + // CordBuffer::CreateWithDefaultLimit() + // + // Creates a CordBuffer instance of the desired `capacity`, capped at the + // default limit `kDefaultLimit`. The returned buffer has a guaranteed + // capacity of at least `min(kDefaultLimit, capacity)`. See the class comments + // for more information on buffer capacities and intended usage. + static CordBuffer CreateWithDefaultLimit(size_t capacity); + + // CordBuffer::CreateWithCustomLimit() + // + // Creates a CordBuffer instance of the desired `capacity` rounded to an + // appropriate power of 2 size less than, or equal to `block_size`. + // Requires `block_size` to be a power of 2. + // + // If `capacity` is less than or equal to `kDefaultLimit`, then this method + // behaves identical to `CreateWithDefaultLimit`, which means that the caller + // is guaranteed to get a buffer of at least the requested capacity. + // + // If `capacity` is greater than or equal to `block_size`, then this method + // returns a buffer with an `allocated size` of `block_size` bytes. Otherwise, + // this methods returns a buffer with a suitable smaller power of 2 block size + // to satisfy the request. The actual size depends on a number of factors, and + // is typically (but not necessarily) the highest or second highest power of 2 + // value less than or equal to `capacity`. + // + // The 'allocated size' includes a small amount of overhead required for + // internal state, which is currently 13 bytes on 64-bit platforms. For + // example: a buffer created with `block_size` and `capacity' set to 8KiB + // will have an allocated size of 8KiB, and an effective internal `capacity` + // of 8KiB - 13 = 8179 bytes. + // + // To demonstrate this in practice, let's assume we want to read data from + // somewhat larger files using approximately 64KiB buffers: + // + // absl::Cord ReadFromFile(int fd, size_t n) { + // absl::Cord cord; + // while (n > 0) { + // CordBuffer buffer = CordBuffer::CreateWithCustomLimit(64 << 10, n); + // absl::Span<char> data = buffer.available_up_to(n); + // ReadFileDataOrDie(fd, data.data(), data.size()); + // buffer.IncreaseLengthBy(data.size()); + // cord.Append(std::move(buffer)); + // n -= data.size(); + // } + // return cord; + // } + // + // If we'd use this function to read a file of 659KiB, we may get the + // following pattern of allocated cord buffer sizes: + // + // CreateWithCustomLimit(64KiB, 674816) --> ~64KiB (65523) + // CreateWithCustomLimit(64KiB, 674816) --> ~64KiB (65523) + // ... + // CreateWithCustomLimit(64KiB, 19586) --> ~16KiB (16371) + // CreateWithCustomLimit(64KiB, 3215) --> 3215 (at least 3215) + // + // The reason the method returns a 16K buffer instead of a roughly 19K buffer + // is to reduce memory overhead and fragmentation risks. Using carefully + // chosen power of 2 values reduces the entropy of allocated memory sizes. + // + // Additionally, let's assume we'd use the above function on files that are + // generally smaller than 64K. If we'd use 'precise' sized buffers for such + // files, than we'd get a very wide distribution of allocated memory sizes + // rounded to 4K page sizes, and we'd end up with a lot of unused capacity. + // + // In general, application should only use custom sizes if the data they are + // consuming or storing is expected to be many times the chosen block size, + // and be based on objective data and performance metrics. For example, a + // compress function may work faster and consume less CPU when using larger + // buffers. Such an application should pick a size offering a reasonable + // trade-off between expected data size, compute savings with larger buffers, + // and the cost or fragmentation effect of larger buffers. + // Applications must pick a reasonable spot on that curve, and make sure their + // data meets their expectations in size distributions such as "mostly large". + static CordBuffer CreateWithCustomLimit(size_t block_size, size_t capacity); + + // CordBuffer::available() + // + // Returns the span delineating the available capacity in this buffer + // which is defined as `{ data() + length(), capacity() - length() }`. + absl::Span<char> available(); + + // CordBuffer::available_up_to() + // + // Returns the span delineating the available capacity in this buffer limited + // to `size` bytes. This is equivalent to `available().subspan(0, size)`. + absl::Span<char> available_up_to(size_t size); + + // CordBuffer::data() + // + // Returns a non-null reference to the data managed by this instance. + // Applications are allowed to write up to `capacity` bytes of instance data. + // CordBuffer data is uninitialized by default. Reading data from an instance + // that has not yet been initialized will lead to undefined behavior. + char* data(); + const char* data() const; + + // CordBuffer::length() + // + // Returns the length of this instance. The default length of a CordBuffer is + // 0, indicating an 'empty' CordBuffer. Applications must specify the length + // of the data in a CordBuffer before adding it to a Cord. + size_t length() const; + + // CordBuffer::capacity() + // + // Returns the capacity of this instance. All instances have a non-zero + // capacity: default and `moved from` instances have a small internal buffer. + size_t capacity() const; + + // CordBuffer::IncreaseLengthBy() + // + // Increases the length of this buffer by the specified 'n' bytes. + // Applications must make sure all data in this buffer up to the new length + // has been initialized before adding a CordBuffer to a Cord: failure to do so + // will lead to undefined behavior. Requires `length() + n <= capacity()`. + // Typically, applications will use 'available_up_to()` to get a span of the + // desired capacity, and use `span.size()` to increase the length as in: + // absl::Span<char> span = buffer.available_up_to(desired); + // buffer.IncreaseLengthBy(span.size()); + // memcpy(span.data(), src, span.size()); + // etc... + void IncreaseLengthBy(size_t n); + + // CordBuffer::SetLength() + // + // Sets the data length of this instance. Applications must make sure all data + // of the specified length has been initialized before adding a CordBuffer to + // a Cord: failure to do so will lead to undefined behavior. + // Setting the length to a small value or zero does not release any memory + // held by this CordBuffer instance. Requires `length <= capacity()`. + // Applications should preferably use the `IncreaseLengthBy()` method above + // in combination with the 'available()` or `available_up_to()` methods. + void SetLength(size_t length); + + private: + // Make sure we don't accidentally over promise. + static_assert(kCustomLimit <= cord_internal::kMaxLargeFlatSize, ""); + + // Assume the cost of an 'uprounded' allocation to CeilPow2(size) versus + // the cost of allocating at least 1 extra flat <= 4KB: + // - Flat overhead = 13 bytes + // - Btree amortized cost / node =~ 13 bytes + // - 64 byte granularity of tcmalloc at 4K =~ 32 byte average + // CPU cost and efficiency requires we should at least 'save' something by + // splitting, as a poor man's measure, we say the slop needs to be + // at least double the cost offset to make it worth splitting: ~128 bytes. + static constexpr size_t kMaxPageSlop = 128; + + // Overhead for allocation a flat. + static constexpr size_t kOverhead = cord_internal::kFlatOverhead; + + using CordRepFlat = cord_internal::CordRepFlat; + + // `Rep` is the internal data representation of a CordBuffer. The internal + // representation has an internal small size optimization similar to + // std::string (SSO). + struct Rep { + // Inline SSO size of a CordBuffer + static constexpr size_t kInlineCapacity = sizeof(intptr_t) * 2 - 1; + + // Creates a default instance with kInlineCapacity. + Rep() : short_rep{} {} + + // Creates an instance managing an allocated non zero CordRep. + explicit Rep(cord_internal::CordRepFlat* rep) : long_rep{rep} { + assert(rep != nullptr); + } + + // Returns true if this instance manages the SSO internal buffer. + bool is_short() const { + constexpr size_t offset = offsetof(Short, raw_size); + return (reinterpret_cast<const char*>(this)[offset] & 1) != 0; + } + + // Returns the available area of the internal SSO data + absl::Span<char> short_available() { + const size_t length = short_length(); + return absl::Span<char>(short_rep.data + length, + kInlineCapacity - length); + } + + // Returns the available area of the internal SSO data + absl::Span<char> long_available() const { + assert(!is_short()); + const size_t length = long_rep.rep->length; + return absl::Span<char>(long_rep.rep->Data() + length, + long_rep.rep->Capacity() - length); + } + + // Returns the length of the internal SSO data. + size_t short_length() const { + assert(is_short()); + return static_cast<size_t>(short_rep.raw_size >> 1); + } + + // Sets the length of the internal SSO data. + // Disregards any previously set CordRep instance. + void set_short_length(size_t length) { + short_rep.raw_size = static_cast<char>((length << 1) + 1); + } + + // Adds `n` to the current short length. + void add_short_length(size_t n) { + assert(is_short()); + short_rep.raw_size += static_cast<char>(n << 1); + } + + // Returns reference to the internal SSO data buffer. + char* data() { + assert(is_short()); + return short_rep.data; + } + const char* data() const { + assert(is_short()); + return short_rep.data; + } + + // Returns a pointer the external CordRep managed by this instance. + cord_internal::CordRepFlat* rep() const { + assert(!is_short()); + return long_rep.rep; + } + + // The internal representation takes advantage of the fact that allocated + // memory is always on an even address, and uses the least significant bit + // of the first or last byte (depending on endianness) as the inline size + // indicator overlapping with the least significant byte of the CordRep*. +#if defined(ABSL_IS_BIG_ENDIAN) + struct Long { + explicit Long(cord_internal::CordRepFlat* rep_arg) : rep(rep_arg) {} + void* padding; + cord_internal::CordRepFlat* rep; + }; + struct Short { + char data[sizeof(Long) - 1]; + char raw_size = 1; + }; +#else + struct Long { + explicit Long(cord_internal::CordRepFlat* rep_arg) : rep(rep_arg) {} + cord_internal::CordRepFlat* rep; + void* padding; + }; + struct Short { + char raw_size = 1; + char data[sizeof(Long) - 1]; + }; +#endif + + union { + Long long_rep; + Short short_rep; + }; + }; + + // Power2 functions + static bool IsPow2(size_t size) { return absl::has_single_bit(size); } + static size_t Log2Floor(size_t size) { + return static_cast<size_t>(absl::bit_width(size) - 1); + } + static size_t Log2Ceil(size_t size) { + return static_cast<size_t>(absl::bit_width(size - 1)); + } + + // Implementation of `CreateWithCustomLimit()`. + // This implementation allows for future memory allocation hints to + // be passed down into the CordRepFlat allocation function. + template <typename... AllocationHints> + static CordBuffer CreateWithCustomLimitImpl(size_t block_size, + size_t capacity, + AllocationHints... hints); + + // Consumes the value contained in this instance and resets the instance. + // This method returns a non-null Cordrep* if the current instances manages a + // CordRep*, and resets the instance to an empty SSO instance. If the current + // instance is an SSO instance, then this method returns nullptr and sets + // `short_value` to the inlined data value. In either case, the current + // instance length is reset to zero. + // This method is intended to be used by Cord internal functions only. + cord_internal::CordRep* ConsumeValue(absl::string_view& short_value) { + cord_internal::CordRep* rep = nullptr; + if (rep_.is_short()) { + short_value = absl::string_view(rep_.data(), rep_.short_length()); + } else { + rep = rep_.rep(); + } + rep_.set_short_length(0); + return rep; + } + + // Internal constructor. + explicit CordBuffer(cord_internal::CordRepFlat* rep) : rep_(rep) { + assert(rep != nullptr); + } + + Rep rep_; + + friend class Cord; + friend class CordBufferTestPeer; +}; + +inline constexpr size_t CordBuffer::MaximumPayload() { + return cord_internal::kMaxFlatLength; +} + +inline constexpr size_t CordBuffer::MaximumPayload(size_t block_size) { + return (std::min)(kCustomLimit, block_size) - cord_internal::kFlatOverhead; +} + +inline CordBuffer CordBuffer::CreateWithDefaultLimit(size_t capacity) { + if (capacity > Rep::kInlineCapacity) { + auto* rep = cord_internal::CordRepFlat::New(capacity); + rep->length = 0; + return CordBuffer(rep); + } + return CordBuffer(); +} + +template <typename... AllocationHints> +inline CordBuffer CordBuffer::CreateWithCustomLimitImpl( + size_t block_size, size_t capacity, AllocationHints... hints) { + assert(IsPow2(block_size)); + capacity = (std::min)(capacity, kCustomLimit); + block_size = (std::min)(block_size, kCustomLimit); + if (capacity + kOverhead >= block_size) { + capacity = block_size; + } else if (capacity <= kDefaultLimit) { + capacity = capacity + kOverhead; + } else if (!IsPow2(capacity)) { + // Check if rounded up to next power 2 is a good enough fit + // with limited waste making it an acceptable direct fit. + const size_t rounded_up = size_t{1} << Log2Ceil(capacity); + const size_t slop = rounded_up - capacity; + if (slop >= kOverhead && slop <= kMaxPageSlop + kOverhead) { + capacity = rounded_up; + } else { + // Round down to highest power of 2 <= capacity. + // Consider a more aggressive step down if that may reduce the + // risk of fragmentation where 'people are holding it wrong'. + const size_t rounded_down = size_t{1} << Log2Floor(capacity); + capacity = rounded_down; + } + } + const size_t length = capacity - kOverhead; + auto* rep = CordRepFlat::New(CordRepFlat::Large(), length, hints...); + rep->length = 0; + return CordBuffer(rep); +} + +inline CordBuffer CordBuffer::CreateWithCustomLimit(size_t block_size, + size_t capacity) { + return CreateWithCustomLimitImpl(block_size, capacity); +} + +inline CordBuffer::~CordBuffer() { + if (!rep_.is_short()) { + cord_internal::CordRepFlat::Delete(rep_.rep()); + } +} + +inline CordBuffer::CordBuffer(CordBuffer&& rhs) noexcept : rep_(rhs.rep_) { + rhs.rep_.set_short_length(0); +} + +inline CordBuffer& CordBuffer::operator=(CordBuffer&& rhs) noexcept { + if (!rep_.is_short()) cord_internal::CordRepFlat::Delete(rep_.rep()); + rep_ = rhs.rep_; + rhs.rep_.set_short_length(0); + return *this; +} + +inline absl::Span<char> CordBuffer::available() { + return rep_.is_short() ? rep_.short_available() : rep_.long_available(); +} + +inline absl::Span<char> CordBuffer::available_up_to(size_t size) { + return available().subspan(0, size); +} + +inline char* CordBuffer::data() { + return rep_.is_short() ? rep_.data() : rep_.rep()->Data(); +} + +inline const char* CordBuffer::data() const { + return rep_.is_short() ? rep_.data() : rep_.rep()->Data(); +} + +inline size_t CordBuffer::capacity() const { + return rep_.is_short() ? Rep::kInlineCapacity : rep_.rep()->Capacity(); +} + +inline size_t CordBuffer::length() const { + return rep_.is_short() ? rep_.short_length() : rep_.rep()->length; +} + +inline void CordBuffer::SetLength(size_t length) { + ABSL_HARDENING_ASSERT(length <= capacity()); + if (rep_.is_short()) { + rep_.set_short_length(length); + } else { + rep_.rep()->length = length; + } +} + +inline void CordBuffer::IncreaseLengthBy(size_t n) { + ABSL_HARDENING_ASSERT(n <= capacity() && length() + n <= capacity()); + if (rep_.is_short()) { + rep_.add_short_length(n); + } else { + rep_.rep()->length += n; + } +} + +ABSL_NAMESPACE_END +} // namespace absl + +#endif // ABSL_STRINGS_CORD_BUFFER_H_ |