/root/doris/be/src/util/faststring.h

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// Licensed to the Apache Software Foundation (ASF) under one
// or more contributor license agreements.  See the NOTICE file
// distributed with this work for additional information
// regarding copyright ownership.  The ASF licenses this file
// to you 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
//
//   http://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.

#pragma once

#include <butil/macros.h>

#include <cstdint>
#include <cstring>
#include <string>

#include "gutil/dynamic_annotations.h"
#include "gutil/port.h"
#include "util/memcpy_inlined.h"
#include "util/slice.h"
#include "vec/common/allocator.h"

namespace doris {

// A faststring is similar to a std::string, except that it is faster for many
// common use cases (in particular, resize() will fill with uninitialized data
// instead of memsetting to \0)
// only build() can transfer data to the outside.
class faststring : private Allocator<false, false, false, DefaultMemoryAllocator> {
public:
    enum { kInitialCapacity = 32 };

    faststring() : data_(initial_data_), len_(0), capacity_(kInitialCapacity) {}

    // Construct a string with the given capacity, in bytes.
    explicit faststring(size_t capacity)
            : data_(initial_data_), len_(0), capacity_(kInitialCapacity) {
        if (capacity > capacity_) {
            data_ = reinterpret_cast<uint8_t*>(Allocator::alloc(capacity));
            capacity_ = capacity;
        }
        ASAN_POISON_MEMORY_REGION(data_, capacity_);
    }

    ~faststring() {
        ASAN_UNPOISON_MEMORY_REGION(initial_data_, arraysize(initial_data_));
        if (data_ != initial_data_) {
            Allocator::free(data_, capacity_);
        }
    }

    // Reset the valid length of the string to 0.
    //
    // This does not free up any memory. The capacity of the string remains unchanged.
    void clear() {
        resize(0);
        ASAN_POISON_MEMORY_REGION(data_, capacity_);
    }

    // Resize the string to the given length.
    // If the new length is larger than the old length, the capacity is expanded as necessary.
    //
    // NOTE: in contrast to std::string's implementation, Any newly "exposed" bytes of data are
    // not cleared.
    void resize(size_t newsize) {
        if (newsize > capacity_) {
            reserve(newsize);
        }
        len_ = newsize;
        ASAN_POISON_MEMORY_REGION(data_ + len_, capacity_ - len_);
        ASAN_UNPOISON_MEMORY_REGION(data_, len_);
    }

    // Return the buffer built so far and reset `this` to the initial status (size() == 0).
    // NOTE: the returned data pointer is not necessarily the pointer returned by data()
    OwnedSlice build() {
        uint8_t* ret = data_;
        if (ret == initial_data_) {
            ret = reinterpret_cast<uint8_t*>(Allocator::alloc(capacity_));
            DCHECK(len_ <= capacity_);
            memcpy(ret, data_, len_);
        }
        OwnedSlice result(ret, len_, capacity_);
        len_ = 0;
        capacity_ = kInitialCapacity;
        data_ = initial_data_;
        ASAN_POISON_MEMORY_REGION(data_, capacity_);
        return result;
    }

    // Reserve space for the given total amount of data. If the current capacity is already
    // larger than the newly requested capacity, this is a no-op (i.e. it does not ever free memory).
    //
    // NOTE: even though the new capacity is reserved, it is illegal to begin writing into that memory
    // directly using pointers. If ASAN is enabled, this is ensured using manual memory poisoning.
    void reserve(size_t newcapacity) {
        if (PREDICT_TRUE(newcapacity <= capacity_)) return;
        GrowArray(newcapacity);
    }

    // Append the given data to the string, resizing capacity as necessary.
    void append(const void* src_v, size_t count) {
        const uint8_t* src = reinterpret_cast<const uint8_t*>(src_v);
        EnsureRoomForAppend(count);
        ASAN_UNPOISON_MEMORY_REGION(data_ + len_, count);

        // appending short values is common enough that this
        // actually helps, according to benchmarks. In theory
        // memcpy_inlined should already be just as good, but this
        // was ~20% faster for reading a large prefix-coded string file
        // where each string was only a few chars different
        if (count <= 4) {
            uint8_t* p = &data_[len_];
            for (int i = 0; i < count; i++) {
                *p++ = *src++;
            }
        } else {
            memcpy_inlined(&data_[len_], src, count);
        }
        len_ += count;
    }

    // Append the given string to this string.
    void append(const std::string& str) { append(str.data(), str.size()); }

    // Append the given character to this string.
    void push_back(const char byte) {
        EnsureRoomForAppend(1);
        ASAN_UNPOISON_MEMORY_REGION(data_ + len_, 1);
        data_[len_] = byte;
        len_++;
    }

    // Return the valid length of this string.
    size_t length() const { return len_; }

    // Return the valid length of this string (identical to length())
    size_t size() const { return len_; }

    // Return the allocated capacity of this string.
    size_t capacity() const { return capacity_; }

    // Return a pointer to the data in this string. Note that this pointer
    // may be invalidated by any later non-const operation.
    const uint8_t* data() const { return &data_[0]; }

    // Return a pointer to the data in this string. Note that this pointer
    // may be invalidated by any later non-const operation.
    uint8_t* data() { return &data_[0]; }

    // Return the given element of this string. Note that this does not perform
    // any bounds checking.
    const uint8_t& at(size_t i) const { return data_[i]; }

    // Return the given element of this string. Note that this does not perform
    // any bounds checking.
    const uint8_t& operator[](size_t i) const { return data_[i]; }

    // Return the given element of this string. Note that this does not perform
    // any bounds checking.
    uint8_t& operator[](size_t i) { return data_[i]; }

    // Reset the contents of this string by copying 'len' bytes from 'src'.
    void assign_copy(const uint8_t* src, size_t len) {
        // Reset length so that the first resize doesn't need to copy the current
        // contents of the array.
        len_ = 0;
        resize(len);
        memcpy(data(), src, len);
    }

    // Reset the contents of this string by copying from the given std::string.
    void assign_copy(const std::string& str) {
        assign_copy(reinterpret_cast<const uint8_t*>(str.c_str()), str.size());
    }

    // Reallocates the internal storage to fit only the current data.
    //
    // This may revert to using internal storage if the current length is shorter than
    // kInitialCapacity. In that case, after this call, capacity() will go down to
    // kInitialCapacity.
    //
    // Any pointers within this instance may be invalidated.
    void shrink_to_fit() {
        if (data_ == initial_data_ || capacity_ == len_) return;
        ShrinkToFitInternal();
    }

    // Return a copy of this string as a std::string.
    std::string ToString() const {
        return std::string(reinterpret_cast<const char*>(data()), len_);
    }

private:
    DISALLOW_COPY_AND_ASSIGN(faststring);

    // If necessary, expand the buffer to fit at least 'count' more bytes.
    // If the array has to be grown, it is grown by at least 50%.
    void EnsureRoomForAppend(size_t count) {
        if (PREDICT_TRUE(len_ + count <= capacity_)) {
            return;
        }

        // Call the non-inline slow path - this reduces the number of instructions
        // on the hot path.
        GrowToAtLeast(len_ + count);
    }

    // The slow path of EnsureRoomForAppend. Grows the buffer by either
    // 'count' bytes, or 50%, whichever is more.
    void GrowToAtLeast(size_t newcapacity);

    // Grow the array to the given capacity, which must be more than
    // the current capacity.
    void GrowArray(size_t newcapacity);

    void ShrinkToFitInternal();

    uint8_t* data_ = nullptr;
    uint8_t initial_data_[kInitialCapacity];
    size_t len_;
    // NOTE: we will make a initial buffer as part of the object, so the smallest
    // possible value of capacity_ is kInitialCapacity.
    size_t capacity_;
};

} // namespace doris

Coverage Report

Created: 2024-11-18 11:49

Line	Count	Source (jump to first uncovered line)
1		// Licensed to the Apache Software Foundation (ASF) under one
2		// or more contributor license agreements. See the NOTICE file
3		// distributed with this work for additional information
4		// regarding copyright ownership. The ASF licenses this file
5		// to you under the Apache License, Version 2.0 (the
6		// "License"); you may not use this file except in compliance
7		// with the License. You may obtain a copy of the License at
8		//
9		// http://www.apache.org/licenses/LICENSE-2.0
10		//
11		// Unless required by applicable law or agreed to in writing,
12		// software distributed under the License is distributed on an
13		// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
14		// KIND, either express or implied. See the License for the
15		// specific language governing permissions and limitations
16		// under the License.
17
18		#pragma once
19
20		#include <butil/macros.h>
21
22		#include <cstdint>
23		#include <cstring>
24		#include <string>
25
26		#include "gutil/dynamic_annotations.h"
27		#include "gutil/port.h"
28		#include "util/memcpy_inlined.h"
29		#include "util/slice.h"
30		#include "vec/common/allocator.h"
31
32		namespace doris {
33
34		// A faststring is similar to a std::string, except that it is faster for many
35		// common use cases (in particular, resize() will fill with uninitialized data
36		// instead of memsetting to \0)
37		// only build() can transfer data to the outside.
38		class faststring : private Allocator<false, false, false, DefaultMemoryAllocator> {
39		public:
40		enum { kInitialCapacity = 32 };
41
42	118k	faststring() : data_(initial_data_), len_(0), capacity_(kInitialCapacity) {}
43
44		// Construct a string with the given capacity, in bytes.
45		explicit faststring(size_t capacity)
46	1.09k	: data_(initial_data_), len_(0), capacity_(kInitialCapacity) {
47	1.09k	if (capacity > capacity_) {
48	640	data_ = reinterpret_cast<uint8_t*>(Allocator::alloc(capacity));
49	640	capacity_ = capacity;
50	640	}
51	1.09k	ASAN_POISON_MEMORY_REGION(data_, capacity_);
52	1.09k	}
53
54	119k	~faststring() {
55	119k	ASAN_UNPOISON_MEMORY_REGION(initial_data_, arraysize(initial_data_));
56	119k	if (data_ != initial_data_) {
57	28.2k	Allocator::free(data_, capacity_);
58	28.2k	}
59	119k	}
60
61		// Reset the valid length of the string to 0.
62		//
63		// This does not free up any memory. The capacity of the string remains unchanged.
64	339k	void clear() {
65	339k	resize(0);
66	339k	ASAN_POISON_MEMORY_REGION(data_, capacity_);
67	339k	}
68
69		// Resize the string to the given length.
70		// If the new length is larger than the old length, the capacity is expanded as necessary.
71		//
72		// NOTE: in contrast to std::string's implementation, Any newly "exposed" bytes of data are
73		// not cleared.
74	1.48M	void resize(size_t newsize) {
75	1.48M	if (newsize > capacity_) {
76	22.5k	reserve(newsize);
77	22.5k	}
78	1.48M	len_ = newsize;
79	1.48M	ASAN_POISON_MEMORY_REGION(data_ + len_, capacity_ - len_);
80	1.48M	ASAN_UNPOISON_MEMORY_REGION(data_, len_);
81	1.48M	}
82
83		// Return the buffer built so far and reset `this` to the initial status (size() == 0).
84		// NOTE: the returned data pointer is not necessarily the pointer returned by data()
85	26.4k	OwnedSlice build() {
86	26.4k	uint8_t* ret = data_;
87	26.4k	if (ret == initial_data_) {
88	31	ret = reinterpret_cast<uint8_t*>(Allocator::alloc(capacity_));
89	31	DCHECK(len_ <= capacity_);
90	31	memcpy(ret, data_, len_);
91	31	}
92	26.4k	OwnedSlice result(ret, len_, capacity_);
93	26.4k	len_ = 0;
94	26.4k	capacity_ = kInitialCapacity;
95	26.4k	data_ = initial_data_;
96	26.4k	ASAN_POISON_MEMORY_REGION(data_, capacity_);
97	26.4k	return result;
98	26.4k	}
99
100		// Reserve space for the given total amount of data. If the current capacity is already
101		// larger than the newly requested capacity, this is a no-op (i.e. it does not ever free memory).
102		//
103		// NOTE: even though the new capacity is reserved, it is illegal to begin writing into that memory
104		// directly using pointers. If ASAN is enabled, this is ensured using manual memory poisoning.
105	358k	void reserve(size_t newcapacity) {
106	358k	if (PREDICT_TRUE(newcapacity <= capacity_)) return;
107	95.7k	GrowArray(newcapacity);
108	95.7k	}
109
110		// Append the given data to the string, resizing capacity as necessary.
111	1.15M	void append(const void* src_v, size_t count) {
112	1.15M	const uint8_t* src = reinterpret_cast<const uint8_t*>(src_v);
113	1.15M	EnsureRoomForAppend(count);
114	1.15M	ASAN_UNPOISON_MEMORY_REGION(data_ + len_, count);
115
116		// appending short values is common enough that this
117		// actually helps, according to benchmarks. In theory
118		// memcpy_inlined should already be just as good, but this
119		// was ~20% faster for reading a large prefix-coded string file
120		// where each string was only a few chars different
121	1.15M	if (count <= 4) {
122	519k	uint8_t* p = &data_[len_];
123	1.46M	for (int i = 0; i < count; i++) {
124	947k	p++ = src++;
125	947k	}
126	630k	} else {
127	630k	memcpy_inlined(&data_[len_], src, count);
128	630k	}
129	1.15M	len_ += count;
130	1.15M	}
131
132		// Append the given string to this string.
133	8	void append(const std::string& str) { append(str.data(), str.size()); }
134
135		// Append the given character to this string.
136	10.8k	void push_back(const char byte) {
137	10.8k	EnsureRoomForAppend(1);
138	10.8k	ASAN_UNPOISON_MEMORY_REGION(data_ + len_, 1);
139	10.8k	data_[len_] = byte;
140	10.8k	len_++;
141	10.8k	}
142
143		// Return the valid length of this string.
144	14	size_t length() const { return len_; }
145
146		// Return the valid length of this string (identical to length())
147	1.40M	size_t size() const { return len_; }
148
149		// Return the allocated capacity of this string.
150	293k	size_t capacity() const { return capacity_; }
151
152		// Return a pointer to the data in this string. Note that this pointer
153		// may be invalidated by any later non-const operation.
154	126k	const uint8_t* data() const { return &data_[0]; }
155
156		// Return a pointer to the data in this string. Note that this pointer
157		// may be invalidated by any later non-const operation.
158	551k	uint8_t* data() { return &data_[0]; }
159
160		// Return the given element of this string. Note that this does not perform
161		// any bounds checking.
162	0	const uint8_t& at(size_t i) const { return data_[i]; }
163
164		// Return the given element of this string. Note that this does not perform
165		// any bounds checking.
166	42.4k	const uint8_t& operator[](size_t i) const { return data_[i]; }
167
168		// Return the given element of this string. Note that this does not perform
169		// any bounds checking.
170	797k	uint8_t& operator[](size_t i) { return data_[i]; }
171
172		// Reset the contents of this string by copying 'len' bytes from 'src'.
173	31.6k	void assign_copy(const uint8_t* src, size_t len) {
174		// Reset length so that the first resize doesn't need to copy the current
175		// contents of the array.
176	31.6k	len_ = 0;
177	31.6k	resize(len);
178	31.6k	memcpy(data(), src, len);
179	31.6k	}
180
181		// Reset the contents of this string by copying from the given std::string.
182	0	void assign_copy(const std::string& str) {
183	0	assign_copy(reinterpret_cast<const uint8_t*>(str.c_str()), str.size());
184	0	}
185
186		// Reallocates the internal storage to fit only the current data.
187		//
188		// This may revert to using internal storage if the current length is shorter than
189		// kInitialCapacity. In that case, after this call, capacity() will go down to
190		// kInitialCapacity.
191		//
192		// Any pointers within this instance may be invalidated.
193	102	void shrink_to_fit() {
194	102	if (data_ == initial_data_ \|\| capacity_ == len_) return;
195	40	ShrinkToFitInternal();
196	40	}
197
198		// Return a copy of this string as a std::string.
199	0	std::string ToString() const {
200	0	return std::string(reinterpret_cast<const char*>(data()), len_);
201	0	}
202
203		private:
204		DISALLOW_COPY_AND_ASSIGN(faststring);
205
206		// If necessary, expand the buffer to fit at least 'count' more bytes.
207		// If the array has to be grown, it is grown by at least 50%.
208	1.16M	void EnsureRoomForAppend(size_t count) {
209	1.16M	if (PREDICT_TRUE(len_ + count <= capacity_)) {
210	1.15M	return;
211	1.15M	}
212
213		// Call the non-inline slow path - this reduces the number of instructions
214		// on the hot path.
215	2.12k	GrowToAtLeast(len_ + count);
216	2.12k	}
217
218		// The slow path of EnsureRoomForAppend. Grows the buffer by either
219		// 'count' bytes, or 50%, whichever is more.
220		void GrowToAtLeast(size_t newcapacity);
221
222		// Grow the array to the given capacity, which must be more than
223		// the current capacity.
224		void GrowArray(size_t newcapacity);
225
226		void ShrinkToFitInternal();
227
228		uint8_t* data_ = nullptr;
229		uint8_t initial_data_[kInitialCapacity];
230		size_t len_;
231		// NOTE: we will make a initial buffer as part of the object, so the smallest
232		// possible value of capacity_ is kInitialCapacity.
233		size_t capacity_;
234		};
235
236		} // namespace doris