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LSST Data Management Base Package
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BaseTable.cc
Go to the documentation of this file.
1// -*- lsst-c++ -*-
2
3#include <memory>
4
5#include "boost/shared_ptr.hpp" // only for ndarray
6
13
14namespace lsst {
15namespace afw {
16namespace table {
17
18// =============== Block ====================================================================================
19
20// This is a block of memory that doles out record-sized chunks when a table asks for them.
21// It inherits from ndarray::Manager so we can return ndarrays that refer to the memory in the
22// block with correct reference counting (ndarray::Manager is just an empty base class with an
23// internal reference count - it's like a shared_ptr without the pointer and template parameter.
24//
25// Records are allocated in Blocks for two reasons:
26// - it allows tables to be either totally contiguous in memory (enabling column views) or
27// not (enabling dynamic addition of records) all in one class.
28// - it saves us from ever having to reallocate all the records associated with a table
29// when we run out of space (that's what a std::vector-like model would require). This keeps
30// records and/or iterators to them from being invalidated, and it keeps tables from having
31// to track all the records whose data it owns.
32
33namespace {
34
35class Block : public ndarray::Manager {
36public:
37 using Ptr = boost::intrusive_ptr<Block>;
38
39 // If the last chunk allocated isn't needed after all (usually because of an exception in a constructor)
40 // we reuse it immediately. If it wasn't the last chunk allocated, it can't be reclaimed until
41 // the entire block goes out of scope.
42 static void reclaim(std::size_t recordSize, void *data, ndarray::Manager::Ptr const &manager) {
43 Ptr block = boost::static_pointer_cast<Block>(manager);
44 if (reinterpret_cast<char *>(data) + recordSize == block->_next) {
45 block->_next -= recordSize;
46 }
47 }
48
49 // Ensure we have space for at least the given number of records as a contiguous block.
50 // May not actually allocate anything if we already do.
51 static void preallocate(std::size_t recordSize, std::size_t recordCount, ndarray::Manager::Ptr &manager) {
52 Ptr block = boost::static_pointer_cast<Block>(manager);
53 if (!block || static_cast<std::size_t>(block->_end - block->_next) < recordSize * recordCount) {
54 block = Ptr(new Block(recordSize, recordCount));
55 manager = block;
56 }
57 }
58
59 static std::size_t getBufferSize(std::size_t recordSize, ndarray::Manager::Ptr const &manager) {
60 Ptr block = boost::static_pointer_cast<Block>(manager);
61 return static_cast<std::size_t>(block->_end - block->_next) / recordSize;
62 }
63
64 // Get the next chunk from the block, making a new block and installing it into the table
65 // if we're all out of space.
66 static void *get(std::size_t recordSize, ndarray::Manager::Ptr &manager) {
67 Ptr block = boost::static_pointer_cast<Block>(manager);
68 if (!block || block->_next == block->_end) {
69 block = Ptr(new Block(recordSize, BaseTable::nRecordsPerBlock));
70 manager = block;
71 }
72 void *r = block->_next;
73 block->_next += recordSize;
74 return r;
75 }
76
77 // Block is also keeper of the special number that says what alignment boundaries are needed for
78 // schemas. Before we start using a schema, we need to first ensure it meets that requirement,
79 // and pad it if not.
80 static void padSchema(Schema &schema) {
81 static int const MIN_RECORD_ALIGN = sizeof(AllocType);
82 std::size_t remainder = schema.getRecordSize() % MIN_RECORD_ALIGN;
83 if (remainder) {
84 detail::Access::padSchema(schema, MIN_RECORD_ALIGN - remainder);
85 }
86 }
87
88private:
89 struct AllocType {
90 double element[2];
91 };
92
93 explicit Block(std::size_t recordSize, std::size_t recordCount)
94 : _mem(new AllocType[(recordSize * recordCount) / sizeof(AllocType)]),
95 _next(reinterpret_cast<char *>(_mem.get())),
96 _end(_next + recordSize * recordCount) {
97 assert((recordSize * recordCount) % sizeof(AllocType) == 0);
98 std::fill(_next, _end, 0); // initialize to zero; we'll later initialize floats to NaN.
99 }
100
102 char *_next;
103 char *_end;
104};
105
106} // namespace
107
108// =============== BaseTable implementation (see header for docs) ===========================================
109
110void BaseTable::preallocate(std::size_t n) { Block::preallocate(_schema.getRecordSize(), n, _manager); }
111
113 if (_manager) {
114 return Block::getBufferSize(_schema.getRecordSize(), _manager);
115 } else {
116 return 0;
117 }
118}
119
122}
123
125 return Schema();
126}
127
130 output->assign(input);
131 return output;
132}
133
136 output->assign(input, mapper);
137 return output;
138}
139
141 return std::make_shared<io::FitsWriter>(fitsfile, flags);
142}
143
145 return std::shared_ptr<BaseTable>(new BaseTable(*this));
146}
147
149 return constructRecord<BaseRecord>();
150}
151
153 Block::padSchema(_schema);
154 _schema.disconnectAliases();
155 _schema.getAliasMap()->_table = this;
156}
157
158BaseTable::~BaseTable() { _schema.getAliasMap()->_table = nullptr; }
159
160namespace {
161
162// A Schema Functor used to set destroy variable-length array fields using an explicit call to their
163// destructor (necessary since we used placement new). All other fields are ignored, as they're POD.
164struct RecordDestroyer {
165 template <typename T>
166 void operator()(SchemaItem<T> const &item) const {}
167
168 template <typename T>
169 void operator()(SchemaItem<Array<T> > const &item) const {
170 using Element = ndarray::Array<T, 1, 1>;
171 if (item.key.isVariableLength()) {
172 (*reinterpret_cast<Element *>(data + item.key.getOffset())).~Element();
173 }
174 }
175
176 void operator()(SchemaItem<std::string> const &item) const {
177 if (item.key.isVariableLength()) {
178 using std::string; // invoking the destructor on a qualified name doesn't compile in gcc 4.8.1
179 // https://stackoverflow.com/q/24593942
180 (*reinterpret_cast<string *>(data + item.key.getOffset())).~string();
181 }
182 }
183
184 char *data;
185};
186
187} // namespace
188
189detail::RecordData BaseTable::_makeNewRecordData() {
190 auto data = Block::get(_schema.getRecordSize(), _manager);
191 return detail::RecordData{
192 data,
194 _manager // manager always points to the most recently-used block.
195 };
196}
197
198void BaseTable::_destroy(BaseRecord &record) {
199 assert(record._table.get() == this);
200 RecordDestroyer f = {reinterpret_cast<char *>(record._data)};
201 _schema.forEach(f);
202 if (record._manager == _manager) Block::reclaim(_schema.getRecordSize(), record._data, _manager);
203}
204
205/*
206 * JFB has no idea whether the default value below is sensible, or even whether
207 * it should be expressed ultimately as an approximate size in bytes rather than a
208 * number of records; the answer probably depends on both the typical size of
209 * records and the typical number of records.
210 */
212
213// =============== BaseCatalog instantiation =================================================================
214
215template class CatalogT<BaseRecord>;
216template class CatalogT<BaseRecord const>;
217} // namespace table
218} // namespace afw
219} // namespace lsst
char * data
Definition: BaseRecord.cc:61
double element[2]
Definition: BaseTable.cc:90
SchemaMapper * mapper
Definition: SchemaMapper.cc:71
table::Schema schema
Definition: python.h:134
A simple struct that combines the two arguments that must be passed to most cfitsio routines and cont...
Definition: fits.h:308
Base class for all records.
Definition: BaseRecord.h:31
Base class for all tables.
Definition: BaseTable.h:61
virtual std::shared_ptr< BaseRecord > _makeRecord()
Default-construct an associated record (protected implementation).
Definition: BaseTable.cc:148
virtual std::shared_ptr< io::FitsWriter > makeFitsWriter(fits::Fits *fitsfile, int flags) const
Definition: BaseTable.cc:140
void preallocate(std::size_t nRecords)
Allocate contiguous space for new records in advance.
Definition: BaseTable.cc:110
std::shared_ptr< BaseRecord > copyRecord(BaseRecord const &input)
Deep-copy a record, requiring that it have the same schema as this table.
Definition: BaseTable.cc:128
BaseTable(Schema const &schema)
Construct from a schema.
Definition: BaseTable.cc:152
std::size_t getBufferSize() const
Return the number of additional records space has been already been allocated for.
Definition: BaseTable.cc:112
static Schema makeMinimalSchema()
Return a minimal schema for Base tables and records.
Definition: BaseTable.cc:124
static int nRecordsPerBlock
Number of records in each memory block.
Definition: BaseTable.h:76
static std::shared_ptr< BaseTable > make(Schema const &schema)
Construct a new table.
Definition: BaseTable.cc:120
virtual std::shared_ptr< BaseTable > _clone() const
Clone implementation with noncovariant return types.
Definition: BaseTable.cc:144
std::shared_ptr< BaseRecord > makeRecord()
Default-construct an associated record.
Definition: BaseTable.h:108
Defines the fields and offsets for a table.
Definition: Schema.h:51
void forEach(F &func) const
Apply a functor to each SchemaItem in the Schema.
Definition: Schema.h:214
void disconnectAliases()
Sever the connection between this schema and any others with which it shares aliases.
Definition: Schema.cc:540
std::shared_ptr< AliasMap > getAliasMap() const
Return the map of aliases.
Definition: Schema.h:279
std::size_t getRecordSize() const
Return the raw size of a record in bytes.
Definition: Schema.h:149
A mapping between the keys of two Schemas, used to copy data between them.
Definition: SchemaMapper.h:21
static void padSchema(Schema &schema, std::size_t bytes)
Definition: Access.h:88
T fill(T... args)
T remainder(T... args)
A simple pair-like struct for mapping a Field (name and description) with a Key (used for actual data...
Definition: SchemaImpl.h:22