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Merge Bolt PrimitiveEncoder into BaseEncoder

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Summary: This diff undoes the changes made in D925

Reviewers: teon.banek

Reviewed By: teon.banek

Subscribers: pullbot

Differential Revision: https://phabricator.memgraph.io/D1614
This commit is contained in:
Matej Ferencevic 2018-09-26 14:23:08 +02:00
parent 91566bb9fc
commit 10556f0d3d
2 changed files with 128 additions and 150 deletions
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178
src/communication/bolt/v1/encoder/base_encoder.hpp
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@ -1,125 +1,193 @@
#pragma once #pragma once
#include "communication/bolt/v1/encoder/primitive_encoder.hpp" #include <experimental/type_traits>
#include "communication/bolt/v1/codes.hpp"
#include "communication/bolt/v1/value.hpp" #include "communication/bolt/v1/value.hpp"
#include "utils/bswap.hpp"
#include "utils/cast.hpp"
static_assert(std::experimental::is_same_v<std::uint8_t, char> ||
std::experimental::is_same_v<std::uint8_t, unsigned char>,
"communication::bolt::Encoder requires uint8_t to be "
"implemented as char or unsigned char.");
namespace communication::bolt { namespace communication::bolt {
/** /**
* Bolt BaseEncoder. Subclass of PrimitiveEncoder. Extends it with the * Bolt BaseEncoder. Has public interfaces for writing Bolt encoded data.
* capability to encode Values (as well as lists and maps of Values), Edges, * Supported types are: Null, Bool, Int, Double, String, List, Map, Vertex, Edge
* Vertices and Paths. *
* The purpose of this class is to stream bolt data into the given Buffer.
* *
* @tparam Buffer the output buffer that should be used * @tparam Buffer the output buffer that should be used
*/ */
template <typename Buffer> template <typename Buffer>
class BaseEncoder : public PrimitiveEncoder<Buffer> { class BaseEncoder {
public: public:
explicit BaseEncoder(Buffer &buffer) : PrimitiveEncoder<Buffer>(buffer) {} explicit BaseEncoder(Buffer &buffer) : buffer_(buffer) {}
void WriteRAW(const uint8_t *data, uint64_t len) { buffer_.Write(data, len); }
void WriteRAW(const char *data, uint64_t len) {
WriteRAW((const uint8_t *)data, len);
}
void WriteRAW(const uint8_t data) { WriteRAW(&data, 1); }
void WriteNull() { WriteRAW(utils::UnderlyingCast(Marker::Null)); }
void WriteBool(const bool &value) {
if (value)
WriteRAW(utils::UnderlyingCast(Marker::True));
else
WriteRAW(utils::UnderlyingCast(Marker::False));
}
void WriteInt(const int64_t &value) {
if (value >= -16L && value < 128L) {
WriteRAW(static_cast<uint8_t>(value));
} else if (value >= -128L && value < -16L) {
WriteRAW(utils::UnderlyingCast(Marker::Int8));
WriteRAW(static_cast<uint8_t>(value));
} else if (value >= -32768L && value < 32768L) {
WriteRAW(utils::UnderlyingCast(Marker::Int16));
WritePrimitiveValue(static_cast<int16_t>(value));
} else if (value >= -2147483648L && value < 2147483648L) {
WriteRAW(utils::UnderlyingCast(Marker::Int32));
WritePrimitiveValue(static_cast<int32_t>(value));
} else {
WriteRAW(utils::UnderlyingCast(Marker::Int64));
WritePrimitiveValue(value);
}
}
void WriteDouble(const double &value) {
WriteRAW(utils::UnderlyingCast(Marker::Float64));
uint64_t tmp = utils::MemcpyCast<uint64_t>(value);
WritePrimitiveValue(tmp);
}
void WriteTypeSize(const size_t size, const uint8_t typ) {
if (size <= 15) {
uint8_t len = size;
len &= 0x0F;
WriteRAW(utils::UnderlyingCast(MarkerTiny[typ]) + len);
} else if (size <= 255) {
uint8_t len = size;
WriteRAW(utils::UnderlyingCast(Marker8[typ]));
WriteRAW(len);
} else if (size <= 65535) {
uint16_t len = size;
WriteRAW(utils::UnderlyingCast(Marker16[typ]));
WritePrimitiveValue(len);
} else {
uint32_t len = size;
WriteRAW(utils::UnderlyingCast(Marker32[typ]));
WritePrimitiveValue(len);
}
}
void WriteString(const std::string &value) {
WriteTypeSize(value.size(), MarkerString);
WriteRAW(value.c_str(), value.size());
}
void WriteList(const std::vector<Value> &value) { void WriteList(const std::vector<Value> &value) {
this->WriteTypeSize(value.size(), MarkerList); WriteTypeSize(value.size(), MarkerList);
for (auto &x : value) WriteValue(x); for (auto &x : value) WriteValue(x);
} }
/** void WriteMap(const std::map<std::string, Value> &value) {
* Writes a map value. WriteTypeSize(value.size(), MarkerMap);
*
* @tparam TMap - an iterable of (std::string, Value) pairs.
*/
template <typename TMap>
void WriteMap(const TMap &value) {
this->WriteTypeSize(value.size(), MarkerMap);
for (auto &x : value) { for (auto &x : value) {
this->WriteString(x.first); WriteString(x.first);
WriteValue(x.second); WriteValue(x.second);
} }
} }
void WriteVertex(const Vertex &vertex) { void WriteVertex(const Vertex &vertex) {
this->WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + 3); WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + 3);
this->WriteRAW(utils::UnderlyingCast(Signature::Node)); WriteRAW(utils::UnderlyingCast(Signature::Node));
this->WriteInt(vertex.id.AsInt()); WriteInt(vertex.id.AsInt());
// write labels // write labels
const auto &labels = vertex.labels; const auto &labels = vertex.labels;
this->WriteTypeSize(labels.size(), MarkerList); WriteTypeSize(labels.size(), MarkerList);
for (const auto &label : labels) this->WriteString(label); for (const auto &label : labels) WriteString(label);
// write properties // write properties
const auto &props = vertex.properties; const auto &props = vertex.properties;
this->WriteTypeSize(props.size(), MarkerMap); WriteTypeSize(props.size(), MarkerMap);
for (const auto &prop : props) { for (const auto &prop : props) {
this->WriteString(prop.first); WriteString(prop.first);
WriteValue(prop.second); WriteValue(prop.second);
} }
} }
void WriteEdge(const Edge &edge, bool unbound = false) { void WriteEdge(const Edge &edge, bool unbound = false) {
this->WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + (unbound ? 3 : 5));
(unbound ? 3 : 5)); WriteRAW(utils::UnderlyingCast(unbound ? Signature::UnboundRelationship
this->WriteRAW(utils::UnderlyingCast( : Signature::Relationship));
unbound ? Signature::UnboundRelationship : Signature::Relationship));
this->WriteInt(edge.id.AsInt()); WriteInt(edge.id.AsInt());
if (!unbound) { if (!unbound) {
this->WriteInt(edge.from.AsInt()); WriteInt(edge.from.AsInt());
this->WriteInt(edge.to.AsInt()); WriteInt(edge.to.AsInt());
} }
this->WriteString(edge.type); WriteString(edge.type);
const auto &props = edge.properties; const auto &props = edge.properties;
this->WriteTypeSize(props.size(), MarkerMap); WriteTypeSize(props.size(), MarkerMap);
for (const auto &prop : props) { for (const auto &prop : props) {
this->WriteString(prop.first); WriteString(prop.first);
WriteValue(prop.second); WriteValue(prop.second);
} }
} }
void WriteEdge(const UnboundedEdge &edge) { void WriteEdge(const UnboundedEdge &edge) {
this->WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + 3); WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + 3);
this->WriteRAW(utils::UnderlyingCast(Signature::UnboundRelationship)); WriteRAW(utils::UnderlyingCast(Signature::UnboundRelationship));
this->WriteInt(edge.id.AsInt()); WriteInt(edge.id.AsInt());
this->WriteString(edge.type); WriteString(edge.type);
const auto &props = edge.properties; const auto &props = edge.properties;
this->WriteTypeSize(props.size(), MarkerMap); WriteTypeSize(props.size(), MarkerMap);
for (const auto &prop : props) { for (const auto &prop : props) {
this->WriteString(prop.first); WriteString(prop.first);
WriteValue(prop.second); WriteValue(prop.second);
} }
} }
void WritePath(const Path &path) { void WritePath(const Path &path) {
this->WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + 3); WriteRAW(utils::UnderlyingCast(Marker::TinyStruct) + 3);
this->WriteRAW(utils::UnderlyingCast(Signature::Path)); WriteRAW(utils::UnderlyingCast(Signature::Path));
this->WriteTypeSize(path.vertices.size(), MarkerList); WriteTypeSize(path.vertices.size(), MarkerList);
for (auto &v : path.vertices) WriteVertex(v); for (auto &v : path.vertices) WriteVertex(v);
this->WriteTypeSize(path.edges.size(), MarkerList); WriteTypeSize(path.edges.size(), MarkerList);
for (auto &e : path.edges) WriteEdge(e); for (auto &e : path.edges) WriteEdge(e);
this->WriteTypeSize(path.indices.size(), MarkerList); WriteTypeSize(path.indices.size(), MarkerList);
for (auto &i : path.indices) this->WriteInt(i); for (auto &i : path.indices) WriteInt(i);
} }
void WriteValue(const Value &value) { void WriteValue(const Value &value) {
switch (value.type()) { switch (value.type()) {
case Value::Type::Null: case Value::Type::Null:
this->WriteNull(); WriteNull();
break; break;
case Value::Type::Bool: case Value::Type::Bool:
this->WriteBool(value.ValueBool()); WriteBool(value.ValueBool());
break; break;
case Value::Type::Int: case Value::Type::Int:
this->WriteInt(value.ValueInt()); WriteInt(value.ValueInt());
break; break;
case Value::Type::Double: case Value::Type::Double:
this->WriteDouble(value.ValueDouble()); WriteDouble(value.ValueDouble());
break; break;
case Value::Type::String: case Value::Type::String:
this->WriteString(value.ValueString()); WriteString(value.ValueString());
break; break;
case Value::Type::List: case Value::Type::List:
WriteList(value.ValueList()); WriteList(value.ValueList());
@ -141,6 +209,16 @@ class BaseEncoder : public PrimitiveEncoder<Buffer> {
break; break;
} }
} }
protected:
Buffer &buffer_;
private:
template <class T>
void WritePrimitiveValue(T value) {
value = utils::Bswap(value);
WriteRAW(reinterpret_cast<const uint8_t *>(&value), sizeof(value));
}
}; };
} // namespace communication::bolt } // namespace communication::bolt

100
src/communication/bolt/v1/encoder/primitive_encoder.hpp
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@ -1,100 +0,0 @@
#pragma once
#include <string>
#include "communication/bolt/v1/codes.hpp"
#include "utils/bswap.hpp"
#include "utils/cast.hpp"
namespace communication::bolt {
/**
* Bolt PrimitiveEncoder. Has public interfaces for writing Bolt encoded data.
* Supported types are: Null, Bool, Int, Double and String.
*
* Bolt encoding is used both for streaming data to network clients and for
* database durability.
*
* @tparam Buffer the output buffer that should be used
*/
template <typename Buffer>
class PrimitiveEncoder {
public:
explicit PrimitiveEncoder(Buffer &buffer) : buffer_(buffer) {}
void WriteRAW(const uint8_t *data, uint64_t len) { buffer_.Write(data, len); }
void WriteRAW(const char *data, uint64_t len) {
WriteRAW((const uint8_t *)data, len);
}
void WriteRAW(const uint8_t data) { WriteRAW(&data, 1); }
template <class T>
void WriteValue(T value) {
value = utils::Bswap(value);
WriteRAW(reinterpret_cast<const uint8_t *>(&value), sizeof(value));
}
void WriteNull() { WriteRAW(utils::UnderlyingCast(Marker::Null)); }
void WriteBool(const bool &value) {
if (value)
WriteRAW(utils::UnderlyingCast(Marker::True));
else
WriteRAW(utils::UnderlyingCast(Marker::False));
}
void WriteInt(const int64_t &value) {
if (value >= -16L && value < 128L) {
WriteRAW(static_cast<uint8_t>(value));
} else if (value >= -128L && value < -16L) {
WriteRAW(utils::UnderlyingCast(Marker::Int8));
WriteRAW(static_cast<uint8_t>(value));
} else if (value >= -32768L && value < 32768L) {
WriteRAW(utils::UnderlyingCast(Marker::Int16));
WriteValue(static_cast<int16_t>(value));
} else if (value >= -2147483648L && value < 2147483648L) {
WriteRAW(utils::UnderlyingCast(Marker::Int32));
WriteValue(static_cast<int32_t>(value));
} else {
WriteRAW(utils::UnderlyingCast(Marker::Int64));
WriteValue(value);
}
}
void WriteDouble(const double &value) {
WriteRAW(utils::UnderlyingCast(Marker::Float64));
WriteValue(*reinterpret_cast<const int64_t *>(&value));
}
void WriteTypeSize(const size_t size, const uint8_t typ) {
if (size <= 15) {
uint8_t len = size;
len &= 0x0F;
WriteRAW(utils::UnderlyingCast(MarkerTiny[typ]) + len);
} else if (size <= 255) {
uint8_t len = size;
WriteRAW(utils::UnderlyingCast(Marker8[typ]));
WriteRAW(len);
} else if (size <= 65535) {
uint16_t len = size;
WriteRAW(utils::UnderlyingCast(Marker16[typ]));
WriteValue(len);
} else {
uint32_t len = size;
WriteRAW(utils::UnderlyingCast(Marker32[typ]));
WriteValue(len);
}
}
void WriteString(const std::string &value) {
WriteTypeSize(value.size(), MarkerString);
WriteRAW(value.c_str(), value.size());
}
protected:
Buffer &buffer_;
};
} // namespace communication::bolt