Skip to content

simo7/parquet-go

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

parquet-go


parquet-go is an implementation of the Apache Parquet file format in Go. It provides functionality to both read and write parquet files, as well as high-level functionality to manage the data schema of parquet files, to directly write Go objects to parquet files using automatic or custom marshalling and to read records from parquet files into Go objects using automatic or custom marshalling.

parquet is a file format to store nested data structures in a flat columnar format. By storing in a column-oriented way, it allows for efficient reading of individual columns without having to read and decode complete rows. This allows for efficient reading and faster processing when using the file format in conjunction with distributed data processing frameworks like Apache Hadoop or distributed SQL query engines like Presto and AWS Athena.

This implementation is divided into several packages. The top-level package is the low-level implementation of the parquet file format. It is accompanied by the sub-packages parquetschema and floor. parquetschema provides functionality to parse textual schema definitions as well as the data types to manually or programmatically construct schema definitions. floor is a high-level wrapper around the low-level package. It provides functionality to open parquet files to read from them or write to them using automated or custom marshalling and unmarshalling.

Supported Features

Feature Read Write Note
Compression Yes Yes Only Gzip and SNAPPY are supported out of the box, but it is possible to add other compressors, see the RegisterBlockCompressor function
Dictionary Encoding Yes Yes
Run Length Encoding / Bit-Packing Hybrid Yes Yes The reader can read RLE/Bit-pack encoding, but the writer only uses bit-packing
Delta Encoding Yes Yes
Byte Stream Split No No
Data page V1 Yes Yes
Data page V2 Yes Yes
Statistics in page meta data No No
Index Pages No No
Dictionary Pages Yes Yes
Encryption No No
Bloom Filter No No
Logical Types Yes Yes Support for logical type is in the high-level package (floor) the low level parquet library only supports the basic types, see the type mapping table

Supported Data Types

Type in parquet Type in Go Note
boolean bool
int32 int32 See the note about the int type
int64 int64 See the note about the int type
int96 [12]byte
float float32
double float64
byte_array []byte
fixed_len_byte_array(N) [N]byte, []byte use any positive number for N

Note: the low-level implementation only supports int32 for the INT32 type and int64 for the INT64 type in Parquet. Plain int or uint are not supported. The high-level floor package contains more extensive support for these data types.

Supported Logical Types

Logical Type Mapped to Go types Note
STRING string, []byte
DATE int32, time.Time int32: days since Unix epoch (Jan 01 1970 00:00:00 UTC); time.Time only in floor
TIME int32, int64, time.Time int32: TIME(MILLIS, ...), int64: TIME(MICROS, ...), TIME(NANOS, ...); time.Time only in floor
TIMESTAMP int64, int96, time.Time time.Time only in floor
UUID [16]byte
LIST []T slices of any type
MAP map[T1]T2 maps with any key and value types
ENUM string, []byte
BSON []byte
DECIMAL []byte, [N]byte
INT {,u}int{8,16,32,64} implementation is loose and will allow any INT logical type converted to any signed or unsigned int Go type.

Supported Converted Types

Converted Type Mapped to Go types Note
UTF8 string, []byte
TIME_MILLIS int32 Number of milliseconds since the beginning of the day
TIME_MICROS int64 Number of microseconds since the beginning of the day
TIMESTAMP_MILLIS int64 Number of milliseconds since Unix epoch (Jan 01 1970 00:00:00 UTC)
TIMESTAMP_MICROS int64 Number of milliseconds since Unix epoch (Jan 01 1970 00:00:00 UTC)
{,U}INT_{8,16,32,64} {,u}int{8,16,32,64} implementation is loose and will allow any converted type with any int Go type.
INTERVAL [12]byte

Please note that converted types are deprecated. Logical types should be used preferably.

Schema Definition

parquet-go comes with support for textual schema definitions. The sub-package parquetschema comes with a parser to turn the textual schema definition into the right data type to use elsewhere to specify parquet schemas. The syntax has been mostly reverse-engineered from a similar format also supported but barely documented in Parquet's Java implementation.

For the full syntax, please have a look at the parquetschema package Go documentation.

Generally, the schema definition describes the structure of a message. Parquet will then flatten this into a purely column-based structure when writing the actual data to parquet files.

A message consists of a number of fields. Each field either has type or is a group. A group itself consists of a number of fields, which in turn can have either a type or are a group themselves. This allows for theoretically unlimited levels of hierarchy.

Each field has a repetition type, describing whether a field is required (i.e. a value has to be present), optional (i.e. a value can be present but doesn't have to be) or repeated (i.e. zero or more values can be present). Optionally, each field (including groups) have an annotation, which contains a logical type or converted type that annotates something about the general structure at this point, e.g. LIST indicates a more complex list structure, or MAP a key-value map structure, both following certain conventions. Optionally, a typed field can also have a numeric field ID. The field ID has no purpose intrinsic to the parquet file format.

Here is a simple example of a message with a few typed fields:

message coordinates {
    required float64 latitude;
    required float64 longitude;
    optional int32 elevation = 1;
    optional binary comment (STRING);
}

In this example, we have a message with four typed fields, two of them required, and two of them optional. float64, int32 and binary describe the fundamental data type of the field, while longitude, latitude, elevation and comment are the field names. The parentheses contain an annotation STRING which indicates that the field is a string, encoded as binary data, i.e. a byte array. The field elevation also has a field ID of 1, indicated as numeric literal and separated from the field name by the equal sign =.

In the following example, we will introduce a plain group as well as two nested groups annotated with logical types to indicate certain data structures:

message transaction {
    required fixed_len_byte_array(16) txn_id (UUID);
    required int32 amount;
    required int96 txn_ts;
    optional group attributes {
        optional int64 shop_id;
        optional binary country_code (STRING);
        optional binary postcode (STRING);
    }
    required group items (LIST) {
        repeated group list {
            required int64 item_id;
            optional binary name (STRING);
        }
    }
    optional group user_attributes (MAP) {
        repeated group key_value {
            required binary key (STRING);
            required binary value (STRING);
        }
    }
}

In this example, we see a number of top-level fields, some of which are groups. The first group is simply a group of typed fields, named attributes.

The second group, items is annotated to be a LIST and in turn contains a repeated group list, which in turn contains a number of typed fields. When a group is annotated as LIST, it needs to follow a particular convention: it has to contain a repeated group named list. Inside this group, any fields can be present.

The third group, user_attributes is annotated as MAP. Similar to LIST, it follows some conventions. In particular, it has to contain only a single required group with the name key_value, which in turn contains exactly two fields, one named key, the other named value. This represents a map structure in which each key is associated with one value.

Contributing

If you want to hack on this repository, please read the short CONTRIBUTING.md guide first.

Versioning

We use SemVer for versioning. For the versions available, see the tags on this repository.

Authors

See also the list of contributors who participated in this project.

License

Copyright 2020 Fraugster GmbH

This project is licensed under the Apache-2 License - see the LICENSE file for details.

This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.