/bigquery-schema-generator

Generates the BigQuery schema from newline-delimited JSON or CSV data records.

Primary LanguagePythonApache License 2.0Apache-2.0

BigQuery Schema Generator

BigQuery Schema Generator CI

This script generates the BigQuery schema from the newline-delimited data records on the STDIN. The records can be in JSON format or CSV format. The BigQuery data importer (bq load) uses only the first 500 records when the schema auto-detection feature is enabled. In contrast, this script uses all data records to generate the schema.

Usage:

$ generate-schema < file.data.json > file.schema.json
$ generate-schema --input_format csv < file.data.csv > file.schema.json

Version: 1.5.1 (2022-12-04)

Changelog: CHANGELOG.md

Table of Contents

Background

Data can be imported into BigQuery using the bq command line tool. It accepts a number of data formats including CSV or newline-delimited JSON. The data can be loaded into an existing table or a new table can be created during the loading process. The structure of the table is defined by its schema. The table's schema can be defined manually or the schema can be auto-detected.

When the auto-detect feature is used, the BigQuery data importer examines only the first 500 records of the input data. In many cases, this is sufficient because the data records were dumped from another database and the exact schema of the source table was known. However, for data extracted from a service (e.g. using a REST API) the record fields could have been organically added at later dates. In this case, the first 500 records do not contain fields which are present in later records. The bq load auto-detection fails and the data fails to load.

The bq load tool does not support the ability to process the entire dataset to determine a more accurate schema. This script fills in that gap. It processes the entire dataset given in the STDIN and outputs the BigQuery schema in JSON format on the STDOUT. This schema file can be fed back into the bq load tool to create a table that is more compatible with the data fields in the input dataset.

Installation

Prerequisite: You need have Python 3.6 or higher.

Install from PyPI repository using pip3. There are too many ways to install packages in Python. The following are in order highest to lowest recommendation:

  1. If you are using a virtual environment (such as venv), then use:
$ pip3 install bigquery_schema_generator
  1. If you aren't using a virtual environment you can install into your local Python directory:
$ pip3 install --user bigquery_schema_generator
  1. If you want to install the package for your entire system globally, use
$ sudo -H pip3 install bigquery_schema_generator

but realize that you will be running code from PyPI as root so this has security implications.

Sometimes, your Python environment gets into a complete mess and the pip3 command won't work. Try typing python3 -m pip instead.

A successful install should print out something like the following (the version number may be different):

Collecting bigquery-schema-generator
Installing collected packages: bigquery-schema-generator
Successfully installed bigquery-schema-generator-1.1

The shell script generate-schema will be installed somewhere in your system, depending on how your Python environment is configured. See below for some notes for Ubuntu Linux and MacOS.

Ubuntu Linux (18.04, 20.04, 22.04)

After running pip3 install bigquery_schema_generator, the generate-schema script may be installed in one the following locations:

  • /usr/bin/generate-schema
  • /usr/local/bin/generate-schema
  • $HOME/.local/bin/generate-schema
  • $HOME/.virtualenvs/{your_virtual_env}/bin/generate-schema

MacOS

I don't have any Macs which are able to run the latest macOS, and I don't use them much for software development these days, but here are some notes on older versions of macOS in case they help.

MacOS 12 (Monterey)

Python 2 or 3 is not installed by default on Monterey. If you try to run python3 on the command line, a dialog box asks you to install the Xcode development package. It apparently takes over an hour at 10 MB/s.

You can instead install Python 3 using Homebrew, by installing brew, and typing $ brew install python. Currently, it downloads Python 3.10 in about 1-2 minutes and installs the python3 and pip3 binaries into /usr/local/bin/python3 and /usr/local/bin/pip3. Using brew seems to be easiest option, so let's assume that Python 3 was installed through that.

If you run:

$ pip3 install bigquery_schema_generator

the package will be installed at /usr/local/lib/python3.10/site-packages/, and the generate-schema script will be installed at /usr/local/bin/generate-schema.

If you use the --user flag:

$ pip3 install --user bigquery_schema_generator

the package will be installed at $HOME/Library/Python/3.10/lib/python/site-packages/, and the generate-schema script will be installed at $HOME/Library/Python/3.10/bin/generate-schema.

You may need to add the $HOME/Library/Python/3.10/bin directory to your $PATH variable in your $HOME/.bashrc file.

MacOS 11 (Big Sur)

Python 2.7.16 is installed by default on Big Sur as /usr/bin/python. If you try to run python3 on the command line, a dialog box asks you to install the Xcode development package will be installed, which I think installs Python 3.8 as /usr/bin/python3 (I can't remember, it was installed a long time ago.)

You can instead install Python 3 using Homebrew, by installing brew, and typing $ brew install python. Currently, it downloads Python 3.10 in about 1-2 minutes and installs the python3 and pip3 binaries into /usr/local/bin/python3 and /usr/local/bin/pip3. Using brew seems to be easiest option, so let's assume that Python 3 was installed through that.

If you run:

$ pip3 install bigquery_schema_generator

the package will be installed at /usr/local/lib/python3.10/site-packages/, and the generate-schema script will be installed at /usr/local/bin/generate-schema.

If you use the --user flag:

$ pip3 install --user bigquery_schema_generator

the package will be installed at $HOME/Library/Python/3.10/lib/python/site-packages/, and the generate-schema script will be installed at $HOME/Library/Python/3.10/bin/generate-schema.

You may need to add the $HOME/Library/Python/3.10/bin directory to your $PATH variable in your $HOME/.bashrc file.

MacOS 10.14 (Mojave)

This MacOS version comes with Python 2.7 only. To install Python 3, you can install using:

1)) Downloading the macos installer directly from Python.org.

The python3 binary will be located at /usr/local/bin/python3, and the /usr/local/bin/pip3 is a symlink to /Library/Frameworks/Python.framework/Versions/3.6/bin/pip3.

So running

$ pip3 install --user bigquery_schema_generator

will install generate-schema at /Library/Frameworks/Python.framework/Versions/3.6/bin/generate-schema.

The Python installer updates $HOME/.bash_profile to add /Library/Frameworks/Python.framework/Versions/3.6/bin to the $PATH environment variable. So you should be able to run the generate-schema command without typing in the full path.

2)) Using Homebrew.

In this environment, the generate-schema script will probably be installed in /usr/local/bin but I'm not completely certain.

Usage

Command Line

The generate_schema.py script accepts a newline-delimited JSON or CSV data file on the STDIN. JSON input format has been tested extensively. CSV input format was added more recently (in v0.4) using the --input_format csv flag. The support is not as robust as JSON file. For example, CSV format supports only the comma-separator, and does not support the pipe (|) or tab (\t) character.

Unlike bq load, the generate_schema.py script reads every record in the input data file to deduce the table's schema. It prints the JSON formatted schema file on the STDOUT.

There are at least 3 ways to run this script:

1) Shell script

If you installed using pip3, then it should have installed a small helper script named generate-schema in your local ./bin directory of your current environment (depending on whether you are using a virtual environment).

$ generate-schema < file.data.json > file.schema.json

2) Python module

You can invoke the module directly using:

$ python3 -m bigquery_schema_generator.generate_schema < file.data.json > file.schema.json

This is essentially what the generate-schema command does.

3) Python script

If you retrieved this code from its GitHub repository, then you can invoke the Python script directly:

$ ./generate_schema.py < file.data.json > file.schema.json

Using the Schema Output

The resulting schema file can be given to the bq load command using the --schema flag:


$ bq load --source_format NEWLINE_DELIMITED_JSON \
    --ignore_unknown_values \
    --schema file.schema.json \
    mydataset.mytable \
    file.data.json

where mydataset.mytable is the target table in BigQuery.

For debugging purposes, here is the equivalent bq load command using schema autodetection:

$ bq load --source_format NEWLINE_DELIMITED_JSON \
    --autodetect \
    mydataset.mytable \
    file.data.json

If the input file is in CSV format, the first line will be the header line which enumerates the names of the columns. But this header line must be skipped when importing the file into the BigQuery table. We accomplish this using --skip_leading_rows flag:

$ bq load --source_format CSV \
    --schema file.schema.json \
    --skip_leading_rows 1 \
    mydataset.mytable \
    file.data.csv

Here is the equivalent bq load command for CSV files using autodetection:

$ bq load --source_format CSV \
    --autodetect \
    mydataset.mytable \
    file.data.csv

A useful flag for bq load, particularly for JSON files, is --ignore_unknown_values, which causes bq load to ignore fields in the input data which are not defined in the schema. When generate_schema.py detects an inconsistency in the definition of a particular field in the input data, it removes the field from the schema definition. Without the --ignore_unknown_values, the bq load fails when the inconsistent data record is read.

Another useful flag during development and debugging is --replace which replaces any existing BigQuery table.

After the BigQuery table is loaded, the schema can be retrieved using:

$ bq show --schema mydataset.mytable | python3 -m json.tool

(The python -m json.tool command will pretty-print the JSON formatted schema file. An alternative is the jq command.) The resulting schema file should be identical to file.schema.json.

Command Line Flag Options

The generate_schema.py script supports a handful of command line flags as shown by the --help flag below.

Help (--help)

Print the built-in help strings:

$ generate-schema --help
usage: generate-schema [-h] [--input_format INPUT_FORMAT] [--keep_nulls]
                       [--quoted_values_are_strings] [--infer_mode]
                       [--debugging_interval DEBUGGING_INTERVAL]
                       [--debugging_map] [--sanitize_names]
                       [--ignore_invalid_lines]
                       [--existing_schema_path EXISTING_SCHEMA_PATH]
                       [--preserve_input_sort_order]

Generate BigQuery schema from JSON or CSV file.

optional arguments:
  -h, --help            show this help message and exit
  --input_format INPUT_FORMAT
                        Specify an alternative input format ('csv', 'json',
                        'dict')
  --keep_nulls          Print the schema for null values, empty arrays or
                        empty records
  --quoted_values_are_strings
                        Quoted values should be interpreted as strings
  --infer_mode          Determine if mode can be 'NULLABLE' or 'REQUIRED'
  --debugging_interval DEBUGGING_INTERVAL
                        Number of lines between heartbeat debugging messages
  --debugging_map       Print the metadata schema_map instead of the schema
  --sanitize_names      Forces schema name to comply with BigQuery naming
                        standard
  --ignore_invalid_lines
                        Ignore lines that cannot be parsed instead of stopping
  --existing_schema_path EXISTING_SCHEMA_PATH
                        File that contains the existing BigQuery schema for a
                        table. This can be fetched with: `bq show --schema
                        <project_id>:<dataset>:<table_name>
  --preserve_input_sort_order
                        Preserve the original ordering of columns from input
                        instead of sorting alphabetically. This only impacts
                        `input_format` of json or dict

Input Format (--input_format)

Specifies the format of the input file as a string. It must be one of json (default), csv, or dict:

  • json
    • a "file-like" object containing newline-delimited JSON
  • csv
    • a "file-like" object containing newline-delimited CSV
  • dict
    • a list of Python dict objects corresponding to list of newline-delimited JSON, in other words List[Dict[str, Any]]
    • applies only if SchemaGenerator is used as a library through the run() or deduce_schema() method
    • useful if the input data (usually JSON) has already been read into memory and parsed from newline-delimited JSON into native Python dict objects.

If csv file is specified, the --keep_nulls flag is automatically activated. This is required because CSV columns are defined positionally, so the schema file must contain all the columns specified by the CSV file, in the same order, even if the column contains an empty value for every record.

See Issue #26 for implementation details.

Keep Nulls (--keep_nulls)

Normally when the input data file contains a field which has a null, empty array or empty record as its value, the field is suppressed in the schema file. This flag enables this field to be included in the schema file.

In other words, using a data file containing just nulls and empty values:

$ generate_schema
{ "s": null, "a": [], "m": {} }
^D
INFO:root:Processed 1 lines
[]

With the keep_nulls flag, we get:

$ generate-schema --keep_nulls
{ "s": null, "a": [], "m": {} }
^D
INFO:root:Processed 1 lines
[
  {
    "mode": "REPEATED",
    "type": "STRING",
    "name": "a"
  },
  {
    "mode": "NULLABLE",
    "fields": [
      {
        "mode": "NULLABLE",
        "type": "STRING",
        "name": "__unknown__"
      }
    ],
    "type": "RECORD",
    "name": "d"
  },
  {
    "mode": "NULLABLE",
    "type": "STRING",
    "name": "s"
  }
]

Quoted Values Are Strings (--quoted_values_are_strings)

By default, quoted values are inspected to determine if they can be interpreted as DATE, TIME, TIMESTAMP, BOOLEAN, INTEGER or FLOAT. This is consistent with the algorithm used by bq load. However, for the BOOLEAN, INTEGER, or FLOAT types, it is sometimes more useful to interpret those as normal strings instead. This flag disables type inference for BOOLEAN, INTEGER and FLOAT types inside quoted strings.

$ generate-schema
{ "name": "1" }
^D
[
  {
    "mode": "NULLABLE",
    "name": "name",
    "type": "INTEGER"
  }
]

$ generate-schema --quoted_values_are_strings
{ "name": "1" }
^D
[
  {
    "mode": "NULLABLE",
    "name": "name",
    "type": "STRING"
  }
]

Infer Mode (--infer_mode)

Set the schema mode of a field to REQUIRED instead of the default NULLABLE if the field contains a non-null or non-empty value for every data record in the input file. This option is available only for CSV (--input_format csv) files. It is theoretically possible to implement this feature for JSON files, but too difficult to implement in practice because fields are often completely missing from a given JSON record (instead of explicitly being defined to be null).

In addition to the above, this option, when used in conjunction with --existing_schema_map, will allow fields to be relaxed from REQUIRED to NULLABLE if they were REQUIRED in the existing schema and NULL rows are found in the new data we are inferring a schema from. In this case it can be used with either input_format, CSV or JSON.

See Issue #28 for implementation details.

Debugging Interval (--debugging_interval)

By default, the generate_schema.py script prints a short progress message every 1000 lines of input data. This interval can be changed using the --debugging_interval flag.

$ generate-schema --debugging_interval 50 < file.data.json > file.schema.json

Debugging Map (--debugging_map)

Instead of printing out the BigQuery schema, the --debugging_map prints out the bookkeeping metadata map which is used internally to keep track of the various fields and their types that were inferred using the data file. This flag is intended to be used for debugging.

$ generate-schema --debugging_map < file.data.json > file.schema.json

Sanitize Names (--sanitize_names)

BigQuery column names are restricted to certain characters and length:

  • it must contain only letters (a-z, A-Z), numbers (0-9), or underscores
  • it must start with a letter or underscore
  • the maximum length is 128 characters
  • column names are case-insensitive

For CSV files, the bq load command seems to automatically convert invalid column names into valid column names. This flag attempts to perform some of the same transformations, to avoid having to scan through the input data twice to generate the schema file. The transformations are:

  • any character outside of ASCII letters, numbers and underscore ([a-zA-Z0-9_]) are converted to an underscore. For example go&2#there! is converted to go_2_there_;
  • names longer than 128 characters are truncated to 128.

My recollection is that the bq load command does not normalize the JSON key names. Instead it prints an error message. So the --sanitize_names flag is useful mostly for CSV files. For JSON files, you'll have to do a second pass through the data files to cleanup the column names anyway. See Issue #14 and Issue #33.

Ignore Invalid Lines (--ignore_invalid_lines)

By default, if an error is encountered on a particular line, processing stops immediately with an exception. This flag causes invalid lines to be ignored and processing continues. A list of all errors and their line numbers will be printed on the STDERR after processing the entire file.

This flag is currently most useful for JSON files, to ignore lines which do not parse correctly as a JSON object.

This flag is probably not useful for CSV files. CSV files are processed by the DictReader class which performs its own line processing internally, including extracting the column names from the first line of the file. If the DictReader does throw an exception on a given line, we would not be able to catch it and continue processing. Fortunately, CSV files are fairly robust, and the schema deduction logic will handle any missing or extra columns gracefully.

Fixes Issue #49.

Existing Schema Path (--existing_schema_path)

There are cases where we would like to start from an existing BigQuery table schema rather than starting from scratch with a new batch of data we would like to load. In this case we can specify the path to a local file on disk that is our existing bigquery table schema. This can be generated via the following bq show --schema command:

bq show --schema <PROJECT_ID>:<DATASET_NAME>.<TABLE_NAME> > existing_table_schema.json

We can then run generate-schema with the additional option

--existing_schema_path existing_table_schema.json

There is some subtle interaction between the --existing_schema_path and fields which are marked with a mode of REQUIRED in the existing schema. If the new data contains a null value (either in a CSV or JSON data file), it is not clear if the schema should be changed to mode=NULLABLE or whether the new data should be ignored and the schema should remain mode=REQUIRED. The choice is determined by overloading the --infer_mode flag:

  • If --infer_mode is given, the new schema will be allowed to revert back to NULLABLE.
  • If --infer_mode is not given, the offending new record will be ignored and the new schema will remain REQUIRED.

See discussion in PR #57 for more details.

Preserve Input Sort Order (--preserve_input_sort_order)

By default, the order of columns in the BQ schema file is sorted lexicographically, which matched the original behavior of bq load --autodetect. If the --preserve_input_sort_order flag is given, the columns in the resulting schema file is not sorted, but preserves the order of appearance in the input JSON data. For example, the following JSON data with the --preserve_input_sort_order flag will produce:

$ generate-schema --preserve_input_sort_order
{ "s": "string", "i": 3, "x": 3.2, "b": true }
^D
[
  {
    "mode": "NULLABLE",
    "name": "s",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "i",
    "type": "INTEGER"
  },
  {
    "mode": "NULLABLE",
    "name": "x",
    "type": "FLOAT"
  },
  {
    "mode": "NULLABLE",
    "name": "b",
    "type": "BOOLEAN"
  }
]

It is possible that each JSON record line contains only a partial subset of the total possible columns in the data set. The order of the columns in the BQ schema will then be the order that each column was first seen by the script:

$ generate-schema --preserve_input_sort_order
{ "s": "string", "i": 3 }
{ "x": 3.2, "s": "string", "i": 3 }
{ "b": true, "x": 3.2, "s": "string", "i": 3 }
^D
[
  {
    "mode": "NULLABLE",
    "name": "s",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "i",
    "type": "INTEGER"
  },
  {
    "mode": "NULLABLE",
    "name": "x",
    "type": "FLOAT"
  },
  {
    "mode": "NULLABLE",
    "name": "b",
    "type": "BOOLEAN"
  }
]

Note: In Python 3.6 (the earliest version of Python supported by this project), the order of keys in a dict was the insertion-order, but this ordering was an implementation detail, and not guaranteed. In Python 3.7, that ordering was made permanent. So the --preserve_input_sort_order flag should work in Python 3.6 but is not guaranteed.

See discussion in PR #75 for more details.

Using As a Library

The SchemaGenerator class can be used programmatically as a library from a larger Python application.

SchemaGenerator.run()

The bigquery_schema_generator module can be used as a library by an external Python client code by creating an instance of SchemaGenerator and calling the run(input, output) method:

from bigquery_schema_generator.generate_schema import SchemaGenerator

generator = SchemaGenerator(
    input_format=input_format,
    infer_mode=infer_mode,
    keep_nulls=keep_nulls,
    quoted_values_are_strings=quoted_values_are_strings,
    debugging_interval=debugging_interval,
    debugging_map=debugging_map,
    sanitize_names=sanitize_names,
    ignore_invalid_lines=ignore_invalid_lines,
    preserve_input_sort_order=preserve_input_sort_order,
)

FILENAME = "..."

with open(FILENAME) as input_file:
    generator.run(input_file=input_file, output_file=output_file)

The input_format is one of json, csv, and dict as described in the Input Format section above. The input_file must match the format given by this parameter.

See generatorrun.py for an example.

SchemaGenerator.deduce_schema() from File

If you need to process the generated schema programmatically, use the deduce_schema() method and process the resulting schema_map and error_log data structures like this:

import json
import logging
import sys
from bigquery_schema_generator.generate_schema import SchemaGenerator

FILENAME = "jsonfile.json"

generator = SchemaGenerator(
    input_format='json',
    quoted_values_are_strings=True,
)

with open(FILENAME) as file:
    schema_map, errors = generator.deduce_schema(file)

for error in errors:
    logging.info("Problem on line %s: %s", error['line_number'], error['msg'])

schema = generator.flatten_schema(schema_map)
json.dump(schema, sys.stdout, indent=2)
print()

See csvreader.py and jsoneader.py for 2 examples.

The deduce_schema() also supports starting from an existing schema_map instead of starting from scratch. This is the internal version of the --existing_schema_path functionality.

schema_map1, errors = generator.deduce_schema(input_data=data1)
schema_map2, errors = generator.deduce_schema(
    input_data=data1, schema_map=schema_map1
)

The input_data must match the input_format given in the constructor. The format is described in the Input Format section above.

SchemaGenerator.deduce_schema() from Dict

If the JSON data set has already been read into memory into a Python dict object, the SchemaGenerator can process that too like this:

import json
import logging
import sys
from bigquery_schema_generator.generate_schema import SchemaGenerator

generator = SchemaGenerator(input_format='dict')
input_data = [
    {
        's': 'string',
        'b': True,
    },
    {
        'd': '2021-08-18',
        'x': 3.1
    },
]
schema_map, errors = generator.deduce_schema(input_data)
schema = generator.flatten_schema(schema_map)
json.dump(schema, sys.stdout, indent=2)
print()

See dictreader.py for an example.

Schema Types

Supported Types

The bq show --schema command produces a JSON schema file that uses the older Legacy SQL date types. For compatibility, generate-schema script will also generate a schema file using the legacy data types.

The supported types are:

  • BOOLEAN
  • INTEGER
  • FLOAT
  • STRING
  • TIMESTAMP
  • DATE
  • TIME
  • RECORD

The generate-schema script supports both NULLABLE and REPEATED modes of all of the above types.

The supported format of TIMESTAMP is as close as practical to the bq load format:

YYYY-[M]M-[D]D[( |T)[H]H:[M]M:[S]S[.DDDDDD]][time zone]

which appears to be an extension of the ISO 8601 format. The difference from bq load is that the [time zone] component can be only

  • Z
  • UTC (same as Z)
  • (+|-)H[H][:M[M]]

Note that BigQuery supports up to 6 decimal places after the integer 'second' component. generate-schema follows the same restriction for compatibility. If your input file contains more than 6 decimal places, you need to write a data cleansing filter to fix this.

The suffix UTC is not standard ISO 8601 nor documented by Google but the UTC suffix is used by bq extract and the web interface. (See Issue 19.)

Timezone names from the tz database (e.g. "America/Los_Angeles") are not supported by generate-schema.

The following types are not supported at all:

  • BYTES
  • DATETIME (unable to distinguish from TIMESTAMP)

Type Inference Rules

The generate-schema script attempts to emulate the various type conversion and compatibility rules implemented by bq load:

  • INTEGER can upgrade to FLOAT
    • if a field in an early record is an INTEGER, but a subsequent record shows this field to have a FLOAT value, the type of the field will be upgraded to a FLOAT
    • the reverse does not happen, once a field is a FLOAT, it will remain a FLOAT
  • conflicting TIME, DATE, TIMESTAMP types upgrades to STRING
    • if a field is determined to have one type of "time" in one record, then subsequently a different "time" type, then the field will be assigned a STRING type
  • NULLABLE RECORD can upgrade to a REPEATED RECORD
    • a field may be defined as RECORD (aka "Struct") type with { ... }
    • if the field is subsequently read as an array with a [{ ... }], the field is upgraded to a REPEATED RECORD
  • a primitive type (FLOAT, INTEGER, STRING) cannot upgrade to a REPEATED primitive type
    • there's no technical reason why this cannot be allowed, but bq load does not support it, so we follow its behavior
  • a DATETIME field is always inferred to be a TIMESTAMP
    • the format of these two fields is identical (in the absence of timezone)
    • we follow the same logic as bq load and always infer these as TIMESTAMP
  • BOOLEAN, INTEGER, and FLOAT can appear inside quoted strings
    • In other words, "true" (or "True" or "false", etc) is considered a BOOLEAN type, "1" is considered an INTEGER type, and "2.1" is considered a FLOAT type. Luigi Mori (jtschichold@) added additional logic to replicate the type conversion logic used by bq load for these strings.
    • This type inference inside quoted strings can be disabled using the --quoted_values_are_strings flag
    • (See Issue #22 for more details.)
  • INTEGER values overflowing a 64-bit signed integer upgrade to FLOAT
    • integers greater than 2^63-1 (9223372036854775807)
    • integers less than -2^63 (-9223372036854775808)
    • (See Issue #18 for more details)

Examples

Here is an example of a single JSON data record on the STDIN (the ^D below means typing Control-D, which indicates "end of file" under Linux and MacOS):

$ generate-schema
{ "s": "string", "b": true, "i": 1, "x": 3.1, "t": "2017-05-22T17:10:00-07:00" }
^D
INFO:root:Processed 1 lines
[
  {
    "mode": "NULLABLE",
    "name": "b",
    "type": "BOOLEAN"
  },
  {
    "mode": "NULLABLE",
    "name": "i",
    "type": "INTEGER"
  },
  {
    "mode": "NULLABLE",
    "name": "s",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "t",
    "type": "TIMESTAMP"
  },
  {
    "mode": "NULLABLE",
    "name": "x",
    "type": "FLOAT"
  }
]

In most cases, the data file will be stored in a file:

$ cat > file.data.json
{ "a": [1, 2] }
{ "i": 3 }
^D

$ generate-schema < file.data.json > file.schema.json
INFO:root:Processed 2 lines

$ cat file.schema.json
[
  {
    "mode": "REPEATED",
    "name": "a",
    "type": "INTEGER"
  },
  {
    "mode": "NULLABLE",
    "name": "i",
    "type": "INTEGER"
  }
]

Here is the schema generated from a CSV input file. The first line is the header containing the names of the columns, and the schema lists the columns in the same order as the header:

$ generate-schema --input_format csv
e,b,c,d,a
1,x,true,,2.0
2,x,,,4
3,,,,
^D
INFO:root:Processed 3 lines
[
  {
    "mode": "NULLABLE",
    "name": "e",
    "type": "INTEGER"
  },
  {
    "mode": "NULLABLE",
    "name": "b",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "c",
    "type": "BOOLEAN"
  },
  {
    "mode": "NULLABLE",
    "name": "d",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "a",
    "type": "FLOAT"
  }
]

Here is an example of the schema generated with the --infer_mode flag:

$ generate-schema --input_format csv --infer_mode
name,surname,age
John
Michael,,
Maria,Smith,30
Joanna,Anders,21
^D
INFO:root:Processed 4 lines
[
  {
    "mode": "REQUIRED",
    "name": "name",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "surname",
    "type": "STRING"
  },
  {
    "mode": "NULLABLE",
    "name": "age",
    "type": "INTEGER"
  }
]

Benchmarks

I wrote the bigquery_schema_generator/anonymize.py script to create an anonymized data file tests/testdata/anon1.data.json.gz:

$ ./bigquery_schema_generator/anonymize.py < original.data.json \
    > anon1.data.json
$ gzip anon1.data.json

This data file is 290MB (5.6MB compressed) with 103080 data records.

Generating the schema using

$ bigquery_schema_generator/generate_schema.py < anon1.data.json \
    > anon1.schema.json

took 67s on a Dell Precision M4700 laptop with an Intel Core i7-3840QM CPU @ 2.80GHz, 32GB of RAM, Ubuntu Linux 18.04, Python 3.6.7.

System Requirements

This project was initially developed on Ubuntu 17.04 using Python 3.5.3, but it now requires Python 3.6 or higher, I think mostly due to the use of f-strings.

I have tested it on:

  • Ubuntu 22.04, Python 3.10.6
  • Ubuntu 20.04, Python 3.8.5
  • Ubuntu 18.04, Python 3.7.7
  • Ubuntu 18.04, Python 3.6.7
  • Ubuntu 17.10, Python 3.6.3
  • MacOS 12.6.2 (Monterey), Python 3.10.9
  • MacOS 11.7.2 (Big Sur), Python 3.10.9
  • MacOS 11.7.2 (Big Sur), Python 3.8.9
  • MacOS 10.14.2 (Mojave), Python 3.6.4
  • MacOS 10.13.2 (High Sierra), Python 3.6.4

The GitHub Actions continuous integration pipeline validates on Python 3.7, 3.8, 3.9, and 3.10.

The unit tests are invoked with $ make tests target, and depends only on the built-in Python unittest package.

The coding style check is invoked using $ make flake8 and depends on the flake8 package. It can be installed using $ pip3 install --user flake8.

License

Apache License 2.0

Feedback and Support

If you have any questions, comments, or feature requests for this library, please use the GitHub Discussions for this project. If you have bug reports, please file a ticket in GitHub Issues. Feature requests should go into Discussions first because they often have alternative solutions which are useful to remain visible, instead of disappearing from the default view of the Issue tracker after the ticket is closed.

Please refrain from emailing me directly unless the content is sensitive. The problem with email is that I cannot reference the email conversation when other people ask similar questions later.

Authors

  • Created by Brian T. Park (brian@xparks.net).
  • Type inference inside quoted strings by Luigi Mori (jtschichold@).
  • Flag to disable type inference inside quoted strings by Daniel Ecer (de-code@).
  • Support for CSV files and detection of REQUIRED fields by Sandor Korotkevics (korotkevics@).
  • Better support for using bigquery_schema_generator as a library from an external Python code by StefanoG_ITA (StefanoGITA@).
  • Sanitizing of column names to valid BigQuery characters and length by Jon Warghed (jonwarghed@).
  • Bug fix in --sanitize_names by Riccardo M. Cefala (riccardomc@).
  • Print full path of nested JSON elements in error messages, by Austin Brogle (abroglesc@).
  • Allow an existing schema file to be specified using --existing_schema_path, by Austin Brogle (abroglesc@) and Bozo Dragojevic (bozzzzo@).
  • Allow SchemaGenerator.deduce_schema() to accept a list of native Python dict objects, by Zigfrid Zvezdin (ZiggerZZ@).
  • Make the column order in the BQ schema file match the order of appearance in the JSON data file using the --preserve_input_sort_order flag. By Kevin Deggelman (kdeggelman@).