static USAGE: &str = r#"
Joins two sets of CSV data on the specified columns.
The default join operation is an 'inner' join. This corresponds to the
intersection of rows on the keys specified.
Joins are always done by ignoring leading and trailing whitespace. By default,
joins are done case sensitively, but this can be disabled with the --ignore-case
flag.
For examples, see https://github.com/dathere/qsv/blob/master/tests/test_join.rs.
Usage:
qsv join [options] <columns1> <input1> <columns2> <input2>
qsv join --help
input arguments:
<input1> is the first CSV data set to join.
<input2> is the second CSV data set to join.
<columns1> & <columns2> are the columns to join on for each input.
The columns arguments specify the columns to join for each input. Columns can
be referenced by name or index, starting at 1. Specify multiple columns by
separating them with a comma. Specify a range of columns with `-`. Both
columns1 and columns2 must specify exactly the same number of columns.
(See 'qsv select --help' for the full syntax.)
For <input1> and <input2>, specifying `-` indicates reading from stdin.
e.g. 'qsv frequency -s Agency nyc311.csv | qsv join value - id nycagencyinfo.csv'
join options:
--left Do a 'left outer' join. This returns all rows in
first CSV data set, including rows with no
corresponding row in the second data set. When no
corresponding row exists, it is padded out with
empty fields.
--left-anti Do a 'left anti' join. This returns all rows in
first CSV data set that has no match with the
second data set.
--left-semi Do a 'left semi' join. This returns all rows in
first CSV data set that has a match with the
second data set.
--right Do a 'right outer' join. This returns all rows in
second CSV data set, including rows with no
corresponding row in the first data set. When no
corresponding row exists, it is padded out with
empty fields. (This is the reverse of 'outer left'.)
--right-anti This returns only the rows in the second CSV data set
that do not have a corresponding row in the first
data set. The output schema is the same as the
second dataset.
--right-semi This returns only the rows in the second CSV data set
that have a corresponding row in the first data set.
The output schema is the same as the second data set.
--full Do a 'full outer' join. This returns all rows in
both data sets with matching records joined. If
there is no match, the missing side will be padded
out with empty fields. (This is the combination of
'outer left' and 'outer right'.)
--cross USE WITH CAUTION.
This returns the cartesian product of the CSV
data sets given. The number of rows return is
equal to N * M, where N and M correspond to the
number of rows in the given data sets, respectively.
--nulls When set, joins will work on empty fields.
Otherwise, empty fields are completely ignored.
(In fact, any row that has an empty field in the
key specified is ignored.)
--keys-output <file> Write successfully joined keys to <file>.
This means that the keys are written to the output
file when a match is found, with the exception of
anti joins, where keys are written when NO match
is found.
Cross joins do not write keys.
JOIN KEY TRANSFORMATION OPTIONS:
Note that transformations are applied to TEMPORARY
join key columns. The original columns are not modified
and the TEMPORARY columns are removed after the join.
-i, --ignore-case When set, joins are done case insensitively.
-z, --ignore-leading-zeros When set, leading zeros are ignored in join keys.
Common options:
-h, --help Display this message
-o, --output <file> Write output to <file> instead of stdout.
-n, --no-headers When set, the first row will not be interpreted
as headers. (i.e., They are not searched, analyzed,
sliced, etc.)
-d, --delimiter <arg> The field delimiter for reading CSV data.
Must be a single character. (default: ,)
"#;
use std::{collections::hash_map::Entry, fmt, io, iter::repeat_n, mem::swap, str};
use byteorder::{BigEndian, WriteBytesExt};
use foldhash::{HashMap, HashMapExt};
use serde::Deserialize;
use crate::{
CliResult,
config::{Config, Delimiter, SeekRead},
index::Indexed,
select::{SelectColumns, Selection},
util,
util::ByteString,
};
#[derive(Deserialize)]
struct Args {
arg_columns1: SelectColumns,
arg_input1: String,
arg_columns2: SelectColumns,
arg_input2: String,
flag_left: bool,
flag_left_anti: bool,
flag_left_semi: bool,
flag_right: bool,
flag_right_anti: bool,
flag_right_semi: bool,
flag_full: bool,
flag_cross: bool,
flag_output: Option<String>,
flag_no_headers: bool,
flag_nulls: bool,
flag_delimiter: Option<Delimiter>,
flag_keys_output: Option<String>,
flag_ignore_case: bool,
flag_ignore_leading_zeros: bool,
}
pub fn run(argv: &[&str]) -> CliResult<()> {
let args: Args = util::get_args(USAGE, argv)?;
let mut state = args.new_io_state()?;
match (
args.flag_left,
args.flag_left_anti,
args.flag_left_semi,
args.flag_right,
args.flag_right_anti,
args.flag_right_semi,
args.flag_full,
args.flag_cross,
) {
(false, false, false, false, false, false, false, false) => {
state.write_headers()?;
state.inner_join()
},
(true, false, false, false, false, false, false, false) => {
state.write_headers()?;
state.outer_join(false)
},
(false, true, false, false, false, false, false, false) => {
state.write_headers1()?;
state.left_join(true)
},
(false, false, true, false, false, false, false, false) => {
state.write_headers1()?;
state.left_join(false)
},
(false, false, false, true, false, false, false, false) => {
state.write_headers()?;
state.outer_join(true)
},
(false, false, false, false, true, false, false, false) => {
let mut swapped_join = state;
swap(&mut swapped_join.rdr1, &mut swapped_join.rdr2);
swap(&mut swapped_join.sel1, &mut swapped_join.sel2);
swapped_join.write_headers1()?;
swapped_join.left_join(true)
},
(false, false, false, false, false, true, false, false) => {
let mut swapped_join = state;
swap(&mut swapped_join.rdr1, &mut swapped_join.rdr2);
swap(&mut swapped_join.sel1, &mut swapped_join.sel2);
swapped_join.write_headers1()?;
swapped_join.left_join(false)
},
(false, false, false, false, false, false, true, false) => {
state.write_headers()?;
state.full_outer_join()
},
(false, false, false, false, false, false, false, true) => {
state.write_headers()?;
state.cross_join()
},
_ => fail_incorrectusage_clierror!("Please pick exactly one join operation."),
}
}
struct IoState<R, W: io::Write> {
wtr: csv::Writer<W>,
rdr1: csv::Reader<R>,
sel1: Selection,
rdr2: csv::Reader<R>,
sel2: Selection,
no_headers: bool,
casei: bool,
zerosi: bool,
nulls: bool,
keys_wtr: KeysWriter,
}
impl<R: io::Read + io::Seek, W: io::Write> IoState<R, W> {
fn write_headers(&mut self) -> CliResult<()> {
if !self.no_headers {
let mut headers = self.rdr1.byte_headers()?.clone();
headers.extend(self.rdr2.byte_headers()?.iter());
self.wtr.write_record(&headers)?;
}
Ok(())
}
fn write_headers1(&mut self) -> CliResult<()> {
if !self.no_headers {
let headers = self.rdr1.byte_headers()?;
self.wtr.write_record(headers)?;
}
Ok(())
}
fn inner_join(mut self) -> CliResult<()> {
let mut scratch = csv::ByteRecord::new();
let mut validx =
ValueIndex::new(self.rdr2, &self.sel2, self.casei, self.zerosi, self.nulls)?;
let mut row = csv::ByteRecord::new();
let mut key;
while self.rdr1.read_byte_record(&mut row)? {
key = get_row_key(&self.sel1, &row, self.casei, self.zerosi);
if let Some(rows) = validx.values.get(&key) {
self.keys_wtr.write_key(&key)?;
for &rowi in rows {
validx.idx.seek(rowi as u64)?;
validx.idx.read_byte_record(&mut scratch)?;
let combined = row.iter().chain(scratch.iter());
self.wtr.write_record(combined)?;
}
}
}
self.wtr.flush()?;
self.keys_wtr.flush()?;
Ok(())
}
fn outer_join(mut self, right: bool) -> CliResult<()> {
if right {
swap(&mut self.rdr1, &mut self.rdr2);
swap(&mut self.sel1, &mut self.sel2);
}
let mut scratch = csv::ByteRecord::new();
let (_, pad2) = self.get_padding()?;
let mut validx =
ValueIndex::new(self.rdr2, &self.sel2, self.casei, self.zerosi, self.nulls)?;
let mut row = csv::ByteRecord::new();
let mut key;
while self.rdr1.read_byte_record(&mut row)? {
key = get_row_key(&self.sel1, &row, self.casei, self.zerosi);
match validx.values.get(&key) {
Some(rows) => {
self.keys_wtr.write_key(&key)?;
for &rowi in rows {
validx.idx.seek(rowi as u64)?;
let row1 = row.iter();
validx.idx.read_byte_record(&mut scratch)?;
if right {
self.wtr.write_record(scratch.iter().chain(row1))?;
} else {
self.wtr.write_record(row1.chain(&scratch))?;
}
}
},
_ => {
if right {
self.wtr.write_record(pad2.iter().chain(&row))?;
} else {
self.wtr.write_record(row.iter().chain(&pad2))?;
}
},
}
}
self.wtr.flush()?;
self.keys_wtr.flush()?;
Ok(())
}
fn left_join(mut self, anti: bool) -> CliResult<()> {
let validx = ValueIndex::new(self.rdr2, &self.sel2, self.casei, self.zerosi, self.nulls)?;
let mut row = csv::ByteRecord::new();
let mut key;
while self.rdr1.read_byte_record(&mut row)? {
key = get_row_key(&self.sel1, &row, self.casei, self.zerosi);
#[allow(clippy::map_entry)]
if !validx.values.contains_key(&key) {
if anti {
self.keys_wtr.write_key(&key)?;
self.wtr.write_record(&row)?;
}
} else if !anti {
self.keys_wtr.write_key(&key)?;
self.wtr.write_record(&row)?;
}
}
self.wtr.flush()?;
self.keys_wtr.flush()?;
Ok(())
}
fn full_outer_join(mut self) -> CliResult<()> {
let mut scratch = csv::ByteRecord::new();
let (pad1, pad2) = self.get_padding()?;
let mut validx =
ValueIndex::new(self.rdr2, &self.sel2, self.casei, self.zerosi, self.nulls)?;
let mut rdr2_written: Vec<_> = repeat_n(false, validx.num_rows).collect();
let mut row1 = csv::ByteRecord::new();
let mut key;
while self.rdr1.read_byte_record(&mut row1)? {
key = get_row_key(&self.sel1, &row1, self.casei, self.zerosi);
match validx.values.get(&key) {
Some(rows) => {
self.keys_wtr.write_key(&key)?;
for &rowi in rows {
rdr2_written[rowi] = true;
validx.idx.seek(rowi as u64)?;
validx.idx.read_byte_record(&mut scratch)?;
self.wtr.write_record(row1.iter().chain(&scratch))?;
}
},
_ => {
self.wtr.write_record(row1.iter().chain(&pad2))?;
},
}
}
for (i, &written) in rdr2_written.iter().enumerate() {
if !written {
validx.idx.seek(i as u64)?;
validx.idx.read_byte_record(&mut scratch)?;
self.wtr.write_record(pad1.iter().chain(&scratch))?;
}
}
self.wtr.flush()?;
self.keys_wtr.flush()?;
Ok(())
}
fn cross_join(mut self) -> CliResult<()> {
let mut pos = csv::Position::new();
pos.set_byte(0);
let mut row2 = csv::ByteRecord::new();
let mut row1 = csv::ByteRecord::new();
let rdr2_has_headers = self.rdr2.has_headers();
while self.rdr1.read_byte_record(&mut row1)? {
self.rdr2.seek(pos.clone())?;
if rdr2_has_headers {
self.rdr2.read_byte_record(&mut row2)?;
}
while self.rdr2.read_byte_record(&mut row2)? {
self.wtr.write_record(row1.iter().chain(&row2))?;
}
}
Ok(self.wtr.flush()?)
}
fn get_padding(&mut self) -> CliResult<(csv::ByteRecord, csv::ByteRecord)> {
let len1 = self.rdr1.byte_headers()?.len();
let len2 = self.rdr2.byte_headers()?.len();
Ok((repeat_n(b"", len1).collect(), repeat_n(b"", len2).collect()))
}
}
impl Args {
fn new_io_state(
&self,
) -> CliResult<IoState<Box<dyn SeekRead + 'static>, Box<dyn io::Write + 'static>>> {
let rconf1 = Config::new(Some(self.arg_input1.clone()).as_ref())
.delimiter(self.flag_delimiter)
.no_headers_flag(self.flag_no_headers)
.select(self.arg_columns1.clone());
let rconf2 = Config::new(Some(self.arg_input2.clone()).as_ref())
.delimiter(self.flag_delimiter)
.no_headers_flag(self.flag_no_headers)
.select(self.arg_columns2.clone());
let mut rdr1 = match rconf1.reader_file_stdin() {
Ok(rdr1) => rdr1,
Err(e) => return fail_clierror!("Failed to read input1: {e}"),
};
let mut rdr2 = match rconf2.reader_file_stdin() {
Ok(rdr2) => rdr2,
Err(e) => return fail_clierror!("Failed to read input2: {e}"),
};
let (sel1, sel2) = self.get_selections(&rconf1, &mut rdr1, &rconf2, &mut rdr2)?;
let keys_wtr = if self.flag_cross {
KeysWriter::new(None)?
} else {
KeysWriter::new(self.flag_keys_output.as_ref())?
};
Ok(IoState {
wtr: Config::new(self.flag_output.as_ref()).writer()?,
rdr1,
sel1,
rdr2,
sel2,
no_headers: rconf1.no_headers,
casei: self.flag_ignore_case,
zerosi: self.flag_ignore_leading_zeros,
nulls: self.flag_nulls,
keys_wtr,
})
}
#[allow(clippy::unused_self)]
fn get_selections<R: io::Read>(
&self,
rconf1: &Config,
rdr1: &mut csv::Reader<R>,
rconf2: &Config,
rdr2: &mut csv::Reader<R>,
) -> CliResult<(Selection, Selection)> {
let headers1 = rdr1.byte_headers()?;
let headers2 = rdr2.byte_headers()?;
let select1 = rconf1.selection(headers1)?;
let select2 = rconf2.selection(headers2)?;
if select1.len() != select2.len() {
return fail_incorrectusage_clierror!(
"Column selections must have the same number of columns, but found column \
selections with {} and {} columns.",
select1.len(),
select2.len()
);
}
Ok((select1, select2))
}
}
struct ValueIndex<R> {
values: HashMap<Vec<ByteString>, Vec<usize>>,
idx: Indexed<R, io::Cursor<Vec<u8>>>,
num_rows: usize,
}
impl<R: io::Read + io::Seek> ValueIndex<R> {
fn new(
mut rdr: csv::Reader<R>,
sel: &Selection,
casei: bool,
zerosi: bool,
nulls: bool,
) -> CliResult<ValueIndex<R>> {
let mut val_idx = HashMap::with_capacity(20_000);
let mut row_idx = io::Cursor::new(Vec::with_capacity(8 * 20_000));
let (mut rowi, mut count) = (0_usize, 0_usize);
if rdr.has_headers() {
rdr.byte_headers()?;
row_idx.write_u64::<BigEndian>(0)?;
count += 1;
} else {
let mut pos = csv::Position::new();
pos.set_byte(0);
rdr.seek(pos)?;
}
let mut row = csv::ByteRecord::new();
while rdr.read_byte_record(&mut row)? {
row_idx.write_u64::<BigEndian>(row.position().unwrap().byte())?;
let fields: Vec<_> = sel
.select(&row)
.map(|v| {
if let Ok(s) = simdutf8::basic::from_utf8(v) {
let cased_bytes_vec = if casei {
s.trim().to_lowercase().into_bytes()
} else {
s.trim().as_bytes().to_vec()
};
if zerosi {
if cased_bytes_vec.iter().all(|&b| b == b'0')
&& !cased_bytes_vec.is_empty()
{
vec![b'0']
} else {
cased_bytes_vec
.iter()
.skip_while(|&b| *b == b'0')
.copied()
.collect()
}
} else {
cased_bytes_vec
}
} else {
v.to_vec()
}
})
.collect();
if nulls || !fields.iter().any(std::vec::Vec::is_empty) {
match val_idx.entry(fields) {
Entry::Vacant(v) => {
let mut rows = Vec::with_capacity(4);
rows.push(rowi);
v.insert(rows);
},
Entry::Occupied(mut v) => {
v.get_mut().push(rowi);
},
}
}
rowi += 1;
count += 1;
}
row_idx.write_u64::<BigEndian>(count as u64)?;
let idx = Indexed::open(rdr, io::Cursor::new(row_idx.into_inner()))?;
Ok(ValueIndex {
values: val_idx,
idx,
num_rows: rowi,
})
}
}
impl<R> fmt::Debug for ValueIndex<R> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let mut kvs = self.values.iter().collect::<Vec<_>>();
kvs.sort_by(|&(_, v1), &(_, v2)| v1[0].cmp(&v2[0]));
for (keys, rows) in kvs {
let keys = keys
.iter()
.map(|k| String::from_utf8(k.clone()).unwrap())
.collect::<Vec<_>>();
writeln!(f, "({}) => {rows:?}", keys.join(", "))?;
}
Ok(())
}
}
#[inline]
fn get_row_key(
sel: &Selection,
row: &csv::ByteRecord,
casei: bool,
zerosi: bool,
) -> Vec<ByteString> {
let key: Vec<_> = sel
.select(row)
.map(|v| {
if let Ok(s) = simdutf8::basic::from_utf8(v) {
let cased_bytes_vec = if casei {
s.trim().to_lowercase().into_bytes()
} else {
s.trim().as_bytes().to_vec()
};
if zerosi {
if cased_bytes_vec.iter().all(|&b| b == b'0') && !cased_bytes_vec.is_empty() {
vec![b'0']
} else {
cased_bytes_vec
.iter()
.skip_while(|&b| *b == b'0')
.copied()
.collect()
}
} else {
cased_bytes_vec
}
} else {
v.to_vec()
}
})
.collect();
key
}
struct KeysWriter {
writer: csv::Writer<Box<dyn io::Write>>,
enabled: bool,
}
impl KeysWriter {
fn new(keys_path: Option<&String>) -> CliResult<Self> {
let (writer, enabled) = if let Some(path) = keys_path {
(Config::new(Some(path)).writer()?, true)
} else {
let sink: Box<dyn io::Write> = Box::new(std::io::sink());
(csv::WriterBuilder::new().from_writer(sink), false)
};
Ok(Self { writer, enabled })
}
#[inline]
fn write_key(&mut self, key: &[ByteString]) -> CliResult<()> {
if self.enabled {
self.writer.write_record(key)?;
}
Ok(())
}
fn flush(&mut self) -> CliResult<()> {
if self.enabled {
self.writer.flush()?;
}
Ok(())
}
}