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Compatibility |
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The SQL plugin tries to produce results that are bit for bit identical with Apache Spark. There are a number of cases where there are some differences. In most cases operators that produce different results are off by default, and you can look at the configs for more information on how to enable them. In some cases we felt that enabling the incompatibility by default was worth the performance gain. All of those operators can be disabled through configs if it becomes a problem. Please also look at the current list of bugs which are typically incompatibilities that we have not yet addressed.
There are some operators where Spark does not guarantee the order of the output.
These are typically things like aggregates and joins that may use a hash to distribute the work
load among downstream tasks. In these cases the plugin does not guarantee that it will
produce the same output order that Spark does. In cases such as an order by
operation
where the ordering is explicit the plugin will produce an ordering that is compatible with
Spark's guarantee. It may not be 100% identical if the ordering is ambiguous.
In versions of Spark prior to 3.1.0 -0.0
is always < 0.0
but in 3.1.0 and above this is
not true for sorting. For all versions of the plugin -0.0
== 0.0
for sorting.
Spark's sorting is typically a stable
sort. Sort stability cannot be guaranteed in distributed work loads because the order in which
upstream data arrives to a task is not guaranteed. Sort stability is only
guaranteed in one situation which is reading and sorting data from a file using a single
task/partition. The RAPIDS Accelerator does an unstable
out of core sort by default. This
simply means that the sort algorithm allows for spilling parts of the data if it is larger than
can fit in the GPU's memory, but it does not guarantee ordering of rows when the ordering of the
keys is ambiguous. If you do rely on a stable sort in your processing you can request this by
setting spark.rapids.sql.stableSort.enabled to true
and
RAPIDS will try to sort all the data for a given task/partition at once on the GPU. This may change
in the future to allow for a spillable stable sort.
For most basic floating-point operations like addition, subtraction, multiplication, and division
the plugin will produce a bit for bit identical result as Spark does. For other functions like
sin
, cos
, etc. the output may be different, but within the rounding error inherent in
floating-point calculations. The ordering of operations to calculate the value may differ between the
underlying JVM implementation used by the CPU and the C++ standard library implementation used by
the GPU.
In the case of round
and bround
the results can be off by more because they can enlarge the
difference. This happens in cases where a binary floating-point representation cannot exactly
capture a decimal value. For example 1.025
cannot exactly be represented and ends up being closer
to 1.02499
. The Spark implementation of round
converts it first to a decimal value with complex
logic to make it 1.025
and then does the rounding. This results in round(1.025, 2)
under pure
Spark getting a value of 1.03
but under the RAPIDS accelerator it produces 1.02
. As a side note
Python will produce 1.02
, Java does not have the ability to do a round like this built in, but if
you do the simple operation of Math.round(1.025 * 100.0)/100.0
you also get 1.02
.
For the degrees
functions, Spark's implementation relies on Java JDK's built-in functions Math.toDegrees
. It is angrad * 180.0 / PI
in Java 8 while angrad * (180d / PI)
in Java 9+. So their results will differ depending on the JDK runtime versions when considering overflow. The RAPIDS Accelerator follows the behavior of Java 9+. Therefore, with JDK 8 or below, the degrees
on GPU will not overflow on some very large numbers while the CPU version does.
For aggregations the underlying implementation is doing the aggregations in parallel and due to race
conditions within the computation itself the result may not be the same each time the query is
run. This is inherent in how the plugin speeds up the calculations and cannot be "fixed." If a query
joins on a floating point value, which is not wise to do anyways, and the value is the result of a
floating point aggregation then the join may fail to work properly with the plugin but would have
worked with plain Spark. This is behavior is enabled by default but can be disabled with the config
spark.rapids.sql.variableFloatAgg.enabled
.
Floating point allows zero to be encoded as 0.0
and -0.0
, but the IEEE standard says that they
should be interpreted as the same. Most databases normalize these values to always be 0.0
. Spark
does this in some cases but not all as is documented
here. The underlying implementation of this
plugin treats them as the same for essentially all processing. This can result in some differences
with Spark for operations, prior to Spark 3.1.0, like sorting, and distinct count. There are still
differences with joins, and comparisons even
after Spark 3.1.0.
We do not disable operations that produce different results due to -0.0
in the data because it is
considered to be a rare occurrence.
Apache Spark does not have a consistent way to handle NaN
comparison. Sometimes, all NaN
are
considered as one unique value while other times they can be treated as different. The outcome of
NaN
comparison can differ in various operations and also changed between Spark versions.
The RAPIDS Accelerator tries to match its output with Apache Spark except for a few operation(s) listed below:
IN
SQL expression:NaN
can be treated as different values in Spark 3.1.2 and prior versions, see SPARK-36792 for more details. The RAPIDS Accelerator comparesNaN
values as equal for this operation which matches the behavior of Apache Spark 3.1.3 and later versions.
Apache Spark supports decimal values with a precision up to 38. This equates to 128-bits.
When processing the data, in most cases, it is temporarily converted to Java's BigDecimal
type
which allows for effectively unlimited precision. Overflows will be detected whenever the
BigDecimal
value is converted back into the Spark decimal type.
The RAPIDS Accelerator does not implement a GPU equivalent of BigDecimal
, but it does implement
computation on 256-bit values to allow the detection of overflows. The points at which overflows
are detected may differ between the CPU and GPU. Spark gives no guarantees that overflows are
detected if an intermediate value could overflow the original decimal type during computation
but the final value does not (e.g.: a sum of values with many large positive values followed by
many large negative values). Spark injects overflow detection at various points during aggregation,
and these points can fluctuate depending on cluster shape and number of shuffle partitions.
Spark delegates Unicode operations to the underlying JVM. Each version of Java complies with a specific version of the Unicode standard. The SQL plugin does not use the JVM for Unicode support and is compatible with Unicode version 12.1. Because of this there may be corner cases where Spark will produce a different result compared to the plugin.
Spark allows for stripping leading and trailing white space using various options that are off by default. The plugin will strip leading and trailing space for all values except strings.
There are also discrepancies/issues with specific types that are detailed below.
Writing strings to a CSV file in general for Spark can be problematic unless you can ensure that
your data does not have any line deliminator in it. The GPU accelerated CSV parser handles quoted
line deliminators similar to multiLine
mode. But there are still a number of issues surrounding
it and they should be avoided.
Escaped quote characters '\"'
are not supported well as described by this
issue.
The GPU accelerated CSV parser does not replace invalid UTF-8 characters with the Unicode replacement character �. Instead it just passes them through as described in this issue.
Only a limited set of formats are supported when parsing dates.
"yyyy-MM-dd"
"yyyy/MM/dd"
"yyyy-MM"
"yyyy/MM"
"MM-yyyy"
"MM/yyyy"
"MM-dd-yyyy"
"MM/dd/yyyy"
"dd-MM-yyyy"
"dd/MM/yyyy"
The CSV parser does not support time zones. It will ignore any trailing time zone information,
despite the format asking for a XXX
or [XXX]
. The CSV parser does not support the TimestampNTZ
type and will fall back to CPU if spark.sql.timestampType
is set to TIMESTAMP_NTZ
or if an
explicit schema is provided that contains the TimestampNTZ
type.
The formats supported for timestamps are limited similar to dates. The first part of the format
must be a supported date format. The second part must start with a 'T'
to separate the time
portion followed by one of the following formats:
HH:mm:ss.SSSXXX
HH:mm:ss[.SSS][XXX]
HH:mm:ss[.SSSXXX]
HH:mm
HH:mm:ss
HH:mm[:ss]
HH:mm:ss.SSS
HH:mm:ss[.SSS]
Just like with dates all timestamp formats are actually supported at the same time. The plugin will disable itself if it sees a format it cannot support.
Invalid timestamps in Spark, ones that have the correct format, but the numbers produce invalid dates or times, can result in an exception by default and how they are parsed can be controlled through a config. The RAPIDS Accelerator does not support any of this and will produce an incorrect date. Typically, one that overflowed.
Parsing floating-point values has the same limitations as casting from string to float.
Also parsing of some values will not produce bit for bit identical results to what the CPU does. They are within round-off errors except when they are close enough to overflow to Inf or -Inf which then results in a number being returned when the CPU would have returned null.
This type was added in as a part of Spark 3.3.0, and it's not supported on Spark versions before 3.3.0. Apache Spark can overflow when reading ANSI day time interval values. The RAPIDS Accelerator does not overflow and as such is not bug for bug compatible with Spark in this case.
Interval string in csv | Spark reads to | The RAPIDS Accelerator reads to | Comments |
---|---|---|---|
interval '106751992' day | INTERVAL '-106751990' DAY | NULL | Spark issue |
interval '2562047789' hour | INTERVAL '-2562047787' HOUR | NULL | Spark issue |
There are two valid textual representations in CSV: the ANSI style and the HIVE style, e.g:
SQL Type | An instance of ANSI style | An instance of HIVE style |
---|---|---|
INTERVAL DAY | INTERVAL '100' DAY TO SECOND | 100 |
INTERVAL DAY TO HOUR | INTERVAL '100 10' DAY TO HOUR | 100 10 |
INTERVAL DAY TO MINUTE | INTERVAL '100 10:30' DAY TO MINUTE | 100 10:30 |
INTERVAL DAY TO SECOND | INTERVAL '100 10:30:40.999999' DAY TO SECOND | 100 10:30:40.999999 |
INTERVAL HOUR | INTERVAL '10' HOUR | 10 |
INTERVAL HOUR TO MINUTE | INTERVAL '10:30' HOUR TO MINUTE | 10:30 |
INTERVAL HOUR TO SECOND | INTERVAL '10:30:40.999999' HOUR TO SECOND | 10:30:40.999999 |
INTERVAL MINUTE | INTERVAL '30' MINUTE | 30 |
INTERVAL MINUTE TO SECOND | INTERVAL '30:40.999999' MINUTE TO SECOND | 30:40.999999 |
INTERVAL SECOND | INTERVAL '40.999999' SECOND | 40.999999 |
Currently, the RAPIDS Accelerator only supports the ANSI style.
Hive text files are very similar to CSV, but not exactly the same.
Parsing floating-point values has the same limitations as casting from string to float.
Also parsing of some values will not produce bit for bit identical results to what the CPU does. They are within round-off errors except when they are close enough to overflow to Inf or -Inf which then results in a number being returned when the CPU would have returned null.
Hive has some limitations in what decimal values it can parse. The GPU kernels that we use
to parse decimal values do not have the same limitations. This means that there are times
when the CPU version would return a null for an input value, but the GPU version will
return a value. This typically happens for numbers with large negative exponents where
the GPU will return 0
and Hive will return null
.
See NVIDIA#7246
The ORC format has fairly complete support for both reads and writes. There are only a few known issues. The first is for reading timestamps and dates around the transition between Julian and Gregorian calendars as described here. A similar issue exists for writing dates as described here. Writing timestamps, however only appears to work for dates after the epoch as described here.
The plugin supports reading uncompressed
, snappy
, zlib
and zstd
ORC files and writing
uncompressed
, snappy
and zstd
ORC files. At this point, the plugin does not have the
ability to
fall
back to the CPU when reading an unsupported compression format, and will error out in that case.
Spark-3.3.0+ pushes down certain aggregations (MIN
/MAX
/COUNT
) into ORC when the user-config
spark.sql.orc.aggregatePushdown
is set to true.
By enabling this feature, aggregate query performance will improve as it takes advantage of the
statistics information.
Caution
Spark ORC reader/writer assumes that all ORC files must have valid column statistics. This assumption deviates from the ORC-specification which states that statistics are optional. When a Spark-3.3.0+ job reads an ORC file with empty file-statistics, it fails while throwing the following runtime exception:
org.apache.spark.SparkException: Cannot read columns statistics in file: /PATH_TO_ORC_FILE
E Caused by: java.util.NoSuchElementException
E at java.util.LinkedList.removeFirst(LinkedList.java:270)
E at java.util.LinkedList.remove(LinkedList.java:685)
E at org.apache.spark.sql.execution.datasources.orc.OrcFooterReader.convertStatistics(OrcFooterReader.java:54)
E at org.apache.spark.sql.execution.datasources.orc.OrcFooterReader.readStatistics(OrcFooterReader.java:45)
E at org.apache.spark.sql.execution.datasources.orc.OrcUtils$.createAggInternalRowFromFooter(OrcUtils.scala:428)
The Spark community is planning to work on a runtime fallback to read from actual rows when ORC file-statistics are missing (see SPARK-34960 discussion).
Writing ORC Files
There are issues writing ORC files with dates or timestamps that fall within the lost days during the switch from the Julian to Gregorian calendar, i.e.: between October 3rd, 1582 and October 15th, 1582. Dates or timestamps that fall within the range of lost days will not always be written properly by the GPU to the ORC file. The values read by the CPU and the GPU may differ with the CPU often rounding the day up to October 15th, 1582 whereas the GPU does not.
Note that the CPU rounds up dates or timestamps in the lost days range to October 15th, 1582 before writing to the ORC file. If the CPU writes these problematic dates or timestamps to an ORC file, they will be read properly by both the CPU and the GPU.
Reading ORC Files
To take advantage of the aggregate query optimization, where only the ORC metadata is read to satisfy the query, the ORC read falls back to the CPU as it is a metadata-only query.
The Parquet format has more configs because there are multiple versions with some compatibility
issues between them. Dates and timestamps are where the known issues exist. For reads when
spark.sql.legacy.parquet.datetimeRebaseModeInWrite
is set to CORRECTED
timestamps before the transition between the
Julian and Gregorian calendars are wrong, but dates are fine. When
spark.sql.legacy.parquet.datetimeRebaseModeInWrite
is set to LEGACY
, the read may fail for
values occurring before the transition between the Julian and Gregorian calendars, i.e.: date <= 1582-10-04.
When writing spark.sql.legacy.parquet.datetimeRebaseModeInWrite
is currently ignored as described
here.
The plugin supports reading uncompressed
, snappy
, gzip
and zstd
Parquet files and writing
uncompressed
, snappy
and zstd
Parquet files. At this point, the plugin does not have the
ability to
fall back to the CPU when reading an unsupported compression format, and will error out in that
case.
The JSON format read is an experimental feature which is expected to have some issues, so we disable
it by default. If you would like to test it, you need to enable spark.rapids.sql.format.json.enabled
and
spark.rapids.sql.format.json.read.enabled
.
In Apache Spark on the CPU if a line in the JSON file is invalid the entire row is considered invalid and will result in nulls being returned for all columns. It is considered invalid if it violates the JSON specification, but with a few extensions.
- Single quotes are allowed to quote strings and keys
- Unquoted values like NaN and Infinity can be parsed as floating point values
- Control characters do not need to be replaced with the corresponding escape sequences in a quoted string.
- Garbage at the end of a row, if there is valid JSON at the beginning of the row, is ignored.
The GPU implementation does the same kinds of validations, but many of them are done on a per-column basis, which, for example, means if a number is formatted incorrectly, it is likely only that value will be considered invalid and return a null instead of nulls for the entire row.
There are options that can be used to enable and disable many of these features which are mostly listed below.
Spark supports passing options to the JSON parser when reading a dataset. In most cases if the RAPIDS Accelerator sees one of these options that it does not support it will fall back to the CPU. In some cases we do not. The following options are documented below.
-
allowNumericLeadingZeros
- Allows leading zeros in numbers (e.g. 00012). By default this is set to false. When it is false Spark considers the JSON invalid if it encounters this type of number. The RAPIDS Accelerator supports validating columns that are returned to the user with this option on or off. -
allowUnquotedControlChars
- Allows JSON Strings to contain unquoted control characters (ASCII characters with value less than 32, including tab and line feed characters) or not. By default this is set to false. If the schema is provided while reading JSON file, then this flag has no impact on the RAPIDS Accelerator as it always allows unquoted control characters but Spark sees these are invalid are returns nulls. However, if the schema is not provided and this option is false, then RAPIDS Accelerator's behavior is same as Spark where an exception is thrown as discussed inJSON Schema discovery
section. -
allowNonNumericNumbers
- AllowsNaN
andInfinity
values to be parsed (note that these are not valid numeric values in the JSON specification). Spark versions prior to 3.3.0 have inconsistent behavior and will parse some variants ofNaN
andInfinity
even when this option is disabled (SPARK-38060). The RAPIDS Accelerator behavior is consistent with Spark version 3.3.0 and later.
In versions of Spark before 3.5.0 there is no maximum to how deeply nested JSON can be. After 3.5.0 this was updated to be 1000 by default. The current GPU implementation limits this to 254 no matter what version of Spark is used. If the nesting level is over this the JSON is considered invalid and all values will be returned as nulls.
Mixed types can have some problems. If an item being read could have some lines that are arrays and others that are structs/dictionaries it is possible an error will be thrown.
Dates and Timestamps have some issues and may return values for technically invalid inputs.
Floating point numbers have issues generally like with the rest of Spark, and we can parse them into a valid floating point number, but it might not match 100% with the way Spark does it.
Strings are supported, but the data returned might not be normalized in the same way as the CPU implementation. Generally this comes down to the GPU not modifying the input, whereas Spark will do things like remove extra white space and parse numbers before turning them back into a string.
Parsing floating-point values has the same limitations as casting from string to float.
Prior to Spark 3.3.0, reading JSON strings such as "+Infinity"
when specifying that the data type is FloatType
or DoubleType
caused these values to be parsed even when allowNonNumericNumbers
is set to false. Also, Spark
versions prior to 3.3.0 only supported the "Infinity"
and "-Infinity"
representations of infinity and did not
support "+INF"
, "-INF"
, or "+Infinity"
, which Spark considers valid when unquoted. The GPU JSON reader is
consistent with the behavior in Spark 3.3.0 and later.
Another limitation of the GPU JSON reader is that it will parse strings containing non-string boolean or numeric values where
Spark will treat them as invalid inputs and will just return null
.
The JSON parser does not support the TimestampNTZ
type and will fall back to CPU if spark.sql.timestampType
is
set to TIMESTAMP_NTZ
or if an explicit schema is provided that contains the TimestampNTZ
type.
There is currently no support for reading numeric values as timestamps and null values are returned instead (#4940). A workaround would be to read as longs and then cast to timestamp.
Spark SQL can automatically infer the schema of a JSON dataset if schema is not provided explicitly. The CPU handles schema discovery and there is no GPU acceleration of this. By default Spark will read/parse the entire dataset to determine the schema. This means that some options/errors which are ignored by the GPU may still result in an exception if used with schema discovery.
JsonToStructs
of from_json
is based on the same code as reading a JSON lines file. There are
a few differences with it.
The from_json
function is disabled by default because it is experimental and has some known
incompatibilities with Spark, and can be enabled by setting
spark.rapids.sql.expression.JsonToStructs=true
. You don't need to set
spark.rapids.sql.format.json.enabled
andspark.rapids.sql.format.json.read.enabled
to true.
There is no schema discovery as a schema is required as input to from_json
In addition to structs
, a top level map
type is supported, but only if the key and value are
strings.
The to_json
function is disabled by default because it is experimental and has some known incompatibilities
with Spark, and can be enabled by setting spark.rapids.sql.expression.StructsToJson=true
.
Known issues are:
- There can be rounding differences when formatting floating-point numbers as strings. For example, Spark may
produce
-4.1243574E26
but the GPU may produce-4.124357351E26
. - Not all JSON options are respected
Known issue:
- Floating-point number normalization error.
get_json_object
floating-point number normalization on the GPU could sometimes return incorrect results if the string contains high-precision values, see the String to Float and Float to String section for more details.
The Avro format read is a very experimental feature which is expected to have some issues, so we disable
it by default. If you would like to test it, you need to enable spark.rapids.sql.format.avro.enabled
and
spark.rapids.sql.format.avro.read.enabled
.
Currently, the GPU accelerated Avro reader doesn't support reading the Avro version 1.2 files.
The boolean, byte, short, int, long, float, double, string are supported in current version.
The following Apache Spark regular expression functions and expressions are supported on the GPU:
RLIKE
regexp
regexp_extract
regexp_extract_all
regexp_like
regexp_replace
string_split
str_to_map
Regular expression evaluation on the GPU is enabled by default when the UTF-8 character set is used
by the current locale. Execution will fall back to the CPU for regular expressions that are not yet
supported on the GPU, and in environments where the locale does not use UTF-8. However, there are
some edge cases that will still execute on the GPU and produce different results to the CPU. To
disable regular expressions on the GPU, set spark.rapids.sql.regexp.enabled=false
.
These are the known edge cases where running on the GPU will produce different results to the CPU:
- Regular expressions that contain an end of line anchor '$' or end of string anchor '\Z' immediately next to a newline or a repetition that produces zero or more results (#5610)`
- Word and non-word boundaries,
\b
and\B
- Line anchor
$
will incorrectly match any of the unicode characters\u0085
,\u2028
, or\u2029
followed by another line-terminator, such as\n
. For example, the patternTEST$
will matchTEST\u0085\n
on the GPU but not on the CPU (#7585).
The following regular expression patterns are not yet supported on the GPU and will fall back to the CPU.
- Line anchors
^
and$
are not supported in some contexts, such as when combined with a choice (^|a
or$|a
). - String anchor
\Z
is not supported byregexp_replace
, and in some rare contexts. - String anchor
\z
is not supported - Patterns containing an end of line or string anchor immediately next to a newline or repetition that produces zero or more results
- Line anchor
$
and string anchors\Z
are not supported in patterns containing\W
or\D
- Line and string anchors are not supported by
string_split
andstr_to_map
- Lazy quantifiers within a choice block such as
(2|\u2029??)+
- Possessive quantifiers, such as
a*+
- Character classes that use union, intersection, or subtraction semantics, such as
[a-d[m-p]]
,[a-z&&[def]]
, or[a-z&&[^bc]]
- Empty groups:
()
- Empty pattern:
""
Work is ongoing to increase the range of regular expressions that can run on the GPU.
parse_url
QUERY with a column key could produce different results on CPU and GPU. In Spark, the key
in parse_url
could act like a regex, but GPU will match the key exactly. If key is literal, GPU will check if key contains regex special characters and fallback to CPU if it does, but if key is column, it will not be able to fallback. For example, parse_url("http://foo/bar?abc=BAD&a.c=GOOD", QUERY, "a.c")
will return "BAD" on CPU, but "GOOD" on GPU. See the Spark issue: https://issues.apache.org/jira/browse/SPARK-44500
Spark stores timestamps internally relative to the JVM time zone. Converting an arbitrary timestamp between time zones is not currently supported on the GPU. Therefore operations involving timestamps will only be GPU-accelerated if the time zone used by the JVM is UTC.
Because of ordering differences between the CPU and the GPU window functions especially row based
window functions like row_number
, lead
, and lag
can produce different results if the ordering
includes both -0.0
and 0.0
, or if the ordering is ambiguous. Spark can produce different results
from one run to another if the ordering is ambiguous on a window function too.
When the order-by column of a range based window is numeric type like byte/short/int/long
and
the range boundary calculated for a value has overflow, CPU and GPU will get different results.
For example, consider the following dataset:
+------+---------+
| id | dollars |
+------+---------+
| 1 | NULL |
| 1 | 13 |
| 1 | 14 |
| 1 | 15 |
| 1 | 15 |
| 1 | 17 |
| 1 | 18 |
| 1 | 52 |
| 1 | 53 |
| 1 | 61 |
| 1 | 65 |
| 1 | 72 |
| 1 | 73 |
| 1 | 75 |
| 1 | 78 |
| 1 | 84 |
| 1 | 85 |
| 1 | 86 |
| 1 | 92 |
| 1 | 98 |
+------+---------+
After executing the SQL statement:
SELECT
COUNT(dollars) over
(PARTITION BY id
ORDER BY CAST (dollars AS Byte) ASC
RANGE BETWEEN 127 PRECEDING AND 127 FOLLOWING)
FROM table
The results will differ between the CPU and GPU due to overflow handling.
CPU: WrappedArray([0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0], [0])
GPU: WrappedArray([0], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19], [19])
To enable byte-range windowing on the GPU, set
spark.rapids.sql.window.range.byte.enabled
to true.
We also provide configurations for other integral range types:
spark.rapids.sql.window.range.short.enabled
spark.rapids.sql.window.range.int.enabled
spark.rapids.sql.window.range.long.enabled
The reason why we default the configurations to false for byte/short and to true for int/long is that we think the most real-world queries are based on int or long.
When converting strings to dates or timestamps using functions like to_date
and unix_timestamp
,
the specified format string will fall into one of three categories:
- Supported on GPU and 100% compatible with Spark
- Supported on GPU but may produce different results to Spark
- Unsupported on GPU
The formats which are supported on GPU vary depending on the setting for timeParserPolicy
.
With timeParserPolicy set to CORRECTED
or EXCEPTION
(the default), the following formats are supported
on the GPU without requiring any additional settings.
yyyy-MM-dd
yyyy/MM/dd
yyyy-MM
yyyy/MM
dd/MM/yyyy
yyyy-MM-dd HH:mm:ss
MM-dd
MM/dd
dd-MM
dd/MM
MM/yyyy
MM-yyyy
MM/dd/yyyy
MM-dd-yyyy
MMyyyy
Valid Spark date/time formats that do not appear in the list above may also be supported but have not been extensively tested and may produce different results compared to the CPU. Known issues include:
- Valid dates and timestamps followed by trailing characters (including whitespace) may be parsed to non-null values on GPU where Spark would treat the data as invalid and return null
To attempt to use other formats on the GPU, set
spark.rapids.sql.incompatibleDateFormats.enabled
to true
.
Formats that contain any of the following characters are unsupported and will fall back to CPU:
'k', 'K','z', 'V', 'c', 'F', 'W', 'Q', 'q', 'G', 'A', 'n', 'N',
'O', 'X', 'p', '\'', '[', ']', '#', '{', '}', 'Z', 'w', 'e', 'E', 'x', 'Z', 'Y'
Formats that contain any of the following words are unsupported and will fall back to CPU:
"u", "uu", "uuu", "uuuu", "uuuuu", "uuuuuu", "uuuuuuu", "uuuuuuuu", "uuuuuuuuu", "uuuuuuuuuu",
"y", "yy", yyy", "yyyyy", "yyyyyy", "yyyyyyy", "yyyyyyyy", "yyyyyyyyy", "yyyyyyyyyy",
"D", "DD", "DDD", "s", "m", "H", "h", "M", "MMM", "MMMM", "MMMMM", "L", "LLL", "LLLL", "LLLLL",
"d", "S", "SS", "SSS", "SSSS", "SSSSS", "SSSSSSSSS", "SSSSSSS", "SSSSSSSS"
With timeParserPolicy set to LEGACY
and
spark.rapids.sql.incompatibleDateFormats.enabled
set to true
, and spark.sql.ansi.enabled
set to false
, the following formats are supported but not
guaranteed to produce the same results as the CPU:
dd-MM-yyyy
dd/MM/yyyy
yyyy/MM/dd
yyyy-MM-dd
yyyy/MM/dd HH:mm:ss
yyyy-MM-dd HH:mm:ss
LEGACY timeParserPolicy support has the following limitations when running on the GPU:
- Only 4 digit years are supported
- The proleptic Gregorian calendar is used instead of the hybrid Julian+Gregorian calendar that Spark uses in legacy mode
When formatting dates and timestamps as strings using functions such as from_unixtime
, only a
subset of valid format strings are supported on the GPU.
Formats that contain any of the following characters are unsupported and will fall back to CPU:
'k', 'K','z', 'V', 'c', 'F', 'W', 'Q', 'q', 'G', 'A', 'n', 'N',
'O', 'X', 'p', '\'', '[', ']', '#', '{', '}', 'Z', 'w', 'e', 'E', 'x', 'Z', 'Y'
Formats that contain any of the following words are unsupported and will fall back to CPU:
"u", "uu", "uuu", "uuuu", "uuuuu", "uuuuuu", "uuuuuuu", "uuuuuuuu", "uuuuuuuuu", "uuuuuuuuuu",
"y", yyy", "yyyyy", "yyyyyy", "yyyyyyy", "yyyyyyyy", "yyyyyyyyy", "yyyyyyyyyy",
"D", "DD", "DDD", "s", "m", "H", "h", "M", "MMM", "MMMM", "MMMMM", "L", "LLL", "LLLL", "LLLLL",
"d", "S", "SS", "SSSS", "SSSSS", "SSSSSSSSS", "SSSSSSS", "SSSSSSSS"
Note that this list differs very slightly from the list given in the previous section for parsing
strings to dates because the two-digit year format "yy"
is supported when formatting dates as
strings but not when parsing strings to dates.
In general, performing cast
and ansi_cast
operations on the GPU is compatible with the same
operations on the CPU. However, there are some exceptions. For this reason, certain casts are
disabled on the GPU by default and require configuration options to be specified to enable them.
The GPU will use a different strategy from Java's BigDecimal to handle/store decimal values, which leads to restrictions:
- Float values cannot be larger than
1e18
or smaller than-1e18
after conversion. - The results produced by GPU slightly differ from the default results of Spark.
This configuration is enabled by default. To disable this operation on the GPU set
spark.rapids.sql.castFloatToDecimal.enabled
to false
With both cast
and ansi_cast
, Spark uses the expression Math.floor(x) <= MAX && Math.ceil(x) >= MIN
to determine whether a floating-point value can be converted to an integral type. Prior to
Spark 3.1.0 the MIN and MAX values were floating-point values such as Int.MaxValue.toFloat
but
starting with 3.1.0 these are now integral types such as Int.MaxValue
so this has slightly
affected the valid range of values and now differs slightly from the behavior on GPU in some cases.
This configuration is enabled by default. To disable this operation on the GPU set
spark.rapids.sql.castFloatToIntegralTypes.enabled
to false
.
The Rapids Accelerator for Apache Spark uses uses a method based on ryu when converting floating point data type to string. As a result the computed string can differ from the output of Spark in some cases: sometimes the output is shorter (which is arguably more accurate) and sometimes the output may differ in the precise digits output.
This configuration is enabled by default. To disable this operation on the GPU set
spark.rapids.sql.castFloatToString.enabled
to false
.
The format_number
function also uses ryu as the solution when formatting floating-point data types to
strings, so results may differ from Spark in the same way. To disable this on the GPU, set
spark.rapids.sql.formatNumberFloat.enabled
to false
.
Casting from string to double on the GPU returns incorrect results when the string represents any
number in the following ranges. In both cases the GPU returns Double.MaxValue
. The default behavior
in Apache Spark is to return +Infinity
and -Infinity
, respectively.
1.7976931348623158E308 <= x < 1.7976931348623159E308
-1.7976931348623159E308 < x <= -1.7976931348623158E308
Casting from string to double on the GPU could also sometimes return incorrect results if the string contains high precision values. Apache Spark rounds the values to the nearest double, while the GPU truncates the values directly.
Also, the GPU does not support casting from strings containing hex values to floating-point types.
This configuration is enabled by default. To disable this operation on the GPU set
spark.rapids.sql.castStringToFloat.enabled
to false
.
The following formats/patterns are supported on the GPU. Timezone of UTC is assumed.
Format or Pattern | Supported on GPU? |
---|---|
"yyyy" |
Yes |
"yyyy-[M]M" |
Yes |
"yyyy-[M]M " |
Yes |
"yyyy-[M]M-[d]d" |
Yes |
"yyyy-[M]M-[d]d " |
Yes |
"yyyy-[M]M-[d]d *" |
Yes |
"yyyy-[M]M-[d]d T*" |
Yes |
"epoch" |
Yes |
"now" |
Yes |
"today" |
Yes |
"tomorrow" |
Yes |
"yesterday" |
Yes |
To allow casts from string to timestamp on the GPU, enable the configuration property
spark.rapids.sql.castStringToTimestamp.enabled
.
Casting from string to timestamp currently has the following limitations.
Format or Pattern | Supported on GPU? |
---|---|
"yyyy" |
Yes |
"yyyy-[M]M" |
Yes |
"yyyy-[M]M " |
Yes |
"yyyy-[M]M-[d]d" |
Yes |
"yyyy-[M]M-[d]d " |
Yes |
"yyyy-[M]M-[d]dT[h]h:[m]m:[s]s[zone_id]" |
Partial [1] |
"yyyy-[M]M-[d]d [h]h:[m]m:[s]s[zone_id]" |
Partial [1] |
"yyyy-[M]M-[d]dT[h]h:[m]m:[s]s.[ms][ms][ms][us][us][us][zone_id]" |
Partial [1] |
"yyyy-[M]M-[d]d [h]h:[m]m:[s]s.[ms][ms][ms][us][us][us][zone_id]" |
Partial [1] |
"[h]h:[m]m:[s]s.[ms][ms][ms][us][us][us][zone_id]" |
Partial [1] |
"T[h]h:[m]m:[s]s.[ms][ms][ms][us][us][us][zone_id]" |
Partial [1] |
"epoch" |
Yes |
"now" |
Yes |
"today" |
Yes |
"tomorrow" |
Yes |
"yesterday" |
Yes |
- [1] Leap seconds are not supported. If a zone_id is provided then only timezone 'Z' (UTC) is supported. Casting unsupported formats will result in null values.
Spark is very lenient when casting from string to timestamp because all date and time components
are optional, meaning that input values such as T
, T2
, :
, ::
, 1:
, :1
, and ::1
are considered valid timestamps. The GPU will treat these values as invalid and cast them to null
values.
ConstantFolding is an operator optimization rule in Catalyst that replaces expressions that can
be statically evaluated with their equivalent literal values. The RAPIDS Accelerator relies
on constant folding and parts of the query will not be accelerated if
org.apache.spark.sql.catalyst.optimizer.ConstantFolding
is excluded as a rule.
Spark 330+ has an issue when casting a big enough long/double as timestamp, refer to https://issues.apache.org/jira/browse/SPARK-39209. Spark 330+ throws errors while the RAPIDS Accelerator can handle correctly when casting a big enough long/double as timestamp.
The 0.5 release introduces the get_json_object
operation. The JSON specification only allows
double quotes around strings in JSON data, whereas Spark allows single quotes around strings in JSON
data. The RAPIDS Spark get_json_object
operation on the GPU will return None
in PySpark or
Null
in Scala when trying to match a string surrounded by single quotes. This behavior will be
updated in a future release to more closely match Spark.
If the JSON has a single quote '
in the path, the GPU query may fail with ai.rapids.cudf.CudfException
.
More examples are in issue-12483.
The GPU implementation of approximate_percentile
uses
t-Digests which have high accuracy, particularly near the tails of a
distribution. The results are not bit-for-bit identical with the Apache Spark implementation of
approximate_percentile
. This feature is enabled by default and can be disabled by setting
spark.rapids.sql.expression.ApproximatePercentile=false
.
In Apache Spark condition operations like if
, coalesce
, and case/when
lazily evaluate
their parameters on a row by row basis. On the GPU it is generally more efficient to
evaluate the parameters regardless of the condition and then select which result to return
based on the condition. This is fine so long as there are no side effects caused by evaluating
a parameter. For most expressions in Spark this is true, but in ANSI mode many expressions can
throw exceptions, like for the Add
expression if an overflow happens. This is also true of
UDFs, because by their nature they are user defined and can have side effects like throwing
exceptions.
Currently, the RAPIDS Accelerator assumes that there are no side effects. This can result it situations, specifically in ANSI mode, where the RAPIDS Accelerator will always throw an exception, but Spark on the CPU will not. For example:
spark.conf.set("spark.sql.ansi.enabled", "true")
Seq(0L, Long.MaxValue).toDF("val")
.repartition(1) // The repartition makes Spark not optimize selectExpr away
.selectExpr("IF(val > 1000, null, val + 1) as ret")
.show()
If the above example is run on the CPU you will get a result like.
+----+
| ret|
+----+
| 1|
|null|
+----+
But if it is run on the GPU an overflow exception is thrown. As was explained before this
is because the RAPIDS Accelerator will evaluate both val + 1
and null
regardless of
the result of the condition. In some cases you can work around this. The above example
could be re-written so the if
happens before the Add
operation.
Seq(0L, Long.MaxValue).toDF("val")
.repartition(1) // The repartition makes Spark not optimize selectExpr away
.selectExpr("IF(val > 1000, null, val) + 1 as ret")
.show()
But this is not something that can be done generically and requires inner knowledge about what can trigger a side effect.