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logical_type.go
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logical_type.go
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// Copyright [2019] LinkedIn Corp. Licensed under the Apache License, Version
// 2.0 (the "License"); you may not use this file except in compliance with the
// License. You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
package goavro
import (
"errors"
"fmt"
"math/big"
"regexp"
"strings"
"time"
)
type toNativeFn func([]byte) (interface{}, []byte, error)
type fromNativeFn func([]byte, interface{}) ([]byte, error)
var reFromPattern = make(map[string]*regexp.Regexp)
// ////////////////////////////////////////////////////////////////////////////////////////////
// date logical type - to/from time.Time, time.UTC location
// ////////////////////////////////////////////////////////////////////////////////////////////
func nativeFromDate(fn toNativeFn) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
l, b, err := fn(bytes)
if err != nil {
return l, b, err
}
i, ok := l.(int32)
if !ok {
return l, b, fmt.Errorf("cannot transform to native date, expected int, received %T", l)
}
t := time.Date(1970, 1, 1, 0, 0, 0, 0, time.UTC).AddDate(0, 0, int(i)).UTC()
return t, b, nil
}
}
func dateFromNative(fn fromNativeFn) fromNativeFn {
return func(b []byte, d interface{}) ([]byte, error) {
switch val := d.(type) {
case int, int32, int64, float32, float64:
// "Language implementations may choose to represent logical types with an appropriate native type, although this is not required."
// especially permitted default values depend on the field's schema type and goavro encodes default values using the field schema
return fn(b, val)
case time.Time:
// rephrasing the avro 1.9.2 spec a date is actually stored as the duration since unix epoch in days
// time.Unix() returns this duration in seconds and time.UnixNano() in nanoseconds
// reviewing the source code, both functions are based on the internal function unixSec()
// unixSec() returns the seconds since unix epoch as int64, whereby Unix() provides the greater range and UnixNano() the higher precision
// As a date requires a precision of days Unix() provides more then enough precision and a greater range, including the go zero time
numDays := val.Unix() / 86400
return fn(b, numDays)
default:
return nil, fmt.Errorf("cannot transform to binary date, expected time.Time or Go numeric, received %T", d)
}
}
}
// ////////////////////////////////////////////////////////////////////////////////////////////
// time-millis logical type - to/from time.Time, time.UTC location
// ////////////////////////////////////////////////////////////////////////////////////////////
func nativeFromTimeMillis(fn toNativeFn) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
l, b, err := fn(bytes)
if err != nil {
return l, b, err
}
i, ok := l.(int32)
if !ok {
return l, b, fmt.Errorf("cannot transform to native time.Duration, expected int, received %T", l)
}
t := time.Duration(i) * time.Millisecond
return t, b, nil
}
}
func timeMillisFromNative(fn fromNativeFn) fromNativeFn {
return func(b []byte, d interface{}) ([]byte, error) {
switch val := d.(type) {
case int, int32, int64, float32, float64:
// "Language implementations may choose to represent logical types with an appropriate native type, although this is not required."
// especially permitted default values depend on the field's schema type and goavro encodes default values using the field schema
return fn(b, val)
case time.Duration:
duration := int32(val.Nanoseconds() / int64(time.Millisecond))
return fn(b, duration)
default:
return nil, fmt.Errorf("cannot transform to binary time-millis, expected time.Duration or Go numeric, received %T", d)
}
}
}
// ////////////////////////////////////////////////////////////////////////////////////////////
// time-micros logical type - to/from time.Time, time.UTC location
// ////////////////////////////////////////////////////////////////////////////////////////////
func nativeFromTimeMicros(fn toNativeFn) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
l, b, err := fn(bytes)
if err != nil {
return l, b, err
}
i, ok := l.(int64)
if !ok {
return l, b, fmt.Errorf("cannot transform to native time.Duration, expected long, received %T", l)
}
t := time.Duration(i) * time.Microsecond
return t, b, nil
}
}
func timeMicrosFromNative(fn fromNativeFn) fromNativeFn {
return func(b []byte, d interface{}) ([]byte, error) {
switch val := d.(type) {
case int, int32, int64, float32, float64:
// "Language implementations may choose to represent logical types with an appropriate native type, although this is not required."
// especially permitted default values depend on the field's schema type and goavro encodes default values using the field schema
return fn(b, val)
case time.Duration:
duration := val.Nanoseconds() / int64(time.Microsecond)
return fn(b, duration)
default:
return nil, fmt.Errorf("cannot transform to binary time-micros, expected time.Duration or Go numeric, received %T", d)
}
}
}
// ////////////////////////////////////////////////////////////////////////////////////////////
// timestamp-millis logical type - to/from time.Time, time.UTC location
// ////////////////////////////////////////////////////////////////////////////////////////////
func nativeFromTimeStampMillis(fn toNativeFn) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
l, b, err := fn(bytes)
if err != nil {
return l, b, err
}
milliseconds, ok := l.(int64)
if !ok {
return l, b, fmt.Errorf("cannot transform native timestamp-millis, expected int64, received %T", l)
}
seconds := milliseconds / 1e3
nanoseconds := (milliseconds - (seconds * 1e3)) * 1e6
return time.Unix(seconds, nanoseconds).UTC(), b, nil
}
}
func timeStampMillisFromNative(fn fromNativeFn) fromNativeFn {
return func(b []byte, d interface{}) ([]byte, error) {
switch val := d.(type) {
case int, int32, int64, float32, float64:
// "Language implementations may choose to represent logical types with an appropriate native type, although this is not required."
// especially permitted default values depend on the field's schema type and goavro encodes default values using the field schema
return fn(b, val)
case time.Time:
// While this code performs a few more steps than seem required, it is
// written this way to allow the best time resolution without overflowing the int64 value.
return fn(b, val.Unix()*1e3+int64(val.Nanosecond()/1e6))
default:
return nil, fmt.Errorf("cannot transform to binary timestamp-millis, expected time.Time or Go numeric, received %T", d)
}
}
}
// ////////////////////////////////////////////////////////////////////////////////////////////
// timestamp-micros logical type - to/from time.Time, time.UTC location
// ////////////////////////////////////////////////////////////////////////////////////////////
func nativeFromTimeStampMicros(fn toNativeFn) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
l, b, err := fn(bytes)
if err != nil {
return l, b, err
}
microseconds, ok := l.(int64)
if !ok {
return l, b, fmt.Errorf("cannot transform native timestamp-micros, expected int64, received %T", l)
}
// While this code performs a few more steps than seem required, it is
// written this way to allow the best time resolution on UNIX and
// Windows without overflowing the int64 value. Windows has a zero-time
// value of 1601-01-01 UTC, and the number of nanoseconds since that
// zero-time overflows 64-bit integers.
seconds := microseconds / 1e6
nanoseconds := (microseconds - (seconds * 1e6)) * 1e3
return time.Unix(seconds, nanoseconds).UTC(), b, nil
}
}
func timeStampMicrosFromNative(fn fromNativeFn) fromNativeFn {
return func(b []byte, d interface{}) ([]byte, error) {
switch val := d.(type) {
case int, int32, int64, float32, float64:
// "Language implementations may choose to represent logical types with an appropriate native type, although this is not required."
// especially permitted default values depend on the field's schema type and goavro encodes default values using the field schema
return fn(b, val)
case time.Time:
// While this code performs a few more steps than seem required, it is
// written this way to allow the best time resolution on UNIX and
// Windows without overflowing the int64 value. Windows has a zero-time
// value of 1601-01-01 UTC, and the number of nanoseconds since that
// zero-time overflows 64-bit integers.
return fn(b, val.Unix()*1e6+int64(val.Nanosecond()/1e3))
default:
return nil, fmt.Errorf("cannot transform to binary timestamp-micros, expected time.Time or Go numeric, received %T", d)
}
}
}
/////////////////////////////////////////////////////////////////////////////////////////////
// decimal logical-type - byte/fixed - to/from math/big.Rat
// two's complement algorithm taken from:
// https://groups.google.com/d/msg/golang-nuts/TV4bRVrHZUw/UcQt7S4IYlcJ by rog
/////////////////////////////////////////////////////////////////////////////////////////////
func precisionAndScaleFromSchemaMap(schemaMap map[string]interface{}) (int, int, error) {
p1, ok := schemaMap["precision"]
if !ok {
return 0, 0, errors.New("cannot create decimal logical type without precision")
}
p2, ok := p1.(float64)
if !ok {
return 0, 0, fmt.Errorf("cannot create decimal logical type with wrong precision type; expected: float64; received: %T", p1)
}
p3 := int(p2)
if p3 < 1 {
return 0, 0, fmt.Errorf("cannot create decimal logical type when precision is less than one: %d", p3)
}
var s3 int // scale defaults to 0 if not set
if s1, ok := schemaMap["scale"]; ok {
s2, ok := s1.(float64)
if !ok {
return 0, 0, fmt.Errorf("cannot create decimal logical type with wrong scale type; expected: float64; received: %T", s1)
}
s3 = int(s2)
if s3 < 0 {
return 0, 0, fmt.Errorf("cannot create decimal logical type when scale is less than zero: %d", s3)
}
if s3 > p3 {
return 0, 0, fmt.Errorf("cannot create decimal logical type when scale is larger than precision: %d > %d", s3, p3)
}
}
return p3, s3, nil
}
var one = big.NewInt(1)
func makeDecimalBytesCodec(st map[string]*Codec, enclosingNamespace string, schemaMap map[string]interface{}) (*Codec, error) {
precision, scale, err := precisionAndScaleFromSchemaMap(schemaMap)
if err != nil {
return nil, err
}
if _, ok := schemaMap["name"]; !ok {
schemaMap["name"] = "bytes.decimal"
}
c, err := registerNewCodec(st, schemaMap, enclosingNamespace)
if err != nil {
return nil, fmt.Errorf("Bytes ought to have valid name: %s", err)
}
// Add an additional cached codec for this "bytes.decimal" keyed also by "precision" and "scale"
decimalSearchType := fmt.Sprintf("bytes.decimal.%d.%d", precision, scale)
st[decimalSearchType] = c
c.binaryFromNative = decimalBytesFromNative(bytesBinaryFromNative, toSignedBytes, precision, scale)
c.textualFromNative = decimalBytesFromNative(bytesTextualFromNative, toSignedBytes, precision, scale)
c.nativeFromBinary = nativeFromDecimalBytes(bytesNativeFromBinary, precision, scale)
c.nativeFromTextual = nativeFromDecimalBytes(bytesNativeFromTextual, precision, scale)
return c, nil
}
func nativeFromDecimalBytes(fn toNativeFn, precision, scale int) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
d, b, err := fn(bytes)
if err != nil {
return d, b, err
}
bs, ok := d.([]byte)
if !ok {
return nil, bytes, fmt.Errorf("cannot transform to native decimal, expected []byte, received %T", d)
}
num := big.NewInt(0)
fromSignedBytes(num, bs)
denom := new(big.Int).Exp(big.NewInt(10), big.NewInt(int64(scale)), nil)
r := new(big.Rat).SetFrac(num, denom)
return r, b, nil
}
}
func decimalBytesFromNative(fromNativeFn fromNativeFn, toBytesFn toBytesFn, precision, scale int) fromNativeFn {
return func(b []byte, d interface{}) ([]byte, error) {
r, ok := d.(*big.Rat)
if !ok {
return nil, fmt.Errorf("cannot transform to bytes, expected *big.Rat, received %T", d)
}
// Reduce accuracy to precision by dividing and multiplying by digit length
num := big.NewInt(0).Set(r.Num())
denom := big.NewInt(0).Set(r.Denom())
i := new(big.Int).Mul(num, new(big.Int).Exp(big.NewInt(10), big.NewInt(int64(scale)), nil))
// divide that by the denominator
precnum := new(big.Int).Div(i, denom)
bout, err := toBytesFn(precnum)
if err != nil {
return nil, err
}
return fromNativeFn(b, bout)
}
}
func makeDecimalFixedCodec(st map[string]*Codec, enclosingNamespace string, schemaMap map[string]interface{}) (*Codec, error) {
precision, scale, err := precisionAndScaleFromSchemaMap(schemaMap)
if err != nil {
return nil, err
}
if _, ok := schemaMap["name"]; !ok {
schemaMap["name"] = "fixed.decimal"
}
c, err := makeFixedCodec(st, enclosingNamespace, schemaMap)
if err != nil {
return nil, err
}
size, err := sizeFromSchemaMap(c.typeName, schemaMap)
if err != nil {
return nil, err
}
c.binaryFromNative = decimalBytesFromNative(c.binaryFromNative, toSignedFixedBytes(size), precision, scale)
c.textualFromNative = decimalBytesFromNative(c.textualFromNative, toSignedFixedBytes(size), precision, scale)
c.nativeFromBinary = nativeFromDecimalBytes(c.nativeFromBinary, precision, scale)
c.nativeFromTextual = nativeFromDecimalBytes(c.nativeFromTextual, precision, scale)
return c, nil
}
func makeValidatedStringCodec(st map[string]*Codec, enclosingNamespace string, schemaMap map[string]interface{}) (*Codec, error) {
pattern, ok := schemaMap["pattern"]
if !ok {
return nil, errors.New("cannot create validated-string logical type without pattern")
}
patternStr := strings.TrimSpace(pattern.(string))
if reFromPattern[patternStr] == nil {
var (
regexpr *regexp.Regexp
err error
)
if regexpr, err = regexp.Compile(patternStr); err != nil {
return nil, err
}
reFromPattern[patternStr] = regexpr
}
if _, ok := schemaMap["name"]; !ok {
schemaMap["name"] = "string.validated-string"
}
c, err := registerNewCodec(st, schemaMap, enclosingNamespace)
if err != nil {
return nil, err
}
c.binaryFromNative = validatedStringBinaryFromNative(c.binaryFromNative)
c.textualFromNative = validatedStringTextualFromNative(c.textualFromNative)
c.nativeFromBinary = validatedStringNativeFromBinary(c.nativeFromBinary, patternStr)
c.nativeFromTextual = validatedStringNativeFromTextual(c.nativeFromTextual, patternStr)
return c, nil
}
func validatedStringBinaryFromNative(fromNativeFn fromNativeFn) fromNativeFn {
return stringBinaryFromNative
}
func validatedStringTextualFromNative(fromNativeFn fromNativeFn) fromNativeFn {
return stringTextualFromNative
}
func validatedStringNativeFromBinary(fn toNativeFn, pattern string) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
fn, newBytes, err := stringNativeFromBinary(bytes)
if err != nil {
return nil, nil, err
}
result := fn.(string)
if ok := reFromPattern[pattern].MatchString(result); !ok {
return nil, bytes, fmt.Errorf("cannot match input string against validation pattern: %q does not match %q", result, pattern)
}
return fn, newBytes, nil
}
}
func validatedStringNativeFromTextual(fn toNativeFn, pattern string) toNativeFn {
return func(bytes []byte) (interface{}, []byte, error) {
fn, newBytes, err := stringNativeFromTextual(bytes)
if err != nil {
return nil, nil, err
}
result := fn.(string)
if ok := reFromPattern[pattern].MatchString(result); !ok {
return nil, bytes, fmt.Errorf("cannot match input string against validation pattern: %q does not match %q", result, pattern)
}
return fn, newBytes, nil
}
}
func padBytes(bytes []byte, fixedSize uint) []byte {
s := int(fixedSize)
padded := make([]byte, s)
if s >= len(bytes) {
copy(padded[s-len(bytes):], bytes)
}
return padded
}
type toBytesFn func(n *big.Int) ([]byte, error)
// fromSignedBytes sets the value of n to the big-endian two's complement
// value stored in the given data. If data[0]&80 != 0, the number
// is negative. If data is empty, the result will be 0.
func fromSignedBytes(n *big.Int, data []byte) {
n.SetBytes(data)
if len(data) > 0 && data[0]&0x80 > 0 {
n.Sub(n, new(big.Int).Lsh(one, uint(len(data))*8))
}
}
// toSignedBytes returns the big-endian two's complement
// form of n.
func toSignedBytes(n *big.Int) ([]byte, error) {
switch n.Sign() {
case 0:
return []byte{0}, nil
case 1:
b := n.Bytes()
if b[0]&0x80 > 0 {
b = append([]byte{0}, b...)
}
return b, nil
case -1:
length := uint(n.BitLen()/8+1) * 8
b := new(big.Int).Add(n, new(big.Int).Lsh(one, length)).Bytes()
// When the most significant bit is on a byte
// boundary, we can get some extra significant
// bits, so strip them off when that happens.
if len(b) >= 2 && b[0] == 0xff && b[1]&0x80 != 0 {
b = b[1:]
}
return b, nil
}
return nil, fmt.Errorf("toSignedBytes: error big.Int.Sign() returned unexpected value")
}
// toSignedFixedBytes returns the big-endian two's complement
// form of n for a given length of bytes.
func toSignedFixedBytes(size uint) func(*big.Int) ([]byte, error) {
return func(n *big.Int) ([]byte, error) {
switch n.Sign() {
case 0:
return []byte{0}, nil
case 1:
b := n.Bytes()
if b[0]&0x80 > 0 {
b = append([]byte{0}, b...)
}
return padBytes(b, size), nil
case -1:
length := size * 8
b := new(big.Int).Add(n, new(big.Int).Lsh(one, length)).Bytes()
// Unlike a variable length byte length we need the extra bits to meet byte length
return b, nil
}
return nil, fmt.Errorf("toSignedBytes: error big.Int.Sign() returned unexpected value")
}
}