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decimal/decimal_test.go

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init
2015-02-10 21:33:58 +01:00
package decimal
import (
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
"database/sql/driver"
Add round-trip JSON test.
2015-03-23 23:07:27 +01:00
"encoding/json"
Add XML test.
2015-03-23 23:14:19 +01:00
"encoding/xml"
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"fmt"
init
2015-02-10 21:33:58 +01:00
"math"
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
"math/big"
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"math/rand"
Remove insignificant digits during string parsing
2017-02-07 18:33:26 +01:00
"reflect"
Implement new initialization function - NewFromFormattedString (#184) * Implement new initialization function - NewFromFormattedString * Redefine docstring
2020-09-14 19:29:03 +02:00
"regexp"
Fix possible int64 overflow and remove unnecessary code
2015-07-31 18:36:54 +02:00
"strconv"
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
"strings"
init
2015-02-10 21:33:58 +01:00
"testing"
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"testing/quick"
add stupid test for extreme values, fix some super-edge-case bugs
2015-06-14 21:39:05 +02:00
"time"
init
2015-02-10 21:33:58 +01:00
)
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
type testEnt struct {
Testing Float64 (#82) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations * Subnormal test added * Float64: adding tests
2018-03-01 22:31:53 +01:00
float float64
short string
exact string
inexact string
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
}
var testTable = []*testEnt{
Testing Float64 (#82) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations * Subnormal test added * Float64: adding tests
2018-03-01 22:31:53 +01:00
{3.141592653589793, "3.141592653589793", "", "3.14159265358979300000000000000000000000000000000000004"},
{3, "3", "", "3.0000000000000000000000002"},
{1234567890123456, "1234567890123456", "", "1234567890123456.00000000000000002"},
{1234567890123456000, "1234567890123456000", "", "1234567890123456000.0000000000000008"},
{1234.567890123456, "1234.567890123456", "", "1234.5678901234560000000000000009"},
{.1234567890123456, "0.1234567890123456", "", "0.12345678901234560000000000006"},
{0, "0", "", "0.000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001"},
{.1111111111111110, "0.111111111111111", "", "0.111111111111111000000000000000009"},
{.1111111111111111, "0.1111111111111111", "", "0.111111111111111100000000000000000000023423545644534234"},
{.1111111111111119, "0.1111111111111119", "", "0.111111111111111900000000000000000000000000000000000134123984192834"},
{.000000000000000001, "0.000000000000000001", "", "0.00000000000000000100000000000000000000000000000000012341234"},
{.000000000000000002, "0.000000000000000002", "", "0.0000000000000000020000000000000000000012341234123"},
{.000000000000000003, "0.000000000000000003", "", "0.00000000000000000299999999999999999999999900000000000123412341234"},
{.000000000000000005, "0.000000000000000005", "", "0.00000000000000000500000000000000000023412341234"},
{.000000000000000008, "0.000000000000000008", "", "0.0000000000000000080000000000000000001241234432"},
{.1000000000000001, "0.1000000000000001", "", "0.10000000000000010000000000000012341234"},
{.1000000000000002, "0.1000000000000002", "", "0.10000000000000020000000000001234123412"},
{.1000000000000003, "0.1000000000000003", "", "0.1000000000000003000000000000001234123412"},
{.1000000000000005, "0.1000000000000005", "", "0.1000000000000005000000000000000006441234"},
{.1000000000000008, "0.1000000000000008", "", "0.100000000000000800000000000000000009999999999999999999999999999"},
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
{1e25, "10000000000000000000000000", "", ""},
{1.5e14, "150000000000000", "", ""},
{1.5e15, "1500000000000000", "", ""},
{1.5e16, "15000000000000000", "", ""},
{1.0001e25, "10001000000000000000000000", "", ""},
{1.0001000000000000033e25, "10001000000000000000000000", "", ""},
{2e25, "20000000000000000000000000", "", ""},
{4e25, "40000000000000000000000000", "", ""},
{8e25, "80000000000000000000000000", "", ""},
{1e250, "10000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000", "", ""},
{2e250, "20000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000", "", ""},
{math.MaxInt64, strconv.FormatFloat(float64(math.MaxInt64), 'f', -1, 64), "", strconv.FormatInt(math.MaxInt64, 10)},
{1.29067116156722e-309, "0.00000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000129067116156722", "", "0.000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001290671161567218558822290567835270536800098852722416870074139002112543896676308448335063375297788379444685193974290737962187240854947838776604607190387984577130572928111657710645015086812756013489109884753559084166516937690932698276436869274093950997935137476803610007959500457935217950764794724766740819156974617155861568214427828145972181876775307023388139991104942469299524961281641158436752347582767153796914843896176260096039358494077706152272661453132497761307744086665088096215425146090058519888494342944692629602847826300550628670375451325582843627504604013541465361435761965354140678551369499812124085312128659002910905639984075064968459581691226705666561364681985266583563078466180095375402399087817404368974165082030458595596655868575908243656158447265625000000000000000000000000000000000000004440000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000"},
fix the rounding bug in roundShortest method (#161) * fix: fix rounding in FormatFloat fallback path
2020-07-07 09:05:46 +02:00
// go Issue 29491.
{498484681984085570, "498484681984085570", "", ""},
{5.8339553793802237e+23, "583395537938022370000000", "", ""},
init
2015-02-10 21:33:58 +01:00
}
Add scientific notation parsing
2015-07-24 18:16:41 +02:00
var testTableScientificNotation = map[string]string{
Add negative numbers on init() and add more tests
2015-07-28 13:27:48 +02:00
"1e9": "1000000000",
"2.41E-3": "0.00241",
"24.2E-4": "0.00242",
"243E-5": "0.00243",
"1e-5": "0.00001",
"245E3": "245000",
"1.2345E-1": "0.12345",
"0e5": "0",
"0e-5": "0",
Fix decoding of .0 Since trailing 0 digits after the decimal point are trimmed, intString becomes an empty string when there is no digit before the decimal point and all digits after the decimal point is 0, causing big.Int SetString to fail because there is no string to parse. Fix #134.
2019-02-19 10:00:26 +01:00
"0.e0": "0",
".0e0": "0",
Add negative numbers on init() and add more tests
2015-07-28 13:27:48 +02:00
"123.456e0": "123.456",
"123.456e2": "12345.6",
"123.456e10": "1234560000000",
Add scientific notation parsing
2015-07-24 18:16:41 +02:00
}
Add negative test values once.
2015-03-23 23:02:29 +01:00
func init() {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, s := range testTable {
Testing Float64 (#82) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations * Subnormal test added * Float64: adding tests
2018-03-01 22:31:53 +01:00
s.exact = strconv.FormatFloat(s.float, 'f', 1500, 64)
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
if strings.ContainsRune(s.exact, '.') {
s.exact = strings.TrimRight(s.exact, "0")
s.exact = strings.TrimRight(s.exact, ".")
}
}
init
2015-02-10 21:33:58 +01:00
// add negatives
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
withNeg := testTable[:]
for _, s := range testTable {
Testing Float64 (#82) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations * Subnormal test added * Float64: adding tests
2018-03-01 22:31:53 +01:00
if s.float > 0 && s.short != "0" && s.exact != "0" {
withNeg = append(withNeg, &testEnt{-s.float, "-" + s.short, "-" + s.exact, "-" + s.inexact})
init
2015-02-10 21:33:58 +01:00
}
}
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
testTable = withNeg
Add negative numbers on init() and add more tests
2015-07-28 13:27:48 +02:00
for e, s := range testTableScientificNotation {
if string(e[0]) != "-" && s != "0" {
testTableScientificNotation["-"+e] = "-" + s
}
}
Add negative test values once.
2015-03-23 23:02:29 +01:00
}
init
2015-02-10 21:33:58 +01:00
Add negative test values once.
2015-03-23 23:02:29 +01:00
func TestNewFromFloat(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, x := range testTable {
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
s := x.short
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
d := NewFromFloat(x.float)
init
2015-02-10 21:33:58 +01:00
if d.String() != s {
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
t.Errorf("expected %s, got %s (float: %v) (%s, %d)",
s, d.String(), x.float,
init
2015-02-10 21:33:58 +01:00
d.value.String(), d.exp)
}
}
shouldPanicOn := []float64{
math.NaN(),
math.Inf(1),
math.Inf(-1),
}
for _, n := range shouldPanicOn {
var d Decimal
if !didPanic(func() { d = NewFromFloat(n) }) {
t.Fatalf("Expected panic when creating a Decimal from %v, got %v instead", n, d.String())
}
}
}
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
func TestNewFromFloatRandom(t *testing.T) {
n := 0
rng := rand.New(rand.NewSource(0xdead1337))
for {
n++
if n == 10 {
break
}
in := (rng.Float64() - 0.5) * math.MaxFloat64 * 2
want, err := NewFromString(strconv.FormatFloat(in, 'f', -1, 64))
if err != nil {
t.Error(err)
continue
}
got := NewFromFloat(in)
if !want.Equal(got) {
t.Errorf("in: %v, expected %s (%s, %d), got %s (%s, %d) ",
in, want.String(), want.value.String(), want.exp,
got.String(), got.value.String(), got.exp)
}
}
}
func TestNewFromFloatQuick(t *testing.T) {
err := quick.Check(func(f float64) bool {
want, werr := NewFromString(strconv.FormatFloat(f, 'f', -1, 64))
if werr != nil {
return true
}
got := NewFromFloat(f)
return got.Equal(want)
}, &quick.Config{})
if err != nil {
t.Error(err)
}
}
func TestNewFromFloat32Random(t *testing.T) {
n := 0
rng := rand.New(rand.NewSource(0xdead1337))
for {
n++
if n == 10 {
break
}
in := float32((rng.Float64() - 0.5) * math.MaxFloat32 * 2)
want, err := NewFromString(strconv.FormatFloat(float64(in), 'f', -1, 32))
if err != nil {
t.Error(err)
continue
}
got := NewFromFloat32(in)
if !want.Equal(got) {
t.Errorf("in: %v, expected %s (%s, %d), got %s (%s, %d) ",
in, want.String(), want.value.String(), want.exp,
got.String(), got.value.String(), got.exp)
}
}
}
func TestNewFromFloat32Quick(t *testing.T) {
err := quick.Check(func(f float32) bool {
want, werr := NewFromString(strconv.FormatFloat(float64(f), 'f', -1, 32))
if werr != nil {
return true
}
got := NewFromFloat32(f)
return got.Equal(want)
}, &quick.Config{})
if err != nil {
t.Error(err)
}
}
init
2015-02-10 21:33:58 +01:00
func TestNewFromString(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, x := range testTable {
s := x.short
d, err := NewFromString(s)
if err != nil {
t.Errorf("error while parsing %s", s)
} else if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
for _, x := range testTable {
s := x.exact
init
2015-02-10 21:33:58 +01:00
d, err := NewFromString(s)
if err != nil {
t.Errorf("error while parsing %s", s)
} else if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
Add scientific notation parsing
2015-07-24 18:16:41 +02:00
for e, s := range testTableScientificNotation {
d, err := NewFromString(e)
if err != nil {
t.Errorf("error while parsing %s", e)
} else if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
init
2015-02-10 21:33:58 +01:00
}
Implement new initialization function - NewFromFormattedString (#184) * Implement new initialization function - NewFromFormattedString * Redefine docstring
2020-09-14 19:29:03 +02:00
func TestNewFromFormattedString(t *testing.T) {
for _, testCase := range []struct {
Formatted string
Expected string
ReplRegex *regexp.Regexp
}{
{"$10.99", "10.99", regexp.MustCompile("[$]")},
{"$ 12.1", "12.1", regexp.MustCompile("[$\\s]")},
{"$61,690.99", "61690.99", regexp.MustCompile("[$,]")},
{"1_000_000.00", "1000000.00", regexp.MustCompile("[_]")},
{"41,410.00", "41410.00", regexp.MustCompile("[,]")},
{"5200 USD", "5200", regexp.MustCompile("[USD\\s]")},
} {
dFormatted, err := NewFromFormattedString(testCase.Formatted, testCase.ReplRegex)
if err != nil {
t.Fatal(err)
}
dExact, err := NewFromString(testCase.Expected)
if err != nil {
t.Fatal(err)
}
if !dFormatted.Equal(dExact) {
t.Errorf("expect %s, got %s", dExact, dFormatted)
}
}
}
Testing Float64 (#82) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations * Subnormal test added * Float64: adding tests
2018-03-01 22:31:53 +01:00
func TestFloat64(t *testing.T) {
for _, x := range testTable {
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
if x.inexact == "" || x.inexact == "-" {
continue
}
Testing Float64 (#82) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations * Subnormal test added * Float64: adding tests
2018-03-01 22:31:53 +01:00
s := x.exact
d, err := NewFromString(s)
if err != nil {
t.Errorf("error while parsing %s", s)
} else if f, exact := d.Float64(); !exact || f != x.float {
t.Errorf("cannot represent exactly %s", s)
}
s = x.inexact
d, err = NewFromString(s)
if err != nil {
t.Errorf("error while parsing %s", s)
} else if f, exact := d.Float64(); exact || f != x.float {
t.Errorf("%s should be represented inexactly", s)
}
}
}
init
2015-02-10 21:33:58 +01:00
func TestNewFromStringErrs(t *testing.T) {
tests := []string{
"",
"qwert",
"-",
".",
"-.",
".-",
"234-.56",
"234-56",
"2-",
"..",
"2..",
"..2",
".5.2",
"8..2",
"8.1.",
Add scientific notation parsing
2015-07-24 18:16:41 +02:00
"1e",
"1-e",
"1e9e",
Add negative numbers on init() and add more tests
2015-07-28 13:27:48 +02:00
"1ee9",
"1ee",
fix some small issues with scientific notation, add more tests
2015-07-31 22:22:14 +02:00
"1eE",
"1e-",
"1e-.",
Add negative numbers on init() and add more tests
2015-07-28 13:27:48 +02:00
"1e1.2",
"123.456e1.3",
"1e-1.2",
"123.456e-1.3",
fix some small issues with scientific notation, add more tests
2015-07-31 22:22:14 +02:00
"123.456Easdf",
Fix possible int64 overflow and remove unnecessary code
2015-07-31 18:36:54 +02:00
"123.456e" + strconv.FormatInt(math.MinInt64, 10),
add one more extreme-value test for scientific notation parsing
2015-07-31 18:52:50 +02:00
"123.456e" + strconv.FormatInt(math.MinInt32, 10),
Implement new initialization function - NewFromFormattedString (#184) * Implement new initialization function - NewFromFormattedString * Redefine docstring
2020-09-14 19:29:03 +02:00
"512.99 USD",
"$99.99",
"51,850.00",
"20_000_000.00",
"$20_000_000.00",
init
2015-02-10 21:33:58 +01:00
}
for _, s := range tests {
_, err := NewFromString(s)
if err == nil {
t.Errorf("error expected when parsing %s", s)
}
}
}
Remove insignificant digits during string parsing
2017-02-07 18:33:26 +01:00
func TestNewFromStringDeepEquals(t *testing.T) {
type StrCmp struct {
str1 string
str2 string
expected bool
}
tests := []StrCmp{
gofmt -s decimal_test.go
2017-02-16 01:08:34 +01:00
{"1", "1", true},
Revert remove insignificant digits (#159) * revert original remove insignificant change (PR 46), and add the logic back as a function
2020-02-27 21:28:08 +01:00
{"1.0", "1.0", true},
{"10", "10.0", false},
{"1.1", "1.10", false},
gofmt -s decimal_test.go
2017-02-16 01:08:34 +01:00
{"1.001", "1.01", false},
Remove insignificant digits during string parsing
2017-02-07 18:33:26 +01:00
}
for _, cmp := range tests {
d1, err1 := NewFromString(cmp.str1)
d2, err2 := NewFromString(cmp.str2)
if err1 != nil || err2 != nil {
t.Errorf("error parsing strings to decimals")
}
if reflect.DeepEqual(d1, d2) != cmp.expected {
t.Errorf("comparison result is different from expected results for %s and %s",
cmp.str1, cmp.str2)
}
}
}
RequireFromString (#73) fmt
2018-03-01 22:32:36 +01:00
func TestRequireFromString(t *testing.T) {
s := "1.23"
defer func() {
err := recover()
if err != nil {
t.Errorf("error while parsing %s", s)
}
}()
d := RequireFromString(s)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
func TestRequireFromStringErrs(t *testing.T) {
s := "qwert"
var d Decimal
var err interface{}
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
func(d Decimal) {
RequireFromString (#73) fmt
2018-03-01 22:32:36 +01:00
defer func() {
err = recover()
}()
Improve go report cards score (#174) * Improve go report cards score
2020-04-27 08:03:21 +02:00
RequireFromString(s)
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}(d)
RequireFromString (#73) fmt
2018-03-01 22:32:36 +01:00
if err == nil {
t.Errorf("panic expected when parsing %s", s)
}
}
init
2015-02-10 21:33:58 +01:00
func TestNewFromFloatWithExponent(t *testing.T) {
type Inp struct {
float float64
exp int32
}
Addressing rounding and overflow issues in NewFromFloatWithExponent (#77) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:13 +01:00
// some tests are taken from here https://www.cockroachlabs.com/blog/rounding-implementations-in-go/
init
2015-02-10 21:33:58 +01:00
tests := map[Inp]string{
Addressing rounding and overflow issues in NewFromFloatWithExponent (#77) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:13 +01:00
Inp{123.4, -3}: "123.4",
Inp{123.4, -1}: "123.4",
Inp{123.412345, 1}: "120",
Inp{123.412345, 0}: "123",
Inp{123.412345, -5}: "123.41235",
Inp{123.412345, -6}: "123.412345",
Inp{123.412345, -7}: "123.412345",
Inp{123.412345, -28}: "123.4123450000000019599610823207",
Inp{1230000000, 3}: "1230000000",
Inp{123.9999999999999999, -7}: "124",
Inp{123.8989898999999999, -7}: "123.8989899",
Inp{0.49999999999999994, 0}: "0",
Inp{0.5, 0}: "1",
Inp{0., -1000}: "0",
Inp{0.5000000000000001, 0}: "1",
Inp{1.390671161567e-309, 0}: "0",
Inp{4.503599627370497e+15, 0}: "4503599627370497",
Inp{4.503599627370497e+60, 0}: "4503599627370497110902645731364739935039854989106233267453952",
Inp{4.503599627370497e+60, 1}: "4503599627370497110902645731364739935039854989106233267453950",
Inp{4.503599627370497e+60, -1}: "4503599627370497110902645731364739935039854989106233267453952",
Inp{50, 2}: "100",
Inp{49, 2}: "0",
Inp{50, 3}: "0",
// subnormals
Inp{1.390671161567e-309, -2000}: "0.000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000001390671161567000864431395448332752540137009987788957394095829635554502771758698872408926974382819387852542087331897381878220271350970912568035007740861074263206736245957501456549756342151614772544950978154339064833880234531754156635411349342950306987480369774780312897442981323940546749863054846093718407237782253156822124910364044261653195961209878120072488178603782495270845071470243842997312255994555557251870400944414666445871039673491570643357351279578519863428540219295076767898526278029257129758694673164251056158277568765100904638511604478844087596428177947970563689475826736810456067108202083804368114484417399279328807983736233036662284338182105684628835292230438999173947056675615385756827890872955322265625",
Inp{1.390671161567e-309, -862}: "0.0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000013906711615670008644313954483327525401370099877889573940958296355545027717586988724089269743828193878525420873318973818782202713509709125680350077408610742632067362459575014565497563421516147725449509781543390648338802345317541566354113493429503069874803697747803128974429813239405467498630548460937184072377822531568221249103640442616531959612098781200724881786037824952708450714702438429973122559945555572518704009444146664458710396734915706433573512795785198634285402192950767678985262780292571297586946731642510561582775687651009046385116044788440876",
Inp{1.390671161567e-309, -863}: "0.0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000013906711615670008644313954483327525401370099877889573940958296355545027717586988724089269743828193878525420873318973818782202713509709125680350077408610742632067362459575014565497563421516147725449509781543390648338802345317541566354113493429503069874803697747803128974429813239405467498630548460937184072377822531568221249103640442616531959612098781200724881786037824952708450714702438429973122559945555572518704009444146664458710396734915706433573512795785198634285402192950767678985262780292571297586946731642510561582775687651009046385116044788440876",
init
2015-02-10 21:33:58 +01:00
}
// add negatives
for p, s := range tests {
if p.float > 0 {
Addressing rounding and overflow issues in NewFromFloatWithExponent (#77) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:13 +01:00
if s != "0" {
tests[Inp{-p.float, p.exp}] = "-" + s
} else {
tests[Inp{-p.float, p.exp}] = "0"
}
init
2015-02-10 21:33:58 +01:00
}
}
for input, s := range tests {
d := NewFromFloatWithExponent(input.float, input.exp)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
shouldPanicOn := []float64{
math.NaN(),
math.Inf(1),
math.Inf(-1),
}
for _, n := range shouldPanicOn {
var d Decimal
if !didPanic(func() { d = NewFromFloatWithExponent(n, 0) }) {
t.Fatalf("Expected panic when creating a Decimal from %v, got %v instead", n, d.String())
}
}
}
Add NewFromInt and NewFromInt32 (#72) Add NewFromInt and NewFromInt32
2019-11-29 06:17:06 +01:00
func TestNewFromInt(t *testing.T) {
tests := map[int64]string{
Add NewFromUint64 constructor (#352)
2024-04-08 16:38:20 +02:00
0: "0",
1: "1",
323412345: "323412345",
9223372036854775807: "9223372036854775807",
-9223372036854775808: "-9223372036854775808",
Add NewFromInt and NewFromInt32 (#72) Add NewFromInt and NewFromInt32
2019-11-29 06:17:06 +01:00
}
// add negatives
for p, s := range tests {
if p > 0 {
tests[-p] = "-" + s
}
}
for input, s := range tests {
d := NewFromInt(input)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
}
func TestNewFromInt32(t *testing.T) {
tests := map[int32]string{
Add NewFromUint64 constructor (#352)
2024-04-08 16:38:20 +02:00
0: "0",
1: "1",
323412345: "323412345",
2147483647: "2147483647",
-2147483648: "-2147483648",
Add NewFromInt and NewFromInt32 (#72) Add NewFromInt and NewFromInt32
2019-11-29 06:17:06 +01:00
}
// add negatives
for p, s := range tests {
if p > 0 {
tests[-p] = "-" + s
}
}
for input, s := range tests {
d := NewFromInt32(input)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
}
Add NewFromUint64 constructor (#352)
2024-04-08 16:38:20 +02:00
func TestNewFromUint64(t *testing.T) {
tests := map[uint64]string{
0: "0",
1: "1",
323412345: "323412345",
9223372036854775807: "9223372036854775807",
18446744073709551615: "18446744073709551615",
}
for input, s := range tests {
d := NewFromUint64(input)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
}
Added NewFromBigInt constructor & unit test (#56)
2017-07-28 21:12:53 +02:00
func TestNewFromBigIntWithExponent(t *testing.T) {
type Inp struct {
val *big.Int
Add null support to UnmarshalJSON (#58) Unmarshal null into zero value
2017-08-16 04:25:21 +02:00
exp int32
Added NewFromBigInt constructor & unit test (#56)
2017-07-28 21:12:53 +02:00
}
tests := map[Inp]string{
Add null support to UnmarshalJSON (#58) Unmarshal null into zero value
2017-08-16 04:25:21 +02:00
Inp{big.NewInt(123412345), -3}: "123412.345",
Inp{big.NewInt(2234), -1}: "223.4",
Inp{big.NewInt(323412345), 1}: "3234123450",
Added NewFromBigInt constructor & unit test (#56)
2017-07-28 21:12:53 +02:00
Inp{big.NewInt(423412345), 0}: "423412345",
Inp{big.NewInt(52341235), -5}: "523.41235",
Add null support to UnmarshalJSON (#58) Unmarshal null into zero value
2017-08-16 04:25:21 +02:00
Inp{big.NewInt(623412345), -6}: "623.412345",
Inp{big.NewInt(723412345), -7}: "72.3412345",
Added NewFromBigInt constructor & unit test (#56)
2017-07-28 21:12:53 +02:00
}
// add negatives
for p, s := range tests {
if p.val.Cmp(Zero.value) > 0 {
tests[Inp{p.val.Neg(p.val), p.exp}] = "-" + s
}
}
for input, s := range tests {
d := NewFromBigInt(input.val, input.exp)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
}
Add NewFromBigRat constructor (#288)
2024-02-19 23:13:43 +01:00
func TestNewFromBigRat(t *testing.T) {
mustParseRat := func(val string) *big.Rat {
num, _ := new(big.Rat).SetString(val)
return num
}
type Inp struct {
val *big.Rat
prec int32
}
tests := map[Inp]string{
Inp{big.NewRat(0, 1), 16}: "0",
Inp{big.NewRat(4, 5), 16}: "0.8",
Inp{big.NewRat(10, 2), 16}: "5",
Inp{big.NewRat(1023427554493, 43432632), 16}: "23563.5628642767953828", // rounded
Inp{big.NewRat(1, 434324545566634), 16}: "0.0000000000000023",
Inp{big.NewRat(1, 3), 16}: "0.3333333333333333",
Inp{big.NewRat(2, 3), 2}: "0.67", // rounded
Inp{big.NewRat(2, 3), 16}: "0.6666666666666667", // rounded
Inp{big.NewRat(10000, 3), 16}: "3333.3333333333333333",
Inp{mustParseRat("30702832066636633479"), 16}: "30702832066636633479",
Inp{mustParseRat("487028320159896636679.1827512895753"), 16}: "487028320159896636679.1827512895753",
Inp{mustParseRat("127028320612589896636633479.173582751289575278357832"), -2}: "127028320612589896636633500", // rounded
Inp{mustParseRat("127028320612589896636633479.173582751289575278357832"), 16}: "127028320612589896636633479.1735827512895753", // rounded
Inp{mustParseRat("127028320612589896636633479.173582751289575278357832"), 32}: "127028320612589896636633479.173582751289575278357832",
}
// add negatives
for p, s := range tests {
if p.val.Cmp(new(big.Rat)) > 0 {
tests[Inp{p.val.Neg(p.val), p.prec}] = "-" + s
}
}
for input, s := range tests {
d := NewFromBigRat(input.val, input.prec)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
}
}
Reformat code base and update decimal copy docs (#249)
2021-10-12 12:11:39 +02:00
func TestCopy(t *testing.T) {
origin := New(1, 0)
cpy := origin.Copy()
Allocate new(big.Int) in Copy method to deeply clone it (#278)
2023-12-27 15:53:43 +01:00
if origin.value == cpy.value {
t.Error("expecting copy and origin to have different value pointers")
}
Reformat code base and update decimal copy docs (#249)
2021-10-12 12:11:39 +02:00
if cpy.Cmp(origin) != 0 {
t.Error("expecting copy and origin to be equals, but they are not")
}
//change value
cpy = cpy.Add(New(1, 0))
if cpy.Cmp(origin) == 0 {
t.Error("expecting copy and origin to have different values, but they are equal")
}
}
Add round-trip JSON test.
2015-03-23 23:07:27 +01:00
func TestJSON(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, x := range testTable {
s := x.short
Add round-trip JSON test.
2015-03-23 23:07:27 +01:00
var doc struct {
Amount Decimal `json:"amount"`
}
docStr := `{"amount":"` + s + `"}`
allow optional marshalling JSON without quotes
2016-09-18 22:52:01 +02:00
docStrNumber := `{"amount":` + s + `}`
Add round-trip JSON test.
2015-03-23 23:07:27 +01:00
err := json.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling %s: %v", docStr, err)
} else if doc.Amount.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, doc.Amount.String(),
doc.Amount.value.String(), doc.Amount.exp)
}
out, err := json.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != docStr {
t.Errorf("expected %s, got %s", docStr, string(out))
}
allow optional marshalling JSON without quotes
2016-09-18 22:52:01 +02:00
// make sure unquoted marshalling works too
MarshalJSONWithoutQuotes = true
out, err = json.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != docStrNumber {
t.Errorf("expected %s, got %s", docStrNumber, string(out))
}
MarshalJSONWithoutQuotes = false
Add round-trip JSON test.
2015-03-23 23:07:27 +01:00
}
}
Add null support to UnmarshalJSON (#58) Unmarshal null into zero value
2017-08-16 04:25:21 +02:00
func TestUnmarshalJSONNull(t *testing.T) {
var doc struct {
Amount Decimal `json:"amount"`
}
docStr := `{"amount": null}`
err := json.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling %s: %v", docStr, err)
} else if !doc.Amount.Equal(Zero) {
t.Errorf("expected Zero, got %s (%s, %d)",
doc.Amount.String(),
doc.Amount.value.String(), doc.Amount.exp)
}
}
Test unhappy JSON and XML paths.
2015-03-24 01:39:37 +01:00
func TestBadJSON(t *testing.T) {
for _, testCase := range []string{
Improve error messages, readability of test cases.
2015-03-26 04:13:03 +01:00
"]o_o[",
"{",
`{"amount":""`,
Test unhappy JSON and XML paths.
2015-03-24 01:39:37 +01:00
`{"amount":""}`,
`{"amount":"nope"}`,
`0.333`,
} {
var doc struct {
Amount Decimal `json:"amount"`
}
err := json.Unmarshal([]byte(testCase), &doc)
if err == nil {
t.Errorf("expected error, got %+v", doc)
}
}
}
Added JSON support for NullDecimal (#62) * Corrected NullDecimal comment Saying that NullDecimal is immutable is just incorrect, and we don't need to duplicate the description of properties of a Decimal type here. * Added UnmarshalJSON and MarshalJSON support for NullDecimal * Added tests for JSON operations on NullDecimal * Fixed mistakes in tests
2017-10-10 18:21:51 +02:00
func TestNullDecimalJSON(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, x := range testTable {
s := x.short
Added JSON support for NullDecimal (#62) * Corrected NullDecimal comment Saying that NullDecimal is immutable is just incorrect, and we don't need to duplicate the description of properties of a Decimal type here. * Added UnmarshalJSON and MarshalJSON support for NullDecimal * Added tests for JSON operations on NullDecimal * Fixed mistakes in tests
2017-10-10 18:21:51 +02:00
var doc struct {
Amount NullDecimal `json:"amount"`
}
docStr := `{"amount":"` + s + `"}`
docStrNumber := `{"amount":` + s + `}`
err := json.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling %s: %v", docStr, err)
} else {
if !doc.Amount.Valid {
t.Errorf("expected %s to be valid (not NULL), got Valid = false", s)
}
if doc.Amount.Decimal.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, doc.Amount.Decimal.String(),
doc.Amount.Decimal.value.String(), doc.Amount.Decimal.exp)
}
}
out, err := json.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != docStr {
t.Errorf("expected %s, got %s", docStr, string(out))
}
// make sure unquoted marshalling works too
MarshalJSONWithoutQuotes = true
out, err = json.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != docStrNumber {
t.Errorf("expected %s, got %s", docStrNumber, string(out))
}
MarshalJSONWithoutQuotes = false
}
var doc struct {
Amount NullDecimal `json:"amount"`
}
docStr := `{"amount": null}`
err := json.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling %s: %v", docStr, err)
} else if doc.Amount.Valid {
t.Errorf("expected null value to have Valid = false, got Valid = true and Decimal = %s (%s, %d)",
doc.Amount.Decimal.String(),
doc.Amount.Decimal.value.String(), doc.Amount.Decimal.exp)
}
expected := `{"amount":null}`
out, err := json.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != expected {
t.Errorf("expected %s, got %s", expected, string(out))
}
// make sure unquoted marshalling works too
MarshalJSONWithoutQuotes = true
expectedUnquoted := `{"amount":null}`
out, err = json.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != expectedUnquoted {
t.Errorf("expected %s, got %s", expectedUnquoted, string(out))
}
MarshalJSONWithoutQuotes = false
}
func TestNullDecimalBadJSON(t *testing.T) {
for _, testCase := range []string{
"]o_o[",
"{",
`{"amount":""`,
`{"amount":""}`,
`{"amount":"nope"}`,
`{"amount":nope}`,
`0.333`,
} {
var doc struct {
Amount NullDecimal `json:"amount"`
}
err := json.Unmarshal([]byte(testCase), &doc)
if err == nil {
t.Errorf("expected error, got %+v", doc)
}
}
}
Add XML test.
2015-03-23 23:14:19 +01:00
func TestXML(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, x := range testTable {
s := x.short
Add XML test.
2015-03-23 23:14:19 +01:00
var doc struct {
XMLName xml.Name `xml:"account"`
Amount Decimal `xml:"amount"`
}
docStr := `<account><amount>` + s + `</amount></account>`
err := xml.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling %s: %v", docStr, err)
} else if doc.Amount.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, doc.Amount.String(),
doc.Amount.value.String(), doc.Amount.exp)
}
out, err := xml.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != docStr {
t.Errorf("expected %s, got %s", docStr, string(out))
}
}
}
Test unhappy JSON and XML paths.
2015-03-24 01:39:37 +01:00
func TestBadXML(t *testing.T) {
for _, testCase := range []string{
Improve error messages, readability of test cases.
2015-03-26 04:13:03 +01:00
"o_o",
"<abc",
"<account><amount>7",
Test unhappy JSON and XML paths.
2015-03-24 01:39:37 +01:00
`<html><body></body></html>`,
`<account><amount></amount></account>`,
`<account><amount>nope</amount></account>`,
`0.333`,
} {
var doc struct {
XMLName xml.Name `xml:"account"`
Amount Decimal `xml:"amount"`
}
err := xml.Unmarshal([]byte(testCase), &doc)
if err == nil {
t.Errorf("expected error, got %+v", doc)
}
}
}
Added XML support for NullDecimal (#192) * Added UnmarshalText and MarshalText support for NullDecimal * Add tests for XML operations on NullDecimal
2021-02-18 23:32:50 +01:00
func TestNullDecimalXML(t *testing.T) {
// test valid values
for _, x := range testTable {
s := x.short
var doc struct {
XMLName xml.Name `xml:"account"`
Amount NullDecimal `xml:"amount"`
}
docStr := `<account><amount>` + s + `</amount></account>`
err := xml.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling %s: %v", docStr, err)
} else if doc.Amount.Decimal.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, doc.Amount.Decimal.String(),
doc.Amount.Decimal.value.String(), doc.Amount.Decimal.exp)
}
out, err := xml.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != docStr {
t.Errorf("expected %s, got %s", docStr, string(out))
}
}
var doc struct {
XMLName xml.Name `xml:"account"`
Amount NullDecimal `xml:"amount"`
}
// test for XML with empty body
docStr := `<account><amount></amount></account>`
err := xml.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling: %s: %v", docStr, err)
} else if doc.Amount.Valid {
t.Errorf("expected null value to have Valid = false, got Valid = true and Decimal = %s (%s, %d)",
doc.Amount.Decimal.String(),
doc.Amount.Decimal.value.String(), doc.Amount.Decimal.exp)
}
expected := `<account><amount></amount></account>`
out, err := xml.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != expected {
t.Errorf("expected %s, got %s", expected, string(out))
}
// test for empty XML
docStr = `<account></account>`
err = xml.Unmarshal([]byte(docStr), &doc)
if err != nil {
t.Errorf("error unmarshaling: %s: %v", docStr, err)
} else if doc.Amount.Valid {
t.Errorf("expected null value to have Valid = false, got Valid = true and Decimal = %s (%s, %d)",
doc.Amount.Decimal.String(),
doc.Amount.Decimal.value.String(), doc.Amount.Decimal.exp)
}
expected = `<account><amount></amount></account>`
out, err = xml.Marshal(&doc)
if err != nil {
t.Errorf("error marshaling %+v: %v", doc, err)
} else if string(out) != expected {
t.Errorf("expected %s, got %s", expected, string(out))
}
}
func TestNullDecimalBadXML(t *testing.T) {
for _, testCase := range []string{
"o_o",
"<abc",
"<account><amount>7",
`<html><body></body></html>`,
`<account><amount>nope</amount></account>`,
`0.333`,
} {
var doc struct {
XMLName xml.Name `xml:"account"`
Amount NullDecimal `xml:"amount"`
}
err := xml.Unmarshal([]byte(testCase), &doc)
if err == nil {
t.Errorf("expected error, got %+v", doc)
}
}
}
init
2015-02-10 21:33:58 +01:00
func TestDecimal_rescale(t *testing.T) {
type Inp struct {
int int64
exp int32
rescale int32
}
tests := map[Inp]string{
Inp{1234, -3, -5}: "1.234",
Inp{1234, -3, 0}: "1",
Inp{1234, 3, 0}: "1234000",
Inp{1234, -4, -4}: "0.1234",
}
// add negatives
for p, s := range tests {
if p.int > 0 {
tests[Inp{-p.int, p.exp, p.rescale}] = "-" + s
}
}
for input, s := range tests {
d := New(input.int, input.exp).rescale(input.rescale)
if d.String() != s {
t.Errorf("expected %s, got %s (%s, %d)",
s, d.String(),
d.value.String(), d.exp)
}
// test StringScaled
s2 := New(input.int, input.exp).StringScaled(input.rescale)
if s2 != s {
t.Errorf("expected %s, got %s", s, s2)
}
}
}
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
func TestDecimal_Floor(t *testing.T) {
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
assertFloor := func(input, expected Decimal) {
got := input.Floor()
if !got.Equal(expected) {
t.Errorf("Floor(%s): got %s, expected %s", input, got, expected)
}
}
type testDataString struct {
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
input string
expected string
}
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
testsWithStrings := []testDataString{
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
{"1.999", "1"},
{"1", "1"},
{"1.01", "1"},
{"0", "0"},
{"0.9", "0"},
{"0.1", "0"},
{"-0.9", "-1"},
{"-0.1", "-1"},
{"-1.00", "-1"},
{"-1.01", "-2"},
{"-1.999", "-2"},
}
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
for _, test := range testsWithStrings {
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
expected, _ := NewFromString(test.expected)
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
input, _ := NewFromString(test.input)
assertFloor(input, expected)
}
type testDataDecimal struct {
input Decimal
expected string
}
testsWithDecimals := []testDataDecimal{
{New(100, -1), "10"},
{New(10, 0), "10"},
{New(1, 1), "10"},
{New(1999, -3), "1"},
{New(101, -2), "1"},
{New(1, 0), "1"},
{New(0, 0), "0"},
{New(9, -1), "0"},
{New(1, -1), "0"},
{New(-1, -1), "-1"},
{New(-9, -1), "-1"},
{New(-1, 0), "-1"},
{New(-101, -2), "-2"},
{New(-1999, -3), "-2"},
}
for _, test := range testsWithDecimals {
expected, _ := NewFromString(test.expected)
assertFloor(test.input, expected)
}
}
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
func TestDecimal_Ceil(t *testing.T) {
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
assertCeil := func(input, expected Decimal) {
got := input.Ceil()
if !got.Equal(expected) {
t.Errorf("Ceil(%s): got %s, expected %s", input, got, expected)
}
}
type testDataString struct {
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
input string
expected string
}
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
testsWithStrings := []testDataString{
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
{"1.999", "2"},
{"1", "1"},
{"1.01", "2"},
{"0", "0"},
{"0.9", "1"},
{"0.1", "1"},
{"-0.9", "0"},
{"-0.1", "0"},
{"-1.00", "-1"},
{"-1.01", "-1"},
{"-1.999", "-1"},
}
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
for _, test := range testsWithStrings {
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
expected, _ := NewFromString(test.expected)
Fix Floor() and Ceil() for integer values (#64) Implementation of aforementioned methods applied an integer multiplier to int part, and rejected the exponent. This did not work well for positive exponent values - multiplier was supposed to be a non-integer value less than 1, but was rounded up to it. This caused different results for equal Decimal values like decimal.New(19, 1) and decimal.New(1900, -1). Now functions return the receiver if it represents an integer value. This also reduces execution time for previously broken cases.
2017-11-08 23:52:54 +01:00
input, _ := NewFromString(test.input)
assertCeil(input, expected)
}
type testDataDecimal struct {
input Decimal
expected string
}
testsWithDecimals := []testDataDecimal{
{New(100, -1), "10"},
{New(10, 0), "10"},
{New(1, 1), "10"},
{New(1999, -3), "2"},
{New(101, -2), "2"},
{New(1, 0), "1"},
{New(0, 0), "0"},
{New(9, -1), "1"},
{New(1, -1), "1"},
{New(-1, -1), "0"},
{New(-9, -1), "0"},
{New(-1, 0), "-1"},
{New(-101, -2), "-1"},
{New(-1999, -3), "-1"},
}
for _, test := range testsWithDecimals {
expected, _ := NewFromString(test.expected)
assertCeil(test.input, expected)
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
}
}
func TestDecimal_RoundAndStringFixed(t *testing.T) {
type testData struct {
input string
places int32
expected string
expectedFixed string
}
tests := []testData{
{"1.454", 0, "1", ""},
{"1.454", 1, "1.5", ""},
{"1.454", 2, "1.45", ""},
{"1.454", 3, "1.454", ""},
{"1.454", 4, "1.454", "1.4540"},
{"1.454", 5, "1.454", "1.45400"},
{"1.554", 0, "2", ""},
{"1.554", 1, "1.6", ""},
{"1.554", 2, "1.55", ""},
{"0.554", 0, "1", ""},
{"0.454", 0, "0", ""},
{"0.454", 5, "0.454", "0.45400"},
{"0", 0, "0", ""},
{"0", 1, "0", "0.0"},
{"0", 2, "0", "0.00"},
{"0", -1, "0", ""},
{"5", 2, "5", "5.00"},
{"5", 1, "5", "5.0"},
{"5", 0, "5", ""},
{"500", 2, "500", "500.00"},
{"545", -1, "550", ""},
{"545", -2, "500", ""},
{"545", -3, "1000", ""},
{"545", -4, "0", ""},
{"499", -3, "0", ""},
{"499", -4, "0", ""},
}
// add negative number tests
for _, test := range tests {
expected := test.expected
if expected != "0" {
expected = "-" + expected
}
expectedStr := test.expectedFixed
if strings.ContainsAny(expectedStr, "123456789") && expectedStr != "" {
expectedStr = "-" + expectedStr
}
tests = append(tests,
testData{"-" + test.input, test.places, expected, expectedStr})
}
for _, test := range tests {
d, err := NewFromString(test.input)
if err != nil {
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
2020-12-11 19:41:11 +01:00
t.Fatal(err)
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
}
// test Round
expected, err := NewFromString(test.expected)
if err != nil {
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
2020-12-11 19:41:11 +01:00
t.Fatal(err)
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
}
got := d.Round(test.places)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got.Equal(expected) {
add Round, Floor, Ceil, and StringFixed. Deprecate StringScaled
2015-06-14 17:53:23 +02:00
t.Errorf("Rounding %s to %d places, got %s, expected %s",
d, test.places, got, expected)
}
// test StringFixed
if test.expectedFixed == "" {
test.expectedFixed = test.expected
}
gotStr := d.StringFixed(test.places)
if gotStr != test.expectedFixed {
t.Errorf("(%s).StringFixed(%d): got %s, expected %s",
d, test.places, gotStr, test.expectedFixed)
}
}
}
Modify Rounding methods (#220) * Change function name from RoundUp -> RoundCeil, RoundDown -> RoundFloor * Add a new RoundUp and RoundDown methods * Modify the docs of RoundUp and RoundDown
2021-03-14 22:09:56 +01:00
func TestDecimal_RoundCeilAndStringFixed(t *testing.T) {
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
2020-12-11 19:41:11 +01:00
type testData struct {
input string
places int32
expected string
expectedFixed string
}
tests := []testData{
{"1.454", 0, "2", ""},
{"1.454", 1, "1.5", ""},
{"1.454", 2, "1.46", ""},
{"1.454", 3, "1.454", ""},
{"1.454", 4, "1.454", "1.4540"},
{"1.454", 5, "1.454", "1.45400"},
{"1.554", 0, "2", ""},
{"1.554", 1, "1.6", ""},
{"1.554", 2, "1.56", ""},
{"0.554", 0, "1", ""},
{"0.454", 0, "1", ""},
{"0.454", 5, "0.454", "0.45400"},
{"0", 0, "0", ""},
{"0", 1, "0", "0.0"},
{"0", 2, "0", "0.00"},
{"0", -1, "0", ""},
{"5", 2, "5", "5.00"},
{"5", 1, "5", "5.0"},
{"5", 0, "5", ""},
{"500", 2, "500", "500.00"},
Fix wrong return RoundUp/RoundDown because of value after rescaled is ignore (#202)
2021-01-18 00:50:46 +01:00
{"500", -2, "500", ""},
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
2020-12-11 19:41:11 +01:00
{"545", -1, "550", ""},
{"545", -2, "600", ""},
{"545", -3, "1000", ""},
{"545", -4, "10000", ""},
{"499", -3, "1000", ""},
{"499", -4, "10000", ""},
{"1.1001", 2, "1.11", ""},
{"-1.1001", 2, "-1.10", ""},
{"-1.454", 0, "-1", ""},
{"-1.454", 1, "-1.4", ""},
{"-1.454", 2, "-1.45", ""},
{"-1.454", 3, "-1.454", ""},
{"-1.454", 4, "-1.454", "-1.4540"},
{"-1.454", 5, "-1.454", "-1.45400"},
{"-1.554", 0, "-1", ""},
{"-1.554", 1, "-1.5", ""},
{"-1.554", 2, "-1.55", ""},
{"-0.554", 0, "0", ""},
{"-0.454", 0, "0", ""},
{"-0.454", 5, "-0.454", "-0.45400"},
{"-5", 2, "-5", "-5.00"},
{"-5", 1, "-5", "-5.0"},
{"-5", 0, "-5", ""},
{"-500", 2, "-500", "-500.00"},
Fix wrong return RoundUp/RoundDown because of value after rescaled is ignore (#202)
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{"-500", -2, "-500", ""},
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
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{"-545", -1, "-540", ""},
{"-545", -2, "-500", ""},
{"-545", -3, "0", ""},
{"-545", -4, "0", ""},
{"-499", -3, "0", ""},
{"-499", -4, "0", ""},
}
for _, test := range tests {
d, err := NewFromString(test.input)
if err != nil {
t.Fatal(err)
}
// test Round
expected, err := NewFromString(test.expected)
if err != nil {
t.Fatal(err)
}
Modify Rounding methods (#220) * Change function name from RoundUp -> RoundCeil, RoundDown -> RoundFloor * Add a new RoundUp and RoundDown methods * Modify the docs of RoundUp and RoundDown
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got := d.RoundCeil(test.places)
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
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if !got.Equal(expected) {
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t.Errorf("Rounding ceil %s to %d places, got %s, expected %s",
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
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d, test.places, got, expected)
}
// test StringFixed
if test.expectedFixed == "" {
test.expectedFixed = test.expected
}
gotStr := got.StringFixed(test.places)
if gotStr != test.expectedFixed {
t.Errorf("(%s).StringFixed(%d): got %s, expected %s",
d, test.places, gotStr, test.expectedFixed)
}
}
}
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func TestDecimal_RoundFloorAndStringFixed(t *testing.T) {
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
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type testData struct {
input string
places int32
expected string
expectedFixed string
}
tests := []testData{
{"1.454", 0, "1", ""},
{"1.454", 1, "1.4", ""},
{"1.454", 2, "1.45", ""},
{"1.454", 3, "1.454", ""},
{"1.454", 4, "1.454", "1.4540"},
{"1.454", 5, "1.454", "1.45400"},
{"1.554", 0, "1", ""},
{"1.554", 1, "1.5", ""},
{"1.554", 2, "1.55", ""},
{"0.554", 0, "0", ""},
{"0.454", 0, "0", ""},
{"0.454", 5, "0.454", "0.45400"},
{"0", 0, "0", ""},
{"0", 1, "0", "0.0"},
{"0", 2, "0", "0.00"},
{"0", -1, "0", ""},
{"5", 2, "5", "5.00"},
{"5", 1, "5", "5.0"},
{"5", 0, "5", ""},
{"500", 2, "500", "500.00"},
Fix wrong return RoundUp/RoundDown because of value after rescaled is ignore (#202)
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{"500", -2, "500", ""},
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
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{"545", -1, "540", ""},
{"545", -2, "500", ""},
{"545", -3, "0", ""},
{"545", -4, "0", ""},
{"499", -3, "0", ""},
{"499", -4, "0", ""},
{"1.1001", 2, "1.10", ""},
{"-1.1001", 2, "-1.11", ""},
{"-1.454", 0, "-2", ""},
{"-1.454", 1, "-1.5", ""},
{"-1.454", 2, "-1.46", ""},
{"-1.454", 3, "-1.454", ""},
{"-1.454", 4, "-1.454", "-1.4540"},
{"-1.454", 5, "-1.454", "-1.45400"},
{"-1.554", 0, "-2", ""},
{"-1.554", 1, "-1.6", ""},
{"-1.554", 2, "-1.56", ""},
{"-0.554", 0, "-1", ""},
{"-0.454", 0, "-1", ""},
{"-0.454", 5, "-0.454", "-0.45400"},
{"-5", 2, "-5", "-5.00"},
{"-5", 1, "-5", "-5.0"},
{"-5", 0, "-5", ""},
{"-500", 2, "-500", "-500.00"},
Fix wrong return RoundUp/RoundDown because of value after rescaled is ignore (#202)
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{"-500", -2, "-500", ""},
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{"-545", -1, "-550", ""},
{"-545", -2, "-600", ""},
{"-545", -3, "-1000", ""},
{"-545", -4, "-10000", ""},
{"-499", -3, "-1000", ""},
{"-499", -4, "-10000", ""},
}
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for _, test := range tests {
d, err := NewFromString(test.input)
if err != nil {
t.Fatal(err)
}
// test Round
expected, err := NewFromString(test.expected)
if err != nil {
t.Fatal(err)
}
got := d.RoundFloor(test.places)
if !got.Equal(expected) {
t.Errorf("Rounding floor %s to %d places, got %s, expected %s",
d, test.places, got, expected)
}
// test StringFixed
if test.expectedFixed == "" {
test.expectedFixed = test.expected
}
gotStr := got.StringFixed(test.places)
if gotStr != test.expectedFixed {
t.Errorf("(%s).StringFixed(%d): got %s, expected %s",
d, test.places, gotStr, test.expectedFixed)
}
}
}
func TestDecimal_RoundUpAndStringFixed(t *testing.T) {
type testData struct {
input string
places int32
expected string
expectedFixed string
}
tests := []testData{
{"1.454", 0, "2", ""},
{"1.454", 1, "1.5", ""},
{"1.454", 2, "1.46", ""},
{"1.454", 3, "1.454", ""},
{"1.454", 4, "1.454", "1.4540"},
{"1.454", 5, "1.454", "1.45400"},
{"1.554", 0, "2", ""},
{"1.554", 1, "1.6", ""},
{"1.554", 2, "1.56", ""},
{"0.554", 0, "1", ""},
{"0.454", 0, "1", ""},
{"0.454", 5, "0.454", "0.45400"},
{"0", 0, "0", ""},
{"0", 1, "0", "0.0"},
{"0", 2, "0", "0.00"},
{"0", -1, "0", ""},
{"5", 2, "5", "5.00"},
{"5", 1, "5", "5.0"},
{"5", 0, "5", ""},
{"500", 2, "500", "500.00"},
{"500", -2, "500", ""},
{"545", -1, "550", ""},
{"545", -2, "600", ""},
{"545", -3, "1000", ""},
{"545", -4, "10000", ""},
{"499", -3, "1000", ""},
{"499", -4, "10000", ""},
{"1.1001", 2, "1.11", ""},
{"-1.1001", 2, "-1.11", ""},
{"-1.454", 0, "-2", ""},
{"-1.454", 1, "-1.5", ""},
{"-1.454", 2, "-1.46", ""},
{"-1.454", 3, "-1.454", ""},
{"-1.454", 4, "-1.454", "-1.4540"},
{"-1.454", 5, "-1.454", "-1.45400"},
{"-1.554", 0, "-2", ""},
{"-1.554", 1, "-1.6", ""},
{"-1.554", 2, "-1.56", ""},
{"-0.554", 0, "-1", ""},
{"-0.454", 0, "-1", ""},
{"-0.454", 5, "-0.454", "-0.45400"},
{"-5", 2, "-5", "-5.00"},
{"-5", 1, "-5", "-5.0"},
{"-5", 0, "-5", ""},
{"-500", 2, "-500", "-500.00"},
{"-500", -2, "-500", ""},
{"-545", -1, "-550", ""},
{"-545", -2, "-600", ""},
{"-545", -3, "-1000", ""},
{"-545", -4, "-10000", ""},
{"-499", -3, "-1000", ""},
{"-499", -4, "-10000", ""},
}
for _, test := range tests {
d, err := NewFromString(test.input)
if err != nil {
t.Fatal(err)
}
// test Round
expected, err := NewFromString(test.expected)
if err != nil {
t.Fatal(err)
}
got := d.RoundUp(test.places)
if !got.Equal(expected) {
t.Errorf("Rounding up %s to %d places, got %s, expected %s",
d, test.places, got, expected)
}
// test StringFixed
if test.expectedFixed == "" {
test.expectedFixed = test.expected
}
gotStr := got.StringFixed(test.places)
if gotStr != test.expectedFixed {
t.Errorf("(%s).StringFixed(%d): got %s, expected %s",
d, test.places, gotStr, test.expectedFixed)
}
}
}
func TestDecimal_RoundDownAndStringFixed(t *testing.T) {
type testData struct {
input string
places int32
expected string
expectedFixed string
}
tests := []testData{
{"1.454", 0, "1", ""},
{"1.454", 1, "1.4", ""},
{"1.454", 2, "1.45", ""},
{"1.454", 3, "1.454", ""},
{"1.454", 4, "1.454", "1.4540"},
{"1.454", 5, "1.454", "1.45400"},
{"1.554", 0, "1", ""},
{"1.554", 1, "1.5", ""},
{"1.554", 2, "1.55", ""},
{"0.554", 0, "0", ""},
{"0.454", 0, "0", ""},
{"0.454", 5, "0.454", "0.45400"},
{"0", 0, "0", ""},
{"0", 1, "0", "0.0"},
{"0", 2, "0", "0.00"},
{"0", -1, "0", ""},
{"5", 2, "5", "5.00"},
{"5", 1, "5", "5.0"},
{"5", 0, "5", ""},
{"500", 2, "500", "500.00"},
{"500", -2, "500", ""},
{"545", -1, "540", ""},
{"545", -2, "500", ""},
{"545", -3, "0", ""},
{"545", -4, "0", ""},
{"499", -3, "0", ""},
{"499", -4, "0", ""},
{"1.1001", 2, "1.10", ""},
{"-1.1001", 2, "-1.10", ""},
{"-1.454", 0, "-1", ""},
{"-1.454", 1, "-1.4", ""},
{"-1.454", 2, "-1.45", ""},
{"-1.454", 3, "-1.454", ""},
{"-1.454", 4, "-1.454", "-1.4540"},
{"-1.454", 5, "-1.454", "-1.45400"},
{"-1.554", 0, "-1", ""},
{"-1.554", 1, "-1.5", ""},
{"-1.554", 2, "-1.55", ""},
{"-0.554", 0, "0", ""},
{"-0.454", 0, "0", ""},
{"-0.454", 5, "-0.454", "-0.45400"},
{"-5", 2, "-5", "-5.00"},
{"-5", 1, "-5", "-5.0"},
{"-5", 0, "-5", ""},
{"-500", 2, "-500", "-500.00"},
{"-500", -2, "-500", ""},
{"-545", -1, "-540", ""},
{"-545", -2, "-500", ""},
{"-545", -3, "0", ""},
{"-545", -4, "0", ""},
{"-499", -3, "0", ""},
{"-499", -4, "0", ""},
}
Implement RoundUp and RoundDown methods (#196) * Implement RoundUp and RoundDown methods
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for _, test := range tests {
d, err := NewFromString(test.input)
if err != nil {
t.Fatal(err)
}
// test Round
expected, err := NewFromString(test.expected)
if err != nil {
t.Fatal(err)
}
got := d.RoundDown(test.places)
if !got.Equal(expected) {
t.Errorf("Rounding down %s to %d places, got %s, expected %s",
d, test.places, got, expected)
}
// test StringFixed
if test.expectedFixed == "" {
test.expectedFixed = test.expected
}
gotStr := got.StringFixed(test.places)
if gotStr != test.expectedFixed {
t.Errorf("(%s).StringFixed(%d): got %s, expected %s",
d, test.places, gotStr, test.expectedFixed)
}
}
}
Added Banker Rounding (#61) * made GTE/GT/LT/LTE go-lint compliant * added banker rounding and tests (RoundBank, StringFixedBank)
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func TestDecimal_BankRoundAndStringFixed(t *testing.T) {
type testData struct {
input string
places int32
expected string
expectedFixed string
}
tests := []testData{
{"1.454", 0, "1", ""},
{"1.454", 1, "1.5", ""},
{"1.454", 2, "1.45", ""},
{"1.454", 3, "1.454", ""},
{"1.454", 4, "1.454", "1.4540"},
{"1.454", 5, "1.454", "1.45400"},
{"1.554", 0, "2", ""},
{"1.554", 1, "1.6", ""},
{"1.554", 2, "1.55", ""},
{"0.554", 0, "1", ""},
{"0.454", 0, "0", ""},
{"0.454", 5, "0.454", "0.45400"},
{"0", 0, "0", ""},
{"0", 1, "0", "0.0"},
{"0", 2, "0", "0.00"},
{"0", -1, "0", ""},
{"5", 2, "5", "5.00"},
{"5", 1, "5", "5.0"},
{"5", 0, "5", ""},
{"500", 2, "500", "500.00"},
{"545", -2, "500", ""},
{"545", -3, "1000", ""},
{"545", -4, "0", ""},
{"499", -3, "0", ""},
{"499", -4, "0", ""},
{"1.45", 1, "1.4", ""},
{"1.55", 1, "1.6", ""},
{"1.65", 1, "1.6", ""},
{"545", -1, "540", ""},
{"565", -1, "560", ""},
{"555", -1, "560", ""},
}
// add negative number tests
for _, test := range tests {
expected := test.expected
if expected != "0" {
expected = "-" + expected
}
expectedStr := test.expectedFixed
if strings.ContainsAny(expectedStr, "123456789") && expectedStr != "" {
expectedStr = "-" + expectedStr
}
tests = append(tests,
testData{"-" + test.input, test.places, expected, expectedStr})
}
for _, test := range tests {
d, err := NewFromString(test.input)
if err != nil {
panic(err)
}
// test Round
expected, err := NewFromString(test.expected)
if err != nil {
panic(err)
}
got := d.RoundBank(test.places)
if !got.Equal(expected) {
t.Errorf("Bank Rounding %s to %d places, got %s, expected %s",
d, test.places, got, expected)
}
// test StringFixed
if test.expectedFixed == "" {
test.expectedFixed = test.expected
}
gotStr := d.StringFixedBank(test.places)
if gotStr != test.expectedFixed {
t.Errorf("(%s).StringFixed(%d): got %s, expected %s",
d, test.places, gotStr, test.expectedFixed)
}
}
}
init
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func TestDecimal_Uninitialized(t *testing.T) {
a := Decimal{}
b := Decimal{}
decs := []Decimal{
a,
a.rescale(10),
a.Abs(),
a.Add(b),
a.Sub(b),
a.Mul(b),
Add support for shifting in base 10 (#86) This allows for very fast multiplying and dividing by powers of 10 without the possibility of losing precision.
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a.Shift(0),
init
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a.Div(New(1, -1)),
add stupid test for extreme values, fix some super-edge-case bugs
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a.Round(2),
ensure decimal is initialized for new methods
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a.Floor(),
a.Ceil(),
add stupid test for extreme values, fix some super-edge-case bugs
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a.Truncate(2),
init
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}
for _, d := range decs {
if d.String() != "0" {
t.Errorf("expected 0, got %s", d.String())
}
ensure decimal is initialized for new methods
2015-06-14 20:06:51 +02:00
if d.StringFixed(3) != "0.000" {
t.Errorf("expected 0, got %s", d.StringFixed(3))
}
if d.StringScaled(-2) != "0" {
t.Errorf("expected 0, got %s", d.StringScaled(-2))
}
init
2015-02-10 21:33:58 +01:00
}
if a.Cmp(b) != 0 {
t.Errorf("a != b")
}
Add Sign method d.Sign() is a more convenient way of saying d.Cmp(Zero).
2016-12-12 03:00:26 +01:00
if a.Sign() != 0 {
t.Errorf("a.Sign() != 0")
}
init
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if a.Exponent() != 0 {
t.Errorf("a.Exponent() != 0")
}
add stupid test for extreme values, fix some super-edge-case bugs
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if a.IntPart() != 0 {
t.Errorf("a.IntPar() != 0")
}
f, _ := a.Float64()
if f != 0 {
t.Errorf("a.Float64() != 0")
}
if a.Rat().RatString() != "0" {
t.Errorf("a.Rat() != 0, got %s", a.Rat().RatString())
}
init
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}
func TestDecimal_Add(t *testing.T) {
type Inp struct {
a string
b string
}
inputs := map[Inp]string{
Inp{"2", "3"}: "5",
Inp{"2454495034", "3451204593"}: "5905699627",
Inp{"24544.95034", ".3451204593"}: "24545.2954604593",
Inp{".1", ".1"}: "0.2",
Inp{".1", "-.1"}: "0",
Inp{"0", "1.001"}: "1.001",
}
for inp, res := range inputs {
a, err := NewFromString(inp.a)
if err != nil {
t.FailNow()
}
b, err := NewFromString(inp.b)
if err != nil {
t.FailNow()
}
c := a.Add(b)
if c.String() != res {
t.Errorf("expected %s, got %s", res, c.String())
}
}
}
func TestDecimal_Sub(t *testing.T) {
type Inp struct {
a string
b string
}
inputs := map[Inp]string{
Inp{"2", "3"}: "-1",
Inp{"12", "3"}: "9",
Inp{"-2", "9"}: "-11",
Inp{"2454495034", "3451204593"}: "-996709559",
Inp{"24544.95034", ".3451204593"}: "24544.6052195407",
Inp{".1", "-.1"}: "0.2",
Inp{".1", ".1"}: "0",
Inp{"0", "1.001"}: "-1.001",
Inp{"1.001", "0"}: "1.001",
Inp{"2.3", ".3"}: "2",
}
for inp, res := range inputs {
a, err := NewFromString(inp.a)
if err != nil {
t.FailNow()
}
b, err := NewFromString(inp.b)
if err != nil {
t.FailNow()
}
c := a.Sub(b)
if c.String() != res {
t.Errorf("expected %s, got %s", res, c.String())
}
}
}
Add Neg method (#48) Neg provides an easy way to negate a Decimal.
2017-02-21 19:39:36 +01:00
func TestDecimal_Neg(t *testing.T) {
inputs := map[string]string{
"0": "0",
"10": "-10",
"5.56": "-5.56",
"-10": "10",
"-5.56": "5.56",
}
for inp, res := range inputs {
a, err := NewFromString(inp)
if err != nil {
t.FailNow()
}
b := a.Neg()
if b.String() != res {
t.Errorf("expected %s, got %s", res, b.String())
}
}
}
Added ensureInitialized() to the Neg() method (#80) * Added ensureInitialized to the Neg() method, because it can panic when d.value is nil * TestDecimal_NegFromEmpty added
2018-01-26 22:25:43 +01:00
func TestDecimal_NegFromEmpty(t *testing.T) {
a := Decimal{}
b := a.Neg()
if b.String() != "0" {
t.Errorf("expected %s, got %s", "0", b)
}
}
init
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func TestDecimal_Mul(t *testing.T) {
type Inp struct {
a string
b string
}
inputs := map[Inp]string{
Inp{"2", "3"}: "6",
Inp{"2454495034", "3451204593"}: "8470964534836491162",
Inp{"24544.95034", ".3451204593"}: "8470.964534836491162",
Inp{".1", ".1"}: "0.01",
Inp{"0", "1.001"}: "0",
}
for inp, res := range inputs {
a, err := NewFromString(inp.a)
if err != nil {
t.FailNow()
}
b, err := NewFromString(inp.b)
if err != nil {
t.FailNow()
}
c := a.Mul(b)
if c.String() != res {
t.Errorf("expected %s, got %s", res, c.String())
}
}
// positive scale
c := New(1234, 5).Mul(New(45, -1))
if c.String() != "555300000" {
t.Errorf("Expected %s, got %s", "555300000", c.String())
}
}
Add support for shifting in base 10 (#86) This allows for very fast multiplying and dividing by powers of 10 without the possibility of losing precision.
2018-03-19 18:08:23 +01:00
func TestDecimal_Shift(t *testing.T) {
type Inp struct {
a string
b int32
}
inputs := map[Inp]string{
Inp{"6", 3}: "6000",
Inp{"10", -2}: "0.1",
Inp{"2.2", 1}: "22",
Inp{"-2.2", -1}: "-0.22",
Inp{"12.88", 5}: "1288000",
Inp{"-10234274355545544493", -3}: "-10234274355545544.493",
Inp{"-4612301402398.4753343454", 5}: "-461230140239847533.43454",
}
for inp, expectedStr := range inputs {
num, _ := NewFromString(inp.a)
got := num.Shift(inp.b)
expected, _ := NewFromString(expectedStr)
if !got.Equal(expected) {
t.Errorf("expected %v when shifting %v by %v, got %v",
expected, num, inp.b, got)
}
}
}
init
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func TestDecimal_Div(t *testing.T) {
type Inp struct {
a string
b string
}
inputs := map[Inp]string{
Inp{"6", "3"}: "2",
Inp{"10", "2"}: "5",
Inp{"2.2", "1.1"}: "2",
Inp{"-2.2", "-1.1"}: "2",
Inp{"12.88", "5.6"}: "2.3",
Inp{"1023427554493", "43432632"}: "23563.5628642767953828", // rounded
Inp{"1", "434324545566634"}: "0.0000000000000023",
Inp{"1", "3"}: "0.3333333333333333",
Inp{"2", "3"}: "0.6666666666666667", // rounded
Inp{"10000", "3"}: "3333.3333333333333333",
Inp{"10234274355545544493", "-3"}: "-3411424785181848164.3333333333333333",
Inp{"-4612301402398.4753343454", "23.5"}: "-196268144782.9138440146978723",
}
larger test for QuoRem
2015-09-01 23:20:23 +02:00
for inp, expectedStr := range inputs {
init
2015-02-10 21:33:58 +01:00
num, err := NewFromString(inp.a)
if err != nil {
t.FailNow()
}
denom, err := NewFromString(inp.b)
if err != nil {
t.FailNow()
}
got := num.Div(denom)
larger test for QuoRem
2015-09-01 23:20:23 +02:00
expected, _ := NewFromString(expectedStr)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got.Equal(expected) {
larger test for QuoRem
2015-09-01 23:20:23 +02:00
t.Errorf("expected %v when dividing %v by %v, got %v",
init
2015-02-10 21:33:58 +01:00
expected, num, denom, got)
}
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
got2 := num.DivRound(denom, int32(DivisionPrecision))
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got2.Equal(expected) {
larger test for QuoRem
2015-09-01 23:20:23 +02:00
t.Errorf("expected %v on DivRound (%v,%v), got %v", expected, num, denom, got2)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
init
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}
type Inp2 struct {
n int64
exp int32
n2 int64
exp2 int32
}
// test code path where exp > 0
inputs2 := map[Inp2]string{
Inp2{124, 10, 3, 1}: "41333333333.3333333333333333",
Inp2{124, 10, 3, 0}: "413333333333.3333333333333333",
Inp2{124, 10, 6, 1}: "20666666666.6666666666666667",
Inp2{124, 10, 6, 0}: "206666666666.6666666666666667",
Inp2{10, 10, 10, 1}: "1000000000",
}
for inp, expectedAbs := range inputs2 {
for i := -1; i <= 1; i += 2 {
for j := -1; j <= 1; j += 2 {
n := inp.n * int64(i)
n2 := inp.n2 * int64(j)
num := New(n, inp.exp)
denom := New(n2, inp.exp2)
expected := expectedAbs
if i != j {
expected = "-" + expectedAbs
}
got := num.Div(denom)
if got.String() != expected {
t.Errorf("expected %s when dividing %v by %v, got %v",
expected, num, denom, got)
}
}
}
}
}
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
func TestDecimal_QuoRem(t *testing.T) {
type Inp4 struct {
d string
d2 string
exp int32
q string
r string
}
cases := []Inp4{
gofmt -s decimal_test.go
2017-02-16 01:08:34 +01:00
{"10", "1", 0, "10", "0"},
{"1", "10", 0, "0", "1"},
{"1", "4", 2, "0.25", "0"},
{"1", "8", 2, "0.12", "0.04"},
{"10", "3", 1, "3.3", "0.1"},
{"100", "3", 1, "33.3", "0.1"},
{"1000", "10", -3, "0", "1000"},
{"1e-3", "2e-5", 0, "50", "0"},
{"1e-3", "2e-3", 1, "0.5", "0"},
{"4e-3", "0.8", 4, "5e-3", "0"},
{"4.1e-3", "0.8", 3, "5e-3", "1e-4"},
{"-4", "-3", 0, "1", "-1"},
{"-4", "3", 0, "-1", "-1"},
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
for _, inp4 := range cases {
d, _ := NewFromString(inp4.d)
d2, _ := NewFromString(inp4.d2)
more tests for division
2015-09-03 13:19:16 +02:00
prec := inp4.exp
q, r := d.QuoRem(d2, prec)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
expectedQ, _ := NewFromString(inp4.q)
expectedR, _ := NewFromString(inp4.r)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !q.Equal(expectedQ) || !r.Equal(expectedR) {
larger test for QuoRem
2015-09-01 23:20:23 +02:00
t.Errorf("bad QuoRem division %s , %s , %d got %v, %v expected %s , %s",
more tests for division
2015-09-03 13:19:16 +02:00
inp4.d, inp4.d2, prec, q, r, inp4.q, inp4.r)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !d.Equal(d2.Mul(q).Add(r)) {
more tests for division
2015-09-03 13:19:16 +02:00
t.Errorf("not fitting: d=%v, d2= %v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !q.Equal(q.Truncate(prec)) {
more tests for division
2015-09-03 13:19:16 +02:00
t.Errorf("quotient wrong precision: d=%v, d2= %v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
more tests for division
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if r.Abs().Cmp(d2.Abs().Mul(New(1, -prec))) >= 0 {
t.Errorf("remainder too large: d=%v, d2= %v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
if r.value.Sign()*d.value.Sign() < 0 {
more tests for division
2015-09-03 13:19:16 +02:00
t.Errorf("signum of divisor and rest do not match: d=%v, d2= %v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
}
}
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
type DivTestCase struct {
d Decimal
d2 Decimal
prec int32
}
func createDivTestCases() []DivTestCase {
res := make([]DivTestCase, 0)
larger test for QuoRem
2015-09-01 23:20:23 +02:00
var n int32 = 5
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
a := []int{1, 2, 3, 6, 7, 10, 100, 14, 5, 400, 0, 1000000, 1000000 + 1, 1000000 - 1}
for s := -1; s < 2; s = s + 2 { // 2
for s2 := -1; s2 < 2; s2 = s2 + 2 { // 2
for e1 := -n; e1 <= n; e1++ { // 2n+1
for e2 := -n; e2 <= n; e2++ { // 2n+1
larger test for QuoRem
2015-09-01 23:20:23 +02:00
var prec int32
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
for prec = -n; prec <= n; prec++ { // 2n+1
for _, v1 := range a { // 11
for _, v2 := range a { // 11, even if 0 is skipped
larger test for QuoRem
2015-09-01 23:20:23 +02:00
sign1 := New(int64(s), 0)
sign2 := New(int64(s2), 0)
Improve go report cards score (#174) * Improve go report cards score
2020-04-27 08:03:21 +02:00
d := sign1.Mul(New(int64(v1), e1))
d2 := sign2.Mul(New(int64(v2), e2))
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
res = append(res, DivTestCase{d, d2, prec})
larger test for QuoRem
2015-09-01 23:20:23 +02:00
}
}
}
}
}
}
}
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
return res
}
func TestDecimal_QuoRem2(t *testing.T) {
for _, tc := range createDivTestCases() {
d := tc.d
if sign(tc.d2) == 0 {
continue
}
d2 := tc.d2
prec := tc.prec
q, r := d.QuoRem(d2, prec)
// rule 1: d = d2*q +r
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !d.Equal(d2.Mul(q).Add(r)) {
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
t.Errorf("not fitting, d=%v, d2=%v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
}
// rule 2: q is integral multiple of 10^(-prec)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !q.Equal(q.Truncate(prec)) {
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
t.Errorf("quotient wrong precision, d=%v, d2=%v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
}
// rule 3: abs(r)<abs(d) * 10^(-prec)
if r.Abs().Cmp(d2.Abs().Mul(New(1, -prec))) >= 0 {
t.Errorf("remainder too large, d=%v, d2=%v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
}
// rule 4: r and d have the same sign
if r.value.Sign()*d.value.Sign() < 0 {
t.Errorf("signum of divisor and rest do not match, "+
"d=%v, d2=%v, prec=%d, q=%v, r=%v",
d, d2, prec, q, r)
}
}
}
// this is the old Div method from decimal
// Div returns d / d2. If it doesn't divide exactly, the result will have
// DivisionPrecision digits after the decimal point.
func (d Decimal) DivOld(d2 Decimal, prec int) Decimal {
// NOTE(vadim): division is hard, use Rat to do it
ratNum := d.Rat()
ratDenom := d2.Rat()
quoRat := big.NewRat(0, 1).Quo(ratNum, ratDenom)
// HACK(vadim): converting from Rat to Decimal inefficiently for now
ret, err := NewFromString(quoRat.FloatString(prec))
if err != nil {
panic(err) // this should never happen
}
return ret
}
more tests for division
2015-09-03 13:19:16 +02:00
func sign(d Decimal) int {
return d.value.Sign()
}
// rules for rounded divide, rounded to integer
// rounded_divide(d,d2) = q
// sign q * sign (d/d2) >= 0
// for d and d2 >0 :
// q is already rounded
// q = d/d2 + r , with r > -0.5 and r <= 0.5
// thus q-d/d2 = r, with r > -0.5 and r <= 0.5
// and d2 q -d = r d2 with r d2 > -d2/2 and r d2 <= d2/2
// and 2 (d2 q -d) = x with x > -d2 and x <= d2
// if we factor in precision then x > -d2 * 10^(-precision) and x <= d2 * 10(-precision)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
func TestDecimal_DivRound(t *testing.T) {
cases := []struct {
d string
d2 string
more tests for division
2015-09-03 13:19:16 +02:00
prec int32
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
result string
}{
{"2", "2", 0, "1"},
{"1", "2", 0, "1"},
{"-1", "2", 0, "-1"},
{"-1", "-2", 0, "1"},
{"1", "-2", 0, "-1"},
{"1", "-20", 1, "-0.1"},
{"1", "-20", 2, "-0.05"},
{"1", "20.0000000000000000001", 1, "0"},
{"1", "19.9999999999999999999", 1, "0.1"},
}
for _, s := range cases {
d, _ := NewFromString(s.d)
d2, _ := NewFromString(s.d2)
result, _ := NewFromString(s.result)
more tests for division
2015-09-03 13:19:16 +02:00
prec := s.prec
q := d.DivRound(d2, prec)
if sign(q)*sign(d)*sign(d2) < 0 {
t.Errorf("sign of quotient wrong, got: %v/%v is about %v", d, d2, q)
}
x := q.Mul(d2).Abs().Sub(d.Abs()).Mul(New(2, 0))
if x.Cmp(d2.Abs().Mul(New(1, -prec))) > 0 {
t.Errorf("wrong rounding, got: %v/%v prec=%d is about %v", d, d2, prec, q)
}
if x.Cmp(d2.Abs().Mul(New(-1, -prec))) <= 0 {
t.Errorf("wrong rounding, got: %v/%v prec=%d is about %v", d, d2, prec, q)
}
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !q.Equal(result) {
more tests for division
2015-09-03 13:19:16 +02:00
t.Errorf("rounded division wrong %s / %s scale %d = %s, got %v", s.d, s.d2, prec, s.result, q)
added divsion with rest and rounded division Added a division based on integer division with rest. A simple rounded division aded.
2015-09-01 14:50:25 +02:00
}
}
}
refactoring div test. benchmarks for old Div vs. New Div
2015-09-03 20:11:07 +02:00
func TestDecimal_DivRound2(t *testing.T) {
for _, tc := range createDivTestCases() {
d := tc.d
if sign(tc.d2) == 0 {
continue
}
d2 := tc.d2
prec := tc.prec
q := d.DivRound(d2, prec)
if sign(q)*sign(d)*sign(d2) < 0 {
t.Errorf("sign of quotient wrong, got: %v/%v is about %v", d, d2, q)
}
x := q.Mul(d2).Abs().Sub(d.Abs()).Mul(New(2, 0))
if x.Cmp(d2.Abs().Mul(New(1, -prec))) > 0 {
t.Errorf("wrong rounding, got: %v/%v prec=%d is about %v", d, d2, prec, q)
}
if x.Cmp(d2.Abs().Mul(New(-1, -prec))) <= 0 {
t.Errorf("wrong rounding, got: %v/%v prec=%d is about %v", d, d2, prec, q)
}
}
}
Implement Swedish/Cash rounding fixes #63 (#66) Performance and allocations not that good but can be optimized later. RoundSwedish aka Cash/Penny/öre rounding rounds decimal to a specific interval. The amount payable for a cash transaction is rounded to the nearest multiple of the minimum currency unit available. The following intervals are available: 5, 10, 15, 25, 50 and 100; any other number throws a panic. 5: 5 cent rounding 3.43 => 3.45 10: 10 cent rounding 3.45 => 3.50 (5 gets rounded up) 15: 10 cent rounding 3.45 => 3.40 (5 gets rounded down) 25: 25 cent rounding 3.41 => 3.50 50: 50 cent rounding 3.75 => 4.00 100: 100 cent rounding 3.50 => 4.00 For more details: https://en.wikipedia.org/wiki/Cash_rounding BenchmarkDecimal_RoundSwedish/five-4 1000000 1918 ns/op 1164 B/op 30 allocs/op BenchmarkDecimal_RoundSwedish/fifteen-4 300000 4331 ns/op 2940 B/op 74 allocs/op
2017-10-20 16:00:25 +02:00
func TestDecimal_RoundCash(t *testing.T) {
tests := []struct {
d string
interval uint8
result string
}{
{"3.44", 5, "3.45"},
{"3.43", 5, "3.45"},
{"3.42", 5, "3.40"},
{"3.425", 5, "3.45"},
{"3.47", 5, "3.45"},
{"3.478", 5, "3.50"},
{"3.48", 5, "3.50"},
{"348", 5, "348"},
{"3.23", 10, "3.20"},
{"3.33", 10, "3.30"},
{"3.53", 10, "3.50"},
{"3.949", 10, "3.90"},
{"3.95", 10, "4.00"},
{"395", 10, "395"},
{"3.23", 25, "3.25"},
{"3.33", 25, "3.25"},
{"3.53", 25, "3.50"},
{"3.93", 25, "4.00"},
{"3.41", 25, "3.50"},
{"3.249", 50, "3.00"},
{"3.33", 50, "3.50"},
{"3.749999999", 50, "3.50"},
{"3.75", 50, "4.00"},
{"3.93", 50, "4.00"},
{"393", 50, "393"},
{"3.249", 100, "3.00"},
{"3.49999", 100, "3.00"},
{"3.50", 100, "4.00"},
{"3.75", 100, "4.00"},
{"3.93", 100, "4.00"},
{"393", 100, "393"},
}
for i, test := range tests {
d, _ := NewFromString(test.d)
haveRounded := d.RoundCash(test.interval)
result, _ := NewFromString(test.result)
if !haveRounded.Equal(result) {
t.Errorf("Index %d: Cash rounding for %q interval %d want %q, have %q", i, test.d, test.interval, test.result, haveRounded)
}
}
}
func TestDecimal_RoundCash_Panic(t *testing.T) {
defer func() {
if r := recover(); r != nil {
if have, ok := r.(string); ok {
remove 15 interval RoundCash (#166) * remove 15 interval RoundCash * update function doc * Remove comments and benchmark referring interval 15 Co-authored-by: Mateusz Woś <wos.mateusz16@gmail.com>
2020-02-26 01:44:03 +01:00
const want = "Decimal does not support this Cash rounding interval `231`. Supported: 5, 10, 25, 50, 100"
Implement Swedish/Cash rounding fixes #63 (#66) Performance and allocations not that good but can be optimized later. RoundSwedish aka Cash/Penny/öre rounding rounds decimal to a specific interval. The amount payable for a cash transaction is rounded to the nearest multiple of the minimum currency unit available. The following intervals are available: 5, 10, 15, 25, 50 and 100; any other number throws a panic. 5: 5 cent rounding 3.43 => 3.45 10: 10 cent rounding 3.45 => 3.50 (5 gets rounded up) 15: 10 cent rounding 3.45 => 3.40 (5 gets rounded down) 25: 25 cent rounding 3.41 => 3.50 50: 50 cent rounding 3.75 => 4.00 100: 100 cent rounding 3.50 => 4.00 For more details: https://en.wikipedia.org/wiki/Cash_rounding BenchmarkDecimal_RoundSwedish/five-4 1000000 1918 ns/op 1164 B/op 30 allocs/op BenchmarkDecimal_RoundSwedish/fifteen-4 300000 4331 ns/op 2940 B/op 74 allocs/op
2017-10-20 16:00:25 +02:00
if want != have {
t.Errorf("\nWant: %q\nHave: %q", want, have)
}
} else {
t.Errorf("Panic should contain an error string but got:\n%+v", r)
}
} else {
t.Error("Expecting a panic but got nothing")
}
}()
d, _ := NewFromString("1")
d.RoundCash(231)
}
Implement Modulus arithmetic function
2016-01-15 22:32:48 +01:00
func TestDecimal_Mod(t *testing.T) {
type Inp struct {
a string
b string
}
inputs := map[Inp]string{
Fix incorrect calculation of decimal modulo (#258)
2021-10-21 11:22:23 +02:00
Inp{"3", "2"}: "1",
Inp{"3451204593", "2454495034"}: "996709559",
Inp{"9999999999", "1275"}: "324",
Inp{"9999999999.9999998", "1275.49"}: "239.2399998",
Inp{"24544.95034", "0.3451204593"}: "0.3283950433",
Inp{"0.499999999999999999", "0.25"}: "0.249999999999999999",
Inp{"0.989512958912895912", "0.000001"}: "0.000000958912895912",
Inp{"0.1", "0.1"}: "0",
Inp{"0", "1.001"}: "0",
Inp{"-7.5", "2"}: "-1.5",
Inp{"7.5", "-2"}: "1.5",
Inp{"-7.5", "-2"}: "-1.5",
Fix mod when the divisor is slightly greater than the half of dividend (#312) (#317)
2024-01-10 02:08:45 +01:00
Inp{"41", "21"}: "20",
Inp{"400000000001", "200000000001"}: "200000000000",
Implement Modulus arithmetic function
2016-01-15 22:32:48 +01:00
}
for inp, res := range inputs {
a, err := NewFromString(inp.a)
if err != nil {
t.FailNow()
}
b, err := NewFromString(inp.b)
if err != nil {
t.FailNow()
}
c := a.Mod(b)
if c.String() != res {
t.Errorf("expected %s, got %s", res, c.String())
}
}
}
init
2015-02-10 21:33:58 +01:00
func TestDecimal_Overflow(t *testing.T) {
if !didPanic(func() { New(1, math.MinInt32).Mul(New(1, math.MinInt32)) }) {
t.Fatalf("should have gotten an overflow panic")
}
if !didPanic(func() { New(1, math.MaxInt32).Mul(New(1, math.MaxInt32)) }) {
t.Fatalf("should have gotten an overflow panic")
}
}
add stupid test for extreme values, fix some super-edge-case bugs
2015-06-14 21:39:05 +02:00
func TestDecimal_ExtremeValues(t *testing.T) {
// NOTE(vadim): this test takes pretty much forever
if testing.Short() {
t.Skip()
}
Fix some typos, add godoc badge
2017-01-28 15:42:33 +01:00
// NOTE(vadim): Seriously, the numbers involved are so large that this
add stupid test for extreme values, fix some super-edge-case bugs
2015-06-14 21:39:05 +02:00
// test will take way too long, so mark it as success if it takes over
// 1 second. The way this test typically fails (integer overflow) is that
// a wrong result appears quickly, so if it takes a long time then it is
// probably working properly.
// Why even bother testing this? Completeness, I guess. -Vadim
const timeLimit = 1 * time.Second
test := func(f func()) {
c := make(chan bool)
go func() {
f()
close(c)
}()
select {
case <-c:
case <-time.After(timeLimit):
}
}
test(func() {
got := New(123, math.MinInt32).Floor()
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got.Equal(NewFromFloat(0)) {
add stupid test for extreme values, fix some super-edge-case bugs
2015-06-14 21:39:05 +02:00
t.Errorf("Error: got %s, expected 0", got)
}
})
test(func() {
got := New(123, math.MinInt32).Ceil()
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got.Equal(NewFromFloat(1)) {
add stupid test for extreme values, fix some super-edge-case bugs
2015-06-14 21:39:05 +02:00
t.Errorf("Error: got %s, expected 1", got)
}
})
test(func() {
got := New(123, math.MinInt32).Rat().FloatString(10)
expected := "0.0000000000"
if got != expected {
t.Errorf("Error: got %s, expected %s", got, expected)
}
})
}
Add IntPart test.
2015-03-24 01:44:55 +01:00
func TestIntPart(t *testing.T) {
for _, testCase := range []struct {
Dec string
IntPart int64
Improve error messages, readability of test cases.
2015-03-26 04:13:03 +01:00
}{
{"0.01", 0},
{"12.1", 12},
{"9999.999", 9999},
{"-32768.01234", -32768},
} {
Add IntPart test.
2015-03-24 01:44:55 +01:00
d, err := NewFromString(testCase.Dec)
if err != nil {
t.Fatal(err)
}
if d.IntPart() != testCase.IntPart {
t.Errorf("expect %d, got %d", testCase.IntPart, d.IntPart())
}
}
}
Add new helper methods: BigInt, BigFloat (#171) * Add new helper methods: BigInt, BigFloat * Add few tests cases showing loss of precision after casting
2020-04-20 00:29:39 +02:00
func TestBigInt(t *testing.T) {
testCases := []struct {
Dec string
BigIntRep string
}{
{"0.0", "0"},
{"0.00000", "0"},
{"0.01", "0"},
{"12.1", "12"},
{"9999.999", "9999"},
{"-32768.01234", "-32768"},
{"-572372.0000000001", "-572372"},
}
for _, testCase := range testCases {
d, err := NewFromString(testCase.Dec)
if err != nil {
t.Fatal(err)
}
if d.BigInt().String() != testCase.BigIntRep {
t.Errorf("expect %s, got %s", testCase.BigIntRep, d.BigInt())
}
}
}
func TestBigFloat(t *testing.T) {
testCases := []struct {
Dec string
BigFloatRep string
}{
{"0.0", "0"},
{"0.00000", "0"},
{"0.01", "0.01"},
{"12.1", "12.1"},
{"9999.999", "9999.999"},
{"-32768.01234", "-32768.01234"},
{"-572372.0000000001", "-572372"},
{"512.012345123451234512345", "512.0123451"},
{"1.010101010101010101010101010101", "1.01010101"},
{"55555555.555555555555555555555", "55555555.56"},
}
for _, testCase := range testCases {
d, err := NewFromString(testCase.Dec)
if err != nil {
t.Fatal(err)
}
if d.BigFloat().String() != testCase.BigFloatRep {
t.Errorf("expect %s, got %s", testCase.BigFloatRep, d.BigFloat())
}
}
}
add Min and Max functions
2015-07-24 13:17:22 +02:00
func TestDecimal_Min(t *testing.T) {
// the first element in the array is the expected answer, rest are inputs
testCases := [][]float64{
{0, 0},
{1, 1},
{-1, -1},
{1, 1, 2},
{-2, 1, 2, -2},
{-3, 0, 2, -2, -3},
}
for _, test := range testCases {
expected, input := test[0], test[1:]
expectedDecimal := NewFromFloat(expected)
decimalInput := []Decimal{}
for _, inp := range input {
d := NewFromFloat(inp)
decimalInput = append(decimalInput, d)
}
got := Min(decimalInput[0], decimalInput[1:]...)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got.Equal(expectedDecimal) {
add Min and Max functions
2015-07-24 13:17:22 +02:00
t.Errorf("Expected %v, got %v, input=%+v", expectedDecimal, got,
decimalInput)
}
}
}
func TestDecimal_Max(t *testing.T) {
// the first element in the array is the expected answer, rest are inputs
testCases := [][]float64{
{0, 0},
{1, 1},
{-1, -1},
{2, 1, 2},
{2, 1, 2, -2},
{3, 0, 3, -2},
{-2, -3, -2},
}
for _, test := range testCases {
expected, input := test[0], test[1:]
expectedDecimal := NewFromFloat(expected)
decimalInput := []Decimal{}
for _, inp := range input {
d := NewFromFloat(inp)
decimalInput = append(decimalInput, d)
}
got := Max(decimalInput[0], decimalInput[1:]...)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !got.Equal(expectedDecimal) {
add Min and Max functions
2015-07-24 13:17:22 +02:00
t.Errorf("Expected %v, got %v, input=%+v", expectedDecimal, got,
decimalInput)
}
}
}
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
func scanHelper(t *testing.T, dbval interface{}, expected Decimal) {
t.Helper()
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
a := Decimal{}
if err := a.Scan(dbval); err != nil {
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
// Scan failed... no need to test result value
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
t.Errorf("a.Scan(%v) failed with message: %s", dbval, err)
} else if !a.Equal(expected) {
Fix some typos, add godoc badge
2017-01-28 15:42:33 +01:00
// Scan succeeded... test resulting values
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
t.Errorf("%s does not equal to %s", a, expected)
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
}
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
}
func TestDecimal_Scan(t *testing.T) {
// test the Scan method that implements the sql.Scanner interface
// check different types received from various database drivers
dbvalue := 54.33
expected := NewFromFloat(dbvalue)
scanHelper(t, dbvalue, expected)
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
Fix same issue as #39 but without changing the Value() interface
2017-02-21 19:34:52 +01:00
// apparently MySQL 5.7.16 and returns these as float32 so we need
// to handle these as well
dbvalueFloat32 := float32(54.33)
expected = NewFromFloat(float64(dbvalueFloat32))
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
scanHelper(t, dbvalueFloat32, expected)
Fix same issue as #39 but without changing the Value() interface
2017-02-21 19:34:52 +01:00
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
// at least SQLite returns an int64 when 0 is stored in the db
// and you specified a numeric format on the schema
Pass lint, add travis stuff to run golint
2017-02-16 00:55:38 +01:00
dbvalueInt := int64(0)
expected = New(dbvalueInt, 0)
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
scanHelper(t, dbvalueInt, expected)
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
// also test uint64
dbvalueUint64 := uint64(2)
expected = New(2, 0)
scanHelper(t, dbvalueUint64, expected)
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
// in case you specified a varchar in your SQL schema,
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
// the database driver may return either []byte or string
Pass lint, add travis stuff to run golint
2017-02-16 00:55:38 +01:00
valueStr := "535.666"
dbvalueStr := []byte(valueStr)
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
expected, err := NewFromString(valueStr)
Handle strings being passed to Scan() lib/pq can now pass strings to Scan() as of: https://github.com/lib/pq/commit/e2402a7cd1e57e08a576b94cdfed36ae30366545
2016-08-03 21:48:35 +02:00
if err != nil {
t.Fatal(err)
}
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
scanHelper(t, dbvalueStr, expected)
scanHelper(t, valueStr, expected)
Increase test coverage a bit
2017-02-16 00:47:03 +01:00
type foo struct{}
Support scanning uint64 (#364)
2024-04-12 15:35:56 +02:00
a := Decimal{}
Increase test coverage a bit
2017-02-16 00:47:03 +01:00
err = a.Scan(foo{})
if err == nil {
t.Errorf("a.Scan(Foo{}) should have thrown an error but did not")
}
Adding tests from the Scan method
2015-12-11 19:46:00 +01:00
}
Make Value take a pointer receiver
2015-12-24 01:56:58 +01:00
func TestDecimal_Value(t *testing.T) {
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
// Make sure this does implement the database/sql's driver.Valuer interface
var d Decimal
if _, ok := interface{}(d).(driver.Valuer); !ok {
t.Error("Decimal does not implement driver.Valuer")
Make Value take a pointer receiver
2015-12-24 01:56:58 +01:00
}
// check that normal case is handled appropriately
make Value() test more realistic
2016-09-18 22:06:18 +02:00
a := New(1234, -2)
expected := "12.34"
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
value, err := a.Value()
Make Value take a pointer receiver
2015-12-24 01:56:58 +01:00
if err != nil {
make Value() test more realistic
2016-09-18 22:06:18 +02:00
t.Errorf("Decimal(12.34).Value() failed with message: %s", err)
Make Value take a pointer receiver
2015-12-24 01:56:58 +01:00
} else if value.(string) != expected {
t.Errorf("%s does not equal to %s", a, expected)
}
}
init
2015-02-10 21:33:58 +01:00
// old tests after this line
func TestDecimal_Scale(t *testing.T) {
a := New(1234, -3)
if a.Exponent() != -3 {
t.Errorf("error")
}
}
func TestDecimal_Abs1(t *testing.T) {
a := New(-1234, -4)
b := New(1234, -4)
c := a.Abs()
if c.Cmp(b) != 0 {
t.Errorf("error")
}
}
func TestDecimal_Abs2(t *testing.T) {
a := New(-1234, -4)
b := New(1234, -4)
c := b.Abs()
if c.Cmp(a) == 0 {
t.Errorf("error")
}
}
added GT, GTE, LT, LTE (#54) * added GT, GTE, LT, LTE * GTE -> GreaterThanOrEqual
2017-05-18 00:01:17 +02:00
func TestDecimal_Equalities(t *testing.T) {
Add Equals test.
2015-03-23 23:14:19 +01:00
a := New(1234, 3)
b := New(1234, 3)
added GT, GTE, LT, LTE (#54) * added GT, GTE, LT, LTE * GTE -> GreaterThanOrEqual
2017-05-18 00:01:17 +02:00
c := New(1234, 4)
Add Equals test.
2015-03-23 23:14:19 +01:00
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if !a.Equal(b) {
Improve error messages, readability of test cases.
2015-03-26 04:13:03 +01:00
t.Errorf("%q should equal %q", a, b)
Add Equals test.
2015-03-23 23:14:19 +01:00
}
added GT, GTE, LT, LTE (#54) * added GT, GTE, LT, LTE * GTE -> GreaterThanOrEqual
2017-05-18 00:01:17 +02:00
if a.Equal(c) {
t.Errorf("%q should not equal %q", a, c)
}
Increase test coverage a bit
2017-02-16 00:47:03 +01:00
added GT, GTE, LT, LTE (#54) * added GT, GTE, LT, LTE * GTE -> GreaterThanOrEqual
2017-05-18 00:01:17 +02:00
// note, this block should be deprecated, here for backwards compatibility
Increase test coverage a bit
2017-02-16 00:47:03 +01:00
if !a.Equals(b) {
t.Errorf("%q should equal %q", a, b)
}
added GT, GTE, LT, LTE (#54) * added GT, GTE, LT, LTE * GTE -> GreaterThanOrEqual
2017-05-18 00:01:17 +02:00
if !c.GreaterThan(b) {
t.Errorf("%q should be greater than %q", c, b)
}
if b.GreaterThan(c) {
t.Errorf("%q should not be greater than %q", b, c)
}
if !a.GreaterThanOrEqual(b) {
t.Errorf("%q should be greater or equal %q", a, b)
}
if !c.GreaterThanOrEqual(b) {
t.Errorf("%q should be greater or equal %q", c, b)
}
if b.GreaterThanOrEqual(c) {
t.Errorf("%q should not be greater or equal %q", b, c)
}
if !b.LessThan(c) {
t.Errorf("%q should be less than %q", a, b)
}
if c.LessThan(b) {
t.Errorf("%q should not be less than %q", a, b)
}
if !a.LessThanOrEqual(b) {
t.Errorf("%q should be less than or equal %q", a, b)
}
if !b.LessThanOrEqual(c) {
t.Errorf("%q should be less than or equal %q", a, b)
}
if c.LessThanOrEqual(b) {
t.Errorf("%q should not be less than or equal %q", a, b)
}
Add Equals test.
2015-03-23 23:14:19 +01:00
}
func TestDecimal_ScalesNotEqual(t *testing.T) {
a := New(1234, 2)
b := New(1234, 3)
Added method Equal instead of method Equals
2017-02-06 16:46:03 +01:00
if a.Equal(b) {
Improve error messages, readability of test cases.
2015-03-26 04:13:03 +01:00
t.Errorf("%q should not equal %q", a, b)
Add Equals test.
2015-03-23 23:14:19 +01:00
}
}
init
2015-02-10 21:33:58 +01:00
func TestDecimal_Cmp1(t *testing.T) {
a := New(123, 3)
b := New(-1234, 2)
if a.Cmp(b) != 1 {
t.Errorf("Error")
}
}
func TestDecimal_Cmp2(t *testing.T) {
a := New(123, 3)
b := New(1234, 2)
if a.Cmp(b) != -1 {
t.Errorf("Error")
}
}
Add improved implementation of power operation (#358) * Adjust Pow implementation * Add PowWithPrecision method * Add PowInt32 method * Add PowBigInt method
2024-04-03 00:16:27 +02:00
func TestDecimal_Pow(t *testing.T) {
for _, testCase := range []struct {
Base string
Exponent string
Expected string
}{
{"0.0", "1.0", "0.0"},
{"0.0", "5.7", "0.0"},
{"0.0", "-3.2", "0.0"},
{"3.13", "0.0", "1.0"},
{"-591.5", "0.0", "1.0"},
{"3.0", "3.0", "27.0"},
{"3.0", "10.0", "59049.0"},
{"3.13", "5.0", "300.4150512793"},
{"4.0", "2.0", "16.0"},
{"4.0", "-2.0", "0.0625"},
{"629.25", "5.0", "98654323103449.5673828125"},
{"5.0", "5.73", "10118.08037159375"},
{"962.0", "3.2791", "6055212360.0000044205714144"},
{"5.69169126", "5.18515912", "8242.26344757948412597909547972726268869189399260047793106028930864"},
{"13.1337", "3.5196719618391835", "8636.856220644773844815693636723928750940666269885"},
{"67762386.283696923", "4.85917691669163916681738", "112761146905370140621385730157437443321.91755738117317148674362233906499698561022574811238435007575701773212242750262081945556470501"},
{"-3.0", "6.0", "729"},
{"-13.757", "5.0", "-492740.983929899460557"},
{"3.0", "-6.0", "0.0013717421124829"},
{"13.757", "-5.0", "0.000002029463821"},
{"66.12", "-7.61313", "0.000000000000013854086588876805036"},
{"6696871.12", "-2.61313", "0.000000000000000001455988684546983"},
{"-3.0", "-6.0", "0.0013717421124829"},
{"-13.757", "-5.0", "-0.000002029463821"},
} {
base, _ := NewFromString(testCase.Base)
exp, _ := NewFromString(testCase.Exponent)
expected, _ := NewFromString(testCase.Expected)
result := base.Pow(exp)
if result.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s, for %s^%s", testCase.Expected, result.String(), testCase.Base, testCase.Exponent)
}
}
}
func TestDecimal_PowWithPrecision(t *testing.T) {
for _, testCase := range []struct {
Base string
Exponent string
Precision int32
Expected string
}{
{"0.0", "1.0", 2, "0.0"},
{"0.0", "5.7", 2, "0.0"},
{"0.0", "-3.2", 2, "0.0"},
{"3.13", "0.0", 2, "1.0"},
{"-591.5", "0.0", 2, "1.0"},
{"3.0", "3.0", 2, "27.0"},
{"3.0", "10.0", 2, "59049.0"},
{"3.13", "5.0", 5, "300.4150512793"},
{"4.0", "2.0", 2, "16.0"},
{"4.0", "-2.0", 2, "0.06"},
{"4.0", "-2.0", 4, "0.0625"},
{"629.25", "5.0", 6, "98654323103449.5673828125"},
{"5.0", "5.73", 20, "10118.080371595019317118681359884375"},
{"962.0", "3.2791", 15, "6055212360.000004406551603058195732"},
{"5.69169126", "5.18515912", 4, "8242.26344757948412587366859330429895955552280978668983459852256"},
{"13.1337", "3.5196719618391835", 8, "8636.85622064477384481569363672392591908386390769375"},
{"67762386.283696923", "4.85917691669163916681738", 10, "112761146905370140621385730157437443321.917557381173174638304347353880676293576708009282115993465286373470882947470198597518762"},
{"-3.0", "6.0", 2, "729"},
{"-13.757", "5.0", 4, "-492740.983929899460557"},
{"3.0", "-6.0", 10, "0.0013717421"},
{"13.757", "-5.0", 20, "0.00000202946382098037"},
{"66.12", "-7.61313", 20, "0.00000000000001385381563049821591633907104023700216"},
{"6696871.12", "-2.61313", 24, "0.0000000000000000014558252733872790626400278983397459207418"},
{"-3.0", "-6.0", 8, "0.00137174"},
{"-13.757", "-5.0", 16, "-0.000002029463821"},
} {
base, _ := NewFromString(testCase.Base)
exp, _ := NewFromString(testCase.Exponent)
expected, _ := NewFromString(testCase.Expected)
result, _ := base.PowWithPrecision(exp, testCase.Precision)
if result.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s, for %s^%s", testCase.Expected, result.String(), testCase.Base, testCase.Exponent)
}
}
}
func TestDecimal_PowWithPrecision_Infinity(t *testing.T) {
for _, testCase := range []struct {
Base string
Exponent string
}{
{"0.0", "0.0"},
{"0.0", "-2.0"},
{"0.0", "-4.6"},
{"-66.12", "7.61313"}, // Imaginary value
{"-5696871.12", "5.61313"}, // Imaginary value
} {
base, _ := NewFromString(testCase.Base)
exp, _ := NewFromString(testCase.Exponent)
_, err := base.PowWithPrecision(exp, 5)
if err == nil {
t.Errorf("lool it should be error")
}
}
}
func TestDecimal_PowWithPrecision_UndefinedResult(t *testing.T) {
base := RequireFromString("0")
exponent := RequireFromString("0")
_, err := base.PowWithPrecision(exponent, 4)
if err == nil {
t.Errorf("expected error, cannot be represent undefined value of 0**0")
add Pow()
2016-09-19 23:54:54 +02:00
}
}
Add improved implementation of power operation (#358) * Adjust Pow implementation * Add PowWithPrecision method * Add PowInt32 method * Add PowBigInt method
2024-04-03 00:16:27 +02:00
func TestDecimal_PowWithPrecision_InfinityResult(t *testing.T) {
for _, testCase := range []struct {
Base string
Exponent string
}{
{"0.0", "-2.0"},
{"0.0", "-4.6"},
{"0.0", "-9239.671333"},
} {
base, _ := NewFromString(testCase.Base)
exp, _ := NewFromString(testCase.Exponent)
_, err := base.PowWithPrecision(exp, 4)
if err == nil {
t.Errorf("expected error, cannot represent infinity value of 0 ** y, where y < 0")
}
}
}
func TestDecimal_PowWithPrecision_ImaginaryResult(t *testing.T) {
for _, testCase := range []struct {
Base string
Exponent string
}{
{"-0.2261", "106.12"},
{"-66.12", "7.61313"},
{"-5696871.12", "5.61313"},
} {
base, _ := NewFromString(testCase.Base)
exp, _ := NewFromString(testCase.Exponent)
_, err := base.PowWithPrecision(exp, 4)
if err == nil {
t.Errorf("expected error, cannot represent imaginary value of x ** y, where x < 0 and y is non-integer decimal")
}
}
}
func TestDecimal_PowInt32(t *testing.T) {
for _, testCase := range []struct {
Decimal string
Exponent int32
Expected string
}{
{"0.0", 1, "0.0"},
{"3.13", 0, "1.0"},
{"-591.5", 0, "1.0"},
{"3.0", 3, "27.0"},
{"3.0", 10, "59049.0"},
{"3.13", 5, "300.4150512793"},
{"629.25", 5, "98654323103449.5673828125"},
{"-3.0", 6, "729"},
{"-13.757", 5, "-492740.983929899460557"},
{"3.0", -6, "0.0013717421124829"},
{"-13.757", -5, "-0.000002029463821"},
} {
base, _ := NewFromString(testCase.Decimal)
expected, _ := NewFromString(testCase.Expected)
result, _ := base.PowInt32(testCase.Exponent)
if result.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s, for %s**%d", testCase.Expected, result.String(), testCase.Decimal, testCase.Exponent)
}
}
}
func TestDecimal_PowInt32_UndefinedResult(t *testing.T) {
base := RequireFromString("0")
_, err := base.PowInt32(0)
if err == nil {
t.Errorf("expected error, cannot be represent undefined value of 0**0")
}
}
func TestDecimal_PowBigInt(t *testing.T) {
for _, testCase := range []struct {
Decimal string
Exponent *big.Int
Expected string
}{
{"3.13", big.NewInt(0), "1.0"},
{"-591.5", big.NewInt(0), "1.0"},
{"3.0", big.NewInt(3), "27.0"},
{"3.0", big.NewInt(10), "59049.0"},
{"3.13", big.NewInt(5), "300.4150512793"},
{"629.25", big.NewInt(5), "98654323103449.5673828125"},
{"-3.0", big.NewInt(6), "729"},
{"-13.757", big.NewInt(5), "-492740.983929899460557"},
{"3.0", big.NewInt(-6), "0.0013717421124829"},
{"-13.757", big.NewInt(-5), "-0.000002029463821"},
} {
base, _ := NewFromString(testCase.Decimal)
expected, _ := NewFromString(testCase.Expected)
result, _ := base.PowBigInt(testCase.Exponent)
if result.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s, for %s**%d", testCase.Expected, result.String(), testCase.Decimal, testCase.Exponent)
}
}
}
func TestDecimal_PowBigInt_UndefinedResult(t *testing.T) {
base := RequireFromString("0")
_, err := base.PowBigInt(big.NewInt(0))
if err == nil {
t.Errorf("expected error, undefined value of 0**0 cannot be represented")
Added negative pow test
2017-02-23 17:50:30 +01:00
}
}
Implement IsInteger method (#179)
2020-07-01 01:20:32 +02:00
func TestDecimal_IsInteger(t *testing.T) {
for _, testCase := range []struct {
Dec string
IsInteger bool
}{
{"0", true},
{"0.0000", true},
{"0.01", false},
{"0.01010101010000", false},
{"12.0", true},
{"12.00000000000000", true},
{"12.10000", false},
{"9999.0000", true},
{"99999999.000000000", true},
{"-656323444.0000000000000", true},
{"-32768.01234", false},
{"-32768.0123423562623600000", false},
} {
d, err := NewFromString(testCase.Dec)
if err != nil {
t.Fatal(err)
}
if d.IsInteger() != testCase.IsInteger {
t.Errorf("expect %t, got %t, for %s", testCase.IsInteger, d.IsInteger(), testCase.Dec)
}
}
}
Add implementation of natural exponent function (Taylor, Hull-Abraham) (#229) * Add implementation of natural exponent function (Taylor, Hull-Abraham) * Update docs * Improve docs, handle multithreading race condition in exp method
2021-10-11 18:39:38 +02:00
func TestDecimal_ExpHullAbrham(t *testing.T) {
for _, testCase := range []struct {
Dec string
OverallPrecision uint32
ExpectedDec string
}{
{"0", 1, "1"},
{"0.00", 5, "1"},
{"0.5", 5, "1.6487"},
{"0.569297", 10, "1.767024397"},
{"0.569297", 16, "1.76702439654095"},
{"0.569297", 20, "1.7670243965409496521"},
{"1.0", 0, "3"},
{"1.0", 1, "3"},
{"1.0", 5, "2.7183"},
{"1.0", 10, "2.718281828"},
{"3.0", 0, "20"},
{"3.0", 2, "20"},
{"5.26", 0, "200"},
{"5.26", 2, "190"},
{"5.26", 10, "192.4814913"},
{"5.2663117716", 2, "190"},
{"5.2663117716", 10, "193.7002327"},
{"26.1", 2, "220000000000"},
{"26.1", 10, "216314672100"},
{"26.1", 20, "216314672147.05767284"},
{"50.1591", 10, "6078834887000000000000"},
{"50.1591", 30, "6078834886623434464595.07937141"},
{"-0.5", 5, "0.60653"},
{"-0.569297", 10, "0.5659231429"},
{"-0.569297", 16, "0.565923142859576"},
{"-0.569297", 20, "0.56592314285957604443"},
{"-1.0", 1, "0.4"},
{"-1.0", 5, "0.36788"},
{"-3.0", 1, "0"},
{"-3.0", 2, "0.05"},
{"-3.0", 10, "0.0497870684"},
{"-5.26", 2, "0.01"},
{"-5.26", 10, "0.0051953047"},
{"-5.2663117716", 2, "0.01"},
{"-5.2663117716", 10, "0.0051626164"},
{"-26.1", 2, "0"},
{"-26.1", 15, "0.000000000004623"},
{"-50.1591", 10, "0"},
{"-50.1591", 30, "0.000000000000000000000164505208"},
} {
d, _ := NewFromString(testCase.Dec)
expected, _ := NewFromString(testCase.ExpectedDec)
exp, err := d.ExpHullAbrham(testCase.OverallPrecision)
if err != nil {
t.Fatal(err)
}
if exp.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s, for decimal %s", testCase.ExpectedDec, exp.String(), testCase.Dec)
}
}
}
func TestDecimal_ExpTaylor(t *testing.T) {
for _, testCase := range []struct {
Dec string
Precision int32
ExpectedDec string
}{
{"0", 1, "1"},
{"0.00", 5, "1"},
{"0", -1, "0"},
{"0.5", 5, "1.64872"},
{"0.569297", 10, "1.7670243965"},
{"0.569297", 16, "1.7670243965409497"},
{"0.569297", 20, "1.76702439654094965215"},
{"1.0", 0, "3"},
{"1.0", 1, "2.7"},
{"1.0", 5, "2.71828"},
{"1.0", -1, "0"},
{"1.0", -5, "0"},
{"3.0", 1, "20.1"},
{"3.0", 2, "20.09"},
{"5.26", 0, "192"},
{"5.26", 2, "192.48"},
{"5.26", 10, "192.4814912972"},
{"5.26", -2, "200"},
{"5.2663117716", 2, "193.70"},
{"5.2663117716", 10, "193.7002326701"},
{"26.1", 2, "216314672147.06"},
{"26.1", 20, "216314672147.05767284062928674083"},
{"26.1", -2, "216314672100"},
{"26.1", -10, "220000000000"},
{"50.1591", 10, "6078834886623434464595.0793714061"},
{"-0.5", 5, "0.60653"},
{"-0.569297", 10, "0.5659231429"},
{"-0.569297", 16, "0.565923142859576"},
{"-0.569297", 20, "0.56592314285957604443"},
{"-1.0", 1, "0.4"},
{"-1.0", 5, "0.36788"},
{"-1.0", -1, "0"},
{"-1.0", -5, "0"},
{"-3.0", 1, "0.1"},
{"-3.0", 2, "0.05"},
{"-3.0", 10, "0.0497870684"},
{"-5.26", 2, "0.01"},
{"-5.26", 10, "0.0051953047"},
{"-5.26", -2, "0"},
{"-5.2663117716", 2, "0.01"},
{"-5.2663117716", 10, "0.0051626164"},
{"-26.1", 2, "0"},
{"-26.1", 15, "0.000000000004623"},
{"-26.1", -2, "0"},
{"-26.1", -10, "0"},
{"-50.1591", 10, "0"},
{"-50.1591", 30, "0.000000000000000000000164505208"},
} {
d, _ := NewFromString(testCase.Dec)
expected, _ := NewFromString(testCase.ExpectedDec)
exp, err := d.ExpTaylor(testCase.Precision)
if err != nil {
t.Fatal(err)
}
if exp.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s", testCase.ExpectedDec, exp.String())
}
}
}
Add implementation of natural logarithm (#339) * Add initial implementation of natural logarithm * Add constApproxmation struct to represent mathematical constants with their approximations
2023-12-29 01:59:48 +01:00
func TestDecimal_Ln(t *testing.T) {
for _, testCase := range []struct {
Dec string
Precision int32
Expected string
}{
{"0.1", 25, "-2.3025850929940456840179915"},
{"0.01", 25, "-4.6051701859880913680359829"},
{"0.001", 25, "-6.9077552789821370520539744"},
{"0.00000001", 25, "-18.4206807439523654721439316"},
{"1.0", 10, "0.0"},
{"1.01", 25, "0.0099503308531680828482154"},
{"1.001", 25, "0.0009995003330835331668094"},
{"1.0001", 25, "0.0000999950003333083353332"},
{"1.1", 25, "0.0953101798043248600439521"},
{"1.13", 25, "0.1222176327242492005461486"},
{"3.13", 10, "1.1410330046"},
{"3.13", 25, "1.1410330045520618486427824"},
{"3.13", 50, "1.14103300455206184864278239988848193837089629107972"},
{"3.13", 100, "1.1410330045520618486427823998884819383708962910797239760817078430268177216960996098918971117211892839"},
{"5.71", 25, "1.7422190236679188486939833"},
{"5.7185108151957193571930205", 50, "1.74370842450178929149992165925283704012576949094645"},
{"839101.0351", 25, "13.6400864014410013994397240"},
{"839101.0351094726488848490572028502", 50, "13.64008640145229044389152437468283605382056561604272"},
{"5023583755703750094849.03519358513093500275017501750602739169823", 25, "49.9684305274348922267409953"},
{"5023583755703750094849.03519358513093500275017501750602739169823", -1, "50.0"},
Adjust Ln method to prevent infinity iteration loops (#357) * Adjust Ln method to prevent infinity iteration loops * Add test case for infinity loop
2024-04-01 22:02:25 +02:00
{"66.12", 18, "4.191471272952823429"},
Add implementation of natural logarithm (#339) * Add initial implementation of natural logarithm * Add constApproxmation struct to represent mathematical constants with their approximations
2023-12-29 01:59:48 +01:00
} {
d, _ := NewFromString(testCase.Dec)
expected, _ := NewFromString(testCase.Expected)
ln, err := d.Ln(testCase.Precision)
if err != nil {
t.Fatal(err)
}
if ln.Cmp(expected) != 0 {
t.Errorf("expected %s, got %s, for decimal %s", testCase.Expected, ln.String(), testCase.Dec)
}
}
}
func TestDecimal_LnZero(t *testing.T) {
d := New(0, 0)
_, err := d.Ln(5)
if err == nil {
t.Errorf("expected error, natural logarithm of 0 cannot be represented (-infinity)")
}
}
func TestDecimal_LnNegative(t *testing.T) {
d := New(-20, 2)
_, err := d.Ln(5)
if err == nil {
t.Errorf("expected error, natural logarithm cannot be calculated for nagative decimals")
}
}
Add implementation of natural exponent function (Taylor, Hull-Abraham) (#229) * Add implementation of natural exponent function (Taylor, Hull-Abraham) * Update docs * Improve docs, handle multithreading race condition in exp method
2021-10-11 18:39:38 +02:00
func TestDecimal_NumDigits(t *testing.T) {
for _, testCase := range []struct {
Dec string
ExpectedNumDigits int
}{
{"0", 1},
{"0.00", 1},
{"1.0", 2},
{"3.0", 2},
{"5.26", 3},
{"5.2663117716", 11},
{"3164836416948884.2162426426426267863", 35},
{"26.1", 3},
{"529.1591", 7},
{"-1.0", 2},
{"-3.0", 2},
{"-5.26", 3},
{"-5.2663117716", 11},
{"-26.1", 3},
Ensure empty Decimal returns correct zero-value NumDigits (#301)
2023-12-31 13:11:33 +01:00
{"", 1},
Add implementation of natural exponent function (Taylor, Hull-Abraham) (#229) * Add implementation of natural exponent function (Taylor, Hull-Abraham) * Update docs * Improve docs, handle multithreading race condition in exp method
2021-10-11 18:39:38 +02:00
} {
d, _ := NewFromString(testCase.Dec)
nums := d.NumDigits()
if nums != testCase.ExpectedNumDigits {
t.Errorf("expected %d digits for decimal %s, got %d", testCase.ExpectedNumDigits, testCase.Dec, nums)
}
}
}
Add Sign method d.Sign() is a more convenient way of saying d.Cmp(Zero).
2016-12-12 03:00:26 +01:00
func TestDecimal_Sign(t *testing.T) {
if Zero.Sign() != 0 {
t.Errorf("%q should have sign 0", Zero)
}
one := New(1, 0)
if one.Sign() != 1 {
t.Errorf("%q should have sign 1", one)
}
mone := New(-1, 0)
if mone.Sign() != -1 {
t.Errorf("%q should have sign -1", mone)
}
}
init
2015-02-10 21:33:58 +01:00
func didPanic(f func()) bool {
ret := false
func() {
defer func() {
if message := recover(); message != nil {
ret = true
}
}()
// call the target function
f()
}()
return ret
}
Add a fast track to d.Cmp(d2) when d.exp == d2.exp This makes a noticeable difference when one is sorting a large slice of decimals when most of them have the same precision, as it is saving a lot of calls to rescale().
2015-12-11 23:54:57 +01:00
Expose a Coefficient() function
2017-01-16 23:54:52 +01:00
func TestDecimal_Coefficient(t *testing.T) {
d := New(123, 0)
co := d.Coefficient()
if co.Int64() != 123 {
t.Error("Coefficient should be 123; Got:", co)
}
Defensive Copy on Coefficient (#52)
2017-05-17 16:58:21 +02:00
co.Set(big.NewInt(0))
if d.IntPart() != 123 {
t.Error("Modifying coefficient modified Decimal; Got:", d)
}
Expose a Coefficient() function
2017-01-16 23:54:52 +01:00
}
Add implementation of CoefficientInt64 method (#244) * Add implementation of CoefficientInt64 method
2021-09-10 15:48:44 +02:00
func TestDecimal_CoefficientInt64(t *testing.T) {
type Inp struct {
Reformat code base and update decimal copy docs (#249)
2021-10-12 12:11:39 +02:00
Dec string
Add implementation of CoefficientInt64 method (#244) * Add implementation of CoefficientInt64 method
2021-09-10 15:48:44 +02:00
Coefficient int64
}
testCases := []Inp{
{"1", 1},
{"1.111", 1111},
{"1.000000", 1000000},
{"1.121215125511", 1121215125511},
{"100000000000000000", 100000000000000000},
{"9223372036854775807", 9223372036854775807},
{"10000000000000000000", -8446744073709551616}, // undefined value
}
// add negative cases
for _, tc := range testCases {
testCases = append(testCases, Inp{"-" + tc.Dec, -tc.Coefficient})
}
for _, tc := range testCases {
d := RequireFromString(tc.Dec)
coefficient := d.CoefficientInt64()
if coefficient != tc.Coefficient {
t.Errorf("expect coefficient %d, got %d, for decimal %s", tc.Coefficient, coefficient, tc.Dec)
}
}
}
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
func TestNullDecimal_Scan(t *testing.T) {
// test the Scan method that implements the
// sql.Scanner interface
// check for the for different type of values
// that are possible to be received from the database
// drivers
// in normal operations the db driver (sqlite at least)
// will return an int64 if you specified a numeric format
// Make sure handles nil values
a := NullDecimal{}
var dbvaluePtr interface{}
err := a.Scan(dbvaluePtr)
if err != nil {
// Scan failed... no need to test result value
t.Errorf("a.Scan(nil) failed with message: %s", err)
} else {
if a.Valid {
t.Errorf("%s is not null", a.Decimal)
}
}
Improve go report cards score (#174) * Improve go report cards score
2020-04-27 08:03:21 +02:00
dbvalue := 54.33
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
expected := NewFromFloat(dbvalue)
err = a.Scan(dbvalue)
if err != nil {
// Scan failed... no need to test result value
t.Errorf("a.Scan(54.33) failed with message: %s", err)
} else {
Fix misspellings
2017-02-16 01:03:27 +01:00
// Scan succeeded... test resulting values
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
if !a.Valid {
t.Errorf("%s is null", a.Decimal)
} else if !a.Decimal.Equals(expected) {
t.Errorf("%s does not equal to %s", a.Decimal, expected)
}
}
// at least SQLite returns an int64 when 0 is stored in the db
// and you specified a numeric format on the schema
dbvalueInt := int64(0)
expected = New(dbvalueInt, 0)
err = a.Scan(dbvalueInt)
if err != nil {
// Scan failed... no need to test result value
t.Errorf("a.Scan(0) failed with message: %s", err)
} else {
Fix misspellings
2017-02-16 01:03:27 +01:00
// Scan succeeded... test resulting values
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
if !a.Valid {
t.Errorf("%s is null", a.Decimal)
} else if !a.Decimal.Equals(expected) {
Fix some grammar, go vet issues
2017-02-16 01:06:17 +01:00
t.Errorf("%v does not equal %v", a, expected)
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
}
}
// in case you specified a varchar in your SQL schema,
// the database driver will return byte slice []byte
valueStr := "535.666"
dbvalueStr := []byte(valueStr)
expected, err = NewFromString(valueStr)
if err != nil {
t.Fatal(err)
}
err = a.Scan(dbvalueStr)
if err != nil {
// Scan failed... no need to test result value
t.Errorf("a.Scan('535.666') failed with message: %s", err)
} else {
Fix misspellings
2017-02-16 01:03:27 +01:00
// Scan succeeded... test resulting values
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
if !a.Valid {
t.Errorf("%s is null", a.Decimal)
} else if !a.Decimal.Equals(expected) {
Fix some grammar, go vet issues
2017-02-16 01:06:17 +01:00
t.Errorf("%v does not equal %v", a, expected)
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
}
}
// lib/pq can also return strings
expected, err = NewFromString(valueStr)
if err != nil {
t.Fatal(err)
}
err = a.Scan(valueStr)
if err != nil {
// Scan failed... no need to test result value
t.Errorf("a.Scan('535.666') failed with message: %s", err)
} else {
Fix misspellings
2017-02-16 01:03:27 +01:00
// Scan succeeded... test resulting values
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
if !a.Valid {
t.Errorf("%s is null", a.Decimal)
} else if !a.Decimal.Equals(expected) {
Fix some grammar, go vet issues
2017-02-16 01:06:17 +01:00
t.Errorf("%v does not equal %v", a, expected)
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
}
}
}
func TestNullDecimal_Value(t *testing.T) {
// Make sure this does implement the database/sql's driver.Valuer interface
var nullDecimal NullDecimal
if _, ok := interface{}(nullDecimal).(driver.Valuer); !ok {
t.Error("NullDecimal does not implement driver.Valuer")
}
// check that null is handled appropriately
value, err := nullDecimal.Value()
if err != nil {
t.Errorf("NullDecimal{}.Valid() failed with message: %s", err)
} else if value != nil {
t.Errorf("%v is not nil", value)
}
// check that normal case is handled appropriately
a := NullDecimal{Decimal: New(1234, -2), Valid: true}
expected := "12.34"
value, err = a.Value()
if err != nil {
t.Errorf("NullDecimal(12.34).Value() failed with message: %s", err)
} else if value.(string) != expected {
Fix some grammar, go vet issues
2017-02-16 01:06:17 +01:00
t.Errorf("%v does not equal %v", a, expected)
Added NullDecimal. Changed Decimal to implement driver.Valuer. From comments in PR 16.
2016-11-02 17:15:14 +01:00
}
}
Binary Marshalling Support (#49) Adds MarshalBinary and UnmarshalBinary methods
2017-02-20 04:31:54 +01:00
func TestBinary(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, y := range testTable {
x := y.float
Binary Marshalling Support (#49) Adds MarshalBinary and UnmarshalBinary methods
2017-02-20 04:31:54 +01:00
// Create the decimal
d1 := NewFromFloat(x)
// Encode to binary
b, err := d1.MarshalBinary()
if err != nil {
t.Errorf("error marshalling %v to binary: %v", d1, err)
}
// Restore from binary
var d2 Decimal
err = (&d2).UnmarshalBinary(b)
if err != nil {
t.Errorf("error unmarshalling from binary: %v", err)
}
// The restored decimal should equal the original
if !d1.Equals(d2) {
t.Errorf("expected %v when restoring, got %v", d1, d2)
}
}
}
Add GobEncode and GobDecode, fixes the issue raised in #23 but with Marshal/UnmarshalBinary
2017-02-21 19:23:18 +01:00
Fix binary marshalling of decimal zero value (#253) * Fix binary marshalling of zero value * Adapt the error message of BinaryUnmarshal
2021-10-20 12:49:41 +02:00
func TestBinary_Zero(t *testing.T) {
var d1 Decimal
b, err := d1.MarshalBinary()
if err != nil {
t.Fatalf("error marshalling %v to binary: %v", d1, err)
}
var d2 Decimal
err = (&d2).UnmarshalBinary(b)
if err != nil {
t.Errorf("error unmarshalling from binary: %v", err)
}
if !d1.Equals(d2) {
t.Errorf("expected %v when restoring, got %v", d1, d2)
}
}
Add slice range checks to `UnmarshalBinary()` (#232) * Add slice range checks to `UnmarshalBinary()`. * Avoid use of `%w` verb with `Errorf()` for compatibility with older Go versions.
2021-06-23 00:24:56 +02:00
func TestBinary_DataTooShort(t *testing.T) {
var d Decimal
err := d.UnmarshalBinary(nil) // nil slice has length 0
if err == nil {
t.Fatalf("expected error, got %v", d)
}
}
func TestBinary_InvalidValue(t *testing.T) {
var d Decimal
err := d.UnmarshalBinary([]byte{0, 0, 0, 0, 'x'}) // valid exponent, invalid value
if err == nil {
t.Fatalf("expected error, got %v", d)
}
}
Add GobEncode and GobDecode, fixes the issue raised in #23 but with Marshal/UnmarshalBinary
2017-02-21 19:23:18 +01:00
func slicesEqual(a, b []byte) bool {
for i, val := range a {
if b[i] != val {
return false
}
}
return true
}
func TestGobEncode(t *testing.T) {
Exact representation in NewFromFloat (#78) * Additional (and some breaking) tests for NewFromFloatWithExponent * Addressing tests for NewFromFloatWithExponent * Naming cosmetic correction * removing unused code * Improving FromFloatWithExponent * Tests for exact float representation added * Exact float representation in FromFloat * Adding breaking test for NewFromFloat * Fast path in FromFloat is unreliable, fixing it * Addressing special meaning of zero exponent in float64 * NewFromFloatWithExponent: subnormals support * NewFromFloatWithExponent: just a few additional test cases * NewFromFloat: documentation update * NewFromFloatWithExponent: optimization and some documentation * NewFromFloatWithExponent: optimizations * NewFromFloatWithExponent: optimizations
2018-03-01 22:29:43 +01:00
for _, y := range testTable {
x := y.float
Add GobEncode and GobDecode, fixes the issue raised in #23 but with Marshal/UnmarshalBinary
2017-02-21 19:23:18 +01:00
d1 := NewFromFloat(x)
b1, err := d1.GobEncode()
if err != nil {
t.Errorf("error encoding %v to binary: %v", d1, err)
}
d2 := NewFromFloat(x)
b2, err := d2.GobEncode()
if err != nil {
t.Errorf("error encoding %v to binary: %v", d2, err)
}
if !slicesEqual(b1, b2) {
t.Errorf("something about the gobencode is not working properly \n%v\n%v", b1, b2)
}
var d3 Decimal
err = d3.GobDecode(b1)
if err != nil {
t.Errorf("Error gobdecoding %v, got %v", b1, d3)
}
var d4 Decimal
err = d4.GobDecode(b2)
if err != nil {
t.Errorf("Error gobdecoding %v, got %v", b2, d4)
}
eq := d3.Equal(d4)
if eq != true {
t.Errorf("Encoding then decoding mutated Decimal")
}
Fix GobDecode (#51) This commit fixes GobDecode, which were mutating a copy of the receiver, rather than the intended pointed struct.
2017-05-09 14:51:20 +02:00
eq = d1.Equal(d3)
if eq != true {
t.Errorf("Error gobencoding/decoding %v, got %v", d1, d3)
}
Add GobEncode and GobDecode, fixes the issue raised in #23 but with Marshal/UnmarshalBinary
2017-02-21 19:23:18 +01:00
}
}
Suggesting Sum and Avg methods (provided unit tests), recommending removing val2 from for range loops in TestBinary & TestGobEncode (#60)
2017-09-05 15:57:20 +02:00
func TestSum(t *testing.T) {
vals := make([]Decimal, 10)
var i = int64(0)
for key := range vals {
vals[key] = New(i, 0)
i++
}
sum := Sum(vals[0], vals[1:]...)
if !sum.Equal(New(45, 0)) {
t.Errorf("Failed to calculate sum, expected %s got %s", New(45, 0), sum)
}
}
func TestAvg(t *testing.T) {
vals := make([]Decimal, 10)
var i = int64(0)
for key := range vals {
vals[key] = New(i, 0)
i++
}
avg := Avg(vals[0], vals[1:]...)
if !avg.Equal(NewFromFloat(4.5)) {
t.Errorf("Failed to calculate average, expected %s got %s", NewFromFloat(4.5).String(), avg.String())
}
}
Fix broken RoundBank func in #75 (#76)
2018-01-18 23:52:17 +01:00
func TestRoundBankAnomaly(t *testing.T) {
a := New(25, -1)
b := New(250, -2)
if !a.Equal(b) {
t.Errorf("Expected %s to equal %s", a, b)
}
expected := New(2, 0)
aRounded := a.RoundBank(0)
if !aRounded.Equal(expected) {
t.Errorf("Expected bank rounding %s to equal %s, but it was %s", a, expected, aRounded)
}
bRounded := b.RoundBank(0)
if !bRounded.Equal(expected) {
t.Errorf("Expected bank rounding %s to equal %s, but it was %s", b, expected, bRounded)
}
}
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
// Trig tests
// For Atan
func TestAtan(t *testing.T) {
inps := []string{
"-2.91919191919191919",
"-1.0",
"-0.25",
"0.0",
"0.33",
"1.0",
"5.0",
"10",
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"11000020.2407442310156021090304691671842603586882014729198302312846062338790031898128063403419218957424",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
sols := []string{
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"-1.24076438822058001027437062753106",
"-0.78539816339744833061616997868383",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
"-0.24497866312686415",
"0.0",
"0.318747560420644443",
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"0.78539816339744833061616997868383",
"1.37340076694501580123233995736766",
"1.47112767430373453123233995736766",
"1.57079623588597296123259450235374",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
for i, inp := range inps {
d, err := NewFromString(inp)
if err != nil {
t.FailNow()
}
s, err := NewFromString(sols[i])
if err != nil {
t.FailNow()
}
a := d.Atan()
if !a.Equal(s) {
t.Errorf("expected %s, got %s", s, a)
}
}
}
// For Sin
func TestSin(t *testing.T) {
inps := []string{
"-2.91919191919191919",
"-1.0",
"-0.25",
"0.0",
"0.33",
"1.0",
"5.0",
"10",
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"11000020.2407442310156021090304691671842603586882014729198302312846062338790031898128063403419218957424",
}
sols := []string{"-0.22057186252002995641471297726318877448242875710373383657841216606788849153474483300147427943530288911869356126149550184271061369789963810497434594683859566879253561990821788142048867910104964466745284318577343435957806286762494529983369776697504436326725441516925396488258485248699247367113416543705253919473126183478178486954138205996912770183192357029798618739277146694040778731661407420114923656224752540889120768",
"-0.841470984807896544828551915928318375739843472469519282898610111931110319333748010828751784005573402229699531838022117989945539661588502120624574802425114599802714611508860519655182175315926637327774878594985045816542706701485174683683726979309922117859910272413672784175028365607893544855897795184024100973080880074046886009375162838756876336134083638363801171409953672944184918309063800980214873465660723218405962257950683415203634506166523593278",
"-0.2474039592545229296662577977006816864013671875",
"0",
"0.3240430283948683457891331120415701894104386268737728",
"0.841470984807896544828551915928318375739843472469519282898610111931110319333748010828751784005573402229699531838022117989945539661588502120624574802425114599802714611508860519655182175315926637327774878594985045816542706701485174683683726979309922117859910272413672784175028365607893544855897795184024100973080880074046886009375162838756876336134083638363801171409953672944184918309063800980214873465660723218405962257950683415203634506166523593278",
"-0.958924274663138409032065951037351417114444405831206421994322505831797734568720303321152847999323782235893449831846516332891972309733806145798957570823292783131379570446989311599459252931842975162373777189193072018951049969744350662993214861042908755303566670204873618202680865638534865944483058650517380292320436016362659617294570185140789829574277032406195741535138712427510938542219940873171248862329526140744770994303733112530324791184417282382",
"-0.54402111088937016772477554483765124109312606762621462357463994520238396180161585438877562935656067241573063207614488370477645194661241525080677431257416988398683714890165970942834453391033857378247849486306346743023618509617104937236345831462093934032592562972419977883837745736210439651143668255744843041350221801750331646628192115694352540293150183983357476391787825596543270240461102629075832777618592034309799936",
"-0.564291758480422881634770440632390475980828840253516895637281099241819037882007239070203007530085741820184955492382572029153491807930868879341091067301689987699567034024159005627332722089169680203292567574310010066799858914647295684974242359142300929248173166551428537696685165964880390889406578530338963341989826231514301546476672476399906348023294571001061677668735117509440368611093448917120819545826797975989350435900286332895885871219875665471968941335407351099209738417818747252638912592184093301853338763294381446907254104878969784040526201729163408095795934201105630182851806342356035203279670146684553491616847294749721014579109870396804713831114709372638323643327823671187472335866664108658093206409882794958673673978956925250261545083579947618620746006004554405785185537391110314728988164693223775249484198058394348289545771967707968288542718255197272633789792059019367104377340604030147471453833808674013259696102003732963091159662478879760121731138091114134586544668859915547568540172541576138084166990547345181184322550297604278946942918844039406876827936831612756344331500301118652183156052728447906384772901595431751550607818380262138322673253023464533931883787069611052589166000316238423939491520880451263927981787175602294299295744",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
for i, inp := range inps {
d, err := NewFromString(inp)
if err != nil {
t.FailNow()
}
s, err := NewFromString(sols[i])
if err != nil {
t.FailNow()
}
a := d.Sin()
if !a.Equal(s) {
t.Errorf("expected %s, got %s", s, a)
}
}
}
// For Cos
func TestCos(t *testing.T) {
inps := []string{
"-2.91919191919191919",
"-1.0",
"-0.25",
"0.0",
"0.33",
"1.0",
"5.0",
"10",
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"11000020.2407442310156021090304691671842603586882014729198302312846062338790031898128063403419218957424",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
sols := []string{
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"-0.975370726167463467746508538219884948528729295145689640359666742268127382748782064668565276308334226452812521220478854320025773591423493734486361306323829818426063430805234608660356853863442937297855742231573288105774823103008774355455799906250461848079705023428527473474556899228935370709945979509634251305018978306493011197513482210179171510947538040406781879762352211326273272515279567525396877609653501706919545667682725671944948392322552266752",
"0.54030230586813965874561515067176071767603141150991567490927772778673118786033739102174242337864109186439207498973007363884202112942385976796862442063752663646870430360736682397798633852405003167527051283327366631405990604840629657123985368031838052877290142895506386796217551784101265975360960112885444847880134909594560331781699767647860744559228420471946006511861233129745921297270844542687374552066388998112901504",
"0.968912421710644784099084544806854121387004852294921875",
"1",
"0.9460423435283869715490383692051286742343482760977712222",
"0.54030230586813965874561515067176071767603141150991567490927772778673118786033739102174242337864109186439207498973007363884202112942385976796862442063752663646870430360736682397798633852405003167527051283327366631405990604840629657123985368031838052877290142895506386796217551784101265975360960112885444847880134909594560331781699767647860744559228420471946006511861233129745921297270844542687374552066388998112901504",
"0.28366218546322646623291670213892426815646045792775066552057877370468842342090306560693620285882975471913545189522117672866861003904575909174769890684057564495184019705963607555427518763375472432216131070235796577209064861003009894615394882021220247535890708789312783718414424224334988974848162884228012265684775651099758365989567444515619764427493598258393280941942356912304265535918025036942025858493361644535438208",
"-0.839071529076452222947082170022504835457755803801719612447629165523199043803440231769716865070163209041973184176293170330332317060558438085478980463542480791358920580076809381102480339018809694514100495572097422057215638383077242523713704127605770444906854175870243452753002238589530499630034663296166308443155999957196346563161387705205277189957388653461251461388391745795979375660087266037741360406956289962327970672363315696841378765492754546688",
"-0.82557544253149396284458404188071504476091346830440347376462206521981928020803354950315062147200396866217255527509254080721982393941347365824137698491042935894213870423296625749297033966815252917361266452901192457318047750698424190124169875103436588397415032138037063155981648677895645409699825582226442363080800781881653440538927704569142007751338851079530521979429507520541625303794665680584709171813053216867014700596866196844144286737568957809383224972108999354839705480223052622003994027222120126949093911643497423100187973906980635670000034664323357488815820848035808846624518774608931622703631130673844138378087837990739103263093532314835289302930152150130664948083902949999427848344301686172490282395687167681679607401220592559832932068966455384902377056623736013617949634746332323529256184776892339963173795176200590119077305668901887229709592836744082027738666294887303249770621722032438202753270710379312736193201366287952361100525126056993039858894987153270630277483613793395809214871734783742285495171911648254647287555645360520115341268930844095156502348405343740866836850201634640011708462641462047870611041595707018966032206807675586825362640000739202116391403514629284000986232673698892843586989003952425039512325844566790376383098534975022847888104706525937115931692008959513984157709954859352131323440787667052399474107219968",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
for i, inp := range inps {
d, err := NewFromString(inp)
if err != nil {
t.FailNow()
}
s, err := NewFromString(sols[i])
if err != nil {
t.FailNow()
}
a := d.Cos()
if !a.Equal(s) {
t.Errorf("expected %s, got %s", s, a)
}
}
}
// For Tan
func TestTan(t *testing.T) {
inps := []string{
"-2.91919191919191919",
"-1.0",
"-0.25",
"0.0",
"0.33",
"1.0",
"5.0",
"10",
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"11000020.2407442310156021090304691671842603586882014729198302312846062338790031898128063403419218957424",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
sols := []string{
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"0.2261415650505790298980791606748881031998682652",
"-1.5574077246549025",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
"-0.255341921221036275",
"0.0",
"0.342524867530038963",
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
"1.5574077246549025",
"-3.3805150062465829",
"0.6483608274590872485524085572681343280321117494",
"0.68351325561491170753499935023939368502774607234006019034769919811202010905597996164029250820702097041244539696",
Added cos, sin, tan, and atan methods and tests (#96) * Added Atan method * added sin and cos methods * added tests for atan, sin, and cos * tan method and test * potentinal fix for './decimal_test.go:261:6: d declared but not used' error thrown by the tip version Travis CI tests + corrected comment in decimal.go
2018-07-09 16:22:25 +02:00
}
for i, inp := range inps {
d, err := NewFromString(inp)
if err != nil {
t.FailNow()
}
s, err := NewFromString(sols[i])
if err != nil {
t.FailNow()
}
a := d.Tan()
if !a.Equal(s) {
t.Errorf("expected %s, got %s", s, a)
}
}
}
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
Add NewNullDecimal init method (#234)
2021-10-12 11:07:45 +02:00
func TestNewNullDecimal(t *testing.T) {
d := NewFromInt(1)
nd := NewNullDecimal(d)
if !nd.Valid {
t.Errorf("expected NullDecimal to be valid")
}
if nd.Decimal != d {
t.Errorf("expected NullDecimal to hold the provided Decimal")
}
}
Make NewFromFloat respect the precision of the input (#100) * Make NewFromFloat respect the precision of the input Restores the previous behaviour where input converted from float is truncated at the precision of the float. The precision is depending on the actual value. Simply making it 15 digits would make it faster, but would in some cases lose some precision. So the code from the stdlib that does this calculation (very well) has been included. Lots of good articles here: https://www.exploringbinary.com/decimal-precision-of-binary-floating-point-numbers/ Performance is around the same as the previous string roundtrip since it basically does the same, but allocations are a bit less. `BenchmarkNewFromStringFloat` is the old method, `BenchmarkNewFromFloat` is the new. ``` BenchmarkNewFromFloatWithExponent-8 10000000 260 ns/op 174 B/op 4 allocs/op BenchmarkNewFromFloat-8 2000000 744 ns/op 90 B/op 2 allocs/op BenchmarkNewFromStringFloat-8 2000000 822 ns/op 258 B/op 6 allocs/op ``` * Update Sin/Tan/Cos tests.
2018-07-09 22:31:17 +02:00
func ExampleNewFromFloat32() {
fmt.Println(NewFromFloat32(123.123123123123).String())
fmt.Println(NewFromFloat32(.123123123123123).String())
fmt.Println(NewFromFloat32(-1e13).String())
// OUTPUT:
//123.12312
//0.123123124
//-10000000000000
}
func ExampleNewFromFloat() {
fmt.Println(NewFromFloat(123.123123123123).String())
fmt.Println(NewFromFloat(.123123123123123).String())
fmt.Println(NewFromFloat(-1e13).String())
// OUTPUT:
//123.123123123123
//0.123123123123123
//-10000000000000
}
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