Why Does Go's `time.Sleep()` Handle Fractional Durations Differently Based on Constant Type?-Golang-php.cn

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Why Does Go's `time.Sleep()` Handle Fractional Durations Differently Based on Constant Type?

Barbara Streisand

Dec 30, 2024 am 06:05 AM

Why Does Go's `time.Sleep()` Handle Fractional Durations Differently Based on Constant Type?

Fraction of Time Sleep Duration in Go

Question:

Why does the following Go code successfully sleep for a fractional duration, while the second one fails?

// Success
s := time.Hour / 73.0
fmt.Println("sleeping: ", s)
time.Sleep(s)

// Failure
d := 73.0
s := time.Hour / d
fmt.Println("sleeping: ", s)
time.Sleep(s)

// Error: invalid operation: time.Hour / d (mismatched types time.Duration and float64)

Answer:

The difference lies in the type of the divisor in each line:

Success: 73.0 is an untyped numeric constant, which adapts to time.Duration in the expression time.Hour / 73.0.
Failure: d is explicitly typed as float64, which cannot be divided by time.Duration.

To make the second line work, you must convert d to time.Duration:

s := time.Hour / time.Duration(d)

or use one of the following alternative ways:

d := time.Duration(73.0)
var d time.Duration = 73.0

For values that cannot be represented in time.Duration, such as 73.5, the time.Hour must be converted to float64:

d := 73.5
s := time.Duration(float64(time.Hour) / d)

Further Considerations:

Constants: Constants like time.Hour have a type that cannot be changed, so they cannot be used directly with non-compatible types.
Untyped Constants: Untyped constants take on the type of the context they are used in. In the first line, 73.0 adapts to time.Duration.
Type Conversion: Explicit type conversions like time.Duration(d) are necessary to ensure compatibility between different types.

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