LocalAI/pkg/sound/int16.go

package sound

import "math"

/*

MIT License

Copyright (c) 2024 Xbozon

*/

// calculateRMS16 calculates the root mean square of the audio buffer for int16 samples.
func CalculateRMS16(buffer []int16) float64 {
	var sumSquares float64
	for _, sample := range buffer {
		val := float64(sample) // Convert int16 to float64 for calculation
		sumSquares += val * val
	}
	meanSquares := sumSquares / float64(len(buffer))
	return math.Sqrt(meanSquares)
}

func ResampleInt16(input []int16, inputRate, outputRate int) []int16 {
	// Calculate the resampling ratio
	ratio := float64(inputRate) / float64(outputRate)

	// Calculate the length of the resampled output
	outputLength := int(float64(len(input)) / ratio)

	// Allocate a slice for the resampled output
	output := make([]int16, outputLength)

	// Perform linear interpolation for resampling
	for i := 0; i < outputLength-1; i++ {
		// Calculate the corresponding position in the input
		pos := float64(i) * ratio

		// Calculate the indices of the surrounding input samples
		indexBefore := int(pos)
		indexAfter := indexBefore + 1
		if indexAfter >= len(input) {
			indexAfter = len(input) - 1
		}

		// Calculate the fractional part of the position
		frac := pos - float64(indexBefore)

		// Linearly interpolate between the two surrounding input samples
		output[i] = int16((1-frac)*float64(input[indexBefore]) + frac*float64(input[indexAfter]))
	}

	// Handle the last sample explicitly to avoid index out of range
	output[outputLength-1] = input[len(input)-1]

	return output
}

func ConvertInt16ToInt(input []int16) []int {
	output := make([]int, len(input)) // Allocate a slice for the output
	for i, value := range input {
		output[i] = int(value) // Convert each int16 to int and assign it to the output slice
	}
	return output // Return the converted slice
}

func BytesToInt16sLE(bytes []byte) []int16 {
	// Ensure the byte slice length is even
	if len(bytes)%2 != 0 {
		panic("bytesToInt16sLE: input bytes slice has odd length, must be even")
	}

	int16s := make([]int16, len(bytes)/2)
	for i := 0; i < len(int16s); i++ {
		int16s[i] = int16(bytes[2*i]) | int16(bytes[2*i+1])<<8
	}
	return int16s
}
chore(vad): try to hook vad to received data from the API (WIP) Signed-off-by: Ettore Di Giacinto <mudler@localai.io> 2024-11-14 17:39:13 +00:00			`package sound`

wip(vad) Signed-off-by: Ettore Di Giacinto <mudler@localai.io> 2024-11-15 20:49:14 +00:00			`import "math"`

chore(vad): try to hook vad to received data from the API (WIP) Signed-off-by: Ettore Di Giacinto <mudler@localai.io> 2024-11-14 17:39:13 +00:00			`/*`

			`MIT License`

			`Copyright (c) 2024 Xbozon`

			`*/`

wip(vad) Signed-off-by: Ettore Di Giacinto <mudler@localai.io> 2024-11-15 20:49:14 +00:00			`// calculateRMS16 calculates the root mean square of the audio buffer for int16 samples.`
			`func CalculateRMS16(buffer []int16) float64 {`
			`var sumSquares float64`
			`for _, sample := range buffer {`
			`val := float64(sample) // Convert int16 to float64 for calculation`
			`sumSquares += val * val`
			`}`
			`meanSquares := sumSquares / float64(len(buffer))`
			`return math.Sqrt(meanSquares)`
			`}`

chore(vad): try to hook vad to received data from the API (WIP) Signed-off-by: Ettore Di Giacinto <mudler@localai.io> 2024-11-14 17:39:13 +00:00			`func ResampleInt16(input []int16, inputRate, outputRate int) []int16 {`
			`// Calculate the resampling ratio`
			`ratio := float64(inputRate) / float64(outputRate)`

			`// Calculate the length of the resampled output`
			`outputLength := int(float64(len(input)) / ratio)`

			`// Allocate a slice for the resampled output`
			`output := make([]int16, outputLength)`

			`// Perform linear interpolation for resampling`
			`for i := 0; i < outputLength-1; i++ {`
			`// Calculate the corresponding position in the input`
			`pos := float64(i) * ratio`

			`// Calculate the indices of the surrounding input samples`
			`indexBefore := int(pos)`
			`indexAfter := indexBefore + 1`
			`if indexAfter >= len(input) {`
			`indexAfter = len(input) - 1`
			`}`

			`// Calculate the fractional part of the position`
			`frac := pos - float64(indexBefore)`

			`// Linearly interpolate between the two surrounding input samples`
			`output[i] = int16((1-frac)float64(input[indexBefore]) + fracfloat64(input[indexAfter]))`
			`}`

			`// Handle the last sample explicitly to avoid index out of range`
			`output[outputLength-1] = input[len(input)-1]`

			`return output`
			`}`

			`func ConvertInt16ToInt(input []int16) []int {`
			`output := make([]int, len(input)) // Allocate a slice for the output`
			`for i, value := range input {`
			`output[i] = int(value) // Convert each int16 to int and assign it to the output slice`
			`}`
			`return output // Return the converted slice`
			`}`

			`func BytesToInt16sLE(bytes []byte) []int16 {`
			`// Ensure the byte slice length is even`
			`if len(bytes)%2 != 0 {`
			`panic("bytesToInt16sLE: input bytes slice has odd length, must be even")`
			`}`

			`int16s := make([]int16, len(bytes)/2)`
			`for i := 0; i < len(int16s); i++ {`
			`int16s[i] = int16(bytes[2i]) \| int16(bytes[2i+1])<<8`
			`}`
			`return int16s`
			`}`