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secg

package

v1.0.2067 Latest Latest Go to latest Published: May 12, 2024 License: Apache-2.0 Imports: 2 Imported by: 0

Details

Valid go.mod file

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Redistributable license

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Tagged version

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Stable version

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Learn more about best practices

Repository

github.com/deatil/go-cryptobin

Links

Open Source Insights

Documentation ¶

Index ¶

func Sect113r1() base_elliptic.Curve
func Sect113r2() base_elliptic.Curve
func Sect131r1() base_elliptic.Curve
func Sect131r2() base_elliptic.Curve
func Sect163k1() base_elliptic.Curve
func Sect163r1() base_elliptic.Curve
func Sect163r2() base_elliptic.Curve
func Sect193r1() base_elliptic.Curve
func Sect193r2() base_elliptic.Curve
func Sect233k1() base_elliptic.Curve
func Sect233r1() base_elliptic.Curve
func Sect239k1() base_elliptic.Curve
func Sect283k1() base_elliptic.Curve
func Sect283r1() base_elliptic.Curve
func Sect409k1() base_elliptic.Curve
func Sect409r1() base_elliptic.Curve
func Sect571k1() base_elliptic.Curve
func Sect571r1() base_elliptic.Curve

Constants ¶

This section is empty.

Variables ¶

This section is empty.

Functions ¶

func Sect113r1 ¶

func Sect113r1() base_elliptic.Curve

Sect113r1 returns a Curve which implements SECG sect113r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect113r2 ¶

func Sect113r2() base_elliptic.Curve

Sect113r2 returns a Curve which implements SECG sect113r2

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect131r1 ¶

func Sect131r1() base_elliptic.Curve

Sect131r1 returns a Curve which implements SECG sect131r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect131r2 ¶

func Sect131r2() base_elliptic.Curve

Sect131r2 returns a Curve which implements SECG sect131r2

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect163k1 ¶

func Sect163k1() base_elliptic.Curve

Sect163k1 returns a Curve which implements SECG sect163k1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect163r1 ¶

func Sect163r1() base_elliptic.Curve

Sect163r1 returns a Curve which implements SECG sect163r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect163r2 ¶

func Sect163r2() base_elliptic.Curve

Sect163r2 returns a Curve which implements SECG sect163r2

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect193r1 ¶

func Sect193r1() base_elliptic.Curve

Sect193r1 returns a Curve which implements SECG sect193r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect193r2 ¶

func Sect193r2() base_elliptic.Curve

Sect193r2 returns a Curve which implements SECG sect193r2

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect233k1 ¶

func Sect233k1() base_elliptic.Curve

Sect233k1 returns a Curve which implements SECG sect233k1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect233r1 ¶

func Sect233r1() base_elliptic.Curve

Sect233r1 returns a Curve which implements SECG sect233r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect239k1 ¶

func Sect239k1() base_elliptic.Curve

Sect239k1 returns a Curve which implements SECG sect239k1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect283k1 ¶

func Sect283k1() base_elliptic.Curve

Sect283k1 returns a Curve which implements SECG sect283k1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect283r1 ¶

func Sect283r1() base_elliptic.Curve

Sect283r1 returns a Curve which implements SECG sect283r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect409k1 ¶

func Sect409k1() base_elliptic.Curve

Sect409k1 returns a Curve which implements SECG sect409k1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect409r1 ¶

func Sect409r1() base_elliptic.Curve

Sect409r1 returns a Curve which implements SECG sect409r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect571k1 ¶

func Sect571k1() base_elliptic.Curve

Sect571k1 returns a Curve which implements SECG sect571k1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

func Sect571r1 ¶

func Sect571r1() base_elliptic.Curve

Sect571r1 returns a Curve which implements SECG sect571r1

Multiple invocations of this function will return the same value, so it can be used for equality checks and switch statements.

The cryptographic operations are implemented using constant-time algorithms.

Types ¶

This section is empty.

Source Files ¶

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