stm32-metapac

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Struct stm32_metapac::rcc::regs::Ahb2rstr

#[repr(transparent)]
pub struct Ahb2rstr(pub u32);
Expand description

RCC AHB2 peripheral reset register

Tuple Fields§

§0: u32

Implementations§

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impl Ahb2rstr

pub const fn gpioarst(&self) -> bool

IO port A reset Set and cleared by software. Access can be secured by GPIOA SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_gpioarst(&mut self, val: bool)

IO port A reset Set and cleared by software. Access can be secured by GPIOA SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn gpiobrst(&self) -> bool

IO port B reset Set and cleared by software. Access can be secured by GPIOB SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_gpiobrst(&mut self, val: bool)

IO port B reset Set and cleared by software. Access can be secured by GPIOB SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn gpiocrst(&self) -> bool

IO port C reset Set and cleared by software. Access can be secured by GPIOC SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_gpiocrst(&mut self, val: bool)

IO port C reset Set and cleared by software. Access can be secured by GPIOC SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn gpiohrst(&self) -> bool

IO port H reset Set and cleared by software. Access can be secured by GPIOH SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_gpiohrst(&mut self, val: bool)

IO port H reset Set and cleared by software. Access can be secured by GPIOH SECx. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn aesrst(&self) -> bool

AES hardware accelerator reset Set and cleared by software. Access can be secured by GTZC_TZSC AESSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_aesrst(&mut self, val: bool)

AES hardware accelerator reset Set and cleared by software. Access can be secured by GTZC_TZSC AESSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn hashrst(&self) -> bool

Hash reset Set and cleared by software. Access can be secured by GTZC_TZSC HASHSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_hashrst(&mut self, val: bool)

Hash reset Set and cleared by software. Access can be secured by GTZC_TZSC HASHSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn rngrst(&self) -> bool

Random number generator reset Set and cleared by software. Access can be secured by GTZC_TZSC RNGSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_rngrst(&mut self, val: bool)

Random number generator reset Set and cleared by software. Access can be secured by GTZC_TZSC RNGSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn saesrst(&self) -> bool

SAES hardware accelerator reset Set and cleared by software. Access can be secured by GTZC_TZSC SAESSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_saesrst(&mut self, val: bool)

SAES hardware accelerator reset Set and cleared by software. Access can be secured by GTZC_TZSC SAESSEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn hsemrst(&self) -> bool

HSEM hardware accelerator reset Set and cleared by software. Can only be accessed secure when one or more features in the HSEM is secure. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_hsemrst(&mut self, val: bool)

HSEM hardware accelerator reset Set and cleared by software. Can only be accessed secure when one or more features in the HSEM is secure. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub const fn pkarst(&self) -> bool

PKA reset Set and cleared by software. Access can be secured by GTZC_TZSC PKASEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

pub fn set_pkarst(&mut self, val: bool)

PKA reset Set and cleared by software. Access can be secured by GTZC_TZSC PKASEC. When secure, a non-secure read/write access is RAZ/WI. It does not generate an illegal access interrupt. This bit can be protected against unprivileged access when secure with RCC SPRIV or when non-secure with RCC NSPRIV.

Trait Implementations§

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impl Clone for Ahb2rstr

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fn clone(&self) -> Ahb2rstr

Returns a copy of the value. Read more
1.0.0 · source§

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source. Read more
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impl Default for Ahb2rstr

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fn default() -> Ahb2rstr

Returns the “default value” for a type. Read more
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impl PartialEq for Ahb2rstr

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fn eq(&self, other: &Ahb2rstr) -> bool

Tests for self and other values to be equal, and is used by ==.
1.0.0 · source§

fn ne(&self, other: &Rhs) -> bool

Tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.
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impl Copy for Ahb2rstr

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impl Eq for Ahb2rstr

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impl StructuralPartialEq for Ahb2rstr

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