stm32-metapac

Crates

git

Versions

stm32h523re

Flavors

Struct stm32_metapac::gpdma::regs::ChTr1

#[repr(transparent)]
pub struct ChTr1(pub u32);
Expand description

GPDMA channel 8 transfer register 1

Tuple Fields§

§0: u32

Implementations§

§

impl ChTr1

pub const fn sdw(&self) -> Dw

binary logarithm of the source data width of a burst in bytes. Note: Setting a 8-byte data width causes a user setting error to be reported and no transfer is issued. A source block size must be a multiple of the source data width (CH[x].BR1.BNDT[2:0] versus SDW_LOG2[1:0]). Otherwise, a user setting error is reported and no transfer is issued. A source single transfer must have an aligned address with its data width (start address CH[x].SAR[2:0] versus SDW_LOG2[1:0]). Otherwise, a user setting error is reported and none transfer is issued.

pub fn set_sdw(&mut self, val: Dw)

binary logarithm of the source data width of a burst in bytes. Note: Setting a 8-byte data width causes a user setting error to be reported and no transfer is issued. A source block size must be a multiple of the source data width (CH[x].BR1.BNDT[2:0] versus SDW_LOG2[1:0]). Otherwise, a user setting error is reported and no transfer is issued. A source single transfer must have an aligned address with its data width (start address CH[x].SAR[2:0] versus SDW_LOG2[1:0]). Otherwise, a user setting error is reported and none transfer is issued.

pub const fn sinc(&self) -> bool

source incrementing burst. The source address, pointed by CH[x].SAR, is kept constant after a burst beat/single transfer or is incremented by the offset value corresponding to a contiguous data after a burst beat/single transfer.

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

source incrementing burst. The source address, pointed by CH[x].SAR, is kept constant after a burst beat/single transfer or is incremented by the offset value corresponding to a contiguous data after a burst beat/single transfer.

pub const fn sbl_1(&self) -> u8

source burst length minus 1, between 0 and 63. The burst length unit is one data named beat within a burst. If SBL_1[5:0] =0 , the burst can be named as single. Each data/beat has a width defined by the destination data width SDW_LOG2[1:0]. Note: If a burst transfer crossed a 1-Kbyte address boundary on a AHB transfer, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the AHB protocol. If a burst transfer is of length greater than the FIFO size of the channel x, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the FIFO size. Transfer performance is lower, with GPDMA re-arbitration between effective and lower bursts/singles, but the data integrity is guaranteed.

pub fn set_sbl_1(&mut self, val: u8)

source burst length minus 1, between 0 and 63. The burst length unit is one data named beat within a burst. If SBL_1[5:0] =0 , the burst can be named as single. Each data/beat has a width defined by the destination data width SDW_LOG2[1:0]. Note: If a burst transfer crossed a 1-Kbyte address boundary on a AHB transfer, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the AHB protocol. If a burst transfer is of length greater than the FIFO size of the channel x, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the FIFO size. Transfer performance is lower, with GPDMA re-arbitration between effective and lower bursts/singles, but the data integrity is guaranteed.

pub const fn pam(&self) -> Pam

padding/alignment mode. If DDW[1:0] = SDW_LOG2[1:0]: if the data width of a burst destination transfer is equal to the data width of a burst source transfer, these bits are ignored. Else: - Case 1: If destination data width > source data width. 1x: successive source data are FIFO queued and packed at the destination data width, in a left (LSB) to right (MSB) order (named little endian), before a destination transfer. - Case 2: If destination data width < source data width. 1x: source data is FIFO queued and unpacked at the destination data width, to be transferred in a left (LSB) to right (MSB) order (named little endian) to the destination. Note:

pub fn set_pam(&mut self, val: Pam)

padding/alignment mode. If DDW[1:0] = SDW_LOG2[1:0]: if the data width of a burst destination transfer is equal to the data width of a burst source transfer, these bits are ignored. Else: - Case 1: If destination data width > source data width. 1x: successive source data are FIFO queued and packed at the destination data width, in a left (LSB) to right (MSB) order (named little endian), before a destination transfer. - Case 2: If destination data width < source data width. 1x: source data is FIFO queued and unpacked at the destination data width, to be transferred in a left (LSB) to right (MSB) order (named little endian) to the destination. Note:

pub const fn sbx(&self) -> bool

source byte exchange within the unaligned half-word of each source word. If set, the two consecutive bytes within the unaligned half-word of each source word are exchanged. If the source data width is shorter than a word, this bit is ignored.

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

source byte exchange within the unaligned half-word of each source word. If set, the two consecutive bytes within the unaligned half-word of each source word are exchanged. If the source data width is shorter than a word, this bit is ignored.

pub const fn sap(&self) -> Ap

source allocated port. This bit is used to allocate the master port for the source transfer. Note: This bit must be written when EN = 0. This bit is read-only when EN = 1.

pub fn set_sap(&mut self, val: Ap)

source allocated port. This bit is used to allocate the master port for the source transfer. Note: This bit must be written when EN = 0. This bit is read-only when EN = 1.

pub const fn ssec(&self) -> bool

security attribute of the GPDMA transfer from the source. If SECCFGR.SECx = 1 and the access is secure: This is a secure register bit. This bit can only be read by a secure software. This bit must be written by a secure software when SECCFGR.SECx =1 . A secure write is ignored when SECCFGR.SECx = 0. When SECCFGR.SECx is de-asserted, this SSEC bit is also de-asserted by hardware (on a secure reconfiguration of the channel as non-secure), and the GPDMA transfer from the source is non-secure.

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

security attribute of the GPDMA transfer from the source. If SECCFGR.SECx = 1 and the access is secure: This is a secure register bit. This bit can only be read by a secure software. This bit must be written by a secure software when SECCFGR.SECx =1 . A secure write is ignored when SECCFGR.SECx = 0. When SECCFGR.SECx is de-asserted, this SSEC bit is also de-asserted by hardware (on a secure reconfiguration of the channel as non-secure), and the GPDMA transfer from the source is non-secure.

pub const fn ddw(&self) -> Dw

binary logarithm of the destination data width of a burst, in bytes. Note: Setting a 8-byte data width causes a user setting error to be reported and none transfer is issued. A destination burst transfer must have an aligned address with its data width (start address CH[x].DAR[2:0] and address offset CH[x].TR3.DAO[2:0], versus DDW[1:0]). Otherwise a user setting error is reported and no transfer is issued.

pub fn set_ddw(&mut self, val: Dw)

binary logarithm of the destination data width of a burst, in bytes. Note: Setting a 8-byte data width causes a user setting error to be reported and none transfer is issued. A destination burst transfer must have an aligned address with its data width (start address CH[x].DAR[2:0] and address offset CH[x].TR3.DAO[2:0], versus DDW[1:0]). Otherwise a user setting error is reported and no transfer is issued.

pub const fn dinc(&self) -> bool

destination incrementing burst. The destination address, pointed by CH[x].DAR, is kept constant after a burst beat/single transfer, or is incremented by the offset value corresponding to a contiguous data after a burst beat/single transfer.

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

destination incrementing burst. The destination address, pointed by CH[x].DAR, is kept constant after a burst beat/single transfer, or is incremented by the offset value corresponding to a contiguous data after a burst beat/single transfer.

pub const fn dbl_1(&self) -> u8

destination burst length minus 1, between 0 and 63. The burst length unit is one data named beat within a burst. If DBL_1[5:0] =0 , the burst can be named as single. Each data/beat has a width defined by the destination data width DDW[1:0]. Note: If a burst transfer crossed a 1-Kbyte address boundary on a AHB transfer, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the AHB protocol. If a burst transfer is of length greater than the FIFO size of the channel x, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the FIFO size. Transfer performance is lower, with GPDMA re-arbitration between effective and lower bursts/singles, but the data integrity is guaranteed.

pub fn set_dbl_1(&mut self, val: u8)

destination burst length minus 1, between 0 and 63. The burst length unit is one data named beat within a burst. If DBL_1[5:0] =0 , the burst can be named as single. Each data/beat has a width defined by the destination data width DDW[1:0]. Note: If a burst transfer crossed a 1-Kbyte address boundary on a AHB transfer, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the AHB protocol. If a burst transfer is of length greater than the FIFO size of the channel x, the GPDMA modifies and shortens the programmed burst into singles or bursts of lower length, to be compliant with the FIFO size. Transfer performance is lower, with GPDMA re-arbitration between effective and lower bursts/singles, but the data integrity is guaranteed.

pub const fn dbx(&self) -> bool

destination byte exchange. IF set, the two consecutive (post PAM) bytes are exchanged in each destination half-word. If the destination data size is a byte, this bit is ignored.

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

destination byte exchange. IF set, the two consecutive (post PAM) bytes are exchanged in each destination half-word. If the destination data size is a byte, this bit is ignored.

pub const fn dhx(&self) -> bool

destination half-word exchange. If set, e two consecutive (post PAM) half-words are exchanged in each destination word. If the destination data size is shorter than a word, this bit is ignored.

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

destination half-word exchange. If set, e two consecutive (post PAM) half-words are exchanged in each destination word. If the destination data size is shorter than a word, this bit is ignored.

pub const fn dap(&self) -> Ap

destination allocated port. This bit is used to allocate the master port for the destination transfer. Note: This bit must be written when EN = 0. This bit is read-only when EN = 1.

pub fn set_dap(&mut self, val: Ap)

destination allocated port. This bit is used to allocate the master port for the destination transfer. Note: This bit must be written when EN = 0. This bit is read-only when EN = 1.

pub const fn dsec(&self) -> bool

security attribute of the GPDMA transfer to the destination. If SECCFGR.SECx = 1 and the access is secure: This is a secure register bit. This bit can only be read by a secure software. This bit must be written by a secure software when SECCFGR.SECx = 1. A secure write is ignored when SECCFGR.SECx = 0. When SECCFGR.SECx is de-asserted, this DSEC bit is also de-asserted by hardware (on a secure reconfiguration of the channel as non-secure), and the GPDMA transfer to the destination is non-secure.

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

security attribute of the GPDMA transfer to the destination. If SECCFGR.SECx = 1 and the access is secure: This is a secure register bit. This bit can only be read by a secure software. This bit must be written by a secure software when SECCFGR.SECx = 1. A secure write is ignored when SECCFGR.SECx = 0. When SECCFGR.SECx is de-asserted, this DSEC bit is also de-asserted by hardware (on a secure reconfiguration of the channel as non-secure), and the GPDMA transfer to the destination is non-secure.

Trait Implementations§

§

impl Clone for ChTr1

§

fn clone(&self) -> ChTr1

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
§

impl Default for ChTr1

§

fn default() -> ChTr1

Returns the “default value” for a type. Read more
§

impl PartialEq for ChTr1

§

fn eq(&self, other: &ChTr1) -> 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.
§

impl Copy for ChTr1

§

impl Eq for ChTr1

§

impl StructuralPartialEq for ChTr1

Auto Trait Implementations§

§

impl Freeze for ChTr1

§

impl RefUnwindSafe for ChTr1

§

impl Send for ChTr1

§

impl Sync for ChTr1

§

impl Unpin for ChTr1

§

impl UnwindSafe for ChTr1

Blanket Implementations§

source§

impl<T> Any for T
where T: 'static + ?Sized,

source§

fn type_id(&self) -> TypeId

Gets the TypeId of self. Read more
source§

impl<T> Borrow<T> for T
where T: ?Sized,

source§

fn borrow(&self) -> &T

Immutably borrows from an owned value. Read more
source§

impl<T> BorrowMut<T> for T
where T: ?Sized,

source§

fn borrow_mut(&mut self) -> &mut T

Mutably borrows from an owned value. Read more
source§

impl<T> CloneToUninit for T
where T: Clone,

source§

unsafe fn clone_to_uninit(&self, dst: *mut T)

🔬This is a nightly-only experimental API. (clone_to_uninit)
Performs copy-assignment from self to dst. Read more
source§

impl<T> From<T> for T

source§

fn from(t: T) -> T

Returns the argument unchanged.

source§

impl<T, U> Into<U> for T
where U: From<T>,

source§

fn into(self) -> U

Calls U::from(self).

That is, this conversion is whatever the implementation of From<T> for U chooses to do.

source§

impl<T, U> TryFrom<U> for T
where U: Into<T>,

source§

type Error = Infallible

The type returned in the event of a conversion error.
source§

fn try_from(value: U) -> Result<T, <T as TryFrom<U>>::Error>

Performs the conversion.
source§

impl<T, U> TryInto<U> for T
where U: TryFrom<T>,

source§

type Error = <U as TryFrom<T>>::Error

The type returned in the event of a conversion error.
source§

fn try_into(self) -> Result<U, <U as TryFrom<T>>::Error>

Performs the conversion.