///Register `BDTR` reader
pub type R = crate::R<BDTRrs>;
///Register `BDTR` writer
pub type W = crate::W<BDTRrs>;
///Field `DTG` reader - Dead-time generator setup This bit-field defines the duration of the dead-time inserted between the complementary outputs. DT correspond to this duration. DTG\[7:5\]=0xx = DT=DTG\[7:0\]x t dtg with t dtg =t DTS . DTG\[7:5\]=10x = DT=(64+DTG\[5:0\])xt dtg with T dtg =2xt DTS . DTG\[7:5\]=110 = DT=(32+DTG\[4:0\])xt dtg with T dtg =8xt DTS . DTG\[7:5\]=111 = DT=(32+DTG\[4:0\])xt dtg with T dtg =16xt DTS . Example if T DTS =125ns (8MHz), dead-time possible values are: 0 to 15875 ns by 125 ns steps, 16 us to 31750 ns by 250 ns steps, 32 us to 63us by 1 us steps, 64 us to 126 us by 2 us steps Note: This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been programmed (LOCK bits in TIMx_BDTR register).
pub type DTG_R = crate::FieldReader;
///Field `DTG` writer - Dead-time generator setup This bit-field defines the duration of the dead-time inserted between the complementary outputs. DT correspond to this duration. DTG\[7:5\]=0xx = DT=DTG\[7:0\]x t dtg with t dtg =t DTS . DTG\[7:5\]=10x = DT=(64+DTG\[5:0\])xt dtg with T dtg =2xt DTS . DTG\[7:5\]=110 = DT=(32+DTG\[4:0\])xt dtg with T dtg =8xt DTS . DTG\[7:5\]=111 = DT=(32+DTG\[4:0\])xt dtg with T dtg =16xt DTS . Example if T DTS =125ns (8MHz), dead-time possible values are: 0 to 15875 ns by 125 ns steps, 16 us to 31750 ns by 250 ns steps, 32 us to 63us by 1 us steps, 64 us to 126 us by 2 us steps Note: This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been programmed (LOCK bits in TIMx_BDTR register).
pub type DTG_W<'a, REG> = crate::FieldWriter<'a, REG, 8, u8, crate::Safe>;
/**Lock configuration These bits offer a write protection against software errors. Note: The LOCK bits can be written only once after the reset. Once the TIMx_BDTR register has been written, their content is frozen until the next reset.
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
#[repr(u8)]
pub enum LOCK {
///0: No bit is write protected
Off = 0,
///1: Any bits except MOE, OSSR, OSSI and LOCK in TIMx_BDTR register, OISx and OISxN bits in TIMx_CR2 register can no longer be written
Level1 = 1,
///2: LOCK Level 1 + CC Polarity bits (CCxP/CCxNP bits in TIMx_CCER register, as long as the related channel is configured in output through the CCxS bits) as well as OSSR and OSSI bits can no longer be written
Level2 = 2,
///3: LOCK Level 2 + CC Control bits (OCxM and OCxPE bits in TIMx_CCMRx registers, as long as the related channel is configured in output through the CCxS bits) can no longer be written
Level3 = 3,
}
impl From<LOCK> for u8 {
#[inline(always)]
fn from(variant: LOCK) -> Self {
variant as _
}
}
impl crate::FieldSpec for LOCK {
type Ux = u8;
}
impl crate::IsEnum for LOCK {}
///Field `LOCK` reader - Lock configuration These bits offer a write protection against software errors. Note: The LOCK bits can be written only once after the reset. Once the TIMx_BDTR register has been written, their content is frozen until the next reset.
pub type LOCK_R = crate::FieldReader<LOCK>;
impl LOCK_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> LOCK {
match self.bits {
0 => LOCK::Off,
1 => LOCK::Level1,
2 => LOCK::Level2,
3 => LOCK::Level3,
_ => unreachable!(),
}
}
///No bit is write protected
#[inline(always)]
pub fn is_off(&self) -> bool {
*self == LOCK::Off
}
///Any bits except MOE, OSSR, OSSI and LOCK in TIMx_BDTR register, OISx and OISxN bits in TIMx_CR2 register can no longer be written
#[inline(always)]
pub fn is_level1(&self) -> bool {
*self == LOCK::Level1
}
///LOCK Level 1 + CC Polarity bits (CCxP/CCxNP bits in TIMx_CCER register, as long as the related channel is configured in output through the CCxS bits) as well as OSSR and OSSI bits can no longer be written
#[inline(always)]
pub fn is_level2(&self) -> bool {
*self == LOCK::Level2
}
///LOCK Level 2 + CC Control bits (OCxM and OCxPE bits in TIMx_CCMRx registers, as long as the related channel is configured in output through the CCxS bits) can no longer be written
#[inline(always)]
pub fn is_level3(&self) -> bool {
*self == LOCK::Level3
}
}
///Field `LOCK` writer - Lock configuration These bits offer a write protection against software errors. Note: The LOCK bits can be written only once after the reset. Once the TIMx_BDTR register has been written, their content is frozen until the next reset.
pub type LOCK_W<'a, REG> = crate::FieldWriter<'a, REG, 2, LOCK, crate::Safe>;
impl<'a, REG> LOCK_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
REG::Ux: From<u8>,
{
///No bit is write protected
#[inline(always)]
pub fn off(self) -> &'a mut crate::W<REG> {
self.variant(LOCK::Off)
}
///Any bits except MOE, OSSR, OSSI and LOCK in TIMx_BDTR register, OISx and OISxN bits in TIMx_CR2 register can no longer be written
#[inline(always)]
pub fn level1(self) -> &'a mut crate::W<REG> {
self.variant(LOCK::Level1)
}
///LOCK Level 1 + CC Polarity bits (CCxP/CCxNP bits in TIMx_CCER register, as long as the related channel is configured in output through the CCxS bits) as well as OSSR and OSSI bits can no longer be written
#[inline(always)]
pub fn level2(self) -> &'a mut crate::W<REG> {
self.variant(LOCK::Level2)
}
///LOCK Level 2 + CC Control bits (OCxM and OCxPE bits in TIMx_CCMRx registers, as long as the related channel is configured in output through the CCxS bits) can no longer be written
#[inline(always)]
pub fn level3(self) -> &'a mut crate::W<REG> {
self.variant(LOCK::Level3)
}
}
/**Off-state selection for idle mode This bit is used when MOE=0 due to a break event or by a software write, on channels configured as outputs. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum OSSI {
///0: When inactive, OC/OCN outputs are disabled
HiZ = 0,
///1: When inactive, OC/OCN outputs are forced to idle level
IdleLevel = 1,
}
impl From<OSSI> for bool {
#[inline(always)]
fn from(variant: OSSI) -> Self {
variant as u8 != 0
}
}
///Field `OSSI` reader - Off-state selection for idle mode This bit is used when MOE=0 due to a break event or by a software write, on channels configured as outputs. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
pub type OSSI_R = crate::BitReader<OSSI>;
impl OSSI_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> OSSI {
match self.bits {
false => OSSI::HiZ,
true => OSSI::IdleLevel,
}
}
///When inactive, OC/OCN outputs are disabled
#[inline(always)]
pub fn is_hi_z(&self) -> bool {
*self == OSSI::HiZ
}
///When inactive, OC/OCN outputs are forced to idle level
#[inline(always)]
pub fn is_idle_level(&self) -> bool {
*self == OSSI::IdleLevel
}
}
///Field `OSSI` writer - Off-state selection for idle mode This bit is used when MOE=0 due to a break event or by a software write, on channels configured as outputs. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
pub type OSSI_W<'a, REG> = crate::BitWriter<'a, REG, OSSI>;
impl<'a, REG> OSSI_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///When inactive, OC/OCN outputs are disabled
#[inline(always)]
pub fn hi_z(self) -> &'a mut crate::W<REG> {
self.variant(OSSI::HiZ)
}
///When inactive, OC/OCN outputs are forced to idle level
#[inline(always)]
pub fn idle_level(self) -> &'a mut crate::W<REG> {
self.variant(OSSI::IdleLevel)
}
}
/**Off-state selection for Run mode This bit is used when MOE=1 on channels having a complementary output which are configured as outputs. OSSR is not implemented if no complementary output is implemented in the timer. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum OSSR {
///0: When inactive, OC/OCN outputs are disabled
HiZ = 0,
///1: When inactive, OC/OCN outputs are enabled with their inactive level
IdleLevel = 1,
}
impl From<OSSR> for bool {
#[inline(always)]
fn from(variant: OSSR) -> Self {
variant as u8 != 0
}
}
///Field `OSSR` reader - Off-state selection for Run mode This bit is used when MOE=1 on channels having a complementary output which are configured as outputs. OSSR is not implemented if no complementary output is implemented in the timer. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
pub type OSSR_R = crate::BitReader<OSSR>;
impl OSSR_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> OSSR {
match self.bits {
false => OSSR::HiZ,
true => OSSR::IdleLevel,
}
}
///When inactive, OC/OCN outputs are disabled
#[inline(always)]
pub fn is_hi_z(&self) -> bool {
*self == OSSR::HiZ
}
///When inactive, OC/OCN outputs are enabled with their inactive level
#[inline(always)]
pub fn is_idle_level(&self) -> bool {
*self == OSSR::IdleLevel
}
}
///Field `OSSR` writer - Off-state selection for Run mode This bit is used when MOE=1 on channels having a complementary output which are configured as outputs. OSSR is not implemented if no complementary output is implemented in the timer. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
pub type OSSR_W<'a, REG> = crate::BitWriter<'a, REG, OSSR>;
impl<'a, REG> OSSR_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///When inactive, OC/OCN outputs are disabled
#[inline(always)]
pub fn hi_z(self) -> &'a mut crate::W<REG> {
self.variant(OSSR::HiZ)
}
///When inactive, OC/OCN outputs are enabled with their inactive level
#[inline(always)]
pub fn idle_level(self) -> &'a mut crate::W<REG> {
self.variant(OSSR::IdleLevel)
}
}
/**Break enable This bit enables the complete break protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum BKE {
///0: Break function x disabled
Disabled = 0,
///1: Break function x enabled
Enabled = 1,
}
impl From<BKE> for bool {
#[inline(always)]
fn from(variant: BKE) -> Self {
variant as u8 != 0
}
}
///Field `BKE` reader - Break enable This bit enables the complete break protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKE_R = crate::BitReader<BKE>;
impl BKE_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BKE {
match self.bits {
false => BKE::Disabled,
true => BKE::Enabled,
}
}
///Break function x disabled
#[inline(always)]
pub fn is_disabled(&self) -> bool {
*self == BKE::Disabled
}
///Break function x enabled
#[inline(always)]
pub fn is_enabled(&self) -> bool {
*self == BKE::Enabled
}
}
///Field `BKE` writer - Break enable This bit enables the complete break protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKE_W<'a, REG> = crate::BitWriter<'a, REG, BKE>;
impl<'a, REG> BKE_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///Break function x disabled
#[inline(always)]
pub fn disabled(self) -> &'a mut crate::W<REG> {
self.variant(BKE::Disabled)
}
///Break function x enabled
#[inline(always)]
pub fn enabled(self) -> &'a mut crate::W<REG> {
self.variant(BKE::Enabled)
}
}
/**Break polarity Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum BKP {
///0: Break input BRKx is active low
ActiveLow = 0,
///1: Break input BRKx is active high
ActiveHigh = 1,
}
impl From<BKP> for bool {
#[inline(always)]
fn from(variant: BKP) -> Self {
variant as u8 != 0
}
}
///Field `BKP` reader - Break polarity Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKP_R = crate::BitReader<BKP>;
impl BKP_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BKP {
match self.bits {
false => BKP::ActiveLow,
true => BKP::ActiveHigh,
}
}
///Break input BRKx is active low
#[inline(always)]
pub fn is_active_low(&self) -> bool {
*self == BKP::ActiveLow
}
///Break input BRKx is active high
#[inline(always)]
pub fn is_active_high(&self) -> bool {
*self == BKP::ActiveHigh
}
}
///Field `BKP` writer - Break polarity Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKP_W<'a, REG> = crate::BitWriter<'a, REG, BKP>;
impl<'a, REG> BKP_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///Break input BRKx is active low
#[inline(always)]
pub fn active_low(self) -> &'a mut crate::W<REG> {
self.variant(BKP::ActiveLow)
}
///Break input BRKx is active high
#[inline(always)]
pub fn active_high(self) -> &'a mut crate::W<REG> {
self.variant(BKP::ActiveHigh)
}
}
/**Automatic output enable Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum AOE {
///0: MOE can be set only by software
Manual = 0,
///1: MOE can be set by software or automatically at the next update event (if none of the break inputs BRK and BRK2 is active)
Automatic = 1,
}
impl From<AOE> for bool {
#[inline(always)]
fn from(variant: AOE) -> Self {
variant as u8 != 0
}
}
///Field `AOE` reader - Automatic output enable Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
pub type AOE_R = crate::BitReader<AOE>;
impl AOE_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> AOE {
match self.bits {
false => AOE::Manual,
true => AOE::Automatic,
}
}
///MOE can be set only by software
#[inline(always)]
pub fn is_manual(&self) -> bool {
*self == AOE::Manual
}
///MOE can be set by software or automatically at the next update event (if none of the break inputs BRK and BRK2 is active)
#[inline(always)]
pub fn is_automatic(&self) -> bool {
*self == AOE::Automatic
}
}
///Field `AOE` writer - Automatic output enable Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
pub type AOE_W<'a, REG> = crate::BitWriter<'a, REG, AOE>;
impl<'a, REG> AOE_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///MOE can be set only by software
#[inline(always)]
pub fn manual(self) -> &'a mut crate::W<REG> {
self.variant(AOE::Manual)
}
///MOE can be set by software or automatically at the next update event (if none of the break inputs BRK and BRK2 is active)
#[inline(always)]
pub fn automatic(self) -> &'a mut crate::W<REG> {
self.variant(AOE::Automatic)
}
}
/**Main output enable This bit is cleared asynchronously by hardware as soon as one of the break inputs is active (tim_brk or tim_brk2). It is set by software or automatically depending on the AOE bit. It is acting only on the channels which are configured in output. In response to a break event or if MOE is written to 0: OC and OCN outputs are disabled or forced to idle state depending on the OSSI bit. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)).
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum MOE {
///0: OC/OCN are disabled or forced idle depending on OSSI
DisabledIdle = 0,
///1: OC/OCN are enabled if CCxE/CCxNE are set
Enabled = 1,
}
impl From<MOE> for bool {
#[inline(always)]
fn from(variant: MOE) -> Self {
variant as u8 != 0
}
}
///Field `MOE` reader - Main output enable This bit is cleared asynchronously by hardware as soon as one of the break inputs is active (tim_brk or tim_brk2). It is set by software or automatically depending on the AOE bit. It is acting only on the channels which are configured in output. In response to a break event or if MOE is written to 0: OC and OCN outputs are disabled or forced to idle state depending on the OSSI bit. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)).
pub type MOE_R = crate::BitReader<MOE>;
impl MOE_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> MOE {
match self.bits {
false => MOE::DisabledIdle,
true => MOE::Enabled,
}
}
///OC/OCN are disabled or forced idle depending on OSSI
#[inline(always)]
pub fn is_disabled_idle(&self) -> bool {
*self == MOE::DisabledIdle
}
///OC/OCN are enabled if CCxE/CCxNE are set
#[inline(always)]
pub fn is_enabled(&self) -> bool {
*self == MOE::Enabled
}
}
///Field `MOE` writer - Main output enable This bit is cleared asynchronously by hardware as soon as one of the break inputs is active (tim_brk or tim_brk2). It is set by software or automatically depending on the AOE bit. It is acting only on the channels which are configured in output. In response to a break event or if MOE is written to 0: OC and OCN outputs are disabled or forced to idle state depending on the OSSI bit. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)).
pub type MOE_W<'a, REG> = crate::BitWriter<'a, REG, MOE>;
impl<'a, REG> MOE_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///OC/OCN are disabled or forced idle depending on OSSI
#[inline(always)]
pub fn disabled_idle(self) -> &'a mut crate::W<REG> {
self.variant(MOE::DisabledIdle)
}
///OC/OCN are enabled if CCxE/CCxNE are set
#[inline(always)]
pub fn enabled(self) -> &'a mut crate::W<REG> {
self.variant(MOE::Enabled)
}
}
/**Break filter This bit-field defines the frequency used to sample tim_brk input and the length of the digital filter applied to tim_brk. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
#[repr(u8)]
pub enum BKF {
///0: No filter, sampling is done at fDTS
NoFilter = 0,
///1: fSAMPLING=fCK_INT, N=2
FckIntN2 = 1,
///2: fSAMPLING=fCK_INT, N=4
FckIntN4 = 2,
///3: fSAMPLING=fCK_INT, N=8
FckIntN8 = 3,
///4: fSAMPLING=fDTS/2, N=6
FdtsDiv2N6 = 4,
///5: fSAMPLING=fDTS/2, N=8
FdtsDiv2N8 = 5,
///6: fSAMPLING=fDTS/4, N=6
FdtsDiv4N6 = 6,
///7: fSAMPLING=fDTS/4, N=8
FdtsDiv4N8 = 7,
///8: fSAMPLING=fDTS/8, N=6
FdtsDiv8N6 = 8,
///9: fSAMPLING=fDTS/8, N=8
FdtsDiv8N8 = 9,
///10: fSAMPLING=fDTS/16, N=5
FdtsDiv16N5 = 10,
///11: fSAMPLING=fDTS/16, N=6
FdtsDiv16N6 = 11,
///12: fSAMPLING=fDTS/16, N=8
FdtsDiv16N8 = 12,
///13: fSAMPLING=fDTS/32, N=5
FdtsDiv32N5 = 13,
///14: fSAMPLING=fDTS/32, N=6
FdtsDiv32N6 = 14,
///15: fSAMPLING=fDTS/32, N=8
FdtsDiv32N8 = 15,
}
impl From<BKF> for u8 {
#[inline(always)]
fn from(variant: BKF) -> Self {
variant as _
}
}
impl crate::FieldSpec for BKF {
type Ux = u8;
}
impl crate::IsEnum for BKF {}
///Field `BKF` reader - Break filter This bit-field defines the frequency used to sample tim_brk input and the length of the digital filter applied to tim_brk. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
pub type BKF_R = crate::FieldReader<BKF>;
impl BKF_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BKF {
match self.bits {
0 => BKF::NoFilter,
1 => BKF::FckIntN2,
2 => BKF::FckIntN4,
3 => BKF::FckIntN8,
4 => BKF::FdtsDiv2N6,
5 => BKF::FdtsDiv2N8,
6 => BKF::FdtsDiv4N6,
7 => BKF::FdtsDiv4N8,
8 => BKF::FdtsDiv8N6,
9 => BKF::FdtsDiv8N8,
10 => BKF::FdtsDiv16N5,
11 => BKF::FdtsDiv16N6,
12 => BKF::FdtsDiv16N8,
13 => BKF::FdtsDiv32N5,
14 => BKF::FdtsDiv32N6,
15 => BKF::FdtsDiv32N8,
_ => unreachable!(),
}
}
///No filter, sampling is done at fDTS
#[inline(always)]
pub fn is_no_filter(&self) -> bool {
*self == BKF::NoFilter
}
///fSAMPLING=fCK_INT, N=2
#[inline(always)]
pub fn is_fck_int_n2(&self) -> bool {
*self == BKF::FckIntN2
}
///fSAMPLING=fCK_INT, N=4
#[inline(always)]
pub fn is_fck_int_n4(&self) -> bool {
*self == BKF::FckIntN4
}
///fSAMPLING=fCK_INT, N=8
#[inline(always)]
pub fn is_fck_int_n8(&self) -> bool {
*self == BKF::FckIntN8
}
///fSAMPLING=fDTS/2, N=6
#[inline(always)]
pub fn is_fdts_div2_n6(&self) -> bool {
*self == BKF::FdtsDiv2N6
}
///fSAMPLING=fDTS/2, N=8
#[inline(always)]
pub fn is_fdts_div2_n8(&self) -> bool {
*self == BKF::FdtsDiv2N8
}
///fSAMPLING=fDTS/4, N=6
#[inline(always)]
pub fn is_fdts_div4_n6(&self) -> bool {
*self == BKF::FdtsDiv4N6
}
///fSAMPLING=fDTS/4, N=8
#[inline(always)]
pub fn is_fdts_div4_n8(&self) -> bool {
*self == BKF::FdtsDiv4N8
}
///fSAMPLING=fDTS/8, N=6
#[inline(always)]
pub fn is_fdts_div8_n6(&self) -> bool {
*self == BKF::FdtsDiv8N6
}
///fSAMPLING=fDTS/8, N=8
#[inline(always)]
pub fn is_fdts_div8_n8(&self) -> bool {
*self == BKF::FdtsDiv8N8
}
///fSAMPLING=fDTS/16, N=5
#[inline(always)]
pub fn is_fdts_div16_n5(&self) -> bool {
*self == BKF::FdtsDiv16N5
}
///fSAMPLING=fDTS/16, N=6
#[inline(always)]
pub fn is_fdts_div16_n6(&self) -> bool {
*self == BKF::FdtsDiv16N6
}
///fSAMPLING=fDTS/16, N=8
#[inline(always)]
pub fn is_fdts_div16_n8(&self) -> bool {
*self == BKF::FdtsDiv16N8
}
///fSAMPLING=fDTS/32, N=5
#[inline(always)]
pub fn is_fdts_div32_n5(&self) -> bool {
*self == BKF::FdtsDiv32N5
}
///fSAMPLING=fDTS/32, N=6
#[inline(always)]
pub fn is_fdts_div32_n6(&self) -> bool {
*self == BKF::FdtsDiv32N6
}
///fSAMPLING=fDTS/32, N=8
#[inline(always)]
pub fn is_fdts_div32_n8(&self) -> bool {
*self == BKF::FdtsDiv32N8
}
}
///Field `BKF` writer - Break filter This bit-field defines the frequency used to sample tim_brk input and the length of the digital filter applied to tim_brk. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
pub type BKF_W<'a, REG> = crate::FieldWriter<'a, REG, 4, BKF, crate::Safe>;
impl<'a, REG> BKF_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
REG::Ux: From<u8>,
{
///No filter, sampling is done at fDTS
#[inline(always)]
pub fn no_filter(self) -> &'a mut crate::W<REG> {
self.variant(BKF::NoFilter)
}
///fSAMPLING=fCK_INT, N=2
#[inline(always)]
pub fn fck_int_n2(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FckIntN2)
}
///fSAMPLING=fCK_INT, N=4
#[inline(always)]
pub fn fck_int_n4(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FckIntN4)
}
///fSAMPLING=fCK_INT, N=8
#[inline(always)]
pub fn fck_int_n8(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FckIntN8)
}
///fSAMPLING=fDTS/2, N=6
#[inline(always)]
pub fn fdts_div2_n6(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv2N6)
}
///fSAMPLING=fDTS/2, N=8
#[inline(always)]
pub fn fdts_div2_n8(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv2N8)
}
///fSAMPLING=fDTS/4, N=6
#[inline(always)]
pub fn fdts_div4_n6(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv4N6)
}
///fSAMPLING=fDTS/4, N=8
#[inline(always)]
pub fn fdts_div4_n8(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv4N8)
}
///fSAMPLING=fDTS/8, N=6
#[inline(always)]
pub fn fdts_div8_n6(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv8N6)
}
///fSAMPLING=fDTS/8, N=8
#[inline(always)]
pub fn fdts_div8_n8(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv8N8)
}
///fSAMPLING=fDTS/16, N=5
#[inline(always)]
pub fn fdts_div16_n5(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv16N5)
}
///fSAMPLING=fDTS/16, N=6
#[inline(always)]
pub fn fdts_div16_n6(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv16N6)
}
///fSAMPLING=fDTS/16, N=8
#[inline(always)]
pub fn fdts_div16_n8(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv16N8)
}
///fSAMPLING=fDTS/32, N=5
#[inline(always)]
pub fn fdts_div32_n5(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv32N5)
}
///fSAMPLING=fDTS/32, N=6
#[inline(always)]
pub fn fdts_div32_n6(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv32N6)
}
///fSAMPLING=fDTS/32, N=8
#[inline(always)]
pub fn fdts_div32_n8(self) -> &'a mut crate::W<REG> {
self.variant(BKF::FdtsDiv32N8)
}
}
///Field `BK2E` reader - Break 2 enable This bit enables the complete break 2 protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: The BRKIN2 must only be used with OSSR = OSSI = 1. Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub use BKE_R as BK2E_R;
///Field `BK2E` writer - Break 2 enable This bit enables the complete break 2 protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: The BRKIN2 must only be used with OSSR = OSSI = 1. Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub use BKE_W as BK2E_W;
///Field `BK2F` reader - Break 2 filter This bit-field defines the frequency used to sample tim_brk2 input and the length of the digital filter applied to tim_brk2. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
pub use BKF_R as BK2F_R;
///Field `BK2F` writer - Break 2 filter This bit-field defines the frequency used to sample tim_brk2 input and the length of the digital filter applied to tim_brk2. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
pub use BKF_W as BK2F_W;
///Field `BK2P` reader - Break 2 polarity Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub use BKP_R as BK2P_R;
///Field `BK2P` writer - Break 2 polarity Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub use BKP_W as BK2P_W;
/**Break disarm This bit is cleared by hardware when no break source is active. The BKDSRM bit must be set by software to release the bidirectional output control (open-drain output in Hi-Z state) and then be polled it until it is reset by hardware, indicating that the fault condition has disappeared. Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum BKDSRM {
///0: Break input BRK is armed
Armed = 0,
///1: Break input BRK is disarmed
Disarmed = 1,
}
impl From<BKDSRM> for bool {
#[inline(always)]
fn from(variant: BKDSRM) -> Self {
variant as u8 != 0
}
}
///Field `BKDSRM` reader - Break disarm This bit is cleared by hardware when no break source is active. The BKDSRM bit must be set by software to release the bidirectional output control (open-drain output in Hi-Z state) and then be polled it until it is reset by hardware, indicating that the fault condition has disappeared. Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKDSRM_R = crate::BitReader<BKDSRM>;
impl BKDSRM_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BKDSRM {
match self.bits {
false => BKDSRM::Armed,
true => BKDSRM::Disarmed,
}
}
///Break input BRK is armed
#[inline(always)]
pub fn is_armed(&self) -> bool {
*self == BKDSRM::Armed
}
///Break input BRK is disarmed
#[inline(always)]
pub fn is_disarmed(&self) -> bool {
*self == BKDSRM::Disarmed
}
}
///Field `BKDSRM` writer - Break disarm This bit is cleared by hardware when no break source is active. The BKDSRM bit must be set by software to release the bidirectional output control (open-drain output in Hi-Z state) and then be polled it until it is reset by hardware, indicating that the fault condition has disappeared. Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKDSRM_W<'a, REG> = crate::BitWriter<'a, REG, BKDSRM>;
impl<'a, REG> BKDSRM_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///Break input BRK is armed
#[inline(always)]
pub fn armed(self) -> &'a mut crate::W<REG> {
self.variant(BKDSRM::Armed)
}
///Break input BRK is disarmed
#[inline(always)]
pub fn disarmed(self) -> &'a mut crate::W<REG> {
self.variant(BKDSRM::Disarmed)
}
}
/**Break2 disarm Refer to BKDSRM description
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum BK2DSRM {
///0: Break input BRK2 is armed
Armed = 0,
///1: Break input BRK2 is disarmed
Disarmed = 1,
}
impl From<BK2DSRM> for bool {
#[inline(always)]
fn from(variant: BK2DSRM) -> Self {
variant as u8 != 0
}
}
///Field `BK2DSRM` reader - Break2 disarm Refer to BKDSRM description
pub type BK2DSRM_R = crate::BitReader<BK2DSRM>;
impl BK2DSRM_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BK2DSRM {
match self.bits {
false => BK2DSRM::Armed,
true => BK2DSRM::Disarmed,
}
}
///Break input BRK2 is armed
#[inline(always)]
pub fn is_armed(&self) -> bool {
*self == BK2DSRM::Armed
}
///Break input BRK2 is disarmed
#[inline(always)]
pub fn is_disarmed(&self) -> bool {
*self == BK2DSRM::Disarmed
}
}
///Field `BK2DSRM` writer - Break2 disarm Refer to BKDSRM description
pub type BK2DSRM_W<'a, REG> = crate::BitWriter<'a, REG, BK2DSRM>;
impl<'a, REG> BK2DSRM_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///Break input BRK2 is armed
#[inline(always)]
pub fn armed(self) -> &'a mut crate::W<REG> {
self.variant(BK2DSRM::Armed)
}
///Break input BRK2 is disarmed
#[inline(always)]
pub fn disarmed(self) -> &'a mut crate::W<REG> {
self.variant(BK2DSRM::Disarmed)
}
}
/**Break bidirectional In the bidirectional mode (BKBID bit set to 1), the break input is configured both in input mode and in open drain output mode. Any active break event asserts a low logic level on the Break input to indicate an internal break event to external devices. Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum BKBID {
///0: Break input BRK in input mode
Input = 0,
///1: Break input BRK in bidirectional mode
Bidirectional = 1,
}
impl From<BKBID> for bool {
#[inline(always)]
fn from(variant: BKBID) -> Self {
variant as u8 != 0
}
}
///Field `BKBID` reader - Break bidirectional In the bidirectional mode (BKBID bit set to 1), the break input is configured both in input mode and in open drain output mode. Any active break event asserts a low logic level on the Break input to indicate an internal break event to external devices. Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKBID_R = crate::BitReader<BKBID>;
impl BKBID_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BKBID {
match self.bits {
false => BKBID::Input,
true => BKBID::Bidirectional,
}
}
///Break input BRK in input mode
#[inline(always)]
pub fn is_input(&self) -> bool {
*self == BKBID::Input
}
///Break input BRK in bidirectional mode
#[inline(always)]
pub fn is_bidirectional(&self) -> bool {
*self == BKBID::Bidirectional
}
}
///Field `BKBID` writer - Break bidirectional In the bidirectional mode (BKBID bit set to 1), the break input is configured both in input mode and in open drain output mode. Any active break event asserts a low logic level on the Break input to indicate an internal break event to external devices. Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
pub type BKBID_W<'a, REG> = crate::BitWriter<'a, REG, BKBID>;
impl<'a, REG> BKBID_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///Break input BRK in input mode
#[inline(always)]
pub fn input(self) -> &'a mut crate::W<REG> {
self.variant(BKBID::Input)
}
///Break input BRK in bidirectional mode
#[inline(always)]
pub fn bidirectional(self) -> &'a mut crate::W<REG> {
self.variant(BKBID::Bidirectional)
}
}
/**Break2 bidirectional Refer to BKBID description
Value on reset: 0*/
#[cfg_attr(feature = "defmt", derive(defmt::Format))]
#[derive(Clone, Copy, Debug, PartialEq, Eq)]
pub enum BK2BID {
///0: Break input BRK2 in input mode
Input = 0,
///1: Break input BRK2 in bidirectional mode
Bidirectional = 1,
}
impl From<BK2BID> for bool {
#[inline(always)]
fn from(variant: BK2BID) -> Self {
variant as u8 != 0
}
}
///Field `BK2BID` reader - Break2 bidirectional Refer to BKBID description
pub type BK2BID_R = crate::BitReader<BK2BID>;
impl BK2BID_R {
///Get enumerated values variant
#[inline(always)]
pub const fn variant(&self) -> BK2BID {
match self.bits {
false => BK2BID::Input,
true => BK2BID::Bidirectional,
}
}
///Break input BRK2 in input mode
#[inline(always)]
pub fn is_input(&self) -> bool {
*self == BK2BID::Input
}
///Break input BRK2 in bidirectional mode
#[inline(always)]
pub fn is_bidirectional(&self) -> bool {
*self == BK2BID::Bidirectional
}
}
///Field `BK2BID` writer - Break2 bidirectional Refer to BKBID description
pub type BK2BID_W<'a, REG> = crate::BitWriter<'a, REG, BK2BID>;
impl<'a, REG> BK2BID_W<'a, REG>
where
REG: crate::Writable + crate::RegisterSpec,
{
///Break input BRK2 in input mode
#[inline(always)]
pub fn input(self) -> &'a mut crate::W<REG> {
self.variant(BK2BID::Input)
}
///Break input BRK2 in bidirectional mode
#[inline(always)]
pub fn bidirectional(self) -> &'a mut crate::W<REG> {
self.variant(BK2BID::Bidirectional)
}
}
impl R {
///Bits 0:7 - Dead-time generator setup This bit-field defines the duration of the dead-time inserted between the complementary outputs. DT correspond to this duration. DTG\[7:5\]=0xx = DT=DTG\[7:0\]x t dtg with t dtg =t DTS . DTG\[7:5\]=10x = DT=(64+DTG\[5:0\])xt dtg with T dtg =2xt DTS . DTG\[7:5\]=110 = DT=(32+DTG\[4:0\])xt dtg with T dtg =8xt DTS . DTG\[7:5\]=111 = DT=(32+DTG\[4:0\])xt dtg with T dtg =16xt DTS . Example if T DTS =125ns (8MHz), dead-time possible values are: 0 to 15875 ns by 125 ns steps, 16 us to 31750 ns by 250 ns steps, 32 us to 63us by 1 us steps, 64 us to 126 us by 2 us steps Note: This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn dtg(&self) -> DTG_R {
DTG_R::new((self.bits & 0xff) as u8)
}
///Bits 8:9 - Lock configuration These bits offer a write protection against software errors. Note: The LOCK bits can be written only once after the reset. Once the TIMx_BDTR register has been written, their content is frozen until the next reset.
#[inline(always)]
pub fn lock(&self) -> LOCK_R {
LOCK_R::new(((self.bits >> 8) & 3) as u8)
}
///Bit 10 - Off-state selection for idle mode This bit is used when MOE=0 due to a break event or by a software write, on channels configured as outputs. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn ossi(&self) -> OSSI_R {
OSSI_R::new(((self.bits >> 10) & 1) != 0)
}
///Bit 11 - Off-state selection for Run mode This bit is used when MOE=1 on channels having a complementary output which are configured as outputs. OSSR is not implemented if no complementary output is implemented in the timer. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn ossr(&self) -> OSSR_R {
OSSR_R::new(((self.bits >> 11) & 1) != 0)
}
///Bit 12 - Break enable This bit enables the complete break protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bke(&self) -> BKE_R {
BKE_R::new(((self.bits >> 12) & 1) != 0)
}
///Bit 13 - Break polarity Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bkp(&self) -> BKP_R {
BKP_R::new(((self.bits >> 13) & 1) != 0)
}
///Bit 14 - Automatic output enable Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn aoe(&self) -> AOE_R {
AOE_R::new(((self.bits >> 14) & 1) != 0)
}
///Bit 15 - Main output enable This bit is cleared asynchronously by hardware as soon as one of the break inputs is active (tim_brk or tim_brk2). It is set by software or automatically depending on the AOE bit. It is acting only on the channels which are configured in output. In response to a break event or if MOE is written to 0: OC and OCN outputs are disabled or forced to idle state depending on the OSSI bit. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)).
#[inline(always)]
pub fn moe(&self) -> MOE_R {
MOE_R::new(((self.bits >> 15) & 1) != 0)
}
///Bits 16:19 - Break filter This bit-field defines the frequency used to sample tim_brk input and the length of the digital filter applied to tim_brk. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn bkf(&self) -> BKF_R {
BKF_R::new(((self.bits >> 16) & 0x0f) as u8)
}
///Bits 20:23 - Break 2 filter This bit-field defines the frequency used to sample tim_brk2 input and the length of the digital filter applied to tim_brk2. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn bk2f(&self) -> BK2F_R {
BK2F_R::new(((self.bits >> 20) & 0x0f) as u8)
}
///Bit 24 - Break 2 enable This bit enables the complete break 2 protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: The BRKIN2 must only be used with OSSR = OSSI = 1. Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bk2e(&self) -> BK2E_R {
BK2E_R::new(((self.bits >> 24) & 1) != 0)
}
///Bit 25 - Break 2 polarity Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bk2p(&self) -> BK2P_R {
BK2P_R::new(((self.bits >> 25) & 1) != 0)
}
///Bit 26 - Break disarm This bit is cleared by hardware when no break source is active. The BKDSRM bit must be set by software to release the bidirectional output control (open-drain output in Hi-Z state) and then be polled it until it is reset by hardware, indicating that the fault condition has disappeared. Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bkdsrm(&self) -> BKDSRM_R {
BKDSRM_R::new(((self.bits >> 26) & 1) != 0)
}
///Bit 27 - Break2 disarm Refer to BKDSRM description
#[inline(always)]
pub fn bk2dsrm(&self) -> BK2DSRM_R {
BK2DSRM_R::new(((self.bits >> 27) & 1) != 0)
}
///Bit 28 - Break bidirectional In the bidirectional mode (BKBID bit set to 1), the break input is configured both in input mode and in open drain output mode. Any active break event asserts a low logic level on the Break input to indicate an internal break event to external devices. Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bkbid(&self) -> BKBID_R {
BKBID_R::new(((self.bits >> 28) & 1) != 0)
}
///Bit 29 - Break2 bidirectional Refer to BKBID description
#[inline(always)]
pub fn bk2bid(&self) -> BK2BID_R {
BK2BID_R::new(((self.bits >> 29) & 1) != 0)
}
}
impl core::fmt::Debug for R {
fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result {
f.debug_struct("BDTR")
.field("dtg", &self.dtg())
.field("lock", &self.lock())
.field("ossi", &self.ossi())
.field("ossr", &self.ossr())
.field("bke", &self.bke())
.field("bkp", &self.bkp())
.field("aoe", &self.aoe())
.field("moe", &self.moe())
.field("bkf", &self.bkf())
.field("bk2f", &self.bk2f())
.field("bk2e", &self.bk2e())
.field("bk2p", &self.bk2p())
.field("bkdsrm", &self.bkdsrm())
.field("bk2dsrm", &self.bk2dsrm())
.field("bkbid", &self.bkbid())
.field("bk2bid", &self.bk2bid())
.finish()
}
}
impl W {
///Bits 0:7 - Dead-time generator setup This bit-field defines the duration of the dead-time inserted between the complementary outputs. DT correspond to this duration. DTG\[7:5\]=0xx = DT=DTG\[7:0\]x t dtg with t dtg =t DTS . DTG\[7:5\]=10x = DT=(64+DTG\[5:0\])xt dtg with T dtg =2xt DTS . DTG\[7:5\]=110 = DT=(32+DTG\[4:0\])xt dtg with T dtg =8xt DTS . DTG\[7:5\]=111 = DT=(32+DTG\[4:0\])xt dtg with T dtg =16xt DTS . Example if T DTS =125ns (8MHz), dead-time possible values are: 0 to 15875 ns by 125 ns steps, 16 us to 31750 ns by 250 ns steps, 32 us to 63us by 1 us steps, 64 us to 126 us by 2 us steps Note: This bit-field can not be modified as long as LOCK level 1, 2 or 3 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn dtg(&mut self) -> DTG_W<BDTRrs> {
DTG_W::new(self, 0)
}
///Bits 8:9 - Lock configuration These bits offer a write protection against software errors. Note: The LOCK bits can be written only once after the reset. Once the TIMx_BDTR register has been written, their content is frozen until the next reset.
#[inline(always)]
pub fn lock(&mut self) -> LOCK_W<BDTRrs> {
LOCK_W::new(self, 8)
}
///Bit 10 - Off-state selection for idle mode This bit is used when MOE=0 due to a break event or by a software write, on channels configured as outputs. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn ossi(&mut self) -> OSSI_W<BDTRrs> {
OSSI_W::new(self, 10)
}
///Bit 11 - Off-state selection for Run mode This bit is used when MOE=1 on channels having a complementary output which are configured as outputs. OSSR is not implemented if no complementary output is implemented in the timer. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)). Note: This bit can not be modified as soon as the LOCK level 2 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn ossr(&mut self) -> OSSR_W<BDTRrs> {
OSSR_W::new(self, 11)
}
///Bit 12 - Break enable This bit enables the complete break protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bke(&mut self) -> BKE_W<BDTRrs> {
BKE_W::new(self, 12)
}
///Bit 13 - Break polarity Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bkp(&mut self) -> BKP_W<BDTRrs> {
BKP_W::new(self, 13)
}
///Bit 14 - Automatic output enable Note: This bit can not be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn aoe(&mut self) -> AOE_W<BDTRrs> {
AOE_W::new(self, 14)
}
///Bit 15 - Main output enable This bit is cleared asynchronously by hardware as soon as one of the break inputs is active (tim_brk or tim_brk2). It is set by software or automatically depending on the AOE bit. It is acting only on the channels which are configured in output. In response to a break event or if MOE is written to 0: OC and OCN outputs are disabled or forced to idle state depending on the OSSI bit. See OC/OCN enable description for more details (Section 65.6.11: TIM1 capture/compare enable register (TIM1_CCER)).
#[inline(always)]
pub fn moe(&mut self) -> MOE_W<BDTRrs> {
MOE_W::new(self, 15)
}
///Bits 16:19 - Break filter This bit-field defines the frequency used to sample tim_brk input and the length of the digital filter applied to tim_brk. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn bkf(&mut self) -> BKF_W<BDTRrs> {
BKF_W::new(self, 16)
}
///Bits 20:23 - Break 2 filter This bit-field defines the frequency used to sample tim_brk2 input and the length of the digital filter applied to tim_brk2. The digital filter is made of an event counter in which N consecutive events are needed to validate a transition on the output: Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register).
#[inline(always)]
pub fn bk2f(&mut self) -> BK2F_W<BDTRrs> {
BK2F_W::new(self, 20)
}
///Bit 24 - Break 2 enable This bit enables the complete break 2 protection (including all sources connected to bk_acth and BKIN sources, as per Figure 635: Break and Break2 circuitry overview). Note: The BRKIN2 must only be used with OSSR = OSSI = 1. Note: This bit cannot be modified when LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bk2e(&mut self) -> BK2E_W<BDTRrs> {
BK2E_W::new(self, 24)
}
///Bit 25 - Break 2 polarity Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bk2p(&mut self) -> BK2P_W<BDTRrs> {
BK2P_W::new(self, 25)
}
///Bit 26 - Break disarm This bit is cleared by hardware when no break source is active. The BKDSRM bit must be set by software to release the bidirectional output control (open-drain output in Hi-Z state) and then be polled it until it is reset by hardware, indicating that the fault condition has disappeared. Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bkdsrm(&mut self) -> BKDSRM_W<BDTRrs> {
BKDSRM_W::new(self, 26)
}
///Bit 27 - Break2 disarm Refer to BKDSRM description
#[inline(always)]
pub fn bk2dsrm(&mut self) -> BK2DSRM_W<BDTRrs> {
BK2DSRM_W::new(self, 27)
}
///Bit 28 - Break bidirectional In the bidirectional mode (BKBID bit set to 1), the break input is configured both in input mode and in open drain output mode. Any active break event asserts a low logic level on the Break input to indicate an internal break event to external devices. Note: This bit cannot be modified as long as LOCK level 1 has been programmed (LOCK bits in TIMx_BDTR register). Note: Any write operation to this bit takes a delay of 1 APB clock cycle to become effective.
#[inline(always)]
pub fn bkbid(&mut self) -> BKBID_W<BDTRrs> {
BKBID_W::new(self, 28)
}
///Bit 29 - Break2 bidirectional Refer to BKBID description
#[inline(always)]
pub fn bk2bid(&mut self) -> BK2BID_W<BDTRrs> {
BK2BID_W::new(self, 29)
}
}
/**TIM1 break and dead-time register
You can [`read`](crate::Reg::read) this register and get [`bdtr::R`](R). You can [`reset`](crate::Reg::reset), [`write`](crate::Reg::write), [`write_with_zero`](crate::Reg::write_with_zero) this register using [`bdtr::W`](W). You can also [`modify`](crate::Reg::modify) this register. See [API](https://docs.rs/svd2rust/#read--modify--write-api).
See register [structure](https://stm32-rs.github.io/stm32-rs/STM32H503.html#TIM1:BDTR)*/
pub struct BDTRrs;
impl crate::RegisterSpec for BDTRrs {
type Ux = u32;
}
///`read()` method returns [`bdtr::R`](R) reader structure
impl crate::Readable for BDTRrs {}
///`write(|w| ..)` method takes [`bdtr::W`](W) writer structure
impl crate::Writable for BDTRrs {
type Safety = crate::Unsafe;
}
///`reset()` method sets BDTR to value 0
impl crate::Resettable for BDTRrs {}