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#[doc = r" Value read from the register"] pub struct R { bits: u32, } #[doc = r" Value to write to the register"] pub struct W { bits: u32, } impl super::FUNCTION0 { #[doc = r" Modifies the contents of the register"] #[inline] pub fn modify<F>(&self, f: F) where for<'w> F: FnOnce(&R, &'w mut W) -> &'w mut W, { let bits = self.register.get(); let r = R { bits: bits }; let mut w = W { bits: bits }; f(&r, &mut w); self.register.set(w.bits); } #[doc = r" Reads the contents of the register"] #[inline] pub fn read(&self) -> R { R { bits: self.register.get(), } } #[doc = r" Writes to the register"] #[inline] pub fn write<F>(&self, f: F) where F: FnOnce(&mut W) -> &mut W, { let mut w = W::reset_value(); f(&mut w); self.register.set(w.bits); } #[doc = r" Writes the reset value to the register"] #[inline] pub fn reset(&self) { self.write(|w| w) } } #[doc = r" Value of the field"] pub struct RESERVED25R { bits: u8, } impl RESERVED25R { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bits(&self) -> u8 { self.bits } } #[doc = r" Value of the field"] pub struct MATCHEDR { bits: bool, } impl MATCHEDR { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bit(&self) -> bool { self.bits } #[doc = r" Returns `true` if the bit is clear (0)"] #[inline] pub fn bit_is_clear(&self) -> bool { !self.bit() } #[doc = r" Returns `true` if the bit is set (1)"] #[inline] pub fn bit_is_set(&self) -> bool { self.bit() } } #[doc = r" Value of the field"] pub struct RESERVED8R { bits: u16, } impl RESERVED8R { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bits(&self) -> u16 { self.bits } } #[doc = r" Value of the field"] pub struct CYCMATCHR { bits: bool, } impl CYCMATCHR { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bit(&self) -> bool { self.bits } #[doc = r" Returns `true` if the bit is clear (0)"] #[inline] pub fn bit_is_clear(&self) -> bool { !self.bit() } #[doc = r" Returns `true` if the bit is set (1)"] #[inline] pub fn bit_is_set(&self) -> bool { self.bit() } } #[doc = r" Value of the field"] pub struct RESERVED6R { bits: bool, } impl RESERVED6R { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bit(&self) -> bool { self.bits } #[doc = r" Returns `true` if the bit is clear (0)"] #[inline] pub fn bit_is_clear(&self) -> bool { !self.bit() } #[doc = r" Returns `true` if the bit is set (1)"] #[inline] pub fn bit_is_set(&self) -> bool { self.bit() } } #[doc = r" Value of the field"] pub struct EMITRANGER { bits: bool, } impl EMITRANGER { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bit(&self) -> bool { self.bits } #[doc = r" Returns `true` if the bit is clear (0)"] #[inline] pub fn bit_is_clear(&self) -> bool { !self.bit() } #[doc = r" Returns `true` if the bit is set (1)"] #[inline] pub fn bit_is_set(&self) -> bool { self.bit() } } #[doc = r" Value of the field"] pub struct RESERVED4R { bits: bool, } impl RESERVED4R { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bit(&self) -> bool { self.bits } #[doc = r" Returns `true` if the bit is clear (0)"] #[inline] pub fn bit_is_clear(&self) -> bool { !self.bit() } #[doc = r" Returns `true` if the bit is set (1)"] #[inline] pub fn bit_is_set(&self) -> bool { self.bit() } } #[doc = r" Value of the field"] pub struct FUNCTIONR { bits: u8, } impl FUNCTIONR { #[doc = r" Value of the field as raw bits"] #[inline] pub fn bits(&self) -> u8 { self.bits } } #[doc = r" Proxy"] pub struct _RESERVED25W<'a> { w: &'a mut W, } impl<'a> _RESERVED25W<'a> { #[doc = r" Writes raw bits to the field"] #[inline] pub unsafe fn bits(self, value: u8) -> &'a mut W { const MASK: u8 = 127; const OFFSET: u8 = 25; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _MATCHEDW<'a> { w: &'a mut W, } impl<'a> _MATCHEDW<'a> { #[doc = r" Sets the field bit"] pub fn set_bit(self) -> &'a mut W { self.bit(true) } #[doc = r" Clears the field bit"] pub fn clear_bit(self) -> &'a mut W { self.bit(false) } #[doc = r" Writes raw bits to the field"] #[inline] pub fn bit(self, value: bool) -> &'a mut W { const MASK: bool = true; const OFFSET: u8 = 24; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _RESERVED8W<'a> { w: &'a mut W, } impl<'a> _RESERVED8W<'a> { #[doc = r" Writes raw bits to the field"] #[inline] pub unsafe fn bits(self, value: u16) -> &'a mut W { const MASK: u16 = 65535; const OFFSET: u8 = 8; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _CYCMATCHW<'a> { w: &'a mut W, } impl<'a> _CYCMATCHW<'a> { #[doc = r" Sets the field bit"] pub fn set_bit(self) -> &'a mut W { self.bit(true) } #[doc = r" Clears the field bit"] pub fn clear_bit(self) -> &'a mut W { self.bit(false) } #[doc = r" Writes raw bits to the field"] #[inline] pub fn bit(self, value: bool) -> &'a mut W { const MASK: bool = true; const OFFSET: u8 = 7; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _RESERVED6W<'a> { w: &'a mut W, } impl<'a> _RESERVED6W<'a> { #[doc = r" Sets the field bit"] pub fn set_bit(self) -> &'a mut W { self.bit(true) } #[doc = r" Clears the field bit"] pub fn clear_bit(self) -> &'a mut W { self.bit(false) } #[doc = r" Writes raw bits to the field"] #[inline] pub fn bit(self, value: bool) -> &'a mut W { const MASK: bool = true; const OFFSET: u8 = 6; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _EMITRANGEW<'a> { w: &'a mut W, } impl<'a> _EMITRANGEW<'a> { #[doc = r" Sets the field bit"] pub fn set_bit(self) -> &'a mut W { self.bit(true) } #[doc = r" Clears the field bit"] pub fn clear_bit(self) -> &'a mut W { self.bit(false) } #[doc = r" Writes raw bits to the field"] #[inline] pub fn bit(self, value: bool) -> &'a mut W { const MASK: bool = true; const OFFSET: u8 = 5; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _RESERVED4W<'a> { w: &'a mut W, } impl<'a> _RESERVED4W<'a> { #[doc = r" Sets the field bit"] pub fn set_bit(self) -> &'a mut W { self.bit(true) } #[doc = r" Clears the field bit"] pub fn clear_bit(self) -> &'a mut W { self.bit(false) } #[doc = r" Writes raw bits to the field"] #[inline] pub fn bit(self, value: bool) -> &'a mut W { const MASK: bool = true; const OFFSET: u8 = 4; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } #[doc = r" Proxy"] pub struct _FUNCTIONW<'a> { w: &'a mut W, } impl<'a> _FUNCTIONW<'a> { #[doc = r" Writes raw bits to the field"] #[inline] pub unsafe fn bits(self, value: u8) -> &'a mut W { const MASK: u8 = 15; const OFFSET: u8 = 0; self.w.bits &= !((MASK as u32) << OFFSET); self.w.bits |= ((value & MASK) as u32) << OFFSET; self.w } } impl R { #[doc = r" Value of the register as raw bits"] #[inline] pub fn bits(&self) -> u32 { self.bits } #[doc = "Bits 25:31 - 31:25\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved25(&self) -> RESERVED25R { let bits = { const MASK: u8 = 127; const OFFSET: u8 = 25; ((self.bits >> OFFSET) & MASK as u32) as u8 }; RESERVED25R { bits } } #[doc = "Bit 24 - 24:24\\] This bit is set when the comparator matches, and indicates that the operation defined by FUNCTION has occurred since this bit was last read. This bit is cleared on read."] #[inline] pub fn matched(&self) -> MATCHEDR { let bits = { const MASK: bool = true; const OFFSET: u8 = 24; ((self.bits >> OFFSET) & MASK as u32) != 0 }; MATCHEDR { bits } } #[doc = "Bits 8:23 - 23:8\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved8(&self) -> RESERVED8R { let bits = { const MASK: u16 = 65535; const OFFSET: u8 = 8; ((self.bits >> OFFSET) & MASK as u32) as u16 }; RESERVED8R { bits } } #[doc = "Bit 7 - 7:7\\] This bit is only available in comparator 0. When set, COMP0 will compare against the cycle counter (CYCCNT)."] #[inline] pub fn cycmatch(&self) -> CYCMATCHR { let bits = { const MASK: bool = true; const OFFSET: u8 = 7; ((self.bits >> OFFSET) & MASK as u32) != 0 }; CYCMATCHR { bits } } #[doc = "Bit 6 - 6:6\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved6(&self) -> RESERVED6R { let bits = { const MASK: bool = true; const OFFSET: u8 = 6; ((self.bits >> OFFSET) & MASK as u32) != 0 }; RESERVED6R { bits } } #[doc = "Bit 5 - 5:5\\] Emit range field. This bit permits emitting offset when range match occurs. PC sampling is not supported when emit range is enabled. This field only applies for: FUNCTION = 1, 2, 3, 12, 13, 14, and 15."] #[inline] pub fn emitrange(&self) -> EMITRANGER { let bits = { const MASK: bool = true; const OFFSET: u8 = 5; ((self.bits >> OFFSET) & MASK as u32) != 0 }; EMITRANGER { bits } } #[doc = "Bit 4 - 4:4\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved4(&self) -> RESERVED4R { let bits = { const MASK: bool = true; const OFFSET: u8 = 4; ((self.bits >> OFFSET) & MASK as u32) != 0 }; RESERVED4R { bits } } #[doc = "Bits 0:3 - 3:0\\] Function settings. 0x0: Disabled 0x1: EMITRANGE = 0, sample and emit PC through ITM. EMITRANGE = 1, emit address offset through ITM 0x2: EMITRANGE = 0, emit data through ITM on read and write. EMITRANGE = 1, emit data and address offset through ITM on read or write. 0x3: EMITRANGE = 0, sample PC and data value through ITM on read or write. EMITRANGE = 1, emit address offset and data value through ITM on read or write. 0x4: Watchpoint on PC match. 0x5: Watchpoint on read. 0x6: Watchpoint on write. 0x7: Watchpoint on read or write. 0x8: ETM trigger on PC match 0x9: ETM trigger on read 0xA: ETM trigger on write 0xB: ETM trigger on read or write 0xC: EMITRANGE = 0, sample data for read transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) for read transfers 0xD: EMITRANGE = 0, sample data for write transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) for write transfers 0xE: EMITRANGE = 0, sample PC + data for read transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) + data for read transfers 0xF: EMITRANGE = 0, sample PC + data for write transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) + data for write transfers Note 1: If the ETM is not fitted, then ETM trigger is not possible. Note 2: Data value is only sampled for accesses that do not fault (MPU or bus fault). The PC is sampled irrespective of any faults. The PC is only sampled for the first address of a burst. Note 3: PC match is not recommended for watchpoints because it stops after the instruction. It mainly guards and triggers the ETM."] #[inline] pub fn function(&self) -> FUNCTIONR { let bits = { const MASK: u8 = 15; const OFFSET: u8 = 0; ((self.bits >> OFFSET) & MASK as u32) as u8 }; FUNCTIONR { bits } } } impl W { #[doc = r" Reset value of the register"] #[inline] pub fn reset_value() -> W { W { bits: 0 } } #[doc = r" Writes raw bits to the register"] #[inline] pub unsafe fn bits(&mut self, bits: u32) -> &mut Self { self.bits = bits; self } #[doc = "Bits 25:31 - 31:25\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved25(&mut self) -> _RESERVED25W { _RESERVED25W { w: self } } #[doc = "Bit 24 - 24:24\\] This bit is set when the comparator matches, and indicates that the operation defined by FUNCTION has occurred since this bit was last read. This bit is cleared on read."] #[inline] pub fn matched(&mut self) -> _MATCHEDW { _MATCHEDW { w: self } } #[doc = "Bits 8:23 - 23:8\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved8(&mut self) -> _RESERVED8W { _RESERVED8W { w: self } } #[doc = "Bit 7 - 7:7\\] This bit is only available in comparator 0. When set, COMP0 will compare against the cycle counter (CYCCNT)."] #[inline] pub fn cycmatch(&mut self) -> _CYCMATCHW { _CYCMATCHW { w: self } } #[doc = "Bit 6 - 6:6\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved6(&mut self) -> _RESERVED6W { _RESERVED6W { w: self } } #[doc = "Bit 5 - 5:5\\] Emit range field. This bit permits emitting offset when range match occurs. PC sampling is not supported when emit range is enabled. This field only applies for: FUNCTION = 1, 2, 3, 12, 13, 14, and 15."] #[inline] pub fn emitrange(&mut self) -> _EMITRANGEW { _EMITRANGEW { w: self } } #[doc = "Bit 4 - 4:4\\] Software should not rely on the value of a reserved. Writing any other value than the reset value may result in undefined behavior."] #[inline] pub fn reserved4(&mut self) -> _RESERVED4W { _RESERVED4W { w: self } } #[doc = "Bits 0:3 - 3:0\\] Function settings. 0x0: Disabled 0x1: EMITRANGE = 0, sample and emit PC through ITM. EMITRANGE = 1, emit address offset through ITM 0x2: EMITRANGE = 0, emit data through ITM on read and write. EMITRANGE = 1, emit data and address offset through ITM on read or write. 0x3: EMITRANGE = 0, sample PC and data value through ITM on read or write. EMITRANGE = 1, emit address offset and data value through ITM on read or write. 0x4: Watchpoint on PC match. 0x5: Watchpoint on read. 0x6: Watchpoint on write. 0x7: Watchpoint on read or write. 0x8: ETM trigger on PC match 0x9: ETM trigger on read 0xA: ETM trigger on write 0xB: ETM trigger on read or write 0xC: EMITRANGE = 0, sample data for read transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) for read transfers 0xD: EMITRANGE = 0, sample data for write transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) for write transfers 0xE: EMITRANGE = 0, sample PC + data for read transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) + data for read transfers 0xF: EMITRANGE = 0, sample PC + data for write transfers. EMITRANGE = 1, sample Daddr (lower 16 bits) + data for write transfers Note 1: If the ETM is not fitted, then ETM trigger is not possible. Note 2: Data value is only sampled for accesses that do not fault (MPU or bus fault). The PC is sampled irrespective of any faults. The PC is only sampled for the first address of a burst. Note 3: PC match is not recommended for watchpoints because it stops after the instruction. It mainly guards and triggers the ETM."] #[inline] pub fn function(&mut self) -> _FUNCTIONW { _FUNCTIONW { w: self } } }