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261 lines
8.1 KiB
C++
261 lines
8.1 KiB
C++
//
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// ClockReceiver.hpp
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// Clock Signal
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//
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// Created by Thomas Harte on 22/07/2017.
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// Copyright 2017 Thomas Harte. All rights reserved.
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//
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#ifndef ClockReceiver_hpp
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#define ClockReceiver_hpp
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#include "ForceInline.hpp"
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#include <cstdint>
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/*
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Informal pattern for all classes that run from a clock cycle:
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Each will implement either or both of run_for(Cycles) and run_for(HalfCycles), as
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is appropriate.
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Callers that are accumulating HalfCycles but want to talk to receivers that implement
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only run_for(Cycles) can use HalfCycle.flush_cycles if they have appropriate storage, or
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can wrap the receiver in HalfClockReceiver in order automatically to bind half-cycle
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storage to it.
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Alignment rule:
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run_for(Cycles) may be called only after an even number of half cycles. E.g. the following
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sequence will have undefined results:
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run_for(HalfCycles(1))
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run_for(Cycles(1))
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An easy way to ensure this as a caller is to pick only one of run_for(Cycles) and
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run_for(HalfCycles) to use.
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Reasoning:
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Users of this template may with to implement run_for(Cycles) and run_for(HalfCycles)
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where there is a need to implement at half-cycle precision but a faster execution
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path can be offered for full-cycle precision. Those users are permitted to assume
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phase in run_for(Cycles) and should do so to be compatible with callers that use
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only run_for(Cycles).
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Corollary:
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Starting from nothing, the first run_for(HalfCycles(1)) will do the **first** half
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of a full cycle. The second will do the second half. Etc.
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*/
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/*!
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Provides a class that wraps a plain int, providing most of the basic arithmetic and
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Boolean operators, but forcing callers and receivers to be explicit as to usage.
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*/
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template <class T> class WrappedInt {
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public:
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using IntType = int64_t;
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forceinline constexpr WrappedInt(IntType l) noexcept : length_(l) {}
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forceinline constexpr WrappedInt() noexcept : length_(0) {}
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forceinline T &operator =(const T &rhs) {
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length_ = rhs.length_;
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return *this;
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}
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forceinline T &operator +=(const T &rhs) {
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length_ += rhs.length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator -=(const T &rhs) {
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length_ -= rhs.length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator ++() {
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++ length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator ++(int) {
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length_ ++;
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return *static_cast<T *>(this);
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}
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forceinline T &operator --() {
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-- length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator --(int) {
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length_ --;
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return *static_cast<T *>(this);
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}
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forceinline T &operator *=(const T &rhs) {
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length_ *= rhs.length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator /=(const T &rhs) {
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length_ /= rhs.length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator %=(const T &rhs) {
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length_ %= rhs.length_;
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return *static_cast<T *>(this);
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}
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forceinline T &operator &=(const T &rhs) {
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length_ &= rhs.length_;
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return *static_cast<T *>(this);
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}
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forceinline constexpr T operator +(const T &rhs) const { return T(length_ + rhs.length_); }
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forceinline constexpr T operator -(const T &rhs) const { return T(length_ - rhs.length_); }
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forceinline constexpr T operator *(const T &rhs) const { return T(length_ * rhs.length_); }
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forceinline constexpr T operator /(const T &rhs) const { return T(length_ / rhs.length_); }
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forceinline constexpr T operator %(const T &rhs) const { return T(length_ % rhs.length_); }
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forceinline constexpr T operator &(const T &rhs) const { return T(length_ & rhs.length_); }
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forceinline constexpr T operator -() const { return T(- length_); }
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forceinline constexpr bool operator <(const T &rhs) const { return length_ < rhs.length_; }
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forceinline constexpr bool operator >(const T &rhs) const { return length_ > rhs.length_; }
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forceinline constexpr bool operator <=(const T &rhs) const { return length_ <= rhs.length_; }
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forceinline constexpr bool operator >=(const T &rhs) const { return length_ >= rhs.length_; }
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forceinline constexpr bool operator ==(const T &rhs) const { return length_ == rhs.length_; }
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forceinline constexpr bool operator !=(const T &rhs) const { return length_ != rhs.length_; }
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forceinline constexpr bool operator !() const { return !length_; }
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// bool operator () is not supported because it offers an implicit cast to int, which is prone silently to permit misuse
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/// @returns The underlying int, cast to an integral type of your choosing.
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template<typename Type = IntType> forceinline constexpr Type as() const { return Type(length_); }
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/// @returns The underlying int, in its native form.
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forceinline constexpr IntType as_integral() const { return length_; }
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/*!
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Severs from @c this the effect of dividing by @c divisor; @c this will end up with
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the value of @c this modulo @c divisor and @c divided by @c divisor is returned.
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*/
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template <typename Result = T> forceinline Result divide(const T &divisor) {
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Result r;
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static_cast<T *>(this)->fill(r, divisor);
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return r;
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}
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/*!
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Flushes the value in @c this. The current value is returned, and the internal value
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is reset to zero.
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*/
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template <typename Result> Result flush() {
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// Jiggery pokery here; switching to function overloading avoids
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// the namespace-level requirement for template specialisation.
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Result r;
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static_cast<T *>(this)->fill(r);
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return r;
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}
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// operator int() is deliberately not provided, to avoid accidental subtitution of
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// classes that use this template.
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protected:
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IntType length_;
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};
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/// Describes an integer number of whole cycles: pairs of clock signal transitions.
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class Cycles: public WrappedInt<Cycles> {
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public:
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forceinline constexpr Cycles(IntType l) noexcept : WrappedInt<Cycles>(l) {}
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forceinline constexpr Cycles() noexcept : WrappedInt<Cycles>() {}
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private:
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friend WrappedInt;
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void fill(Cycles &result) {
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result.length_ = length_;
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length_ = 0;
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}
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void fill(Cycles &result, const Cycles &divisor) {
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result.length_ = length_ / divisor.length_;
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length_ %= divisor.length_;
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}
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};
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/// Describes an integer number of half cycles: single clock signal transitions.
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class HalfCycles: public WrappedInt<HalfCycles> {
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public:
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forceinline constexpr HalfCycles(IntType l) noexcept : WrappedInt<HalfCycles>(l) {}
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forceinline constexpr HalfCycles() noexcept : WrappedInt<HalfCycles>() {}
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forceinline constexpr HalfCycles(const Cycles &cycles) noexcept : WrappedInt<HalfCycles>(cycles.as_integral() * 2) {}
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/// @returns The number of whole cycles completely covered by this span of half cycles.
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forceinline constexpr Cycles cycles() const {
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return Cycles(length_ >> 1);
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}
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/*!
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Severs from @c this the effect of dividing by @c divisor; @c this will end up with
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the value of @c this modulo @c divisor and @c divided by @c divisor is returned.
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*/
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forceinline Cycles divide_cycles(const Cycles &divisor) {
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const HalfCycles half_divisor = HalfCycles(divisor);
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const Cycles result(length_ / half_divisor.length_);
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length_ %= half_divisor.length_;
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return result;
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}
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private:
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friend WrappedInt;
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void fill(Cycles &result) {
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result = Cycles(length_ >> 1);
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length_ &= 1;
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}
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void fill(HalfCycles &result) {
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result.length_ = length_;
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length_ = 0;
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}
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void fill(Cycles &result, const HalfCycles &divisor) {
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result = Cycles(length_ / (divisor.length_ << 1));
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length_ %= (divisor.length_ << 1);
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}
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void fill(HalfCycles &result, const HalfCycles &divisor) {
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result.length_ = length_ / divisor.length_;
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length_ %= divisor.length_;
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}
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};
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// Create a specialisation of WrappedInt::flush for converting HalfCycles to Cycles
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// without losing the fractional part.
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/*!
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If a component implements only run_for(Cycles), an owner can wrap it in HalfClockReceiver
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automatically to gain run_for(HalfCycles).
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*/
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template <class T> class HalfClockReceiver: public T {
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public:
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using T::T;
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forceinline void run_for(const HalfCycles half_cycles) {
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half_cycles_ += half_cycles;
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T::run_for(half_cycles_.flush<Cycles>());
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}
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private:
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HalfCycles half_cycles_;
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};
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#endif /* ClockReceiver_hpp */
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