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Each architecture must implement the following types and APIs.
The syntax `const_range<T>` is used to denote anything that has a `begin()` and `end()` method that return const forward iterators. This can be a `std::list<T>`, `std::vector<T>`, a (const) reference to those, or anything else that behaves in a similar way.
archdefs.h
==========
The architecture-specific `archdefs.h` must define the following types.
With the exception of `ArchNetInfo` and `ArchCellInfo`, the following types should be "lightweight" enough so that passing them by value is sensible.
### delay\_t
A scalar type that is used to represent delays. May be an integer or float type.
### DelayInfo
A struct representing the delay across a timing arc. Must provide a `+` operator for getting the combined delay of two arcs, and the following methods to access concrete timings:
```
delay_t minRaiseDelay() const { return delay; }
delay_t maxRaiseDelay() const { return delay; }
delay_t minFallDelay() const { return delay; }
delay_t maxFallDelay() const { return delay; }
delay_t minDelay() const { return delay; }
delay_t maxDelay() const { return delay; }
```
### BelId
A type representing a bel name. `BelId()` must construct a unique null-value. Must provide `==` and `!=` operators and a specialization for `std::hash<BelId>`.
### WireId
A type representing a wire name. `WireId()` must construct a unique null-value. Must provide `==` and `!=` operators and a specialization for `std::hash<WireId>`.
### PipId
A type representing a pip name. `PipId()` must construct a unique null-value. Must provide `==` and `!=` operators and a specialization for `std::hash<PipId>`.
### GroupId
A type representing a group name. `GroupId()` must construct a unique null-value. Must provide `==` and `!=` operators and a specialization for `std::hash<GroupId>`.
### DecalId
A type representing a reference to a graphical decal. `DecalId()` must construct a unique null-value. Must provide `==` and `!=` operators and a specialization for `std::hash<DecalId>`.
### ArchNetInfo
The global `NetInfo` type derives from this one. Can be used to add arch-specific data (caches of information derived from wire attributes, bound wires and pips, and other net state). Must be declared as empty struct if unused.
### ArchCellInfo
The global `CellInfo` type derives from this one. Can be used to add arch-specific data (caches of information derived from cell attributes and parameters, bound bel, and other cell state). Must be declared as empty struct if unused.
arch.h
======
Each architecture must provide their own implementation of the `Arch` struct in `arch.h`. `Arch` must derive from `BaseCtx` and must provide the following methods:
General Methods
---------------
### Arch(ArchArgs args)
Constructor. ArchArgs is a architecture-specific type (usually a struct also defined in `arch.h`).
### std::string getChipName() const
Return a string representation of the ArchArgs that was used to construct this object.
### int getGridDimX() const
Get grid X dimension. All bels and pips must have Y coordinates in the range `0 .. getGridDimX()-1` (inclusive).
### int getGridDimY() const
Get grid Y dimension. All bels and pips must have Y coordinates in the range `0 .. getGridDimY()-1` (inclusive).
### int getTileBelDimZ(int x, int y) const
Get Z dimension for the specified tile for bels. All bels with at specified X and Y coordinates must have a Z coordinate in the range `0 .. getTileDimZ(X,Y)-1` (inclusive).
### int getTilePipDimZ(int x, int y) const
Get Z dimension for the specified tile for pips. All pips with at specified X and Y coordinates must have a Z coordinate in the range `0 .. getTileDimZ(X,Y)-1` (inclusive).
Bel Methods
-----------
### BelId getBelByName(IdString name) const
Lookup a bel by its name.
### IdString getBelName(BelId bel) const
Get the name for a bel. (Bel names must be unique.)
### Loc getBelLocation(BelId bel) const
Get the X/Y/Z location of a given bel. Each bel must have a unique X/Y/Z location.
### BelId getBelByLocation(Loc loc) const
Lookup a bel by its X/Y/Z location.
### const\_range\<BelId\> getBelsByTile(int x, int y) const
Return a list of all bels at the give X/Y location.
### bool getBelGlobalBuf(BelId bel) const
Returns true if the given bel is a global buffer. A global buffer does not "pull in" other cells it drives to be close to the location of the global buffer.
### uint32\_t getBelChecksum(BelId bel) const
Return a (preferably unique) number that represents this bel. This is used in design state checksum calculations.
### void bindBel(BelId bel, CellInfo \*cell, PlaceStrength strength)
Bind a given bel to a given cell with the given strength.
This method must also update `cell->bel` and `cell->belStrength`.
### void unbindBel(BelId bel)
Unbind a bel.
This method must also update `CellInfo::bel` and `CellInfo::belStrength`.
### bool checkBelAvail(BelId bel) const
Returns true if the bel is available. A bel can be unavailable because it is bound, or because it is exclusive to some other resource that is bound.
### CellInfo \*getBoundBelCell(BelId bel) const
Return the cell the given bel is bound to, or nullptr if the bel is not bound.
### CellInfo \*getConflictingBelCell(BelId bel) const
If the bel is unavailable, and unbinding a single cell would make it available, then this method must return that cell.
### const\_range\<BelId\> getBels() const
Return a list of all bels on the device.
### IdString getBelType(BelId bel) const
Return the type of a given bel.
### const\_range\<std\:\:pair\<IdString, std::string\>\> getBelAttrs(BelId bel) const
Return the attributes for that bel. Bel attributes are only informal. They are displayed by the GUI but are otherwise
unused. An implementation may simply return an empty range.
### WireId getBelPinWire(BelId bel, IdString pin) const
Return the wire connected to the given bel pin.
### PortType getBelPinType(BelId bel, IdString pin) const
Return the type (input/output/inout) of the given bel pin.
### const\_range\<IdString\> getBelPins(BelId bel) const
Return a list of all pins on that bel.
Wire Methods
------------
### WireId getWireByName(IdString name) const
Lookup a wire by its name.
### IdString getWireName(WireId wire) const
Get the name for a wire. (Wire names must be unique.)
### IdString getWireType(WireId wire) const
Get the type of a wire. The wire type is purely informal and
isn't used by any of the core algorithms. Implementations may
simply return `IdString()`.
### const\_range\<std\:\:pair\<IdString, std::string\>\> getWireAttrs(WireId wire) const
Return the attributes for that wire. Wire attributes are only informal. They are displayed by the GUI but are otherwise
unused. An implementation may simply return an empty range.
### uint32\_t getWireChecksum(WireId wire) const
Return a (preferably unique) number that represents this wire. This is used in design state checksum calculations.
### void bindWire(WireId wire, NetInfo \*net, PlaceStrength strength)
Bind a wire to a net. This method must be used when binding a wire that is driven by a bel pin. Use `binPip()`
when binding a wire that is driven by a pip.
This method must also update `net->wires`.
### void unbindWire(WireId wire)
Unbind a wire. For wires that are driven by a pip, this will also unbind the driving pip.
This method must also update `NetInfo::wires`.
### bool checkWireAvail(WireId wire) const
Return true if the wire is available, i.e. can be bound to a net.
### NetInfo \*getBoundWireNet(WireId wire) const
Return the net a wire is bound to.
### WireId getConflictingWireWire(WireId wire) const
If this returns a non-WireId(), then unbinding that wire
will make the given wire available.
### NetInfo \*getConflictingWireNet(WireId wire) const
If this returns a non-nullptr, then unbinding that entire net
will make the given wire available.
### DelayInfo getWireDelay(WireId wire) const
Get the delay for a wire.
### const\_range\<WireId\> getWires() const
Get a list of all wires on the device.
### const\_range\<BelPin\> getWireBelPins(WireId wire) const
Get a list of all bel pins attached to a given wire.
Pip Methods
-----------
### PipId getPipByName(IdString name) const
Lookup a pip by its name.
### IdString getPipName(PipId pip) const
Get the name for a pip. (Pip names must be unique.)
### IdString getPipType(PipId pip) const
Get the type of a pip. Pip types are purely informal and
implementations may simply return `IdString()`.
### const\_range\<std\:\:pair\<IdString, std::string\>\> getPipAttrs(PipId pip) const
Return the attributes for that pip. Pip attributes are only informal. They are displayed by the GUI but are otherwise
unused. An implementation may simply return an empty range.
### Loc getPipLocation(PipId pip) const
Get the X/Y/Z location of a given pip. Pip locations do not need to be unique, and in most cases they aren't. So
for pips a X/Y/Z location refers to a group of pips, not an individual pip.
### uint32\_t getPipChecksum(PipId pip) const
Return a (preferably unique) number that represents this pip. This is used in design state checksum calculations.
### void bindPip(PipId pip, NetInfo \*net, PlaceStrength strength)
Bid a pip to a net. This also bind the destination wire of that pip.
This method must also update `net->wires`.
### void unbindPip(PipId pip)
Unbind a pip and the wire driven by that pip.
This method must also update `NetInfo::wires`.
### bool checkPipAvail(PipId pip) const
Returns true if the given pip is available to be bound to a net.
Users must also check if the pip destination wire is available
with `checkWireAvail(getPipDstWire(pip))` before binding the
pip to a net.
### NetInfo \*getBoundPipNet(PipId pip) const
Return the net this pip is bound to.
### WireId getConflictingPipWire(PipId pip) const
If this returns a non-WireId(), then unbinding that wire
will make the given pip available.
### NetInfo \*getConflictingPipNet(PipId pip) const
If this returns a non-nullptr, then unbinding that entire net
will make the given pip available.
### const\_range\<PipId\> getPips() const
Return a list of all pips on the device.
### WireId getPipSrcWire(PipId pip) const
Get the source wire for a pip.
### WireId getPipDstWire(PipId pip) const
Get the destination wire for a pip.
Bi-directional switches (transfer gates) are modelled using two
antiparallel pips.
### DelayInfo getPipDelay(PipId pip) const
Get the delay for a pip.
### const\_range\<PipId\> getPipsDownhill(WireId wire) const
Get all pips downhill of a wire, i.e. pips that use this wire as source wire.
### const\_range\<PipId\> getPipsUphill(WireId wire) const
Get all pips uphill of a wire, i.e. pips that use this wire as destination wire.
### const\_range\<PipId\> getWireAliases(WireId wire) const
Get all alias pips downhill of a wire.
There is no api for getting the alias pips uphill of a wire.
Alias pips come in antiparallel pairs if a signal can be injected on either
side of the alias pip.
Group Methods
-------------
### GroupId getGroupByName(IdString name) const
Lookup a group by its name.
### IdString getGroupName(GroupId group) const
Get the name for a group. (Group names must be unique.)
### const\_range\<GroupId\> getGroups() const
Get a list of all groups on the device.
### const\_range\<BelId\> getGroupBels(GroupId group) const
Get a list of all bels within a group.
### const\_range\<WireId\> getGroupWires(GroupId group) const
Get a list of all wires within a group.
### const\_range\<PipId\> getGroupPips(GroupId group) const
Get a list of all pips within a group.
### const\_range\<GroupId\> getGroupGroups(GroupId group) const
Get a list of all groups within a group.
Delay Methods
-------------
### delay\_t estimateDelay(WireId src, WireId dst) const
Return a rough estimate for the total `maxDelay()` delay from the given src wire to
the given dst wire.
This should return a low upper bound for the fastest route from `src` to `dst`.
Or in other words it should assume an otherwise unused chip (thus "fastest route").
But it only produces an estimate for that fastest route, not an exact
result, and for that estimate it is considered more accaptable to return a
slightly too high result and it is considered less accaptable to return a
too low result (thus "low upper bound").
### delay\_t predictDelay(const NetInfo \*net\_info, const PortRef &sink) const
Return a reasonably good estimate for the total `maxDelay()` delay for the
given arc. This should return a low upper bound for the fastest route for that arc.
### delay\_t getDelayEpsilon() const
Return a small delay value that can be used as small epsilon during routing.
The router will for example not re-calculate cached routing data if faster routes
are found when the difference is smaller than this value.
### delay\_t getRipupDelayPenalty() const
The base penality when calculating delay penalty for ripping up routed nets. The
actual penalty used is a multiple of this value (i.e. a weighted version of this value).
### float getDelayNS(delay\_t v) const
Convert an `delay_t` to an actual real-world delay in nanoseconds.
### uint32\_t getDelayChecksum(delay\_t v) const
Convert a `delay_t` to an integer for checksum calculations.
### bool getBudgetOverride(const NetInfo \*net\_info, const PortRef &sink, delay\_t &budget) const
Overwrite or modify (in-place) the timing budget for a given arc. Returns a bool to indicate whether this was done.
Flow Methods
------------
### bool pack()
Run the packer.
### bool place()
Run the placer.
### bool route()
run the router.
Graphics Methods
----------------
### const\_range\<GraphicElement\> getDecalGraphics(DecalId decal) const
Return the graphic elements that make up a decal.
The same decal must always produce the same list. If the graphics for
a design element changes, that element must return another decal.
### DecalXY getBelDecal(BelId bel) const
Return the decal and X/Y position for the graphics representing a bel.
### DecalXY getWireDecal(WireId wire) const
Return the decal and X/Y position for the graphics representing a wire.
### DecalXY getPipDecal(PipId pip) const
Return the decal and X/Y position for the graphics representing a pip.
### DecalXY getGroupDecal(GroupId group) const
Return the decal and X/Y position for the graphics representing a group.
Cell Delay Methods
------------------
### bool getCellDelay(const CellInfo \*cell, IdString fromPort, IdString toPort, DelayInfo &delay) const
Returns the delay for the specified path through a cell in the `&delay` argument. The method returns
false if there is no timing relationship from `fromPort` to `toPort`.
### TimingPortClass getPortTimingClass(const CellInfo *cell, IdString port, IdString &clockPort) const
Return the _timing port class_ of a port. This can be a register or combinational input or output; clock input or
output; general startpoint or endpoint; or a port ignored for timing purposes. For register ports, clockPort is set
to the associated clock port.
Placer Methods
--------------
### bool isValidBelForCell(CellInfo \*cell, BelId bel) const
Returns true if the given cell can be bound to the given bel, considering
other bound resources. For example, this can be used if there is only
a certain number of different clock signals allowed for a group of bels.
### bool isBelLocationValid(BelId bel) const
Returns true if a bell in the current configuration is valid, i.e. if
`isValidBelForCell()` would return true for the current mapping.
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