mirror of https://github.com/YosysHQ/yosys.git
409 lines
18 KiB
ReStructuredText
409 lines
18 KiB
ReStructuredText
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The RTL Intermediate Language (RTLIL)
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=====================================
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All frontends, passes and backends in Yosys operate on a design in RTLIL
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representation. The only exception are the high-level frontends that use the AST
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representation as an intermediate step before generating RTLIL data.
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In order to avoid reinventing names for the RTLIL classes, they are simply
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referred to by their full C++ name, i.e. including the RTLIL:: namespace prefix,
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in this document.
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:numref:`Figure %s <fig:Overview_RTLIL>` shows a simplified Entity-Relationship
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Diagram (ER Diagram) of RTLIL. In :math:`1:N` relationships the arrow points
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from the :math:`N` side to the :math:`1`. For example one RTLIL::Design contains
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:math:`N` (zero to many) instances of RTLIL::Module. A two-pointed arrow
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indicates a :math:`1:1` relationship.
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The RTLIL::Design is the root object of the RTLIL data structure. There is
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always one "current design" in memory which passes operate on, frontends add
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data to and backends convert to exportable formats. But in some cases passes
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internally generate additional RTLIL::Design objects. For example when a pass is
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reading an auxiliary Verilog file such as a cell library, it might create an
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additional RTLIL::Design object and call the Verilog frontend with this other
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object to parse the cell library.
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.. figure:: ../../../images/overview_rtlil.*
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:class: width-helper
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:name: fig:Overview_RTLIL
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Simplified RTLIL Entity-Relationship Diagram
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There is only one active RTLIL::Design object that is used by all frontends,
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passes and backends called by the user, e.g. using a synthesis script. The
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RTLIL::Design then contains zero to many RTLIL::Module objects. This corresponds
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to modules in Verilog or entities in VHDL. Each module in turn contains objects
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from three different categories:
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- RTLIL::Cell and RTLIL::Wire objects represent classical netlist data.
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- RTLIL::Process objects represent the decision trees (if-then-else statements,
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etc.) and synchronization declarations (clock signals and sensitivity) from
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Verilog always and VHDL process blocks.
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- RTLIL::Memory objects represent addressable memories (arrays).
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Usually the output of the synthesis procedure is a netlist, i.e. all
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RTLIL::Process and RTLIL::Memory objects must be replaced by RTLIL::Cell and
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RTLIL::Wire objects by synthesis passes.
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All features of the HDL that cannot be mapped directly to these RTLIL classes
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must be transformed to an RTLIL-compatible representation by the HDL frontend.
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This includes Verilog-features such as generate-blocks, loops and parameters.
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The following sections contain a more detailed description of the different
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parts of RTLIL and rationale behind some of the design decisions.
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RTLIL identifiers
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-----------------
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All identifiers in RTLIL (such as module names, port names, signal names, cell
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types, etc.) follow the following naming convention: they must either start with
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a backslash (\) or a dollar sign ($).
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Identifiers starting with a backslash are public visible identifiers. Usually
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they originate from one of the HDL input files. For example the signal name
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"\\sig42" is most likely a signal that was declared using the name "sig42" in an
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HDL input file. On the other hand the signal name "$sig42" is an auto-generated
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signal name. The backends convert all identifiers that start with a dollar sign
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to identifiers that do not collide with identifiers that start with a backslash.
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This has three advantages:
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- First, it is impossible that an auto-generated identifier collides with an
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identifier that was provided by the user.
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- Second, the information about which identifiers were originally provided by
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the user is always available which can help guide some optimizations. For
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example the "opt_rmunused" tries to preserve signals with a user-provided
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name but doesn't hesitate to delete signals that have auto-generated names
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when they just duplicate other signals.
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- Third, the delicate job of finding suitable auto-generated public visible
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names is deferred to one central location. Internally auto-generated names
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that may hold important information for Yosys developers can be used without
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disturbing external tools. For example the Verilog backend assigns names in
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the form \_integer\_.
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Whitespace and control characters (any character with an ASCII code 32 or less)
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are not allowed in RTLIL identifiers; most frontends and backends cannot support
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these characters in identifiers.
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In order to avoid programming errors, the RTLIL data structures check if all
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identifiers start with either a backslash or a dollar sign, and contain no
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whitespace or control characters. Violating these rules results in a runtime
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error.
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All RTLIL identifiers are case sensitive.
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Some transformations, such as flattening, may have to change identifiers
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provided by the user to avoid name collisions. When that happens, attribute
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"hdlname" is attached to the object with the changed identifier. This attribute
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contains one name (if emitted directly by the frontend, or is a result of
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disambiguation) or multiple names separated by spaces (if a result of
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flattening). All names specified in the "hdlname" attribute are public and do
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not include the leading "\".
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RTLIL::Design and RTLIL::Module
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-------------------------------
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The RTLIL::Design object is basically just a container for RTLIL::Module
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objects. In addition to a list of RTLIL::Module objects the RTLIL::Design also
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keeps a list of selected objects, i.e. the objects that passes should operate
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on. In most cases the whole design is selected and therefore passes operate on
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the whole design. But this mechanism can be useful for more complex synthesis
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jobs in which only parts of the design should be affected by certain passes.
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Besides the objects shown in the ER diagram in :numref:`Fig. %s
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<fig:Overview_RTLIL>` an RTLIL::Module object contains the following additional
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properties:
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- The module name
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- A list of attributes
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- A list of connections between wires
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- An optional frontend callback used to derive parametrized variations of the
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module
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The attributes can be Verilog attributes imported by the Verilog frontend or
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attributes assigned by passes. They can be used to store additional metadata
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about modules or just mark them to be used by certain part of the synthesis
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script but not by others.
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Verilog and VHDL both support parametric modules (known as "generic entities" in
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VHDL). The RTLIL format does not support parametric modules itself. Instead each
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module contains a callback function into the AST frontend to generate a
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parametrized variation of the RTLIL::Module as needed. This callback then
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returns the auto-generated name of the parametrized variation of the module. (A
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hash over the parameters and the module name is used to prohibit the same
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parametrized variation from being generated twice. For modules with only a few
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parameters, a name directly containing all parameters is generated instead of a
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hash string.)
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.. _sec:rtlil_cell_wire:
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RTLIL::Cell and RTLIL::Wire
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---------------------------
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A module contains zero to many RTLIL::Cell and RTLIL::Wire objects. Objects of
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these types are used to model netlists. Usually the goal of all synthesis
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efforts is to convert all modules to a state where the functionality of the
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module is implemented only by cells from a given cell library and wires to
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connect these cells with each other. Note that module ports are just wires with
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a special property.
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An RTLIL::Wire object has the following properties:
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- The wire name
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- A list of attributes
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- A width (buses are just wires with a width > 1)
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- Bus direction (MSB to LSB or vice versa)
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- Lowest valid bit index (LSB or MSB depending on bus direction)
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- If the wire is a port: port number and direction (input/output/inout)
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As with modules, the attributes can be Verilog attributes imported by the
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Verilog frontend or attributes assigned by passes.
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In Yosys, busses (signal vectors) are represented using a single wire object
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with a width > 1. So Yosys does not convert signal vectors to individual
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signals. This makes some aspects of RTLIL more complex but enables Yosys to be
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used for coarse grain synthesis where the cells of the target architecture
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operate on entire signal vectors instead of single bit wires.
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In Verilog and VHDL, busses may have arbitrary bounds, and LSB can have either
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the lowest or the highest bit index. In RTLIL, bit 0 always corresponds to LSB;
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however, information from the HDL frontend is preserved so that the bus will be
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correctly indexed in error messages, backend output, constraint files, etc.
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An RTLIL::Cell object has the following properties:
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- The cell name and type
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- A list of attributes
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- A list of parameters (for parametric cells)
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- Cell ports and the connections of ports to wires and constants
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The connections of ports to wires are coded by assigning an RTLIL::SigSpec to
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each cell port. The RTLIL::SigSpec data type is described in the next section.
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.. _sec:rtlil_sigspec:
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RTLIL::SigSpec
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--------------
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A "signal" is everything that can be applied to a cell port. I.e.
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- | Any constant value of arbitrary bit-width
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| 1em For example: ``1337, 16'b0000010100111001, 1'b1, 1'bx``
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- | All bits of a wire or a selection of bits from a wire
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| 1em For example: ``mywire, mywire[24], mywire[15:8]``
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- | Concatenations of the above
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| 1em For example: ``{16'd1337, mywire[15:8]}``
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The RTLIL::SigSpec data type is used to represent signals. The RTLIL::Cell
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object contains one RTLIL::SigSpec for each cell port.
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In addition, connections between wires are represented using a pair of
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RTLIL::SigSpec objects. Such pairs are needed in different locations. Therefore
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the type name RTLIL::SigSig was defined for such a pair.
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.. _sec:rtlil_process:
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RTLIL::Process
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--------------
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When a high-level HDL frontend processes behavioural code it splits it up into
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data path logic (e.g. the expression a + b is replaced by the output of an adder
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that takes a and b as inputs) and an RTLIL::Process that models the control
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logic of the behavioural code. Let's consider a simple example:
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.. code:: verilog
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:number-lines:
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module ff_with_en_and_async_reset(clock, reset, enable, d, q);
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input clock, reset, enable, d;
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output reg q;
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always @(posedge clock, posedge reset)
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if (reset)
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q <= 0;
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else if (enable)
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q <= d;
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endmodule
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In this example there is no data path and therefore the RTLIL::Module generated
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by the frontend only contains a few RTLIL::Wire objects and an RTLIL::Process.
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The RTLIL::Process in RTLIL syntax:
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.. code:: RTLIL
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:number-lines:
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process $proc$ff_with_en_and_async_reset.v:4$1
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assign $0\q[0:0] \q
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switch \reset
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case 1'1
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assign $0\q[0:0] 1'0
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case
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switch \enable
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case 1'1
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assign $0\q[0:0] \d
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case
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end
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end
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sync posedge \clock
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update \q $0\q[0:0]
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sync posedge \reset
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update \q $0\q[0:0]
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end
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This RTLIL::Process contains two RTLIL::SyncRule objects, two RTLIL::SwitchRule
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objects and five RTLIL::CaseRule objects. The wire $0\q[0:0] is an automatically
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created wire that holds the next value of \\q. The lines :math:`2 \dots 12`
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describe how $0\q[0:0] should be calculated. The lines :math:`13 \dots 16`
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describe how the value of $0\q[0:0] is used to update \\q.
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An RTLIL::Process is a container for zero or more RTLIL::SyncRule objects and
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exactly one RTLIL::CaseRule object, which is called the root case.
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An RTLIL::SyncRule object contains an (optional) synchronization condition
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(signal and edge-type), zero or more assignments (RTLIL::SigSig), and zero or
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more memory writes (RTLIL::MemWriteAction). The always synchronization condition
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is used to break combinatorial loops when a latch should be inferred instead.
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An RTLIL::CaseRule is a container for zero or more assignments (RTLIL::SigSig)
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and zero or more RTLIL::SwitchRule objects. An RTLIL::SwitchRule objects is a
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container for zero or more RTLIL::CaseRule objects.
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In the above example the lines :math:`2 \dots 12` are the root case. Here
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$0\q[0:0] is first assigned the old value \\q as default value (line 2). The
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root case also contains an RTLIL::SwitchRule object (lines :math:`3 \dots 12`).
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Such an object is very similar to the C switch statement as it uses a control
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signal (\\reset in this case) to determine which of its cases should be active.
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The RTLIL::SwitchRule object then contains one RTLIL::CaseRule object per case.
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In this example there is a case [1]_ for \\reset == 1 that causes $0\q[0:0] to
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be set (lines 4 and 5) and a default case that in turn contains a switch that
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sets $0\q[0:0] to the value of \\d if \\enable is active (lines :math:`6 \dots
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11`).
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A case can specify zero or more compare values that will determine whether it
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matches. Each of the compare values must be the exact same width as the control
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signal. When more than one compare value is specified, the case matches if any
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of them matches the control signal; when zero compare values are specified, the
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case always matches (i.e. it is the default case).
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A switch prioritizes cases from first to last: multiple cases can match, but
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only the first matched case becomes active. This normally synthesizes to a
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priority encoder. The parallel_case attribute allows passes to assume that no
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more than one case will match, and full_case attribute allows passes to assume
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that exactly one case will match; if these invariants are ever dynamically
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violated, the behavior is undefined. These attributes are useful when an
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invariant invisible to the synthesizer causes the control signal to never take
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certain bit patterns.
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The lines :math:`13 \dots 16` then cause \\q to be updated whenever there is a
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positive clock edge on \\clock or \\reset.
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In order to generate such a representation, the language frontend must be able
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to handle blocking and nonblocking assignments correctly. However, the language
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frontend does not need to identify the correct type of storage element for the
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output signal or generate multiplexers for the decision tree. This is done by
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passes that work on the RTLIL representation. Therefore it is relatively easy to
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substitute these steps with other algorithms that target different target
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architectures or perform optimizations or other transformations on the decision
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trees before further processing them.
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One of the first actions performed on a design in RTLIL representation in most
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synthesis scripts is identifying asynchronous resets. This is usually done using
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the proc_arst pass. This pass transforms the above example to the following
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RTLIL::Process:
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.. code:: RTLIL
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:number-lines:
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process $proc$ff_with_en_and_async_reset.v:4$1
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assign $0\q[0:0] \q
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switch \enable
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case 1'1
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assign $0\q[0:0] \d
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case
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end
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sync posedge \clock
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update \q $0\q[0:0]
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sync high \reset
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update \q 1'0
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end
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This pass has transformed the outer RTLIL::SwitchRule into a modified
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RTLIL::SyncRule object for the \\reset signal. Further processing converts the
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RTLIL::Process into e.g. a d-type flip-flop with asynchronous reset and a
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multiplexer for the enable signal:
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.. code:: RTLIL
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:number-lines:
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cell $adff $procdff$6
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parameter \ARST_POLARITY 1'1
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parameter \ARST_VALUE 1'0
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parameter \CLK_POLARITY 1'1
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parameter \WIDTH 1
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connect \ARST \reset
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connect \CLK \clock
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connect \D $0\q[0:0]
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connect \Q \q
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end
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cell $mux $procmux$3
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parameter \WIDTH 1
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connect \A \q
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connect \B \d
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connect \S \enable
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connect \Y $0\q[0:0]
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end
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Different combinations of passes may yield different results. Note that $adff
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and $mux are internal cell types that still need to be mapped to cell types from
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the target cell library.
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Some passes refuse to operate on modules that still contain RTLIL::Process
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objects as the presence of these objects in a module increases the complexity.
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Therefore the passes to translate processes to a netlist of cells are usually
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called early in a synthesis script. The proc pass calls a series of other passes
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that together perform this conversion in a way that is suitable for most
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synthesis tasks.
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.. _sec:rtlil_memory:
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RTLIL::Memory
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-------------
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For every array (memory) in the HDL code an RTLIL::Memory object is created. A
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memory object has the following properties:
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- The memory name
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- A list of attributes
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- The width of an addressable word
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- The size of the memory in number of words
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All read accesses to the memory are transformed to $memrd cells and all write
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accesses to $memwr cells by the language frontend. These cells consist of
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independent read- and write-ports to the memory. Memory initialization is
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transformed to $meminit cells by the language frontend. The ``\MEMID`` parameter
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on these cells is used to link them together and to the RTLIL::Memory object
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they belong to.
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The rationale behind using separate cells for the individual ports versus
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creating a large multiport memory cell right in the language frontend is that
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the separate $memrd and $memwr cells can be consolidated using resource sharing.
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As resource sharing is a non-trivial optimization problem where different
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synthesis tasks can have different requirements it lends itself to do the
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optimisation in separate passes and merge the RTLIL::Memory objects and $memrd
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and $memwr cells to multiport memory blocks after resource sharing is completed.
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The memory pass performs this conversion and can (depending on the options
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passed to it) transform the memories directly to d-type flip-flops and address
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logic or yield multiport memory blocks (represented using $mem cells).
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See :ref:`sec:memcells` for details about the memory cell types.
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.. [1]
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The syntax 1'1 in the RTLIL code specifies a constant with a length of one
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bit (the first "1"), and this bit is a one (the second "1").
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