2022-03-10 04:46:21 -05:00
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In F4PGA
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########
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Synthesis
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2022-03-15 18:09:50 -04:00
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*********
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2022-03-10 04:46:21 -05:00
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In the F4PGA toolchain synthesis is made with the use of Yosys, that is able to perform all the mentioned steps and
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convert HDL to netlist description.
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The result of these steps is written to a file in ``.eblif`` format.
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2022-08-03 23:25:44 -04:00
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.. _Flows:F4PGA:Yosys:
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2022-03-15 18:09:50 -04:00
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Yosys
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=====
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Yosys is a Free and Open Source Verilog HDL synthesis tool.
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It was designed to be highly extensible and multiplatform.
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In F4PGA toolchain, it is responsible for the whole synthesis process described in `FPGA Design Flow <./design-flow.html>`_
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It is not necessary to call Yosys directly using F4PGA.
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Nevertheless, the following description, should provide sufficient introduction to Yosys usage inside the project.
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It is also a good starting point for a deeper understanding of the whole toolchain.
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Short description
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-----------------
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Yosys consists of several subsystems. Most distinguishable are the first and last ones used in the synthesis process,
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called *frontend* and *backend* respectively.
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Intermediate subsystems are called *passes*.
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The *frontend* is responsible for changing the Verilog input file into an internal Yosys, representation which is common
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for all *passes* used by the program.
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The *passes* are responsible for a variety of optimizations (``opt_``) and simplifications (``proc_``).
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Two *passes*, that are worth to mention separately are ``ABC`` and ``techmap``.
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The first one optimizes logic functions from the design and assigns obtained results into Look Up Tables (LUTs) of
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chosen width.
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The second mentioned *pass* - ``techmap`` is responsible for mapping the synthesized design from Yosys internal blocks
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to the primitives used by the implementation tool.
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Recommended synthesis flows for different FPGAs are combined into macros i.e. ``synth_ice40`` (for Lattice iCE40 FPGA)
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or ``synth_xilinx`` (for Xilinx 7-series FPGAs).
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The *backend* on the other hand, is responsible for converting internal Yosys representation into one of the
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standardized formats.
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F4PGA uses ``.eblif`` as its output file format.
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Usage in Toolchain
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------------------
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All operations performed by Yosys are written in ``.tcl`` script. Commands used
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in the scripts are responsible for preparing output file to match with the
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expectations of other toolchain tools.
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There is no need to change it even for big designs.
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An example configuration script can be found below:
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.. code-block:: tcl
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yosys -import
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synth_ice40 -nocarry
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opt_expr -undriven
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opt_clean
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setundef -zero -params
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write_blif -attr -cname -param $::env(OUT_EBLIF)
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write_verilog $::env(OUT_SYNTH_V)
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It can be seen that this script performs a platform-specific process of synthesis, some optimization steps (``opt_``
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commands), and writes the final file in ``.eblif`` and Verilog formats.
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Yosys synthesis configuration scripts are platform-specific and can by found in ``<platform-dir>/yosys/synth.tcl`` in
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the :gh:`F4PGA Architecture Definitions <SymbiFlow/f4pga-arch-defs>` repository.
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To understand performed operations, view the log file.
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It is usually generated in the project build directory. It should be named ``top.eblif.log``.
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Output analysis
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---------------
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Input file:
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.. code-block:: verilog
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module top (
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input clk,
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output LD7,
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);
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localparam BITS = 1;
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localparam LOG2DELAY = 25;
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reg [BITS+LOG2DELAY-1:0] counter = 0;
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always @(posedge clk) begin
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counter <= counter + 1;
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end
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assign {LD7} = counter >> LOG2DELAY;
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endmodule
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after synthesis is described only with use of primitives appropriate for
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chosen platform:
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.. code-block:: verilog
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module top(clk, LD7);
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wire [25:0] _000_;
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wire _001_;
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...
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FDRE_ZINI #(
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.IS_C_INVERTED(1'h0),
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.ZINI(1'h1)
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) _073_ (
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.C(clk),
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.CE(_012_),
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.D(_000_[0]),
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.Q(counter[0]),
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.R(_013_)
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);
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...
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SR_GND _150_ (
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.GND(_062_)
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);
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assign _003_[25:0] = _000_;
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assign counter[25] = LD7;
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endmodule
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The same structure is described by the ``.eblif`` file.
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Technology mapping in F4PGA toolchain
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-------------------------------------
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.. _Xilinx 7 Series FPGAs Clocking Resources User Guide: https://www.xilinx.com/support/documentation/user_guides/ug472_7Series_Clocking.pdf#page=38
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.. _VTR FPGA Architecture Description: https://docs.verilogtorouting.org/en/latest/arch/
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2022-04-05 07:32:19 -04:00
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.. _techmap section in the Yosys Manual: https://yosyshq.net/yosys/files/yosys_manual.pdf#page=153
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2022-03-15 18:09:50 -04:00
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It is important to understand the connection between the synthesis and
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implementation tools used in the F4PGA toolchain. As mentioned before,
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synthesis tools like Yosys take the design description from the source files
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and convert them into a netlist that consists of the primitives used by
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the implementation tool. Usually, to support multiple implementation tools,
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an additional intermediate representation of FPGA primitives is provided.
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The process of translating the primitives from the synthesis
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tool’s internal representation to the specific primitives used in the
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implementation tools is called technology mapping (or techmapping).
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Technology mapping for VPR
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--------------------------
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As mentioned before, VPR is one of the implementation tools (often referred to
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as Place & Route or P&R tools) used in F4PGA. By default, the F4PGA
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toolchain uses it during bitstream generation for, i.e., Xilinx 7-Series
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devices. Since the architecture models for this FPGA family were created from
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scratch, appropriate techmaps were needed to instruct Yosys on translating
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the primitives to the versions compatible with VPR.
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The clock buffers used in the 7-Series devices are a good example for explaining
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the techmapping process. Generally, as stated in the
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`Xilinx 7 Series FPGAs Clocking Resources User Guide`_, a designer has various
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buffer types that they can use in designs:
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- ``BUFGCTRL``
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- ``BUFG``
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- ``BUFGCE``
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- ``BUFGCE_1``
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- ``BUFGMUX``
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- ``BUFGMUX_1``
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- ``BUFGMUX_CTRL``
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Nevertheless, the actual chips consist only of the ``BUFGCTRL`` primitives,
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which are the most universal and can function as other clock buffer
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primitives from the Xilinx manual. Because of that, only one architecture model
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is required for VPR. The rest of the primitives is mapped to this general
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buffer during the techmapping process. The model of ``BUFGCTRL`` primitive used
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by VPR is called ``BUFGCTR_VPR`` (More information about the architecture
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modeling in VPR can be found in the `VTR FPGA Architecture Description`_).
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Support for particular primitive in VTR consist of two files:
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- Model XML (``xxx.model.xml``) - Contains general information about
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the module's input and output ports and their relations.
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- Physical Block XML (``xxx.pb_type.xml``) - Describes the actual layout of the
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primitive, with information about the timings, internal connections, etc.
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Below you can see the pb_type XML for ``BUFGCTRL_VPR`` primitive:
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.. code-block:: xml
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<!-- Model of BUFG group in BUFG_CLK_TOP/BOT -->
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<pb_type name="BLK-TL-BUFGCTRL" xmlns:xi="https://www.w3.org/2001/XInclude">
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<output name="O" num_pins="1"/>
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<input name="CE0" num_pins="1"/>
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<input name="CE1" num_pins="1"/>
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<clock name="I0" num_pins="1"/>
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<clock name="I1" num_pins="1"/>
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<input name="IGNORE0" num_pins="1"/>
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<input name="IGNORE1" num_pins="1"/>
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<input name="S0" num_pins="1"/>
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<input name="S1" num_pins="1"/>
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<mode name="EMPTY">
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<pb_type name="empty" blif_model=".latch" num_pb="1" />
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<interconnect />
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</mode>
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<mode name="BUFGCTRL">
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<pb_type name="BUFGCTRL_VPR" blif_model=".subckt BUFGCTRL_VPR" num_pb="1">
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<output name="O" num_pins="1"/>
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<input name="CE0" num_pins="1"/>
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<input name="CE1" num_pins="1"/>
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<clock name="I0" num_pins="1"/>
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<clock name="I1" num_pins="1"/>
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<input name="IGNORE0" num_pins="1"/>
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<input name="IGNORE1" num_pins="1"/>
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<input name="S0" num_pins="1"/>
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<input name="S1" num_pins="1"/>
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<metadata>
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<meta name="fasm_params">
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ZPRESELECT_I0 = ZPRESELECT_I0
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ZPRESELECT_I1 = ZPRESELECT_I1
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IS_IGNORE0_INVERTED = IS_IGNORE0_INVERTED
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IS_IGNORE1_INVERTED = IS_IGNORE1_INVERTED
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ZINV_CE0 = ZINV_CE0
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ZINV_CE1 = ZINV_CE1
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ZINV_S0 = ZINV_S0
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ZINV_S1 = ZINV_S1
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</meta>
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</metadata>
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</pb_type>
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<interconnect>
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<direct name="O" input="BUFGCTRL_VPR.O" output="BLK-TL-BUFGCTRL.O"/>
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<direct name="CE0" input="BLK-TL-BUFGCTRL.CE0" output="BUFGCTRL_VPR.CE0"/>
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<direct name="CE1" input="BLK-TL-BUFGCTRL.CE1" output="BUFGCTRL_VPR.CE1"/>
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<direct name="I0" input="BLK-TL-BUFGCTRL.I0" output="BUFGCTRL_VPR.I0"/>
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<direct name="I1" input="BLK-TL-BUFGCTRL.I1" output="BUFGCTRL_VPR.I1"/>
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<direct name="IGNORE0" input="BLK-TL-BUFGCTRL.IGNORE0" output="BUFGCTRL_VPR.IGNORE0"/>
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<direct name="IGNORE1" input="BLK-TL-BUFGCTRL.IGNORE1" output="BUFGCTRL_VPR.IGNORE1"/>
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<direct name="S0" input="BLK-TL-BUFGCTRL.S0" output="BUFGCTRL_VPR.S0"/>
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<direct name="S1" input="BLK-TL-BUFGCTRL.S1" output="BUFGCTRL_VPR.S1"/>
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</interconnect>
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<metadata>
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<meta name="fasm_features">
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IN_USE
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</meta>
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</metadata>
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</mode>
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</pb_type>
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A correctly prepared techmap for any VPR model contains a declaration of
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the module that should be substituted. Inside the module declaration, one
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should provide a necessary logic and instantiate another module that
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will substitute its original version. Additionally, all equations within
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a techmap that are not used directly in a module instantiation should evaluate
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to a constant value. Therefore most of the techmaps use additional constant
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parameters to modify the signals attached to the instantiated module.
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Here is a piece of a techmap, which instructs Yosys to convert
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a ``BUFG`` primitive to the ``BUFGCTRL_VPR``. In this case, the techmaping process
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consists of two steps. Firstly, the techmap shows how to translate the ``BUFG``
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primitive to the ``BUFGCTRL``. Then how to translate the ``BUFGCTRL`` to
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the ``BUFGCTRL_VPR``:
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.. code-block:: verilog
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module BUFG (
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input I,
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output O
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);
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BUFGCTRL _TECHMAP_REPLACE_ (
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.O(O),
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.CE0(1'b1),
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.CE1(1'b0),
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.I0(I),
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.I1(1'b1),
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.IGNORE0(1'b0),
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.IGNORE1(1'b1),
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.S0(1'b1),
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.S1(1'b0)
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);
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endmodule
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module BUFGCTRL (
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output O,
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input I0, input I1,
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input S0, input S1,
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input CE0, input CE1,
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input IGNORE0, input IGNORE1
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);
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parameter [0:0] INIT_OUT = 1'b0;
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parameter [0:0] PRESELECT_I0 = 1'b0;
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parameter [0:0] PRESELECT_I1 = 1'b0;
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parameter [0:0] IS_IGNORE0_INVERTED = 1'b0;
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parameter [0:0] IS_IGNORE1_INVERTED = 1'b0;
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parameter [0:0] IS_CE0_INVERTED = 1'b0;
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parameter [0:0] IS_CE1_INVERTED = 1'b0;
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parameter [0:0] IS_S0_INVERTED = 1'b0;
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parameter [0:0] IS_S1_INVERTED = 1'b0;
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parameter _TECHMAP_CONSTMSK_IGNORE0_ = 0;
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parameter _TECHMAP_CONSTVAL_IGNORE0_ = 0;
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parameter _TECHMAP_CONSTMSK_IGNORE1_ = 0;
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parameter _TECHMAP_CONSTVAL_IGNORE1_ = 0;
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parameter _TECHMAP_CONSTMSK_CE0_ = 0;
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parameter _TECHMAP_CONSTVAL_CE0_ = 0;
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parameter _TECHMAP_CONSTMSK_CE1_ = 0;
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parameter _TECHMAP_CONSTVAL_CE1_ = 0;
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parameter _TECHMAP_CONSTMSK_S0_ = 0;
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parameter _TECHMAP_CONSTVAL_S0_ = 0;
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parameter _TECHMAP_CONSTMSK_S1_ = 0;
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parameter _TECHMAP_CONSTVAL_S1_ = 0;
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localparam [0:0] INV_IGNORE0 = (
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_TECHMAP_CONSTMSK_IGNORE0_ == 1 &&
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_TECHMAP_CONSTVAL_IGNORE0_ == 0 &&
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IS_IGNORE0_INVERTED == 0);
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localparam [0:0] INV_IGNORE1 = (
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_TECHMAP_CONSTMSK_IGNORE1_ == 1 &&
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_TECHMAP_CONSTVAL_IGNORE1_ == 0 &&
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IS_IGNORE1_INVERTED == 0);
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localparam [0:0] INV_CE0 = (
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_TECHMAP_CONSTMSK_CE0_ == 1 &&
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_TECHMAP_CONSTVAL_CE0_ == 0 &&
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|
IS_CE0_INVERTED == 0);
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localparam [0:0] INV_CE1 = (
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_TECHMAP_CONSTMSK_CE1_ == 1 &&
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_TECHMAP_CONSTVAL_CE1_ == 0 &&
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|
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|
IS_CE1_INVERTED == 0);
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localparam [0:0] INV_S0 = (
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_TECHMAP_CONSTMSK_S0_ == 1 &&
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_TECHMAP_CONSTVAL_S0_ == 0 &&
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|
|
|
|
IS_S0_INVERTED == 0);
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localparam [0:0] INV_S1 = (
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_TECHMAP_CONSTMSK_S1_ == 1 &&
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|
_TECHMAP_CONSTVAL_S1_ == 0 &&
|
|
|
|
|
IS_S1_INVERTED == 0);
|
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|
|
BUFGCTRL_VPR #(
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|
|
|
|
.INIT_OUT(INIT_OUT),
|
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|
|
.ZPRESELECT_I0(PRESELECT_I0),
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|
|
|
|
.ZPRESELECT_I1(PRESELECT_I1),
|
|
|
|
|
.IS_IGNORE0_INVERTED(!IS_IGNORE0_INVERTED ^ INV_IGNORE0),
|
|
|
|
|
.IS_IGNORE1_INVERTED(!IS_IGNORE1_INVERTED ^ INV_IGNORE1),
|
|
|
|
|
.ZINV_CE0(!IS_CE0_INVERTED ^ INV_CE0),
|
|
|
|
|
.ZINV_CE1(!IS_CE1_INVERTED ^ INV_CE1),
|
|
|
|
|
.ZINV_S0(!IS_S0_INVERTED ^ INV_S0),
|
|
|
|
|
.ZINV_S1(!IS_S1_INVERTED ^ INV_S1)
|
|
|
|
|
) _TECHMAP_REPLACE_ (
|
|
|
|
|
.O(O),
|
|
|
|
|
.CE0(CE0 ^ INV_CE0),
|
|
|
|
|
.CE1(CE1 ^ INV_CE1),
|
|
|
|
|
.I0(I0),
|
|
|
|
|
.I1(I1),
|
|
|
|
|
.IGNORE0(IGNORE0 ^ INV_IGNORE0),
|
|
|
|
|
.IGNORE1(IGNORE1 ^ INV_IGNORE1),
|
|
|
|
|
.S0(S0 ^ INV_S0),
|
|
|
|
|
.S1(S1 ^ INV_S1)
|
|
|
|
|
);
|
|
|
|
|
|
|
|
|
|
endmodule
|
|
|
|
|
|
|
|
|
|
.. note::
|
|
|
|
|
|
|
|
|
|
All F4PGA techmaps for Xilinx 7-Series devices use special inverter
|
|
|
|
|
logic that converts constant 0 signals at the BEL to constant-1 signals
|
|
|
|
|
at the site. This behavior is desired since VCC is the default signal in
|
|
|
|
|
7-Series and US/US+ devices. The presented solution matches the conventions
|
|
|
|
|
used by the vendor tools and gives the opportunity to validate generated
|
|
|
|
|
bitstreams with fasm2bels and Vivado.
|
|
|
|
|
|
|
|
|
|
Yosys provides special techmapping naming conventions for wires,
|
|
|
|
|
parameters, and modules. The special names that start with ``_TECHMAP_``
|
|
|
|
|
can be used to force certain behavior during the techmapping process.
|
|
|
|
|
Currently, the following special names are used in F4PGA techmaps:
|
|
|
|
|
|
|
|
|
|
- ``_TECHMAP_REPLACE_`` is used as a name for an instantiated module, which will
|
|
|
|
|
replace the one used in the original design. This special name causes
|
|
|
|
|
the instantiated module to inherit the name and all attributes
|
|
|
|
|
from the module that is being replaced.
|
|
|
|
|
|
|
|
|
|
- ``_TECHMAP_CONSTMSK_<port_name>_`` and ``_TECHMAP_CONSTVAL_<port_name>_``
|
|
|
|
|
are used together as names of parameters. The ``_TECHMAP_CONSTMASK_<port_name>_``
|
|
|
|
|
has a length of the input signal. Its bits take the value 1 if
|
|
|
|
|
the corresponding signal bit has a constant value, or 0 otherwise.
|
|
|
|
|
The ``_TECHMAP_CONSTVAL_<port_name>_`` bits store the actual constant signal
|
|
|
|
|
values when the ``_TECHMAP_CONSTMASK_<port_name>_`` is equal to 1.
|
|
|
|
|
|
|
|
|
|
More information about special wire, parameter, and module names can be found in
|
|
|
|
|
`techmap section in the Yosys Manual`_.
|
|
|
|
|
|
|
|
|
|
.. note::
|
|
|
|
|
|
|
|
|
|
Techmapping can be used not only to change the names of the primitives
|
|
|
|
|
but primarily to match the port declarations and express the logic behind
|
|
|
|
|
the primitive substitution:
|
|
|
|
|
|
|
|
|
|
.. verilog:module:: module BUFG (output O, input I)
|
|
|
|
|
|
|
|
|
|
.. verilog:module:: module BUFGCTRL (output O, input CE0, input CE1, input I0, input I1, input IGNORE0, input IGNORE1, input S0, input S1)
|
|
|
|
|
|
|
|
|
|
More information
|
|
|
|
|
----------------
|
|
|
|
|
|
|
|
|
|
Additional information about Yosys can be found on the `Yosys Project Website
|
2022-04-05 07:21:12 -04:00
|
|
|
|
<https://yosyshq.net/yosys/>`_ , or in `Yosys Manual
|
2022-04-05 07:32:19 -04:00
|
|
|
|
<https://yosyshq.net/yosys/files/yosys_manual.pdf>`_. You can also compile
|
2022-03-15 18:09:50 -04:00
|
|
|
|
one of the tests described in Getting Started section and watch the log file
|
|
|
|
|
to understand which operations are performed by Yosys.
|
|
|
|
|
|
2022-03-10 04:46:21 -05:00
|
|
|
|
Place & Route
|
2022-03-15 18:09:50 -04:00
|
|
|
|
*************
|
2022-03-10 04:46:21 -05:00
|
|
|
|
|
|
|
|
|
The F4PGA Project uses two different tools for the PnR process - ``nextpnr`` and ``Versatile Place and Route`` (VPR).
|
|
|
|
|
Both of them write their final result to a file in the ``.fasm`` format.
|
2022-03-15 18:09:50 -04:00
|
|
|
|
|
|
|
|
|
VPR
|
|
|
|
|
===
|
|
|
|
|
|
|
|
|
|
See `VPR ➚ <https://docs.verilogtorouting.org/en/latest/vpr/>`__.
|
|
|
|
|
|
|
|
|
|
nextpnr
|
|
|
|
|
=======
|
|
|
|
|
|
|
|
|
|
See :gh:`nextpnr ➚ <f4pga/nextpnr>`.
|