| --- |
| # TinyTapeout project information |
| project: |
| wokwi_id: 350008746567533140 # If using wokwi, set this to your project's ID |
| # source_files: # If using an HDL, set wokwi_id as 0 and uncomment and list your source files here |
| # - verilog/rtl/counter.v |
| # - verilog/rtl/decoder.v |
| # top_module: "seven_segment_seconds" # put the name of your top module here, make it unique by prepending your github username |
| |
| # As everyone will have access to all designs, try to make it easy for someone new to your design to know what |
| # it does and how to operate it. |
| # |
| # Here is an example: https://github.com/mattvenn/tinytapeout_m_segments/blob/main/info.yaml |
| # |
| # This info will be automatically collected and used to make a datasheet for the chip. |
| documentation: |
| author: "saicharan0112" # Your name |
| discord: "" # Your discord handle - make sure to include the # part as well |
| title: "reversible_programmable_logic_ic" # Project title |
| description: "Quad 3-input Fredkin gate which can be programmed into the 3 basic logic gates - AND, OR and NOT whose outputs are reversible" # Short description of what your project does |
| how_it_works: "Refer to datasheet.md inside saicharan0112/reversible_programmable_logic_ic repo" # Longer description of how the project works |
| how_to_test: "" # Instructions on how someone could test your project, include things like what buttons do what and how to set the clock if needed |
| external_hw: "" # Describe any external hardware needed |
| language: "wokwi" # other examples include Verilog, Amaranth, VHDL, etc |
| doc_link: "Refer to datasheet.md inside saicharan0112/reversible_programmable_logic_ic repo" # URL to longer form documentation, eg the README.md in your repository |
| clock_hz: 0 # Clock frequency in Hz (if required) we are expecting max clock frequency to be ~6khz. Provided on input 0. |
| picture: "" # relative path to a picture in your repository |
| inputs: # a description of what the inputs do |
| - in0 [input A to the first Fredkin gate] |
| - in1 [input B to the first Fredkin gate] |
| - in2 [input C to the first Fredkin gate] |
| - in3 [input A to the second Fredkin gate] |
| - in4 [input B to the second Fredkin gate] |
| - in5 [input C to the second Fredkin gate] |
| - in6 [input A to the third Fredkin gate] |
| - in7 [input B to the third Fredkin gate] |
| - in8 [input C to the third Fredkin gate] |
| - in9 [input A to the fourth Fredkin gate] |
| - in10 [input B to the fourth Fredkin gate] |
| - in11 [input C to the fourth Fredkin gate] |
| outputs: # a description of what the outputs do |
| - out0 [output X to the first Fredkin gate] |
| - out1 [output Y to the first Fredkin gate] |
| - out2 [output Z to the first Fredkin gate] |
| - out3 [output X to the second Fredkin gate] |
| - out4 [output Y to the second Fredkin gate] |
| - out5 [output Z to the second Fredkin gate] |
| - out6 [output X to the third Fredkin gate] |
| - out7 [output Y to the third Fredkin gate] |
| - out8 [output Z to the third Fredkin gate] |
| - out9 [output X to the fourth Fredkin gate] |
| - out10 [output Y to the fourth Fredkin gate] |
| - out11 [output Z to the fourth Fredkin gate] |
| |
