tree: d8117d4ae2b14391e56e45b80a7e4a2fe4adc412 [path history] [tgz]
  1. .travisCI/
  2. checks/
  3. def/
  4. doc/
  5. gds/
  6. lef/
  7. macros/
  8. mag/
  9. maglef/
  10. ngspice/
  11. openlane/
  12. qflow/
  13. scripts/
  14. spi/
  15. utils/
  16. verilog/
  17. .travis.yml
  18. info.yaml
  19. LICENSE
  20. Makefile
  21. mpw-one-b.md
  22. README.md
README.md

Test Circuits for Stochastic Computation

This project contains test circuits for stochastic computation, namely the synthesizable comparators for a stochastic ADC, to be submitted for Google SKY130 open MPW shuttle on the Caravel SoC.

Build instructions (assuming Openlane, PDK, set up properly):

  1. From main caravel directory:
make uncompress
  1. From openlane directory:
make top_astria
make user_project_wrapper
  1. From main caravel directory:
make ship

(Optional if pushing repo):

make compress 

CIIC Harness

A template SoC for Google SKY130 free shuttles. It is still WIP. The current SoC architecture is given below.

Getting Started:

  • For information on tooling and versioning, please refer to this.

Start by cloning the repo and uncompressing the files.

git clone https://github.com/efabless/caravel.git
cd caravel
make uncompress

Then you need to install the open_pdks prerequisite:

* Note: You can avoid the need for the magic prerequisite by using the openlane docker to do the installation step in open_pdks. This could be done by cloning openlane and following the instructions given there to use the Makefile.

Install the required version of the PDK by running the following commands:

export PDK_ROOT=<The place where you want to install the pdk>
make pdk

Then, you can learn more about the caravel chip by watching these video:

Aboard Caravel:

Your area is the full user_project_wrapper, so feel free to add your project there or create a differnt macro and harden it seperately then insert it into the user_project_wrapper. For example, if your design is analog or you're using a different tool other than OpenLANE.

If you will use OpenLANE to harden your design, go through the instructions in this README.md.

You must copy your synthesized gate-level-netlist for user_project_wrapper to verilog/gl/ and overwrite user_project_wrapper.v. Otherwise, you can point to it in info.yaml.

Note: If you're using openlane to harden your design, this should happen automatically.

Then, you will need to put your design aboard the Caravel chip. Make sure you have the following:

  • Magic VLSI Layout Tool installed on your machine. We may provide a Dockerized version later.*
  • You have your user_project_wrapper.gds under ./gds/ in the Caravel directory.

* Note: You can avoid the need for the magic prerequisite by using the openlane docker to run the make step. This section shows how.

Run the following command:

export PDK_ROOT=<The place where the installed pdk resides. The same PDK_ROOT used in the pdk installation step>
make

This should merge the GDSes using magic and you'll end up with your version of ./gds/caravel.gds. You should expect ~90 magic DRC violations with the current “development” state of caravel.

Running Make using OpenLANE Magic

To use the magic installed inside Openlane to complete the final GDS streaming out step, export the following:

export PDK_ROOT=<The location where the pdk is installed>
export OPENLANE_ROOT=<the absolute path to the openlane directory cloned or to be cloned>
export IMAGE_NAME=<the openlane image name installed on your machine. Preferably openlane:rc6>
export CARAVEL_PATH=$(pwd)

Then, mount the docker:

docker run -it -v $CARAVEL_PATH:$CARAVEL_PATH -v $OPENLANE_ROOT:/openLANE_flow -v $PDK_ROOT:$PDK_ROOT -e CARAVEL_PATH=$CARAVEL_PATH -e PDK_ROOT=$PDK_ROOT -u $(id -u $USER):$(id -g $USER) $IMAGE_NAME

Finally, once inside the docker run the following commands:

cd $CARAVEL_PATH
make
exit

This should merge the GDSes using magic and you'll end up with your version of ./gds/caravel.gds. You should expect ~90 magic DRC violations with the current “development” state of caravel.

IMPORTANT:

Please make sure to run make compress before commiting anything to your repository. Avoid having 2 versions of the gds/user_project_wrapper.gds or gds/caravel.gds one compressed and the other not compressed.

Required Directory Structure

  • ./gds/ : includes all the gds files used or produced from the project.
  • ./def/ : includes all the def files used or produced from the project.
  • ./lef/ : includes all the lef files used or produced from the project.
  • ./mag/ : includes all the mag files used or produced from the project.
  • ./maglef/ : includes all the maglef files used or produced from the project.
  • ./spi/lvs/ : includes all the maglef files used or produced from the project.
  • ./verilog/dv/ : includes all the simulation test benches and how to run them.
  • ./verilog/gl/ : includes all the synthesized/elaborated netlists.
  • ./verilog/rtl/ : includes all the Verilog RTLs and source files.
  • ./openlane/<macro>/ : includes all configuration files used to run openlane on your project.
  • info.yaml: includes all the info required in this example. Please make sure that you are pointing to an elaborated caravel netlist as well as a synthesized gate-level-netlist for the user_project_wrapper

Managment SoC

The managment SoC runs firmware that can be used to:

  • Configure User Project I/O pads
  • Observe and control User Project signals (through on-chip logic analyzer probes)
  • Control the User Project power supply

The memory map of the management SoC can be found here

User Project Area

This is the user space. It has limited silicon area (TBD, about 3.1mm x 3.8mm) as well as a fixed number of I/O pads (37) and power pads (10). See the Caravel premliminary datasheet for details. The repository contains a sample user project that contains a binary 32-bit up counter.

The firmware running on the Management Area SoC, configures the I/O pads used by the counter and uses the logic probes to observe/control the counter. Three firmware examples are provided:

  1. Configure the User Project I/O pads as o/p. Observe the counter value in the testbench: IO_Ports Test.
  2. Configure the User Project I/O pads as o/p. Use the Chip LA to load the counter and observe the o/p till it reaches 500: LA_Test1.
  3. Configure the User Project I/O pads as o/p. Use the Chip LA to control the clock source and reset signals and observe the counter value for five clock cylcles: LA_Test2.