202 lines
8.6 KiB
Markdown
202 lines
8.6 KiB
Markdown
# EL2 SweRV RISC-V Core<sup>TM</sup> 1.2 from Western Digital
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This repository contains the SweRV EL2 Core<sup>TM</sup> design RTL
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## License
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By contributing to this project, you agree that your contribution is governed by [Apache-2.0](LICENSE).
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Files under the [tools](tools/) directory may be available under a different license. Please review individual file for details.
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## Directory Structure
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├── configs # Configurations Dir
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│ └── snapshots # Where generated configuration files are created
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├── design # Design root dir
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│ ├── dbg # Debugger
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│ ├── dec # Decode, Registers and Exceptions
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│ ├── dmi # DMI block
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│ ├── exu # EXU (ALU/MUL/DIV)
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│ ├── ifu # Fetch & Branch Prediction
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│ ├── include
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│ ├── lib
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│ └── lsu # Load/Store
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├── docs
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├── tools # Scripts/Makefiles
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└── testbench # (Very) simple testbench
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├── asm # Example assembly files
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└── hex # Canned demo hex files
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## Dependencies
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- Verilator **(4.020 or later)** must be installed on the system if running with verilator
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- If adding/removing instructions, espresso must be installed (used by *tools/coredecode*)
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- RISCV tool chain (based on gcc version 7.3 or higher) must be
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installed so that it can be used to prepare RISCV binaries to run.
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## Quickstart guide
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1. Clone the repository
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1. Setup RV_ROOT to point to the path in your local filesystem
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1. Determine your configuration {optional}
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1. Run make with tools/Makefile
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## Release Notes for this version
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Please see [release notes](release-notes.md) for changes and bug fixes in this version of SweRV
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### Configurations
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SweRV can be configured by running the `$RV_ROOT/configs/swerv.config` script:
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`% $RV_ROOT/configs/swerv.config -h` for detailed help options
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For example to build with a DCCM of size 64 Kb:
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`% $RV_ROOT/configs/swerv.config -dccm_size=64`
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This will update the **default** snapshot in $RV_ROOT/configs/snapshots/default/ with parameters for a 64K DCCM.
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Add `-snapshot=dccm64`, for example, if you wish to name your build snapshot *dccm64* and refer to it during the build.
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There are 4 predefined target configurations: `default`, `default_ahb`, `typical_pd` and `high_perf` that can be selected via
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the `-target=name` option to swerv.config.
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This script derives the following consistent set of include files :
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$RV_ROOT/configs/snapshots/default
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├── common_defines.vh # `defines for testbench or design
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├── defines.h # #defines for C/assembly headers
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├── el2_param.vh # Design parameters
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├── el2_pdef.vh # Parameter structure
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├── pd_defines.vh # `defines for physical design
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├── perl_configs.pl # Perl %configs hash for scripting
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├── pic_map_auto.h # PIC memory map based on configure size
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└── whisper.json # JSON file for swerv-iss
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### Building a model
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while in a work directory:
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1. Set the RV_ROOT environment variable to the root of the SweRV directory structure.
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Example for bash shell:
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`export RV_ROOT=/path/to/swerv`
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Example for csh or its derivatives:
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`setenv RV_ROOT /path/to/swerv`
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1. Create your specific configuration
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*(Skip if default is sufficient)*
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*(Name your snapshot to distinguish it from the default. Without an explicit name, it will update/override the __default__ snapshot)*
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For example if `mybuild` is the name for the snapshot:
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set BUILD_PATH environment variable:
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`setenv BUILD_PATH snapshots/mybuild`
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`$RV_ROOT/configs/swerv.config [configuration options..] -snapshot=mybuild`
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Snapshots are placed in `$BUILD_PATH` directory
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1. Running a simple Hello World program (verilator)
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`make -f $RV_ROOT/tools/Makefile`
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This command will build a verilator model of SweRV EL2 with AXI bus, and
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execute a short sequence of instructions that writes out "HELLO WORLD"
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to the bus.
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The simulation produces output on the screen like:
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```
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VerilatorTB: Start of sim
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----------------------------------
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Hello World from SweRV EL2 @WDC !!
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----------------------------------
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TEST_PASSED
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Finished : minstret = 437, mcycle = 922
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See "exec.log" for execution trace with register updates..
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```
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The simulation generates following files:
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`console.log` contains what the cpu writes to the console address of 0xd0580000.
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`exec.log` shows instruction trace with GPR updates.
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`trace_port.csv` contains a log of the trace port.
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When `debug=1` is provided, a vcd file `sim.vcd` is created and can be browsed by
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gtkwave or similar waveform viewers.
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You can re-execute simulation using:
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` ./obj_dir/Vtb_top `
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or
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`make -f $RV_ROOT/tools/Makefile verilator`
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The simulation run/build command has following generic form:
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make -f $RV_ROOT/tools/Makefile [<simulator>] [debug=1] [snapshot=mybuild] [target=<target>] [TEST=<test>] [TEST_DIR=<path_to_test_dir>]
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where:
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```
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<simulator> - can be 'verilator' (by default) 'irun' - Cadence xrun, 'vcs' - Synopsys VCS, 'vlog' Mentor Questa
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if not provided, 'make' cleans work directory, builds verilator executable and runs a test.
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debug=1 - allows VCD generation for verilator and VCS and SHM waves for irun option.
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<target> - predefined CPU configurations 'default' ( by default), 'default_ahb', 'typical_pd', 'high_perf'
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TEST - allows to run a C (<test>.c) or assembly (<test>.s) test, hello_world is run by default
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TEST_DIR - alternative to test source directory testbench/asm
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<snapshot> - run and build executable model of custom CPU configuration, remember to provide 'snapshot' argument
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for runs on custom configurations.
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```
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Example:
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make -f $RV_ROOT/tools/Makefile verilator TEST=cmark
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will simulate testbench/asm/cmark.c program with verilator
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If you want to compile a test only, you can run:
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make -f $RV_ROOT/tools/Makefile program.hex TEST=<test> [TEST_DIR=/path/to/dir]
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The Makefile uses `$RV_ROOT/testbench/link.ld` file by default to build test executable.
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User can provide test specific linker file in form `<test_name>.ld` to build the test executable,
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in the same directory with the test source.
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User also can create a test specific makefile in form `<test_name>.makefile`, containing building instructions
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how to create `program.hex` and `data.hex` files used by simulation. The private makefile should be in the same directory
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as the test source.
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*(`program.hex` file is loaded to instruction bus memory slave and `data.hex` file is loaded to LSU bus memory slave and
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optionally to DCCM at the beginning of simulation)*.
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Note: You may need to delete `program.hex` file from work directory, when run a new test.
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The `$RV_ROOT/testbench/asm` directory contains following tests ready to simulate:
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```
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hello_world - default tes to run, prints Hello World message to screen and console.log
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hello_world_dccm - the same as above, but takes the string from preloaded DCCM.
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hello_world_iccm - the same as hello_world, but loads the test code to ICCM via LSU to DMA bridge and then executes
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it from there. Runs on EL2 with AXI4 buses only.
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cmark - coremark benchmark running with code and data in external memories
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cmark_dccm - the same as above, running data and stack from DCCM (faster)
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cmark_iccm - the same as above with preloaded code to ICCM.
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```
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The `$RV_ROOT/testbench/hex` directory contains precompiled hex files of the tests, ready for simulation in case RISCV SW tools are not installed.
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**Note**: The testbench has a simple synthesizable bridge that allows you to load the ICCM via load/store instructions. This is only supported for AXI4 builds.
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**Building an FPGA speed optimized model:**
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Use ``-set=fpga_optimize=1`` option to ``swerv.config`` to build a model that is removes clock gating logic from flop model so that the FPGA builds can run a higher speeds.
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----
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Western Digital, the Western Digital logo, G-Technology, SanDisk, Tegile, Upthere, WD, SweRV Core, SweRV ISS,
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and OmniXtend are registered trademarks or trademarks of Western Digital Corporation or its affiliates in the US
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and/or other countries. All other marks are the property of their respective owners.
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