# Links

* <https://bugs.libre-soc.org/show_bug.cgi?id=758>
* [Pypowersim](https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=src/openpower/decoder/isa/pypowersim.py)
* [Media directory](https://git.libre-soc.org/?p=openpower-isa.git;a=tree;f=media;hb=HEAD)
* [MP3 test directory](https://git.libre-soc.org/?p=openpower-isa.git;a=tree;f=media/audio/mp3;hb=HEAD)
* [Machine-readable executable Power ISA 3.0 pseudocode](https://git.libre-soc.org/?p=openpower-isa.git;a=tree;f=openpower/isa;hb=HEAD)

# Prerequisite installation

pypowersim is part of the
[openpower-isa](https://git.libre-soc.org/?p=openpower-isa.git;a=summary)
repository.  It is easiest installed with the [[HDL_workflow/devscripts]].

*Note: installation time without following the scripts has typically taken
new users 2-3 weeks. After much pain and failure, when they then follow the
advice given (formerly ignored), they find it takes under 1 day*.

# Pypowersim Guide

These are multimedia tests intended to cover the inner loops of various
Audio/Video CODECs (such as MP3) and this guide uses them as examples
to demonstrate pypowersim's functionality.  Other examples also exist:

* [basic scalar integer](https://git.libre-soc.org/?p=openpower-isa.git;a=tree;f=src/test/basic_pypowersim;hb=HEAD)
* [basic scalar FP](https://git.libre-soc.org/?p=openpower-isa.git;a=tree;f=src/test/basic_pypowersim_fp;hb=HEAD)

**Note 1:** This is a bare-metal simulator.
There's no GUI, UART, or console. To check that the tests ran
succesfully, you need to dump the memory contents and inspect the output.

**Note 2:** pypowersim is designed for ease-of-understanding of the Power
ISA and as a tool to check that the Power ISA Specification itself is
correct. For example, a python class
[SelectableInt](https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=src/openpower/decoder/selectable_int.py;hb=HEAD)
has been created which understands IBM MSB0 ordering. Even
a RADIX MMU has been implemented, 100% in python using IBM-sponsored
[gem5-experimental](https://github.com/power-gem5/gem5/blob/gem5-experimental/src/arch/power/radixwalk.cc) work as a guide.  This
*deliberate and conscious* design choice to focus on readability
and understanding makes pypowersim extremely slow: an Intel i9 running
at 4.8 ghz is only capable of 2,500 instructions per second.

# Pypowersim - PowerISA Simulator

Pypowersim is a PowerISA simulator written in Python. It includes
the **exact** same
[RADIX MMU](https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=src/openpower/decoder/isa/radixmmu.py;hb=HEAD)
support as
[Microwatt](https://github.com/antonblanchard/microwatt/blob/master/mmu.vhdl).
PowerISA binaries are decoded by an
[ISA class instance](https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=src/openpower/decoder/isa/caller.py;hb=HEAD).
ISACaller utilises compiled machine-readable Power ISA 3.0
pseudocode taken directly from the Power ISA Specification.

SVP64 binaries are also supported. Simulation is managed cycle by cycle,
for instruction and memory debugging.
Use of QEMU as a co-simulator is also supported for verifying the
binaries run identically.

To find out about input arg information, run the script with "-h/--help"
or no arguments to get the help message:

```
$ python3 openpower-isa/src/openpower/decoder/isa/pypowersim.py
```

# Tests


The tests consist of running Pypowersim with several input arg's:

* ".gpr" text file for initialising the General Purpose (integer) Registers
* ".spr" text file for initialising the Special Purpose Registers
* Initialising the Program Counter
* Loading given binaries into specified memory locations
* Select which memory regions to dump to a file
* Select the executable to run

There are other options available (such as initialising the Floating Point
Registers).
for 

**Example GPR file**:

See <https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=media/audio/mp3/mp3_0.gpr;hb=HEAD>

This file sets the GPRs to explicit values prior to execution.
This allows for example a function call's parameters, according
to Power ISA
[ABI calling convention](https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=media/calling-conv;hb=HEAD),
to be set conveniently and quickly, but
more importantly without requiring execution of additional
instructions.

In this example below the parameters point to areas of memory
that are loaded or dumped, containing the input and output areas
of the function.  They match up with the other parameters to the
example script

```
   1 # void ff_mpadsp_apply_window_float(float *synth_buf, float *window,
   2 #                                  int *dither_state, float *samples,
   3 #                                  ptrdiff_t incr);
   4 1: 0x8000        # stack pointer
   5 3: 0x600000      # param 1: float *sunth_buf     buf
   6 4: 0x700000      # param 2: float *window        win
   7 5: 0x800000      # param 3: int *dither_state    &unused
   8 6: 0x900000      # param 3: float *samples       out
   9 7: 1             # param 5: ptr_diff_t incr      1
```

**Example SPR file**

See <https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=media/common.spr;hb=HEAD>

This file sets SPRs to explicit values prior to execution. In this
example Link Register LR is set to 0xffffffff which on completion
of the function sets PC to an invalid out-of-bounds value causing
program termination.

```
  1 LR: 0xffffffff
```

**Example Execution**

See <https://git.libre-soc.org/?p=openpower-isa.git;a=blob;f=media/audio/mp3/mp3_0.sh;hb=HEAD>

The GPRs and SPRs above are loaded prior to execution, as is the
sample data (at appropriate addresses matching the function parameters).
After execution 128 bytes are dumped from address 0x900000.

```
   1 #!/bin/sh -xe
   2 
   3 pypowersim -g audio/mp3/mp3_0.gpr \
   4         -s common.spr \
   5         -p 0x20000000 \
   6         -l data/audio/mp3/mp3_0_data/buf${1}:0x600000 \
   7         -l data/audio/mp3/mp3_0_data/win0:0x700000 \
   8         -d ${2}:0x900000:128 \
   9         -i audio/mp3/mp3_0_apply_window_float.bin
```

# Before running the media tests

During development, the available opcodes may change.
Make sure to update the auto-generated Python functions
simulating the instructions. Also the audio data needs to be downloaded.

* run "pywriter". This is an installed utility, so should be in your PATH.
  It recompiles the machine-readable Power ISA pseudocode into
  executable python.
* Download audio data. Use the Makefile inside "openpower-isa/media" to 
 download the audio samples.

```
$ pywriter
$ make wget
```

# Running both tests

Run the Makefile in the "openpower-isa/media" directory with "tests" arg:

```
$ make tests
```

All the debug will go to standard output, so you may wish to direct it to a
log file (the file will be **big**!).

To suppress verbose debug log, uncomment "#export SILENCELOG = 1" in the
Makefile or export it manually.

# Running "mp3_x" tests individually

Inside "openpower-isa/media" directory run:

```
$ ./audio/mp3/mp3_0.sh 0 out0
```

The "out0" file will be created in the "media" directory. Change the name
if you don't want the second test to overwrite the results of the first. 

# Checking results

If you run both tests through the makefile, the shell script
automatically compares the input "sample0" file with the
generated "out0" file.

For manual checking, you need to know where the "out" file is, and then
use the "cmp" program to compare byte by byte the sample and output
files.

```
$ cmp out0 data/audio/mp3/mp3_0_data/samples0
```

As is usual for UNIX commands no output indicates the files are identical.