Whisper is a RISCV instruction set simulator (ISS) developed for the verification of the Swerv micro-controller. It allows the user to run RISCV code without RISCV hardware. It has an interactive mode where the user can single step the target RISCV code and inspect/modify the RISCV registers or the simulated system memory. It can also run in lock step with a Verilog simulator serving as a "golden model" against which an implementation is checked after each instruction of a test program.
To use Whisper, you would need to download its source code, compile it, prepare some target test program, compile the test program to RISCV binary code and then run the RISCV binary within the Whisper simulator. In particular you would need:
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A Linux machine to host the RISCV tool-chain and Whisper.
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The RISCV tool-chain which contains a cross-compiler to compile C/C++ code to RISCV binary. This can be installed on most Linux distributions using your distros pacakge manager (apt, dnf, pacman etc.). Otherwise it can be built from the upstream source code.
Ubuntu
$ sudo apt install gcc-riscv64-unknown-elf
Arch
$ sudo pacman -Syu riscv64-elf-gcc
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The Whisper source code which can be downloaded from github.
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The g++ compiler version 7.2 or higher to compiler Whisper. The g++ compiler can be installed from a Linux distribution. Alternatively, the source code can be downloaded from gnu.org/software/gcc.
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The boost library version 1.67 of higher compiled with c++-14 or c++-17. Boost source can be downloaded from boost.org.
On a Unix system, in the whisper directory, do the following: make BOOST_DIR=x where x is the path to your boost library installation.
Standalone C/assembly programs not requiring operating system support (such programs cannot do any I/O) should be compiled as follows:
$ riscv32-unknown-elf-gcc -mabi=ilp32 -march=rv32imc -static -O3 -nostdlib -o test1 test1.c
The key switch in the above compilation command is "-nostdlib" which prevents the compiler from linking-in the standard C library.
Note that without the standard C library, there is no "_start" symbol. The linker will complain that the start symbol is missing and will use another symbol as the default start address of the program. The user can always override that start address (program counter at the beginning of the simulation) by using the --startpc command line option.
Also note that without an operating system, the simulator does not know when the program finishes. It will execute instructions indefinitely. Consider the following test program:
int
main(int argc, char* argv[])
{
int x = 1;
int y = 2;
int z = x + y;
return z;
}
The simulator will start execution at the ELF file entry point (address corresponding to main) and will return to address 0 (initial value of return address register) when the instruction corresponding to "return z" is executed. This will most likely cause an illegal instruction exception and given that no trap handlers are loaded into the memory, it will cause an infinite loop of illegal traps. To avoid this, simple stand-alone no-operating-system programs should define a global 32-bit integer named "tohost" and should write to that location at the end of the program. This signals the simulator to terminate the program.
Here's a modified version of the above program that stops once main is done:
#include <stdint.h>
volatile uint32_t tohost = 0;
int
main(int argc, char* argv[])
{
int x = 1;
int y = 2;
int z = x + y;
return z;
}
void _start()
{
main(0, 0);
tohost = 1;
}
And here's how to compile and run the above program
$ riscv32-unknown-elf-gcc -mabi=ilp32 -march=rv32imc -nostdlib -g -o test2 test2.c
$ whisper test2
If no global variable named "tohost" is written by the program, the simulator will stop on its own if a sequence of 64 consecutive illegal instructions is encountered.
For programs requiring minimal operating system support (e.g. brk, open, read and write) the user can compile with the newlib C library and use the simulator with the "--newlib" option.
Here's a sample program:
#include <stdio.h>
int
main(int argc, char* argv[])
{
printf("hello world\n");
return 0;
}
And here's how to compile and run it (assuming riscv32-unknown-elf-gcc was compiled with newlib):
$ riscv32-unknown-elf-gcc -mabi=ilp32 -march=rv32imc -static -O3 -o test3 test3.c
$ whisper --newlib test3
Note that in this case the simulator will intercept the exit system call invoked by the C library code and terminate the program accordingly. There is no need for the "tohost" mechanism.
Running whisper with -h or --help will print a brief description of all the command line options. To run a RISCV program, prog, in whisper, one would issue the Linux command:
whisper prog
which will run the program until it writes to the "tohost" location.
A program compiled with the newlib C library need not have a "tohost" location. Such a program will run until it calls exit. Such a program would be run as follows:
whisper --newlib prog
The following is a brief description of the command line options:
--help
Produce help message.
--log
Enable tracing to standard output of executed instructions.
--xlen len
Specify register width (32 or 64), defaults to 32.
--isa string
Select the RISCV options to enable. The currently supported options are
a (atomic), c (compressed instructions), d (double precision fp),
f (single precision fp), i (base integer), m (multiply divide),
s (supervisor mode), and u (user mode). By default, only i, m and c
are enabled. Note that option i cannot be turned off. Example: --isa imcf
--target program
Specify target program (ELF file) to load into simulated memory. In newlib
emulations mode, program options may follow program name.
--hex file
Hexadecimal file to load into simulator memory.
--logfile file
Enable tracing to given file of executed instructions.
--consoleoutfile file
Redirect console output to given file.
--commandlog file
Enable logging of interactive/socket commands to the given file.
--startpc address
Set program entry point to the given address (in hex notation with a 0x prefix).
If not specified, use the ELF file entry point.
--endpc address
Set stop program counter to the given address (in hex notation with a 0x
prefix). Simulator will stop once instruction at the stop program counter
is executed. If not specified, use the ELF file _finish symbol.
--tohost address
Memory address to which a write stops the simulator (in hex with 0x prefix).
--consoleio address
Memory address corresponding to console io (in hex with 0x prefix).
Reading/writing a byte (using lb/sb instruction) from given address
reads/writes a byte from the console.
--maxinst limit
Limit executed instruction count to given number.
--interactive
After loading any target file into memory, the simulator enters interactive
mode.
--triggers
Enable debug triggers (triggers are automatically enabled in interactive and
server modes).
--counters
Enable performance counters.
--gdb
Run in gdb mode enabling remote debugging from gdb.
--profileinst file
Report executed instruction frequencies to the given file.
--setreg spec ...
Initialize registers. Example --setreg x1=4 x2=0xff
--disass code ...
Disassemble instruction code(s). Example --disass 0x93 0x33
--configfile file
Configuration file (JSON file defining system features).
--snapshotdir path
Directory prefix for saving snapshots: Snapshots (see --sanpshotpreid)
are placed in sub-directories of the given path. Default: "snapshot".
--snapshotperiod n
Snapshot period: Save a snapshot every n instructions putting data in
directory specified by --snapshotdir.
--loadfrom path
Snapshot directory from which to restore a previously saved (snapshot)
state.
--newlib
Emulate limited emulation of newlib system calls. Done automatically
if newlib symbols are detected in the target ELF file.
--linux
Emulate limited emulation of Linux system calls. Done automatically
if Linux symbols are detected in the target ELF file.
--raw
Bare metal mode: Disable emulation of Linux/newlib system call emulation
even if Linux/newlib symbols detected in the target ELF file.
--stdout path
Redirect the standard output of the newlib/Linux target program to the
file specified by the given path.
--stderr path
Redirect the standard error of the newlib/Linux target program to the
file specified by the given path.
--alarm period
External interrupt period in micro-seconds: Convert period to an instruction
count, n, assuming a 1ghz clock, and set to 1 the timer bit of the MIP
CSR every n instructions. The timer bit of MIP is automatically cleared if
the interrupt is actually taken (interrupts enabled in MSTATUS and timer
bit set in MIE CSR). No-op if n is zero.
--abinames
Use ABI register names (e.g. sp instead of x2) in instruction disassembly.
--verbose
Produce additional messages.
--version
Print version.
Whisper is started in interactive mode using the "--interactive" command line option. Here's are some examples:
$ whisper --interactive
$ whisper --interactive test1
In the second example, the program test1 is first loaded into the simulated memory. In interactive mode the user can issue commands to control the execution of the target program and to set/examine the registers and memory location of the simulated system. The help command will produce a list of all available interactive commands. The "help x" command will produce information about command x.
Here's the output of the "help" command:
help [<command>]
Print help for given command or for all commands if no command given.
run
Run till interrupted.
until <address>
Run until address or interrupted.
step [<n>]
Execute n instructions (1 if n is missing).
peek <res> <addr>
Print value of resource res (one of r, f, c, m) and address addr.
For memory (m) up to 2 addresses may be provided to define a range
of memory locations to be printed.
examples: peek r x1 peek c mtval peek m 0x4096
peek pc
Print value of the program counter.
peek all
Print value of all non-memory resources.
poke res addr value
Set value of resource res (one of r, c or m) and address addr.
Examples: poke r x1 0xff poke c 0x4096 0xabcd
disass opcode <code> <code> ...
Disassemble opcodes. Example: disass opcode 0x3b 0x8082
disass function <name>
Disassemble function with given name. Example: disass func main
disass <addr1> <addr2>>
Disassemble memory locations between addr1 and addr2.
elf file
Load elf file into simulated memory.
hex file
Load hex file into simulated memory.
replay_file file
Open command file for replay.
replay n
Execute the next n commands in the replay file or all the
remaining commands if n is missing.
replay step n
Execute consecutive commands from the replay file until n
step commands are executed or the file is exhausted.
reset [<reset_pc>]
Reset hart. If reset_pc is given, then change the reset program
counter to the given reset_pc before resetting the hart.
quit
Terminate the simulator.
Whisper will emulate the newlib open, close, read, write, brk and exit system calls. This allows simple programs to run and use the newlib C-library functions such as printf, fopen, fread, fwrite, fclose, malloc, free and exit. Here an example of running a program with limited C-library support:
$ whisper --newlib test3
And here is an example of passing the command line arguments arg1 and arg2 to the to the target program test3:
$ whisper --newlib "test3 arg1 arg2"
And examples of passing command line switches to a target program that requires them:
$ whisper --newlib "test4 -opt1 val1 -opt2"
$ whisper --newlib --target "test4 -opt1 val1 -opt2"
With the --gdb option, whisper will follow the gdb remote debugging protocol. This allows the user to debug a RISCV program using a cross-compiled gdb and whisper. For example, to debug a RISCV program named xyz on a Linux x86 machine, we would start the (cross-compiled) RISCV gdb as follows:
$ riscv-unknown-elf-gdb xyz
at the gdb prompt, we would connect to whisper by issuing a "target remote" gdb command as follows:
target remote | whisper --gdb xyz
The MISA register is read only. It is not possible to change XLEN at run time by writing to the MISA register.
The "round to nearest break tie to max magnitude" rounding mode is not implemented unless you compile with the softfloat library: "make SOFT_FLOAT=1" in which case simulation of floating point instructions slows down significantly.
Only extensions A, C, D, F, I, M, S and U are supported.