Crate fuel_asm[−][src]
Expand description
FuelVM opcodes representation
Fuel ASM
Instruction set for the FuelVM.
Compile features
std
: Unless set, the crate will link to the core-crate instead of the std-crate. More info here.serde-types
: Add support for serde for the types exposed by this crate.serde-types-minimal
: Add support forno-std
serde for the types exposed by this crate.
Example
use fuel_asm::*;
use Opcode::*;
// A sample program to perform ecrecover
let program = vec![
MOVE(0x10, 0x01), // set r[0x10] := $one
SLLI(0x20, 0x10, 5), // set r[0x20] := `r[0x10] << 5 == 32`
SLLI(0x21, 0x10, 6), // set r[0x21] := `r[0x10] << 6 == 64`
ALOC(0x21), // alloc `r[0x21] == 64` to the heap
ADDI(0x10, 0x07, 1), // set r[0x10] := `$hp + 1` (allocated heap)
MOVE(0x11, 0x04), // set r[0x11] := $ssp
ADD(0x12, 0x04, 0x20), // set r[0x12] := `$ssp + r[0x20]`
ECR(0x10, 0x11, 0x12), // recover public key in memory[r[0x10], 64]
RET(0x01), // return `1`
];
// Convert program to bytes representation
let bytes: Vec<u8> = program.iter().copied().collect();
// A program can be reconstructed from an iterator of bytes
let restored = Opcode::from_bytes_iter(bytes.iter().copied());
assert_eq!(program, restored);
// Every instruction can be described as `u32` big-endian bytes
let halfwords: Vec<u32> = program.iter().copied().map(u32::from).collect();
let bytes = halfwords.iter().copied().map(u32::to_be_bytes).flatten();
let restored = Opcode::from_bytes_iter(bytes);
assert_eq!(program, restored);
// We can also reconstruct the instructions individually
let restored: Vec<Opcode> = halfwords.iter().copied().map(Opcode::from).collect();
assert_eq!(program, restored);
// We have an unchecked variant for optimal performance
let restored: Vec<Opcode> = halfwords
.iter()
.copied()
.map(|w| unsafe { Opcode::from_bytes_unchecked(&w.to_be_bytes()) })
.collect();
assert_eq!(program, restored);
// Finally, we have [`Instruction`] to allow optimal runtime parsing of the components of the
// opcode
//
// `Opcode` itself is only but an abstraction/helper to facilitate visualization, but the VM is
// expected to use raw instructions
let instrs: Vec<Instruction> = program.iter().copied().map(Instruction::from).collect();
let restored: Vec<Opcode> = instrs.iter().copied().map(Opcode::from).collect();
assert_eq!(program, restored);
// An instruction is composed by the opcode representation registers Id and immediate values
assert_eq!(instrs[1].op(), OpcodeRepr::SLLI as u8);
assert_eq!(instrs[1].ra(), 0x20);
assert_eq!(instrs[1].rb(), 0x10);
assert_eq!(instrs[1].imm12(), 5);
Structs
A version of Opcode that can used without unnecessary branching
Describe a panic reason with the instruction that generated it
Enums
Instruction representation for the interpreter.
Byte representation of an opcode
Panic reason representation for the interpreter.
Type Definitions
6-bits immediate value type
12-bits immediate value type
18-bits immediate value type
24-bits immediate value type
Register ID type
Register value type