use crate::BPFError; use solana_rbpf::ebpf; use thiserror::Error; #[derive(Debug, Error)] pub enum VerifierError { #[error("program length must be a multiple of {} octets", ebpf::INSN_SIZE)] ProgramLengthNotMultiple, #[error("program too big, max {}, is {}", ebpf::PROG_MAX_INSNS, .0)] ProgramTooLarge(usize), #[error("no program set, call prog_set() to load one")] NoProgram, #[error("division by 0 (insn #{0})")] DivisionByZero(usize), #[error("unsupported argument for LE/BE (insn #{0})")] UnsupportedLEBEArgument(usize), #[error("LD_DW instruction cannot be last in program")] LDDWCannotBeLast, #[error("incomplete LD_DW instruction (insn #{0})")] IncompleteLDDW(usize), #[error("infinite loop (insn #{0})")] InfiniteLoop(usize), #[error("jump out of code to #{0} (insn #{1})")] JumpOutOfCode(usize, usize), #[error("jump to middle of LD_DW at #{0} (insn #{1})")] JumpToMiddleOfLDDW(usize, usize), #[error("invalid source register (insn #{0})")] InvalidSourceRegister(usize), #[error("cannot write into register r10 (insn #{0})")] CannotWriteR10(usize), #[error("invalid destination register (insn #{0})")] InvalidDestinationRegister(usize), #[error("unknown eBPF opcode {0:#2x} (insn #{1:?})")] UnknownOpCode(u8, usize), } fn check_prog_len(prog: &[u8]) -> Result<(), BPFError> { if prog.len() % ebpf::INSN_SIZE != 0 { return Err(VerifierError::ProgramLengthNotMultiple.into()); } if prog.len() > ebpf::PROG_MAX_SIZE { return Err(VerifierError::ProgramTooLarge(prog.len() / ebpf::INSN_SIZE).into()); } if prog.is_empty() { return Err(VerifierError::NoProgram.into()); } Ok(()) } fn check_imm_nonzero(insn: &ebpf::Insn, insn_ptr: usize) -> Result<(), BPFError> { if insn.imm == 0 { return Err(VerifierError::DivisionByZero(insn_ptr).into()); } Ok(()) } fn check_imm_endian(insn: &ebpf::Insn, insn_ptr: usize) -> Result<(), BPFError> { match insn.imm { 16 | 32 | 64 => Ok(()), _ => Err(VerifierError::UnsupportedLEBEArgument(insn_ptr).into()), } } fn check_load_dw(prog: &[u8], insn_ptr: usize) -> Result<(), BPFError> { if insn_ptr >= (prog.len() / ebpf::INSN_SIZE) { // Last instruction cannot be LD_DW because there would be no 2nd DW return Err(VerifierError::LDDWCannotBeLast.into()); } let next_insn = ebpf::get_insn(prog, insn_ptr + 1); if next_insn.opc != 0 { return Err(VerifierError::IncompleteLDDW(insn_ptr).into()); } Ok(()) } fn check_jmp_offset(prog: &[u8], insn_ptr: usize) -> Result<(), BPFError> { let insn = ebpf::get_insn(prog, insn_ptr); if insn.off == -1 { return Err(VerifierError::InfiniteLoop(insn_ptr).into()); } let dst_insn_ptr = insn_ptr as isize + 1 + insn.off as isize; if dst_insn_ptr < 0 || dst_insn_ptr as usize >= (prog.len() / ebpf::INSN_SIZE) { return Err(VerifierError::JumpOutOfCode(dst_insn_ptr as usize, insn_ptr).into()); } let dst_insn = ebpf::get_insn(prog, dst_insn_ptr as usize); if dst_insn.opc == 0 { return Err(VerifierError::JumpToMiddleOfLDDW(dst_insn_ptr as usize, insn_ptr).into()); } Ok(()) } fn check_registers(insn: &ebpf::Insn, store: bool, insn_ptr: usize) -> Result<(), BPFError> { if insn.src > 10 { return Err(VerifierError::InvalidSourceRegister(insn_ptr).into()); } match (insn.dst, store) { (0..=9, _) | (10, true) => Ok(()), (10, false) => Err(VerifierError::CannotWriteR10(insn_ptr).into()), (_, _) => Err(VerifierError::InvalidDestinationRegister(insn_ptr).into()), } } pub fn check(prog: &[u8]) -> Result<(), BPFError> { check_prog_len(prog)?; let mut insn_ptr: usize = 0; while insn_ptr * ebpf::INSN_SIZE < prog.len() { let insn = ebpf::get_insn(prog, insn_ptr); let mut store = false; match insn.opc { // BPF_LD class ebpf::LD_ABS_B => {} ebpf::LD_ABS_H => {} ebpf::LD_ABS_W => {} ebpf::LD_ABS_DW => {} ebpf::LD_IND_B => {} ebpf::LD_IND_H => {} ebpf::LD_IND_W => {} ebpf::LD_IND_DW => {} ebpf::LD_DW_IMM => { store = true; check_load_dw(prog, insn_ptr)?; insn_ptr += 1; } // BPF_LDX class ebpf::LD_B_REG => {} ebpf::LD_H_REG => {} ebpf::LD_W_REG => {} ebpf::LD_DW_REG => {} // BPF_ST class ebpf::ST_B_IMM => store = true, ebpf::ST_H_IMM => store = true, ebpf::ST_W_IMM => store = true, ebpf::ST_DW_IMM => store = true, // BPF_STX class ebpf::ST_B_REG => store = true, ebpf::ST_H_REG => store = true, ebpf::ST_W_REG => store = true, ebpf::ST_DW_REG => store = true, ebpf::ST_W_XADD => { unimplemented!(); } ebpf::ST_DW_XADD => { unimplemented!(); } // BPF_ALU class ebpf::ADD32_IMM => {} ebpf::ADD32_REG => {} ebpf::SUB32_IMM => {} ebpf::SUB32_REG => {} ebpf::MUL32_IMM => {} ebpf::MUL32_REG => {} ebpf::DIV32_IMM => { check_imm_nonzero(&insn, insn_ptr)?; } ebpf::DIV32_REG => {} ebpf::OR32_IMM => {} ebpf::OR32_REG => {} ebpf::AND32_IMM => {} ebpf::AND32_REG => {} ebpf::LSH32_IMM => {} ebpf::LSH32_REG => {} ebpf::RSH32_IMM => {} ebpf::RSH32_REG => {} ebpf::NEG32 => {} ebpf::MOD32_IMM => { check_imm_nonzero(&insn, insn_ptr)?; } ebpf::MOD32_REG => {} ebpf::XOR32_IMM => {} ebpf::XOR32_REG => {} ebpf::MOV32_IMM => {} ebpf::MOV32_REG => {} ebpf::ARSH32_IMM => {} ebpf::ARSH32_REG => {} ebpf::LE => { check_imm_endian(&insn, insn_ptr)?; } ebpf::BE => { check_imm_endian(&insn, insn_ptr)?; } // BPF_ALU64 class ebpf::ADD64_IMM => {} ebpf::ADD64_REG => {} ebpf::SUB64_IMM => {} ebpf::SUB64_REG => {} ebpf::MUL64_IMM => { check_imm_nonzero(&insn, insn_ptr)?; } ebpf::MUL64_REG => {} ebpf::DIV64_IMM => { check_imm_nonzero(&insn, insn_ptr)?; } ebpf::DIV64_REG => {} ebpf::OR64_IMM => {} ebpf::OR64_REG => {} ebpf::AND64_IMM => {} ebpf::AND64_REG => {} ebpf::LSH64_IMM => {} ebpf::LSH64_REG => {} ebpf::RSH64_IMM => {} ebpf::RSH64_REG => {} ebpf::NEG64 => {} ebpf::MOD64_IMM => {} ebpf::MOD64_REG => {} ebpf::XOR64_IMM => {} ebpf::XOR64_REG => {} ebpf::MOV64_IMM => {} ebpf::MOV64_REG => {} ebpf::ARSH64_IMM => {} ebpf::ARSH64_REG => {} // BPF_JMP class ebpf::JA => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JEQ_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JEQ_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JGT_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JGT_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JGE_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JGE_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JLT_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JLT_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JLE_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JLE_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSET_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSET_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JNE_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JNE_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSGT_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSGT_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSGE_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSGE_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSLT_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSLT_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSLE_IMM => { check_jmp_offset(prog, insn_ptr)?; } ebpf::JSLE_REG => { check_jmp_offset(prog, insn_ptr)?; } ebpf::CALL_IMM => {} ebpf::CALL_REG => {} ebpf::EXIT => {} _ => { return Err(VerifierError::UnknownOpCode(insn.opc, insn_ptr).into()); } } check_registers(&insn, store, insn_ptr)?; insn_ptr += 1; } // insn_ptr should now be equal to number of instructions. if insn_ptr != prog.len() / ebpf::INSN_SIZE { return Err(VerifierError::JumpOutOfCode(insn_ptr, insn_ptr).into()); } Ok(()) }