320 likes | 340 Views
This study evaluates the faults in computer systems caused by electromagnetic interference (EMI). The methodology for detecting and classifying these faults is discussed, along with experimental results. The goal is to provide comprehensive analysis and reliable operation in the presence of EM effects.
E N D
Evaluation of Computer Faults Due to to EM Interference Concepts, Simulation Environment and Some Results Shantanu Dutt (Student Involved: Hasan Arslan) ECE Dept. University of Illinois -Chicago
Outline • Past Work-- General Fault Detection and Tolerance, EMI Faults • Our Goals • Our Methodology for Fault Detection and Classification • Experimental Results • Conclusions and Future Work
Past work – General Fault Detection and tolerance • Off-line testing (mainly for hard faults) • Concurrent-online testing (operational faults): Adding external hardware, monitoring data, address and control lines • Memory:error-detecting & correcting codes • Computer systems • Watchdog processor – detecting control flow errors in program execution [Mahmood & McCluskey, TC’88] • Algorithm-based fault tolerance: use of some property of computation for self-checking [Huang & Abraham, TC’84, Dutt & Assad, TC’96]
Past Work On EM/Radiation-Induced Faults • Detection of high level computer failure due to different types of EM signals [Mojert et al., EMC’01] • Failure in real-time communication & control systems from communication line errors due to EM signals [Kohlberg & Carter, EMC’01] • Also: Radiation Hardened Processors: Leon and ERC32 processors (http sites). But primarily only ECC for memory and register file---simple fault tolerance but probably targeting the most likely source of “permanent” faults.
Assumptions/Scenarios of Past Work • Past Work on general fault detection: • Random single (sometimes double) faults • Deterministic faults • Types of faults: permanent, transient, intermittent; intermittent type not generally tackled • Past Work on EM-induced faults: • No how/why/what analysis and classification of computer failure due to EM interference
Goals of Our Work • Will determine and classify the following type of computer system behavioral error (i.e., program errors) due to different patterns, extent, duration and location of faults: • Control flow errors -- incorrect sequence of instruction execution. Causes: address gen. error, memory faults, bus faults • Data errors. Causes: computation errors, memory & bus faults • Termination Errors (hung processor & crashes). Causes: C.U. transition to dead-end states, invalid instruction, out-of-bound address, divide-by-zero, spurious interrupts (?) • Note: Error types are NOT mutually exclusive • Provide broad-based recipes for FT and reliable operation • To the best of our knowledge, more comprehensive analysis of fault effects on a computer system than that attempted previously • Comprehensive analysis needed due to the nature of EM effects--all pervasive, periodic, clustered
In each comp; control of fault duration, freq, #, pattern (rand, clust) Observation & Error Classification Detection & Classification using CFC & ABFT/Data Encoding Use VHDL model of a modern micro-proc---DLX & SuperScalar DLX Our System of Fault Analysis in a Computer System Fault Injection Computer Sys = Processor + Memory + Et. Buses
Inject Faults in a “Software” Model (VHDL) of a Computer-- • adv of both the h/w and s/w approaches w/o the disadvantages Counter_2 • Fault Types (stuck_at 0, stuck-at 1, single random, clustered, multiple random, etc) • Variable Duration of Faults & Frequency Counter_1 Fault Generator 1 0 data Var-width Var-period Pulse gen. MUX Data Bus DLX CPU Memory Address Bus Fault Generator Our Fault Injection Approach
NOP Sign(v4) ADD r1 r3 LD r2 address NOP sign(v5) NOP sign(v6) BLT r4 r8 off Memory Hierarchy v1 MAIN Watchdog v2 v3 v4 Memory Bus Sign(v4) BRT v6 v5 Signal from branch circuit v5 Processor WD v6 Methodologies for Control Flow Errors [Mahmood & McCluskey, TC’88] • A node is a block of instructions with a branch at the end • A derived signature of a node is a function (e.g., or, LFSR) of all its instructions • A program graph is one in which there is an arc from node u to v if the branch at u can lead to node v
Block Header Checking Block header detected New Block Detected START NOP Sign(v4) ADD r1 r3 LD r2 address NOP sign(v5) NOP sign(v6) BLT r4 r8 off v1 Middle of block Compute Block Sign. Wait for new block MAIN v2 v3 Sig. ok v4 Check Branch Sig. Corrupted Sig. Sign(v4) BRT v6 v5 v5 WD End of block Sig.ok Error flag v6 Check Block Sig. error Methodologies for Control Flow Errors: CFCChecking Using a Watchdog • WD compares the information gathered concurrently to the information previously provided • Complexity,lies between the current circuit-level and system-level tech. • 90% error coverage for single errors [Mahmood et al, ieee tc’88]
Data Error Methodologies: Algorithm-Based Fault Tolerance • Difficult to detect, occurs inside the microproc, not necessarily observable to an external WD processor • Use properties of the computation to check correctness of computed data • E.g. linearly property: f(v1+v2)=f(v1)+f(2) of computation f( ) can be used to check it • Pre-compute v’ = v1 + v1 + …+ vk (input checksum) • Computer f(v1), …..f(vk) • Compute u = f(v) + f(v2) + …. + f(vk) (output checksum) • Check if f(v’) = u; inequality indicates computation error(s) • Can be used for linear computations such as matrix multiplication, matrix addition, Gaussian elimination [Huang & Abraham, TC’84],[Dutt & Assad, TC’96]
Data Error Methodologies: Data Encoding • Data that is numerically processed can be encoded and checked if the output of arithmetic operations is still encoded (e.g., Berger, AN codes) • A simple coding scheme is AN coding: # N is transformed to A.N where A is odd, say, 3 • Works for addition: 3.N1 + 3.N2 = 3(N1+N2) -- check if result is still a multiple of 3; if not then error • 100% det of single faults -- single fault will change result by +/- (2^i) and so no longer multiple of 3.
Methodologies for Termination Errors • Valid address range registers R_low, R_high in processor -- check generated address to see if in range • Can detect crashes due to invalid addresses • Timeout Mechanisms -- Store upper bound exec time for each block in the watchdog; if time is exceeded during run time flag error • Can detect infinite loops or hung processor due to control unit faults
Current Implementation • Fault Injection w/ various controls (duration, frequency, extent, pattern) for a non-pipelined DLX processor in VHDL • Fault injection on memory data/address buses • Description of a watchdog processor in VHDL for control flow checking + infinite-loop termination errors • Valid address range registers in processor • ECC (1-error correction and 2-error detection) of memory (commercial feature) and buses (non-standard) • Some error analysis results for a simple Fibonacci computation:f(i) = f(i-1) + f(i-2), i=2 to 99, f(0)=f(1)=0
Fault Injector Add r30,r0,r14 rfe 4380ee8818 4181ee8008 000ef020 410ee030 encoder Current Implementation -- ECC Capabilities on Memory and Buses En En Dec Dec CPU Memory L. Adr. Reg. address decoder PC check 32+7ECC=39 bits H. Adr. Reg.
Orig. Instruction ADDI R7, R0, 3 SW 0(R3), R7 . . LW R3, -12(R30) LHI R4, 0 . . LW R6, -12(R30) SLLI R6, R6, 2 ADD R5, R5, R6 LW R4, 0(R4) LW R5, 0(R5) ADD R4, R4, R5 SW 0(R3), R4 . . LW R3, -12(R30) ADDI R3, R3, 1 SW -12(R30), R3 Corrupted Inst. ADDI R7, R0, 3 SW 0(R2), R23 . . LW R3, -12(R30) LHI R4, 0 . . LW R6, -12(R30) SLLI R14, R4, 2 ADD R5, R5, R6 LW R4, 0(R4) LW R5, 0(R5) ADD R4, R4, R5 SW 0(R3), R4 . . LW R3, 1040(R14) ADDI R3, R3, 1 SW -12(R30), R3 Adress 00000040 00000044 . . 000000A4 000000A8 . . 000000D4 000000D8 000000DC 000000E0 000000E4 000000E8 000000EC . . 0000010C 00000110 00000114 wrong initializ. Invalid Addr Err Ind. Addr. Err Inc. unknown value as index value Some Error Observations
0 5 6 31 Add r4,r4,r5 Slli r5,r5,#4 Trap_id TRAP 50c60004 00a62820 2 bit faults Trap_0 44XXXXX4 Some Error Observations(contd.) Trap_0 code=44000000 • DLX uses TRAP_0 to stop exec. Processor checks first 6 bits (0-5) for Trap • instruction, and last bit (31) for trap_id. No other bit checked. • For All ALU instructions, first 6 bits are always 0. When 2nd and 5th bits are set, they become trap inst. Hence their distance is 2. • For trap instructions if last bit is 0, then execution stops (Trap_0). Unfortunately, for most ALU inst.(add,and,xor,rfe…etc), the last bit is also 0. • DLX interprets the last 5 bits (27-31) as trap_id (bit 6-26 are ignored). Non-trap instructions interpret bit 6-10 as src./dst. register. • Check for trap/non-trap inst. extended to bit 6-10, to inc. min. dist. from 2 to 3. • Premature stops due to trap_0 thus reduced. • More refined schemes to increase min. distance -- on-going work
Repeat Period: 10 ns - 800 ns (f=100 Mz - 1.25 MHz) Duration Range: 5 ns - 400 ns Clock cycle: 22 ns R=20 D=5 Repeat Period Range: Duration Range: Low_Low 305 - 425 5 - 25 Med_Med 180 - 220 160 - 440 High_High 300 - 400 305 - 425 Experimental Setup: Fault Injection Parameters • 4 random errors simulated on the data bus w/ foll. • characteristics
Avrg. Exec. Inst. For each run stopped by Trap. No. Addr. Corr. Trap_0 No. Addr. Corr. Trap_Fixed 169 Addr. Corr. Trap_0 116 Addr. Corr. Trap_Fixed 441 74 Exec. inst. 276 70 314.1 154 When we fixed trap few runs is terminated because of trap.But Invalid. Addr. Termination (IAT) error increases 35.42 inst exec. When Sim stopped because of IAT. 38.37 inst exec. For second type 88.46 inst exec. (IAT) third type 124.54 inst exec. (IAT) 4th type Experimental Results Executed inst. Avgr. Exec. Inst. For each sim. (1134 inst. no fault)
No. Addr. Corr. Trap_Fixed No. Addr. Corr. Trap_0 38,826 ns 15.18 13.23 Addr. Corr. Trap_0 Addr. Corr. Trap_Fixed 27,009 ns Array Elts Updated Simulation time (ns) 6.35 13,258 ns 14,015 ns 3.86 Avgr. Exec. time. For each sim. (265,620 ns for non faulty) Avrg. Array. Elts Updates Experimental Results (Cont)Simulation Times, Data Computation When simulation runs more it calculates more data elements
T_0: No Addr. Corr. Trap_0: 410 err. Error_density:7/100 43:Term. Err(%10) 14 trap 29 Inv.Addr 66 CF (%16) 301 Dat_Err. (%74) T_F: No Addr. Corr. Trap_Fixed: 424 err. Error_density:7/100 41:Term. Err(%9.6) 9 trap 32 Inv.Addr 76 CF (%18) 307 Dat_Err. (%73) A_0: Addr. Corr. Trap_0: 444 err. Error_density:2.2/100 38:Term. Err(%6.8) 11 trap 27 Inv.Addr A_F: Addr. Corr. Trap_Fixed: 446 err. Error_density:1.7/100 54 CF (%13.6) 315 Dat_Err. (%79.5) 27:Term. Err(%6) 6 trap 21 Inv.Addr 24 CF (%5.4) 395 Dat_Err. (%88.6) Experimental Results 52 simulation for Low_Low The more program runs the more it gives Data Err. When trap is fixed, more simulation is completed. But it increase the Inv. Addr. Term. When Addr. corrected Inv. Addr. Err. is reduced.Simulation executes more instruction It increase the Data Err.
T_0: No Addr. Corr. Trap_0: 68 err. Error_density:15/100 52:Term. Err(%76.5) 1 trap 51 Inv.Addr T_F: No Addr. Corr. Trap_Fixed: 82 err. Error_density: 11/100 3 CF (%4.4) 13 Dat_Err. (%19.1) 52:Term. Err(%63.5) 0 trap 52 Inv.Addr A_0: Addr. Corr. Trap_0: 150 err. Error_Density:10/100 7 CF (%8.5) 23 Dat_Err. (%28) 52:Term. Err(%34) 7 trap 43 Inv.Addr A_F: Addr. Corr. Trap_Fixed: 175 err. Error_density:8/100 54 CF (%36) 44 Dat_Err. (%30) 45:Term. Err(%25.7) 8 trap 37 Inv.Addr 45 CF (%25.7) 85 Dat_Err. (%48.6) Experimental Results (cont) 52 simulation for Med_MEd Increasing fault inject period, reduces the # of executed Inst. So error density increases terribly
T_0: No Addr. Corr. Trap_0: 61 err. Error_density: 35/100 52:Term. Err(%85) 1 trap 51 Inv.Addr 9 CF (%15) 0 Dat_Err. (%0) T_F: No Addr. Corr. Trap_Fixed: 90 err. Error_density: 48/100 52:Term. Err(%57) 0 trap 52 Inv.Addr 38 CF (%43) 0 Dat_Err. (% 0) A_0: Addr. Corr. Trap_0: 93 err. Error_density: 22/100 52:Term. Err(%55.3) 9 trap 43 Inv.Addr 41 CF (%43.6) 1 Dat_Err. (% 1.1) A_F: Addr. Corr. Trap_Fixed: 52 err. Error_Density: 26/100 52:Term. Err(%100) 4 trap 48 Inv.Addr 0 CF (% 0) 0 Dat_Err. (% 0) Experimental Results (cont) 52 simulation for High_High Process never get able to calculate Fib.val because of high fault injection.None of the simulation is completed.
90 ECC cover. 80 Cont.Flow. Cov. 95 Data cov. 70 60 434 erroneous inst. 411 err. inst. covered by ECC (95%) 50 40 90 err. Inst. covered by WD (20%). We are injection 4 bit faults, If process jumps the middle of a block, WD spends time to get beginning of block. 30 20 20 10 0 Total: 434 erroneous inst. executed Error Coverage For error coverage, we run our simulation 122 times for: repeat period: 300 ns - 500 ns. dura. range : 150 ns - 250 ns T_0: No. Addr. Corr. Trap_0
90 ECC cover. 80 Cont.Flow. Cov. 95 Data cov 70 60 474 erroneous inst. 450 err. inst. covered by ECC (95%) 50 40 106 err. Inst. covered by WD (23%). We are injection 4 bit faults, If process jumps the middle of a block, WD spends time to get beginning of block. 30 20 23 10 0 Total: 474 erroneous inst. executed Error Coverage(Cont.) For error coverage, we run our simulation 122 times for repeat period: 300 ns - 500 ns. dura. range : 150 ns - 250 ns T_F: No. Addr. Corr. Trap_Fixed
90 ECC cover. 80 Cont.Flow. Cov. 83 Data cov 70 60 3553 erroneous inst. 2959 err. inst. covered by ECC (83%) 50 40 703 err. Inst. covered by WD (20%). We are injection 4 bit faults, If process jumps the middle of a block, WD spends time to get beginning of block. 30 20 20 There were 89 data error. 12 (13%) of them covered by 3N coding 10 13 0 Total: 3553 erroneous inst. executed Error Coverage (Cont.) For error coverage, we run our simulation 122 times for repeat period: 300 ns - 500 ns. dura. range : 150 ns - 250 ns A_0: Addr. Corr. Trap_0
90 ECC cover. 80 Cont.Flow. Cov. 82 Data cov 70 60 4219 erroneous inst. 3426 err. inst. covered by ECC (82%) 50 40 762 err. Inst. covered by WD (18%). We are injection 4 bit faults, If process jumps the middle of a block, WD spends time to get beginning of block.. 30 20 19 18 There were 106 data error. 20 (19%) of them covered by 3N coding 10 0 Total: 4219 erroneous inst. executed Error Coverage (Cont.) For error coverage, we run our simulation 122 times for repeat period: 300 ns - 500 ns. dura. range : 150 ns - 250 ns A_F: Addr. Corr. Trap_Fixed
90 80 70 60 50 40 30 20 10 0 Total: 438 erroneous inst. executed Error Coverage (cont) For error cover., 20 runs selected that resulted in complete simulations w/ combinations of period: 305 - 460 ns and dura. range : 5 - 60 ns ECC cover. Cont.Flow. Cov. 80 Data cov 438 erroneous inst. 349 err. inst. covered by ECC (80%) 39 170 err. Inst. covered by WD (39%). We are injecting 4 bit faults. If process jumps the middle of a block, WD spends time to get beginning of block. 23 There were 217 data error. 51 (23%) of them covered by 3N coding Addr. Corr. Trap_0
Conclusions • Have completed a significant but preliminary fault simulation of the DLX processor in VHDL • Obtain % of termination, control and data errors for different fault duration and frequencies • Encoding the TRAP instruction to have a min. distance from other instructions helps in reducing incorrect termination • Need to have ECC for register fields of instrs to reduce incorrect address generation and data errors • It seems to be possible to catch most errors by the combination of mechanisms we have suggested so at least a fail safe mode can be guaranteed with high confidence; though room for improvement for control & data error detection
Future Work • Other fault patterns (e.g., clusters); correlation with EM induced fault work by others in our group • Other block signature techniques (e.g., LFSR) with better fault coverage • Aliasing analysis (math., empirical) for signatures • Perform error analysis for more substantial “real-life” programs (scientific computations, non-numeric, system or O.S.) • Fault injection and analysis for SuperScalar DLX • Fault injection and analysis of on-chip processor components (integer and FP ALU, register files, control unit, internal buses, power/ground lines)
Looking Further Ahead • Q: Are there patterns of errors that lead to computer crashes w/ high probability? • Q:If so, can the detection of such patterns be used to shut down the computer in a fail-safe manner (save state & data for later resumption) • Q:Are there patterns of errors that are characteristic of EM-induced faults versus random single/double faults? • Q:If so, can these be used as “early detection & warning” of EM interference? • Future: Based on the correlation of system errors to EM faults, determine fault tolerance/ error minimization techniques for EM-induced faults.