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Processor Exceptions

Processor Exceptions. A survey of the x86 exceptions and mechanism for handling faults, traps, and aborts. Types of exceptions. The CPU recognizes various kinds of processing errors (called ‘exceptions’): Those which are known before they have occurred (and which therefore can be prevented)

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Processor Exceptions

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  1. Processor Exceptions A survey of the x86 exceptions and mechanism for handling faults, traps, and aborts

  2. Types of exceptions • The CPU recognizes various kinds of processing errors (called ‘exceptions’): • Those which are known before they have occurred (and which therefore can be prevented) • Those which are known only after they’ve occurred (but for which corrective action can still be taken) • Those which were not forseen, and which do not permit any steps that would lead to recovery • We will need some more background for explaining these distinctions

  3. More ‘application’ registers • The 8087 NPX (numeric processor extension) introduced eight 80-bit registers (for doing floating-point arithmetic): • and the Pentium continues to implement these registers 80-bits st0 st1 st2 st3 st4 st5 st6 st7

  4. Control Register 0 31 0 P G C D N W A M W P N E E T = 1 T S E M M P P E These are cache-related These are NPX-related Legend: PE = Protection Enabled (1=yes, 0=no) MP = Math NPX Present (1=yes, 0=no) EM = Emulate Math NPX (1=yes, 0=no) TS = Task was Switched (1=yes, 0=no) ET = NPX Extension-Type (1=387, 0=287) NE = NPX Errors trapped (1=yes, 0=no) WP = Write-Protect user-pages (1=yes, 0=no) AM = Alignment-checking Mask (1=on, 0=off) NW = Non-Write-through (1=yes, 0=no) CD = Cache is Disabled (1=yes, 0=no) PG = Paging is Enabled (1=yes, 0=no)

  5. More ‘system’ registers • We already mentioned Control Register 0, but there are also other system registers: DR0 CR0 DR1 CR1 DR2 CR2 DR3 CR3 DR4 CR4 DR5 4 Control Registers DR6 DR7 6 Debug Registers = unimplemented register

  6. ‘Before-the-fact’ errors • The CPU may fetch an instruction which it cannot correctly execute (due to an invalid operand or insufficient privilege-level, or to the instruction’s opcode not being defined) • A few examples are: • Attempting to perform a division by zero • Attempting to exceed memory-segment limits • Attempting to modify a ‘read-only’ segment

  7. ‘After-the-fact’ errors • Also the cpu may perform some operation that results in an incorrect or illegal value (due to limits on the CPU register-sizes or to limits on the supported data-formats) • A few examples: • Add positive numbers, but get a negative total • Store an array-entry beyond the array-bounds • Take square-root of a real value less than 0.0

  8. “privileged” instructions • In Protected-Mode the instructions below can only be executed at ring0 (i.e., if the CPU’s Current Privilege Level is zero): • ‘MOV’ to/from a control-register (e.g., CR0) • ‘MOV’ to/from a debug-register (e.g., DR7) • Modifying a system segment-register (i.e., ‘LGDT’ / ’LIDT’ / ’LLDT’ / ’LTR’ / ’LMSW’ ) • Cache-invalidates: ‘INVD’/‘INVLPG’/ WBINVD’ • ‘CLTS’ or ‘HLT’

  9. What happens if…? • If protection rules are violated, or if errors result from computations, the processor will generate an ‘exception’ (i.e., it will save some information on the stack and transfer control to an ‘exception-handler’) • Different kinds of exceptions will trigger different exception-handling procedures • Gates in the IDT define the ‘entry-points’

  10. Faults, traps, and aborts • Intel classifies exceptions into categories, (according to whether or not it may be possible to ‘recover’ from the ‘error’): • ‘Faults’ are detected ‘before-the-fact’ (and generally indicate ‘recoverable’ errors) • ‘Traps’ are detected ‘after-the-fact’ (and indicate some corrective action is needed) • ‘Aborts’ are unrecoverable error-conditions

  11. A ‘fault’ example • Suppose an instruction tries to read from a ‘not-present’ data-segment: mov (%si),ax • The CPU generate exception-number 0xB • In case the corresponding IDT-descriptor is a 32-bit interrupt-gate (or trap-gate), the CPU will push at least four 32-bit values: • Current contents of the EFLAGS register • Current contents of registers CS and EIP • An ‘error-code’ (with info about DS register)

  12. ‘Fault’ example (continued) • If it is necessary to switch stacks (because of a change in the exception-handler’s code-segment privilege-level), then the ‘old’ stack’s address (i.e., registers SS and ESP) will also get pushed onto the ‘new’ stack • The fault-handler can take whatever actions are necessary to resolve the ‘not-present’ condition, then mark the data-segment as being ‘present’ and ‘restart’ execution of the prior instruction

  13. What about ‘not-present’ gates? • If an exception is generated, but the IDT’s gate-descriptor for that type of exception isn’t ‘present’, then the CPU generates a General Protection exception (INT-0x0D) • So by supplying one exception-handler for this ‘catch-all’ exception, you can ‘service’ nearly all of the various error-conditions (if you include code that distinguishes them)

  14. Error-Code Formats • The format of the error-code that the CPU pushes onto its stack depends upon which type of exception has been encountered • For General Protection exceptions, the error-code format looks like this: 3 2 1 0 15 segment selector index T I I N T E X T TI=Table Indicator (0=GDT, 1=LDT) INT=Interrupt (1=yes, 0=no) EXT=External-to-CPU event was cause of the exception (1=yes, 0=no)

  15. Stack Frame Layout (32bit) SS points to the old stack’s top ESP EFLAGS CS points to the faulting instruction EIP Error Code SS:ESP = the new stack’s top When the ‘fault’ exception uses a 32-bit Interrupt-Gate (or Trap-Gate)

  16. Stack Frame Layout (16bit) SS points to the old stack’s top SP FLAGS CS points to the faulting instruction IP Error Code SS:SP = the new stack’s top When the ‘fault’ exception uses a 16-bit Interrupt-Gate (or Trap-Gate)

  17. Catalog of x86 exceptions • 0x00: divide-overflow fault • 0x01: single-step trap or debug fault • 0x02: non-maskable interrupt (NMI) trap • 0x03: breakpoint trap • 0x04: integer overflow trap • 0x05: array bounds fault • 0x06: invalid opcode fault • 0x07: coprocessor unavailable fault

  18. Catalog (continue) • 0x08: double-fault abort • 0x09: (reserved) • 0x0A: invalid TSS fault/abort • 0x0B: segment not present fault • 0x0C: stack fault • 0x0D: general protection exception fault • 0x0E: page fault • 0x0F: (reserved)

  19. Catalog (continued again) • 0x10: FPU floating-point error fault • 0x11: operand alignment-check fault • 0x12: machine-check exception abort • 0x13: SIMD floating-point exception fault • 0x14-0x1F: (reserved) • 0x20-0xFF: (user-defined interrupts) • NOTE: Only the following exceptions have error-codes: 0x8, 0xA, 0xB, 0xC, 0xD, 0xE

  20. Demo program: ‘whycrash.s’ • To illustrate the processor’s response to exceptions, we created this short demo • It displays some diagnostic information (including the ‘error-code’) when the CPU triggers any exception-condition (all get routed through the IDT-gate for General Protection exceptions in this demo) • Can help us identify causes for a ‘crash’

  21. In-class exercise #1 • Try experimenting with your own examples of impermissible instructions • What if you try to store a value to the vram memory-segment using an address-offset larger than its 32KB segment-limit? • What if you try to load a segment-register with a selector-value that exceeds the size of your descriptor-table? • What if you try to ‘call’ to ring3 from ring0?

  22. In-class exercise #2 • What if you tried to load a selector for the wrong kind of descriptor: • e.g., putting a code-selector into register SS? • e.g., putting a data-selector into register CS? • e.g., putting a gate-descriptor into register DS? • What if you tried to execute an ‘undefined opcode’? • e.g., putting bytes 0xF, 0xB in instruction-stream

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