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ORG ; FOURTEEN

Dec Hex Bin. 14 E 00001110. ORG ; FOURTEEN. Interrupts In x86 PC. OBJECTIVES this chapter enables the student to:. Explain how the x86 executes interrupts by using the interrupt vector table and interrupt routines. List the differences between interrupts and CALL instructions.

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ORG ; FOURTEEN

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  1. Dec Hex Bin 14 E 00001110 ORG ; FOURTEEN Interrupts In x86 PC

  2. OBJECTIVESthis chapter enables the student to: • Explain how the x86 executes interrupts by using the interrupt vector table and interrupt routines. • List the differences between interrupts andCALL instructions. • Describe the differences between hardwareand software interrupts. • Examine the ISR for any interrupt, given itsinterrupt number. • Describe the function of each pin of the 8259 programmable interrupt controller (PIC) chip.

  3. OBJECTIVESthis chapter enables the student to: (cont) • Explain the purpose of each of the four control words of the 8259 and demonstrate how theyare programmed. • Examine the interrupts in x86 PCs.

  4. 14.1: 8088/86 INTERRUPTS • An interrupt is an external event that informs the CPU that a device needs its service. • In 8088/86 there are a total of 256 interrupts. • INT 00, INT 01, ..., INT FF (sometimes called TYPEs). • When an interrupt is executed the processor: • Saves the flag register (FR), instruction pointer (IP),and code segment register (CS) on the stack,. • Goes to a fixed memory location. • In x86, always four times the value of the interrupt number.

  5. 14.1: 8088/86 INTERRUPTSinterrupt service routine (ISR) When an interrupt is invoked it is asked to run a program to performa certain service. There must be a program associated with every interrupt . This program is commonly referred to as an interrupt service routine (ISR), and also called the interrupt handler. When an interrupt is invoked, the CPU runs the interrupt service routine.

  6. 14.1: 8088/86 INTERRUPTS interrupt service routine (ISR) • For every interrupt thereare allocated four bytesof memory in the interrupt vector table. • Two bytes for the IP. • Two for the CS of the ISR. • These locations provide the addresses of the interruptservice routine for which the interrupt was invoked. • The lowest 1024 bytes of memory space are set aside for the interrupt vector table.

  7. 14.1: 8088/86 INTERRUPTS interrupt service routine (ISR)

  8. 14.1: 8088/86 INTERRUPTS differences between INT and CALL • What is the difference between… • INT instruction - which saves the CS:IP of the following instruction and jumps indirectly to the subroutine associated with the interrupt. • A CALL FAR instruction, which also saves CS:IPand jumps to the desired subroutine (procedure)?

  9. 14.1: 8088/86 INTERRUPTS differences between INT and CALL • A "CALL FAR " instruction… • can jump to any location within the 1-megabyte address range of the 8088/86 CPU. • The "INT nn" goes to a fixed memory location in the interrupt vector table to get the address of the interrupt service routine. • is used in the program instructions, but an externally activated hardware interrupt can come in any time, requesting CPU attention. • cannot be masked (disabled), but "INT nn" belonging to externally activated hardware interrupts can be masked. • auto-saves only CS:IP of the next instruction on the stack. • "INT nn" saves FR (flag register) also.

  10. 14.1: 8088/86 INTERRUPTS differences between INT and CALL • "INT nn" is a 2-byte instruction where the first byte is for the opcode & the second the interrupt number. • A maximum of 256 (INT 00 INT FFH) interrupts. • Some are used for software interrupts; some for hardware.

  11. 14.1: 8088/86 INTERRUPTS categories of interrupts • Three x86 pins are associated with hardware interrupts... • INTR (interrupt request) • NMI (nonmaskable interrupt) • INTA (interrupt acknowledge) • INTR is a CPU input signal, which can be masked (ignored) & unmasked through use CLI and STI. • NMI, also an input signal into the CPU, cannot be masked and unmasked using CLI & STI. • For this reason, it is called a nonmaskable interrupt.

  12. 14.1: 8088/86 INTERRUPTS hardware interrupts • INTR and NMI are activated externally by putting5V on the x86 microprocessor NMI & INTR pins. • On activation of either interrupt, x86: • Finishes the instruction it is executing. • Pushes FR & CS:IP of the next instruction onto the stack. • Jumps to a fixed location in the interrupt vector table and fetches the CS:IP for the interrupt service routine (ISR) associated with that interrupt. • At the end of the ISR, IRET causes the CPU to get (pop) back its original FR and CS:IP from the stack. • Forcing the CPU to continue at the instructionwhere it left off when the interrupt came in.

  13. 14.1: 8088/86 INTERRUPTS hardware interrupts • Intel has embedded "INT 02" in x86, only for NMI. • Whenthe NMI pin is activated, the CPU location 00008to get the address (CS:IP) of the ISR. • Memory locations 00008, 00009, 0000A, and 0000Bcontain the 4 bytes of CS:IP of the ISR belonging to NMI. • There is no specific location in the vector table assigned to INTR. • Allowed to use any "INT nn" not previously assigned. • The 8259 programmable interrupt controller (PIC) chip can be connected to INTR to expand the number of hardware interrupts to 64.

  14. 14.1: 8088/86 INTERRUPTS software interrupts • An ISR called as a result of execution of an x86 instruction such as "INT nn“ is referred to as a software interrupt. • As it was invoked from software, not external hardware. • DOS "INT 21H" function calls,and video interrupts "INT 10H". • Can be invoked in code like a CALL or other x86 instruction • Some of the interrupts are associated with predefined functions.

  15. 14.1: 8088/86 INTERRUPTS software interrupts Interrupts INT 05 to INTFF can be used for either software or hardware interrupts. INT 00 to INT 04 have predefined functions. INT 00 (divide error) INT 01 (single step) INT 03 (breakpoint) INT 04 (signed number overflow) Figure 14-1 Intel's List of Designated Interrupts for the 8088/86

  16. 14.1: 8088/86 INTERRUPTS interrupts and the flag register • Two flag register bits are associated with interrupt: • D9, or IF (interrupt enable flag) • D8, or TF (trap or single step flag). • OF (overflow flag) can be used by the interrupt.

  17. 14.1: 8088/86 INTERRUPTS processing interrupts • When 8088/86 processes any interrupt: • 1. The flag register (FR) is pushed onto the stack &SP is decremented by 2, as FR is a 2-byte register. • 2. The IF (interrupt enable flag) & TF (trap flag) areboth cleared. (IF = 0 and TF = 0). • 3. The current CS is pushed onto the stack andSP is decremented by 2. • 4. The current IP is pushed onto the stack and SPis decremented by 2.

  18. 14.1: 8088/86 INTERRUPTS processing interrupts • When 8088/86 processes any interrupt: • 5. The INT number (type) is multiplied by 4 to get the physical address of the location within the vector tableto fetch the CS and IP of the interrupt service routine. • 6. From the new CS:IP, the CPU starts to fetch and execute instructions belonging to the ISR program. • 7. The last instruction of the interrupt service routine must be IRET, to get IP, CS, and FR back from the stack and make the CPU run the code where it left off.

  19. 14.1: 8088/86 INTERRUPTS software interrupts A conditional or exception interrupt. Invoked by the processor when there are conditions (exceptions) the CPU is unable to handle. INT 00 invokes by when there is an attempt to divide a number by zero. INT 00 is also invoked if the quotientis too large to fit into the assigned register when executing a DIV. INT 00 to INT 04 have predefined functions. INT 00 (divide error)

  20. 14.1: 8088/86 INTERRUPTS software interrupts Intel designated INT 01 specificallyfor implementation of single-stepping instructions for program tracing. The trap flag (TF), D8 of the flag register, must be set to 1. After execution of each instruction, 8088/86 jumps to physical location 00004 to fetch CS:IP of the interrupt service routine. INT 00 to INT 04 have predefined functions. INT 01 (single step)

  21. 14.1: 8088/86 INTERRUPTS hardware interrupts All Intel x86 processors have a pin designated NMI, an active-high input, and has reserved INT 02 for NMI. When the NMI pin is activated by a high (5V) signal, the CPU jumps to physical memory location 00008 to fetch the CS:IP of the ISR routine associated with NMI. INT 00 to INT 04 have predefined functions. INT 02 (nonmaskable interrupt)

  22. 14.1: 8088/86 INTERRUPTS software interrupts Intel has set aside INT 03 for the implementation of breakpoints in software engineering. A breakpoint is used to examine CPU and memory after the execution of a group of instructions. INT 3 is the fact is a 1-byte instruction. INT 00 to INT 04 have predefined functions. INT 03 (breakpoint)

  23. 14.1: 8088/86 INTERRUPTS software interrupts Invoked by signed number overflow,& associated with the INTO (interrupt on overflow) instruction. If instruction INTO is placed after a signed number arithmetic or logic operation such as IMUL or ADD, the CPU will activate INT 04 if OF = 1. If OF = 0, INTO is is bypassed, acting as a NOP (no operation) instruction. INT 00 to INT 04 have predefined functions. INT 04 (signed number overflow)

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