CSNB374: Microprocessor Systems

CSNB374: Microprocessor Systems Chapter 2: Intel x86 Microprocessor Architecture

Introduction • Most Intel microprocessors uses an instruction set called x86 (IA-32). • A CISC instruction set. • Always being extended by Intel when they develop a new microprocessor. • The 64-bit extension of this instruction set is called x86-64. • Supports larger virtual and physical address space. • Backward compatible with x86. • Implemented in the later versions of Pentium 4 and above.

History of Intel Microprocessors • Intel 4004 • The world’s first microprocessor • Introduced in 1971 • 4-bit microprocessor • Can only support 4K of memory • Each address location contains only 4-bit (1 nibble) of data • Instruction set contains 45 instructions

History of Intel Microprocessors • Intel 8008 • 8-bit version of Intel 4004 microprocessor • Supports 16K of memory • Each memory location can store 8-bit (1 byte) of data • Introduced in 1972 • Instruction set contains 48 instructions • Small memory size, slow speed and limited instruction set limits the 8008 usefulness

History of Intel Microprocessors • Intel 8080 • The first of the modern 8-bit microprocessors • Introduced in 1974 • Supports 64K of memory • 10 times faster than Intel 8008 • Compatible with TTL (transistor to transistor logic) • Allows for easier interfacing

History of Intel Microprocessors • Intel 8085 • An updated version of Intel 8080 • Introduced in 1977 • The last 8-bit microprocessor from Intel • Advantages compared to Intel 8080: • Higher clock frequency • Internal clock generator and system controller • The higher level of component integration allows simpler and less expensive microcomputers to be built • Instruction set contains 246 instructions

History of Intel Microprocessors • Intel 8086 and 8088 • Intel 8086 is the first microprocessor using the x86 instruction set • Intel 8086 was introduced in 1978 while Intel 8088 was introduced in 1979 • Both are 16-bit microprocessors • Supports 1MB (1024 K) of memory • Both processors have the same architecture except for the external data bus width • Intel 8086 has 16-bit external data bus • Intel 8088 has 8-bit external data bus

History of Intel Microprocessors • The use of 8-bit external data bus allows Intel 8088 to be compatible with 8-bit support chips (which is cheaper than 16-bit support chips) • Also contains 4/6-byte instruction cache that prefetches instructions before they were executed • Speed up the operation of many sequences of instructions • Basis for much larger instruction caches found in modern microprocessors • Instruction set contains over 20,000 variations of instructions • Include multiply and divide instructions which were missing in earlier microprocessors

History of Intel Microprocessors • Intel 80286 • An updated version of 8086 • Still a 16-bit microprocessor • Introduced in 1982 • Supports 16M of memory • Provides improved performance over Intel 8086: • Higher clock speed • Changes to internal execution of instructions • The first x86 microprocessor to provide protected mode • Allows features such as virtual memory, paging and safe multitasking (with memory protection)

History of Intel Microprocessors • Intel 80386 • The first 32-bit microprocessor • 32-bit data bus and memory address • Introduced in 1985 • Support 4GB of memory • Provides memory management unit • Allows memory resources to be managed by the OS • Instruction set compatible with earlier 16-bit Intel microprocessors • Allow 16-bit software to run

History of Intel Microprocessors • Intel 80486 • An integrated chip which incorporates: • 80386-like microprocessor • 80387-like numeric coprocessor • 8K-byte cache memory system • Introduced in 1989 • Changes made to internal structure so that half of its instructions are executed in one clock cycle instead of two

History of Intel Microprocessors • Intel Pentium • The original Pentium is based on the P5 microarchitecture • Introduced in 1993 • Provides faster clock speed and larger cache compared 80386 and 80486 • Data bus width is increased to 64 bits • Later Pentium models include the multimedia extensions (MMX)

History of Intel Microprocessors • The Pentium trademark is used by Intel for a long line of microprocessors that are based on various different microarchitectures. • P6 microarchitecture: Pentium Pro, Pentium II, Pentium III • Netburst microarchitecure: Pentium 4, Pentium D • Pentium M microarchitecture: Pentium M • Core microarchitecture: Pentium Dual-Core, Pentium • Nehalem microarchitecture: Pentium

History of Intel Microprocessors • Intel Core2, Core i3, Core i5, Core i7 • After Pentium 4, it becomes impractical to improve performance by increasing clock speed • Intel starts to put multiple cores in one chip • Increase speed of multithreaded applications • Provides 64-bit extension • A feature that has been there since later versions of Pentium 4 • Theoretically allow for 64-bit address • However, earlier Intel Core2 microprocessor contains only 40 address pins which supports 1TB of memory • Allows for 64-bit arithmetic

History of Intel Microprocessors • Other Intel microprocessors • Intel Celeron: • Low-end version • Intel Xeon: • High-end version for servers and workstations • Support multiprocessor • Intel Atom: • For ultra-mobile devices • Intel Itanium: • Allows greater parallelism than traditional architecture • Uses IA-64 instruction set (incompatible with x86/IA-32) • Used in high-end servers

Programming Model • Microprocessors can be programmed directly using an assembly language. • Differences with high-level languages: • Use commands to execute data movements, arithmetic, logic and program control operations. • Use registers to hold data for operation. • Programmers need to know not only the assembly language for the microprocessor, but also the internal configuration of the microprocessor.

Programming Model

Registers • A register is a storage element inside a microprocessor. • Almost all operations would involve using registers. • Some registers are general purpose registers, while others have special purposes. • General purpose registers can hold various data sizes and used for almost any purpose as dictated by the program. • However, each general purpose register does have its own special purposes.

Registers

Registers • Since the x86 instruction set is designed to be compatible with previous microprocessors, the same register can be accessed using different names. • Different names are given for 64-bit, 32-bit, 16-bit and 8-bit version of the same register.

General Purpose Registers • RAX, EAX, AX (AH & AL) • A general purpose register • Also an accumulator – stores intermediate results after arithmetic and logic operations • Can also hold the offset address of a location in memory (80386 and above) • RBX, EBX, BX (BH & BL) • A general purpose register • Also a base index register – holds the offset address of a location in memory • Can also address memory data (80386 and above)

General Purpose Registers • RCX, ECX, CX (CH & CL) • A general purpose register • Also a count register – holds the count for various instructions • Can also hold the offset address of a location in memory (80386 and above) • RDX, EDX, DX (DH & DL) • A general purpose register • Also a data register – stores data related to accumulator’s calculation (multiply and divide) • Can also address memory data (80386 and above)

General Purpose Registers • RBP, EBP, BP • A general purpose register • Also a base pointer register – points to a memory location for memory data transfer • RDI, EDI, DI • A general purpose register • Also a destination index register – holds the memory address for the destination data of a string instruction

General Purpose Registers • RSI, ESI, SI • A general purpose register • Also a source index register - holds the memory address for the source data of a string instruction • R8 through R15 • General purpose registers • Found only in 64-bit microprocessors • Data are addressed in 64-, 32-, 16-, or 8-bitsizes

Special Purpose Registers • RIP, EIP, IP • Instruction pointer – points to the next instruction in the memory to be executed • RSP, ESP, SP • Stack pointer – points to an area in memory called the stack • RFLAGS, EFLAGS, FLAGS • Indicates the condition of the microprocessor and control its operation

Flags

Flags • The C, P, A, Z, S and O flags are changed by most arithmetic and logic operations. • Flags never change for any data transfer or program control operations. • Some flags are also used to control features found in the microprocessor.

Flags • Descriptions for some of the flag bits: • C (carry): holds the carry after addition or borrow after subtraction. • P (parity): the count of 1s in a number expressed as even or odd. • 0 for odd, 1 for even. • A (auxiliary carry): holds the half-carry after addition or the borrow after subtraction between bit positions 3 and 4 of the result.

Flags • Z (zero): shows that the result of an arithmetic or logic operation is zero. • 0 result is not zero, 1 result is zero. • S (sign): holds the arithmetic sign of the result after an arithmetic or logic instruction executes. • 0 for positive, 1 for negative. • T (trap): enables trapping through an on-chip debugging feature. • 0 disable trapping, 1 enable trapping. • If enabled, allows the microprocessor to interrupt the flow of the program on conditions indicated by the debug registers and control registers. • Microsoft Visual Studio debugging tool uses this feature.

Flags • I (interrupt): control the operation of the INTR (interrupt request) input pin. • 0 disables INTR pin, 1 enables INTR pin. • D (direction): selects increment or decrement mode for SI/DI registers. • 0 increment, 1 decrement. • O (overflow): indicates that the result of an addition/subtraction of signed numbers exceeded the capacity of the machine.

Segment Registers • Generate memory addresses when combined with other registers in the microprocessor. • Function differently in real mode than in protected mode. • List of segment registers: • CS (code segment): defines the memory area that contains the code (programs and procedures) • DS (data segment): defines the memory area that contains most data used by a program.

Segment Registers • ES (extra segment): defines the memory area that contains additional data segment used by some string instructions to hold destination data. • SS (stack segment): defines the memory area that is used for the stack. • FS and GS: supplemental segment registers available in 80386 and above.

Memory Organization • Memory stores addresses of instructions and data. • These value are used by the processor to access memory locations. We begin with the memory organization. • Chap 1 explained that memory is a collection of bytes. • Each memory bytes has an address, starting with 0. The 8086 processor assigns 20-bit physical address to its memory locations. Thus it is possible to address 220 = 1, 048, 576 bytes (1MB) of memory.

The first five bytes in memory have the following addresses: • Because addresses are so cumbersome to write in binary, we usually express them as five hex digits, -> • And so on. The highest address is FFFFFh

Segmented Memory • In order to explain the function of the segment registers; need to introduce the idea of memory segments, which is a direct consequence of using a 20-bit address in a 16-bit processor. • The address are too big to fit in a 16-bit register. • Solution!!-> by partitioning its memory into segments.

Segmented Memory • A mechanism that allows the extend the addressability of a Processor • It uses 2 components to specify memory locations: a segment value and an offset value within that segment.

Segmented Memory • A memory segment is a block of 216 (or 64k) consecutive memory bytes. • Each segment is identified by a segment number. • Within a segment, a memory location is specified by giving an offset. • This is the number of bytes from the beginning of the segment.

Segmented Memory • A memory location may be specified by providing a segment number and an offset, written in the form segment:offset; this is know as a logical address • In the 8086 processor each 20bit address is expressed as: • 16 bit segment • 16 bit offset • Example: 2000h:0BAFh • Means offset 0BAFh within segment 2000h.

Real Mode Memory Addressing • All Intel microprocessors before 80286 can only operate in real mode. • 80286 and above can operate in both real and protected mode. • Real mode operation allows addressing of only the first 1MB of memory space. • True even in latest Intel microprocessors. • The first 1MB of memory is called the real memory, conventional memory or DOS memory. • Intel microprocessors begins operating in real mode by default.

Real Mode Memory Addressing • Generation of 20-bit linear address (physical address)from a segment:offset address • in the real mode, each segment register (16 bits) is internally appended with a 0h on its rightmost end (i.e., the segment is shifted left by 4 bits) • The segment and the offset are then added to form 20-bit memory address.

Segments and Offsets • All real mode memory addresses consist of a segment address plus an offset address. • Segment address defines the beginning of any 64KB memory segment. • Offset address selects any location within the 64KB memory segment. • Can be written in the form segment:offset • Example: 10000:F000 • Segment address = 0x10000 • Offset address = 0xF000

Segments and Offsets • Given a segment and an offset address, the actual linear address (physical address) is calculated as follows: • Linear addr = (segment addr x 10H) + offset addr • Example 1: 1000:F000 • Linear addr = (1000H x 10H) + F000H = 10000H + F000H = 1F000H • Example 2: 020A:1BCD • Linear addr = (020AH x 10H) + 1BCDH = 020A0H + 1BCDH = 03C6DH

Segments and Offsets • Beginning of memory segment = 0x10000. • End of memory segment = 0x1FFFF. • 64KB in length. • If the offset = 0xF000, selected memory address = 0x1F000

Segments and Offsets • The segment address is stored in one of the segment registers. • The offset address is stored in one of the general purpose registers. • The segment plus offset addressing allows program or data to be relocated. • The program or data segment can be placed anywhere in the memory and executed or used without any change to the program.

Segments and Offsets Default 16-bit segment and offset combinations

Segments and Offsets: Use of Segments

Protected Mode Memory Addressing • Protected mode allows access to data and programs located within and above the first 1MB of memory. • Microsoft Windows operates in protected mode. • The segment registers are used differently in protected mode. • They no longer store the segment address. • Instead, they contain a selector that selects a descriptor from a descriptor table.

Protected Mode Memory Addressing The contents of a segment register during protected mode operation of the 80286 through Core2 microprocessors.

Protected Mode Memory Addressing • A descriptor table can contain up to 8192 descriptors. • There are two types of descriptor tables: • Global descriptors: contain segment definitions that apply to all programs. • Local descriptors: unique to an application. • A descriptor contains information about: • Memory segment’s location • Length of the segment • Access rights

Protected Mode Memory Addressing

CSNB374: Microprocessor Systems

CSNB374: Microprocessor Systems

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