xv6-cs450/web/l2.html

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<title>L2</title>
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<h1>6.828 Lecture Notes: x86 and PC architecture</h1>

<h2>Outline</h2>
<ul>
<li>PC architecture
<li>x86 instruction set
<li>gcc calling conventions
<li>PC emulation
</ul>

<h2>PC architecture</h2>

<ul>
<li>A full PC has:
  <ul>
  <li>an x86 CPU with registers, execution unit, and memory management
  <li>CPU chip pins include address and data signals
  <li>memory
  <li>disk
  <li>keyboard
  <li>display
  <li>other resources: BIOS ROM, clock, ...
  </ul>

<li>We will start with the original 16-bit 8086 CPU (1978)
<li>CPU runs instructions:
<pre>
for(;;){
	run next instruction
}
</pre>

<li>Needs work space: registers
	<ul>
	<li>four 16-bit data registers: AX, CX, DX, BX
        <li>each in two 8-bit halves, e.g. AH and AL
	<li>very fast, very few
	</ul>
<li>More work space: memory
	<ul>
	<li>CPU sends out address on address lines (wires, one bit per wire)
	<li>Data comes back on data lines
	<li><i>or</i> data is written to data lines
	</ul>

<li>Add address registers: pointers into memory
	<ul>
	<li>SP - stack pointer
	<li>BP - frame base pointer
	<li>SI - source index
	<li>DI - destination index
	</ul>

<li>Instructions are in memory too!
	<ul>
	<li>IP - instruction pointer (PC on PDP-11, everything else)
	<li>increment after running each instruction
	<li>can be modified by CALL, RET, JMP, conditional jumps
	</ul>

<li>Want conditional jumps
	<ul>
	<li>FLAGS - various condition codes
		<ul>
		<li>whether last arithmetic operation overflowed
		<li> ... was positive/negative
		<li> ... was [not] zero
		<li> ... carry/borrow on add/subtract
		<li> ... overflow
		<li> ... etc.
		<li>whether interrupts are enabled
		<li>direction of data copy instructions
		</ul>
	<li>JP, JN, J[N]Z, J[N]C, J[N]O ...
	</ul>

<li>Still not interesting - need I/O to interact with outside world
	<ul>
	<li>Original PC architecture: use dedicated <i>I/O space</i>
		<ul>
		<li>Works same as memory accesses but set I/O signal
		<li>Only 1024 I/O addresses
		<li>Example: write a byte to line printer:
<pre>
#define DATA_PORT    0x378
#define STATUS_PORT  0x379
#define   BUSY 0x80
#define CONTROL_PORT 0x37A
#define   STROBE 0x01
void
lpt_putc(int c)
{
  /* wait for printer to consume previous byte */
  while((inb(STATUS_PORT) & BUSY) == 0)
    ;

  /* put the byte on the parallel lines */
  outb(DATA_PORT, c);

  /* tell the printer to look at the data */
  outb(CONTROL_PORT, STROBE);
  outb(CONTROL_PORT, 0);
}
<pre>
		</ul>

<li>Memory-Mapped I/O
	<ul>
	<li>Use normal physical memory addresses
		<ul>
		<li>Gets around limited size of I/O address space
		<li>No need for special instructions
		<li>System controller routes to appropriate device
		</ul>
	<li>Works like ``magic'' memory:
		<ul>
		<li>	<i>Addressed</i> and <i>accessed</i> like memory,
			but ...
		<li>	... does not <i>behave</i> like memory!
		<li>	Reads and writes can have ``side effects''
		<li>	Read results can change due to external events
		</ul>
	</ul>
</ul>


<li>What if we want to use more than 2^16 bytes of memory?
	<ul>
        <li>8086 has 20-bit physical addresses, can have 1 Meg RAM
        <li>each segment is a 2^16 byte window into physical memory
        <li>virtual to physical translation: pa = va + seg*16
        <li>the segment is usually implicit, from a segment register
	<li>CS - code segment (for fetches via IP)
	<li>SS - stack segment (for load/store via SP and BP)
	<li>DS - data segment (for load/store via other registers)
	<li>ES - another data segment (destination for string operations)
        <li>tricky: can't use the 16-bit address of a stack variable as a pointer
        <li>but a <i>far pointer</i> includes full segment:offset (16 + 16 bits)
	</ul>

<li>But 8086's 16-bit addresses and data were still painfully small
  <ul>
  <li>80386 added support for 32-bit data and addresses (1985)
  <li>boots in 16-bit mode, boot.S switches to 32-bit mode
  <li>registers are 32 bits wide, called EAX rather than AX
  <li>operands and addresses are also 32 bits, e.g. ADD does 32-bit arithmetic
  <li>prefix 0x66 gets you 16-bit mode: MOVW is really 0x66 MOVW
  <li>the .code32 in boot.S tells assembler to generate 0x66 for e.g. MOVW
  <li>80386 also changed segments and added paged memory...
  </ul>

</ul>

<h2>x86 Physical Memory Map</h2>

<ul>
<li>The physical address space mostly looks like ordinary RAM
<li>Except some low-memory addresses actually refer to other things
<li>Writes to VGA memory appear on the screen
<li>Reset or power-on jumps to ROM at 0x000ffff0
</ul>

<pre>
+------------------+  <- 0xFFFFFFFF (4GB)
|      32-bit      |
|  memory mapped   |
|     devices      |
|                  |
/\/\/\/\/\/\/\/\/\/\

/\/\/\/\/\/\/\/\/\/\
|                  |
|      Unused      |
|                  |
+------------------+  <- depends on amount of RAM
|                  |
|                  |
| Extended Memory  |
|                  |
|                  |
+------------------+  <- 0x00100000 (1MB)
|     BIOS ROM     |
+------------------+  <- 0x000F0000 (960KB)
|  16-bit devices, |
|  expansion ROMs  |
+------------------+  <- 0x000C0000 (768KB)
|   VGA Display    |
+------------------+  <- 0x000A0000 (640KB)
|                  |
|    Low Memory    |
|                  |
+------------------+  <- 0x00000000
</pre>

<h2>x86 Instruction Set</h2>

<ul>
<li>Two-operand instruction set
	<ul>
	<li>Intel syntax: <tt>op dst, src</tt>
	<li>AT&amp;T (gcc/gas) syntax: <tt>op src, dst</tt>
		<ul>
		<li>uses b, w, l suffix on instructions to specify size of operands
		</ul>
	<li>Operands are registers, constant, memory via register, memory via constant
	<li>	Examples:
		<table cellspacing=5>
		<tr><td><u>AT&amp;T syntax</u> <td><u>"C"-ish equivalent</u>
		<tr><td>movl %eax, %edx <td>edx = eax; <td><i>register mode</i>
		<tr><td>movl $0x123, %edx <td>edx = 0x123; <td><i>immediate</i>
		<tr><td>movl 0x123, %edx <td>edx = *(int32_t*)0x123; <td><i>direct</i>
		<tr><td>movl (%ebx), %edx <td>edx = *(int32_t*)ebx; <td><i>indirect</i>
		<tr><td>movl 4(%ebx), %edx <td>edx = *(int32_t*)(ebx+4); <td><i>displaced</i>
		</table>
	</ul>

<li>Instruction classes
	<ul>
	<li>data movement: MOV, PUSH, POP, ...
	<li>arithmetic: TEST, SHL, ADD, AND, ...
	<li>i/o: IN, OUT, ...
	<li>control: JMP, JZ, JNZ, CALL, RET
	<li>string: REP MOVSB, ...
	<li>system: IRET, INT
	</ul>

<li>Intel architecture manual Volume 2 is <i>the</i> reference

</ul>

<h2>gcc x86 calling conventions</h2>

<ul>
<li>x86 dictates that stack grows down:
	<table cellspacing=5>
	<tr><td><u>Example instruction</u> <td><u>What it does</u>
	<tr><td>pushl %eax
		<td>
		subl $4, %esp <br>
		movl %eax, (%esp) <br>
	<tr><td>popl %eax
		<td>
		movl (%esp), %eax <br>
		addl $4, %esp <br>
	<tr><td>call $0x12345
		<td>
		pushl %eip <sup>(*)</sup> <br>
		movl $0x12345, %eip <sup>(*)</sup> <br>
	<tr><td>ret
		<td>
		popl %eip <sup>(*)</sup>
	</table>
	(*) <i>Not real instructions</i>

<li>GCC dictates how the stack is used.
	Contract between caller and callee on x86:
	<ul>
	<li>after call instruction:
		<ul>
		<li>%eip points at first instruction of function
		<li>%esp+4 points at first argument
		<li>%esp points at return address
		</ul>
	<li>after ret instruction:
		<ul>
		<li>%eip contains return address
		<li>%esp points at arguments pushed by caller
		<li>called function may have trashed arguments
		<li>%eax contains return value
			(or trash if function is <tt>void</tt>)
		<li>%ecx, %edx may be trashed
		<li>%ebp, %ebx, %esi, %edi must contain contents from time of <tt>call</tt>
		</ul>
	<li>Terminology:
		<ul>
		<li>%eax, %ecx, %edx are "caller save" registers
		<li>%ebp, %ebx, %esi, %edi are "callee save" registers
		</ul>
	</ul>

<li>Functions can do anything that doesn't violate contract.
	By convention, GCC does more:
	<ul>
	<li>each function has a stack frame marked by %ebp, %esp
		<pre>
		       +------------+   |
		       | arg 2      |   \
		       +------------+    &gt;- previous function's stack frame
		       | arg 1      |   /
		       +------------+   |
		       | ret %eip   |   /
		       +============+   
		       | saved %ebp |   \
		%ebp-&gt; +------------+   |
		       |            |   |
		       |   local    |   \
		       | variables, |    &gt;- current function's stack frame
		       |    etc.    |   /
		       |            |   |
		       |            |   |
		%esp-&gt; +------------+   /
		</pre>
	<li>%esp can move to make stack frame bigger, smaller
	<li>%ebp points at saved %ebp from previous function,
		chain to walk stack
	<li>function prologue:
		<pre>
			pushl %ebp
			movl %esp, %ebp
		</pre>
	<li>function epilogue:
		<pre>
			movl %ebp, %esp
			popl %ebp
		</pre>
		or
		<pre>
			leave
		</pre>
	</ul>

<li>Big example:
	<ul>
	<li>C code
		<pre>
		int main(void) { return f(8)+1; }
		int f(int x) { return g(x); }
		int g(int x) { return x+3; }
		</pre>
	<li>assembler
		<pre>
		_main:
					<i>prologue</i>
			pushl %ebp
			movl %esp, %ebp
					<i>body</i>
			pushl $8
			call _f
			addl $1, %eax
					<i>epilogue</i>
			movl %ebp, %esp
			popl %ebp
			ret
		_f:
					<i>prologue</i>
			pushl %ebp
			movl %esp, %ebp
					<i>body</i>
			pushl 8(%esp)
			call _g
					<i>epilogue</i>
			movl %ebp, %esp
			popl %ebp
			ret

		_g:
					<i>prologue</i>
			pushl %ebp
			movl %esp, %ebp
					<i>save %ebx</i>
			pushl %ebx
					<i>body</i>
			movl 8(%ebp), %ebx
			addl $3, %ebx
			movl %ebx, %eax
					<i>restore %ebx</i>
			popl %ebx
					<i>epilogue</i>
			movl %ebp, %esp
			popl %ebp
			ret
		</pre>
	</ul>

<li>Super-small <tt>_g</tt>:
	<pre>
		_g:
			movl 4(%esp), %eax
			addl $3, %eax
			ret
	</pre>

<li>Compiling, linking, loading:
	<ul>
	<li>	<i>Compiler</i> takes C source code (ASCII text),
		produces assembly language (also ASCII text)
	<li>	<i>Assembler</i> takes assembly language (ASCII text),
		produces <tt>.o</tt> file (binary, machine-readable!)
	<li>	<i>Linker</i> takse multiple '<tt>.o</tt>'s,
		produces a single <i>program image</i> (binary)
	<li>	<i>Loader</i> loads the program image into memory
		at run-time and starts it executing
	</ul>
</ul>


<h2>PC emulation</h2>

<ul>
<li>	Emulator like Bochs works by
	<ul>
	<li>	doing exactly what a real PC would do,
	<li>	only implemented in software rather than hardware!
	</ul>
<li>	Runs as a normal process in a "host" operating system (e.g., Linux)
<li>	Uses normal process storage to hold emulated hardware state:
	e.g.,
	<ul>
	<li>	Hold emulated CPU registers in global variables
		<pre>
		int32_t regs[8];
		#define REG_EAX 1;
		#define REG_EBX 2;
		#define REG_ECX 3;
		...
		int32_t eip;
		int16_t segregs[4];
		...
		</pre>
	<li>	<tt>malloc</tt> a big chunk of (virtual) process memory
		to hold emulated PC's (physical) memory
	</ul>
<li>	Execute instructions by simulating them in a loop:
	<pre>
	for (;;) {
		read_instruction();
		switch (decode_instruction_opcode()) {
		case OPCODE_ADD:
			int src = decode_src_reg();
			int dst = decode_dst_reg();
			regs[dst] = regs[dst] + regs[src];
			break;
		case OPCODE_SUB:
			int src = decode_src_reg();
			int dst = decode_dst_reg();
			regs[dst] = regs[dst] - regs[src];
			break;
		...
		}
		eip += instruction_length;
	}
	</pre>

<li>	Simulate PC's physical memory map
	by decoding emulated "physical" addresses just like a PC would:
	<pre>
	#define KB		1024
	#define MB		1024*1024

	#define LOW_MEMORY	640*KB
	#define EXT_MEMORY	10*MB

	uint8_t low_mem[LOW_MEMORY];
	uint8_t ext_mem[EXT_MEMORY];
	uint8_t bios_rom[64*KB];

	uint8_t read_byte(uint32_t phys_addr) {
		if (phys_addr < LOW_MEMORY)
			return low_mem[phys_addr];
		else if (phys_addr >= 960*KB && phys_addr < 1*MB)
			return rom_bios[phys_addr - 960*KB];
		else if (phys_addr >= 1*MB && phys_addr < 1*MB+EXT_MEMORY) {
			return ext_mem[phys_addr-1*MB];
		else ...
	}

	void write_byte(uint32_t phys_addr, uint8_t val) {
		if (phys_addr < LOW_MEMORY)
			low_mem[phys_addr] = val;
		else if (phys_addr >= 960*KB && phys_addr < 1*MB)
			; /* ignore attempted write to ROM! */
		else if (phys_addr >= 1*MB && phys_addr < 1*MB+EXT_MEMORY) {
			ext_mem[phys_addr-1*MB] = val;
		else ...
	}
	</pre>
<li>	Simulate I/O devices, etc., by detecting accesses to
	"special" memory and I/O space and emulating the correct behavior:
	e.g.,
	<ul>
	<li>	Reads/writes to emulated hard disk
		transformed into reads/writes of a file on the host system
	<li>	Writes to emulated VGA display hardware
		transformed into drawing into an X window
	<li>	Reads from emulated PC keyboard
		transformed into reads from X input event queue
	</ul>
</ul>