Assembly III: Procedures. Jin-Soo Kim Computer Systems Laboratory Sungkyunkwan University
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1 Assembly III: Procedures Jin-Soo Kim Computer Systems Laboratory Sungkyunkwan University
2 IA-32 (1) Characteristics Region of memory managed with stack discipline Grows toward lower addresses Register indicates lowest stack address address of top element Bottom Increasing Addresses Grows Down Top 2
3 IA-32 (2) Pushing pushl Src Fetch operand at Src Decrement by 4 Write operand at address given by Bottom Increasing Addresses -4 Grows Down Top 3
4 IA-32 (3) Popping popl Dest Read operand at address given by Increment by 4 Write to Dest Bottom Increasing Addresses +4 Grows Down Top 4
5 IA-32 (4) operation examples pushl %eax popl %edx 0x110 0x110 0x110 0x10c 0x10c 0x10c 0x x x x x %eax 213 %eax 213 %eax 213 %edx 555 %edx 555 %edx x108 0x108 0x104 0x104 0x108 5
6 Procedure Control Flow Use stack to support procedure call and return Procedure call call label Push return address on stack Jump to label Return address value Address of instruction beyond call Procedure return ret Pop address from stack Jump to address 6
7 Procedure Call Example e: e8 3d call 8048b90 <main> : 50 pushl %eax call 8048b90 0x x d =0x08048b90 0x110 0x10c 0x x110 0x10c 0x x104 0x x108 0x108 0x104 %eip 0x804854e %eip 0x804854e 0x8048b90 %eip is program counter 7
8 Procedure Return Example : c3 ret ret 0x110 0x10c 0x108 0x104 0x110 0x10c 123 0x108 0x x x104 0x104 0x108 %eip 0x %eip 0x x %eip is program counter 8
9 -based Languages Languages that support recursion e.g., C, Pascal, Java, etc. Code must be Reentrant Multiple simultaneous instantiations of single procedure Need some place to store state of each instantiation Arguments, local variables, return pointer discipline State for given procedure needed for limited time From when called to when return Callee returns before caller does allocated in frames State for single procedure instantiation 9
10 Frames (1) Code Structure ( ) { who(); } who( ) { (); (); } Procedure recursive ( ) { (); } Call Chain who 10
11 Frames (2) Contents Return information Arguments Local variables & temp space Management Space allocated when enter procedure set-up code Deallocated when return finish code s pointer indicates stack top Frame pointer indicates start of current frame Frame who proc Top 11
12 Frames (3) ( ) { who(); } Call Chain Frame 12
13 Frames (4) who( ) { (); (); } Call Chain who Frame who 13
14 Frames (5) ( ) { (); } Call Chain who Frame who 14
15 Frames (6) ( ) { (); } Call Chain who Frame who 15
16 Frames (7) ( ) { (); } Call Chain who who Frame 16
17 Frames (8) ( ) { (); } Call Chain who Frame who 17
18 Frames (9) ( ) { (); } Call Chain who Frame who 18
19 Frames (10) who( ) { (); (); } Call Chain who Frame who 19
20 Frames (11) ( ) { } Call Chain who Frame who 20
21 Frames (12) who( ) { (); (); } Call Chain who Frame who 21
22 Frames (13) ( ) { who(); } Call Chain who Frame 22
23 IA-32/Linux Frame Current stack frame ( Top to Bottom) Parameters for function about to call Argument build Local variables If can t keep in registers Saved register context Old frame pointer Caller stack frame Return address Pushed by call instruction Arguments for this call Caller Frame Frame () () Arguments Return Addr Old Saved Registers + Local Variables Argument Build 23
24 Revisiting swap (1) int zip1 = 15213; int zip2 = 91125; void call_swap() { swap(&zip1, &zip2); } Calling swap from call_swap call_swap: pushl $zip2 pushl $zip1 call swap # Global Var # Global Var void swap(int *xp, int *yp) { int t0 = *xp; int t1 = *yp; *xp = t1; *yp = t0; } &zip2 &zip1 Resulting 24
25 Revisiting swap (2) void swap(int *xp, int *yp) { int t0 = *xp; int t1 = *yp; *xp = t1; *yp = t0; } swap: pushl movl, pushl %ebx movl 12(),%ecx movl 8(),%edx movl (%ecx),%eax movl (%edx),%ebx movl %eax,(%edx) movl %ebx,(%ecx) movl -4(),%ebx movl, popl ret Setup Body Finish 25
26 Swap Setup (1) Entering Resulting &zip2 &zip1 swap: pushl movl, pushl %ebx yp xp Old 26
27 Swap Setup (2) Entering Resulting &zip2 &zip1 swap: pushl movl, pushl %ebx yp xp Old 27
28 Swap Setup (3) Entering Resulting &zip2 &zip1 swap: pushl movl, pushl %ebx yp xp Old Old %ebx 28
29 Effect of swap Setup Entering Resulting &zip2 12 yp &zip1 8 xp 4 0 Old movl 12(),%ecx movl 8(),%edx... # get yp # get xp Old %ebx Body 29
30 swap Finish (1) swap s Offset Offset 12 yp 12 yp 8 xp 8 xp Old Old %ebx 0-4 Old Old %ebx Observation Saved & restored register %ebx movl 4(),%ebx movl, popl ret 30
31 swap Finish (2) swap s Offset Offset 12 yp 12 yp 8 xp 8 xp Old 0 Old -4 Old %ebx -4 Old %ebx movl 4(),%ebx movl, popl ret 31
32 swap Finish (3) swap s Offset Offset 12 yp 12 yp 8 xp 8 xp Old 0 Old -4 Old %ebx -4 Old %ebx movl 4(),%ebx movl, popl ret 32
33 swap Finish (4) swap s Exiting Offset Offset yp xp Old Old %ebx yp xp Old Old %ebx Observation Saved & restored register %ebx Didn t do so for %eax, %ecx, or %edx movl 4(),%ebx movl, popl ret 33
34 Register Saving Conventions (1) When procedure () calls who(): is the caller, who is the callee Can register be used for temporary storage? : movl $15213, %edx call who addl %edx, %eax ret who: movl 8(), %edx addl $91125, %edx ret Contents of register %edx overwritten by who 34
35 Register Saving Conventions (2) Conventions Caller save Caller saves temporary in its frame before calling Callee save Callee saves temporary in its frame before using 35
36 IA-32/Linux Register Usage Integer registers Two have special uses:, Three managed as callee-save: %ebx, %esi, %edi Old values saved on stack prior to using Three managed as caller-save: %eax, %edx, %ecx Do what you please, but expect any callee to do so, as well Register %eax also stores returned value Caller-Save Temporaries Callee-Save Temporaries Special %eax %edx %ecx %ebx %esi %edi 36
37 Recursive Factorial: rfact Registers %eax used without first saving %ebx used, but save at beginning & restore at end int rfact(int x) { int rval; if (x <= 1) return 1; rval = rfact(x-1); return rval * x; } rfact: pushl movl, pushl %ebx movl 8(),%ebx cmpl $1,%ebx jle.l78 leal -1(%ebx),%eax pushl %eax call rfact imull %ebx,%eax jmp.l79.align 4.L78: movl $1,%eax.L79: movl -4(),%ebx movl, popl ret 37
38 rfact Setup Entering Caller pre pre %ebx x Caller 8 pre pre %ebx x 4 rfact: pushl movl, pushl %ebx 0 Callee -4 Old Old %ebx 38
39 rfact Body Registers %ebx: stored value of x %eax Temporary value of x-1 Returned value from rfact(x-1) Returned value from this call Recursion int rfact(int x) { int rval; if (x <= 1) return 1; rval = rfact(x-1); return rval * x; } movl 8(),%ebx # ebx = x cmpl $1,%ebx # Compare x : 1 jle.l78 # If <= goto Term leal -1(%ebx),%eax # eax = x-1 pushl %eax # Push x-1 call rfact # rfact(x-1) imull %ebx,%eax # rval * x jmp.l79 # Goto done.l78: # Term: movl $1,%eax # return val = 1.L79: # Done: 39
40 rfact Recursion leal -1(%ebx),%eax x pushl %eax Old Old %ebx x Old Old %ebx x-1 call rfact x Old Old %ebx %eax %ebx x-1 x %eax x-1 x-1 %ebx x %eax x-1 %ebx x 40
41 rfact Result Return from Call imull %ebx,%eax x x Old Old Old %ebx Old %ebx x-1 x-1 %eax (x-1)! %eax (x-1)! x! %ebx x %ebx x Assume that rfact(x-1) returns (x-1)! in register %eax 41
42 rfact Completion 8 pre pre %ebx x movl 4(),%ebx movl, popl ret %eax Old Old %ebx x-1 x! pre pre %ebx x Old pre pre %ebx x %ebx Old x %ebx %eax x! %ebx Old %ebx %eax x! %ebx Old %ebx 42
43 Summary The stack makes recursion work Private storage for each instance of procedure call Instantiations don t clobber each other Addressing of locals + arguments can be relative to stack positions Can be managed by stack discipline Procedures return in inverse order of calls Procedures = Instructions + Conventions Call / Ret instructions Register usage conventions Caller / Callee save and frame organization conventions 43
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