I am preparing for a microprocessor exam. If the use of a program counter is to hold the address of the next instruction, what is use of stack pointer?
A stack is a LIFO data structure (last in, first out, meaning last entry you push on to the stack is the first one you get back when you pop). It is typically used to hold stack frames (bits of the stack that belong to the current function).
This may include, but is not limited to:
- the return address.
- a place for a return value.
- passed parameters.
- local variables.
You push items onto the stack and pop them off. In a microprocessor, the stack can be used for both user data (such as local variables and passed parameters) and CPU data (such as return addresses when calling subroutines).
The actual implementation of a stack depends on the microprocessor architecture. It can grow up or down in memory and can move either before or after the push/pop operations.
Operation which typically affect the stack are:
- subroutine calls and returns.
- interrupt calls and returns.
- code explicitly pushing and popping entries.
- direct manipulation of the stack pointer register,
Consider the following program in my (fictional) assembly language:
Addr Opcodes Instructions ; Comments ---- -------- -------------- ---------- ; 1: pc<-0000, sp<-8000 0000 01 00 07 load r0,7 ; 2: pc<-0003, r0<-7 0003 02 00 push r0 ; 3: pc<-0005, sp<-7ffe, (sp:7ffe)<-0007 0005 03 00 00 call 000b ; 4: pc<-000b, sp<-7ffc, (sp:7ffc)<-0008 0008 04 00 pop r0 ; 7: pc<-000a, r0<-(sp:7ffe), sp<-8000 000a 05 halt ; 8: pc<-000a 000b 06 01 02 load r1,[sp+2] ; 5: pc<-000e, r1<-(sp+2:7ffe) 000e 07 ret ; 6: pc<-(sp:7ffc), sp<-7ffe
Now let's follow the execution, describing the steps shown in the comments above:
This is the starting condition where
pc(the program counter) is
8000(all these numbers are hexadecimal).
This simply loads register
r0with the immediate value
pcto the next instruction (I'll assume that you understand the default behavior will be to move to the next instruction unless otherwise specified).
r0onto the stack by reducing
spby two then storing the value of the register to that location.
This calls a subroutine. What would have been
pcin the next step is pushed on to the stack in a similar fashion to
r0in the previous step, then
pcis set to its new value. This is no different to a user-level push other than the fact it's done more as a system-level thing.
r1from a memory location calculated from the stack pointer - it shows a way to pass parameters to functions.
The return statement extracts the value from where
sppoints and loads it into
spup at the same time. This is like a system-level
popinstruction (see next step).
r0off the stack involves extracting the value from where
spcurrently points, then adjusting
haltinstruction simply leaves
pcwhere it is, an infinite loop of sorts.
Hopefully from that description, it will become clear. Bottom line is: a stack is useful for storing state in a LIFO way and this is generally ideal for the way most microprocessors do subroutine calls.
Unless you're a SPARC of course, in which case you use a circular buffer for your stack :-)
Update: Just to clarify the steps taken when pushing and popping values in the above example (whether explicitly or by call/return), see the following examples:
LOAD R0,7 PUSH R0 Adjust sp Store val sp-> +--------+ +--------+ +--------+ | xxxx | sp->| xxxx | sp->| 0007 | | | | | | | | | | | | | | | | | | | +--------+ +--------+ +--------+ POP R0 Get value Adjust sp +--------+ +--------+ sp->+--------+ sp-> | 0007 | sp->| 0007 | | 0007 | | | | | | | | | | | | | | | | | | | +--------+ +--------+ +--------+
3This answer is all kinds of win. Sep 23, 2009 at 5:45
I love SPARC and its register windows :) Sep 23, 2009 at 16:15
1@DenysS, a stack overflow happens when you push too many things - that's going to be a decresing SP assuming the stack grows downward. What happens depends on what it runs into. If it runs into your data, your program will be suspect. If it runs into your code it will probably be catastrophic as the code instructions are set to arbitrary values. The stack going above ffff would actually be a stack underflow (too many pops). In any case, what happens is pretty much a crapshoot - anything could happen so you want to avoid it. Feb 10, 2013 at 10:32
1This is one of the best answers I've ever seen.– suprjamiSep 13, 2014 at 12:36
1@dust, l don't think so. Line 4 calls 000b so that's what ends up in the PC. The halt is the only instruction that doesn't update PC so it effectively halts the program. That's why it sets PC to 000a. Let me know if that clears it up or I've misunderstood. Jun 14, 2018 at 23:32
The stack pointer stores the address of the most recent entry that was pushed onto the stack.
To push a value onto the stack, the stack pointer is incremented to point to the next physical memory address, and the new value is copied to that address in memory.
To pop a value from the stack, the value is copied from the address of the stack pointer, and the stack pointer is decremented, pointing it to the next available item in the stack.
The most typical use of a hardware stack is to store the return address of a subroutine call. When the subroutine is finished executing, the return address is popped off the top of the stack and placed in the Program Counter register, causing the processor to resume execution at the next instruction following the call to the subroutine.
You got more preparing [for the exam] to do ;-)
The Stack Pointer is a register which holds the address of the next available spot on the stack.
The stack is a area in memory which is reserved to store a stack, that is a LIFO (Last In First Out) type of container, where we store the local variables and return address, allowing a simple management of the nesting of function calls in a typical program.
See this Wikipedia article for a basic explanation of the stack management.
For 8085: Stack pointer is a special purpose 16-bit register in the Microprocessor, which holds the address of the top of the stack.
The stack pointer register in a computer is made available for general purpose use by programs executing at lower privilege levels than interrupt handlers. A set of instructions in such programs, excluding stack operations, stores data other than the stack pointer, such as operands, and the like, in the stack pointer register. When switching execution to an interrupt handler on an interrupt, return address data for the currently executing program is pushed onto a stack at the interrupt handler's privilege level. Thus, storing other data in the stack pointer register does not result in stack corruption. Also, these instructions can store data in a scratch portion of a stack segment beyond the current stack pointer.
Read this one for more info.
1Good Lord, do people really patent this stuff? What a crock. I should patent the posting of programming questions and answers to a Q*A site. Then all of you would have to pay me royalties. Sep 23, 2009 at 5:36
The Stack is an area of memory for keeping temporary data. Stack is used by the CALL instruction to keep the return address for procedures The return RET instruction gets this value from the stack and returns to that offset. The same thing happens when an INT instruction calls an interrupt. It stores in the Stack the flag register, code segment and offset. The IRET instruction is used to return from interrupt call.
The Stack is a Last In First Out (LIFO) memory. Data is placed onto the Stack with a PUSH instruction and removed with a POP instruction. The Stack memory is maintained by two registers: the Stack Pointer (SP) and the Stack Segment (SS) register. When a word of data is PUSHED onto the stack the the High order 8-bit Byte is placed in location SP-1 and the Low 8-bit Byte is placed in location SP-2. The SP is then decremented by 2. The SP addds to the (SS x 10H) register, to form the physical stack memory address. The reverse sequence occurs when data is POPPED from the Stack. When a word of data is POPPED from the stack the the High order 8-bit Byte is obtained in location SP-1 and the Low 8-bit Byte is obtained in location SP-2. The SP is then incremented by 2.
The stack pointer holds the address to the top of the stack. A stack allows functions to pass arguments stored on the stack to each other, and to create scoped variables. Scope in this context means that the variable is popped of the stack when the stack frame is gone, and/or when the function returns. Without a stack, you would need to use explicit memory addresses for everything. That would make it impossible (or at least severely difficult) to design high-level programming languages for the architecture. Also, each CPU mode usually have its own banked stack pointer. So when exceptions occur (interrupts for example), the exception handler routine can use its own stack without corrupting the user process.
Should you ever crave deeper understanding, I heartily recommend Patterson and Hennessy as an intro and Hennessy and Patterson as an intermediate to advanced text. They're pricey, but truly non-pareil; I just wish either or both were available when I got my Masters' degree and entered the workforce designing chips, systems, and parts of system software for them (but, alas!, that was WAY too long ago;-). Stack pointers are so crucial (and the distinction between a microprocessor and any other kind of CPU so utterly meaningful in this context... or, for that matter, in ANY other context, in the last few decades...!-) that I doubt anything but a couple of thorough from-the-ground-up refreshers can help!-)
nonpariel - a small, flat chocolate drop covered with white pellets of sugar. Mmm, chocolate and sugar. Oh, you meant the adjective, "without equal"? Well, there's my word learned for the week. Sep 23, 2009 at 6:04
1@pax, pariel != pareil. I before E except when it's not!-) Sep 23, 2009 at 6:07
+1 but I have evil flashback about that book late at night when I'm all alone. The book is excellent... I still have it on my shelf. It's the class associated with it that did it to me.– beggsSep 24, 2009 at 2:03
On some CPUs, there is a dedicated set of registers for the stack. When a call instruction is executed, one register is loaded with the program counter at the same time as a second register is loaded with the contents of the first, a third register is be loaded with the second, and a fourth with the third, etc. When a return instruction is executed, the program counter is latched with the contents of the first stack register and the same time as that register is latched from the second; that second register is loaded from a third, etc. Note that such hardware stacks tend to be rather small (many the smaller PIC series micros, for example, have a two-level stack).
While a hardware stack does have some advantages (push and pop don't add any time to a call/return, for example) having registers which can be loaded with two sources adds cost. If the stack gets very big, it will be cheaper to replace the push-pull registers with an addressable memory. Even if a small dedicated memory is used for this, it's cheaper to have 32 addressable registers and a 5-bit pointer register with increment/decrement logic, than it is to have 32 registers each with two inputs. If an application might need more stack than would easily fit on the CPU, it's possible to use a stack pointer along with logic to store/fetch stack data from main RAM.
A stack pointer is a small register that stores the address of the top of stack. It is used for the purpose of pointing address of the top of the stack.