Handed out Wednesday, September 15, 2004
Due Thursday, September 30, 2004
In this lab, your will write the memory management code for your operating system. Memory management is comprised of two components.
The first component that comes under the umbrella of memory management is virtual memory, where we set up the PC'S Memory Management Unit (MMU) hardware to map the virtual addresses used by software into different, physical addresses for purposes of accessing memory. You will set up the virtual memory layout for JOS according to the specification we provide. Your task will be to build a page table data structure to match our specification.
The second component is managing the physical memory of the computer so that the kernel can be dynamically allocate memory for various uses, and later deallocate that memory and re-assign it for different purposes. The x86 divides physical memory up into 4096 byte regions called pages. Your task will be to maintain data structures that record which pages are free and allocated and how many processes are sharing each allocated page. You will also write the routines to allocate and free pages of memory.
Download the code for lab 2 from http://pdos.lcs.mit.edu/6.828/2004/labs/lab2/lab2.tar.gz and untar it into your 6.828 directory, just as you did for lab 1. You will then need to merge the changes between our lab 1 and lab 2 source code trees into your own kernel code resulting from completing lab 1.
In this and future labs you will progressively build on this same kernel. With each new lab we will hand out a source tree containing additional files and possibly some changes to existing files. You will need to compare the new source tree against the one we provided for the previous lab in order to figure out what new code you need to incorporate into your kernel. You may find it useful to keep a "pristine" copy of our source tree for each lab around along with your modified versions. You should expect to become intimately familiar with the Unix diff utility if you aren't already, and patch can be highly useful as well. If you're particularly organized you might try using cvs and learn how to deal with branches. "Diff-and-merge" is an important and unavoidable component of all real OS development activity, so any time you spend learning to do this effectively is time well spent.
One option is to just merge in your changes manually. If you remember what functions you modified, you can copy the changes into the lab2 code. To actually see what changes you made, and try to patch them in to the code, run the following sequence of commands. Be warned that these utilities are not perfect, and merging in the changes by hand may be simpler.
cd ~/6.828 # this creates a tar of what you handed in, for backup purposes tar czvf lab1-handin.tar.gz lab1 mkdir given-code cd given-code tar xzf ../lab1.tar.gz cd .. mv given-code/lab1 lab1-unchanged # now we have the handed out lab1 code in lab1-unchanged diff -r -u lab1-unchanged lab1 > lab1-changes.txt # It is very important to look at the patch file. All of the changes # in it should be for code that you added to lab 1 and want to bring # to lab 2. If there are other changes (like changes to the # makefiles), then you should NOT run the 'patch' command below. # Instead, you should apply the patch by hand. If you decide to apply # it with patch, then run the commands below. cd lab2 patch -p1 -u < ../lab1-changes.txt # if any chunks failed, then you will need to look at the rejects # files (.rej) and merge those changes in yourself.
Lab 2 contains the following new source files, which you should browse through as you merge them into your kernel:
When you are ready to hand in your lab code and write-up, run gmake handin in the lab2 directory. This will first do a gmake clean to clean out any .o files and executables, and then tar up and submit the entire contents of your lab2 directory.
As before, we will be grading your solutions with a grading program. You can run gmake grade in the lab2 directory to test your kernel with the grading program. You may change any of the kernel source and header files you need to in order to complete the lab, but needless to say you must not change or otherwise subvert the grading code.
Before doing anything else, you will need to familiarize yourself with the x86's protected-mode memory management architecture: namely segmentation and page translation.
| Exercise 1. Read chapters 5 and 6 of the Intel 80386 Reference Manual, if you haven't done so already. Although JOS relies most heavily on page translation, you will also need a basic understanding of how segmentation works in protected mode to understand what's going on in JOS. |
In x86 terminology, a virtual address is a "segment:offset"-style address before segment translation is performed; a linear address is what you get after segmentation but before page translation; and a physical address is what you finally get after both segmentation and page translation. Be sure you understand the difference between these three types or "levels" of addresses!
Exercise 2.
Review the
debugger section in the
Bochs user manual,
and make sure you understand which debugger commands
deal with which kinds of addresses.
In particular, note the various vb, lb,
and pb breakpoint commands to set breakpoints at
virtual, linear, and physical addresses.
The default b command breaks at a physical address.
Also note that the x command
examines data at a linear address,
while the command xp takes a physical address.
Sadly there is no xv at all.
|
In Part 3 of Lab 1 we noted that the boot loader sets up the x86 segmentation hardware so that the kernel appears to run at its link address of 0xf0100020, even though it is actually loaded in physical memory just above the ROM BIOS at 0x00100020. In other words, the kernel's virtual starting address at this point is 0xf0100020, but its linear and physical starting addresses are both 0x00100020. The kernel's linear and physical addresses are the same because we have not yet initialized or enabled page translation.
In the virtual memory layout you are going to set up for JOS, we will stop using the x86 segmentation hardware for anything interesting, and instead start using page translation to accomplish everything we've already done with segmentation and much more. That is, after you finish this lab and the JOS kernel successfully enables paging, linear addresses will be the same as (the offset portion of) the kernel's virtual addresses, rather than being the same as physical addresses as they are when the boot loader first enters the kernel.
In JOS,
we divide the processor's 32-bit linear address space
into two parts.
User environments (processes),
which we will begin loading and running in lab 3,
will have control over the layout and contents of the lower part,
while the kernel always maintains complete control over the upper part.
The dividing line is defined somewhat arbitrarily
by the symbol ULIM in inc/pmap.h,
reserving approximately 256MB of linear (and therefore virtual) address space
for the kernel.
This explains why we needed to give the kernel
such a high link address in lab 1:
otherwise there would not be enough room in the kernel's linear address space
to map in a user environment below it at the same time.
Since the kernel and user environment will effectively co-exist in each environment's address space, we will have to use permission bits in our x86 page tables to prevent user code from accessing the kernel's memory: i.e., to enforce fault isolation. We do this as follows.
The user environment will have no permission to any of the
memory above ULIM, while the kernel will be able to
read and write this memory. For the address range
(UTOP,ULIM], both the kernel and the user environment have
the same permission: they can read but not write this address range.
This range of address is used to expose certain kernel data structures
read-only to the user environment. Lastly, the address space below
UTOP is for the user environment to use; the user environment
will set permissions for accessing this memory.
In this lab, you are going to set up the address space above
UTOP - the kernel part of the address space.
The layout of this portion of the virtual address space will be
handled by the i386_vm_init() function, defined in
kern/pmap.c. The actual layout is as described
is diagrammed in inc/pmap.h. It would behoove you to
become familiar with this file
as well as inc/mmu.h,
which contains useful macros and definitions
relating to the x86 memory management hardware.
Exercise 3.
Implement the following functions in kern/pmap.c:
alloc() boot_pgdir_walk() boot_map_segment() i386_vm_init()The comments in i386_vm_init() specify the virtual memory
layout. Your task is to fill in the missing code to build a 2-level
page table fulfilling this specification.
The other functions are helper routines you will find useful.
Once you have done this, run the code. The function call to
|
Make sure you can answer these questions:
| Entry | Base Virtual Address | Points to (logically): |
| 1023 | ? | Page table for top 4MB of phys memory |
| 1022 | ? | ? |
| . | ? | ? |
| . | ? | ? |
| . | ? | ? |
| 2 | 0x00800000 | ? |
| 1 | 0x00400000 | ? |
| 0 | 0x00000000 | [see next question?] |
i386_vm_init(), after
check_boot_page_directory, we map the first entry of
the page directory to the page table of the first four MB of
RAM, but delete this mapping at the end of the function. Why is
this necessary? What would happen if it were omitted? Does this
actually limit our kernel to be 4MB? What must be true if our
kernel were larger than 4MB?Is there a comparable mechanism on the PDP-11/40 which would provide the fault isolation necessary to allow the kernel and the user environment to run in the same address space? (read: "same address space" as "with the same set of PARs/PDRs")
|
Challenge!
We wasted a lot of page tables to allocate the KERNBASE mapping.
Do a better job using the PTE_PS ("Page Size") bit
in the page directory entries.
This bit was not supported in the original 80386,
but is supported on more recent x86 processors.
You will therefore have to refer to
Volume 3
of the current Intel manuals.
Make sure you design the kernel to use this optimization
only on processors that support it! Note: If you compiled bochs yourself, be sure that the appropriate configuration options were specified. By default bochs does not support some extended page table features, and the tools.html page did not include them at the beginning of the term. |
Challenge!
Extend the JOS kernel monitor with commands to:
|
Many other address space layout schemes besides the one we chose for JOS are certainly possible; all of this is up to the operating system. It is possible, for example, to map the kernel at low linear addresses while leaving the upper part of the linear address space for user processes to use. x86 kernels generally do not take this approach, however, because one of the x86's backward-compatibility modes, known as virtual 8086 mode, is "hard-wired" in the processor to use the bottom part of the linear address space, and thus cannot be used at all if the kernel is mapped there.
It is even possible, though much more difficult, to design the kernel so as not to have to reserve any fixed portion of the processor's linear or virtual address space for itself, but instead effectively to allow allow user-level processes unrestricted use of the entire 4GB of virtual address space - while still fully protecting the kernel from these processes and protecting different processes from each other!
| Challenge! Write up an outline of how a kernel could be designed to allow user environments unrestricted use of the full 4GB virtual and linear address space. Hint: the technique is sometimes known as "follow the bouncing kernel." In your design, be sure to address exactly what has to happen when the processor transitions between kernel and user modes, and how the kernel would accomplish such transitions. Also describe how the kernel would access physical memory and I/O devices in this scheme, and how the kernel would access a user environment's virtual address space during system calls and the like. Finally, think about and describe the advantages and disadvantages of such a scheme in terms of flexibility, performance, kernel complexity, and other factors you can think of. |
Exercise 4.
In the file kern/pmap.c,
you must implement code for
the five functions listed below: You may find it useful
to read inc/pmap.h and kern/pmap.h.
page_init() page_alloc() page_free() pgdir_walk() page_insert() page_remove()
The function |
Be able to answer the following questions:
|
Challenge!
Since our JOS kernel's memory management system
only allocates and frees memory on page granularity,
we do not have anything comparable
to a general-purpose malloc/free facility
that we can use within the kernel.
This could be a problem if we want to support
certain types of I/O devices
that require physically contiguous buffers
larger than 4KB in size,
or if we want user-level environments,
and not just the kernel,
to be able to allocate and map 4MB superpages
for maximum processor efficiency.
(See the earlier challenge problem about PTE_PS.) Note: If you compiled bochs yourself, be sure that the appropriate configuration options were specified. By default bochs does not support some extended page table features, and the tools.html page did not include them at the beginning of the term. Generalize the kernel's memory allocation system to support pages of a variety of power-of-two allocation unit sizes from 4KB up to some reasonable maximum of your choice. Be sure you have some way to divide larger allocation units into smaller ones on demand, and to coalesce multiple small allocation units back into larger units when possible. Think about the issues that might arise in such a system. |
Challenge!
Extend the JOS kernel monitor with commands to
allocate and free pages explicitly,
and display whether or not any given page of physical memory
is currently allocated.
For example:
K> alloc_page 0x13000 K> page_status 0x13000 allocated K> free_page 0x13000 K> page_status 0x13000 freeThink of other commands or extensions to these commands that may be useful for debugging, and add them. |
This completes the lab.