Archive for the 'mozilla' Category

• Go to the Debian Mozilla Team page.
• Select the Debian version you are running, "Iceweasel" and the version, "5.0".
• Follow the instructions.
• Profit.

Only amd64 and i386 packages are available. Note that there is another Iceweasel "version" available there: "aurora". Currently, this is the same as "5.0", but whenever Firefox 5.0 will reach the beta stage, "aurora" will be 6.0a2. Please feel free to use "aurora" if you want to keep using these pre-beta builds.

I'm glad that 5 years after the facts, people are still not getting them straight.

The Firefox logo was not under a free copyright license. Therefore, Debian was using the Firefox name with the "earth" logo (without the fox), which was and still is under a free copyright license. Then Mozilla didn't want the Firefox name associated to an icon that is not the Firefox icon, for trademark reasons. Fair enough.

Although at the time Debian had concerns with the trademark policy, there was no point arguing over it, since Debian was not going to use the logo under a non-free copyright license anyway.

Now, it happens that the logo has turned to a free copyright license. Request for a trademark license was filed a few weeks after we found out about the good news, and we are still waiting for an agreement draft from Mozilla to hopefully go forward.

It is still not certain that this will actually lead to Debian shipping something called Firefox some day, but things are progressing, even if at a rather slow pace, and I have good hope (discussions are promising).

By the way, thank you for the nice words, Daniel.

最近のIceweaselベータでメニューバーを隠して、その代わりにIceweaselボタンが表示されます。そうするにはメニューバーに右クリックして、メニューバーを無効にしたらIceweaselボタンが現れます。

あまり魅力的ではありませんし、タブバーの場所を無駄に取りますが、少しのCSSで変えられます。ユーザーのプロファイルのchrome/userChrome.cssに下記のCSSを追加して下さい：

#appmenu-toolbar-button {
  list-style-image: url("chrome://branding/content/icon16.png");
}
#appmenu-toolbar-button > .toolbarbutton-text,
#appmenu-toolbar-button > .toolbarbutton-menu-dropmarker {
  display: none !important;
}

それで、Iceweaselはこうなります：

Recent Iceweasel betas allows to replace the menu bar with a Iceweasel button. This is not enabled by default, but right-clicking on the menu bar allows to disable the menu bar, which enables the Iceweasel button.

The button is not exactly very appealing, and takes quite a lot of horizontal space on the tab bar. But with a few lines of CSS, this can fortunately be changed. Edit the chrome/userChrome.css file under your user profile, and add the following lines:

#appmenu-toolbar-button {
  list-style-image: url("chrome://branding/content/icon16.png");
}
#appmenu-toolbar-button > .toolbarbutton-text,
#appmenu-toolbar-button > .toolbarbutton-menu-dropmarker {
  display: none !important;
}

This what Iceweasel looks like, then:

お久しぶりです。

Debianアーカイブでまだ配布出来ないパッケージの配布の仕方を変化させていただきました。これからは4.0ベータを利用するには下記のAPTのソースを追加してください：

deb http://mozilla.debian.net/ experimental iceweasel-4.0

Experimentalのリポジトリも必要ですので、APTのsources.listに追加してください。その設定で4.0ベータのインストールが下記の通りに簡単なはずです：

# apt-get install -t experimental iceweasel

Squeezeでもunstableでも利用出来るはずです。

Debian Lenny向けのIceweasel 3.6のbackportも配布します。インストールするには下記のAPTのソースを追加してください：

deb http://mozilla.debian.net/ lenny-backports iceweasel-3.6

Lenny-backportsのリポジトリも必要ですので、APTのsources.listに追加してください。Experimentalのようにインストールが下記の通りに簡単なはずです：

# apt-get install -t lenny-backports iceweasel

APTが公開鍵を利用出来ない場合は公開鍵をAPTキーリングに追加する説明を読んでみてください(英語)。

I made some changes as to how packages from the Debian Mozilla team that can't yet be distributed in the Debian archives are distributed to users. Please update your APT sources and now use the following for 4.0 beta packages:

deb http://mozilla.debian.net/ experimental iceweasel-4.0

You'll also need the experimental repository in your sources, but the overall installation is much easier now:

# apt-get install -t experimental iceweasel

This should work for squeeze and unstable users.

I also added Iceweasel 3.6 backports for Debian Lenny users. For these, add the following APT source:

deb http://mozilla.debian.net/ lenny-backports iceweasel-3.6

You'll also need the lenny-backports repository in your sources. As for the experimental packages above, installation should be as easy as:

# apt-get install -t lenny-backports iceweasel

If your APT complains about the archive key, please check the instructions to add the key to your APT keyring.

I did some experiments with the small tool I wrote in previous post in order to gather some startup data about Firefox. It turns out it can't flush directories and other metadata from the page cache, making it unfortunately useless for what I'm most interested in.

So, I gathered various startup information about Firefox, showing how page cache (thus I/O) has a huge influence on startup. The data in this post are mean times and 95% confidence interval for 50 startups with an existing but fresh profile, in a mono-processor GNU/Linux x86-64 virtual machine (using kvm) with 1GB RAM and a 10GB raw hard drive partition over USB, running, except when said otherwise, on an i7 870 (up to 3.6GHz with Intel Turbo Boost). The Operating System itself is an up-to-date Debian Squeeze running the default GNOME environment.

Firefox startup time is measured as the difference between the time in ms right before starting Firefox and time in ms as returned by javascript in a data:text/html page used as home page.

Startup vs. page cache

The selectively cold cache case makes use of the flush program from previous post and a systemtap script used to get the list of files read during startup. This script will be described in a separate post.

As you can see, profiling startup after echo 3 > /proc/sys/vm/drop_caches takes significantly more time than in the normal conditions users would experience, because of all system libraries that would normally be in the page cache being flushed, hence biasing the view one can have of the actual startup performance. Mozilla build bots were running, until recently, a ts_cold startup test that, as I understand it, had this bias (which is part of why it was stopped).

The Hot cache value is also interesting because it shows that the vast majority of cold startup time is due to hard disk I/O (and no, there is no page faults number difference).

I/O vs CPU

Interestingly, testing on a less beefy machine (Core 2 Duo 2.2GHz) with the same USB disk and kvm setup shows something not entirely intuitive:

I, for one, would have expected I/O bound startups to only be slower by around 320ms, which is roughly the hot cache startup difference, or, in other words, the CPU bound startup difference. But I figured I was forgetting an important factor.

I/O vs. CPU scaling

Modern processors do frequency scaling, which allows the processor to run slowly when underused, and faster when used, thus saving power. It was first used on laptop processors to reduce power drawn from the battery, allowing batteries to last longer, and is now used on desktop processors to reduce power consumption. It unfortunately has a drawback, in that it introduces some latency when the scaling kicks in.

A not so nice side effect of frequency scaling is that when a process is waiting for I/O, the CPU is underused, making the CPU usually run at its slowest frequency. When the I/O ends and the process runs again, the CPU can go back to full speed. This means every I/O can induce, on top of latency because of, e.g. disk seeks, CPU scaling latency. And it actually has much more impact than I would have thought.

Here are results on the same Core 2 Duo, with frequency scaling disabled, and the CPU forced to its top speed :

(I would have liked to do the same on the i7, but Intel Turbo Boost complicates things and I would have needed to get two new sets of data)

Update: I actually found a way to force one core at its max frequency and run kvm processes on it, giving the following results:

I haven't gathered enough data to have accurate figures, but it also seems that forcing the CPU frequency to a fraction of the fastest supported frequency gives the intuitive results where the difference between all I/O bound startup times is the same as the difference for hot cache startup times. As such, I/O bound startup improvements would be best measured as an improvement in the difference between cold and hot cache startup times, i.e. (cold2 - hot2) - (cold1 - hot1), at a fixed CPU frequency.

Startup vs. desktop environment

We saw above that the amount of system libraries in page cache directly influences application startup times. And not all GNU/Linux systems are made equal. While the above times were obtained under a GNOME environment, some other desktop environments don't use the same base libraries, which can make Firefox require to load more of them at cold startup. The most used environment besides GNOME is KDE, and here is what cold startup looks like under KDE:

It's significantly slower, yet not as slow as the entirely cold cache case. This is due to KDE not using (thus not pre-loading) some of the GNOME core libraries, yet using libraries in common, like e.g. libc (obviously), or dbus.

If you have been following this blog during the past months, you might have gathered that I've been focusing on I/O patterns on library initialization, more specifically libxul.so. The very patterns there's not much to do about, except enduring them, or hacking ld.so and/or the toolchain. The latter is not necessarily easy, and won't benefit everyone until all linux distros use an improved glibc and/or toolchain. This could take years before any actual result would reach end users.

But with a little creativity, one can overcome these limitations and improve the situation today. Here is a summary of my recent hacks.

Backwards static initializers

As Taras showed in the past, static initializers are executed in reverse order. It turns out it is an unfortunate design choice in gcc, and it also turns out not to impact all ELF binary files.

As far as I know there are currently two different implementations of the static initializers call loop, one provided by gcc, and one provided by ld.so.

In the gcc case, the compiler creates a .ctors section, starting with 0xffffffff, ending with 0x00000000, and filled with pointers to the various static initializer functions, in ascending order. The compiler also injects an initializer function, called from .init, going through this .ctors section, starting from the end (__do_global_ctors_aux in crtend.o). A similar .dtors section is created for functions to run when the library is unloaded, and the pointers in it are called in ascending order. There is actually no importance in the order in which .ctors and .dtors are executed. All that matters is that they are executed in reverse order from each other, because that limits the risks of bad ordering. It is only unfortunate that .ctors was chosen to be the one backwards.

In the ld.so case, the compiler creates a .init_array section, filled with pointers to the various static initializer functions, in ascending order. It also stores the location and the size of this section in the PT_DYNAMIC ELF header. At runtime, ld.so itself reads this information and executes the static initializers in ascending orders. A similar .fini_array section is created for functions to run when the library in unloaded, and ld.so goes through it in descending order.

The .init_array section is newer, and for backwards compatibility reasons, is not used on systems that have been using the .ctors approach forever. On the other hand, some newer ABIs, such as arm EABI, uses the new facility, which means they are not victim of backwards static initialization. I however wonder if backwards compatibility is still needed, considering how long .init_array support has been around (more than 11 years, according to glibc git repository).

While we could obviously bug the gcc maintainers to revert their .ctors execution order, or ditch .ctors support on glibc systems, which means we wouldn't get any immediate global benefit, we can also just revert the .ctors section content. Please note the source code out there doesn't take care of reverting the .dtors section accordingly, because it is currently empty in libxul.so.

Relocations

As I mentioned in an earlier post, relocations are what make it possible to load libraries at arbitrary locations. Unfortunately, a great number of relocations means awful I/O patterns: ld.so reads and applies them one by one, and while the kernel reads ahead by 128 KB chunks, when your relocation section exceeds that amount by more than an order of magnitude, it means I/O goes back and forth a lot between the relocation section and where the relocations take place.

There are two classes of relocations: REL and RELA. In both cases, there are several types of relocations, some of which require an addend. The difference between both classes is in REL relocations, the addend is stored at the offset the relocation takes place, and in RELA relocations, the addend is stored in the relocation entry. It means that RELA relocations effectively waste space, as the addend ends up actually being stored twice: it is also stored at the offset the relocation takes place, like with REL relocations, though it could technically be nulled out, there ; in any case, the space is wasted.

REL relocations thus take 2 words of storage, and RELA relocations, 3. On x86, the ELF ABI only uses REL relocations, and words are 32 bits, making each relocation take 8 bytes ; on x86-64, the ELF ABI only uses RELA relocations, and words are 64 bits, thus making each relocation take 24 bytes, 3 times that of x86 relocations. On ARM, both may be used, but apparently the compiler and the linker only use REL relocations.

These words of storage are used to store 3 or 4 bits of informations:

• r_offset: the offset at which the relocation takes place
• r_info: containing both the relocation type and a symbol reference for the relocation. On 32 bits systems, the symbol reference is stored on 24 bits, and the relocation type on 8 bits. On 64 bits systems, the symbol reference is stored on 32 bits, and the relocation type on 32 bits (which means at least 24 bits are never going to be used: there are currently no ABI using more than 256 relocation types).
• r_addend: The addend, only in RELA relocations

The linker splits relocations in two main categories: those for dynamic linking at startup and those for procedure linkage table (PLT) resolution at runtime. Here is what the repartition look like on libxul.so (taken from the mozilla-central nightly from Nov, the 22nd):

So, PLT relocations are quite negligible, and dynamic relocations are just huge, especially on x86-64. Compared to the binary size, it's pretty scary:

Let me remind you that not only do we need to read these relocations at startup (at least the dynamic ones, but the PLT ones are just negligible), but we only read them by chunks, and need to read other data in between.

Of the many existing types of relocations, only a few are actually used in dynamic libraries. Here is a summary of those in use in libxul.so:

The above types can be separated in two distinct categories:

• Requiring symbols resolution (R_*_GLOB_DAT, R_*_JUMP_SLOT, R_386_32, R_X86_64_64)
• Not requiring symbols resolution (R_*_RELATIVE, R_386_TLS_DTPMOD32, R_X86_64_TLS_DTPMOD64)

In the second category, it means we are wasting all the bits for the symbol reference in each entry: 24 on x86 and 32 on x86-64. Unfortunately, the vast majority of the relocations in libxul.so are from that category. At this point, this is how much waste we identified:

On top of that, one could argue that we don't need 24 or 32 bits for symbol reference (which is the entry number in the symbol table), and that we're really far from requiring 64 bits for r_offset on 64 bits systems, as libxul.so is far from being bigger than 4GB. Anyways, that means we have room for improvement here, and it means that the ELF format, especially on 64 bits systems with RELA relocations, really doesn't help with big programs or libraries with a lot of relocations. (For that matter, the mach-o format used on OS-X has some kind of similar issues ; I don't know for the DLL format)

Another interesting data point is looking at how relocations' r_offset are following each other, once relocations are reordered (to avoid too much symbol resolution, they are actually grouped by symbol). It turns out 206,739 relocations' r_offset are at 4 bytes from the previous one on x86 (i.e. strictly following it), and 210,364 at 8 bytes from the previous on x86-64. The main reason why this happens is that most relocations are happening in pointer tables, and libxul.so has lots of them:

• That's what you get with virtual methods in C++.
• That's also what you get in .ctors and .dtors sections, which are relocated as well (but not .init_array and .fini_array sections).
• That's what you get when you use function tables.
• Obvously, that's what you get when you use pointer tables.

And when I say libxul.so has lots of them, that's not an understatement: there are 184,320 relocations due to vtables (function tables you get when using virtual methods in C++) on x86 and 184,098 on x86-64. That's respectively 78.23% and 76.81% of the total number of relocations. Interestingly, while most of these relocations are R_*_RELATIVE, 26,853 are R_386_32, and 26,829 are R_X86_64_64. Except for a very few, these non relative relocations are for the __cxa_pure_virtual symbol, which is a dummy function that does nothing, used for pure virtual methods, such as the following:

class Abstract {
public:
virtual void pure_virtual() = 0;
};

As for the remaining relative relocations, there are a few pointer tables responsible for several thousand relocations, such as JSString::length2StringTable, gEntries, GkAtoms_info, Html5Atoms_info, kUnixCharsets, nsIDOMCSS2Properties_properties, etc.

Packing relocations

While they are not detrimental to most binaries, we saw that relocations can have a bad effect on startup I/O for big binaries. Reducing how much space they take would have a direct impact on these startup I/Os. One way to do so is obviously to reduce the number of relocations. But as we saw above, the vast majority are due to vtables. While reducing vtables would be a nice goal, it's a long way before this can have a significant impact on the relocations number. So another possible way is to try to avoid wasting so much space in relocations.

The main problem is that relocations are applied by ld.so, and that, as mentioned in the introduction, while we can hack ld.so to do what we want, it won't work everywhere before a long time. Moreover, it's difficult to test various implementations, and binary compatibility needs to be guaranteed once something is applied in the upstream libc.

The idea I started to test a few weeks ago, is to effectively apply relocations by hand instead of relying on ld.so doing it. Considering the first thing ld.so does with a library after applying relocations is to call its DT_INIT function, the idea was to replace the dynamic relocations we can with a new DT_INIT function we would inject that'd apply those relocations, while storing them in a more efficient manner. The function would obviously need to call the original DT_INIT function once done. Some parts of the PT_DYNAMIC section also obviously need to be adjusted accordingly.

The first iteration I tested a few weeks ago helped validating the idea, but didn't change much of the binary: the dynamic relocation section still was taking all the space it took before, though its content was mostly empty (we'll see further below how efficient even the current dumb format is). Once the theory that an injected DT_INIT function could apply the relocations without breaking everything, I went on to implement a program that would actually strip the ELF binary. I won't get too much into the gory details, but it required PT_LOAD splitting, thus program headers growth, which means moving the following sections, then removing a huge part of the relocations, shrinking the relocations section, injecting our code and the packed relocations as sections, and moving the remaining sections after these new sections, to avoid empty space, but still respecting the proper offsets for both PT_LOAD and the code itself.

So far, I only took care of the R_*_RELATIVE relocations. Some but not all other relocations could be taken care of, too, but everything involving symbol resolution from other libraries would be really difficult to handle from the injected code. The relocations are currently stored with a quite dumb format:

• a 32 bits word containing r_offset
• a 32 bits word containing the number of relocations to apply consecutively

As we only take care of one type of relocations, we can skip any information about the type. Also, the addend already being stored at r_offset, we just strip it from RELA relocations ; the binary being far from 4GB big, 32 bits is enough on 64 bits systems too. We also saw that a lot of relocations were next to the following ones, so instead of storing r_offset for each one, storing some kind of range is more efficient. As I've so far been focusing on getting something that actually works more than on getting something really efficient, I only tested this format, but the results are already nice:

Getting rid of the __cxa_pure_virtual relocations would help getting this even further down, and an even better storage format could be used, too. Gathering new startup coverage data should be interesting as well.

The code is available via mercurial. Please note the Makefile deeply sucks, and that the code is in the middle of its third refactoring. Anyways, once you get the code to compile, you just need to run test-x86 or test-x64 depending on your architecture, from the build directory, and give it the libxul.so file as an argument. It will create a libxul.so.new file that you can use to replace libxul.so. You may successfully use the tool on other libraries, but chances are you'll bump into an assert(), or in the worst case, that the resulting library ends up broken. The tool might work on PIE executables, but most probably not on other executables. If you wonder, Chrome is not PIE. It's not even relocatable (which means ASLR won't work with it) ; or at least the x86-64 binaries I just got aren't.

More possible ELF hacking

The code I wrote to pack relocations allows to do various tricks on ELF files, and it opens various opportunities, such as:

• Aligning .bss. As I wrote on this blog a while ago, ld.so fills the last page from the .data section with zeroes, starting at the offset of the .bss section. Unfortunately, this means reading ahead at most 128KB of data nobody needs, and the corresponding disk seek. Inserting a section full of zeroes between .data and .bss would get rid of that, while minimally wasting space (less than 4KB in a 20MB+ binary).
• Trying to move the PT_DYNAMIC section. It is one of the first bunch of data to be read from programs and libraries, yet it is near the end of the binary.
• Replacing .ctors/.dtors with .init_array/.fini_array (thus removing the corresponding relocations, though there's only around 300 of them).
• Replacing the __cxa_pure_virtual relocations with relative relocations pointing to an injected dummy function (it could even just point to any ret code in any existing function).
• Replacing some internal symbol resolutions with relative relocations (which should be equivalent to building with -Bsymbolic)
• etc.

Some of the above could probably be done with linker scripts, but using linker scripts is unnecessarily over complicated: as soon as you start using a linker script to fiddle with sections, you need to reimplement the entire default linker script (the one you can see with ld --verbose). And it's not guaranteed to work (Taras told me he had a hard time failing to align the .bss section). And as far as I know, you can't use the same thing depending whether you use ld or gold (AIUI, gold doesn't support the whole ld linker script syntax).

You may have been using the repository as described on a previous blog post. You may also have noticed that despite a lack of announcement, all beta releases but 4.0beta6 have been subsequently made available on that repository (moreover, within 24 hours of the upstream release). I just made a change to that repository which will most likely make your APT complain, but all the necessary instructions are given on the repository itself.