General Overview
The frame reflow can be logged with the debug capabilities implemented in nsFrame.cpp. It provides the following information for each frame at the start of its reflow
- reflow reason
- available width, available height
- computed width, computed height
- the previous and the next frame in flow
- and a count number.
When the frame's reflow is finished the following information is displayed :
- reflow metric (desired) width, height
- max. element width
- maximum width
- frame status
- overflow area
Getting the log
- Make sure that your build is a debug build (in short you need
ac_add_options --enable-debug
in your.mozconfig
file). - Create a text file (for instance
reflow_rules.txt
). - Enter this line in the text file
* 1
- This should look like:
- point the
GECKO_DISPLAY_REFLOW_RULES_FILE
environment variable to the path of thereflow_rules.txt
file.
- Run the debug build, saving stdout to a file.
- On Mac this is accomplished with:
$ env DYLD_LIBRARY_PATH="`pwd`/obj-ff-dbg/dist/NightlyDebug.app/Contents/MacOS" \ ./obj-ff-dbg/dist/NightlyDebug.app/Contents/MacOS/firefox-bin > logfile.txt
After loading your testcase, the log file will contain the promised information.
- On Mac this is accomplished with:
Log File analysis
The log file for a simple table like
<!DOCTYPE html PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN"> <html> <head> <meta http-equiv="content-type" content="text/html; charset=ISO-8859-1"> </head> <body> <table width="100"> <tbody> <tr> <td>foo</td> </tr> </tbody> </table> </body> </html>
will create the following log:
VP 00B97C30 r=0 a=9180,4470 c=9180,4470 cnt=856 scroll 00B97EE0 r=0 a=9180,4470 c=9180,4470 cnt=857 scroll 00B97EE0 r=0 a=9180,4470 c=9180,4470 cnt=858 canvas 00B97C6C r=0 a=9180,UC c=9180,4470 cnt=859 area 02D7AFE4 r=0 a=9180,UC c=9180,UC cnt=860 text 02D7B150 r=0 a=9180,UC c=UC,UC cnt=861 text 02D7B150 d=0,0 block 02D7B210 r=0 a=9180,UC c=8940,UC cnt=862 block 02D7B210 d=8940,0 area 02D7AFE4 d=9180,120 canvas 00B97C6C d=9180,4470 scroll 00B97EE0 d=9180,4470 scroll 00B97EE0 d=9180,4470 VP 00B97C30 d=9180,4470 VP 00B97C30 r=1 a=9180,4470 c=9180,4470 cnt=863 scroll 00B97EE0 r=1 a=9180,4470 c=9180,4470 cnt=864 scroll 00B97EE0 r=1 a=9180,4470 c=9180,4470 cnt=865 canvas 00B97C6C r=1 a=9180,UC c=9180,4470 cnt=866 area 02D7AFE4 r=1 a=9180,UC c=9180,UC cnt=867 block 02D7B210 r=1 a=9180,UC c=8940,UC cnt=868 text 02D7B3F8 r=0 a=8940,UC c=UC,UC cnt=869 text 02D7B3F8 d=0,0 tblO 02D7B5F0 r=0 a=8940,UC c=0,0 cnt=870 tbl 02D7B7EC r=0 a=8940,UC c=1500,UC cnt=871 rowG 00B984A4 r=0 a=UC,UC c=UC,UC cnt=872 row 02D7BAF8 r=0 a=UC,UC c=UC,UC cnt=873 cell 02D7BC98 r=0 a=UC,UC c=UC,UC cnt=874 block 02D7BCF8 r=0 a=UC,UC c=UC,UC cnt=875 text 02D7BE84 r=0 a=UC,UC c=UC,UC cnt=876 text 02D7BE84 d=300,285 me=300 block 02D7BCF8 d=300,300 me=300 cell 02D7BC98 d=330,330 me=330 row 02D7BAF8 d=UC,330 rowG 00B984A4 d=UC,330 colG 02D7BFB0 r=0 a=UC,UC c=UC,UC cnt=877 col 02D7C0D8 r=0 a=0,0 c=1500,UC cnt=878 col 02D7C0D8 d=0,0 colG 02D7BFB0 d=0,0 rowG 00B984A4 r=2 a=1500,UC c=1500,UC cnt=879 row 02D7BAF8 r=2 a=1500,UC c=1500,UC cnt=880 cell 02D7BC98 r=2 a=1440,UC c=1410,UC cnt=881 block 02D7BCF8 r=2 a=1410,UC c=1410,UC cnt=882 block 02D7BCF8 d=1410,300 cell 02D7BC98 d=1440,330 row 02D7BAF8 d=1500,330 rowG 00B984A4 d=1500,330 colG 02D7BFB0 r=2 a=1500,UC c=1500,UC cnt=883 col 02D7C0D8 r=0 a=0,0 c=1500,UC cnt=884 col 02D7C0D8 d=0,0 colG 02D7BFB0 d=0,0 tbl 02D7B7EC d=1500,390 tblO 02D7B5F0 d=1500,390 text 02D7C130 r=0 a=8940,UC c=UC,UC cnt=885 text 02D7C130 d=0,0 block 02D7B210 d=8940,390 area 02D7AFE4 d=9180,630 canvas 00B97C6C d=9180,4470 scroll 00B97EE0 d=9180,4470 scroll 00B97EE0 d=9180,4470 VP 00B97C30 d=9180,4470
The first line shows the reflow of the viewport (VP
). This viewport has the address 00B97C30
. It is the initial reflow: r=0
. Other reflow reasons are:
- incremental reflow
- resize reflow
- style change reflow
- dirty reflow
The available width is 9180 twips. The available height is 4470 twips (a=9180,4470
). The computed width is 9180 twips. The computed height is 4470 twips (c=9180,4470
). The line count is 856 (cnt=856
).
Below this is a line that reads:
tblO 02D7B5F0 r=0 a=8940,UC c=0,0 cnt=870
Here the UC
shows that on initial reflow the available height for the outer table frame is unconstrained.
The table cell requires its children to compute the MES. It is reported back from the block as:
block 02D7BCF8 d=300,300 me=300
The block max. element size is 300 twips.
The second table reflow is started at
rowG 00B984A4 r=2 a=1500,UC c=1500,UC cnt=879
where the previous information is used. The block has been required to compute the max. element size only once and it reports now:
block 02D7BCF8 d=1410,300
The block shows the same address as the previous one.
Frames with children that overflow the parent have the NS_FRAME_OUTSIDE_CHILDREN
flag set. For these frames the overflow area is displayed as block 025ED8F0 d=8940,1020 o=(0,0) 9180 x 1020
. The overflow area is specified as (x,y) origin and width x height.
The reflow finishes at the same level where it started.
Advanced reflow debugging
The previously described technique dumps the data for every frame. Sometimes the log is clearer if only the main frames are shown. The entries in the reflow log can be controlled on a frame level. For instance adding text 0
to the rules in reflow_rules.txt
would hide the text entries from the reflow. The display of the following frames can be turned on by adding a line with the frame name and 1
or turned off by adding a line with the frame name and 0
:
short name | layout tag |
---|---|
area | area |
block | block |
br | br |
bullet | bullet |
button | gfxButtonControl |
hr | hr |
frameI | htmlFrameInner |
frameO | htmlFrameOuter |
img | image |
inline | inline |
letter | letter |
line | line |
select | select |
obj | object |
page | page |
place | placeholder |
posInline | positionedInline |
canvas | canvas |
root | root |
scroll | scroll |
caption | tableCaption |
cell | tableCell |
bcCell | bcTableCell |
col | tableCol |
colG | tableColGroup |
tbl | table |
tblO | tableOuter |
rowG | tableRowGroup |
row | tableRow |
textCtl | textInput |
text | text |
VP | viewport |
Once the problem is reduced to a single frame level, placing a breakpoint at DisplayReflowEnterPrint
in nsFrame.cpp is a very efficient way to step through the reflow tree.
Other reflow debug options
GECKO_DISPLAY_REFLOW_FLAG_PIXEL_ERRORS
Setting this option via set GECKO_DISPLAY_REFLOW_FLAG_PIXEL_ERRORS = 1
enables a verification for each coordinate value that the coordinates are aligned at pixel boundaries.
row 0268A594 r=0 a=UC,UC c=UC,20 cnt=870 VALUE 20 is not a whole pixel cell 0268A6C0 r=0 a=UC,UC c=UC,15 cnt=871 block 0268A764 r=0 a=UC,UC c=UC,UC cnt=872 block 0268A764 d=0,0 me=0 cell 0268A6C0 d=0,0 me=0 row 0268A594 d=UC,20 VALUE 20 is not a whole pixel rowG 0268A02C d=UC,695 VALUE 695 is not a whole pixel
While unaligned values at the entrance of a frame reflow can be ignored, when they appear at the exit of a routine this can cause display errors like stray lines. OS2 is very vulnerable to pixel alignment errors as text is drawn on pixel boundaries.
GECKO_DISPLAY_REFLOW_INDENT_UNDISPLAYED_FRAMES
Setting this option via set GECKO_DISPLAY_REFLOW_INDENT_UNDISPLAYED_FRAMES = 1
will cause an advance of the indent even for frames which are blocked via the reflow rules file.
Original Document Information
- Author(s): Bernd Mielke
- Last Updated Date: December 4, 2004
- Copyright Information: Portions of this content are © 1998–2007 by individual mozilla.org contributors; content available under a Creative Commons license | Details.