*usr_29.txt* For Vim version 7.1. Last change: 2006 Apr 24
VIM USER MANUAL - by Bram Moolenaar
Moving through programs
The creator of Vim is a computer programmer. It's no surprise that Vim
contains many features to aid in writing programs. Jump around to find where
identifiers are defined and used. Preview declarations in a separate window.
There is more in the next chapter.
|29.1| Using tags
|29.2| The preview window
|29.3| Moving through a program
|29.4| Finding global identifiers
|29.5| Finding local identifiers
Next chapter: |usr_30.txt| Editing programs
Previous chapter: |usr_28.txt| Folding
Table of contents: |usr_toc.txt|
==============================================================================
*29.1* Using tags
What is a tag? It is a location where an identifier is defined. An example
is a function definition in a C or C++ program. A list of tags is kept in a
tags file. This can be used by Vim to directly jump from any place to the
tag, the place where an identifier is defined.
To generate the tags file for all C files in the current directory, use the
following command: >
ctags *.c
"ctags" is a separate program. Most Unix systems already have it installed.
If you do not have it yet, you can find Exuberant ctags here:
http://ctags.sf.net ~
Now when you are in Vim and you want to go to a function definition, you can
jump to it by using the following command: >
:tag startlist
This command will find the function "startlist" even if it is in another file.
The CTRL-] command jumps to the tag of the word that is under the cursor.
This makes it easy to explore a tangle of C code. Suppose, for example, that
you are in the function "write_block". You can see that it calls
"write_line". But what does "write_line" do? By placing the cursor on the
call to "write_line" and pressing CTRL-], you jump to the definition of this
function.
The "write_line" function calls "write_char". You need to figure out what
it does. So you position the cursor over the call to "write_char" and press
CTRL-]. Now you are at the definition of "write_char".
+-------------------------------------+
|void write_block(char **s; int cnt) |
|{ |
| int i; |
| for (i = 0; i < cnt; ++i) |
| write_line(s[i]); |
|} | |
+-----------|-------------------------+
|
CTRL-] |
| +----------------------------+
+--> |void write_line(char *s) |
|{ |
| while (*s != 0) |
| write_char(*s++); |
|} | |
+--------|-------------------+
|
CTRL-] |
| +------------------------------------+
+--> |void write_char(char c) |
|{ |
| putchar((int)(unsigned char)c); |
|} |
+------------------------------------+
The ":tags" command shows the list of tags that you traversed through:
:tags
# TO tag FROM line in file/text ~
1 1 write_line 8 write_block.c ~
2 1 write_char 7 write_line.c ~
> ~
>
Now to go back. The CTRL-T command goes to the preceding tag. In the example
above you get back to the "write_line" function, in the call to "write_char".
This command takes a count argument that indicates how many tags to jump
back. You have gone forward, and now back. Let's go forward again. The
following command goes to the tag on top of the list: >
:tag
You can prefix it with a count and jump forward that many tags. For example:
":3tag". CTRL-T also can be preceded with a count.
These commands thus allow you to go down a call tree with CTRL-] and back
up again with CTRL-T. Use ":tags" to find out where you are.
SPLIT WINDOWS
The ":tag" command replaces the file in the current window with the one
containing the new function. But suppose you want to see not only the old
function but also the new one? You can split the window using the ":split"
command followed by the ":tag" command. Vim has a shorthand command that does
both: >
:stag tagname
To split the current window and jump to the tag under the cursor use this
command: >
CTRL-W ]
If a count is specified, the new window will be that many lines high.
MORE TAGS FILES
When you have files in many directories, you can create a tags file in each of
them. Vim will then only be able to jump to tags within that directory.
To find more tags files, set the 'tags' option to include all the relevant
tags files. Example: >
:set tags=./tags,./../tags,./*/tags
This finds a tags file in the same directory as the current file, one
directory level higher and in all subdirectories.
This is quite a number of tags files, but it may still not be enough. For
example, when editing a file in "~/proj/src", you will not find the tags file
"~/proj/sub/tags". For this situation Vim offers to search a whole directory
tree for tags files. Example: >
:set tags=~/proj/**/tags
ONE TAGS FILE
When Vim has to search many places for tags files, you can hear the disk
rattling. It may get a bit slow. In that case it's better to spend this
time while generating one big tags file. You might do this overnight.
This requires the Exuberant ctags program, mentioned above. It offers an
argument to search a whole directory tree: >
cd ~/proj
ctags -R .
The nice thing about this is that Exuberant ctags recognizes various file
types. Thus this doesn't work just for C and C++ programs, also for Eiffel
and even Vim scripts. See the ctags documentation to tune this.
Now you only need to tell Vim where your big tags file is: >
:set tags=~/proj/tags
MULTIPLE MATCHES
When a function is defined multiple times (or a method in several classes),
the ":tag" command will jump to the first one. If there is a match in the
current file, that one is used first.
You can now jump to other matches for the same tag with: >
:tnext
Repeat this to find further matches. If there are many, you can select which
one to jump to: >
:tselect tagname
Vim will present you with a list of choices:
# pri kind tag file ~
1 F f mch_init os_amiga.c ~
mch_init() ~
2 F f mch_init os_mac.c ~
mch_init() ~
3 F f mch_init os_msdos.c ~
mch_init(void) ~
4 F f mch_init os_riscos.c ~
mch_init() ~
Enter nr of choice (<CR> to abort): ~
You can now enter the number (in the first column) of the match that you would
like to jump to. The information in the other columns give you a good idea of
where the match is defined.
To move between the matching tags, these commands can be used:
:tfirst go to first match
:[count]tprevious go to [count] previous match
:[count]tnext go to [count] next match
:tlast go to last match
If [count] is omitted then one is used.
GUESSING TAG NAMES
Command line completion is a good way to avoid typing a long tag name. Just
type the first bit and press <Tab>: >
:tag write_<Tab>
You will get the first match. If it's not the one you want, press <Tab> until
you find the right one.
Sometimes you only know part of the name of a function. Or you have many
tags that start with the same string, but end differently. Then you can tell
Vim to use a pattern to find the tag.
Suppose you want to jump to a tag that contains "block". First type
this: >
:tag /block
Now use command line completion: press <Tab>. Vim will find all tags that
contain "block" and use the first match.
The "/" before a tag name tells Vim that what follows is not a literal tag
name, but a pattern. You can use all the items for search patterns here. For
example, suppose you want to select a tag that starts with "write_": >
:tselect /^write_
The "^" specifies that the tag starts with "write_". Otherwise it would also
be found halfway a tag name. Similarly "$" at the end makes sure the pattern
matches until the end of a tag.
A TAGS BROWSER
Since CTRL-] takes you to the definition of the identifier under the cursor,
you can use a list of identifier names as a table of contents. Here is an
example.
First create a list of identifiers (this requires Exuberant ctags): >
ctags --c-types=f -f functions *.c
Now start Vim without a file, and edit this file in Vim, in a vertically split
window: >
vim
:vsplit functions
The window contains a list of all the functions. There is some more stuff,
but you can ignore that. Do ":setlocal ts=99" to clean it up a bit.
In this window, define a mapping: >
:nnoremap <buffer> <CR> 0ye<C-W>w:tag <C-R>"<CR>
Move the cursor to the line that contains the function you want to go to.
Now press <Enter>. Vim will go to the other window and jump to the selected
function.
RELATED ITEMS
You can set 'ignorecase' to make case in tag names be ignored.
The 'tagbsearch' option tells if the tags file is sorted or not. The default
is to assume a sorted tags file, which makes a tags search a lot faster, but
doesn't work if the tags file isn't sorted.
The 'taglength' option can be used to tell Vim the number of significant
characters in a tag.
When you use the SNiFF+ program, you can use the Vim interface to it |sniff|.
SNiFF+ is a commercial program.
Cscope is a free program. It does not only find places where an identifier is
declared, but also where it is used. See |cscope|.
==============================================================================
*29.2* The preview window
When you edit code that contains a function call, you need to use the correct
arguments. To know what values to pass you can look at how the function is
defined. The tags mechanism works very well for this. Preferably the
definition is displayed in another window. For this the preview window can be
used.
To open a preview window to display the function "write_char": >
:ptag write_char
Vim will open a window, and jumps to the tag "write_char". Then it takes you
back to the original position. Thus you can continue typing without the need
to use a CTRL-W command.
If the name of a function appears in the text, you can get its definition
in the preview window with: >
CTRL-W }
There is a script that automatically displays the text where the word under
the cursor was defined. See |CursorHold-example|.
To close the preview window use this command: >
:pclose
To edit a specific file in the preview window, use ":pedit". This can be
useful to edit a header file, for example: >
:pedit defs.h
Finally, ":psearch" can be used to find a word in the current file and any
included files and display the match in the preview window. This is
especially useful when using library functions, for which you do not have a
tags file. Example: >
:psearch popen
This will show the "stdio.h" file in the preview window, with the function
prototype for popen():
FILE *popen __P((const char *, const char *)); ~
You can specify the height of the preview window, when it is opened, with the
'previewheight' option.
==============================================================================
*29.3* Moving through a program
Since a program is structured, Vim can recognize items in it. Specific
commands can be used to move around.
C programs often contain constructs like this:
#ifdef USE_POPEN ~
fd = popen("ls", "r") ~
#else ~
fd = fopen("tmp", "w") ~
#endif ~
But then much longer, and possibly nested. Position the cursor on the
"#ifdef" and press %. Vim will jump to the "#else". Pressing % again takes
you to the "#endif". Another % takes you to the "#ifdef" again.
When the construct is nested, Vim will find the matching items. This is a
good way to check if you didn't forget an "#endif".
When you are somewhere inside a "#if" - "#endif", you can jump to the start
of it with: >
[#
If you are not after a "#if" or "#ifdef" Vim will beep. To jump forward to
the next "#else" or "#endif" use: >
]#
These two commands skip any "#if" - "#endif" blocks that they encounter.
Example:
#if defined(HAS_INC_H) ~
a = a + inc(); ~
# ifdef USE_THEME ~
a += 3; ~
# endif ~
set_width(a); ~
With the cursor in the last line, "[#" moves to the first line. The "#ifdef"
- "#endif" block in the middle is skipped.
MOVING IN CODE BLOCKS
In C code blocks are enclosed in {}. These can get pretty long. To move to
the start of the outer block use the "[[" command. Use "][" to find the end.
This assumes that the "{" and "}" are in the first column.
The "[{" command moves to the start of the current block. It skips over
pairs of {} at the same level. "]}" jumps to the end.
An overview:
function(int a)
+-> {
| if (a)
| +-> {
[[ | | for (;;) --+
| | +-> { |
| [{ | | foo(32); | --+
| | [{ | if (bar(a)) --+ | ]} |
+-- | +-- break; | ]} | |
| } <-+ | | ][
+-- foobar(a) | |
} <-+ |
} <-+
When writing C++ or Java, the outer {} block is for the class. The next level
of {} is for a method. When somewhere inside a class use "[m" to find the
previous start of a method. "]m" finds the next end of a method.
Additionally, "[]" moves backward to the end of a function and "]]" moves
forward to the start of the next function. The end of a function is defined
by a "}" in the first column.
int func1(void)
{
return 1;
+----------> }
|
[] | int func2(void)
| +-> {
| [[ | if (flag)
start +-- +-- return flag;
| ][ | return 2;
| +-> }
]] |
| int func3(void)
+----------> {
return 3;
}
Don't forget you can also use "%" to move between matching (), {} and [].
That also works when they are many lines apart.
MOVING IN BRACES
The "[(" and "])" commands work similar to "[{" and "]}", except that they
work on () pairs instead of {} pairs.
>
[(
< <--------------------------------
<-------
if (a == b && (c == d || (e > f)) && x > y) ~
-------------->
--------------------------------> >
])
MOVING IN COMMENTS
To move back to the start of a comment use "[/". Move forward to the end of a
comment with "]/". This only works for /* - */ comments.
+-> +-> /*
| [/ | * A comment about --+
[/ | +-- * wonderful life. | ]/
| */ <-+
|
+-- foo = bar * 3; --+
| ]/
/* a short comment */ <-+
==============================================================================
*29.4* Finding global identifiers
You are editing a C program and wonder if a variable is declared as "int" or
"unsigned". A quick way to find this is with the "[I" command.
Suppose the cursor is on the word "column". Type: >
[I
Vim will list the matching lines it can find. Not only in the current file,
but also in all included files (and files included in them, etc.). The result
looks like this:
structs.h ~
1: 29 unsigned column; /* column number */ ~
The advantage over using tags or the preview window is that included files are
searched. In most cases this results in the right declaration to be found.
Also when the tags file is out of date. Also when you don't have tags for the
included files.
However, a few things must be right for "[I" to do its work. First of all,
the 'include' option must specify how a file is included. The default value
works for C and C++. For other languages you will have to change it.
LOCATING INCLUDED FILES
Vim will find included files in the places specified with the 'path'
option. If a directory is missing, some include files will not be found. You
can discover this with this command: >
:checkpath
It will list the include files that could not be found. Also files included
by the files that could be found. An example of the output:
--- Included files not found in path --- ~
<io.h> ~
vim.h --> ~
<functions.h> ~
<clib/exec_protos.h> ~
The "io.h" file is included by the current file and can't be found. "vim.h"
can be found, thus ":checkpath" goes into this file and checks what it
includes. The "functions.h" and "clib/exec_protos.h" files, included by
"vim.h" are not found.
Note:
Vim is not a compiler. It does not recognize "#ifdef" statements.
This means every "#include" statement is used, also when it comes
after "#if NEVER".
To fix the files that could not be found, add a directory to the 'path'
option. A good place to find out about this is the Makefile. Look out for
lines that contain "-I" items, like "-I/usr/local/X11". To add this directory
use: >
:set path+=/usr/local/X11
When there are many subdirectories, you an use the "*" wildcard. Example: >
:set path+=/usr/*/include
This would find files in "/usr/local/include" as well as "/usr/X11/include".
When working on a project with a whole nested tree of included files, the "**"
items is useful. This will search down in all subdirectories. Example: >
:set path+=/projects/invent/**/include
This will find files in the directories:
/projects/invent/include ~
/projects/invent/main/include ~
/projects/invent/main/os/include ~
etc.
There are even more possibilities. Check out the 'path' option for info.
If you want to see which included files are actually found, use this
command: >
:checkpath!
You will get a (very long) list of included files, the files they include, and
so on. To shorten the list a bit, Vim shows "(Already listed)" for files that
were found before and doesn't list the included files in there again.
JUMPING TO A MATCH
"[I" produces a list with only one line of text. When you want to have a
closer look at the first item, you can jump to that line with the command: >
[<Tab>
You can also use "[ CTRL-I", since CTRL-I is the same as pressing <Tab>.
The list that "[I" produces has a number at the start of each line. When you
want to jump to another item than the first one, type the number first: >
3[<Tab>
Will jump to the third item in the list. Remember that you can use CTRL-O to
jump back to where you started from.
RELATED COMMANDS
[i only lists the first match
]I only lists items below the cursor
]i only lists the first item below the cursor
FINDING DEFINED IDENTIFIERS
The "[I" command finds any identifier. To find only macros, defined with
"#define" use: >
[D
Again, this searches in included files. The 'define' option specifies what a
line looks like that defines the items for "[D". You could change it to make
it work with other languages than C or C++.
The commands related to "[D" are:
[d only lists the first match
]D only lists items below the cursor
]d only lists the first item below the cursor
==============================================================================
*29.5* Finding local identifiers
The "[I" command searches included files. To search in the current file only,
and jump to the first place where the word under the cursor is used: >
gD
Hint: Goto Definition. This command is very useful to find a variable or
function that was declared locally ("static", in C terms). Example (cursor on
"counter"):
+-> static int counter = 0;
|
| int get_counter(void)
gD | {
| ++counter;
+-- return counter;
}
To restrict the search even further, and look only in the current function,
use this command: >
gd
This will go back to the start of the current function and find the first
occurrence of the word under the cursor. Actually, it searches backwards to
an empty line above the a "{" in the first column. From there it searches
forward for the identifier. Example (cursor on "idx"):
int find_entry(char *name)
{
+-> int idx;
|
gd | for (idx = 0; idx < table_len; ++idx)
| if (strcmp(table[idx].name, name) == 0)
+-- return idx;
}
==============================================================================
Next chapter: |usr_30.txt| Editing programs
Copyright: see |manual-copyright| vim:tw=78:ts=8:ft=help:norl:
|