[qemu.git] / HACKING

1. Preprocessor

For variadic macros, stick with this C99-like syntax:

#define DPRINTF(fmt, ...)                                       \
    do { printf("IRQ: " fmt, ## __VA_ARGS__); } while (0)

2. C types

It should be common sense to use the right type, but we have collected
a few useful guidelines here.

2.1. Scalars

If you're using "int" or "long", odds are good that there's a better type.
If a variable is counting something, it should be declared with an
unsigned type.

If it's host memory-size related, size_t should be a good choice (use
ssize_t only if required). Guest RAM memory offsets must use ram_addr_t,
but only for RAM, it may not cover whole guest address space.

If it's file-size related, use off_t.
If it's file-offset related (i.e., signed), use off_t.
If it's just counting small numbers use "unsigned int";
(on all but oddball embedded systems, you can assume that that
type is at least four bytes wide).

In the event that you require a specific width, use a standard type
like int32_t, uint32_t, uint64_t, etc.  The specific types are
mandatory for VMState fields.

Don't use Linux kernel internal types like u32, __u32 or __le32.

Use hwaddr for guest physical addresses except pcibus_t
for PCI addresses.  In addition, ram_addr_t is a QEMU internal address
space that maps guest RAM physical addresses into an intermediate
address space that can map to host virtual address spaces.  Generally
speaking, the size of guest memory can always fit into ram_addr_t but
it would not be correct to store an actual guest physical address in a
ram_addr_t.

For CPU virtual addresses there are several possible types.
vaddr is the best type to use to hold a CPU virtual address in
target-independent code. It is guaranteed to be large enough to hold a
virtual address for any target, and it does not change size from target
to target. It is always unsigned.
target_ulong is a type the size of a virtual address on the CPU; this means
it may be 32 or 64 bits depending on which target is being built. It should
therefore be used only in target-specific code, and in some
performance-critical built-per-target core code such as the TLB code.
There is also a signed version, target_long.
abi_ulong is for the *-user targets, and represents a type the size of
'void *' in that target's ABI. (This may not be the same as the size of a
full CPU virtual address in the case of target ABIs which use 32 bit pointers
on 64 bit CPUs, like sparc32plus.) Definitions of structures that must match
the target's ABI must use this type for anything that on the target is defined
to be an 'unsigned long' or a pointer type.
There is also a signed version, abi_long.

Of course, take all of the above with a grain of salt.  If you're about
to use some system interface that requires a type like size_t, pid_t or
off_t, use matching types for any corresponding variables.

Also, if you try to use e.g., "unsigned int" as a type, and that
conflicts with the signedness of a related variable, sometimes
it's best just to use the *wrong* type, if "pulling the thread"
and fixing all related variables would be too invasive.

Finally, while using descriptive types is important, be careful not to
go overboard.  If whatever you're doing causes warnings, or requires
casts, then reconsider or ask for help.

2.2. Pointers

Ensure that all of your pointers are "const-correct".
Unless a pointer is used to modify the pointed-to storage,
give it the "const" attribute.  That way, the reader knows
up-front that this is a read-only pointer.  Perhaps more
importantly, if we're diligent about this, when you see a non-const
pointer, you're guaranteed that it is used to modify the storage
it points to, or it is aliased to another pointer that is.

2.3. Typedefs
Typedefs are used to eliminate the redundant 'struct' keyword.

2.4. Reserved namespaces in C and POSIX
Underscore capital, double underscore, and underscore 't' suffixes should be
avoided.

3. Low level memory management

Use of the malloc/free/realloc/calloc/valloc/memalign/posix_memalign
APIs is not allowed in the QEMU codebase. Instead of these routines,
use the GLib memory allocation routines g_malloc/g_malloc0/g_new/
g_new0/g_realloc/g_free or QEMU's qemu_memalign/qemu_blockalign/qemu_vfree
APIs.

Please note that g_malloc will exit on allocation failure, so there
is no need to test for failure (as you would have to with malloc).
Calling g_malloc with a zero size is valid and will return NULL.

Memory allocated by qemu_memalign or qemu_blockalign must be freed with
qemu_vfree, since breaking this will cause problems on Win32.

4. String manipulation

Do not use the strncpy function.  As mentioned in the man page, it does *not*
guarantee a NULL-terminated buffer, which makes it extremely dangerous to use.
It also zeros trailing destination bytes out to the specified length.  Instead,
use this similar function when possible, but note its different signature:
void pstrcpy(char *dest, int dest_buf_size, const char *src)

Don't use strcat because it can't check for buffer overflows, but:
char *pstrcat(char *buf, int buf_size, const char *s)

The same limitation exists with sprintf and vsprintf, so use snprintf and
vsnprintf.

QEMU provides other useful string functions:
int strstart(const char *str, const char *val, const char **ptr)
int stristart(const char *str, const char *val, const char **ptr)
int qemu_strnlen(const char *s, int max_len)

There are also replacement character processing macros for isxyz and toxyz,
so instead of e.g. isalnum you should use qemu_isalnum.

Because of the memory management rules, you must use g_strdup/g_strndup
instead of plain strdup/strndup.

5. Printf-style functions

Whenever you add a new printf-style function, i.e., one with a format
string argument and following "..." in its prototype, be sure to use
gcc's printf attribute directive in the prototype.

This makes it so gcc's -Wformat and -Wformat-security options can do
their jobs and cross-check format strings with the number and types
of arguments.

6. C standard, implementation defined and undefined behaviors

C code in QEMU should be written to the C99 language specification. A copy
of the final version of the C99 standard with corrigenda TC1, TC2, and TC3
included, formatted as a draft, can be downloaded from:
 http://www.open-std.org/jtc1/sc22/WG14/www/docs/n1256.pdf

The C language specification defines regions of undefined behavior and
implementation defined behavior (to give compiler authors enough leeway to
produce better code).  In general, code in QEMU should follow the language
specification and avoid both undefined and implementation defined
constructs. ("It works fine on the gcc I tested it with" is not a valid
argument...) However there are a few areas where we allow ourselves to
assume certain behaviors because in practice all the platforms we care about
behave in the same way and writing strictly conformant code would be
painful. These are:
 * you may assume that integers are 2s complement representation
 * you may assume that right shift of a signed integer duplicates
   the sign bit (ie it is an arithmetic shift, not a logical shift)
Commit	Line	Data
45fad878 BS	1	1. Preprocessor
	2
	3	For variadic macros, stick with this C99-like syntax:
	4
	5	#define DPRINTF(fmt, ...) \
	6	do { printf("IRQ: " fmt, ## __VA_ARGS__); } while (0)
84174436 BS	7
	8	2. C types
	9
	10	It should be common sense to use the right type, but we have collected
	11	a few useful guidelines here.
	12
	13	2.1. Scalars
	14
	15	If you're using "int" or "long", odds are good that there's a better type.
	16	If a variable is counting something, it should be declared with an
	17	unsigned type.
	18
	19	If it's host memory-size related, size_t should be a good choice (use
	20	ssize_t only if required). Guest RAM memory offsets must use ram_addr_t,
	21	but only for RAM, it may not cover whole guest address space.
	22
	23	If it's file-size related, use off_t.
	24	If it's file-offset related (i.e., signed), use off_t.
	25	If it's just counting small numbers use "unsigned int";
	26	(on all but oddball embedded systems, you can assume that that
	27	type is at least four bytes wide).
	28
	29	In the event that you require a specific width, use a standard type
	30	like int32_t, uint32_t, uint64_t, etc. The specific types are
	31	mandatory for VMState fields.
	32
	33	Don't use Linux kernel internal types like u32, __u32 or __le32.
	34
a8170e5e	35	Use hwaddr for guest physical addresses except pcibus_t
84174436 BS	36	for PCI addresses. In addition, ram_addr_t is a QEMU internal address
	37	space that maps guest RAM physical addresses into an intermediate
	38	address space that can map to host virtual address spaces. Generally
	39	speaking, the size of guest memory can always fit into ram_addr_t but
	40	it would not be correct to store an actual guest physical address in a
	41	ram_addr_t.
	42
2be8d450 PM	43	For CPU virtual addresses there are several possible types.
	44	vaddr is the best type to use to hold a CPU virtual address in
	45	target-independent code. It is guaranteed to be large enough to hold a
	46	virtual address for any target, and it does not change size from target
	47	to target. It is always unsigned.
	48	target_ulong is a type the size of a virtual address on the CPU; this means
	49	it may be 32 or 64 bits depending on which target is being built. It should
	50	therefore be used only in target-specific code, and in some
	51	performance-critical built-per-target core code such as the TLB code.
	52	There is also a signed version, target_long.
	53	abi_ulong is for the *-user targets, and represents a type the size of
	54	'void *' in that target's ABI. (This may not be the same as the size of a
	55	full CPU virtual address in the case of target ABIs which use 32 bit pointers
	56	on 64 bit CPUs, like sparc32plus.) Definitions of structures that must match
	57	the target's ABI must use this type for anything that on the target is defined
	58	to be an 'unsigned long' or a pointer type.
	59	There is also a signed version, abi_long.
84174436 BS	60
	61	Of course, take all of the above with a grain of salt. If you're about
	62	to use some system interface that requires a type like size_t, pid_t or
	63	off_t, use matching types for any corresponding variables.
	64
	65	Also, if you try to use e.g., "unsigned int" as a type, and that
	66	conflicts with the signedness of a related variable, sometimes
	67	it's best just to use the wrong type, if "pulling the thread"
	68	and fixing all related variables would be too invasive.
	69
	70	Finally, while using descriptive types is important, be careful not to
	71	go overboard. If whatever you're doing causes warnings, or requires
	72	casts, then reconsider or ask for help.
	73
	74	2.2. Pointers
	75
	76	Ensure that all of your pointers are "const-correct".
	77	Unless a pointer is used to modify the pointed-to storage,
	78	give it the "const" attribute. That way, the reader knows
	79	up-front that this is a read-only pointer. Perhaps more
	80	importantly, if we're diligent about this, when you see a non-const
	81	pointer, you're guaranteed that it is used to modify the storage
	82	it points to, or it is aliased to another pointer that is.
	83
	84	2.3. Typedefs
	85	Typedefs are used to eliminate the redundant 'struct' keyword.
	86
	87	2.4. Reserved namespaces in C and POSIX
	88	Underscore capital, double underscore, and underscore 't' suffixes should be
	89	avoided.
54b2cc50 BS	90
	91	3. Low level memory management
	92
	93	Use of the malloc/free/realloc/calloc/valloc/memalign/posix_memalign
	94	APIs is not allowed in the QEMU codebase. Instead of these routines,
f603a687	95	use the GLib memory allocation routines g_malloc/g_malloc0/g_new/
6eebf958	96	g_new0/g_realloc/g_free or QEMU's qemu_memalign/qemu_blockalign/qemu_vfree
f603a687	97	APIs.
54b2cc50	98
f603a687 PM	99	Please note that g_malloc will exit on allocation failure, so there
	100	is no need to test for failure (as you would have to with malloc).
	101	Calling g_malloc with a zero size is valid and will return NULL.
54b2cc50	102
6eebf958 PB	103	Memory allocated by qemu_memalign or qemu_blockalign must be freed with
6eebf958 PB	104	qemu_vfree, since breaking this will cause problems on Win32.
d241f143 BS	105
	106	4. String manipulation
	107
9b9e3ec1 JM	108	Do not use the strncpy function. As mentioned in the man page, it does not
	109	guarantee a NULL-terminated buffer, which makes it extremely dangerous to use.
	110	It also zeros trailing destination bytes out to the specified length. Instead,
	111	use this similar function when possible, but note its different signature:
	112	void pstrcpy(char dest, int dest_buf_size, const char src)
d241f143 BS	113
	114	Don't use strcat because it can't check for buffer overflows, but:
	115	char pstrcat(char buf, int buf_size, const char *s)
	116
	117	The same limitation exists with sprintf and vsprintf, so use snprintf and
	118	vsnprintf.
	119
	120	QEMU provides other useful string functions:
	121	int strstart(const char str, const char val, const char **ptr)
	122	int stristart(const char str, const char val, const char **ptr)
	123	int qemu_strnlen(const char *s, int max_len)
	124
	125	There are also replacement character processing macros for isxyz and toxyz,
	126	so instead of e.g. isalnum you should use qemu_isalnum.
	127
145e21db	128	Because of the memory management rules, you must use g_strdup/g_strndup
d241f143	129	instead of plain strdup/strndup.
876f256b BS	130
	131	5. Printf-style functions
	132
	133	Whenever you add a new printf-style function, i.e., one with a format
	134	string argument and following "..." in its prototype, be sure to use
	135	gcc's printf attribute directive in the prototype.
	136
	137	This makes it so gcc's -Wformat and -Wformat-security options can do
	138	their jobs and cross-check format strings with the number and types
	139	of arguments.
47536317 PM	140
	141	6. C standard, implementation defined and undefined behaviors
	142
	143	C code in QEMU should be written to the C99 language specification. A copy
	144	of the final version of the C99 standard with corrigenda TC1, TC2, and TC3
	145	included, formatted as a draft, can be downloaded from:
	146	http://www.open-std.org/jtc1/sc22/WG14/www/docs/n1256.pdf
	147
	148	The C language specification defines regions of undefined behavior and
	149	implementation defined behavior (to give compiler authors enough leeway to
	150	produce better code). In general, code in QEMU should follow the language
	151	specification and avoid both undefined and implementation defined
	152	constructs. ("It works fine on the gcc I tested it with" is not a valid
	153	argument...) However there are a few areas where we allow ourselves to
	154	assume certain behaviors because in practice all the platforms we care about
	155	behave in the same way and writing strictly conformant code would be
	156	painful. These are:
	157	* you may assume that integers are 2s complement representation
	158	* you may assume that right shift of a signed integer duplicates
	159	the sign bit (ie it is an arithmetic shift, not a logical shift)