nvme/nvme-cli
1
0
Fork 0
Code Issues Activity

Merging upstream version 2.0.

Browse source 
Signed-off-by: Daniel Baumann <daniel@debian.org>
This commit is contained in:
Daniel Baumann 2025-02-16 12:15:45 +01:00
parent 888be815c6
commit e4376063b0
Signed by: daniel
GPG key ID: FBB4F0E80A80222F
521 changed files with 21541 additions and 21644 deletions
Download patch file Download diff file Expand all files Collapse all files

1
ccan/ccan/build_assert/LICENSE Symbolic link
View file

@ -0,0 +1 @@
../../licenses/CC0

49
ccan/ccan/build_assert/_info Normal file
View file

@ -0,0 +1,49 @@
#include "config.h"
#include <stdio.h>
#include <string.h>
/**
* build_assert - routines for build-time assertions
*
* This code provides routines which will cause compilation to fail should some
* assertion be untrue: such failures are preferable to run-time assertions,
* but much more limited since they can only depends on compile-time constants.
*
* These assertions are most useful when two parts of the code must be kept in
* sync: it is better to avoid such cases if possible, but seconds best is to
* detect invalid changes at build time.
*
* For example, a tricky piece of code might rely on a certain element being at
* the start of the structure. To ensure that future changes don't break it,
* you would catch such changes in your code like so:
*
* Example:
* #include <stddef.h>
* #include <ccan/build_assert/build_assert.h>
*
* struct foo {
* char string[5];
* int x;
* };
*
* static char *foo_string(struct foo *foo)
* {
* // This trick requires that the string be first in the structure
* BUILD_ASSERT(offsetof(struct foo, string) == 0);
* return (char *)foo;
* }
*
* License: CC0 (Public domain)
* Author: Rusty Russell <rusty@rustcorp.com.au>
*/
int main(int argc, char *argv[])
{
if (argc != 2)
return 1;
if (strcmp(argv[1], "depends") == 0)
/* Nothing. */
return 0;
return 1;
}

40
ccan/ccan/build_assert/build_assert.h Normal file
View file

@ -0,0 +1,40 @@
/* CC0 (Public domain) - see LICENSE file for details */
#ifndef CCAN_BUILD_ASSERT_H
#define CCAN_BUILD_ASSERT_H
/**
* BUILD_ASSERT - assert a build-time dependency.
* @cond: the compile-time condition which must be true.
*
* Your compile will fail if the condition isn't true, or can't be evaluated
* by the compiler. This can only be used within a function.
*
* Example:
* #include <stddef.h>
* ...
* static char *foo_to_char(struct foo *foo)
* {
* // This code needs string to be at start of foo.
* BUILD_ASSERT(offsetof(struct foo, string) == 0);
* return (char *)foo;
* }
*/
#define BUILD_ASSERT(cond) \
do { (void) sizeof(char [1 - 2*!(cond)]); } while(0)
/**
* BUILD_ASSERT_OR_ZERO - assert a build-time dependency, as an expression.
* @cond: the compile-time condition which must be true.
*
* Your compile will fail if the condition isn't true, or can't be evaluated
* by the compiler. This can be used in an expression: its value is "0".
*
* Example:
* #define foo_to_char(foo) \
* ((char *)(foo) \
* + BUILD_ASSERT_OR_ZERO(offsetof(struct foo, string) == 0))
*/
#define BUILD_ASSERT_OR_ZERO(cond) \
(sizeof(char [1 - 2*!(cond)]) - 1)
#endif /* CCAN_BUILD_ASSERT_H */

1
ccan/ccan/check_type/LICENSE Symbolic link
View file

@ -0,0 +1 @@
../../licenses/CC0

33
ccan/ccan/check_type/_info Normal file
View file

@ -0,0 +1,33 @@
#include "config.h"
#include <stdio.h>
#include <string.h>
/**
* check_type - routines for compile time type checking
*
* C has fairly weak typing: ints get automatically converted to longs, signed
* to unsigned, etc. There are some cases where this is best avoided, and
* these macros provide methods for evoking warnings (or build errors) when
* a precise type isn't used.
*
* On compilers which don't support typeof() these routines are less effective,
* since they have to use sizeof() which can only distiguish between types of
* different size.
*
* License: CC0 (Public domain)
* Author: Rusty Russell <rusty@rustcorp.com.au>
*/
int main(int argc, char *argv[])
{
if (argc != 2)
return 1;
if (strcmp(argv[1], "depends") == 0) {
#if !HAVE_TYPEOF
printf("ccan/build_assert\n");
#endif
return 0;
}
return 1;
}

64
ccan/ccan/check_type/check_type.h Normal file
View file

@ -0,0 +1,64 @@
/* CC0 (Public domain) - see LICENSE file for details */
#ifndef CCAN_CHECK_TYPE_H
#define CCAN_CHECK_TYPE_H
#include "config.h"
/**
* check_type - issue a warning or build failure if type is not correct.
* @expr: the expression whose type we should check (not evaluated).
* @type: the exact type we expect the expression to be.
*
* This macro is usually used within other macros to try to ensure that a macro
* argument is of the expected type. No type promotion of the expression is
* done: an unsigned int is not the same as an int!
*
* check_type() always evaluates to 0.
*
* If your compiler does not support typeof, then the best we can do is fail
* to compile if the sizes of the types are unequal (a less complete check).
*
* Example:
* // They should always pass a 64-bit value to _set_some_value!
* #define set_some_value(expr) \
* _set_some_value((check_type((expr), uint64_t), (expr)))
*/
/**
* check_types_match - issue a warning or build failure if types are not same.
* @expr1: the first expression (not evaluated).
* @expr2: the second expression (not evaluated).
*
* This macro is usually used within other macros to try to ensure that
* arguments are of identical types. No type promotion of the expressions is
* done: an unsigned int is not the same as an int!
*
* check_types_match() always evaluates to 0.
*
* If your compiler does not support typeof, then the best we can do is fail
* to compile if the sizes of the types are unequal (a less complete check).
*
* Example:
* // Do subtraction to get to enclosing type, but make sure that
* // pointer is of correct type for that member.
* #define container_of(mbr_ptr, encl_type, mbr) \
* (check_types_match((mbr_ptr), &((encl_type *)0)->mbr), \
* ((encl_type *) \
* ((char *)(mbr_ptr) - offsetof(encl_type, mbr))))
*/
#if HAVE_TYPEOF
#define check_type(expr, type) \
((typeof(expr) *)0 != (type *)0)
#define check_types_match(expr1, expr2) \
((typeof(expr1) *)0 != (typeof(expr2) *)0)
#else
#include <ccan/build_assert/build_assert.h>
/* Without typeof, we can only test the sizes. */
#define check_type(expr, type) \
BUILD_ASSERT_OR_ZERO(sizeof(expr) == sizeof(type))
#define check_types_match(expr1, expr2) \
BUILD_ASSERT_OR_ZERO(sizeof(expr1) == sizeof(expr2))
#endif /* HAVE_TYPEOF */
#endif /* CCAN_CHECK_TYPE_H */

1
ccan/ccan/container_of/LICENSE Symbolic link
View file

@ -0,0 +1 @@
../../licenses/CC0

65
ccan/ccan/container_of/_info Normal file
View file

@ -0,0 +1,65 @@
#include "config.h"
#include <stdio.h>
#include <string.h>
/**
* container_of - routine for upcasting
*
* It is often convenient to create code where the caller registers a pointer
* to a generic structure and a callback. The callback might know that the
* pointer points to within a larger structure, and container_of gives a
* convenient and fairly type-safe way of returning to the enclosing structure.
*
* This idiom is an alternative to providing a void * pointer for every
* callback.
*
* Example:
* #include <stdio.h>
* #include <ccan/container_of/container_of.h>
*
* struct timer {
* void *members;
* };
*
* struct info {
* int my_stuff;
* struct timer timer;
* };
*
* static void my_timer_callback(struct timer *timer)
* {
* struct info *info = container_of(timer, struct info, timer);
* printf("my_stuff is %u\n", info->my_stuff);
* }
*
* static void register_timer(struct timer *timer)
* {
* (void)timer;
* (void)my_timer_callback;
* //...
* }
*
* int main(void)
* {
* struct info info = { .my_stuff = 1 };
*
* register_timer(&info.timer);
* // ...
* return 0;
* }
*
* License: CC0 (Public domain)
* Author: Rusty Russell <rusty@rustcorp.com.au>
*/
int main(int argc, char *argv[])
{
if (argc != 2)
return 1;
if (strcmp(argv[1], "depends") == 0) {
printf("ccan/check_type\n");
return 0;
}
return 1;
}

145
ccan/ccan/container_of/container_of.h Normal file
View file

@ -0,0 +1,145 @@
/* CC0 (Public domain) - see LICENSE file for details */
#ifndef CCAN_CONTAINER_OF_H
#define CCAN_CONTAINER_OF_H
#include <stddef.h>
#include "config.h"
#include <ccan/check_type/check_type.h>
/**
* container_of - get pointer to enclosing structure
* @member_ptr: pointer to the structure member
* @containing_type: the type this member is within
* @member: the name of this member within the structure.
*
* Given a pointer to a member of a structure, this macro does pointer
* subtraction to return the pointer to the enclosing type.
*
* Example:
* struct foo {
* int fielda, fieldb;
* // ...
* };
* struct info {
* int some_other_field;
* struct foo my_foo;
* };
*
* static struct info *foo_to_info(struct foo *foo)
* {
* return container_of(foo, struct info, my_foo);
* }
*/
#define container_of(member_ptr, containing_type, member) \
((containing_type *) \
((char *)(member_ptr) \
- container_off(containing_type, member)) \
+ check_types_match(*(member_ptr), ((containing_type *)0)->member))
/**
* container_of_or_null - get pointer to enclosing structure, or NULL
* @member_ptr: pointer to the structure member
* @containing_type: the type this member is within
* @member: the name of this member within the structure.
*
* Given a pointer to a member of a structure, this macro does pointer
* subtraction to return the pointer to the enclosing type, unless it
* is given NULL, in which case it also returns NULL.
*
* Example:
* struct foo {
* int fielda, fieldb;
* // ...
* };
* struct info {
* int some_other_field;
* struct foo my_foo;
* };
*
* static struct info *foo_to_info_allowing_null(struct foo *foo)
* {
* return container_of_or_null(foo, struct info, my_foo);
* }
*/
static inline char *container_of_or_null_(void *member_ptr, size_t offset)
{
return member_ptr ? (char *)member_ptr - offset : NULL;
}
#define container_of_or_null(member_ptr, containing_type, member) \
((containing_type *) \
container_of_or_null_(member_ptr, \
container_off(containing_type, member)) \
+ check_types_match(*(member_ptr), ((containing_type *)0)->member))
/**
* container_off - get offset to enclosing structure
* @containing_type: the type this member is within
* @member: the name of this member within the structure.
*
* Given a pointer to a member of a structure, this macro does
* typechecking and figures out the offset to the enclosing type.
*
* Example:
* struct foo {
* int fielda, fieldb;
* // ...
* };
* struct info {
* int some_other_field;
* struct foo my_foo;
* };
*
* static struct info *foo_to_info(struct foo *foo)
* {
* size_t off = container_off(struct info, my_foo);
* return (void *)((char *)foo - off);
* }
*/
#define container_off(containing_type, member) \
offsetof(containing_type, member)
/**
* container_of_var - get pointer to enclosing structure using a variable
* @member_ptr: pointer to the structure member
* @container_var: a pointer of same type as this member's container
* @member: the name of this member within the structure.
*
* Given a pointer to a member of a structure, this macro does pointer
* subtraction to return the pointer to the enclosing type.
*
* Example:
* static struct info *foo_to_i(struct foo *foo)
* {
* struct info *i = container_of_var(foo, i, my_foo);
* return i;
* }
*/
#if HAVE_TYPEOF
#define container_of_var(member_ptr, container_var, member) \
container_of(member_ptr, typeof(*container_var), member)
#else
#define container_of_var(member_ptr, container_var, member) \
((void *)((char *)(member_ptr) - \
container_off_var(container_var, member)))
#endif
/**
* container_off_var - get offset of a field in enclosing structure
* @container_var: a pointer to a container structure
* @member: the name of a member within the structure.
*
* Given (any) pointer to a structure and a its member name, this
* macro does pointer subtraction to return offset of member in a
* structure memory layout.
*
*/
#if HAVE_TYPEOF
#define container_off_var(var, member) \
container_off(typeof(*var), member)
#else
#define container_off_var(var, member) \
((const char *)&(var)->member - (const char *)(var))
#endif
#endif /* CCAN_CONTAINER_OF_H */

1
ccan/ccan/endian/LICENSE Symbolic link
View file

@ -0,0 +1 @@
../../licenses/CC0

55
ccan/ccan/endian/_info Normal file
View file

@ -0,0 +1,55 @@
#include "config.h"
#include <stdio.h>
#include <string.h>
/**
* endian - endian conversion macros for simple types
*
* Portable protocols (such as on-disk formats, or network protocols)
* are often defined to be a particular endian: little-endian (least
* significant bytes first) or big-endian (most significant bytes
* first).
*
* Similarly, some CPUs lay out values in memory in little-endian
* order (most commonly, Intel's 8086 and derivatives), or big-endian
* order (almost everyone else).
*
* This module provides conversion routines, inspired by the linux kernel.
* It also provides leint32_t, beint32_t etc typedefs, which are annotated for
* the sparse checker.
*
* Example:
* #include <stdio.h>
* #include <err.h>
* #include <ccan/endian/endian.h>
*
* //
* int main(int argc, char *argv[])
* {
* uint32_t value;
*
* if (argc != 2)
* errx(1, "Usage: %s <value>", argv[0]);
*
* value = atoi(argv[1]);
* printf("native: %08x\n", value);
* printf("little-endian: %08x\n", cpu_to_le32(value));
* printf("big-endian: %08x\n", cpu_to_be32(value));
* printf("byte-reversed: %08x\n", bswap_32(value));
* exit(0);
* }
*
* License: License: CC0 (Public domain)
* Author: Rusty Russell <rusty@rustcorp.com.au>
*/
int main(int argc, char *argv[])
{
if (argc != 2)
return 1;
if (strcmp(argv[1], "depends") == 0)
/* Nothing */
return 0;
return 1;
}

363
ccan/ccan/endian/endian.h Normal file
View file

@ -0,0 +1,363 @@
/* CC0 (Public domain) - see LICENSE file for details */
#ifndef CCAN_ENDIAN_H
#define CCAN_ENDIAN_H
#include <stdint.h>
#include "config.h"
/**
* BSWAP_16 - reverse bytes in a constant uint16_t value.
* @val: constant value whose bytes to swap.
*
* Designed to be usable in constant-requiring initializers.
*
* Example:
* struct mystruct {
* char buf[BSWAP_16(0x1234)];
* };
*/
#define BSWAP_16(val) \
((((uint16_t)(val) & 0x00ff) << 8) \
| (((uint16_t)(val) & 0xff00) >> 8))
/**
* BSWAP_32 - reverse bytes in a constant uint32_t value.
* @val: constant value whose bytes to swap.
*
* Designed to be usable in constant-requiring initializers.
*
* Example:
* struct mystruct {
* char buf[BSWAP_32(0xff000000)];
* };
*/
#define BSWAP_32(val) \
((((uint32_t)(val) & 0x000000ff) << 24) \
| (((uint32_t)(val) & 0x0000ff00) << 8) \
| (((uint32_t)(val) & 0x00ff0000) >> 8) \
| (((uint32_t)(val) & 0xff000000) >> 24))
/**
* BSWAP_64 - reverse bytes in a constant uint64_t value.
* @val: constantvalue whose bytes to swap.
*
* Designed to be usable in constant-requiring initializers.
*
* Example:
* struct mystruct {
* char buf[BSWAP_64(0xff00000000000000ULL)];
* };
*/
#define BSWAP_64(val) \
((((uint64_t)(val) & 0x00000000000000ffULL) << 56) \
| (((uint64_t)(val) & 0x000000000000ff00ULL) << 40) \
| (((uint64_t)(val) & 0x0000000000ff0000ULL) << 24) \
| (((uint64_t)(val) & 0x00000000ff000000ULL) << 8) \
| (((uint64_t)(val) & 0x000000ff00000000ULL) >> 8) \
| (((uint64_t)(val) & 0x0000ff0000000000ULL) >> 24) \
| (((uint64_t)(val) & 0x00ff000000000000ULL) >> 40) \
| (((uint64_t)(val) & 0xff00000000000000ULL) >> 56))
#if HAVE_BYTESWAP_H
#include <byteswap.h>
#else
/**
* bswap_16 - reverse bytes in a uint16_t value.
* @val: value whose bytes to swap.
*
* Example:
* // Output contains "1024 is 4 as two bytes reversed"
* printf("1024 is %u as two bytes reversed\n", bswap_16(1024));
*/
static inline uint16_t bswap_16(uint16_t val)
{
return BSWAP_16(val);
}
/**
* bswap_32 - reverse bytes in a uint32_t value.
* @val: value whose bytes to swap.
*
* Example:
* // Output contains "1024 is 262144 as four bytes reversed"
* printf("1024 is %u as four bytes reversed\n", bswap_32(1024));
*/
static inline uint32_t bswap_32(uint32_t val)
{
return BSWAP_32(val);
}
#endif /* !HAVE_BYTESWAP_H */
#if !HAVE_BSWAP_64
/**
* bswap_64 - reverse bytes in a uint64_t value.
* @val: value whose bytes to swap.
*
* Example:
* // Output contains "1024 is 1125899906842624 as eight bytes reversed"
* printf("1024 is %llu as eight bytes reversed\n",
* (unsigned long long)bswap_64(1024));
*/
static inline uint64_t bswap_64(uint64_t val)
{
return BSWAP_64(val);
}
#endif
/* Needed for Glibc like endiness check */
#define __LITTLE_ENDIAN 1234
#define __BIG_ENDIAN 4321
/* Sanity check the defines. We don't handle weird endianness. */
#if !HAVE_LITTLE_ENDIAN && !HAVE_BIG_ENDIAN
#error "Unknown endian"
#elif HAVE_LITTLE_ENDIAN && HAVE_BIG_ENDIAN
#error "Can't compile for both big and little endian."
#elif HAVE_LITTLE_ENDIAN
#ifndef __BYTE_ORDER
#define __BYTE_ORDER __LITTLE_ENDIAN
#elif __BYTE_ORDER != __LITTLE_ENDIAN
#error "__BYTE_ORDER already defined, but not equal to __LITTLE_ENDIAN"
#endif
#elif HAVE_BIG_ENDIAN
#ifndef __BYTE_ORDER
#define __BYTE_ORDER __BIG_ENDIAN
#elif __BYTE_ORDER != __BIG_ENDIAN
#error "__BYTE_ORDER already defined, but not equal to __BIG_ENDIAN"
#endif
#endif
#ifdef __CHECKER__
/* sparse needs forcing to remove bitwise attribute from ccan/short_types */
#define ENDIAN_CAST __attribute__((force))
#define ENDIAN_TYPE __attribute__((bitwise))
#else
#define ENDIAN_CAST
#define ENDIAN_TYPE
#endif
typedef uint64_t ENDIAN_TYPE leint64_t;
typedef uint64_t ENDIAN_TYPE beint64_t;
typedef uint32_t ENDIAN_TYPE leint32_t;
typedef uint32_t ENDIAN_TYPE beint32_t;
typedef uint16_t ENDIAN_TYPE leint16_t;
typedef uint16_t ENDIAN_TYPE beint16_t;
#if HAVE_LITTLE_ENDIAN
/**
* CPU_TO_LE64 - convert a constant uint64_t value to little-endian
* @native: constant to convert
*/
#define CPU_TO_LE64(native) ((ENDIAN_CAST leint64_t)(native))
/**
* CPU_TO_LE32 - convert a constant uint32_t value to little-endian
* @native: constant to convert
*/
#define CPU_TO_LE32(native) ((ENDIAN_CAST leint32_t)(native))
/**
* CPU_TO_LE16 - convert a constant uint16_t value to little-endian
* @native: constant to convert
*/
#define CPU_TO_LE16(native) ((ENDIAN_CAST leint16_t)(native))
/**
* LE64_TO_CPU - convert a little-endian uint64_t constant
* @le_val: little-endian constant to convert
*/
#define LE64_TO_CPU(le_val) ((ENDIAN_CAST uint64_t)(le_val))
/**
* LE32_TO_CPU - convert a little-endian uint32_t constant
* @le_val: little-endian constant to convert
*/
#define LE32_TO_CPU(le_val) ((ENDIAN_CAST uint32_t)(le_val))
/**
* LE16_TO_CPU - convert a little-endian uint16_t constant
* @le_val: little-endian constant to convert
*/
#define LE16_TO_CPU(le_val) ((ENDIAN_CAST uint16_t)(le_val))
#else /* ... HAVE_BIG_ENDIAN */
#define CPU_TO_LE64(native) ((ENDIAN_CAST leint64_t)BSWAP_64(native))
#define CPU_TO_LE32(native) ((ENDIAN_CAST leint32_t)BSWAP_32(native))
#define CPU_TO_LE16(native) ((ENDIAN_CAST leint16_t)BSWAP_16(native))
#define LE64_TO_CPU(le_val) BSWAP_64((ENDIAN_CAST uint64_t)le_val)
#define LE32_TO_CPU(le_val) BSWAP_32((ENDIAN_CAST uint32_t)le_val)
#define LE16_TO_CPU(le_val) BSWAP_16((ENDIAN_CAST uint16_t)le_val)
#endif /* HAVE_BIG_ENDIAN */
#if HAVE_BIG_ENDIAN
/**
* CPU_TO_BE64 - convert a constant uint64_t value to big-endian
* @native: constant to convert
*/
#define CPU_TO_BE64(native) ((ENDIAN_CAST beint64_t)(native))
/**
* CPU_TO_BE32 - convert a constant uint32_t value to big-endian
* @native: constant to convert
*/
#define CPU_TO_BE32(native) ((ENDIAN_CAST beint32_t)(native))
/**
* CPU_TO_BE16 - convert a constant uint16_t value to big-endian
* @native: constant to convert
*/
#define CPU_TO_BE16(native) ((ENDIAN_CAST beint16_t)(native))
/**
* BE64_TO_CPU - convert a big-endian uint64_t constant
* @le_val: big-endian constant to convert
*/
#define BE64_TO_CPU(le_val) ((ENDIAN_CAST uint64_t)(le_val))
/**
* BE32_TO_CPU - convert a big-endian uint32_t constant
* @le_val: big-endian constant to convert
*/
#define BE32_TO_CPU(le_val) ((ENDIAN_CAST uint32_t)(le_val))
/**
* BE16_TO_CPU - convert a big-endian uint16_t constant
* @le_val: big-endian constant to convert
*/
#define BE16_TO_CPU(le_val) ((ENDIAN_CAST uint16_t)(le_val))
#else /* ... HAVE_LITTLE_ENDIAN */
#define CPU_TO_BE64(native) ((ENDIAN_CAST beint64_t)BSWAP_64(native))
#define CPU_TO_BE32(native) ((ENDIAN_CAST beint32_t)BSWAP_32(native))
#define CPU_TO_BE16(native) ((ENDIAN_CAST beint16_t)BSWAP_16(native))
#define BE64_TO_CPU(le_val) BSWAP_64((ENDIAN_CAST uint64_t)le_val)
#define BE32_TO_CPU(le_val) BSWAP_32((ENDIAN_CAST uint32_t)le_val)
#define BE16_TO_CPU(le_val) BSWAP_16((ENDIAN_CAST uint16_t)le_val)
#endif /* HAVE_LITTE_ENDIAN */
/**
* cpu_to_le64 - convert a uint64_t value to little-endian
* @native: value to convert
*/
static inline leint64_t cpu_to_le64(uint64_t native)
{
return CPU_TO_LE64(native);
}
/**
* cpu_to_le32 - convert a uint32_t value to little-endian
* @native: value to convert
*/
static inline leint32_t cpu_to_le32(uint32_t native)
{
return CPU_TO_LE32(native);
}
/**
* cpu_to_le16 - convert a uint16_t value to little-endian
* @native: value to convert
*/
static inline leint16_t cpu_to_le16(uint16_t native)
{
return CPU_TO_LE16(native);
}
/**
* le64_to_cpu - convert a little-endian uint64_t value
* @le_val: little-endian value to convert
*/
static inline uint64_t le64_to_cpu(leint64_t le_val)
{
return LE64_TO_CPU(le_val);
}
/**
* le32_to_cpu - convert a little-endian uint32_t value
* @le_val: little-endian value to convert
*/
static inline uint32_t le32_to_cpu(leint32_t le_val)
{
return LE32_TO_CPU(le_val);
}
/**
* le16_to_cpu - convert a little-endian uint16_t value
* @le_val: little-endian value to convert
*/
static inline uint16_t le16_to_cpu(leint16_t le_val)
{
return LE16_TO_CPU(le_val);
}
/**
* cpu_to_be64 - convert a uint64_t value to big endian.
* @native: value to convert
*/
static inline beint64_t cpu_to_be64(uint64_t native)
{
return CPU_TO_BE64(native);
}
/**
* cpu_to_be32 - convert a uint32_t value to big endian.
* @native: value to convert
*/
static inline beint32_t cpu_to_be32(uint32_t native)
{
return CPU_TO_BE32(native);
}
/**
* cpu_to_be16 - convert a uint16_t value to big endian.
* @native: value to convert
*/
static inline beint16_t cpu_to_be16(uint16_t native)
{
return CPU_TO_BE16(native);
}
/**
* be64_to_cpu - convert a big-endian uint64_t value
* @be_val: big-endian value to convert
*/
static inline uint64_t be64_to_cpu(beint64_t be_val)
{
return BE64_TO_CPU(be_val);
}
/**
* be32_to_cpu - convert a big-endian uint32_t value
* @be_val: big-endian value to convert
*/
static inline uint32_t be32_to_cpu(beint32_t be_val)
{
return BE32_TO_CPU(be_val);
}
/**
* be16_to_cpu - convert a big-endian uint16_t value
* @be_val: big-endian value to convert
*/
static inline uint16_t be16_to_cpu(beint16_t be_val)
{
return BE16_TO_CPU(be_val);
}
/* Whichever they include first, they get these definitions. */
#ifdef CCAN_SHORT_TYPES_H
/**
* be64/be32/be16 - 64/32/16 bit big-endian representation.
*/
typedef beint64_t be64;
typedef beint32_t be32;
typedef beint16_t be16;
/**
* le64/le32/le16 - 64/32/16 bit little-endian representation.
*/
typedef leint64_t le64;
typedef leint32_t le32;
typedef leint16_t le16;
#endif
#endif /* CCAN_ENDIAN_H */

1
ccan/ccan/list/LICENSE Symbolic link
View file

@ -0,0 +1 @@
../../licenses/BSD-MIT

72
ccan/ccan/list/_info Normal file
View file

@ -0,0 +1,72 @@
#include "config.h"
#include <stdio.h>
#include <string.h>
/**
* list - double linked list routines
*
* The list header contains routines for manipulating double linked lists.
* It defines two types: struct list_head used for anchoring lists, and
* struct list_node which is usually embedded in the structure which is placed
* in the list.
*
* Example:
* #include <err.h>
* #include <stdio.h>
* #include <stdlib.h>
* #include <ccan/list/list.h>
*
* struct parent {
* const char *name;
* struct list_head children;
* unsigned int num_children;
* };
*
* struct child {
* const char *name;
* struct list_node list;
* };
*
* int main(int argc, char *argv[])
* {
* struct parent p;
* struct child *c;
* int i;
*
* if (argc < 2)
* errx(1, "Usage: %s parent children...", argv[0]);
*
* p.name = argv[1];
* list_head_init(&p.children);
* p.num_children = 0;
* for (i = 2; i < argc; i++) {
* c = malloc(sizeof(*c));
* c->name = argv[i];
* list_add(&p.children, &c->list);
* p.num_children++;
* }
*
* printf("%s has %u children:", p.name, p.num_children);
* list_for_each(&p.children, c, list)
* printf("%s ", c->name);
* printf("\n");
* return 0;
* }
*
* License: BSD-MIT
* Author: Rusty Russell <rusty@rustcorp.com.au>
*/
int main(int argc, char *argv[])
{
if (argc != 2)
return 1;
if (strcmp(argv[1], "depends") == 0) {
printf("ccan/str\n");
printf("ccan/container_of\n");
printf("ccan/check_type\n");
return 0;
}
return 1;
}

43
ccan/ccan/list/list.c Normal file
View file

@ -0,0 +1,43 @@
/* Licensed under BSD-MIT - see LICENSE file for details */
#include <stdio.h>
#include <stdlib.h>
#include "list.h"
static void *corrupt(const char *abortstr,
const struct list_node *head,
const struct list_node *node,
unsigned int count)
{
if (abortstr) {
fprintf(stderr,
"%s: prev corrupt in node %p (%u) of %p\n",
abortstr, node, count, head);
abort();
}
return NULL;
}
struct list_node *list_check_node(const struct list_node *node,
const char *abortstr)
{
const struct list_node *p, *n;
int count = 0;
for (p = node, n = node->next; n != node; p = n, n = n->next) {
count++;
if (n->prev != p)
return corrupt(abortstr, node, n, count);
}
/* Check prev on head node. */
if (node->prev != p)
return corrupt(abortstr, node, node, 0);
return (struct list_node *)node;
}
struct list_head *list_check(const struct list_head *h, const char *abortstr)
{
if (!list_check_node(&h->n, abortstr))
return NULL;
return (struct list_head *)h;
}

842
ccan/ccan/list/list.h Normal file
View file

@ -0,0 +1,842 @@
/* Licensed under BSD-MIT - see LICENSE file for details */
#ifndef CCAN_LIST_H
#define CCAN_LIST_H
//#define CCAN_LIST_DEBUG 1
#include <stdbool.h>
#include <assert.h>
#include <ccan/str/str.h>
#include <ccan/container_of/container_of.h>
#include <ccan/check_type/check_type.h>
/**
* struct list_node - an entry in a doubly-linked list
* @next: next entry (self if empty)
* @prev: previous entry (self if empty)
*
* This is used as an entry in a linked list.
* Example:
* struct child {
* const char *name;
* // Linked list of all us children.
* struct list_node list;
* };
*/
struct list_node
{
struct list_node *next, *prev;
};
/**
* struct list_head - the head of a doubly-linked list
* @h: the list_head (containing next and prev pointers)
*
* This is used as the head of a linked list.
* Example:
* struct parent {
* const char *name;
* struct list_head children;
* unsigned int num_children;
* };
*/
struct list_head
{
struct list_node n;
};
/**
* list_check - check head of a list for consistency
* @h: the list_head
* @abortstr: the location to print on aborting, or NULL.
*
* Because list_nodes have redundant information, consistency checking between
* the back and forward links can be done. This is useful as a debugging check.
* If @abortstr is non-NULL, that will be printed in a diagnostic if the list
* is inconsistent, and the function will abort.
*
* Returns the list head if the list is consistent, NULL if not (it
* can never return NULL if @abortstr is set).
*
* See also: list_check_node()
*
* Example:
* static void dump_parent(struct parent *p)
* {
* struct child *c;
*
* printf("%s (%u children):\n", p->name, p->num_children);
* list_check(&p->children, "bad child list");
* list_for_each(&p->children, c, list)
* printf(" -> %s\n", c->name);
* }
*/
struct list_head *list_check(const struct list_head *h, const char *abortstr);
/**
* list_check_node - check node of a list for consistency
* @n: the list_node
* @abortstr: the location to print on aborting, or NULL.
*
* Check consistency of the list node is in (it must be in one).
*
* See also: list_check()
*
* Example:
* static void dump_child(const struct child *c)
* {
* list_check_node(&c->list, "bad child list");
* printf("%s\n", c->name);
* }
*/
struct list_node *list_check_node(const struct list_node *n,
const char *abortstr);
#define LIST_LOC __FILE__ ":" stringify(__LINE__)
#ifdef CCAN_LIST_DEBUG
#define list_debug(h, loc) list_check((h), loc)
#define list_debug_node(n, loc) list_check_node((n), loc)
#else
#define list_debug(h, loc) ((void)loc, h)
#define list_debug_node(n, loc) ((void)loc, n)
#endif
/**
* LIST_HEAD_INIT - initializer for an empty list_head
* @name: the name of the list.
*
* Explicit initializer for an empty list.
*
* See also:
* LIST_HEAD, list_head_init()
*
* Example:
* static struct list_head my_list = LIST_HEAD_INIT(my_list);
*/
#define LIST_HEAD_INIT(name) { { &(name).n, &(name).n } }
/**
* LIST_HEAD - define and initialize an empty list_head
* @name: the name of the list.
*
* The LIST_HEAD macro defines a list_head and initializes it to an empty
* list. It can be prepended by "static" to define a static list_head.
*
* See also:
* LIST_HEAD_INIT, list_head_init()
*
* Example:
* static LIST_HEAD(my_global_list);
*/
#define LIST_HEAD(name) \
struct list_head name = LIST_HEAD_INIT(name)
/**
* list_head_init - initialize a list_head
* @h: the list_head to set to the empty list
*
* Example:
* ...
* struct parent *parent = malloc(sizeof(*parent));
*
* list_head_init(&parent->children);
* parent->num_children = 0;
*/
static inline void list_head_init(struct list_head *h)
{
h->n.next = h->n.prev = &h->n;
}
/**
* list_node_init - initialize a list_node
* @n: the list_node to link to itself.
*
* You don't need to use this normally! But it lets you list_del(@n)
* safely.
*/
static inline void list_node_init(struct list_node *n)
{
n->next = n->prev = n;
}
/**
* list_add_after - add an entry after an existing node in a linked list
* @h: the list_head to add the node to (for debugging)
* @p: the existing list_node to add the node after
* @n: the new list_node to add to the list.
*
* The existing list_node must already be a member of the list.
* The new list_node does not need to be initialized; it will be overwritten.
*
* Example:
* struct child c1, c2, c3;
* LIST_HEAD(h);
*
* list_add_tail(&h, &c1.list);
* list_add_tail(&h, &c3.list);
* list_add_after(&h, &c1.list, &c2.list);
*/
#define list_add_after(h, p, n) list_add_after_(h, p, n, LIST_LOC)
static inline void list_add_after_(struct list_head *h,
struct list_node *p,
struct list_node *n,
const char *abortstr)
{
n->next = p->next;
n->prev = p;
p->next->prev = n;
p->next = n;
(void)list_debug(h, abortstr);
}
/**
* list_add - add an entry at the start of a linked list.
* @h: the list_head to add the node to
* @n: the list_node to add to the list.
*
* The list_node does not need to be initialized; it will be overwritten.
* Example:
* struct child *child = malloc(sizeof(*child));
*
* child->name = "marvin";
* list_add(&parent->children, &child->list);
* parent->num_children++;
*/
#define list_add(h, n) list_add_(h, n, LIST_LOC)
static inline void list_add_(struct list_head *h,
struct list_node *n,
const char *abortstr)
{
list_add_after_(h, &h->n, n, abortstr);
}
/**
* list_add_before - add an entry before an existing node in a linked list
* @h: the list_head to add the node to (for debugging)
* @p: the existing list_node to add the node before
* @n: the new list_node to add to the list.
*
* The existing list_node must already be a member of the list.
* The new list_node does not need to be initialized; it will be overwritten.
*
* Example:
* list_head_init(&h);
* list_add_tail(&h, &c1.list);
* list_add_tail(&h, &c3.list);
* list_add_before(&h, &c3.list, &c2.list);
*/
#define list_add_before(h, p, n) list_add_before_(h, p, n, LIST_LOC)
static inline void list_add_before_(struct list_head *h,
struct list_node *p,
struct list_node *n,
const char *abortstr)
{
n->next = p;
n->prev = p->prev;
p->prev->next = n;
p->prev = n;
(void)list_debug(h, abortstr);
}
/**
* list_add_tail - add an entry at the end of a linked list.
* @h: the list_head to add the node to
* @n: the list_node to add to the list.
*
* The list_node does not need to be initialized; it will be overwritten.
* Example:
* list_add_tail(&parent->children, &child->list);
* parent->num_children++;
*/
#define list_add_tail(h, n) list_add_tail_(h, n, LIST_LOC)
static inline void list_add_tail_(struct list_head *h,
struct list_node *n,
const char *abortstr)
{
list_add_before_(h, &h->n, n, abortstr);
}
/**
* list_empty - is a list empty?
* @h: the list_head
*
* If the list is empty, returns true.
*
* Example:
* assert(list_empty(&parent->children) == (parent->num_children == 0));
*/
#define list_empty(h) list_empty_(h, LIST_LOC)
static inline bool list_empty_(const struct list_head *h, const char* abortstr)
{
(void)list_debug(h, abortstr);
return h->n.next == &h->n;
}
/**
* list_empty_nodebug - is a list empty (and don't perform debug checks)?
* @h: the list_head
*
* If the list is empty, returns true.
* This differs from list_empty() in that if CCAN_LIST_DEBUG is set it
* will NOT perform debug checks. Only use this function if you REALLY
* know what you're doing.
*
* Example:
* assert(list_empty_nodebug(&parent->children) == (parent->num_children == 0));
*/
#ifndef CCAN_LIST_DEBUG
#define list_empty_nodebug(h) list_empty(h)
#else
static inline bool list_empty_nodebug(const struct list_head *h)
{
return h->n.next == &h->n;
}
#endif
/**
* list_empty_nocheck - is a list empty?
* @h: the list_head
*
* If the list is empty, returns true. This doesn't perform any
* debug check for list consistency, so it can be called without
* locks, racing with the list being modified. This is ok for
* checks where an incorrect result is not an issue (optimized
* bail out path for example).
*/
static inline bool list_empty_nocheck(const struct list_head *h)
{
return h->n.next == &h->n;
}
/**
* list_del - delete an entry from an (unknown) linked list.
* @n: the list_node to delete from the list.
*
* Note that this leaves @n in an undefined state; it can be added to
* another list, but not deleted again.
*
* See also:
* list_del_from(), list_del_init()
*
* Example:
* list_del(&child->list);
* parent->num_children--;
*/
#define list_del(n) list_del_(n, LIST_LOC)
static inline void list_del_(struct list_node *n, const char* abortstr)
{
(void)list_debug_node(n, abortstr);
n->next->prev = n->prev;
n->prev->next = n->next;
#ifdef CCAN_LIST_DEBUG
/* Catch use-after-del. */
n->next = n->prev = NULL;
#endif
}
/**
* list_del_init - delete a node, and reset it so it can be deleted again.
* @n: the list_node to be deleted.
*
* list_del(@n) or list_del_init() again after this will be safe,
* which can be useful in some cases.
*
* See also:
* list_del_from(), list_del()
*
* Example:
* list_del_init(&child->list);
* parent->num_children--;
*/
#define list_del_init(n) list_del_init_(n, LIST_LOC)
static inline void list_del_init_(struct list_node *n, const char *abortstr)
{
list_del_(n, abortstr);
list_node_init(n);
}
/**
* list_del_from - delete an entry from a known linked list.
* @h: the list_head the node is in.
* @n: the list_node to delete from the list.
*
* This explicitly indicates which list a node is expected to be in,
* which is better documentation and can catch more bugs.
*
* See also: list_del()
*
* Example:
* list_del_from(&parent->children, &child->list);
* parent->num_children--;
*/
static inline void list_del_from(struct list_head *h, struct list_node *n)
{
#ifdef CCAN_LIST_DEBUG
{
/* Thorough check: make sure it was in list! */
struct list_node *i;
for (i = h->n.next; i != n; i = i->next)
assert(i != &h->n);
}
#endif /* CCAN_LIST_DEBUG */
/* Quick test that catches a surprising number of bugs. */
assert(!list_empty(h));
list_del(n);
}
/**
* list_swap - swap out an entry from an (unknown) linked list for a new one.
* @o: the list_node to replace from the list.
* @n: the list_node to insert in place of the old one.
*
* Note that this leaves @o in an undefined state; it can be added to
* another list, but not deleted/swapped again.
*
* See also:
* list_del()
*
* Example:
* struct child x1, x2;
* LIST_HEAD(xh);
*
* list_add(&xh, &x1.list);
* list_swap(&x1.list, &x2.list);
*/
#define list_swap(o, n) list_swap_(o, n, LIST_LOC)
static inline void list_swap_(struct list_node *o,
struct list_node *n,
const char* abortstr)
{
(void)list_debug_node(o, abortstr);
*n = *o;
n->next->prev = n;
n->prev->next = n;
#ifdef CCAN_LIST_DEBUG
/* Catch use-after-del. */
o->next = o->prev = NULL;
#endif
}
/**
* list_entry - convert a list_node back into the structure containing it.
* @n: the list_node
* @type: the type of the entry
* @member: the list_node member of the type
*
* Example:
* // First list entry is children.next; convert back to child.
* child = list_entry(parent->children.n.next, struct child, list);
*
* See Also:
* list_top(), list_for_each()
*/
#define list_entry(n, type, member) container_of(n, type, member)
/**
* list_top - get the first entry in a list
* @h: the list_head
* @type: the type of the entry
* @member: the list_node member of the type
*
* If the list is empty, returns NULL.
*
* Example:
* struct child *first;
* first = list_top(&parent->children, struct child, list);
* if (!first)
* printf("Empty list!\n");
*/
#define list_top(h, type, member) \
((type *)list_top_((h), list_off_(type, member)))
static inline const void *list_top_(const struct list_head *h, size_t off)
{
if (list_empty(h))
return NULL;
return (const char *)h->n.next - off;
}
/**
* list_pop - remove the first entry in a list
* @h: the list_head
* @type: the type of the entry
* @member: the list_node member of the type
*
* If the list is empty, returns NULL.
*
* Example:
* struct child *one;
* one = list_pop(&parent->children, struct child, list);
* if (!one)
* printf("Empty list!\n");
*/
#define list_pop(h, type, member) \
((type *)list_pop_((h), list_off_(type, member)))
static inline const void *list_pop_(const struct list_head *h, size_t off)
{
struct list_node *n;
if (list_empty(h))
return NULL;
n = h->n.next;
list_del(n);
return (const char *)n - off;
}
/**
* list_tail - get the last entry in a list
* @h: the list_head
* @type: the type of the entry
* @member: the list_node member of the type
*
* If the list is empty, returns NULL.
*
* Example:
* struct child *last;
* last = list_tail(&parent->children, struct child, list);
* if (!last)
* printf("Empty list!\n");
*/
#define list_tail(h, type, member) \
((type *)list_tail_((h), list_off_(type, member)))
static inline const void *list_tail_(const struct list_head *h, size_t off)
{
if (list_empty(h))
return NULL;
return (const char *)h->n.prev - off;
}
/**
* list_for_each - iterate through a list.
* @h: the list_head (warning: evaluated multiple times!)
* @i: the structure containing the list_node
* @member: the list_node member of the structure
*
* This is a convenient wrapper to iterate @i over the entire list. It's
* a for loop, so you can break and continue as normal.
*
* Example:
* list_for_each(&parent->children, child, list)
* printf("Name: %s\n", child->name);
*/
#define list_for_each(h, i, member) \
list_for_each_off(h, i, list_off_var_(i, member))
/**
* list_for_each_rev - iterate through a list backwards.
* @h: the list_head
* @i: the structure containing the list_node
* @member: the list_node member of the structure
*
* This is a convenient wrapper to iterate @i over the entire list. It's
* a for loop, so you can break and continue as normal.
*
* Example:
* list_for_each_rev(&parent->children, child, list)
* printf("Name: %s\n", child->name);
*/
#define list_for_each_rev(h, i, member) \
list_for_each_rev_off(h, i, list_off_var_(i, member))
/**
* list_for_each_rev_safe - iterate through a list backwards,
* maybe during deletion
* @h: the list_head
* @i: the structure containing the list_node
* @nxt: the structure containing the list_node
* @member: the list_node member of the structure
*
* This is a convenient wrapper to iterate @i over the entire list backwards.
* It's a for loop, so you can break and continue as normal. The extra
* variable * @nxt is used to hold the next element, so you can delete @i
* from the list.
*
* Example:
* struct child *next;
* list_for_each_rev_safe(&parent->children, child, next, list) {
* printf("Name: %s\n", child->name);
* }
*/
#define list_for_each_rev_safe(h, i, nxt, member) \
list_for_each_rev_safe_off(h, i, nxt, list_off_var_(i, member))
/**
* list_for_each_safe - iterate through a list, maybe during deletion
* @h: the list_head
* @i: the structure containing the list_node
* @nxt: the structure containing the list_node
* @member: the list_node member of the structure
*
* This is a convenient wrapper to iterate @i over the entire list. It's
* a for loop, so you can break and continue as normal. The extra variable
* @nxt is used to hold the next element, so you can delete @i from the list.
*
* Example:
* list_for_each_safe(&parent->children, child, next, list) {
* list_del(&child->list);
* parent->num_children--;
* }
*/
#define list_for_each_safe(h, i, nxt, member) \
list_for_each_safe_off(h, i, nxt, list_off_var_(i, member))
/**
* list_next - get the next entry in a list
* @h: the list_head
* @i: a pointer to an entry in the list.
* @member: the list_node member of the structure
*
* If @i was the last entry in the list, returns NULL.
*
* Example:
* struct child *second;
* second = list_next(&parent->children, first, list);
* if (!second)
* printf("No second child!\n");
*/
#define list_next(h, i, member) \
((list_typeof(i))list_entry_or_null(list_debug(h, \
__FILE__ ":" stringify(__LINE__)), \
(i)->member.next, \
list_off_var_((i), member)))
/**
* list_prev - get the previous entry in a list
* @h: the list_head
* @i: a pointer to an entry in the list.
* @member: the list_node member of the structure
*
* If @i was the first entry in the list, returns NULL.
*
* Example:
* first = list_prev(&parent->children, second, list);
* if (!first)
* printf("Can't go back to first child?!\n");
*/
#define list_prev(h, i, member) \
((list_typeof(i))list_entry_or_null(list_debug(h, \
__FILE__ ":" stringify(__LINE__)), \
(i)->member.prev, \
list_off_var_((i), member)))
/**
* list_append_list - empty one list onto the end of another.
* @to: the list to append into
* @from: the list to empty.
*
* This takes the entire contents of @from and moves it to the end of
* @to. After this @from will be empty.
*
* Example:
* struct list_head adopter;
*
* list_append_list(&adopter, &parent->children);
* assert(list_empty(&parent->children));
* parent->num_children = 0;
*/
#define list_append_list(t, f) list_append_list_(t, f, \
__FILE__ ":" stringify(__LINE__))
static inline void list_append_list_(struct list_head *to,
struct list_head *from,
const char *abortstr)
{
struct list_node *from_tail = list_debug(from, abortstr)->n.prev;
struct list_node *to_tail = list_debug(to, abortstr)->n.prev;
/* Sew in head and entire list. */
to->n.prev = from_tail;
from_tail->next = &to->n;
to_tail->next = &from->n;
from->n.prev = to_tail;
/* Now remove head. */
list_del(&from->n);
list_head_init(from);
}
/**
* list_prepend_list - empty one list into the start of another.
* @to: the list to prepend into
* @from: the list to empty.
*
* This takes the entire contents of @from and moves it to the start
* of @to. After this @from will be empty.
*
* Example:
* list_prepend_list(&adopter, &parent->children);
* assert(list_empty(&parent->children));
* parent->num_children = 0;
*/
#define list_prepend_list(t, f) list_prepend_list_(t, f, LIST_LOC)
static inline void list_prepend_list_(struct list_head *to,
struct list_head *from,
const char *abortstr)
{
struct list_node *from_tail = list_debug(from, abortstr)->n.prev;
struct list_node *to_head = list_debug(to, abortstr)->n.next;
/* Sew in head and entire list. */
to->n.next = &from->n;
from->n.prev = &to->n;
to_head->prev = from_tail;
from_tail->next = to_head;
/* Now remove head. */
list_del(&from->n);
list_head_init(from);
}
/* internal macros, do not use directly */
#define list_for_each_off_dir_(h, i, off, dir) \
for (i = list_node_to_off_(list_debug(h, LIST_LOC)->n.dir, \
(off)); \
list_node_from_off_((void *)i, (off)) != &(h)->n; \
i = list_node_to_off_(list_node_from_off_((void *)i, (off))->dir, \
(off)))
#define list_for_each_safe_off_dir_(h, i, nxt, off, dir) \
for (i = list_node_to_off_(list_debug(h, LIST_LOC)->n.dir, \
(off)), \
nxt = list_node_to_off_(list_node_from_off_(i, (off))->dir, \
(off)); \
list_node_from_off_(i, (off)) != &(h)->n; \
i = nxt, \
nxt = list_node_to_off_(list_node_from_off_(i, (off))->dir, \
(off)))
/**
* list_for_each_off - iterate through a list of memory regions.
* @h: the list_head
* @i: the pointer to a memory region which contains list node data.
* @off: offset(relative to @i) at which list node data resides.
*
* This is a low-level wrapper to iterate @i over the entire list, used to
* implement all oher, more high-level, for-each constructs. It's a for loop,
* so you can break and continue as normal.
*
* WARNING! Being the low-level macro that it is, this wrapper doesn't know
* nor care about the type of @i. The only assumption made is that @i points
* to a chunk of memory that at some @offset, relative to @i, contains a
* properly filled `struct list_node' which in turn contains pointers to
* memory chunks and it's turtles all the way down. With all that in mind
* remember that given the wrong pointer/offset couple this macro will
* happily churn all you memory until SEGFAULT stops it, in other words
* caveat emptor.
*
* It is worth mentioning that one of legitimate use-cases for that wrapper
* is operation on opaque types with known offset for `struct list_node'
* member(preferably 0), because it allows you not to disclose the type of
* @i.
*
* Example:
* list_for_each_off(&parent->children, child,
* offsetof(struct child, list))
* printf("Name: %s\n", child->name);
*/
#define list_for_each_off(h, i, off) \
list_for_each_off_dir_((h),(i),(off),next)
/**
* list_for_each_rev_off - iterate through a list of memory regions backwards
* @h: the list_head
* @i: the pointer to a memory region which contains list node data.
* @off: offset(relative to @i) at which list node data resides.
*
* See list_for_each_off for details
*/
#define list_for_each_rev_off(h, i, off) \
list_for_each_off_dir_((h),(i),(off),prev)
/**
* list_for_each_safe_off - iterate through a list of memory regions, maybe
* during deletion
* @h: the list_head
* @i: the pointer to a memory region which contains list node data.
* @nxt: the structure containing the list_node
* @off: offset(relative to @i) at which list node data resides.
*
* For details see `list_for_each_off' and `list_for_each_safe'
* descriptions.
*
* Example:
* list_for_each_safe_off(&parent->children, child,
* next, offsetof(struct child, list))
* printf("Name: %s\n", child->name);
*/
#define list_for_each_safe_off(h, i, nxt, off) \
list_for_each_safe_off_dir_((h),(i),(nxt),(off),next)
/**
* list_for_each_rev_safe_off - iterate backwards through a list of
* memory regions, maybe during deletion
* @h: the list_head
* @i: the pointer to a memory region which contains list node data.
* @nxt: the structure containing the list_node
* @off: offset(relative to @i) at which list node data resides.
*
* For details see `list_for_each_rev_off' and `list_for_each_rev_safe'
* descriptions.
*
* Example:
* list_for_each_rev_safe_off(&parent->children, child,
* next, offsetof(struct child, list))
* printf("Name: %s\n", child->name);
*/
#define list_for_each_rev_safe_off(h, i, nxt, off) \
list_for_each_safe_off_dir_((h),(i),(nxt),(off),prev)
/* Other -off variants. */
#define list_entry_off(n, type, off) \
((type *)list_node_from_off_((n), (off)))
#define list_head_off(h, type, off) \
((type *)list_head_off((h), (off)))
#define list_tail_off(h, type, off) \
((type *)list_tail_((h), (off)))
#define list_add_off(h, n, off) \
list_add((h), list_node_from_off_((n), (off)))
#define list_del_off(n, off) \
list_del(list_node_from_off_((n), (off)))
#define list_del_from_off(h, n, off) \
list_del_from(h, list_node_from_off_((n), (off)))
/* Offset helper functions so we only single-evaluate. */
static inline void *list_node_to_off_(struct list_node *node, size_t off)
{
return (void *)((char *)node - off);
}
static inline struct list_node *list_node_from_off_(void *ptr, size_t off)
{
return (struct list_node *)((char *)ptr + off);
}
/* Get the offset of the member, but make sure it's a list_node. */
#define list_off_(type, member) \
(container_off(type, member) + \
check_type(((type *)0)->member, struct list_node))
#define list_off_var_(var, member) \
(container_off_var(var, member) + \
check_type(var->member, struct list_node))
#if HAVE_TYPEOF
#define list_typeof(var) typeof(var)
#else
#define list_typeof(var) void *
#endif
/* Returns member, or NULL if at end of list. */
static inline void *list_entry_or_null(const struct list_head *h,
const struct list_node *n,
size_t off)
{
if (n == &h->n)
return NULL;
return (char *)n - off;
}
#endif /* CCAN_LIST_H */

1
ccan/ccan/str/LICENSE Symbolic link
View file

@ -0,0 +1 @@
../../licenses/CC0

52
ccan/ccan/str/_info Normal file
View file

@ -0,0 +1,52 @@
#include "config.h"
#include <stdio.h>
#include <string.h>
/**
* str - string helper routines
*
* This is a grab bag of functions for string operations, designed to enhance
* the standard string.h.
*
* Note that if you define CCAN_STR_DEBUG, you will get extra compile
* checks on common misuses of the following functions (they will now
* be out-of-line, so there is a runtime penalty!).
*
* strstr, strchr, strrchr:
* Return const char * if first argument is const (gcc only).
*
* isalnum, isalpha, isascii, isblank, iscntrl, isdigit, isgraph,
* islower, isprint, ispunct, isspace, isupper, isxdigit:
* Static and runtime check that input is EOF or an *unsigned*
* char, as per C standard (really!).
*
* Example:
* #include <stdio.h>
* #include <ccan/str/str.h>
*
* int main(int argc, char *argv[])
* {
* if (argc > 1 && streq(argv[1], "--verbose"))
* printf("verbose set\n");
* if (argc > 1 && strstarts(argv[1], "--"))
* printf("Some option set\n");
* if (argc > 1 && strends(argv[1], "cow-powers"))
* printf("Magic option set\n");
* return 0;
* }
*
* License: CC0 (Public domain)
* Author: Rusty Russell <rusty@rustcorp.com.au>
*/
int main(int argc, char *argv[])
{
if (argc != 2)
return 1;
if (strcmp(argv[1], "depends") == 0) {
printf("ccan/build_assert\n");
return 0;
}
return 1;
}

108
ccan/ccan/str/debug.c Normal file
View file

@ -0,0 +1,108 @@
/* CC0 (Public domain) - see LICENSE file for details */
#include "config.h"
#include <ccan/str/str_debug.h>
#include <assert.h>
#include <ctype.h>
#include <string.h>
#ifdef CCAN_STR_DEBUG
/* Because we mug the real ones with macros, we need our own wrappers. */
int str_isalnum(int i)
{
assert(i >= -1 && i < 256);
return isalnum(i);
}
int str_isalpha(int i)
{
assert(i >= -1 && i < 256);
return isalpha(i);
}
int str_isascii(int i)
{
assert(i >= -1 && i < 256);
return isascii(i);
}
#if HAVE_ISBLANK
int str_isblank(int i)
{
assert(i >= -1 && i < 256);
return isblank(i);
}
#endif
int str_iscntrl(int i)
{
assert(i >= -1 && i < 256);
return iscntrl(i);
}
int str_isdigit(int i)
{
assert(i >= -1 && i < 256);
return isdigit(i);
}
int str_isgraph(int i)
{
assert(i >= -1 && i < 256);
return isgraph(i);
}
int str_islower(int i)
{
assert(i >= -1 && i < 256);
return islower(i);
}
int str_isprint(int i)
{
assert(i >= -1 && i < 256);
return isprint(i);
}
int str_ispunct(int i)
{
assert(i >= -1 && i < 256);
return ispunct(i);
}
int str_isspace(int i)
{
assert(i >= -1 && i < 256);
return isspace(i);
}
int str_isupper(int i)
{
assert(i >= -1 && i < 256);
return isupper(i);
}
int str_isxdigit(int i)
{
assert(i >= -1 && i < 256);
return isxdigit(i);
}
#undef strstr
#undef strchr
#undef strrchr
char *str_strstr(const char *haystack, const char *needle)
{
return strstr(haystack, needle);
}
char *str_strchr(const char *haystack, int c)
{
return strchr(haystack, c);
}
char *str_strrchr(const char *haystack, int c)
{
return strrchr(haystack, c);
}
#endif

13
ccan/ccan/str/str.c Normal file
View file

@ -0,0 +1,13 @@
/* CC0 (Public domain) - see LICENSE file for details */
#include <ccan/str/str.h>
size_t strcount(const char *haystack, const char *needle)
{
size_t i = 0, nlen = strlen(needle);
while ((haystack = strstr(haystack, needle)) != NULL) {
i++;
haystack += nlen;
}
return i;
}

228
ccan/ccan/str/str.h Normal file
View file

@ -0,0 +1,228 @@
/* CC0 (Public domain) - see LICENSE file for details */
#ifndef CCAN_STR_H
#define CCAN_STR_H
#include "config.h"
#include <string.h>
#include <stdbool.h>
#include <limits.h>
#include <ctype.h>
/**
* streq - Are two strings equal?
* @a: first string
* @b: first string
*
* This macro is arguably more readable than "!strcmp(a, b)".
*
* Example:
* if (streq(somestring, ""))
* printf("String is empty!\n");
*/
#define streq(a,b) (strcmp((a),(b)) == 0)
/**
* strstarts - Does this string start with this prefix?
* @str: string to test
* @prefix: prefix to look for at start of str
*
* Example:
* if (strstarts(somestring, "foo"))
* printf("String %s begins with 'foo'!\n", somestring);
*/
#define strstarts(str,prefix) (strncmp((str),(prefix),strlen(prefix)) == 0)
/**
* strends - Does this string end with this postfix?
* @str: string to test
* @postfix: postfix to look for at end of str
*
* Example:
* if (strends(somestring, "foo"))
* printf("String %s end with 'foo'!\n", somestring);
*/
static inline bool strends(const char *str, const char *postfix)
{
if (strlen(str) < strlen(postfix))
return false;
return streq(str + strlen(str) - strlen(postfix), postfix);
}
/**
* stringify - Turn expression into a string literal
* @expr: any C expression
*
* Example:
* #define PRINT_COND_IF_FALSE(cond) \
* ((cond) || printf("%s is false!", stringify(cond)))
*/
#define stringify(expr) stringify_1(expr)
/* Double-indirection required to stringify expansions */
#define stringify_1(expr) #expr
/**
* strcount - Count number of (non-overlapping) occurrences of a substring.
* @haystack: a C string
* @needle: a substring
*
* Example:
* assert(strcount("aaa aaa", "a") == 6);
* assert(strcount("aaa aaa", "ab") == 0);
* assert(strcount("aaa aaa", "aa") == 2);
*/
size_t strcount(const char *haystack, const char *needle);
/**
* STR_MAX_CHARS - Maximum possible size of numeric string for this type.
* @type_or_expr: a pointer or integer type or expression.
*
* This provides enough space for a nul-terminated string which represents the
* largest possible value for the type or expression.
*
* Note: The implementation adds extra space so hex values or negative
* values will fit (eg. sprintf(... "%p"). )
*
* Example:
* char str[STR_MAX_CHARS(int)];
*
* sprintf(str, "%i", 7);
*/
#define STR_MAX_CHARS(type_or_expr) \
((sizeof(type_or_expr) * CHAR_BIT + 8) / 9 * 3 + 2 \
+ STR_MAX_CHARS_TCHECK_(type_or_expr))
#if HAVE_TYPEOF
/* Only a simple type can have 0 assigned, so test that. */
#define STR_MAX_CHARS_TCHECK_(type_or_expr) \
(sizeof(({ typeof(type_or_expr) x = 0; x; }))*0)
#else
#define STR_MAX_CHARS_TCHECK_(type_or_expr) 0
#endif
/**
* cisalnum - isalnum() which takes a char (and doesn't accept EOF)
* @c: a character
*
* Surprisingly, the standard ctype.h isalnum() takes an int, which
* must have the value of EOF (-1) or an unsigned char. This variant
* takes a real char, and doesn't accept EOF.
*/
static inline bool cisalnum(char c)
{
return isalnum((unsigned char)c);
}
static inline bool cisalpha(char c)
{
return isalpha((unsigned char)c);
}
static inline bool cisascii(char c)
{
return isascii((unsigned char)c);
}
#if HAVE_ISBLANK
static inline bool cisblank(char c)
{
return isblank((unsigned char)c);
}
#endif
static inline bool ciscntrl(char c)
{
return iscntrl((unsigned char)c);
}
static inline bool cisdigit(char c)
{
return isdigit((unsigned char)c);
}
static inline bool cisgraph(char c)
{
return isgraph((unsigned char)c);
}
static inline bool cislower(char c)
{
return islower((unsigned char)c);
}
static inline bool cisprint(char c)
{
return isprint((unsigned char)c);
}
static inline bool cispunct(char c)
{
return ispunct((unsigned char)c);
}
static inline bool cisspace(char c)
{
return isspace((unsigned char)c);
}
static inline bool cisupper(char c)
{
return isupper((unsigned char)c);
}
static inline bool cisxdigit(char c)
{
return isxdigit((unsigned char)c);
}
#include <ccan/str/str_debug.h>
/* These checks force things out of line, hence they are under DEBUG. */
#ifdef CCAN_STR_DEBUG
#include <ccan/build_assert/build_assert.h>
/* These are commonly misused: they take -1 or an *unsigned* char value. */
#undef isalnum
#undef isalpha
#undef isascii
#undef isblank
#undef iscntrl
#undef isdigit
#undef isgraph
#undef islower
#undef isprint
#undef ispunct
#undef isspace
#undef isupper
#undef isxdigit
/* You can use a char if char is unsigned. */
#if HAVE_BUILTIN_TYPES_COMPATIBLE_P && HAVE_TYPEOF
#define str_check_arg_(i) \
((i) + BUILD_ASSERT_OR_ZERO(!__builtin_types_compatible_p(typeof(i), \
char) \
|| (char)255 > 0))
#else
#define str_check_arg_(i) (i)
#endif
#define isalnum(i) str_isalnum(str_check_arg_(i))
#define isalpha(i) str_isalpha(str_check_arg_(i))
#define isascii(i) str_isascii(str_check_arg_(i))
#if HAVE_ISBLANK
#define isblank(i) str_isblank(str_check_arg_(i))
#endif
#define iscntrl(i) str_iscntrl(str_check_arg_(i))
#define isdigit(i) str_isdigit(str_check_arg_(i))
#define isgraph(i) str_isgraph(str_check_arg_(i))
#define islower(i) str_islower(str_check_arg_(i))
#define isprint(i) str_isprint(str_check_arg_(i))
#define ispunct(i) str_ispunct(str_check_arg_(i))
#define isspace(i) str_isspace(str_check_arg_(i))
#define isupper(i) str_isupper(str_check_arg_(i))
#define isxdigit(i) str_isxdigit(str_check_arg_(i))
#if HAVE_TYPEOF
/* With GNU magic, we can make const-respecting standard string functions. */
#undef strstr
#undef strchr
#undef strrchr
/* + 0 is needed to decay array into pointer. */
#define strstr(haystack, needle) \
((typeof((haystack) + 0))str_strstr((haystack), (needle)))
#define strchr(haystack, c) \
((typeof((haystack) + 0))str_strchr((haystack), (c)))
#define strrchr(haystack, c) \
((typeof((haystack) + 0))str_strrchr((haystack), (c)))
#endif
#endif /* CCAN_STR_DEBUG */
#endif /* CCAN_STR_H */

30
ccan/ccan/str/str_debug.h Normal file
View file

@ -0,0 +1,30 @@
/* CC0 (Public domain) - see LICENSE file for details */
#ifndef CCAN_STR_DEBUG_H
#define CCAN_STR_DEBUG_H
/* #define CCAN_STR_DEBUG 1 */
#ifdef CCAN_STR_DEBUG
/* Because we mug the real ones with macros, we need our own wrappers. */
int str_isalnum(int i);
int str_isalpha(int i);
int str_isascii(int i);
#if HAVE_ISBLANK
int str_isblank(int i);
#endif
int str_iscntrl(int i);
int str_isdigit(int i);
int str_isgraph(int i);
int str_islower(int i);
int str_isprint(int i);
int str_ispunct(int i);
int str_isspace(int i);
int str_isupper(int i);
int str_isxdigit(int i);
char *str_strstr(const char *haystack, const char *needle);
char *str_strchr(const char *s, int c);
char *str_strrchr(const char *s, int c);
#endif /* CCAN_STR_DEBUG */
#endif /* CCAN_STR_DEBUG_H */