/* SPDX-License-Identifier: LGPL-2.1-or-later */
/*
* Copyright (C) 2018 Red Hat, Inc.
*/
#ifndef __NM_SECRET_UTILS_H__
#define __NM_SECRET_UTILS_H__
#include "nm-macros-internal.h"
/*****************************************************************************/
void nm_explicit_bzero(void *s, gsize n);
/*****************************************************************************/
char *nm_secret_strchomp(char *secret);
/*****************************************************************************/
void nm_free_secret(char *secret);
NM_AUTO_DEFINE_FCN0(char *, _nm_auto_free_secret, nm_free_secret);
/**
* nm_auto_free_secret:
*
* Call g_free() on a variable location when it goes out of scope.
* Also, previously, calls memset(loc, 0, strlen(loc)) to clear out
* the secret.
*/
#define nm_auto_free_secret nm_auto(_nm_auto_free_secret)
/*****************************************************************************/
GBytes *nm_secret_copy_to_gbytes(gconstpointer mem, gsize mem_len);
/*****************************************************************************/
/* NMSecretPtr is a pair of malloc'ed data pointer and the length of the
* data. The purpose is to use it in combination with nm_auto_clear_secret_ptr
* which ensures that the data pointer (with all len bytes) is cleared upon
* cleanup. */
typedef struct {
gsize len;
/* the data pointer. This pointer must be allocated with malloc (at least
* when used with nm_secret_ptr_clear()). */
union {
char * str;
void * ptr;
guint8 *bin;
};
} NMSecretPtr;
static inline void
nm_secret_ptr_bzero(NMSecretPtr *secret)
{
if (secret) {
if (secret->len > 0) {
if (secret->ptr)
nm_explicit_bzero(secret->ptr, secret->len);
}
}
}
#define nm_auto_bzero_secret_ptr nm_auto(nm_secret_ptr_bzero)
static inline void
nm_secret_ptr_clear(NMSecretPtr *secret)
{
if (secret) {
if (secret->len > 0) {
if (secret->ptr)
nm_explicit_bzero(secret->ptr, secret->len);
secret->len = 0;
}
nm_clear_g_free(&secret->ptr);
}
}
#define nm_auto_clear_secret_ptr nm_auto(nm_secret_ptr_clear)
#define NM_SECRET_PTR_INIT() \
((const NMSecretPtr){ \
.len = 0, \
.ptr = NULL, \
})
#define NM_SECRET_PTR_STATIC(_len) \
((const NMSecretPtr){ \
.len = _len, \
.ptr = ((guint8[_len]){}), \
})
#define NM_SECRET_PTR_ARRAY(_arr) \
((const NMSecretPtr){ \
.len = G_N_ELEMENTS(_arr) * sizeof((_arr)[0]), \
.ptr = &((_arr)[0]), \
})
static inline void
nm_secret_ptr_clear_static(const NMSecretPtr *secret)
{
if (secret) {
if (secret->len > 0) {
nm_assert(secret->ptr);
nm_explicit_bzero(secret->ptr, secret->len);
}
}
}
#define nm_auto_clear_static_secret_ptr nm_auto(nm_secret_ptr_clear_static)
static inline void
nm_secret_ptr_move(NMSecretPtr *dst, NMSecretPtr *src)
{
if (dst && dst != src) {
*dst = *src;
src->len = 0;
src->ptr = NULL;
}
}
/*****************************************************************************/
typedef struct {
const gsize len;
union {
char str[0];
guint8 bin[0];
};
} NMSecretBuf;
static inline void
_nm_auto_free_secret_buf(NMSecretBuf **ptr)
{
NMSecretBuf *b = *ptr;
if (b) {
nm_assert(b->len > 0);
nm_explicit_bzero(b->bin, b->len);
g_free(b);
}
}
#define nm_auto_free_secret_buf nm_auto(_nm_auto_free_secret_buf)
NMSecretBuf *nm_secret_buf_new(gsize len);
GBytes *nm_secret_buf_to_gbytes_take(NMSecretBuf *secret, gssize actual_len);
/*****************************************************************************/
gboolean nm_utils_memeqzero_secret(gconstpointer data, gsize length);
/*****************************************************************************/
/**
* nm_secret_mem_realloc:
* @m_old: the current buffer of length @cur_len.
* @do_bzero_mem: if %TRUE, bzero the old buffer
* @cur_len: the current buffer length of @m_old. It is necessary for bzero.
* @new_len: the desired new length
*
* If @do_bzero_mem is false, this is like g_realloc().
* Otherwise, this will allocate a new buffer of the desired size, copy over the
* old data, and bzero the old buffer before freeing it. As such, it also behaves
* similar to g_realloc(), with the overhead of nm_explicit_bzero() and using
* malloc/free instead of realloc().
*
* Returns: the new allocated buffer. Think of it behaving like g_realloc().
*/
static inline gpointer
nm_secret_mem_realloc(gpointer m_old, gboolean do_bzero_mem, gsize cur_len, gsize new_len)
{
gpointer m_new;
nm_assert(m_old || cur_len == 0);
if (do_bzero_mem && G_LIKELY(cur_len > 0)) {
m_new = g_malloc(new_len);
if (G_LIKELY(new_len > 0))
memcpy(m_new, m_old, NM_MIN(cur_len, new_len));
nm_explicit_bzero(m_old, cur_len);
g_free(m_old);
} else
m_new = g_realloc(m_old, new_len);
return m_new;
}
/**
* nm_secret_mem_try_realloc:
* @m_old: the current buffer of length @cur_len.
* @do_bzero_mem: if %TRUE, bzero the old buffer
* @cur_len: the current buffer length of @m_old. It is necessary for bzero.
* @new_len: the desired new length
*
* If @do_bzero_mem is false, this is like g_try_realloc().
* Otherwise, this will try to allocate a new buffer of the desired size, copy over the
* old data, and bzero the old buffer before freeing it. As such, it also behaves
* similar to g_try_realloc(), with the overhead of nm_explicit_bzero() and using
* malloc/free instead of realloc().
*
* Returns: the new allocated buffer or NULL. Think of it behaving like g_try_realloc().
*/
static inline gpointer
nm_secret_mem_try_realloc(gpointer m_old, gboolean do_bzero_mem, gsize cur_len, gsize new_len)
{
gpointer m_new;
nm_assert(m_old || cur_len == 0);
if (do_bzero_mem && G_LIKELY(cur_len > 0)) {
if (G_UNLIKELY(new_len == 0))
m_new = NULL;
else {
m_new = g_try_malloc(new_len);
if (!m_new)
return NULL;
memcpy(m_new, m_old, NM_MIN(cur_len, new_len));
}
nm_explicit_bzero(m_old, cur_len);
g_free(m_old);
return m_new;
}
return g_try_realloc(m_old, new_len);
}
/**
* nm_secret_mem_try_realloc_take:
* @m_old: the current buffer of length @cur_len.
* @do_bzero_mem: if %TRUE, bzero the old buffer
* @cur_len: the current buffer length of @m_old. It is necessary for bzero.
* @new_len: the desired new length
*
* This works like nm_secret_mem_try_realloc(), which is not unlike g_try_realloc().
* The difference is, if we fail to allocate a new buffer, then @m_old will be
* freed (and possibly cleared). This differs from plain realloc(), where the
* old buffer is unchanged if the operation fails.
*
* Returns: the new allocated buffer or NULL. Think of it behaving like g_try_realloc()
* but it will always free @m_old.
*/
static inline gpointer
nm_secret_mem_try_realloc_take(gpointer m_old, gboolean do_bzero_mem, gsize cur_len, gsize new_len)
{
gpointer m_new;
nm_assert(m_old || cur_len == 0);
if (do_bzero_mem && G_LIKELY(cur_len > 0)) {
if (G_UNLIKELY(new_len == 0))
m_new = NULL;
else {
m_new = g_try_malloc(new_len);
if (G_LIKELY(m_new))
memcpy(m_new, m_old, NM_MIN(cur_len, new_len));
}
nm_explicit_bzero(m_old, cur_len);
g_free(m_old);
return m_new;
}
m_new = g_try_realloc(m_old, new_len);
if (G_UNLIKELY(!m_new && new_len > 0))
g_free(m_old);
return m_new;
}
/*****************************************************************************/
#endif /* __NM_SECRET_UTILS_H__ */