27 Miscellaneous Utilities (BC)🔗ℹ
The MZSCHEME_VERSION preprocessor macro is defined as a string
describing the version of Racket. The MZSCHEME_VERSION_MAJOR
and MZSCHEME_VERSION_MINOR macros are defined as the major and
minor version numbers, respectively.
int | | scheme_eq | ( | Scheme_Object* obj1, | | | | | Scheme_Object* obj2) |
|
Returns 1 if the Scheme values are
eq?.
int | | scheme_eqv | ( | Scheme_Object* obj1, | | | | | Scheme_Object* obj2) |
|
Returns 1 if the Scheme values are
eqv?.
Returns 1 if the Scheme values are
equal?.
Returns the primary
equal?-hash key for
obj.
Returns the secondary
equal?-hash key for
obj.
Creates and returns a list of length c with the elements
elems.
Returns the length of the list. If
list is not a proper list,
then the last
cdr counts as an item. If there is a cycle in
list (involving only
cdrs), this procedure will not
terminate.
Returns the length of the list, or -1 if it is not a proper list. If
there is a cycle in
list (involving only
cdrs), this
procedure returns -1.
Returns the
car of the pair.
Returns the
cdr of the pair.
Returns the
cadr of the pair.
Returns the
caddr of the pair.
Creates a list with the same elements as the given vector.
Creates a vector with the same elements as the given list.
Scheme_Object* | | scheme_append | ( | Scheme_Object* lstx, | | | | | Scheme_Object* lsty) |
|
Non-destructively appends the given lists.
Returns the contents of the given box.
Sets the contents of the given box.
The same as
dynamic-require. The
argc argument must be
2, and
argv contains the arguments.
Loads the specified Racket file, returning the value of the last
expression loaded, or NULL if the load fails.
Loads the specified Racket extension file, returning the value provided
by the extension’s initialization function.
Creates a hash table. The type argument must be either
SCHEME_hash_ptr or SCHEME_hash_string, which determines
how keys are compared (unless the hash and compare functions are
modified in the hash table record; see below). A SCHEME_hash_ptr
table hashes on a key’s pointer address, while
SCHEME_hash_string uses a key as a char* and hashes on the
null-terminated string content. Since a hash table created with
SCHEME_hash_string (instead of SCHEME_hash_ptr) does not
use a key as a Racket value, it cannot be used from Racket code.
Although the hash table interface uses the type Scheme_Object*
for both keys and values, the table functions never inspect values,
and they inspect keys only for SCHEME_hash_string hashing. Thus,
the actual types of the values (and keys, for SCHEME_hash_ptr
tables) can be anything.
The public portion of the Scheme_Hash_Table type is defined
roughly as follows:
typedef struct Scheme_Hash_Table { |
Scheme_Object so; /* so.type == scheme_hash_table_type */ |
/* ... */ |
int size; /* size of keys and vals arrays */ |
int count; /* number of mapped keys */ |
Scheme_Object **keys; |
Scheme_Object **vals; |
void (*make_hash_indices)(void *v, intptr_t *h1, intptr_t *h2); |
int (*compare)(void *v1, void *v2); |
/* ... */ |
} Scheme_Hash_Table; |
The make_hash_indices and compare function pointers can be
set to arbitrary hashing and comparison functions (before any mapping
is installed into the table). A hash function should fill h1
with a primary hash value and h2 with a secondary hash value;
the values are for double-hashing, where the caller takes appropriate
modulos. Either h1 or h2 can be NULL if the
corresponding hash code is not needed.
To traverse the hash table content, iterate over keys and
vals in parallel from 0 to size-1, and ignore
keys where the corresponding vals entry is NULL.
The count field indicates the number of non-NULL values
that will be encountered.
void | | scheme_hash_set | ( | Scheme_Hash_Table* table, | | | | | Scheme_Object* key, | | | | | Scheme_Object* val) |
|
Sets the current value for key in table to val. If
val is NULL, the key is unmapped in table.
Scheme_Object* | | scheme_hash_get | ( | Scheme_Hash_Table* table, | | | | | Scheme_Object* key) |
|
Returns the current value for key in table, or NULL
if key has no value.
Like make_hash_table, but bucket tables are somewhat more
flexible, in that hash buckets are accessible and weak keys are
supported. (They also consume more space than hash tables.)
The type argument must be either SCHEME_hash_ptr,
SCHEME_hash_string, or SCHEME_hash_weak_ptr. The first
two are the same as for hash tables. The last is like
SCHEME_hash_ptr, but the keys are weakly held.
The public portion of the Scheme_Bucket_Table type is defined
roughly as follows:
typedef struct Scheme_Bucket_Table { |
Scheme_Object so; /* so.type == scheme_variable_type */ |
/* ... */ |
int size; /* size of buckets array */ |
int count; /* number of buckets, >= number of mapped keys */ |
Scheme_Bucket **buckets; |
void (*make_hash_indices)(void *v, intptr_t *h1, intptr_t *h2); |
int (*compare)(void *v1, void *v2); |
/* ... */ |
} Scheme_Bucket_Table; |
The make_hash_indices and compare functions are used as
for hash tables. Note that SCHEME_hash_weak_ptr supplied as the
initial type makes keys weak even if the hash and comparison functions
are changed.
See scheme_bucket_from_table for information on buckets.
Sets the current value for key in table to val. If
const is non-zero, the value for key must never be
changed.
Sets the current value for key in table to val, but
only if key is already mapped in the table.
Returns the current value for key in table, or NULL
if key has no value.
Returns the bucket for key in table. The
Scheme_Bucket structure is defined as:
typedef struct Scheme_Bucket { |
Scheme_Object so; /* so.type == scheme_bucket_type */ |
/* ... */ |
void *key; |
void *val; |
} Scheme_Bucket; |
Setting val to NULL unmaps the bucket’s key, and key
can be NULL in that case as well. If the table holds keys
weakly, then key points to a (weak) pointer to the actual key,
and the weak pointer’s value can be NULL.
Similar to
scheme_make_hash_table, but creates a hash
tree. A hash tree is equivalent to an immutable hash table
created by
hash. The
type argument must be
either
SCHEME_hashtr_eq,
SCHEME_hashtr_equal, or
SCHEME_hashtr_eqv,
which determines how keys are compared.
Returns a fixnum value for the given floating-point number d. If d
is not an integer or if it is too large, then an error message is
reported; name is used for error-reporting.
Returns the string that is used as the Racket startup banner.
Returns a string for the executing version of Racket.
Returns an
eq?-based hash table that is global to the current
place.
A key generated by scheme_malloc_key can be useful as a common
key across multiple places.
Generates an uncollectable Racket value that can be used across
places. Free the value with
scheme_free_key.
Frees a key allocated with
scheme_malloc_key. When a key is
freed, it must not be accessible from any GC-travsered reference in
any place.
Gets or sets a value in a process-global table (i.e., shared across
multiple places, if any). If val is NULL, the current mapping
for key is given. If val is not NULL, and no value has been
installed for that key, then the value is installed and NULL is returned. If a
value has already been installed, then no new value is installed and the old
value is returned. The given val must not refer to garbage-collected
memory.
This function is intended for infrequent use with a small number of
keys.
See also register-process-global from
ffi/unsafe/global.
Given the address of machine code generated by Racket’s compiler,
attempts to infer and return the address just after the end of the
generated code (for a single source function, typically). The result
is #f if the address cannot be inferred, which may be because
the given p does not refer to generated machine code.
Added in version 6.0.1.9.
If val is a procedure that can be JIT-compiled, JIT compilation
is forced immediately if it has not been forced already (usually
through calling the function).
Added in version 6.0.1.10.