eBookReaderSwitch/include/mupdf/fitz/context.h

330 lines
9.6 KiB
C

#ifndef MUPDF_FITZ_CONTEXT_H
#define MUPDF_FITZ_CONTEXT_H
#include "mupdf/fitz/version.h"
#include "mupdf/fitz/system.h"
#include "mupdf/fitz/geometry.h"
typedef struct fz_font_context_s fz_font_context;
typedef struct fz_colorspace_context_s fz_colorspace_context;
typedef struct fz_style_context_s fz_style_context;
typedef struct fz_tuning_context_s fz_tuning_context;
typedef struct fz_store_s fz_store;
typedef struct fz_glyph_cache_s fz_glyph_cache;
typedef struct fz_document_handler_context_s fz_document_handler_context;
typedef struct fz_context_s fz_context;
typedef struct fz_alloc_context_s fz_alloc_context;
struct fz_alloc_context_s
{
void *user;
void *(*malloc)(void *, size_t);
void *(*realloc)(void *, void *, size_t);
void (*free)(void *, void *);
};
typedef struct fz_error_stack_slot_s fz_error_stack_slot;
struct fz_error_stack_slot_s
{
int state, code;
fz_jmp_buf buffer;
};
typedef struct fz_error_context_s fz_error_context;
struct fz_error_context_s
{
fz_error_stack_slot *top;
fz_error_stack_slot stack[256];
int errcode;
void *print_user;
void (*print)(void *user, const char *message);
char message[256];
};
typedef struct fz_warn_context_s fz_warn_context;
struct fz_warn_context_s
{
void *print_user;
void (*print)(void *user, const char *message);
int count;
char message[256];
};
typedef struct fz_aa_context_s fz_aa_context;
struct fz_aa_context_s
{
int hscale;
int vscale;
int scale;
int bits;
int text_bits;
float min_line_width;
};
/*
Exception macro definitions. Just treat these as a black box - pay no
attention to the man behind the curtain.
*/
void fz_var_imp(void *);
#define fz_var(var) fz_var_imp((void *)&(var))
fz_jmp_buf *fz_push_try(fz_context *ctx);
int fz_do_try(fz_context *ctx);
int fz_do_always(fz_context *ctx);
int fz_do_catch(fz_context *ctx);
#define fz_try(ctx) if (!fz_setjmp(*fz_push_try(ctx))) if (fz_do_try(ctx)) do
#define fz_always(ctx) while (0); if (fz_do_always(ctx)) do
#define fz_catch(ctx) while (0); if (fz_do_catch(ctx))
FZ_NORETURN void fz_vthrow(fz_context *ctx, int errcode, const char *, va_list ap);
FZ_NORETURN void fz_throw(fz_context *ctx, int errcode, const char *, ...) FZ_PRINTFLIKE(3,4);
FZ_NORETURN void fz_rethrow(fz_context *ctx);
void fz_vwarn(fz_context *ctx, const char *fmt, va_list ap);
void fz_warn(fz_context *ctx, const char *fmt, ...) FZ_PRINTFLIKE(2,3);
const char *fz_caught_message(fz_context *ctx);
int fz_caught(fz_context *ctx);
void fz_rethrow_if(fz_context *ctx, int errcode);
enum
{
FZ_ERROR_NONE = 0,
FZ_ERROR_MEMORY = 1,
FZ_ERROR_GENERIC = 2,
FZ_ERROR_SYNTAX = 3,
FZ_ERROR_MINOR = 4,
FZ_ERROR_TRYLATER = 5,
FZ_ERROR_ABORT = 6,
FZ_ERROR_COUNT
};
void fz_flush_warnings(fz_context *ctx);
/*
Locking functions
MuPDF is kept deliberately free of any knowledge of particular
threading systems. As such, in order for safe multi-threaded
operation, we rely on callbacks to client provided functions.
A client is expected to provide FZ_LOCK_MAX number of mutexes,
and a function to lock/unlock each of them. These may be
recursive mutexes, but do not have to be.
If a client does not intend to use multiple threads, then it
may pass NULL instead of a lock structure.
In order to avoid deadlocks, we have one simple rule
internally as to how we use locks: We can never take lock n
when we already hold any lock i, where 0 <= i <= n. In order
to verify this, we have some debugging code, that can be
enabled by defining FITZ_DEBUG_LOCKING.
*/
typedef struct fz_locks_context_s fz_locks_context;
struct fz_locks_context_s
{
void *user;
void (*lock)(void *user, int lock);
void (*unlock)(void *user, int lock);
};
enum {
FZ_LOCK_ALLOC = 0,
FZ_LOCK_FREETYPE,
FZ_LOCK_GLYPHCACHE,
FZ_LOCK_MAX
};
struct fz_context_s
{
void *user;
fz_alloc_context alloc;
fz_locks_context locks;
fz_error_context error;
fz_warn_context warn;
/* unshared contexts */
fz_aa_context aa;
uint16_t seed48[7];
#if FZ_ENABLE_ICC
int icc_enabled;
#endif
/* TODO: should these be unshared? */
fz_document_handler_context *handler;
fz_style_context *style;
fz_tuning_context *tuning;
/* shared contexts */
fz_font_context *font;
fz_colorspace_context *colorspace;
fz_store *store;
fz_glyph_cache *glyph_cache;
};
/*
Specifies the maximum size in bytes of the resource store in
fz_context. Given as argument to fz_new_context.
FZ_STORE_UNLIMITED: Let resource store grow unbounded.
FZ_STORE_DEFAULT: A reasonable upper bound on the size, for
devices that are not memory constrained.
*/
enum {
FZ_STORE_UNLIMITED = 0,
FZ_STORE_DEFAULT = 256 << 20,
};
fz_context *fz_new_context_imp(const fz_alloc_context *alloc, const fz_locks_context *locks, size_t max_store, const char *version);
#define fz_new_context(alloc, locks, max_store) fz_new_context_imp(alloc, locks, max_store, FZ_VERSION)
fz_context *fz_clone_context(fz_context *ctx);
void fz_drop_context(fz_context *ctx);
void fz_set_user_context(fz_context *ctx, void *user);
void *fz_user_context(fz_context *ctx);
void fz_default_error_callback(void *user, const char *message);
void fz_default_warning_callback(void *user, const char *message);
void fz_set_error_callback(fz_context *ctx, void (*print)(void *user, const char *message), void *user);
void fz_set_warning_callback(fz_context *ctx, void (*print)(void *user, const char *message), void *user);
/*
In order to tune MuPDF's behaviour, certain functions can
(optionally) be provided by callers.
*/
/*
Given the width and height of an image,
the subsample factor, and the subarea of the image actually
required, the caller can decide whether to decode the whole image
or just a subarea.
arg: The caller supplied opaque argument.
w, h: The width/height of the complete image.
l2factor: The log2 factor for subsampling (i.e. image will be
decoded to (w>>l2factor, h>>l2factor)).
subarea: The actual subarea required for the current operation.
The tuning function is allowed to increase this in size if required.
*/
typedef void (fz_tune_image_decode_fn)(void *arg, int w, int h, int l2factor, fz_irect *subarea);
/*
Given the source width and height of
image, together with the actual required width and height,
decide whether we should use mitchell scaling.
arg: The caller supplied opaque argument.
dst_w, dst_h: The actual width/height required on the target device.
src_w, src_h: The source width/height of the image.
Return 0 not to use the Mitchell scaler, 1 to use the Mitchell scaler. All
other values reserved.
*/
typedef int (fz_tune_image_scale_fn)(void *arg, int dst_w, int dst_h, int src_w, int src_h);
void fz_tune_image_decode(fz_context *ctx, fz_tune_image_decode_fn *image_decode, void *arg);
void fz_tune_image_scale(fz_context *ctx, fz_tune_image_scale_fn *image_scale, void *arg);
int fz_aa_level(fz_context *ctx);
void fz_set_aa_level(fz_context *ctx, int bits);
int fz_text_aa_level(fz_context *ctx);
void fz_set_text_aa_level(fz_context *ctx, int bits);
int fz_graphics_aa_level(fz_context *ctx);
void fz_set_graphics_aa_level(fz_context *ctx, int bits);
float fz_graphics_min_line_width(fz_context *ctx);
void fz_set_graphics_min_line_width(fz_context *ctx, float min_line_width);
const char *fz_user_css(fz_context *ctx);
void fz_set_user_css(fz_context *ctx, const char *text);
int fz_use_document_css(fz_context *ctx);
void fz_set_use_document_css(fz_context *ctx, int use);
void fz_enable_icc(fz_context *ctx);
void fz_disable_icc(fz_context *ctx);
/*
Memory Allocation and Scavenging:
All calls to MuPDF's allocator functions pass through to the
underlying allocators passed in when the initial context is
created, after locks are taken (using the supplied locking function)
to ensure that only one thread at a time calls through.
If the underlying allocator fails, MuPDF attempts to make room for
the allocation by evicting elements from the store, then retrying.
Any call to allocate may then result in several calls to the underlying
allocator, and result in elements that are only referred to by the
store being freed.
*/
/*
* Allocate memory for a structure, clear it, and tag the pointer for Memento.
*/
#define fz_malloc_struct(CTX, TYPE) \
((TYPE*)Memento_label(fz_calloc(CTX, 1, sizeof(TYPE)), #TYPE))
/*
* Allocate uninitialized memory for an array of structures, and tag the
* pointer for Memento. Does NOT clear the memory!
*/
#define fz_malloc_array(CTX, COUNT, TYPE) \
((TYPE*)Memento_label(fz_malloc(CTX, (COUNT) * sizeof(TYPE)), #TYPE "[]"))
#define fz_realloc_array(CTX, OLD, COUNT, TYPE) \
((TYPE*)Memento_label(fz_realloc(CTX, OLD, (COUNT) * sizeof(TYPE)), #TYPE "[]"))
void *fz_malloc(fz_context *ctx, size_t size);
void *fz_calloc(fz_context *ctx, size_t count, size_t size);
void *fz_realloc(fz_context *ctx, void *p, size_t size);
void fz_free(fz_context *ctx, void *p);
void *fz_malloc_no_throw(fz_context *ctx, size_t size);
void *fz_calloc_no_throw(fz_context *ctx, size_t count, size_t size);
void *fz_realloc_no_throw(fz_context *ctx, void *p, size_t size);
char *fz_strdup(fz_context *ctx, const char *s);
void *fz_zlib_alloc(void *ctx, unsigned int items, unsigned int size);
void fz_zlib_free(void *ctx, void *ptr);
extern fz_alloc_context fz_alloc_default;
extern fz_locks_context fz_locks_default;
double fz_drand48(fz_context *ctx);
int32_t fz_lrand48(fz_context *ctx);
int32_t fz_mrand48(fz_context *ctx);
double fz_erand48(fz_context *ctx, uint16_t xsubi[3]);
int32_t fz_jrand48(fz_context *ctx, uint16_t xsubi[3]);
int32_t fz_nrand48(fz_context *ctx, uint16_t xsubi[3]);
void fz_lcong48(fz_context *ctx, uint16_t param[7]);
uint16_t *fz_seed48(fz_context *ctx, uint16_t seed16v[3]);
void fz_srand48(fz_context *ctx, int32_t seedval);
void fz_memrnd(fz_context *ctx, uint8_t *block, int len);
#endif