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1 /*
2  * Copyright (C) 2005 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 //
18 // Definitions of resource data structures.
19 //
20 #ifndef _LIBS_UTILS_RESOURCE_TYPES_H
21 #define _LIBS_UTILS_RESOURCE_TYPES_H
22 
23 #include <androidfw/Asset.h>
24 #include <utils/ByteOrder.h>
25 #include <utils/Errors.h>
26 #include <utils/String16.h>
27 #include <utils/Vector.h>
28 
29 #include <utils/threads.h>
30 
31 #include <stdint.h>
32 #include <sys/types.h>
33 
34 #include <android/configuration.h>
35 
36 namespace android {
37 
38 /** ********************************************************************
39  *  PNG Extensions
40  *
41  *  New private chunks that may be placed in PNG images.
42  *
43  *********************************************************************** */
44 
45 /**
46  * This chunk specifies how to split an image into segments for
47  * scaling.
48  *
49  * There are J horizontal and K vertical segments.  These segments divide
50  * the image into J*K regions as follows (where J=4 and K=3):
51  *
52  *      F0   S0    F1     S1
53  *   +-----+----+------+-------+
54  * S2|  0  |  1 |  2   |   3   |
55  *   +-----+----+------+-------+
56  *   |     |    |      |       |
57  *   |     |    |      |       |
58  * F2|  4  |  5 |  6   |   7   |
59  *   |     |    |      |       |
60  *   |     |    |      |       |
61  *   +-----+----+------+-------+
62  * S3|  8  |  9 |  10  |   11  |
63  *   +-----+----+------+-------+
64  *
65  * Each horizontal and vertical segment is considered to by either
66  * stretchable (marked by the Sx labels) or fixed (marked by the Fy
67  * labels), in the horizontal or vertical axis, respectively. In the
68  * above example, the first is horizontal segment (F0) is fixed, the
69  * next is stretchable and then they continue to alternate. Note that
70  * the segment list for each axis can begin or end with a stretchable
71  * or fixed segment.
72  *
73  * The relative sizes of the stretchy segments indicates the relative
74  * amount of stretchiness of the regions bordered by the segments.  For
75  * example, regions 3, 7 and 11 above will take up more horizontal space
76  * than regions 1, 5 and 9 since the horizontal segment associated with
77  * the first set of regions is larger than the other set of regions.  The
78  * ratios of the amount of horizontal (or vertical) space taken by any
79  * two stretchable slices is exactly the ratio of their corresponding
80  * segment lengths.
81  *
82  * xDivs and yDivs point to arrays of horizontal and vertical pixel
83  * indices.  The first pair of Divs (in either array) indicate the
84  * starting and ending points of the first stretchable segment in that
85  * axis. The next pair specifies the next stretchable segment, etc. So
86  * in the above example xDiv[0] and xDiv[1] specify the horizontal
87  * coordinates for the regions labeled 1, 5 and 9.  xDiv[2] and
88  * xDiv[3] specify the coordinates for regions 3, 7 and 11. Note that
89  * the leftmost slices always start at x=0 and the rightmost slices
90  * always end at the end of the image. So, for example, the regions 0,
91  * 4 and 8 (which are fixed along the X axis) start at x value 0 and
92  * go to xDiv[0] and slices 2, 6 and 10 start at xDiv[1] and end at
93  * xDiv[2].
94  *
95  * The array pointed to by the colors field lists contains hints for
96  * each of the regions.  They are ordered according left-to-right and
97  * top-to-bottom as indicated above. For each segment that is a solid
98  * color the array entry will contain that color value; otherwise it
99  * will contain NO_COLOR.  Segments that are completely transparent
100  * will always have the value TRANSPARENT_COLOR.
101  *
102  * The PNG chunk type is "npTc".
103  */
104 struct Res_png_9patch
105 {
Res_png_9patchRes_png_9patch106     Res_png_9patch() : wasDeserialized(false), xDivs(NULL),
107                        yDivs(NULL), colors(NULL) { }
108 
109     int8_t wasDeserialized;
110     int8_t numXDivs;
111     int8_t numYDivs;
112     int8_t numColors;
113 
114     // These tell where the next section of a patch starts.
115     // For example, the first patch includes the pixels from
116     // 0 to xDivs[0]-1 and the second patch includes the pixels
117     // from xDivs[0] to xDivs[1]-1.
118     // Note: allocation/free of these pointers is left to the caller.
119     int32_t* xDivs;
120     int32_t* yDivs;
121 
122     int32_t paddingLeft, paddingRight;
123     int32_t paddingTop, paddingBottom;
124 
125     enum {
126         // The 9 patch segment is not a solid color.
127         NO_COLOR = 0x00000001,
128 
129         // The 9 patch segment is completely transparent.
130         TRANSPARENT_COLOR = 0x00000000
131     };
132     // Note: allocation/free of this pointer is left to the caller.
133     uint32_t* colors;
134 
135     // Convert data from device representation to PNG file representation.
136     void deviceToFile();
137     // Convert data from PNG file representation to device representation.
138     void fileToDevice();
139     // Serialize/Marshall the patch data into a newly malloc-ed block
140     void* serialize();
141     // Serialize/Marshall the patch data
142     void serialize(void* outData);
143     // Deserialize/Unmarshall the patch data
144     static Res_png_9patch* deserialize(const void* data);
145     // Compute the size of the serialized data structure
146     size_t serializedSize();
147 };
148 
149 /** ********************************************************************
150  *  Base Types
151  *
152  *  These are standard types that are shared between multiple specific
153  *  resource types.
154  *
155  *********************************************************************** */
156 
157 /**
158  * Header that appears at the front of every data chunk in a resource.
159  */
160 struct ResChunk_header
161 {
162     // Type identifier for this chunk.  The meaning of this value depends
163     // on the containing chunk.
164     uint16_t type;
165 
166     // Size of the chunk header (in bytes).  Adding this value to
167     // the address of the chunk allows you to find its associated data
168     // (if any).
169     uint16_t headerSize;
170 
171     // Total size of this chunk (in bytes).  This is the chunkSize plus
172     // the size of any data associated with the chunk.  Adding this value
173     // to the chunk allows you to completely skip its contents (including
174     // any child chunks).  If this value is the same as chunkSize, there is
175     // no data associated with the chunk.
176     uint32_t size;
177 };
178 
179 enum {
180     RES_NULL_TYPE               = 0x0000,
181     RES_STRING_POOL_TYPE        = 0x0001,
182     RES_TABLE_TYPE              = 0x0002,
183     RES_XML_TYPE                = 0x0003,
184 
185     // Chunk types in RES_XML_TYPE
186     RES_XML_FIRST_CHUNK_TYPE    = 0x0100,
187     RES_XML_START_NAMESPACE_TYPE= 0x0100,
188     RES_XML_END_NAMESPACE_TYPE  = 0x0101,
189     RES_XML_START_ELEMENT_TYPE  = 0x0102,
190     RES_XML_END_ELEMENT_TYPE    = 0x0103,
191     RES_XML_CDATA_TYPE          = 0x0104,
192     RES_XML_LAST_CHUNK_TYPE     = 0x017f,
193     // This contains a uint32_t array mapping strings in the string
194     // pool back to resource identifiers.  It is optional.
195     RES_XML_RESOURCE_MAP_TYPE   = 0x0180,
196 
197     // Chunk types in RES_TABLE_TYPE
198     RES_TABLE_PACKAGE_TYPE      = 0x0200,
199     RES_TABLE_TYPE_TYPE         = 0x0201,
200     RES_TABLE_TYPE_SPEC_TYPE    = 0x0202
201 };
202 
203 /**
204  * Macros for building/splitting resource identifiers.
205  */
206 #define Res_VALIDID(resid) (resid != 0)
207 #define Res_CHECKID(resid) ((resid&0xFFFF0000) != 0)
208 #define Res_MAKEID(package, type, entry) \
209     (((package+1)<<24) | (((type+1)&0xFF)<<16) | (entry&0xFFFF))
210 #define Res_GETPACKAGE(id) ((id>>24)-1)
211 #define Res_GETTYPE(id) (((id>>16)&0xFF)-1)
212 #define Res_GETENTRY(id) (id&0xFFFF)
213 
214 #define Res_INTERNALID(resid) ((resid&0xFFFF0000) != 0 && (resid&0xFF0000) == 0)
215 #define Res_MAKEINTERNAL(entry) (0x01000000 | (entry&0xFFFF))
216 #define Res_MAKEARRAY(entry) (0x02000000 | (entry&0xFFFF))
217 
218 #define Res_MAXPACKAGE 255
219 
220 /**
221  * Representation of a value in a resource, supplying type
222  * information.
223  */
224 struct Res_value
225 {
226     // Number of bytes in this structure.
227     uint16_t size;
228 
229     // Always set to 0.
230     uint8_t res0;
231 
232     // Type of the data value.
233     enum {
234         // Contains no data.
235         TYPE_NULL = 0x00,
236         // The 'data' holds a ResTable_ref, a reference to another resource
237         // table entry.
238         TYPE_REFERENCE = 0x01,
239         // The 'data' holds an attribute resource identifier.
240         TYPE_ATTRIBUTE = 0x02,
241         // The 'data' holds an index into the containing resource table's
242         // global value string pool.
243         TYPE_STRING = 0x03,
244         // The 'data' holds a single-precision floating point number.
245         TYPE_FLOAT = 0x04,
246         // The 'data' holds a complex number encoding a dimension value,
247         // such as "100in".
248         TYPE_DIMENSION = 0x05,
249         // The 'data' holds a complex number encoding a fraction of a
250         // container.
251         TYPE_FRACTION = 0x06,
252 
253         // Beginning of integer flavors...
254         TYPE_FIRST_INT = 0x10,
255 
256         // The 'data' is a raw integer value of the form n..n.
257         TYPE_INT_DEC = 0x10,
258         // The 'data' is a raw integer value of the form 0xn..n.
259         TYPE_INT_HEX = 0x11,
260         // The 'data' is either 0 or 1, for input "false" or "true" respectively.
261         TYPE_INT_BOOLEAN = 0x12,
262 
263         // Beginning of color integer flavors...
264         TYPE_FIRST_COLOR_INT = 0x1c,
265 
266         // The 'data' is a raw integer value of the form #aarrggbb.
267         TYPE_INT_COLOR_ARGB8 = 0x1c,
268         // The 'data' is a raw integer value of the form #rrggbb.
269         TYPE_INT_COLOR_RGB8 = 0x1d,
270         // The 'data' is a raw integer value of the form #argb.
271         TYPE_INT_COLOR_ARGB4 = 0x1e,
272         // The 'data' is a raw integer value of the form #rgb.
273         TYPE_INT_COLOR_RGB4 = 0x1f,
274 
275         // ...end of integer flavors.
276         TYPE_LAST_COLOR_INT = 0x1f,
277 
278         // ...end of integer flavors.
279         TYPE_LAST_INT = 0x1f
280     };
281     uint8_t dataType;
282 
283     // Structure of complex data values (TYPE_UNIT and TYPE_FRACTION)
284     enum {
285         // Where the unit type information is.  This gives us 16 possible
286         // types, as defined below.
287         COMPLEX_UNIT_SHIFT = 0,
288         COMPLEX_UNIT_MASK = 0xf,
289 
290         // TYPE_DIMENSION: Value is raw pixels.
291         COMPLEX_UNIT_PX = 0,
292         // TYPE_DIMENSION: Value is Device Independent Pixels.
293         COMPLEX_UNIT_DIP = 1,
294         // TYPE_DIMENSION: Value is a Scaled device independent Pixels.
295         COMPLEX_UNIT_SP = 2,
296         // TYPE_DIMENSION: Value is in points.
297         COMPLEX_UNIT_PT = 3,
298         // TYPE_DIMENSION: Value is in inches.
299         COMPLEX_UNIT_IN = 4,
300         // TYPE_DIMENSION: Value is in millimeters.
301         COMPLEX_UNIT_MM = 5,
302 
303         // TYPE_FRACTION: A basic fraction of the overall size.
304         COMPLEX_UNIT_FRACTION = 0,
305         // TYPE_FRACTION: A fraction of the parent size.
306         COMPLEX_UNIT_FRACTION_PARENT = 1,
307 
308         // Where the radix information is, telling where the decimal place
309         // appears in the mantissa.  This give us 4 possible fixed point
310         // representations as defined below.
311         COMPLEX_RADIX_SHIFT = 4,
312         COMPLEX_RADIX_MASK = 0x3,
313 
314         // The mantissa is an integral number -- i.e., 0xnnnnnn.0
315         COMPLEX_RADIX_23p0 = 0,
316         // The mantissa magnitude is 16 bits -- i.e, 0xnnnn.nn
317         COMPLEX_RADIX_16p7 = 1,
318         // The mantissa magnitude is 8 bits -- i.e, 0xnn.nnnn
319         COMPLEX_RADIX_8p15 = 2,
320         // The mantissa magnitude is 0 bits -- i.e, 0x0.nnnnnn
321         COMPLEX_RADIX_0p23 = 3,
322 
323         // Where the actual value is.  This gives us 23 bits of
324         // precision.  The top bit is the sign.
325         COMPLEX_MANTISSA_SHIFT = 8,
326         COMPLEX_MANTISSA_MASK = 0xffffff
327     };
328 
329     // The data for this item, as interpreted according to dataType.
330     uint32_t data;
331 
332     void copyFrom_dtoh(const Res_value& src);
333 };
334 
335 /**
336  *  This is a reference to a unique entry (a ResTable_entry structure)
337  *  in a resource table.  The value is structured as: 0xpptteeee,
338  *  where pp is the package index, tt is the type index in that
339  *  package, and eeee is the entry index in that type.  The package
340  *  and type values start at 1 for the first item, to help catch cases
341  *  where they have not been supplied.
342  */
343 struct ResTable_ref
344 {
345     uint32_t ident;
346 };
347 
348 /**
349  * Reference to a string in a string pool.
350  */
351 struct ResStringPool_ref
352 {
353     // Index into the string pool table (uint32_t-offset from the indices
354     // immediately after ResStringPool_header) at which to find the location
355     // of the string data in the pool.
356     uint32_t index;
357 };
358 
359 /** ********************************************************************
360  *  String Pool
361  *
362  *  A set of strings that can be references by others through a
363  *  ResStringPool_ref.
364  *
365  *********************************************************************** */
366 
367 /**
368  * Definition for a pool of strings.  The data of this chunk is an
369  * array of uint32_t providing indices into the pool, relative to
370  * stringsStart.  At stringsStart are all of the UTF-16 strings
371  * concatenated together; each starts with a uint16_t of the string's
372  * length and each ends with a 0x0000 terminator.  If a string is >
373  * 32767 characters, the high bit of the length is set meaning to take
374  * those 15 bits as a high word and it will be followed by another
375  * uint16_t containing the low word.
376  *
377  * If styleCount is not zero, then immediately following the array of
378  * uint32_t indices into the string table is another array of indices
379  * into a style table starting at stylesStart.  Each entry in the
380  * style table is an array of ResStringPool_span structures.
381  */
382 struct ResStringPool_header
383 {
384     struct ResChunk_header header;
385 
386     // Number of strings in this pool (number of uint32_t indices that follow
387     // in the data).
388     uint32_t stringCount;
389 
390     // Number of style span arrays in the pool (number of uint32_t indices
391     // follow the string indices).
392     uint32_t styleCount;
393 
394     // Flags.
395     enum {
396         // If set, the string index is sorted by the string values (based
397         // on strcmp16()).
398         SORTED_FLAG = 1<<0,
399 
400         // String pool is encoded in UTF-8
401         UTF8_FLAG = 1<<8
402     };
403     uint32_t flags;
404 
405     // Index from header of the string data.
406     uint32_t stringsStart;
407 
408     // Index from header of the style data.
409     uint32_t stylesStart;
410 };
411 
412 /**
413  * This structure defines a span of style information associated with
414  * a string in the pool.
415  */
416 struct ResStringPool_span
417 {
418     enum {
419         END = 0xFFFFFFFF
420     };
421 
422     // This is the name of the span -- that is, the name of the XML
423     // tag that defined it.  The special value END (0xFFFFFFFF) indicates
424     // the end of an array of spans.
425     ResStringPool_ref name;
426 
427     // The range of characters in the string that this span applies to.
428     uint32_t firstChar, lastChar;
429 };
430 
431 /**
432  * Convenience class for accessing data in a ResStringPool resource.
433  */
434 class ResStringPool
435 {
436 public:
437     ResStringPool();
438     ResStringPool(const void* data, size_t size, bool copyData=false);
439     ~ResStringPool();
440 
441     status_t setTo(const void* data, size_t size, bool copyData=false);
442 
443     status_t getError() const;
444 
445     void uninit();
446 
447     // Return string entry as UTF16; if the pool is UTF8, the string will
448     // be converted before returning.
stringAt(const ResStringPool_ref & ref,size_t * outLen)449     inline const char16_t* stringAt(const ResStringPool_ref& ref, size_t* outLen) const {
450         return stringAt(ref.index, outLen);
451     }
452     const char16_t* stringAt(size_t idx, size_t* outLen) const;
453 
454     // Note: returns null if the string pool is not UTF8.
455     const char* string8At(size_t idx, size_t* outLen) const;
456 
457     // Return string whether the pool is UTF8 or UTF16.  Does not allow you
458     // to distinguish null.
459     const String8 string8ObjectAt(size_t idx) const;
460 
461     const ResStringPool_span* styleAt(const ResStringPool_ref& ref) const;
462     const ResStringPool_span* styleAt(size_t idx) const;
463 
464     ssize_t indexOfString(const char16_t* str, size_t strLen) const;
465 
466     size_t size() const;
467     size_t styleCount() const;
468     size_t bytes() const;
469 
470     bool isSorted() const;
471     bool isUTF8() const;
472 
473 private:
474     status_t                    mError;
475     void*                       mOwnedData;
476     const ResStringPool_header* mHeader;
477     size_t                      mSize;
478     mutable Mutex               mDecodeLock;
479     const uint32_t*             mEntries;
480     const uint32_t*             mEntryStyles;
481     const void*                 mStrings;
482     char16_t**                  mCache;
483     uint32_t                    mStringPoolSize;    // number of uint16_t
484     const uint32_t*             mStyles;
485     uint32_t                    mStylePoolSize;    // number of uint32_t
486 };
487 
488 /** ********************************************************************
489  *  XML Tree
490  *
491  *  Binary representation of an XML document.  This is designed to
492  *  express everything in an XML document, in a form that is much
493  *  easier to parse on the device.
494  *
495  *********************************************************************** */
496 
497 /**
498  * XML tree header.  This appears at the front of an XML tree,
499  * describing its content.  It is followed by a flat array of
500  * ResXMLTree_node structures; the hierarchy of the XML document
501  * is described by the occurrance of RES_XML_START_ELEMENT_TYPE
502  * and corresponding RES_XML_END_ELEMENT_TYPE nodes in the array.
503  */
504 struct ResXMLTree_header
505 {
506     struct ResChunk_header header;
507 };
508 
509 /**
510  * Basic XML tree node.  A single item in the XML document.  Extended info
511  * about the node can be found after header.headerSize.
512  */
513 struct ResXMLTree_node
514 {
515     struct ResChunk_header header;
516 
517     // Line number in original source file at which this element appeared.
518     uint32_t lineNumber;
519 
520     // Optional XML comment that was associated with this element; -1 if none.
521     struct ResStringPool_ref comment;
522 };
523 
524 /**
525  * Extended XML tree node for CDATA tags -- includes the CDATA string.
526  * Appears header.headerSize bytes after a ResXMLTree_node.
527  */
528 struct ResXMLTree_cdataExt
529 {
530     // The raw CDATA character data.
531     struct ResStringPool_ref data;
532 
533     // The typed value of the character data if this is a CDATA node.
534     struct Res_value typedData;
535 };
536 
537 /**
538  * Extended XML tree node for namespace start/end nodes.
539  * Appears header.headerSize bytes after a ResXMLTree_node.
540  */
541 struct ResXMLTree_namespaceExt
542 {
543     // The prefix of the namespace.
544     struct ResStringPool_ref prefix;
545 
546     // The URI of the namespace.
547     struct ResStringPool_ref uri;
548 };
549 
550 /**
551  * Extended XML tree node for element start/end nodes.
552  * Appears header.headerSize bytes after a ResXMLTree_node.
553  */
554 struct ResXMLTree_endElementExt
555 {
556     // String of the full namespace of this element.
557     struct ResStringPool_ref ns;
558 
559     // String name of this node if it is an ELEMENT; the raw
560     // character data if this is a CDATA node.
561     struct ResStringPool_ref name;
562 };
563 
564 /**
565  * Extended XML tree node for start tags -- includes attribute
566  * information.
567  * Appears header.headerSize bytes after a ResXMLTree_node.
568  */
569 struct ResXMLTree_attrExt
570 {
571     // String of the full namespace of this element.
572     struct ResStringPool_ref ns;
573 
574     // String name of this node if it is an ELEMENT; the raw
575     // character data if this is a CDATA node.
576     struct ResStringPool_ref name;
577 
578     // Byte offset from the start of this structure where the attributes start.
579     uint16_t attributeStart;
580 
581     // Size of the ResXMLTree_attribute structures that follow.
582     uint16_t attributeSize;
583 
584     // Number of attributes associated with an ELEMENT.  These are
585     // available as an array of ResXMLTree_attribute structures
586     // immediately following this node.
587     uint16_t attributeCount;
588 
589     // Index (1-based) of the "id" attribute. 0 if none.
590     uint16_t idIndex;
591 
592     // Index (1-based) of the "class" attribute. 0 if none.
593     uint16_t classIndex;
594 
595     // Index (1-based) of the "style" attribute. 0 if none.
596     uint16_t styleIndex;
597 };
598 
599 struct ResXMLTree_attribute
600 {
601     // Namespace of this attribute.
602     struct ResStringPool_ref ns;
603 
604     // Name of this attribute.
605     struct ResStringPool_ref name;
606 
607     // The original raw string value of this attribute.
608     struct ResStringPool_ref rawValue;
609 
610     // Processesd typed value of this attribute.
611     struct Res_value typedValue;
612 };
613 
614 class ResXMLTree;
615 
616 class ResXMLParser
617 {
618 public:
619     ResXMLParser(const ResXMLTree& tree);
620 
621     enum event_code_t {
622         BAD_DOCUMENT = -1,
623         START_DOCUMENT = 0,
624         END_DOCUMENT = 1,
625 
626         FIRST_CHUNK_CODE = RES_XML_FIRST_CHUNK_TYPE,
627 
628         START_NAMESPACE = RES_XML_START_NAMESPACE_TYPE,
629         END_NAMESPACE = RES_XML_END_NAMESPACE_TYPE,
630         START_TAG = RES_XML_START_ELEMENT_TYPE,
631         END_TAG = RES_XML_END_ELEMENT_TYPE,
632         TEXT = RES_XML_CDATA_TYPE
633     };
634 
635     struct ResXMLPosition
636     {
637         event_code_t                eventCode;
638         const ResXMLTree_node*      curNode;
639         const void*                 curExt;
640     };
641 
642     void restart();
643 
644     const ResStringPool& getStrings() const;
645 
646     event_code_t getEventType() const;
647     // Note, unlike XmlPullParser, the first call to next() will return
648     // START_TAG of the first element.
649     event_code_t next();
650 
651     // These are available for all nodes:
652     int32_t getCommentID() const;
653     const uint16_t* getComment(size_t* outLen) const;
654     uint32_t getLineNumber() const;
655 
656     // This is available for TEXT:
657     int32_t getTextID() const;
658     const uint16_t* getText(size_t* outLen) const;
659     ssize_t getTextValue(Res_value* outValue) const;
660 
661     // These are available for START_NAMESPACE and END_NAMESPACE:
662     int32_t getNamespacePrefixID() const;
663     const uint16_t* getNamespacePrefix(size_t* outLen) const;
664     int32_t getNamespaceUriID() const;
665     const uint16_t* getNamespaceUri(size_t* outLen) const;
666 
667     // These are available for START_TAG and END_TAG:
668     int32_t getElementNamespaceID() const;
669     const uint16_t* getElementNamespace(size_t* outLen) const;
670     int32_t getElementNameID() const;
671     const uint16_t* getElementName(size_t* outLen) const;
672 
673     // Remaining methods are for retrieving information about attributes
674     // associated with a START_TAG:
675 
676     size_t getAttributeCount() const;
677 
678     // Returns -1 if no namespace, -2 if idx out of range.
679     int32_t getAttributeNamespaceID(size_t idx) const;
680     const uint16_t* getAttributeNamespace(size_t idx, size_t* outLen) const;
681 
682     int32_t getAttributeNameID(size_t idx) const;
683     const uint16_t* getAttributeName(size_t idx, size_t* outLen) const;
684     uint32_t getAttributeNameResID(size_t idx) const;
685 
686     int32_t getAttributeValueStringID(size_t idx) const;
687     const uint16_t* getAttributeStringValue(size_t idx, size_t* outLen) const;
688 
689     int32_t getAttributeDataType(size_t idx) const;
690     int32_t getAttributeData(size_t idx) const;
691     ssize_t getAttributeValue(size_t idx, Res_value* outValue) const;
692 
693     ssize_t indexOfAttribute(const char* ns, const char* attr) const;
694     ssize_t indexOfAttribute(const char16_t* ns, size_t nsLen,
695                              const char16_t* attr, size_t attrLen) const;
696 
697     ssize_t indexOfID() const;
698     ssize_t indexOfClass() const;
699     ssize_t indexOfStyle() const;
700 
701     void getPosition(ResXMLPosition* pos) const;
702     void setPosition(const ResXMLPosition& pos);
703 
704 private:
705     friend class ResXMLTree;
706 
707     event_code_t nextNode();
708 
709     const ResXMLTree&           mTree;
710     event_code_t                mEventCode;
711     const ResXMLTree_node*      mCurNode;
712     const void*                 mCurExt;
713 };
714 
715 /**
716  * Convenience class for accessing data in a ResXMLTree resource.
717  */
718 class ResXMLTree : public ResXMLParser
719 {
720 public:
721     ResXMLTree();
722     ResXMLTree(const void* data, size_t size, bool copyData=false);
723     ~ResXMLTree();
724 
725     status_t setTo(const void* data, size_t size, bool copyData=false);
726 
727     status_t getError() const;
728 
729     void uninit();
730 
731 private:
732     friend class ResXMLParser;
733 
734     status_t validateNode(const ResXMLTree_node* node) const;
735 
736     status_t                    mError;
737     void*                       mOwnedData;
738     const ResXMLTree_header*    mHeader;
739     size_t                      mSize;
740     const uint8_t*              mDataEnd;
741     ResStringPool               mStrings;
742     const uint32_t*             mResIds;
743     size_t                      mNumResIds;
744     const ResXMLTree_node*      mRootNode;
745     const void*                 mRootExt;
746     event_code_t                mRootCode;
747 };
748 
749 /** ********************************************************************
750  *  RESOURCE TABLE
751  *
752  *********************************************************************** */
753 
754 /**
755  * Header for a resource table.  Its data contains a series of
756  * additional chunks:
757  *   * A ResStringPool_header containing all table values.  This string pool
758  *     contains all of the string values in the entire resource table (not
759  *     the names of entries or type identifiers however).
760  *   * One or more ResTable_package chunks.
761  *
762  * Specific entries within a resource table can be uniquely identified
763  * with a single integer as defined by the ResTable_ref structure.
764  */
765 struct ResTable_header
766 {
767     struct ResChunk_header header;
768 
769     // The number of ResTable_package structures.
770     uint32_t packageCount;
771 };
772 
773 /**
774  * A collection of resource data types within a package.  Followed by
775  * one or more ResTable_type and ResTable_typeSpec structures containing the
776  * entry values for each resource type.
777  */
778 struct ResTable_package
779 {
780     struct ResChunk_header header;
781 
782     // If this is a base package, its ID.  Package IDs start
783     // at 1 (corresponding to the value of the package bits in a
784     // resource identifier).  0 means this is not a base package.
785     uint32_t id;
786 
787     // Actual name of this package, \0-terminated.
788     char16_t name[128];
789 
790     // Offset to a ResStringPool_header defining the resource
791     // type symbol table.  If zero, this package is inheriting from
792     // another base package (overriding specific values in it).
793     uint32_t typeStrings;
794 
795     // Last index into typeStrings that is for public use by others.
796     uint32_t lastPublicType;
797 
798     // Offset to a ResStringPool_header defining the resource
799     // key symbol table.  If zero, this package is inheriting from
800     // another base package (overriding specific values in it).
801     uint32_t keyStrings;
802 
803     // Last index into keyStrings that is for public use by others.
804     uint32_t lastPublicKey;
805 };
806 
807 /**
808  * Describes a particular resource configuration.
809  */
810 struct ResTable_config
811 {
812     // Number of bytes in this structure.
813     uint32_t size;
814 
815     union {
816         struct {
817             // Mobile country code (from SIM).  0 means "any".
818             uint16_t mcc;
819             // Mobile network code (from SIM).  0 means "any".
820             uint16_t mnc;
821         };
822         uint32_t imsi;
823     };
824 
825     union {
826         struct {
827             // \0\0 means "any".  Otherwise, en, fr, etc.
828             char language[2];
829 
830             // \0\0 means "any".  Otherwise, US, CA, etc.
831             char country[2];
832         };
833         uint32_t locale;
834     };
835 
836     enum {
837         ORIENTATION_ANY  = ACONFIGURATION_ORIENTATION_ANY,
838         ORIENTATION_PORT = ACONFIGURATION_ORIENTATION_PORT,
839         ORIENTATION_LAND = ACONFIGURATION_ORIENTATION_LAND,
840         ORIENTATION_SQUARE = ACONFIGURATION_ORIENTATION_SQUARE,
841     };
842 
843     enum {
844         TOUCHSCREEN_ANY  = ACONFIGURATION_TOUCHSCREEN_ANY,
845         TOUCHSCREEN_NOTOUCH  = ACONFIGURATION_TOUCHSCREEN_NOTOUCH,
846         TOUCHSCREEN_STYLUS  = ACONFIGURATION_TOUCHSCREEN_STYLUS,
847         TOUCHSCREEN_FINGER  = ACONFIGURATION_TOUCHSCREEN_FINGER,
848     };
849 
850     enum {
851         DENSITY_DEFAULT = ACONFIGURATION_DENSITY_DEFAULT,
852         DENSITY_LOW = ACONFIGURATION_DENSITY_LOW,
853         DENSITY_MEDIUM = ACONFIGURATION_DENSITY_MEDIUM,
854         DENSITY_TV = ACONFIGURATION_DENSITY_TV,
855         DENSITY_HIGH = ACONFIGURATION_DENSITY_HIGH,
856         DENSITY_XHIGH = ACONFIGURATION_DENSITY_XHIGH,
857         DENSITY_XXHIGH = ACONFIGURATION_DENSITY_XXHIGH,
858         DENSITY_XXXHIGH = ACONFIGURATION_DENSITY_XXXHIGH,
859         DENSITY_NONE = ACONFIGURATION_DENSITY_NONE
860     };
861 
862     union {
863         struct {
864             uint8_t orientation;
865             uint8_t touchscreen;
866             uint16_t density;
867         };
868         uint32_t screenType;
869     };
870 
871     enum {
872         KEYBOARD_ANY  = ACONFIGURATION_KEYBOARD_ANY,
873         KEYBOARD_NOKEYS  = ACONFIGURATION_KEYBOARD_NOKEYS,
874         KEYBOARD_QWERTY  = ACONFIGURATION_KEYBOARD_QWERTY,
875         KEYBOARD_12KEY  = ACONFIGURATION_KEYBOARD_12KEY,
876     };
877 
878     enum {
879         NAVIGATION_ANY  = ACONFIGURATION_NAVIGATION_ANY,
880         NAVIGATION_NONAV  = ACONFIGURATION_NAVIGATION_NONAV,
881         NAVIGATION_DPAD  = ACONFIGURATION_NAVIGATION_DPAD,
882         NAVIGATION_TRACKBALL  = ACONFIGURATION_NAVIGATION_TRACKBALL,
883         NAVIGATION_WHEEL  = ACONFIGURATION_NAVIGATION_WHEEL,
884     };
885 
886     enum {
887         MASK_KEYSHIDDEN = 0x0003,
888         KEYSHIDDEN_ANY = ACONFIGURATION_KEYSHIDDEN_ANY,
889         KEYSHIDDEN_NO = ACONFIGURATION_KEYSHIDDEN_NO,
890         KEYSHIDDEN_YES = ACONFIGURATION_KEYSHIDDEN_YES,
891         KEYSHIDDEN_SOFT = ACONFIGURATION_KEYSHIDDEN_SOFT,
892     };
893 
894     enum {
895         MASK_NAVHIDDEN = 0x000c,
896         SHIFT_NAVHIDDEN = 2,
897         NAVHIDDEN_ANY = ACONFIGURATION_NAVHIDDEN_ANY << SHIFT_NAVHIDDEN,
898         NAVHIDDEN_NO = ACONFIGURATION_NAVHIDDEN_NO << SHIFT_NAVHIDDEN,
899         NAVHIDDEN_YES = ACONFIGURATION_NAVHIDDEN_YES << SHIFT_NAVHIDDEN,
900     };
901 
902     union {
903         struct {
904             uint8_t keyboard;
905             uint8_t navigation;
906             uint8_t inputFlags;
907             uint8_t inputPad0;
908         };
909         uint32_t input;
910     };
911 
912     enum {
913         SCREENWIDTH_ANY = 0
914     };
915 
916     enum {
917         SCREENHEIGHT_ANY = 0
918     };
919 
920     union {
921         struct {
922             uint16_t screenWidth;
923             uint16_t screenHeight;
924         };
925         uint32_t screenSize;
926     };
927 
928     enum {
929         SDKVERSION_ANY = 0
930     };
931 
932     enum {
933         MINORVERSION_ANY = 0
934     };
935 
936     union {
937         struct {
938             uint16_t sdkVersion;
939             // For now minorVersion must always be 0!!!  Its meaning
940             // is currently undefined.
941             uint16_t minorVersion;
942         };
943         uint32_t version;
944     };
945 
946     enum {
947         // screenLayout bits for screen size class.
948         MASK_SCREENSIZE = 0x0f,
949         SCREENSIZE_ANY = ACONFIGURATION_SCREENSIZE_ANY,
950         SCREENSIZE_SMALL = ACONFIGURATION_SCREENSIZE_SMALL,
951         SCREENSIZE_NORMAL = ACONFIGURATION_SCREENSIZE_NORMAL,
952         SCREENSIZE_LARGE = ACONFIGURATION_SCREENSIZE_LARGE,
953         SCREENSIZE_XLARGE = ACONFIGURATION_SCREENSIZE_XLARGE,
954 
955         // screenLayout bits for wide/long screen variation.
956         MASK_SCREENLONG = 0x30,
957         SHIFT_SCREENLONG = 4,
958         SCREENLONG_ANY = ACONFIGURATION_SCREENLONG_ANY << SHIFT_SCREENLONG,
959         SCREENLONG_NO = ACONFIGURATION_SCREENLONG_NO << SHIFT_SCREENLONG,
960         SCREENLONG_YES = ACONFIGURATION_SCREENLONG_YES << SHIFT_SCREENLONG,
961 
962         // screenLayout bits for layout direction.
963         MASK_LAYOUTDIR = 0xC0,
964         SHIFT_LAYOUTDIR = 6,
965         LAYOUTDIR_ANY = ACONFIGURATION_LAYOUTDIR_ANY << SHIFT_LAYOUTDIR,
966         LAYOUTDIR_LTR = ACONFIGURATION_LAYOUTDIR_LTR << SHIFT_LAYOUTDIR,
967         LAYOUTDIR_RTL = ACONFIGURATION_LAYOUTDIR_RTL << SHIFT_LAYOUTDIR,
968     };
969 
970     enum {
971         // uiMode bits for the mode type.
972         MASK_UI_MODE_TYPE = 0x0f,
973         UI_MODE_TYPE_ANY = ACONFIGURATION_UI_MODE_TYPE_ANY,
974         UI_MODE_TYPE_NORMAL = ACONFIGURATION_UI_MODE_TYPE_NORMAL,
975         UI_MODE_TYPE_DESK = ACONFIGURATION_UI_MODE_TYPE_DESK,
976         UI_MODE_TYPE_CAR = ACONFIGURATION_UI_MODE_TYPE_CAR,
977         UI_MODE_TYPE_TELEVISION = ACONFIGURATION_UI_MODE_TYPE_TELEVISION,
978         UI_MODE_TYPE_APPLIANCE = ACONFIGURATION_UI_MODE_TYPE_APPLIANCE,
979 
980         // uiMode bits for the night switch.
981         MASK_UI_MODE_NIGHT = 0x30,
982         SHIFT_UI_MODE_NIGHT = 4,
983         UI_MODE_NIGHT_ANY = ACONFIGURATION_UI_MODE_NIGHT_ANY << SHIFT_UI_MODE_NIGHT,
984         UI_MODE_NIGHT_NO = ACONFIGURATION_UI_MODE_NIGHT_NO << SHIFT_UI_MODE_NIGHT,
985         UI_MODE_NIGHT_YES = ACONFIGURATION_UI_MODE_NIGHT_YES << SHIFT_UI_MODE_NIGHT,
986     };
987 
988     union {
989         struct {
990             uint8_t screenLayout;
991             uint8_t uiMode;
992             uint16_t smallestScreenWidthDp;
993         };
994         uint32_t screenConfig;
995     };
996 
997     union {
998         struct {
999             uint16_t screenWidthDp;
1000             uint16_t screenHeightDp;
1001         };
1002         uint32_t screenSizeDp;
1003     };
1004 
1005     void copyFromDeviceNoSwap(const ResTable_config& o);
1006 
1007     void copyFromDtoH(const ResTable_config& o);
1008 
1009     void swapHtoD();
1010 
1011     int compare(const ResTable_config& o) const;
1012     int compareLogical(const ResTable_config& o) const;
1013 
1014     // Flags indicating a set of config values.  These flag constants must
1015     // match the corresponding ones in android.content.pm.ActivityInfo and
1016     // attrs_manifest.xml.
1017     enum {
1018         CONFIG_MCC = ACONFIGURATION_MCC,
1019         CONFIG_MNC = ACONFIGURATION_MCC,
1020         CONFIG_LOCALE = ACONFIGURATION_LOCALE,
1021         CONFIG_TOUCHSCREEN = ACONFIGURATION_TOUCHSCREEN,
1022         CONFIG_KEYBOARD = ACONFIGURATION_KEYBOARD,
1023         CONFIG_KEYBOARD_HIDDEN = ACONFIGURATION_KEYBOARD_HIDDEN,
1024         CONFIG_NAVIGATION = ACONFIGURATION_NAVIGATION,
1025         CONFIG_ORIENTATION = ACONFIGURATION_ORIENTATION,
1026         CONFIG_DENSITY = ACONFIGURATION_DENSITY,
1027         CONFIG_SCREEN_SIZE = ACONFIGURATION_SCREEN_SIZE,
1028         CONFIG_SMALLEST_SCREEN_SIZE = ACONFIGURATION_SMALLEST_SCREEN_SIZE,
1029         CONFIG_VERSION = ACONFIGURATION_VERSION,
1030         CONFIG_SCREEN_LAYOUT = ACONFIGURATION_SCREEN_LAYOUT,
1031         CONFIG_UI_MODE = ACONFIGURATION_UI_MODE,
1032         CONFIG_LAYOUTDIR = ACONFIGURATION_LAYOUTDIR,
1033     };
1034 
1035     // Compare two configuration, returning CONFIG_* flags set for each value
1036     // that is different.
1037     int diff(const ResTable_config& o) const;
1038 
1039     // Return true if 'this' is more specific than 'o'.
1040     bool isMoreSpecificThan(const ResTable_config& o) const;
1041 
1042     // Return true if 'this' is a better match than 'o' for the 'requested'
1043     // configuration.  This assumes that match() has already been used to
1044     // remove any configurations that don't match the requested configuration
1045     // at all; if they are not first filtered, non-matching results can be
1046     // considered better than matching ones.
1047     // The general rule per attribute: if the request cares about an attribute
1048     // (it normally does), if the two (this and o) are equal it's a tie.  If
1049     // they are not equal then one must be generic because only generic and
1050     // '==requested' will pass the match() call.  So if this is not generic,
1051     // it wins.  If this IS generic, o wins (return false).
1052     bool isBetterThan(const ResTable_config& o, const ResTable_config* requested) const;
1053 
1054     // Return true if 'this' can be considered a match for the parameters in
1055     // 'settings'.
1056     // Note this is asymetric.  A default piece of data will match every request
1057     // but a request for the default should not match odd specifics
1058     // (ie, request with no mcc should not match a particular mcc's data)
1059     // settings is the requested settings
1060     bool match(const ResTable_config& settings) const;
1061 
1062     void getLocale(char str[6]) const;
1063 
1064     String8 toString() const;
1065 };
1066 
1067 /**
1068  * A specification of the resources defined by a particular type.
1069  *
1070  * There should be one of these chunks for each resource type.
1071  *
1072  * This structure is followed by an array of integers providing the set of
1073  * configuration change flags (ResTable_config::CONFIG_*) that have multiple
1074  * resources for that configuration.  In addition, the high bit is set if that
1075  * resource has been made public.
1076  */
1077 struct ResTable_typeSpec
1078 {
1079     struct ResChunk_header header;
1080 
1081     // The type identifier this chunk is holding.  Type IDs start
1082     // at 1 (corresponding to the value of the type bits in a
1083     // resource identifier).  0 is invalid.
1084     uint8_t id;
1085 
1086     // Must be 0.
1087     uint8_t res0;
1088     // Must be 0.
1089     uint16_t res1;
1090 
1091     // Number of uint32_t entry configuration masks that follow.
1092     uint32_t entryCount;
1093 
1094     enum {
1095         // Additional flag indicating an entry is public.
1096         SPEC_PUBLIC = 0x40000000
1097     };
1098 };
1099 
1100 /**
1101  * A collection of resource entries for a particular resource data
1102  * type. Followed by an array of uint32_t defining the resource
1103  * values, corresponding to the array of type strings in the
1104  * ResTable_package::typeStrings string block. Each of these hold an
1105  * index from entriesStart; a value of NO_ENTRY means that entry is
1106  * not defined.
1107  *
1108  * There may be multiple of these chunks for a particular resource type,
1109  * supply different configuration variations for the resource values of
1110  * that type.
1111  *
1112  * It would be nice to have an additional ordered index of entries, so
1113  * we can do a binary search if trying to find a resource by string name.
1114  */
1115 struct ResTable_type
1116 {
1117     struct ResChunk_header header;
1118 
1119     enum {
1120         NO_ENTRY = 0xFFFFFFFF
1121     };
1122 
1123     // The type identifier this chunk is holding.  Type IDs start
1124     // at 1 (corresponding to the value of the type bits in a
1125     // resource identifier).  0 is invalid.
1126     uint8_t id;
1127 
1128     // Must be 0.
1129     uint8_t res0;
1130     // Must be 0.
1131     uint16_t res1;
1132 
1133     // Number of uint32_t entry indices that follow.
1134     uint32_t entryCount;
1135 
1136     // Offset from header where ResTable_entry data starts.
1137     uint32_t entriesStart;
1138 
1139     // Configuration this collection of entries is designed for.
1140     ResTable_config config;
1141 };
1142 
1143 /**
1144  * This is the beginning of information about an entry in the resource
1145  * table.  It holds the reference to the name of this entry, and is
1146  * immediately followed by one of:
1147  *   * A Res_value structure, if FLAG_COMPLEX is -not- set.
1148  *   * An array of ResTable_map structures, if FLAG_COMPLEX is set.
1149  *     These supply a set of name/value mappings of data.
1150  */
1151 struct ResTable_entry
1152 {
1153     // Number of bytes in this structure.
1154     uint16_t size;
1155 
1156     enum {
1157         // If set, this is a complex entry, holding a set of name/value
1158         // mappings.  It is followed by an array of ResTable_map structures.
1159         FLAG_COMPLEX = 0x0001,
1160         // If set, this resource has been declared public, so libraries
1161         // are allowed to reference it.
1162         FLAG_PUBLIC = 0x0002
1163     };
1164     uint16_t flags;
1165 
1166     // Reference into ResTable_package::keyStrings identifying this entry.
1167     struct ResStringPool_ref key;
1168 };
1169 
1170 /**
1171  * Extended form of a ResTable_entry for map entries, defining a parent map
1172  * resource from which to inherit values.
1173  */
1174 struct ResTable_map_entry : public ResTable_entry
1175 {
1176     // Resource identifier of the parent mapping, or 0 if there is none.
1177     ResTable_ref parent;
1178     // Number of name/value pairs that follow for FLAG_COMPLEX.
1179     uint32_t count;
1180 };
1181 
1182 /**
1183  * A single name/value mapping that is part of a complex resource
1184  * entry.
1185  */
1186 struct ResTable_map
1187 {
1188     // The resource identifier defining this mapping's name.  For attribute
1189     // resources, 'name' can be one of the following special resource types
1190     // to supply meta-data about the attribute; for all other resource types
1191     // it must be an attribute resource.
1192     ResTable_ref name;
1193 
1194     // Special values for 'name' when defining attribute resources.
1195     enum {
1196         // This entry holds the attribute's type code.
1197         ATTR_TYPE = Res_MAKEINTERNAL(0),
1198 
1199         // For integral attributes, this is the minimum value it can hold.
1200         ATTR_MIN = Res_MAKEINTERNAL(1),
1201 
1202         // For integral attributes, this is the maximum value it can hold.
1203         ATTR_MAX = Res_MAKEINTERNAL(2),
1204 
1205         // Localization of this resource is can be encouraged or required with
1206         // an aapt flag if this is set
1207         ATTR_L10N = Res_MAKEINTERNAL(3),
1208 
1209         // for plural support, see android.content.res.PluralRules#attrForQuantity(int)
1210         ATTR_OTHER = Res_MAKEINTERNAL(4),
1211         ATTR_ZERO = Res_MAKEINTERNAL(5),
1212         ATTR_ONE = Res_MAKEINTERNAL(6),
1213         ATTR_TWO = Res_MAKEINTERNAL(7),
1214         ATTR_FEW = Res_MAKEINTERNAL(8),
1215         ATTR_MANY = Res_MAKEINTERNAL(9)
1216 
1217     };
1218 
1219     // Bit mask of allowed types, for use with ATTR_TYPE.
1220     enum {
1221         // No type has been defined for this attribute, use generic
1222         // type handling.  The low 16 bits are for types that can be
1223         // handled generically; the upper 16 require additional information
1224         // in the bag so can not be handled generically for TYPE_ANY.
1225         TYPE_ANY = 0x0000FFFF,
1226 
1227         // Attribute holds a references to another resource.
1228         TYPE_REFERENCE = 1<<0,
1229 
1230         // Attribute holds a generic string.
1231         TYPE_STRING = 1<<1,
1232 
1233         // Attribute holds an integer value.  ATTR_MIN and ATTR_MIN can
1234         // optionally specify a constrained range of possible integer values.
1235         TYPE_INTEGER = 1<<2,
1236 
1237         // Attribute holds a boolean integer.
1238         TYPE_BOOLEAN = 1<<3,
1239 
1240         // Attribute holds a color value.
1241         TYPE_COLOR = 1<<4,
1242 
1243         // Attribute holds a floating point value.
1244         TYPE_FLOAT = 1<<5,
1245 
1246         // Attribute holds a dimension value, such as "20px".
1247         TYPE_DIMENSION = 1<<6,
1248 
1249         // Attribute holds a fraction value, such as "20%".
1250         TYPE_FRACTION = 1<<7,
1251 
1252         // Attribute holds an enumeration.  The enumeration values are
1253         // supplied as additional entries in the map.
1254         TYPE_ENUM = 1<<16,
1255 
1256         // Attribute holds a bitmaks of flags.  The flag bit values are
1257         // supplied as additional entries in the map.
1258         TYPE_FLAGS = 1<<17
1259     };
1260 
1261     // Enum of localization modes, for use with ATTR_L10N.
1262     enum {
1263         L10N_NOT_REQUIRED = 0,
1264         L10N_SUGGESTED    = 1
1265     };
1266 
1267     // This mapping's value.
1268     Res_value value;
1269 };
1270 
1271 /**
1272  * Convenience class for accessing data in a ResTable resource.
1273  */
1274 class ResTable
1275 {
1276 public:
1277     ResTable();
1278     ResTable(const void* data, size_t size, void* cookie,
1279              bool copyData=false);
1280     ~ResTable();
1281 
1282     status_t add(const void* data, size_t size, void* cookie,
1283                  bool copyData=false, const void* idmap = NULL);
1284     status_t add(Asset* asset, void* cookie,
1285                  bool copyData=false, const void* idmap = NULL);
1286     status_t add(ResTable* src);
1287 
1288     status_t getError() const;
1289 
1290     void uninit();
1291 
1292     struct resource_name
1293     {
1294         const char16_t* package;
1295         size_t packageLen;
1296         const char16_t* type;
1297         size_t typeLen;
1298         const char16_t* name;
1299         size_t nameLen;
1300     };
1301 
1302     bool getResourceName(uint32_t resID, resource_name* outName) const;
1303 
1304     /**
1305      * Retrieve the value of a resource.  If the resource is found, returns a
1306      * value >= 0 indicating the table it is in (for use with
1307      * getTableStringBlock() and getTableCookie()) and fills in 'outValue'.  If
1308      * not found, returns a negative error code.
1309      *
1310      * Note that this function does not do reference traversal.  If you want
1311      * to follow references to other resources to get the "real" value to
1312      * use, you need to call resolveReference() after this function.
1313      *
1314      * @param resID The desired resoruce identifier.
1315      * @param outValue Filled in with the resource data that was found.
1316      *
1317      * @return ssize_t Either a >= 0 table index or a negative error code.
1318      */
1319     ssize_t getResource(uint32_t resID, Res_value* outValue, bool mayBeBag = false,
1320                     uint16_t density = 0,
1321                     uint32_t* outSpecFlags = NULL,
1322                     ResTable_config* outConfig = NULL) const;
1323 
1324     inline ssize_t getResource(const ResTable_ref& res, Res_value* outValue,
1325             uint32_t* outSpecFlags=NULL) const {
1326         return getResource(res.ident, outValue, false, 0, outSpecFlags, NULL);
1327     }
1328 
1329     ssize_t resolveReference(Res_value* inOutValue,
1330                              ssize_t blockIndex,
1331                              uint32_t* outLastRef = NULL,
1332                              uint32_t* inoutTypeSpecFlags = NULL,
1333                              ResTable_config* outConfig = NULL) const;
1334 
1335     enum {
1336         TMP_BUFFER_SIZE = 16
1337     };
1338     const char16_t* valueToString(const Res_value* value, size_t stringBlock,
1339                                   char16_t tmpBuffer[TMP_BUFFER_SIZE],
1340                                   size_t* outLen);
1341 
1342     struct bag_entry {
1343         ssize_t stringBlock;
1344         ResTable_map map;
1345     };
1346 
1347     /**
1348      * Retrieve the bag of a resource.  If the resoruce is found, returns the
1349      * number of bags it contains and 'outBag' points to an array of their
1350      * values.  If not found, a negative error code is returned.
1351      *
1352      * Note that this function -does- do reference traversal of the bag data.
1353      *
1354      * @param resID The desired resource identifier.
1355      * @param outBag Filled inm with a pointer to the bag mappings.
1356      *
1357      * @return ssize_t Either a >= 0 bag count of negative error code.
1358      */
1359     ssize_t lockBag(uint32_t resID, const bag_entry** outBag) const;
1360 
1361     void unlockBag(const bag_entry* bag) const;
1362 
1363     void lock() const;
1364 
1365     ssize_t getBagLocked(uint32_t resID, const bag_entry** outBag,
1366             uint32_t* outTypeSpecFlags=NULL) const;
1367 
1368     void unlock() const;
1369 
1370     class Theme {
1371     public:
1372         Theme(const ResTable& table);
1373         ~Theme();
1374 
getResTable()1375         inline const ResTable& getResTable() const { return mTable; }
1376 
1377         status_t applyStyle(uint32_t resID, bool force=false);
1378         status_t setTo(const Theme& other);
1379 
1380         /**
1381          * Retrieve a value in the theme.  If the theme defines this
1382          * value, returns a value >= 0 indicating the table it is in
1383          * (for use with getTableStringBlock() and getTableCookie) and
1384          * fills in 'outValue'.  If not found, returns a negative error
1385          * code.
1386          *
1387          * Note that this function does not do reference traversal.  If you want
1388          * to follow references to other resources to get the "real" value to
1389          * use, you need to call resolveReference() after this function.
1390          *
1391          * @param resID A resource identifier naming the desired theme
1392          *              attribute.
1393          * @param outValue Filled in with the theme value that was
1394          *                 found.
1395          *
1396          * @return ssize_t Either a >= 0 table index or a negative error code.
1397          */
1398         ssize_t getAttribute(uint32_t resID, Res_value* outValue,
1399                 uint32_t* outTypeSpecFlags = NULL) const;
1400 
1401         /**
1402          * This is like ResTable::resolveReference(), but also takes
1403          * care of resolving attribute references to the theme.
1404          */
1405         ssize_t resolveAttributeReference(Res_value* inOutValue,
1406                 ssize_t blockIndex, uint32_t* outLastRef = NULL,
1407                 uint32_t* inoutTypeSpecFlags = NULL,
1408                 ResTable_config* inoutConfig = NULL) const;
1409 
1410         void dumpToLog() const;
1411 
1412     private:
1413         Theme(const Theme&);
1414         Theme& operator=(const Theme&);
1415 
1416         struct theme_entry {
1417             ssize_t stringBlock;
1418             uint32_t typeSpecFlags;
1419             Res_value value;
1420         };
1421         struct type_info {
1422             size_t numEntries;
1423             theme_entry* entries;
1424         };
1425         struct package_info {
1426             size_t numTypes;
1427             type_info types[];
1428         };
1429 
1430         void free_package(package_info* pi);
1431         package_info* copy_package(package_info* pi);
1432 
1433         const ResTable& mTable;
1434         package_info*   mPackages[Res_MAXPACKAGE];
1435     };
1436 
1437     void setParameters(const ResTable_config* params);
1438     void getParameters(ResTable_config* params) const;
1439 
1440     // Retrieve an identifier (which can be passed to getResource)
1441     // for a given resource name.  The 'name' can be fully qualified
1442     // (<package>:<type>.<basename>) or the package or type components
1443     // can be dropped if default values are supplied here.
1444     //
1445     // Returns 0 if no such resource was found, else a valid resource ID.
1446     uint32_t identifierForName(const char16_t* name, size_t nameLen,
1447                                const char16_t* type = 0, size_t typeLen = 0,
1448                                const char16_t* defPackage = 0,
1449                                size_t defPackageLen = 0,
1450                                uint32_t* outTypeSpecFlags = NULL) const;
1451 
1452     static bool expandResourceRef(const uint16_t* refStr, size_t refLen,
1453                                   String16* outPackage,
1454                                   String16* outType,
1455                                   String16* outName,
1456                                   const String16* defType = NULL,
1457                                   const String16* defPackage = NULL,
1458                                   const char** outErrorMsg = NULL,
1459                                   bool* outPublicOnly = NULL);
1460 
1461     static bool stringToInt(const char16_t* s, size_t len, Res_value* outValue);
1462     static bool stringToFloat(const char16_t* s, size_t len, Res_value* outValue);
1463 
1464     // Used with stringToValue.
1465     class Accessor
1466     {
1467     public:
~Accessor()1468         inline virtual ~Accessor() { }
1469 
1470         virtual uint32_t getCustomResource(const String16& package,
1471                                            const String16& type,
1472                                            const String16& name) const = 0;
1473         virtual uint32_t getCustomResourceWithCreation(const String16& package,
1474                                                        const String16& type,
1475                                                        const String16& name,
1476                                                        const bool createIfNeeded = false) = 0;
1477         virtual uint32_t getRemappedPackage(uint32_t origPackage) const = 0;
1478         virtual bool getAttributeType(uint32_t attrID, uint32_t* outType) = 0;
1479         virtual bool getAttributeMin(uint32_t attrID, uint32_t* outMin) = 0;
1480         virtual bool getAttributeMax(uint32_t attrID, uint32_t* outMax) = 0;
1481         virtual bool getAttributeEnum(uint32_t attrID,
1482                                       const char16_t* name, size_t nameLen,
1483                                       Res_value* outValue) = 0;
1484         virtual bool getAttributeFlags(uint32_t attrID,
1485                                        const char16_t* name, size_t nameLen,
1486                                        Res_value* outValue) = 0;
1487         virtual uint32_t getAttributeL10N(uint32_t attrID) = 0;
1488         virtual bool getLocalizationSetting() = 0;
1489         virtual void reportError(void* accessorCookie, const char* fmt, ...) = 0;
1490     };
1491 
1492     // Convert a string to a resource value.  Handles standard "@res",
1493     // "#color", "123", and "0x1bd" types; performs escaping of strings.
1494     // The resulting value is placed in 'outValue'; if it is a string type,
1495     // 'outString' receives the string.  If 'attrID' is supplied, the value is
1496     // type checked against this attribute and it is used to perform enum
1497     // evaluation.  If 'acccessor' is supplied, it will be used to attempt to
1498     // resolve resources that do not exist in this ResTable.  If 'attrType' is
1499     // supplied, the value will be type checked for this format if 'attrID'
1500     // is not supplied or found.
1501     bool stringToValue(Res_value* outValue, String16* outString,
1502                        const char16_t* s, size_t len,
1503                        bool preserveSpaces, bool coerceType,
1504                        uint32_t attrID = 0,
1505                        const String16* defType = NULL,
1506                        const String16* defPackage = NULL,
1507                        Accessor* accessor = NULL,
1508                        void* accessorCookie = NULL,
1509                        uint32_t attrType = ResTable_map::TYPE_ANY,
1510                        bool enforcePrivate = true) const;
1511 
1512     // Perform processing of escapes and quotes in a string.
1513     static bool collectString(String16* outString,
1514                               const char16_t* s, size_t len,
1515                               bool preserveSpaces,
1516                               const char** outErrorMsg = NULL,
1517                               bool append = false);
1518 
1519     size_t getBasePackageCount() const;
1520     const char16_t* getBasePackageName(size_t idx) const;
1521     uint32_t getBasePackageId(size_t idx) const;
1522 
1523     // Return the number of resource tables that the object contains.
1524     size_t getTableCount() const;
1525     // Return the values string pool for the resource table at the given
1526     // index.  This string pool contains all of the strings for values
1527     // contained in the resource table -- that is the item values themselves,
1528     // but not the names their entries or types.
1529     const ResStringPool* getTableStringBlock(size_t index) const;
1530     // Return unique cookie identifier for the given resource table.
1531     void* getTableCookie(size_t index) const;
1532 
1533     // Return the configurations (ResTable_config) that we know about
1534     void getConfigurations(Vector<ResTable_config>* configs) const;
1535 
1536     void getLocales(Vector<String8>* locales) const;
1537 
1538     // Generate an idmap.
1539     //
1540     // Return value: on success: NO_ERROR; caller is responsible for free-ing
1541     // outData (using free(3)). On failure, any status_t value other than
1542     // NO_ERROR; the caller should not free outData.
1543     status_t createIdmap(const ResTable& overlay, uint32_t originalCrc, uint32_t overlayCrc,
1544                          void** outData, size_t* outSize) const;
1545 
1546     enum {
1547         IDMAP_HEADER_SIZE_BYTES = 3 * sizeof(uint32_t),
1548     };
1549     // Retrieve idmap meta-data.
1550     //
1551     // This function only requires the idmap header (the first
1552     // IDMAP_HEADER_SIZE_BYTES) bytes of an idmap file.
1553     static bool getIdmapInfo(const void* idmap, size_t size,
1554                              uint32_t* pOriginalCrc, uint32_t* pOverlayCrc);
1555 
1556 #ifndef HAVE_ANDROID_OS
1557     void print(bool inclValues) const;
1558     static String8 normalizeForOutput(const char* input);
1559 #endif
1560 
1561 private:
1562     struct Header;
1563     struct Type;
1564     struct Package;
1565     struct PackageGroup;
1566     struct bag_set;
1567 
1568     status_t add(const void* data, size_t size, void* cookie,
1569                  Asset* asset, bool copyData, const Asset* idmap);
1570 
1571     ssize_t getResourcePackageIndex(uint32_t resID) const;
1572     ssize_t getEntry(
1573         const Package* package, int typeIndex, int entryIndex,
1574         const ResTable_config* config,
1575         const ResTable_type** outType, const ResTable_entry** outEntry,
1576         const Type** outTypeClass) const;
1577     status_t parsePackage(
1578         const ResTable_package* const pkg, const Header* const header, uint32_t idmap_id);
1579 
1580     void print_value(const Package* pkg, const Res_value& value) const;
1581 
1582     mutable Mutex               mLock;
1583 
1584     status_t                    mError;
1585 
1586     ResTable_config             mParams;
1587 
1588     // Array of all resource tables.
1589     Vector<Header*>             mHeaders;
1590 
1591     // Array of packages in all resource tables.
1592     Vector<PackageGroup*>       mPackageGroups;
1593 
1594     // Mapping from resource package IDs to indices into the internal
1595     // package array.
1596     uint8_t                     mPackageMap[256];
1597 };
1598 
1599 }   // namespace android
1600 
1601 #endif // _LIBS_UTILS_RESOURCE_TYPES_H
1602