#include <errno.h>
#include <stdio.h>
-#include <string.h>
-#include <apc/ir.h>
+#include <stdint.h> //uint64_t
+#include <string.h> //memmove
+#include <stdlib.h> //malloc
+#include "ir.h"
+
+#define CURR_CDAT (*cdat_stackp)
+#define CURR_SET set_list[CURR_CDAT->num_sets]
+#define CURR_ELE ele_list[CURR_CDAT->CURR_SET.num_ele]
+#define PREV_REF (ref_buf[num_refs-1])
+#define CURR_REF (ref_buf[num_refs])
+#define PREV_ODAT (odat_buf[num_odats-1])
+#define CURR_ODAT (odat_buf[num_odats])
+#define CURR_VDAT (vdat_buf[num_vdats])
+#define PREV_VDAT (vdat_buf[num_vdats-1])
+#define CURR_MODEL model_list[CURR_VDAT->num_models]
+#define CURR_LINK (link_buf[num_links])
-#define CURR_ODAT (odat_buf[obi])
-#define CURR_VDAT (vdat_buf[vbi])
-#define CURR_CDAT (cdat_buf[cbi]) //more like the base cdat
-//TODO: label and vdat_id
void
-insert_set()
+ir_init()
{
- CURR_CDAT.set_list[CURR_CDAT.set_index].odat_id = obi;
- CURR_CDAT.set_list[CURR_CDAT.set_index].parent_id = 0;//from lexer
- //TODO: add ele_stack is created in element_list
- //TODO: add set to odat_buf
+ /* Init root cdat and stack */
+ char root[4] = "root";
+
+ cdat_buf[num_cdats] = (struct cdat*) malloc(sizeof(struct cdat) );
+ cdat_buf[num_cdats]->idx = 0;
+ memmove(cdat_buf[num_cdats]->name, root, 4);
+
+ cdat_stackp = cdat_stack;
+ *cdat_stackp = cdat_buf[num_cdats++];
+ /* Init first odat */
+ if( (CURR_ODAT = (struct odat*) malloc(sizeof(struct odat))) == NULL)
+ perror("malloc first odat failed");
+
+ /* init first vdat*/
+ if( (CURR_VDAT = (struct vdat*) malloc(sizeof(struct vdat))) == NULL)
+ perror("malloc first vdat failed");
+
+ /* Init first ref */
+ if( (CURR_REF = (struct ref*) malloc(sizeof(struct ref))) == NULL)
+ perror("malloc first ref failed");
+
+ /* Init first link */
+ if( (CURR_LINK = (struct link*) malloc(sizeof(struct link))) == NULL)
+ perror("malloc first link failed");
}
-#define CURR_QUAD (CURR_ODAT.ref_list[CURR_ODAT.ref_index])
+//TODO: FREE MEMORY!
void
-insert_ref(int x, int y, int z, int ref)
+malloc_cdat()
{
- CURR_QUAD.x = x;
- CURR_QUAD.y = y;
- CURR_QUAD.z = z;
- CURR_QUAD.objref = ref;
+
+ if(curr_max_cdats <= num_cdats)
+ {
+ if( (realloc((void*) cdat_buf, PTRS_IN_PAGE * 4)) == NULL)
+ perror("realloc cdat_buf failed");
+ curr_max_cdats += PTRS_IN_PAGE;
+ if( (realloc( (void*) cdat_stack, PTRS_IN_PAGE * 4)) == NULL) //increase cdat_stack also
+ perror("realloc cdat_stack failed");
+ }
+ if( (cdat_buf[num_cdats] = (struct cdat*) malloc(sizeof (struct cdat)) ) == NULL )
+ perror("malloc cdat failed");
+
+
}
+/* Dynamically allocate memory for a class data structure,
+ or cdat, after a class has been identified in a grammar.
+ We also create a stack of class pointers so that
+ we can access the cdat during processing of that
+ cdats sets and elements, a requirement because the
+ nature of recursive classes prevents us from accessing
+ the cdat based on the previous index into cdat_buf,
+ which is a list of all allocated cdats*/
+void
+push_cdat(char* name)
+{
+
+ malloc_cdat();
+
+ memmove(cdat_buf[num_cdats]->name, name, 32);
+ cdat_buf[num_cdats]->idx = num_cdats;
+
+ /* Set the cdat as a class of the previous cdat */
+ (*cdat_stackp)->class_list[(*cdat_stackp)->num_classes++] = cdat_buf[num_cdats];
+
+ /* Push the cdat onto the cdat_stack */
+ *++cdat_stackp = cdat_buf[num_cdats++];
+
+}
+
+void
+pop_cdat()
+{
+ *cdat_stackp = NULL;
+ cdat_stackp--;
+}
+
+void
+inc_odat()
+{
+ num_odats++;
+ if(num_odats >= curr_max_odats)
+ {
+ if( (realloc((void*) odat_buf, PTRS_IN_PAGE * 4)) == NULL)
+ perror("realloc odat_buf failed");
+ curr_max_odats += PTRS_IN_PAGE;
+ }
+ if( (CURR_ODAT = (struct odat*) malloc(sizeof (struct odat))) == NULL)
+ {
+ perror("malloc odat failed");
+ }
+
+}
+
+void
+inc_vdat()
+{
+ num_vdats++;
+ if(num_vdats >= curr_max_vdats)
+ {
+ if( (realloc((void*) vdat_buf, PTRS_IN_PAGE * 4)) == NULL)
+ perror("realloc vdat_buf failed");
+ curr_max_vdats += PTRS_IN_PAGE;
+ }
+ if((CURR_VDAT = (struct vdat*) malloc(sizeof (struct vdat))) == NULL)
+ {
+ perror("malloc vdat failed");
+ }
+
+}
+
+void
+inc_link()
+{
+ num_links++;
+ if(num_links >= curr_max_links)
+ {
+ if( (realloc((void*) link_buf, PTRS_IN_PAGE * 4)) == NULL)
+ perror("realloc vdat_buf failed");
+ curr_max_links += PTRS_IN_PAGE;
+ }
+ if((CURR_LINK = (struct link*) malloc(sizeof (struct link))) == NULL)
+ {
+ perror("malloc link failed");
+ }
+}
+
+void
+inc_ref()
+{
+
+ if(num_refs % 16 == 0)
+ {
+ posts[num_posts++] = *CURR_REF;
+ }
+
+ num_refs++;
+ if(num_refs >= curr_max_refs)
+ {
+ if( (realloc((void*) ref_buf, PTRS_IN_PAGE * 4)) == NULL)
+ perror("realloc ref_buf failed");
+ curr_max_refs += PTRS_IN_PAGE;
+ }
+ if((CURR_REF = (struct ref*) malloc(sizeof (struct ref))) == NULL)
+ perror("malloc ref failed");
+}
-//Insert element into odat_buf and cdat_buf
void
-insert_ele(char* label, int vdat_id)
+insert_set_label(char* name, uint64_t ref_id)
{
- memmove(CURR_ODAT.label,label,32);
- CURR_ODAT.vdat_id = vdat_id;
- //TODO: check set_obi to see if set_map_data exists
- //comes from e
- //CURR_ODAT.num_ref = //comes from its set
- //CURR_ODAT.ref_list = //comes from its set
- //CURR_ODAT.class_id = //comes from lexer?
+ memmove(CURR_CDAT->CURR_SET.name,name,32);
+ memmove(&CURR_CDAT->CURR_SET.ref_id,&ref_id,64);
- obi++;
}
+void
+insert_set_olink(uint64_t ref_id)
+{
+ CURR_CDAT->CURR_SET.cdat_idx = CURR_CDAT->idx;
+ CURR_CDAT->CURR_SET.ref_id = ref_id; /* Will be resolved to offset
+ when link is processed */
+ CURR_LINK->type = 1;
+ CURR_LINK->link_t.olink.ref_id = ref_id;
+ CURR_LINK->cdat_idx = CURR_CDAT->idx;
+ CURR_LINK->set_idx = CURR_CDAT->num_sets++;
+ CURR_LINK->ele_idx = -1;
+ inc_link();
+}
-/* fd could be a directory entry */
void
-insert_fdat(char* label, char direction, int fd)
+insert_set_vlink(uint64_t ref_id, char* anim_name)
{
- memmove(CURR_VDAT.model_list[CURR_VDAT.num_models].label,label,32);
- CURR_VDAT.model_list[CURR_VDAT.num_models].fdat_id[(int)direction] = fd;
+ /* Insert vlink into link_stack so that it gets processed at
+ output time */
+ CURR_LINK->cdat_idx = CURR_CDAT->idx;
+ CURR_LINK->set_idx = CURR_CDAT->num_sets;
+ CURR_LINK->type = 2;
+ CURR_LINK->link_t.vlink.ref_id = ref_id;
+ memmove(CURR_LINK->link_t.vlink.anim_name, anim_name, 32);
+
+
}
void
-condense()
+insert_set_svlink(uint64_t ref_id)
{
- FILE *vp, *op, *cp;
- int v, m;
- int num_models;
- vp = fopen("vdat_output", "w+");
- if(!vp)
- perror("vdat_output failed to open\n");
+ /* Insert vlink into link_stack so that it gets processed at
+ output time */
+ CURR_LINK->cdat_idx = CURR_CDAT->idx;
+ CURR_LINK->set_idx = CURR_CDAT->num_sets;
+ CURR_LINK->type = 3;
+ CURR_LINK->link_t.svlink.ref_id = ref_id;
- op = fopen("odat_output", "w+");
- if(!op)
- perror("odat_output failed to open\n");
+}
- cp = fopen("cdat_output", "w+");
- if(!cp)
- perror("cdat_output failed to open\n");
+/* At the point of reducing to a set, most of the
+ sets odat information has already been populated
+ during the reduction of its right hand side
+ non terminals (hitbox, root, quad_list). */
+void
+insert_set()
+{
+ uint64_t ref_id;
+ ref_id = CURR_CDAT->CURR_SET.ref_id;
+ CURR_CDAT->CURR_SET.cdat_idx = CURR_CDAT->idx;
+ memmove(CURR_ODAT->name, CURR_CDAT->CURR_SET.name, 32);
+ CURR_CDAT->num_sets++;
- /* fwrite vdat */
- for(v = 0; v <= vbi; v++)
- {
- num_models = vdat_buf[v].num_models; //data duplication for caching
- for(m = 0; m <= num_models; m++)
- {
-
- }
+ CURR_ODAT->cdat_idx = CURR_CDAT->idx;
+ CURR_ODAT->refp = CURR_REF;
+
+
+ CURR_REF->lastref = PREV_REF;
+ PREV_REF->nextref = CURR_REF;
+ CURR_REF->odatp = CURR_ODAT;
+
+
+ if(ref_id == -1) /* user did not define a ref_id so */
+ { /* use a ref_id from system_space */
+ ref_id = ss_ref_id;
+ ss_ref_id++;
}
- /* fwrite odat */
- /* Convert ref_list to actual offset */
+ CURR_REF->ref_id = ref_id;
- /* fwrite cdat */
+ inc_ref();
+ inc_odat();
}
+
void
-inc_cbi()
+insert_vdat()
{
- cbi++;
+ PREV_ODAT->vdat_id = num_vdats; //NULL for vlink, svlink
+ inc_vdat();
}
+/* Populates both the odat name and ref_id
+ for element. */
void
-set_class_label(char* label)
+insert_ele_label(char* name, uint64_t ref_id)
{
- memmove(CURR_CDAT.label,label,32);
+ memmove(CURR_CDAT->CURR_SET.CURR_ELE.name, name, 32);
+ memmove(&CURR_CDAT->CURR_SET.ele_list[CURR_CDAT->CURR_SET.ref_id].ref_id, &ref_id, 64);
}
void
-inc_subclass_idx()
+insert_ele_olink(uint64_t ref_id)
{
- CURR_CDAT.subclass_index++;
+ CURR_CDAT->CURR_SET.CURR_ELE.cdat_idx = CURR_CDAT->idx;
+ CURR_CDAT->CURR_SET.CURR_ELE.ref_id = ref_id; /* Will be resolved to offset
+ when link is processed */
+ CURR_LINK->type = 1;
+ CURR_LINK->link_t.olink.ref_id = ref_id;
+ CURR_LINK->cdat_idx = CURR_CDAT->idx;
+ CURR_LINK->set_idx = CURR_CDAT->num_sets++;
+ CURR_LINK->ele_idx = CURR_CDAT->CURR_SET.num_ele++;
+
}
+void
+insert_ele_vlink(uint64_t ref_id, char* anim_name)
+{
+
+ /* Insert vlink into link_stack so that it gets processed at
+ output time */
+ CURR_LINK->cdat_idx = CURR_CDAT->idx;
+ CURR_LINK->type = 2;
+ CURR_LINK->set_idx = CURR_CDAT->num_sets;
+ CURR_LINK->ele_idx = CURR_CDAT->CURR_SET.num_ele;
+ CURR_LINK->link_t.vlink.ref_id = ref_id;
+ memmove(CURR_LINK->link_t.vlink.anim_name, anim_name, 32);
+
+}
void
-inc_set_index()
+insert_ele_svlink(uint64_t ref_id)
{
- cdat_buf[cbi].set_index++;
+
+ CURR_LINK->cdat_idx = CURR_CDAT->idx;
+ CURR_LINK->type = 3;
+ CURR_LINK->set_idx = CURR_CDAT->num_sets;
+ CURR_LINK->ele_idx = CURR_CDAT->CURR_SET.num_ele;
+ CURR_LINK->link_t.svlink.ref_id = ref_id;
+
+
+}
+//Insert element into odat_buf and cdatpages
+void
+insert_ele()
+{
+
+ uint64_t ref_id;
+
+ ref_id = CURR_CDAT->CURR_SET.CURR_ELE.ref_id;
+
+ CURR_CDAT->CURR_SET.CURR_ELE.cdat_idx = CURR_CDAT->idx;
+ memmove(CURR_ODAT->name,CURR_CDAT->CURR_SET.CURR_ELE.name, 32);
+ CURR_CDAT->CURR_SET.num_ele++;
+
+ CURR_ODAT->cdat_idx = CURR_CDAT->idx;
+ CURR_ODAT->refp = CURR_REF;
+
+ if(ref_id == -1) /* user did not define a ref_id so */
+ { /* use a ref_id from system_space */
+ ref_id = ss_ref_id;
+ ss_ref_id++;
+ }
+
+ CURR_REF->ref_id = ref_id;
+
+ inc_odat();
+ inc_ref();
+
}
void
-inc_ref()
+insert_framesheets(char direction, char* name, uint64_t ref_id, int height , int width, int num_frames)
+{
+ CURR_VDAT->CURR_MODEL.spritesheet[(int)direction].height = height;
+ CURR_VDAT->CURR_MODEL.spritesheet[(int)direction].width = width;
+ CURR_VDAT->CURR_MODEL.spritesheet[(int)direction].num_frames = num_frames;
+ CURR_VDAT->num_models++;
+}
+
+#define CURR_QUAD (CURR_ODAT->quad_list[CURR_ODAT->num_quads])
+void
+insert_quad(int x, int y, int z, uint64_t ref_id)
+{
+ CURR_QUAD.x = x;
+ CURR_QUAD.y = y;
+ CURR_QUAD.z = z;
+ CURR_QUAD.ref_id = ref_id;
+ CURR_ODAT->num_quads++;
+}
+
+/* Inserting the hitbox into the set
+ odat. Elements that don't have
+ a hitbox will use the sets root. */
+void
+insert_hitbox(int hitbox)
{
- CURR_ODAT.ref_index++;
- CURR_ODAT.num_ref++;
+ CURR_ODAT->hitbox = hitbox;
}
-//TODO: This needs to be changed to account for
-// when the set is of a subclass.
+/* Inserting the root into the set
+ odat. Elements that don't have
+ a root will use the sets root. */
void
-inc_ele()
+insert_root(int x, int y, int z)
{
- CURR_CDAT.set_list[CURR_CDAT.set_index].num_ele++;
- vbi++;
+
+ CURR_ODAT->root.x = x;
+ CURR_ODAT->root.y = y;
+ CURR_ODAT->root.z = z;
}
void
-inc_models()
+insert_frame_pointer(char direction, void* frame)
{
- CURR_VDAT.num_models++;
+ CURR_VDAT->CURR_MODEL.spritesheet[(int)direction].frames[CURR_VDAT->CURR_MODEL.spritesheet[(int)direction].num_frames++] = frame;
}
+
-/* Structures allocated for and updated during parse time that
- are the IR before writing to the output file */
+/*!@file
+ \brief Intermediate Representation (IR) between Directory Structure and Engine Grammar
+ \details The IR serves as a storage structure that is populated during the
+ parsing of the input directory structure. After parsing is complete,
+ the IR will be condensed (removed of excess allocated space) and then
+ output as the Engine Grammar. In this file we describe the semantic actions
+ that are called at each step, and the memory buffers that they populate.
+ See parser.y for the description on how the input grammar is constructed,
+ and where/when semantic actions are called.
+ TODO: or just write it here.
+ \author Jordan Lavatai
+ \date Aug 2016
+ ----------------------------------------------------------------------------*/
+
+
+#include <stdint.h>
+//#include <apc/mem.h>TODO:
#define BUF_SIZE 256
-#define MAX_SUBCLASSES 16
#define MAX_SETS 256
#define MAX_ELES 256
-#define MAX_REFS 256
+#define MAX_QUADS 256
#define MAX_MODELS 256
+#define MAX_POSTS 256
+#define MAX_CLASS_DEPTH 256
+#define MAX_CLASSES 256
+#define MAX_FRAMES 256
+/* All bufs are of pointers to their respective structs. When a buf is full */
+/* (number of data structs pointers >= max number of data struct pointers), */
+/* we need to allocate a more pointers for that buf. Allocate these */
+/* pointers a page at a time (1024 = Page bytes (4096)/bytes per pointer(4)) */
+/* TODO: Account for different page sizes in different system */
+#define PTRS_IN_PAGE 1024
+
+/* General: All information from the directory structure is stored in */
+/* five buffers that comprise the IR: cdat_buf, odat_buf, vdat_buf, ref_buf */
+/* and link_buf. Each buf corresponds to the data structure that it stores. */
+/* The storage techique for all bufs (except cdat) is the same. Each bufs member first */
+/* populates its struct and then allocates the space for the next member */
+/* and increments the buf index. This means that we have to allocate the */
+/* very first member of each buf at ir_init(), so that we don't segfault */
+/* as the first member attempts to access memory that its previous member */
+/* didn't allocate (because it doesnt exist). We access the buf members */
+/* through standard array indexing but conceal the tediousness of array */
+/* indexing with macros. E.g. without macros, acessing an elements name */
+/* member would look like (split up to not go over line char limit): */
+/* (*cdat_stackp)->set_list[(*cdat_stackp)->num_sets] */
+/* .ele_list[(*cdat_stackp)->set_list[(*cdat_stackp->num_sets)].num_ele].name */
+
+/* For cdats in cdat_buf, we allocate the memory for a cdat once a cdat
+ is recognized in the grammar. Cdat_buf is different from the other bufs
+ because cdats have a root cdat that all cdats are a subclass of. This root
+ cdat can have a set_list like other cdats. */
-struct ref {
- int x, y, z, objref;
-};
+
+/* Elements: Ele stands for element and has two representations in the IR. */
+/* In the cdat_buf eles store their name, cdat_idx (their classes index in */
+/* the cdat_buf) and the ref_id (refer to ref ). In the odat_buf, eles store */
+/* their object data (odat). At output time, the ref_id is dereferenced to */
+/* determine the elements odat which is the data that the engine expects */
+/* from an element. */
struct ele {
- int odat_id;
- int parent_id;//offset into class set_stack
+ char name[32];
+ uint64_t ref_id;
+ int cdat_idx;
};
+/* Sets: The set is similar to the ele, but it contains a list of its */
+/* elements. The set is populated at parse time AFTER the elements are */
+/* populated, due to the nature of bottom up parsing. */
+
struct set {
- int odat_id;
- int parent_id;//offset into CB
+ char name[32];
+ uint64_t ref_id;
+ int cdat_idx;
int num_ele;
- int ele_index; //same as num_ele?
struct ele ele_list[MAX_ELES];
};
+/* Cdats: A cdat is a class data structure. Cdats serve as the central */
+/* data types of the IR. At output, the cdat_buf is iterated through and */
+/* each is written to the output file. For each cdat, sets and element */
+/* ref_ids must be dereferenced to determine the odat information. Cdats */
+/* contain pointers to their subclasses so that the relationship between */
+/* classes can be determined, but the subclasses are not represented inside */
+/* of the cdat itself but rather in the subsequent cdats in cdat_buf. We */
+/* can determine the number of subclasses (the last index into cdat_buf */
+/* that represents a subclass of some arbitrary cdat) each cdat has by */
+/* incrementing num_classes during parse time. */
+/* TODO: Should classes point to their parent class? */
-//8 ids for each direction
-//fdat_id ordered by alphabetical direction
-struct model {
- char label[32];
- int fdat_id[8];
+struct cdat {
+ char name[32];
+ int idx;
+ int num_classes;
+ int num_sets;
+ struct cdat* class_list[MAX_CLASSES];
+ struct set set_list[MAX_SETS];
};
-struct vdat {
- char label[32];
- int num_models;
- int msi; //model_stack_index
- struct model model_list[MAX_MODELS];
+/* There are an unknown amount of cdats at compile time, so we maintain */
+/* a cdat_buf of cdat pointers that can be expanded as needed. */
+struct cdat* cdat_buf[PTRS_IN_PAGE];
+int num_cdats = 0;
+int curr_max_cdats = PTRS_IN_PAGE;
+
+/* The cdat_stack is a stack pointers to cdat pointers, the top of which is
+ the cdat that is currently being parsed. Whenever a new cdat is recognized
+ by the grammar (CLOPEN), a cdat is pushed onto the cdat_stack, and we refer
+ to this cdat through the macro CURR_CDAT. By keeping a cdat_stack, we have
+ access to the current cdat so that the elements and sets can populate themselves
+ in the cdat accordingly. */
+
+struct cdat* cdat_stack[PTRS_IN_PAGE];
+struct cdat** cdat_stackp;
+
+/* Refs: Each set/ele has a reference to its object data (odat) through a ref_id.
+ Ref_ids are unsigned 64 byte integers that map to the hex values RGBA. During
+ the construction of the directory structure, users can choose a RGBA value for
+ each object that any other object can refer to via links (see link). If a user
+ does not choose an RGBA value, then the object is given one from the system space.
+ We maintain a doubly linked list of refs in the ref_buf at parse time so that
+ links can be resolved after the parsing of the directory structure is complete.
+ For every 16th ref, we create a post so that we can reduce on the search time for
+ a random access. */
+
+struct ref {
+ int type;
+ struct ref* nextref;
+ struct ref* lastref;
+ struct odat* odatp;
+ uint64_t ref_id; //0xFFFFFF->digit
};
-struct cdat {
- char label[32];
- int num_subclasses;
- int num_sets;
- int subclass_index;
- int set_index;
- struct cdat* subclass_list[MAX_SUBCLASSES];
- struct set set_list[MAX_SETS];
+/* Like the cdat_buf, ref_buf stores pointers to refs and can
+ increase in size */
+struct ref* ref_buf[PTRS_IN_PAGE];
+int num_refs = 0;
+int curr_max_refs = PTRS_IN_PAGE;
+uint64_t ss_ref_id = 0x00FFFFFF; /* system space for ref_ids */
+
+
+/* posts for ref_buf */
+struct ref posts[MAX_POSTS];
+int num_posts;
+
+/* Links: At parse time, a set/ele can include a link in their
+ grammar representation instead of the actual data and this signifies
+ to the APC that that set/ele wishes to use the data of another
+ set/ele, either its video data (vdat) or object data (odat). The link
+ itself contains the type of link it is, the ref_id OR name, and
+ which set/ele created the link. During parse time, links can be made
+ to o/vdats that have yet to be parsed. In order to accomodate for this,
+ we resolve all links AFTER parse time by iterating through the link_buf,
+ finding the ref_id that was stored for some object (if the ref_id exists),
+ and creating a relative pointer from the original object to the data that
+ was linked */
+
+/* Svlinks stand for short vlink, which is a link to a vdat
+ TODO: diff btwn vlink*/
+
+struct svlink {
+ uint64_t ref_id;
+};
+
+/* A vlink is what it sounds like, a link to a vdat
+ TODO: model link? */
+struct vlink {
+ uint64_t ref_id;
+ char anim_name[32];
+};
+
+/* Olinks are links to odats */
+struct olink {
+ uint64_t ref_id;
+};
+
+union link_t {
+ struct olink olink;
+ struct vlink vlink;
+ struct svlink svlink;
+};
+
+struct link {
+ int type; //1 = olink, 2 = vlink, 3 = svlink
+ union link_t link_t;
+ int cdat_idx;
+ int set_idx;
+ int ele_idx;
+};
+/* link_buf contains all the links that
+ we encountered during parse time that need
+ to be resolved to an offset at output time.
+ This does not include quad refs, because
+ those are already known to need to be resolved */
+struct link* link_buf[PTRS_IN_PAGE];
+int num_links = 0;
+int curr_max_links = PTRS_IN_PAGE;
+
+
+/* Odats: Odats consist of the object data necessary for
+ each object. Odats are sometimes referred to as archetypes
+ at compile-time, in order to distinguish the difference from
+ a runtime object and a compile-time object.
+ TODO: Need more info about objects at runtime, to described
+ the reasoning behind odat structure at compile-time*/
+
+/* Each set has a quad_list or a list of quads. The quad_list
+ is the ? */
+struct quad {
+ int x, y, z;
+ uint64_t ref_id; //rgba
+};
+
+struct root {
+ int x, y, z;
};
-//Element or a set
struct odat {
- char label[32];
+ char name[32];
int vdat_id;
- int class_id;
- int num_ref;
- int ref_index;
- struct ref ref_list[MAX_REFS];
+ int cdat_idx;
+ int hitbox;
+ struct root root;
+ struct ref* refp; /* pointer to it's ref on ref_list */
+ int num_quads;
+ struct quad quad_list[MAX_QUADS];
+};
+
+/* Populated and allocated same way as other bufs */
+struct odat* odat_buf[PTRS_IN_PAGE];
+int curr_max_odats = PTRS_IN_PAGE;
+int num_odats = 0;
+
+/* A framesheet is a grouping of animation frames in
+ a single direction (N,W,S,E) */
+struct framesheet {
+ int width;
+ int height;
+ int num_frames;
+ void* frames[MAX_FRAMES];
};
+/* A model is a collection of framesheets for every
+ direction (N,W,S,E,NW,NE,SW,SE)*/
+/* NAMED spritesheet */
+struct model {
+ char name[32];
+ struct framesheet spritesheet[8]; //one for each
+};
+
+/* Vdat: Vdats are the video data of each object. They can not be
+ created as a stand alone object (because they consist solely
+ of animation information and not the skeleton on which the
+ animation manipulates). Vdats have a list of models for every
+ animation that the vdats odat can do for that vdat*/
+struct vdat {
+ struct odat* creator; //pointer to odat that made this vdat
+ int num_models;
+ struct model model_list[MAX_MODELS];
+};
-struct cdat cdat_buf[BUF_SIZE];
-struct odat odat_buf[BUF_SIZE];
-struct vdat vdat_buf[BUF_SIZE];
-//indexes for buffers
-int cbi = 0;
-int vbi = 0;
-int obi = 0;
+struct vdat* vdat_buf[PTRS_IN_PAGE];
+int curr_max_vdats = PTRS_IN_PAGE;
+int num_vdats = 0;
+/* The initalization function of the IR. Mallocs the
+ first c/v/odat and the first links and refs and
+ inits the cdat_stack */
void
-insert_set(void);
+ir_init(void);
+
+/* mallocs memory for a new cdat. If the cdat_buf
+ is full, mallocs another 1024 cdat pointers. */
+void
+malloc_cdat(void);
+/* Called after the cdat open operator has been recognized in grammar. Allocates
+ the space for a cdat on the cdat_buf, pushes that pointer onto
+ the cdat_stack */
void
-insert_ref(int, int, int, int);
+push_cdat(char*);
+/* Called after a cdat end operator has been recognized in grammar. Sets
+ top stack cdat ** to null and decrements stack pointer */
void
-inc_cbi(void);
+pop_cdat(void);
+/* Called after an odat has been populated. Allocates memory for
+ the next odat. */
void
-set_class_label(char*);
+inc_odat(void);
+/* Called after an vdat has been populated. Allocates memory for
+ the next vdat. */
void
-inc_subclass_index(void);
+inc_vdat(void);
void
-inc_subclass_index(void);
+inc_link(void);
void
inc_ref(void);
+/* Called in the reduction of a set. While both odats (eles and sets)
+ have identical label terminals, we are unable to give a single grammatical rule
+ for both due to how we allocate odats in the odat buf. Due to the
+ nature of bottom up parsing, all the elements will be inserted into the
+ odat_buf first, and then the set that contains these element is inserted. Since
+ the sets label comes before the element list in the grammar, we would be giving an element
+ a set label in its respective odat, which would then be replaced by the
+ elements label. Instead, we store the label in the sets representation inside
+ CURR_CDAT and after we are done parsing the element_list and know that the CURR_ODAT
+ is the set, we populate the sets label members in CURR_ODAT with the values we stored
+ previously in CURR_CDAT. */
+void
+insert_set_label(char*, uint64_t);
+
+/* Populate the sets representation in CURR_CDAT with a ref_id and insert a link
+ into the link_buf that will resolve the ref_id to an actual odat after parse time. */
void
-inc_models(void);
+insert_set_olink(uint64_t);
+
+/* Put the vlink in the link_buf to be processed after parsetime */
+void
+insert_set_vlink(uint64_t, char*);
+
+/* Put svlink in the link_buf to be processed after parsetime */
+void
+insert_set_svlink(uint64_t);
+
+/* Called for every set reduction except for sets with olinks. Populates the
+ set data structures in the CDAT and in the ODAT. Uses the name and ref_id
+ from insert_set_label. Also inserts a ref into the ref_buf with the CURR_ODAT
+ pointer so that we can also resolve the odat from its ref_id. */
+void
+insert_set(void);
+
+/* Insertion of eles is practically equivalent to how sets are inserted because both
+ share the same data type (ODAT). Like sets, eles have links, labels
+ and odats. Eles have the added notion of a parent set, and so must be inserted
+ into said parent set, but this is the only place they truly differ from sets. */
+
+void
+insert_ele_label(char*, uint64_t);
+
+void
+insert_ele_olink(uint64_t);
+
+void
+insert_ele_vlink(uint64_t, char*);
+
+void
+insert_ele_svlink(uint64_t);
+
+void
+insert_ele(void);
+
+/* Created as a seperate function, instead of setting the ODATS vdat_id and
+ calling inc_vdat() inside of insert_set(), to account for the set reduction
+ where a vdat is not created (o/v/svlinks). Because insert_set/ele is always
+ called before insert_vdat, and thus increments the CURR_ODAT to be the next
+ ODAT to be populated, insert_vdat() targets the last ODAT that was populated,
+ via PREV_ODAT. */
+void
+insert_vdat(void);
+
+/* Inserts the hitbox into the CURR_ODAT */
+void
+insert_hitbox(int);
+
+/* Inserts the root into the CURR_ODAT */
+void
+insert_root(int, int, int);
+
+/* Inserts a quad into the CURR_ODAT */
+void
+insert_quad(int, int, int, uint64_t);
+
+void
+insert_model(void);
+
+void
+insert_framesheet(char, char*, uint64_t, int, int, int);
+
+void
+insert_frame_pointer(char, void*);
+
%token VOPEN
%token VCLOSE
-%token RLS //!
-%token RLE //#
+%token QOPEN //!
+%token QCLOSE //#
%token RT //*
%token HB
%token MOD
%token <int> HEIGHT
%token <int> NUM_PTRS
//precedence
-%precedence LOW
-%precedence MED
-%precedence HIGH
+%precedence LP
+%precedence MP
+%precedence HP
/* Syntax Directed Translation Scheme of the APC grammar */
class_block:
class_list
-| class_list set_list
+| class_list set_list
| set_list
;
root:
RT NUM NUM NUM {insert_root($2, $3, $4);};
;
-quad_list:
-RLS quads RLE
-;
-quads:
-quads quad
+quad_list:
+quad_list quad
| quad
;
quad:
-NUM NUM NUM REF {insert_quad($1, $2, $3, $4);};
+QOPEN NUM NUM NUM REF QCLOSE {insert_quad($2, $3, $4, $5);};
hitbox:
HB NUM {insert_hitbox($2);}
set_label:
-HIGH NAME REF {insert_set_label($2,$3);};
-| LOW NAME {insert_set_label($2, -1);};
+HP NAME REF {insert_set_label($2,$3);};
+| LP NAME {insert_set_label($2, -1);};
;
set_svlink:
//parent_id is the set_index of the subclass_index.
element_list:
-element_list element MED
-| element LOW
+element_list element MP
+| element LP
;
ele_label:
-HIGH NAME REF {insert_ele_label($2, $3);};
-| LOW NAME {insert_ele_label($2, -1);};
+HP NAME REF {insert_ele_label($2, $3);};
+| LP NAME {insert_ele_label($2, -1);};
;
ele_vlink:
;
model:
-spritesheet LOW
+spritesheet LP
;
spritesheet:
-spritesheet HIGH framesheet
+spritesheet HP framesheet
| framesheet
;
framesheet:
-SSD NAME REF HEIGHT WIDTH NUM_PTRS frame_pointers LOW {insert_framesheet($1, $2, $3, $4, $5, $6);};
+SSD NAME REF HEIGHT WIDTH NUM_PTRS frame_pointers LP {insert_framesheet($1, $2, $3, $4, $5, $6);};
;
frame_pointers:
-frame_pointers SSD HIGH FPTR {insert_frame_pointer($2, $4);};
+frame_pointers SSD HP FPTR {insert_frame_pointer($2, $4);};
| SSD FPTR {insert_frame_pointer($1, $2);};
;