Added garbage collection (and a memory corruption bug)

4 місяці тому · efd764b907
--- a/ink.h
+++ b/ink.h
@ -1,6 +1,7 @@
 #pragma once
 #include "stddef.h"


 /**
 * Represents the natively defined type of integers
 */
@ -85,16 +86,31 @@ struct ink_routine {
 	void *routine_userdata;
 };

 /**
 * Contains a list of element on which garbage collection is to not be performed
 */
 struct ink_collection_list {
 	struct elem* elems;
 	size_t size;
    struct elem* elements;
    size_t count;
 };

 struct element_slab {
    void* data;
    int uses;
    int in_use;
 };

 /**
 * Contains all the data for every element of any type and its garbage collection information.
 */
 struct ink_type {
 	const char* name;
 	void* elements;
 	void (*collect)(void*);
 	struct ink_collection_list (*gc)(void*);
 	const char* name; //< The name of the type
    int element_size; //< The size of individual elements of the type, 0 for int adjacent, negative for unmanaged size
 	struct element_slab* elements; //< The elements that are still live
    int elements_top; //< The top of the elements list
    int elements_capacity; //< The allocated capacity of the elements list
 	void (*collect)(struct context*,void*); //< The "destructor" of the object
 	struct ink_collection_list (*gc)(struct context*,void*); //< A function that returns an in-interpreter allocated list of elem references within the object
 };

 /**
@ -136,8 +152,9 @@ struct context {
 	char **lex_reserved_words;
 	int lex_reserved_words_capacity;
 	int lex_reserved_words_top;
 	
 	unsigned int steps;

    unsigned int steps;
    unsigned int collections;

    /**
     * Can be set to any data that is convenient to the user to track and use within natively defined functions
@ -251,6 +268,56 @@ void ink_pop_fn(struct context *ctx);
 */
 void ink_pop(struct context *ctx);

 /**
 * Declares a new type that can be stored within the interpreter
 * @param ctx The context in which to add the file
 * @param type_name The name of the type we want to add
 * @param size The size in bytes of the type to add, size of 0 mean no size, in which case the type is adjacent to C int, negative size means that the memory is not managed by the interpreter.
 * @param collect A "destructor" function for the data
 * @param gc A function that returns a list (allocated with the `inner_malloc`) of all the elements this element holds references to
 * @return if positive, a new type id, if negative an error value
 * @internal user defined type ids minimal value is 15, we keep the first 16 types as reserved, just like negative type ids
 */
 int ink_new_type(
        struct context* ctx,
        const char* type_name,
        int size,
        void (*collect)(struct context*,void*),
        struct ink_collection_list (*gc)(struct context*,void*)
 );

 /**
 *
 * @param ctx The context of the interpreter
 * @param ref The in-interpreter reference
 * @return A pointer to the created value or NULL if it can't be found or has a size of 0
 */
 void* ink_get_value(struct context* ctx, struct elem ref);

 /**
 * Builds a native type from the provided memory by copying it using memcpy
 * @param ctx The context in which we operate
 * @param type_id The type_id to use
 * @param ptr The pointer from which to copy
 * @return The in-interpreter reference of the newly created element
 */
 struct elem ink_make_native(struct context* ctx, int type_id, void* ptr);

 /**
 * Builds a transparent type from the provided pointer
 * @param ctx The context in which we operate
 * @param type_id The type_id to use
 * @param ptr The pointer
 * @return The in-interpreter reference of the newly created element
 */
 struct elem ink_make_transparent(struct context* ctx, int type_id, void* ptr);

 /**
 * Launch the mark and sweep garbage collection
 * @param ctx The context to clean
 */
 void ink_gc(struct context* ctx);

 #ifdef __cplusplus
 };
 #endif
--- a/lib.c
+++ b/lib.c
@ -21,6 +21,9 @@
 #define _KEYWORD_INK_END "end"
 #define _KEYWORD_INK_RETURN "return"

 #define min(x, y) ((x) > (y) ? (y) : (x))
 #define max(x, y) ((x) < (y) ? (y) : (x))

 struct label {
 	int active;
 	int dest;
@ -271,6 +274,9 @@ struct context* ink_make_context(void*(*malloc)(size_t), void*(*realloc)(void*,
 	ctx->routines = NULL;
 	ctx->routines_capacity = 0;
 	ctx->routines_top = 0;
    ctx->types = NULL;
    ctx->types_capacity = 0;
    ctx->types_top = 0;
 	ctx->native_words = NULL;
 	ctx->native_words_capacity = 0;
 	ctx->native_words_top = 0;
@ -280,7 +286,8 @@ struct context* ink_make_context(void*(*malloc)(size_t), void*(*realloc)(void*,
 	ctx->lex_reserved_words = NULL;
 	ctx->lex_reserved_words_capacity = 0;
 	ctx->lex_reserved_words_top = 0;
 	ctx->steps = 0;
    ctx->collections = 0;
    ctx->steps = 0;
 	return ctx;
 }

@ -791,6 +798,172 @@ int ink_step_everyone(struct context* pContext) {
 	return 0;
 }

 int ink_new_type(
    struct context* ctx,
    const char* type_name,
    int size,
    void (*collect)(struct context*,void*),
    struct ink_collection_list (*gc)(struct context*,void*)
 ) {
    if(ctx->panic) return -128;
    if(ctx->types == NULL) {
        ctx->types = ctx->inner_malloc(sizeof(struct ink_type) * 8);
        ctx->types_top = 0;
        ctx->types_capacity = 8;
    } else if(ctx->types_top == ctx->types_capacity) {
        int new_count = (ctx->types_capacity + ctx->types_capacity/2);
        void* renewed = ctx->inner_realloc(ctx->types, sizeof(struct ink_type) * new_count);
        if(renewed == NULL) {
            return -129;
        } else {
            ctx->types = renewed;
            ctx->types_capacity = new_count;
        }
    }
    ctx->types[ctx->types_top].name = type_name;
    ctx->types[ctx->types_top].element_size = size;
    ctx->types[ctx->types_top].elements = NULL;
    ctx->types[ctx->types_top].elements_top = 0;
    ctx->types[ctx->types_top].elements_capacity = 0;
    ctx->types[ctx->types_top].collect = collect;
    ctx->types[ctx->types_top].gc = gc;

    ctx->types_top++;
    // Satisfying the minimal value requirement
    return ctx->types_top - 1 + 16;
 }

 static struct element_slab* ink_get_value_link(struct context* ctx, struct elem ref) {
    if(ref.type < 16) return NULL;
    int type_id = ref.type - 16;
    if(type_id >= ctx->types_top) return NULL;
    if(ctx->types[type_id].element_size == 0) return NULL;
    if(ref.value < 0) return NULL;
    if(ref.value >= ctx->types[type_id].elements_top) return NULL;
    if(! ctx->types[type_id].elements[ref.value].in_use) return NULL;
    return ctx->types[type_id].elements + ref.value;
 }

 void* ink_get_value(struct context* ctx, struct elem ref) {
    struct element_slab* s;
    s = ink_get_value_link(ctx, ref);
    if(s == NULL) return NULL;
    return s->data;
 }

 struct elem ink_make_native(struct context* ctx, int type, void* ptr) {
    if(type < 16) {
        struct elem ret;
        ret.type = 0;
        ret.value = -130;
        return ret;
    }
    int type_id = type - 16;
    if(type_id >= ctx->types_top) {
        struct elem ret;
        ret.type = 0;
        ret.value = -129;
        return ret;
    }

    if(ctx->panic) {
        struct elem ret;
        ret.type = 0;
        ret.value = -135;
        return ret;
    }
    if(ctx->types[type_id].elements == NULL) {
        ctx->types[type_id].elements = ctx->inner_malloc(sizeof(struct element_slab) * 8);
        ctx->types[type_id].elements_top = 0;
        ctx->types[type_id].elements_capacity = 8;
        memset(ctx->types[type_id].elements + ctx->types[type_id].elements_top, 0, ctx->types[type_id].elements_capacity - ctx->types[type_id].elements_top);
    } else if(ctx->types[type_id].elements_top == ctx->types[type_id].elements_capacity) {
        int new_count = (ctx->types[type_id].elements_capacity + ctx->types[type_id].elements_capacity/2);
        void* renewed = ctx->inner_realloc(ctx->types[type_id].elements, sizeof(struct element_slab) * new_count);
        if(renewed == NULL) {
            struct elem ret;
            ret.type = 0;
            ret.value = -129;
            return ret;
        } else {
            ctx->types[type_id].elements = renewed;
            ctx->types[type_id].elements_capacity = new_count;
            memset(ctx->types[type_id].elements + ctx->types[type_id].elements_top, 0, ctx->types[type_id].elements_capacity - ctx->types[type_id].elements_top);
        }
    }
    int g = ctx->types[type_id].elements_capacity;
    int i;
    for(i = 0; i < g; ++i) {
        if(! ctx->types[type_id].elements[i].in_use) {
            ctx->types[type_id].elements[i].in_use = 1;
            ctx->types[type_id].elements[i].uses = 1;
            if(ctx->types[type_id].element_size < 0) {
                ctx->types[type_id].elements[i].data = ptr;
            } else {
                void* new_ptr = ctx->malloc(ctx->types[type_id].element_size);
                if(new_ptr == NULL) {
                    struct elem ret;
                    ret.type = 0;
                    ret.value = -139;
                    return ret;
                }
                memcpy(new_ptr, ptr, ctx->types[type_id].element_size);
                ctx->types[type_id].elements[i].data = ptr;
            }
            ctx->types[type_id].elements_top = max(ctx->types[type_id].elements_top+1, i+1);
            struct elem ret;
            ret.type = type;
            ret.value = i;
            return ret;
        }
    }
    struct elem ret;
    ret.type = 0;
    ret.value = -140;
    return ret;
 }

 void ink_gc(struct context* ctx) {
    int i, j, k;
    for(i = 0; i < ctx->types_top; ++i) {
        for(j = 0; j < ctx->types[i].elements_top; ++j) {
            ctx->types[i].elements[j].uses = 0;
        }
    }

    for(i = 0; i < ctx->types_top; ++i) {
        for(j = 0; j < ctx->types[i].elements_top; ++j) {
            struct ink_collection_list c = ctx->types[i].gc(ctx, ctx->types[i].elements[j].data);
            for(k = 0; k < c.count; ++k) {
                struct element_slab* v = ink_get_value_link(ctx, c.elements[k]);
                if(v != NULL) ++v->uses;
            }
            if(c.elements != NULL) ctx->inner_free(c.elements);
        }
    }
    for(i = 0; i < ctx->routines_top; ++i) {
        for(j = 0; j < ctx->routines[i].top; ++j) {
            struct element_slab* v = ink_get_value_link(ctx, ctx->routines[i].stack[j]);
            if(v != NULL) ++v->uses;
        }
    }

    for(i = 0; i < ctx->types_top; ++i) {
        for(j = 0; j < ctx->types[i].elements_top; ++j) {
            if(ctx->types[i].elements[j].uses == 0) {
                ctx->collections++;
                ctx->types[i].collect(ctx, ctx->types[i].elements[j].data);
                if(ctx->types[i].element_size > 0) {
                    ctx->free(ctx->types[i].elements[j].data);
                }
                ctx->types[i].elements[j].data = NULL;
                ctx->types[i].elements[j].uses = 0;
                ctx->types[i].elements[j].in_use = 0;
            }
        }
    }
 }

 /**********************************************************************************************************************/

 static void print_stacktrace(struct context* _) {
@ -1069,10 +1242,54 @@ static void print_as_utf8(struct context* ctx) {
 	ink_pop(ctx);
 }

 struct ink_array {
    int top;
    int capacity;
    struct elem* elements;
 };

 static int get_type_by_name(struct context* ctx, const char* name) {
    int i;
    for(i = 0; i < ctx->types_top; ++i) {
        if(strcmp(ctx->types[i].name, name) == 0) {
            return i + 16;
        }
    }
    return -1;
 }

 static void collect_array(struct context* ctx, void* array) {
    struct ink_array* ary = array;
    ctx->free(ary->elements);
 }

 static struct ink_collection_list gc_array(struct context* ctx, void* array) {
    struct ink_array* ary = array;
    struct ink_collection_list c;
    c.elements = ctx->inner_malloc(sizeof(struct elem)*ary->top);
    c.count = ary->top;
    memcpy(c.elements, ary->elements, sizeof(struct elem)*ary->top);
    return c;
 }

 static void new_array(struct context* ctx) {
    int tid =  get_type_by_name(ctx, "array");
    struct ink_array ary;
    ary.elements = NULL;
    ary.top = 0;
    ary.capacity = 0;
    struct elem e = ink_make_native(ctx, tid, &ary);
    ink_push(ctx, e);
 }



 int ink_std_library(struct context* ctx) {
 	int v;
 	v = 0;
 	v += ink_add_native(ctx, "trace", print_stacktrace);
    int array_t = ink_new_type(ctx, "array", sizeof(struct ink_array), collect_array, gc_array);
    v += ink_add_native(ctx, "array", new_array);
    v += ink_add_native(ctx, "trace", print_stacktrace);
 	v += ink_add_native(ctx, "print_int", print_int);
 	v += ink_add_native(ctx, "print_utf8", print_as_utf8);
 	v += ink_add_native(ctx, "+", add_int);
--- a/main.c
+++ b/main.c
@ -24,6 +24,7 @@ int main(int argc, char** argv) {
 	while(ink_can_run(ctx)) {
 		ink_step_everyone(ctx);
 	}
 	printf("\nExecuted in %u steps\n", ctx->steps);
    ink_gc(ctx);
 	printf("\nExecuted in %u steps\nCollected %u times\n", ctx->steps, ctx->collections);
 	return ctx->panic;
 }
--- a/test/test02.nk
+++ b/test/test02.nk
@ -1,3 +1,5 @@
 fn print_n_utf8 do
    print_n_utf8_impl drop
 end

 array drop array drop
--- a/test/test03.nk
+++ b/test/test03.nk
@ -1 +1,9 @@
 4 potato2
 4 potato2

 fn u do

 loop:
    65 print_int
 loop 1 jump_if

 end
--- a/test/test04.nk
+++ b/test/test04.nk
@ -1 +1 @@
 4 potato3
 4 potato3