/src/ghostpdl/psi/ireclaim.c

Source (jump to first uncovered line)
/* Copyright (C) 2001-2023 Artifex Software, Inc.
   All Rights Reserved.

   This software is provided AS-IS with no warranty, either express or
   implied.

   This software is distributed under license and may not be copied,
   modified or distributed except as expressly authorized under the terms
   of the license contained in the file LICENSE in this distribution.

   Refer to licensing information at http://www.artifex.com or contact
   Artifex Software, Inc.,  39 Mesa Street, Suite 108A, San Francisco,
   CA 94129, USA, for further information.
*/


/* Interpreter's interface to garbage collector */
#include "ghost.h"
#include "ierrors.h"
#include "gsstruct.h"
#include "iastate.h"
#include "icontext.h"
#include "interp.h"
#include "isave.h"    /* for isstate.h */
#include "isstate.h"    /* for mem->saved->state */
#include "dstack.h"   /* for dsbot, dsp, dict_set_top */
#include "estack.h"   /* for esbot, esp */
#include "ostack.h"   /* for osbot, osp */
#include "opdef.h"    /* for defining init procedure */
#include "store.h"    /* for make_array */

/* Import preparation and cleanup routines. */
extern void ialloc_gc_prepare(gs_ref_memory_t *);

/* Forward references */
static int gs_vmreclaim(gs_dual_memory_t *, bool);

/* Initialize the GC hook in the allocator. */
static int ireclaim(gs_dual_memory_t *, int);
static int
ireclaim_init(i_ctx_t *i_ctx_p)
{
    gs_imemory.reclaim = ireclaim;
    return 0;
}

/* GC hook called when the allocator signals a GC is needed (space = -1), */
/* or for vmreclaim (space = the space to collect). */
static int
ireclaim(gs_dual_memory_t * dmem, int space)
{
    bool global;
    gs_ref_memory_t *mem = NULL;
    int code;

    if (space < 0) {
        /* Determine which allocator exceeded the limit. */
        int i;

        for (i = 0; i < countof(dmem->spaces_indexed); i++) {
            mem = dmem->spaces_indexed[i];
            if (mem == 0)
                continue;
            if (mem->gc_status.requested > 0 ||
                ((gs_ref_memory_t *)mem->stable_memory)->gc_status.requested > 0
                )
                break;
        }
        if (!mem) {
            mem = dmem->space_global; /* just in case */
        }
    } else {
        mem = dmem->spaces_indexed[space >> r_space_shift];
    }
    if_debug3m('0', (gs_memory_t *)mem, "[0]GC called, space=%d, requestor=%d, requested=%ld\n",
               space, mem->space, (long)mem->gc_status.requested);
    global = mem->space != avm_local;
    /* Since dmem may move, reset the request now. */
    ialloc_reset_requested(dmem);
    code = gs_vmreclaim(dmem, global);
    if (code < 0)
        return code;
    ialloc_set_limit(mem);
    if (space < 0) {
        gs_memory_status_t stats;
        size_t allocated;

        /* If the ammount still allocated after the GC is complete */
        /* exceeds the max_vm setting, then return a VMerror       */
        gs_memory_status((gs_memory_t *) mem, &stats);
        allocated = stats.allocated;
        if (mem->stable_memory != (gs_memory_t *)mem) {
            gs_memory_status(mem->stable_memory, &stats);
            allocated += stats.allocated;
        }
        if (allocated >= mem->gc_status.max_vm) {
            /* We can't satisfy this request within max_vm. */
            return_error(gs_error_VMerror);
        }
    }
    return 0;
}

/* Interpreter entry to garbage collector. */
static int
gs_vmreclaim(gs_dual_memory_t *dmem, bool global)
{
    /* HACK: we know the gs_dual_memory_t is embedded in a context state. */
    i_ctx_t *i_ctx_p =
        (i_ctx_t *)((char *)dmem - offset_of(i_ctx_t, memory));
    gs_ref_memory_t *lmem = dmem->space_local;
    int code = context_state_store(i_ctx_p);
    gs_ref_memory_t *memories[5];
    gs_ref_memory_t *mem;
    int nmem, i;

    if (code < 0)
        return code;

    memories[0] = dmem->space_system;
    memories[1] = mem = dmem->space_global;
    nmem = 2;
    if (lmem != dmem->space_global)
        memories[nmem++] = lmem;
    for (i = nmem; --i >= 0;) {
        mem = memories[i];
        if (mem->stable_memory != (gs_memory_t *)mem)
            memories[nmem++] = (gs_ref_memory_t *)mem->stable_memory;
    }

    /****** ABORT IF code < 0 ******/
    for (i = nmem; --i >= 0; )
        alloc_close_clump(memories[i]);

    /* Prune the file list so it won't retain potentially collectible */
    /* files. */

    for (i = (global ? i_vm_system : i_vm_local);
         i < countof(dmem->spaces_indexed);
         ++i
         ) {
        gs_ref_memory_t *mem = dmem->spaces_indexed[i];

        /* Always safe to substract 1 from i here, as i is always at
         * least i_vm_system (1) or i_vm_local (2). */
        if (mem == 0 || (mem == dmem->spaces_indexed[i - 1]))
            continue;
        if (mem->stable_memory != (gs_memory_t *)mem)
            ialloc_gc_prepare((gs_ref_memory_t *)mem->stable_memory);
        for (;; mem = &mem->saved->state) {
            ialloc_gc_prepare(mem);
            if (mem->saved == 0)
                break;
        }
    }

    /* Do the actual collection. */

    {
        void *ctxp = i_ctx_p;
        gs_gc_root_t context_root, *r = &context_root;

        gs_register_struct_root((gs_memory_t *)lmem, &r,
                                &ctxp, "i_ctx_p root");
        GS_RECLAIM(&dmem->spaces, global);
        gs_unregister_root((gs_memory_t *)lmem, r, "i_ctx_p root");
        i_ctx_p = ctxp;
        dmem = &i_ctx_p->memory;
    }

    /* Update caches not handled by context_state_load. */

    *systemdict = *ref_stack_index(&d_stack, ref_stack_count(&d_stack) - 1);

    /* Update the cached value pointers in names. */

    dicts_gc_cleanup();

    /* Reopen the active clumps. */

    for (i = 0; i < nmem; ++i)
        alloc_open_clump(memories[i]);

    /* Reload the context state.  Note this should be done
       AFTER the clumps are reopened, since the context state
       load could do allocations that must remain.
       If it were done while the clumps were still closed,
       we would lose those allocations when the clumps were opened */

    code = context_state_load(i_ctx_p);
    return code;
}

/* ------ Initialization procedure ------ */

const op_def ireclaim_l2_op_defs[] =
{
    op_def_end(ireclaim_init)
};

Line	Count	Source (jump to first uncovered line)
1		/* Copyright (C) 2001-2023 Artifex Software, Inc.
2		All Rights Reserved.
3
4		This software is provided AS-IS with no warranty, either express or
5		implied.
6
7		This software is distributed under license and may not be copied,
8		modified or distributed except as expressly authorized under the terms
9		of the license contained in the file LICENSE in this distribution.
10
11		Refer to licensing information at http://www.artifex.com or contact
12		Artifex Software, Inc., 39 Mesa Street, Suite 108A, San Francisco,
13		CA 94129, USA, for further information.
14		*/
15
16
17		/* Interpreter's interface to garbage collector */
18		#include "ghost.h"
19		#include "ierrors.h"
20		#include "gsstruct.h"
21		#include "iastate.h"
22		#include "icontext.h"
23		#include "interp.h"
24		#include "isave.h" /* for isstate.h */
25		#include "isstate.h" /* for mem->saved->state */
26		#include "dstack.h" /* for dsbot, dsp, dict_set_top */
27		#include "estack.h" /* for esbot, esp */
28		#include "ostack.h" /* for osbot, osp */
29		#include "opdef.h" /* for defining init procedure */
30		#include "store.h" /* for make_array */
31
32		/* Import preparation and cleanup routines. */
33		extern void ialloc_gc_prepare(gs_ref_memory_t *);
34
35		/* Forward references */
36		static int gs_vmreclaim(gs_dual_memory_t *, bool);
37
38		/* Initialize the GC hook in the allocator. */
39		static int ireclaim(gs_dual_memory_t *, int);
40		static int
41		ireclaim_init(i_ctx_t *i_ctx_p)
42	159k	{
43	159k	gs_imemory.reclaim = ireclaim;
44	159k	return 0;
45	159k	}
46
47		/* GC hook called when the allocator signals a GC is needed (space = -1), */
48		/* or for vmreclaim (space = the space to collect). */
49		static int
50		ireclaim(gs_dual_memory_t * dmem, int space)
51	335k	{
52	335k	bool global;
53	335k	gs_ref_memory_t *mem = NULL;
54	335k	int code;
55
56	335k	if (space < 0) {
57		/* Determine which allocator exceeded the limit. */
58	15.1k	int i;
59
60	60.2k	for (i = 0; i < countof(dmem->spaces_indexed); i++) {
61	60.2k	mem = dmem->spaces_indexed[i];
62	60.2k	if (mem == 0)
63	15.1k	continue;
64	45.1k	if (mem->gc_status.requested > 0 \|\|
65	45.1k	((gs_ref_memory_t *)mem->stable_memory)->gc_status.requested > 0
66	45.1k	)
67	15.1k	break;
68	45.1k	}
69	15.1k	if (!mem) {
70	0	mem = dmem->space_global; /* just in case */
71	0	}
72	319k	} else {
73	319k	mem = dmem->spaces_indexed[space >> r_space_shift];
74	319k	}
75	335k	if_debug3m('0', (gs_memory_t *)mem, "[0]GC called, space=%d, requestor=%d, requested=%ld\n",
76	335k	space, mem->space, (long)mem->gc_status.requested);
77	335k	global = mem->space != avm_local;
78		/* Since dmem may move, reset the request now. */
79	335k	ialloc_reset_requested(dmem);
80	335k	code = gs_vmreclaim(dmem, global);
81	335k	if (code < 0)
82	0	return code;
83	335k	ialloc_set_limit(mem);
84	335k	if (space < 0) {
85	15.1k	gs_memory_status_t stats;
86	15.1k	size_t allocated;
87
88		/* If the ammount still allocated after the GC is complete */
89		/* exceeds the max_vm setting, then return a VMerror */
90	15.1k	gs_memory_status((gs_memory_t *) mem, &stats);
91	15.1k	allocated = stats.allocated;
92	15.1k	if (mem->stable_memory != (gs_memory_t *)mem) {
93	15.1k	gs_memory_status(mem->stable_memory, &stats);
94	15.1k	allocated += stats.allocated;
95	15.1k	}
96	15.1k	if (allocated >= mem->gc_status.max_vm) {
97		/* We can't satisfy this request within max_vm. */
98	0	return_error(gs_error_VMerror);
99	0	}
100	15.1k	}
101	335k	return 0;
102	335k	}
103
104		/* Interpreter entry to garbage collector. */
105		static int
106		gs_vmreclaim(gs_dual_memory_t *dmem, bool global)
107	335k	{
108		/* HACK: we know the gs_dual_memory_t is embedded in a context state. */
109	335k	i_ctx_t *i_ctx_p =
110	335k	(i_ctx_t )((char )dmem - offset_of(i_ctx_t, memory));
111	335k	gs_ref_memory_t *lmem = dmem->space_local;
112	335k	int code = context_state_store(i_ctx_p);
113	335k	gs_ref_memory_t *memories[5];
114	335k	gs_ref_memory_t *mem;
115	335k	int nmem, i;
116
117	335k	if (code < 0)
118	0	return code;
119
120	335k	memories[0] = dmem->space_system;
121	335k	memories[1] = mem = dmem->space_global;
122	335k	nmem = 2;
123	335k	if (lmem != dmem->space_global)
124	335k	memories[nmem++] = lmem;
125	1.34M	for (i = nmem; --i >= 0;) {
126	1.00M	mem = memories[i];
127	1.00M	if (mem->stable_memory != (gs_memory_t *)mem)
128	670k	memories[nmem++] = (gs_ref_memory_t *)mem->stable_memory;
129	1.00M	}
130
131		/**** ABORT IF code < 0 ****/
132	2.01M	for (i = nmem; --i >= 0; )
133	1.67M	alloc_close_clump(memories[i]);
134
135		/* Prune the file list so it won't retain potentially collectible */
136		/* files. */
137
138	335k	for (i = (global ? i_vm_system : i_vm_local);
139	1.31M	i < countof(dmem->spaces_indexed);
140	975k	++i
141	975k	) {
142	975k	gs_ref_memory_t *mem = dmem->spaces_indexed[i];
143
144		/* Always safe to substract 1 from i here, as i is always at
145		* least i_vm_system (1) or i_vm_local (2). */
146	975k	if (mem == 0 \|\| (mem == dmem->spaces_indexed[i - 1]))
147	0	continue;
148	975k	if (mem->stable_memory != (gs_memory_t *)mem)
149	655k	ialloc_gc_prepare((gs_ref_memory_t *)mem->stable_memory);
150	5.40M	for (;; mem = &mem->saved->state) {
151	5.40M	ialloc_gc_prepare(mem);
152	5.40M	if (mem->saved == 0)
153	975k	break;
154	5.40M	}
155	975k	}
156
157		/* Do the actual collection. */
158
159	335k	{
160	335k	void *ctxp = i_ctx_p;
161	335k	gs_gc_root_t context_root, *r = &context_root;
162
163	335k	gs_register_struct_root((gs_memory_t *)lmem, &r,
164	335k	&ctxp, "i_ctx_p root");
165	335k	GS_RECLAIM(&dmem->spaces, global);
166	335k	gs_unregister_root((gs_memory_t *)lmem, r, "i_ctx_p root");
167	335k	i_ctx_p = ctxp;
168	335k	dmem = &i_ctx_p->memory;
169	335k	}
170
171		/* Update caches not handled by context_state_load. */
172
173	335k	systemdict = ref_stack_index(&d_stack, ref_stack_count(&d_stack) - 1);
174
175		/* Update the cached value pointers in names. */
176
177	335k	dicts_gc_cleanup();
178
179		/* Reopen the active clumps. */
180
181	2.01M	for (i = 0; i < nmem; ++i)
182	1.67M	alloc_open_clump(memories[i]);
183
184		/* Reload the context state. Note this should be done
185		AFTER the clumps are reopened, since the context state
186		load could do allocations that must remain.
187		If it were done while the clumps were still closed,
188		we would lose those allocations when the clumps were opened */
189
190	335k	code = context_state_load(i_ctx_p);
191	335k	return code;
192	335k	}
193
194		/* ------ Initialization procedure ------ */
195
196		const op_def ireclaim_l2_op_defs[] =
197		{
198		op_def_end(ireclaim_init)
199		};

Coverage Report

Created: 2025-06-10 07:27