/** * @file NCDInterpProcess.c * @author Ambroz Bizjak * * @section LICENSE * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the author nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include "NCDInterpProcess.h" #include static int compute_prealloc (NCDInterpProcess *o) { int size = 0; for (int i = 0; i < o->num_stmts; i++) { int mod = size % BMAX_ALIGN; int align_size = (mod == 0 ? 0 : BMAX_ALIGN - mod); if (align_size + o->stmts[i].alloc_size > INT_MAX - size) { return 0; } o->stmts[i].prealloc_offset = size + align_size; size += align_size + o->stmts[i].alloc_size; } ASSERT(size >= 0) o->prealloc_size = size; return 1; } static int convert_value_recurser (NCDPlaceholderDb *pdb, NCDStringIndex *string_index, NCDValue *value, NCDValMem *mem, NCDValRef *out) { ASSERT(pdb) ASSERT(string_index) ASSERT((NCDValue_Type(value), 1)) ASSERT(mem) ASSERT(out) switch (NCDValue_Type(value)) { case NCDVALUE_STRING: { const char *str = NCDValue_StringValue(value); size_t len = NCDValue_StringLength(value); NCD_string_id_t string_id = NCDStringIndex_GetBin(string_index, str, len); if (string_id < 0) { BLog(BLOG_ERROR, "NCDStringIndex_GetBin failed"); goto fail; } *out = NCDVal_NewIdString(mem, string_id, string_index); if (NCDVal_IsInvalid(*out)) { goto fail; } } break; case NCDVALUE_LIST: { *out = NCDVal_NewList(mem, NCDValue_ListCount(value)); if (NCDVal_IsInvalid(*out)) { goto fail; } for (NCDValue *e = NCDValue_ListFirst(value); e; e = NCDValue_ListNext(value, e)) { NCDValRef vval; if (!convert_value_recurser(pdb, string_index, e, mem, &vval)) { goto fail; } if (!NCDVal_ListAppend(*out, vval)) { BLog(BLOG_ERROR, "depth limit exceeded"); goto fail; } } } break; case NCDVALUE_MAP: { *out = NCDVal_NewMap(mem, NCDValue_MapCount(value)); if (NCDVal_IsInvalid(*out)) { goto fail; } for (NCDValue *ekey = NCDValue_MapFirstKey(value); ekey; ekey = NCDValue_MapNextKey(value, ekey)) { NCDValue *eval = NCDValue_MapKeyValue(value, ekey); NCDValRef vkey; NCDValRef vval; if (!convert_value_recurser(pdb, string_index, ekey, mem, &vkey) || !convert_value_recurser(pdb, string_index, eval, mem, &vval) ) { goto fail; } int inserted; if (!NCDVal_MapInsert(*out, vkey, vval, &inserted)) { BLog(BLOG_ERROR, "depth limit exceeded"); goto fail; } if (!inserted) { BLog(BLOG_ERROR, "duplicate key in map"); goto fail; } } } break; case NCDVALUE_VAR: { int plid; if (!NCDPlaceholderDb_AddVariable(pdb, NCDValue_VarName(value), &plid)) { goto fail; } if (NCDVAL_MINIDX + plid >= -1) { goto fail; } *out = NCDVal_NewPlaceholder(mem, plid); } break; default: goto fail; } return 1; fail: return 0; } int NCDInterpProcess_Init (NCDInterpProcess *o, NCDProcess *process, NCDStringIndex *string_index, NCDPlaceholderDb *pdb, NCDModuleIndex *module_index) { ASSERT(process) ASSERT(string_index) ASSERT(pdb) ASSERT(module_index) NCDBlock *block = NCDProcess_Block(process); if (NCDBlock_NumStatements(block) > INT_MAX) { BLog(BLOG_ERROR, "too many statements"); goto fail0; } int num_stmts = NCDBlock_NumStatements(block); if (!(o->stmts = BAllocArray(num_stmts, sizeof(o->stmts[0])))) { BLog(BLOG_ERROR, "BAllocArray failed"); goto fail0; } o->num_hash_buckets = num_stmts; if (!(o->hash_buckets = BAllocArray(o->num_hash_buckets, sizeof(o->hash_buckets[0])))) { BLog(BLOG_ERROR, "BAllocArray failed"); goto fail1; } for (size_t i = 0; i < o->num_hash_buckets; i++) { o->hash_buckets[i] = -1; } if (!(o->name = b_strdup(NCDProcess_Name(process)))) { BLog(BLOG_ERROR, "b_strdup failed"); goto fail2; } o->num_stmts = 0; o->prealloc_size = -1; o->is_template = NCDProcess_IsTemplate(process); o->cache = NULL; for (NCDStatement *s = NCDBlock_FirstStatement(block); s; s = NCDBlock_NextStatement(block, s)) { ASSERT(NCDStatement_Type(s) == NCDSTATEMENT_REG) struct NCDInterpProcess__stmt *e = &o->stmts[o->num_stmts]; e->name = -1; e->objnames = NULL; e->num_objnames = 0; e->alloc_size = 0; if (NCDStatement_Name(s)) { e->name = NCDStringIndex_Get(string_index, NCDStatement_Name(s)); if (e->name < 0) { BLog(BLOG_ERROR, "NCDStringIndex_Get failed"); goto loop_fail0; } } e->cmdname = NCDStringIndex_Get(string_index, NCDStatement_RegCmdName(s)); if (e->cmdname < 0) { BLog(BLOG_ERROR, "NCDStringIndex_Get failed"); goto loop_fail0; } NCDValMem_Init(&e->arg_mem); NCDValRef val; if (!convert_value_recurser(pdb, string_index, NCDStatement_RegArgs(s), &e->arg_mem, &val)) { BLog(BLOG_ERROR, "convert_value_recurser failed"); goto loop_fail1; } e->arg_ref = NCDVal_ToSafe(val); if (!NCDValReplaceProg_Init(&e->arg_prog, val)) { BLog(BLOG_ERROR, "NCDValReplaceProg_Init failed"); goto loop_fail1; } if (NCDStatement_RegObjName(s)) { if (!ncd_make_name_indices(string_index, NCDStatement_RegObjName(s), &e->objnames, &e->num_objnames)) { BLog(BLOG_ERROR, "ncd_make_name_indices failed"); goto loop_fail2; } e->binding.method_name_id = NCDModuleIndex_GetMethodNameId(module_index, NCDStatement_RegCmdName(s)); if (e->binding.method_name_id == -1) { BLog(BLOG_ERROR, "NCDModuleIndex_GetMethodNameId failed"); goto loop_fail3; } } else { e->binding.simple_module = NCDModuleIndex_FindModule(module_index, NCDStatement_RegCmdName(s)); } if (e->name >= 0) { size_t bucket_idx = e->name % o->num_hash_buckets; e->hash_next = o->hash_buckets[bucket_idx]; o->hash_buckets[bucket_idx] = o->num_stmts; } o->num_stmts++; continue; loop_fail3: BFree(e->objnames); loop_fail2: NCDValReplaceProg_Free(&e->arg_prog); loop_fail1: NCDValMem_Free(&e->arg_mem); loop_fail0: goto fail3; } ASSERT(o->num_stmts == num_stmts) DebugObject_Init(&o->d_obj); return 1; fail3: while (o->num_stmts-- > 0) { struct NCDInterpProcess__stmt *e = &o->stmts[o->num_stmts]; BFree(e->objnames); NCDValReplaceProg_Free(&e->arg_prog); NCDValMem_Free(&e->arg_mem); } free(o->name); fail2: BFree(o->hash_buckets); fail1: BFree(o->stmts); fail0: return 0; } void NCDInterpProcess_Free (NCDInterpProcess *o) { DebugObject_Free(&o->d_obj); while (o->num_stmts-- > 0) { struct NCDInterpProcess__stmt *e = &o->stmts[o->num_stmts]; BFree(e->objnames); NCDValReplaceProg_Free(&e->arg_prog); NCDValMem_Free(&e->arg_mem); } free(o->name); BFree(o->hash_buckets); BFree(o->stmts); } int NCDInterpProcess_FindStatement (NCDInterpProcess *o, int from_index, NCD_string_id_t name) { DebugObject_Access(&o->d_obj); ASSERT(from_index >= 0) ASSERT(from_index <= o->num_stmts) size_t bucket_idx = name % o->num_hash_buckets; int stmt_idx = o->hash_buckets[bucket_idx]; ASSERT(stmt_idx >= -1) ASSERT(stmt_idx < o->num_stmts) while (stmt_idx >= 0) { if (stmt_idx < from_index && o->stmts[stmt_idx].name == name) { return stmt_idx; } stmt_idx = o->stmts[stmt_idx].hash_next; ASSERT(stmt_idx >= -1) ASSERT(stmt_idx < o->num_stmts) } return -1; } const char * NCDInterpProcess_StatementCmdName (NCDInterpProcess *o, int i, NCDStringIndex *string_index) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(string_index) return NCDStringIndex_Value(string_index, o->stmts[i].cmdname); } void NCDInterpProcess_StatementObjNames (NCDInterpProcess *o, int i, const NCD_string_id_t **out_objnames, size_t *out_num_objnames) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(out_objnames) ASSERT(out_num_objnames) *out_objnames = o->stmts[i].objnames; *out_num_objnames = o->stmts[i].num_objnames; } const struct NCDInterpModule * NCDInterpProcess_StatementGetSimpleModule (NCDInterpProcess *o, int i, NCDStringIndex *string_index, NCDModuleIndex *module_index) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(!o->stmts[i].objnames) struct NCDInterpProcess__stmt *e = &o->stmts[i]; if (!e->binding.simple_module) { const char *cmdname = NCDStringIndex_Value(string_index, e->cmdname); e->binding.simple_module = NCDModuleIndex_FindModule(module_index, cmdname); } return e->binding.simple_module; } const struct NCDInterpModule * NCDInterpProcess_StatementGetMethodModule (NCDInterpProcess *o, int i, NCD_string_id_t obj_type, NCDModuleIndex *module_index) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(o->stmts[i].objnames) ASSERT(obj_type >= 0) ASSERT(module_index) return NCDModuleIndex_GetMethodModule(module_index, obj_type, o->stmts[i].binding.method_name_id); } int NCDInterpProcess_CopyStatementArgs (NCDInterpProcess *o, int i, NCDValMem *out_valmem, NCDValRef *out_val, NCDValReplaceProg *out_prog) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(out_valmem) ASSERT(out_val) ASSERT(out_prog) struct NCDInterpProcess__stmt *e = &o->stmts[i]; if (!NCDValMem_InitCopy(out_valmem, &e->arg_mem)) { return 0; } *out_val = NCDVal_FromSafe(out_valmem, e->arg_ref); *out_prog = e->arg_prog; return 1; } void NCDInterpProcess_StatementBumpAllocSize (NCDInterpProcess *o, int i, int alloc_size) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(alloc_size >= 0) if (alloc_size > o->stmts[i].alloc_size) { o->stmts[i].alloc_size = alloc_size; o->prealloc_size = -1; } } int NCDInterpProcess_PreallocSize (NCDInterpProcess *o) { DebugObject_Access(&o->d_obj); ASSERT(o->prealloc_size == -1 || o->prealloc_size >= 0) if (o->prealloc_size < 0 && !compute_prealloc(o)) { return -1; } return o->prealloc_size; } int NCDInterpProcess_StatementPreallocSize (NCDInterpProcess *o, int i) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(o->prealloc_size >= 0) return o->stmts[i].alloc_size; } int NCDInterpProcess_StatementPreallocOffset (NCDInterpProcess *o, int i) { DebugObject_Access(&o->d_obj); ASSERT(i >= 0) ASSERT(i < o->num_stmts) ASSERT(o->prealloc_size >= 0) return o->stmts[i].prealloc_offset; } const char * NCDInterpProcess_Name (NCDInterpProcess *o) { DebugObject_Access(&o->d_obj); return o->name; } int NCDInterpProcess_IsTemplate (NCDInterpProcess *o) { DebugObject_Access(&o->d_obj); return o->is_template; } int NCDInterpProcess_NumStatements (NCDInterpProcess *o) { DebugObject_Access(&o->d_obj); return o->num_stmts; } int NCDInterpProcess_CachePush (NCDInterpProcess *o, void *elem) { DebugObject_Access(&o->d_obj); ASSERT(elem) if (o->cache) { return 0; } o->cache = elem; return 1; } void * NCDInterpProcess_CachePull (NCDInterpProcess *o) { DebugObject_Access(&o->d_obj); void *elem = o->cache; o->cache = NULL; return elem; }