/** * @file call2.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. * * @section DESCRIPTION * * Synopsis: * call(string template, list args) * * Description: * Calls a process template. The 'template' argument is the name of the process * template to call, and the 'list' argument is a list of arguments for the * process template. Calling a process template is roughly equivalent to placing * the statements within that template into the place of call(), except for the * points presented next. The 'template' argument can be a special value "", * which makes call() a no-op. * * The process created from the called template will be able to access the arguments * that were given in the 'args' argument to call() via the '_argN' predefined\ * objects (e.g. _arg0 for the first argumens), and also via '_args' for the entire * argument list. * * The called process also will be able to access objects within the calling * process as seen by the call() statement. However such any access needs to happen * via a special '_caller' predefined object. For example, if there is a statement * 'var("a") x;' somewhere above the call() statement, the called process can access * it as '_caller.x'. * * Note that call() preserves backtracking semantics, i.e. when a statement within * the called process goes down after having gone up, the behaviour really is as * if the call() statement was replaced with the statements in the called template, * (disregarding variable resolution). * * Because the template name is an argument, call() can be used for branching. * For example, if we have an object 'x' with the value "true" or "false", a * branch can be performed by defining two process templates, 'branch_true' * and 'branch_false', and branching with the following code: * * concat("branch_", x) name; * call(name, {}); * * Synopsis: * call_with_caller_target(string template, list args, string caller_target) * * Description: * Like call(), except that the target of the '_caller' predefined object is * specified by the 'caller_target' argument. This is indented to be used from * generic code for user-specified callbacks, allowing the user to easily refer to * his own objects from inside the callback. * * The 'caller_target' must be a non-empty string referring to an actual object; * there is no choice of 'caller_target' that would make call_with_caller_target() * equivalent to call(). * * Synopsis: * embcall2_multif(string cond1, string template1, ..., [string else_template]) * * Description: * This is an internal command used to implement the 'If' clause. The arguments * are pairs of (cond, template), where 'cond' is a condition in form of a string, * and 'template' is the name of the process template for this condition. The * template corresponding to the first condition equal to "true" is called; if * there is no true condition, either the template 'else_template' is called, * if it is provided, or nothing is performed, if 'else_template' is not provided. */ #include #include #include #include #include #include #include #include #define ModuleLog(i, ...) NCDModuleInst_Backend_Log((i), BLOG_CURRENT_CHANNEL, __VA_ARGS__) #define STATE_WORKING 1 #define STATE_UP 2 #define STATE_WAITING 3 #define STATE_TERMINATING 4 #define STATE_NONE 5 #define NUM_STATIC_NAMES 4 struct instance { NCDModuleInst *i; NCDModuleProcess process; int state; }; struct instance_with_caller_target { struct instance base; NCD_string_id_t *dynamic_names; size_t num_names; NCD_string_id_t static_names[NUM_STATIC_NAMES]; }; #define NAMES_PARAM_NAME CallNames #define NAMES_PARAM_TYPE struct instance_with_caller_target #define NAMES_PARAM_MEMBER_DYNAMIC_NAMES dynamic_names #define NAMES_PARAM_MEMBER_STATIC_NAMES static_names #define NAMES_PARAM_MEMBER_NUM_NAMES num_names #define NAMES_PARAM_NUM_STATIC_NAMES NUM_STATIC_NAMES #include static void process_handler_event (NCDModuleProcess *process, int event); static int process_func_getspecialobj_embed (NCDModuleProcess *process, NCD_string_id_t name, NCDObject *out_object); static int process_func_getspecialobj_noembed (NCDModuleProcess *process, NCD_string_id_t name, NCDObject *out_object); static int process_func_getspecialobj_with_caller_target (NCDModuleProcess *process, NCD_string_id_t name, NCDObject *out_object); static int caller_obj_func_getobj (const NCDObject *obj, NCD_string_id_t name, NCDObject *out_object); static int caller_obj_func_getobj_with_caller_target (const NCDObject *obj, NCD_string_id_t name, NCDObject *out_object); static void func_new_templ (void *vo, NCDModuleInst *i, NCDValRef template_name, NCDValRef args, int embed); static void instance_free (struct instance *o); static void process_handler_event (NCDModuleProcess *process, int event) { struct instance *o = UPPER_OBJECT(process, struct instance, process); switch (event) { case NCDMODULEPROCESS_EVENT_UP: { ASSERT(o->state == STATE_WORKING) // signal up NCDModuleInst_Backend_Up(o->i); // set state up o->state = STATE_UP; } break; case NCDMODULEPROCESS_EVENT_DOWN: { ASSERT(o->state == STATE_UP) // signal down NCDModuleInst_Backend_Down(o->i); // set state waiting o->state = STATE_WAITING; } break; case NCDMODULEPROCESS_EVENT_TERMINATED: { ASSERT(o->state == STATE_TERMINATING) // die finally instance_free(o); return; } break; default: ASSERT(0); } } static int process_func_getspecialobj_embed (NCDModuleProcess *process, NCD_string_id_t name, NCDObject *out_object) { struct instance *o = UPPER_OBJECT(process, struct instance, process); return NCDModuleInst_Backend_GetObj(o->i, name, out_object); } static int process_func_getspecialobj_noembed (NCDModuleProcess *process, NCD_string_id_t name, NCDObject *out_object) { struct instance *o = UPPER_OBJECT(process, struct instance, process); if (name == NCD_STRING_CALLER) { *out_object = NCDObject_Build(-1, o, NCDObject_no_getvar, caller_obj_func_getobj); return 1; } return 0; } static int process_func_getspecialobj_with_caller_target (NCDModuleProcess *process, NCD_string_id_t name, NCDObject *out_object) { struct instance *o = UPPER_OBJECT(process, struct instance, process); if (name == NCD_STRING_CALLER) { *out_object = NCDObject_Build(-1, o, NCDObject_no_getvar, caller_obj_func_getobj_with_caller_target); return 1; } return 0; } static int caller_obj_func_getobj (const NCDObject *obj, NCD_string_id_t name, NCDObject *out_object) { struct instance *o = NCDObject_DataPtr(obj); return NCDModuleInst_Backend_GetObj(o->i, name, out_object); } static int caller_obj_func_getobj_with_caller_target (const NCDObject *obj, NCD_string_id_t name, NCDObject *out_object) { struct instance_with_caller_target *o_ch = NCDObject_DataPtr(obj); ASSERT(o_ch->num_names > 0) NCD_string_id_t *names = CallNames_GetNames(o_ch); NCDObject object; if (!NCDModuleInst_Backend_GetObj(o_ch->base.i, names[0], &object)) { return 0; } NCDObject obj2; if (!NCDObject_ResolveObjExprCompact(&object, names + 1, o_ch->num_names - 1, &obj2)) { return 0; } if (name == NCD_STRING_EMPTY) { *out_object = obj2; return 1; } return NCDObject_GetObj(&obj2, name, out_object); } static void func_new_templ (void *vo, NCDModuleInst *i, NCDValRef template_name, NCDValRef args, int embed) { ASSERT(NCDVal_IsInvalid(template_name) || NCDVal_IsString(template_name)) ASSERT(NCDVal_IsInvalid(args) || NCDVal_IsList(args)) ASSERT(embed == !!embed) struct instance *o = vo; o->i = i; if (NCDVal_IsInvalid(template_name) || ncd_is_none(template_name)) { // signal up NCDModuleInst_Backend_Up(o->i); // set state none o->state = STATE_NONE; } else { // create process if (!NCDModuleProcess_InitValue(&o->process, o->i, template_name, args, process_handler_event)) { ModuleLog(o->i, BLOG_ERROR, "NCDModuleProcess_Init failed"); goto fail0; } // set special functions if (embed) { NCDModuleProcess_SetSpecialFuncs(&o->process, process_func_getspecialobj_embed); } else { NCDModuleProcess_SetSpecialFuncs(&o->process, process_func_getspecialobj_noembed); } // set state working o->state = STATE_WORKING; } return; fail0: NCDModuleInst_Backend_DeadError(i); } static void instance_free (struct instance *o) { // free process if (o->state != STATE_NONE) { NCDModuleProcess_Free(&o->process); } NCDModuleInst_Backend_Dead(o->i); } static void func_new_call (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params) { NCDValRef template_arg; NCDValRef args_arg; if (!NCDVal_ListRead(params->args, 2, &template_arg, &args_arg)) { ModuleLog(i, BLOG_ERROR, "wrong arity"); goto fail0; } if (!NCDVal_IsString(template_arg) || !NCDVal_IsList(args_arg)) { ModuleLog(i, BLOG_ERROR, "wrong type"); goto fail0; } func_new_templ(vo, i, template_arg, args_arg, 0); return; fail0: NCDModuleInst_Backend_DeadError(i); } static void func_new_call_with_caller_target (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params) { struct instance *o = vo; struct instance_with_caller_target *o_ct = vo; o->i = i; NCDValRef template_arg; NCDValRef args_arg; NCDValRef caller_target_arg; if (!NCDVal_ListRead(params->args, 3, &template_arg, &args_arg, &caller_target_arg)) { ModuleLog(i, BLOG_ERROR, "wrong arity"); goto fail0; } if (!NCDVal_IsString(template_arg) || !NCDVal_IsList(args_arg) || !NCDVal_IsString(caller_target_arg)) { ModuleLog(i, BLOG_ERROR, "wrong type"); goto fail0; } NCDValContString cts; if (!NCDVal_StringContinuize(caller_target_arg, &cts)) { ModuleLog(i, BLOG_ERROR, "NCDVal_StringContinuize failed"); goto fail0; } int res = CallNames_InitNames(o_ct, i->params->iparams->string_index, cts.data, NCDVal_StringLength(caller_target_arg)); NCDValContString_Free(&cts); if (!res) { ModuleLog(i, BLOG_ERROR, "CallerNames_InitNames failed"); goto fail0; } if (ncd_is_none(template_arg)) { // signal up NCDModuleInst_Backend_Up(i); // set state none o->state = STATE_NONE; } else { // create process if (!NCDModuleProcess_InitValue(&o->process, i, template_arg, args_arg, process_handler_event)) { ModuleLog(i, BLOG_ERROR, "NCDModuleProcess_Init failed"); goto fail1; } // set special functions NCDModuleProcess_SetSpecialFuncs(&o->process, process_func_getspecialobj_with_caller_target); // set state working o->state = STATE_WORKING; } return; fail1: CallNames_FreeNames(o_ct); fail0: NCDModuleInst_Backend_DeadError(i); } static void func_new_embcall_multif (void *vo, NCDModuleInst *i, const struct NCDModuleInst_new_params *params) { NCDValRef args = params->args; NCDValRef template_value = NCDVal_NewInvalid(); size_t count = NCDVal_ListCount(args); size_t j = 0; while (j < count) { NCDValRef arg = NCDVal_ListGet(args, j); if (j == count - 1) { if (!NCDVal_IsString(arg)) { ModuleLog(i, BLOG_ERROR, "bad arguments"); goto fail0; } template_value = arg; break; } NCDValRef arg2 = NCDVal_ListGet(args, j + 1); if (!NCDVal_IsString(arg) || !NCDVal_IsString(arg2)) { ModuleLog(i, BLOG_ERROR, "bad arguments"); goto fail0; } if (ncd_read_boolean(arg)) { template_value = arg2; break; } j += 2; } func_new_templ(vo, i, template_value, NCDVal_NewInvalid(), 1); return; fail0: NCDModuleInst_Backend_DeadError(i); } static void func_die (void *vo) { struct instance *o = vo; ASSERT(o->state != STATE_TERMINATING) // if none, die now if (o->state == STATE_NONE) { instance_free(o); return; } // request process to terminate NCDModuleProcess_Terminate(&o->process); // set state terminating o->state = STATE_TERMINATING; } static void func_die_with_caller_target (void *vo) { struct instance_with_caller_target *o_ct = vo; CallNames_FreeNames(o_ct); func_die(vo); } static void func_clean (void *vo) { struct instance *o = vo; if (o->state != STATE_WAITING) { return; } // allow process to continue NCDModuleProcess_Continue(&o->process); // set state working o->state = STATE_WORKING; } static int func_getobj (void *vo, NCD_string_id_t name, NCDObject *out_object) { struct instance *o = vo; if (o->state == STATE_NONE) { return 0; } return NCDModuleProcess_GetObj(&o->process, name, out_object); } static struct NCDModule modules[] = { { .type = "call", .func_new2 = func_new_call, .func_die = func_die, .func_clean = func_clean, .func_getobj = func_getobj, .flags = NCDMODULE_FLAG_CAN_RESOLVE_WHEN_DOWN|NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS, .alloc_size = sizeof(struct instance) }, { .type = "call_with_caller_target", .func_new2 = func_new_call_with_caller_target, .func_die = func_die_with_caller_target, .func_clean = func_clean, .func_getobj = func_getobj, .flags = NCDMODULE_FLAG_CAN_RESOLVE_WHEN_DOWN|NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS, .alloc_size = sizeof(struct instance_with_caller_target) }, { .type = "embcall2_multif", .func_new2 = func_new_embcall_multif, .func_die = func_die, .func_clean = func_clean, .func_getobj = func_getobj, .flags = NCDMODULE_FLAG_CAN_RESOLVE_WHEN_DOWN|NCDMODULE_FLAG_ACCEPT_NON_CONTINUOUS_STRINGS, .alloc_size = sizeof(struct instance) }, { .type = NULL } }; const struct NCDModuleGroup ncdmodule_call2 = { .modules = modules };