/* * This file is part of the sigrok project. * * Copyright (C) 2010 Uwe Hermann * Copyright (C) 2012 Bert Vermeulen * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "sigrokdecode.h" /* First, so we avoid a _POSIX_C_SOURCE warning. */ #include "sigrokdecode-internal.h" #include "config.h" #include #include #include /* List of decoder instances. */ static GSList *di_list = NULL; /* List of frontend callbacks to receive PD output. */ static GSList *callbacks = NULL; /* lives in decoder.c */ extern GSList *pd_list; /* lives in module_sigrokdecode.c */ extern PyMODINIT_FUNC PyInit_sigrokdecode(void); /* lives in type_logic.c */ extern PyTypeObject srd_logic_type; /** * Initialize libsigrokdecode. * * This initializes the Python interpreter, and creates and initializes * a "sigrok" Python module with a single put() method. * * Then, it searches for sigrok protocol decoder files (*.py) in the * "decoders" subdirectory of the the sigrok installation directory. * All decoders that are found are loaded into memory and added to an * internal list of decoders, which can be queried via srd_list_decoders(). * * The caller is responsible for calling the clean-up function srd_exit(), * which will properly shut down libsigrokdecode and free its allocated memory. * * Multiple calls to srd_init(), without calling srd_exit() in between, * are not allowed. * * @return SRD_OK upon success, a (negative) error code otherwise. * Upon Python errors, return SRD_ERR_PYTHON. If the sigrok decoders * directory cannot be accessed, return SRD_ERR_DECODERS_DIR. * If not enough memory could be allocated, return SRD_ERR_MALLOC. */ int srd_init(void) { int ret; srd_dbg("srd: initializing"); /* Add our own module to the list of built-in modules. */ PyImport_AppendInittab("sigrokdecode", PyInit_sigrokdecode); /* Initialize the python interpreter. */ Py_Initialize(); if ((ret = set_modulepath()) != SRD_OK) { Py_Finalize(); return ret; } if ((ret = srd_load_all_decoders()) != SRD_OK) { Py_Finalize(); return ret; } return SRD_OK; } /** * Shutdown libsigrokdecode. * * This frees all the memory allocated for protocol decoders and shuts down * the Python interpreter. * * This function should only be called if there was a (successful!) invocation * of srd_init() before. Calling this function multiple times in a row, without * any successful srd_init() calls in between, is not allowed. * * @return SRD_OK upon success, a (negative) error code otherwise. */ int srd_exit(void) { srd_dbg("srd: exiting"); srd_unload_all_decoders(); g_slist_free(pd_list); /* Py_Finalize() returns void, any finalization errors are ignored. */ Py_Finalize(); return SRD_OK; } /** * Add search directories for the protocol decoders. * * TODO: add path from env var SIGROKDECODE_PATH, config etc * TODO: Should take directoryname/path as input. */ int set_modulepath(void) { int ret; gchar *path, *s; #ifdef _WIN32 gchar **splitted; /* * On Windows/MinGW, Python's sys.path needs entries of the form * 'C:\\foo\\bar' instead of '/foo/bar'. */ splitted = g_strsplit(DECODERS_DIR, "/", 0); path = g_build_pathv("\\\\", splitted); g_strfreev(splitted); #else path = g_strdup(DECODERS_DIR); #endif /* TODO: Prepend instead of appending. */ /* TODO: Sanity check on 'path' (length, escape special chars, ...). */ s = g_strdup_printf("import sys; sys.path.append(r'%s')", path); ret = PyRun_SimpleString(s); g_free(path); g_free(s); return ret; } /** * Set options in a decoder instance. * * @param di Decoder instance. * @param options A GHashTable of options to set. * * Handled options are removed from the hash. * * @return SRD_OK upon success, a (negative) error code otherwise. */ int srd_instance_set_options(struct srd_decoder_instance *di, GHashTable *options) { PyObject *py_dec_options, *py_dec_optkeys, *py_di_options, *py_optval; PyObject *py_optlist, *py_classval; Py_UNICODE *py_ustr; unsigned long long int val_ull; int num_optkeys, ret, size, i; char *key, *value; if(!PyObject_HasAttrString(di->decoder->py_dec, "options")) { /* Decoder has no options. */ if (g_hash_table_size(options) == 0) { /* No options provided. */ return SRD_OK; } else { srd_err("Protocol decoder has no options."); return SRD_ERR_ARG; } return SRD_OK; } ret = SRD_ERR_PYTHON; key = NULL; py_dec_options = py_dec_optkeys = py_di_options = py_optval = NULL; py_optlist = py_classval = NULL; py_dec_options = PyObject_GetAttrString(di->decoder->py_dec, "options"); /* All of these are synthesized objects, so they're good. */ py_dec_optkeys = PyDict_Keys(py_dec_options); num_optkeys = PyList_Size(py_dec_optkeys); if (!(py_di_options = PyObject_GetAttrString(di->py_instance, "options"))) goto err_out; for (i = 0; i < num_optkeys; i++) { /* Get the default class value for this option. */ py_str_as_str(PyList_GetItem(py_dec_optkeys, i), &key); if (!(py_optlist = PyDict_GetItemString(py_dec_options, key))) goto err_out; if (!(py_classval = PyList_GetItem(py_optlist, 1))) goto err_out; if (!PyUnicode_Check(py_classval) && !PyLong_Check(py_classval)) { srd_err("Options of type %s are not yet supported.", Py_TYPE(py_classval)->tp_name); goto err_out; } if ((value = g_hash_table_lookup(options, key))) { /* An override for this option was provided. */ if (PyUnicode_Check(py_classval)) { if (!(py_optval = PyUnicode_FromString(value))) { /* Some UTF-8 encoding error. */ PyErr_Clear(); goto err_out; } } else if (PyLong_Check(py_classval)) { if (!(py_optval = PyLong_FromString(value, NULL, 0))) { /* ValueError Exception */ PyErr_Clear(); srd_err("Option %s has invalid value %s: expected integer.", key, value); goto err_out; } } g_hash_table_remove(options, key); } else { /* Use the class default for this option. */ if (PyUnicode_Check(py_classval)) { /* Make a brand new copy of the string. */ py_ustr = PyUnicode_AS_UNICODE(py_classval); size = PyUnicode_GET_SIZE(py_classval); py_optval = PyUnicode_FromUnicode(py_ustr, size); } else if (PyLong_Check(py_classval)) { /* Make a brand new copy of the integer. */ val_ull = PyLong_AsUnsignedLongLong(py_classval); if (val_ull == (unsigned long long)-1) { /* OverFlowError exception */ PyErr_Clear(); srd_err("Invalid integer value for %s: expected integer.", key); goto err_out; } if (!(py_optval = PyLong_FromUnsignedLongLong(val_ull))) goto err_out; } } /* If we got here, py_optval holds a known good new reference * to the instance option to set. */ if (PyDict_SetItemString(py_di_options, key, py_optval) == -1) goto err_out; } ret = SRD_OK; err_out: Py_XDECREF(py_optlist); Py_XDECREF(py_di_options); Py_XDECREF(py_dec_optkeys); Py_XDECREF(py_dec_options); if (key) g_free(key); if (PyErr_Occurred()) { srd_dbg("srd: stray exception!"); PyErr_Print(); PyErr_Clear(); } return ret; } static gint compare_probe_id(struct srd_probe *a, char *probe_id) { return strcmp(a->id, probe_id); } /** * Set probes in a decoder instance. * * @param di Decoder instance. * @param probes A GHashTable of probes to set. Key is probe name, value is * the probe number. Samples passed to this instance will be arranged in this * order. * * @return SRD_OK upon success, a (negative) error code otherwise. */ int srd_instance_set_probes(struct srd_decoder_instance *di, GHashTable *new_probes) { GList *l; GSList *sl; struct srd_probe *p; int *new_probemap, new_probenum; char *probe_id; if (g_hash_table_size(new_probes) == 0) /* No probes provided. */ return SRD_OK; if(di->dec_num_probes == 0) { /* Decoder has no probes. */ srd_err("Protocol decoder %s has no probes to define.", di->decoder->name); return SRD_ERR_ARG; } new_probemap = NULL; if (!(new_probemap = g_try_malloc(sizeof(int) * di->dec_num_probes))) { srd_err("Failed to malloc new probe map."); return SRD_ERR_MALLOC; } for (l = g_hash_table_get_keys(new_probes); l; l = l->next) { probe_id = l->data; new_probenum = strtol(g_hash_table_lookup(new_probes, probe_id), NULL, 10); if (!(sl = g_slist_find_custom(di->decoder->probes, probe_id, (GCompareFunc)compare_probe_id))) { /* Fall back on optional probes. */ if (!(sl = g_slist_find_custom(di->decoder->extra_probes, probe_id, (GCompareFunc)compare_probe_id))) { srd_err("Protocol decoder %s has no probe '%s'.", di->decoder->name, probe_id); g_free(new_probemap); return SRD_ERR_ARG; } } p = sl->data; new_probemap[p->order] = new_probenum; } g_free(di->dec_probemap); di->dec_probemap = new_probemap; return SRD_OK; } /** * Create a new protocol decoder instance. * * @param id Decoder 'id' field. * @param options GHashtable of options which override the defaults set in * the decoder class. * @return Pointer to a newly allocated struct srd_decoder_instance, or * NULL in case of failure. */ struct srd_decoder_instance *srd_instance_new(const char *decoder_id, GHashTable *options) { struct srd_decoder *dec; struct srd_decoder_instance *di; int i; char *instance_id; srd_dbg("srd: creating new %s instance", decoder_id); if (!(dec = srd_get_decoder_by_id(decoder_id))) { srd_err("Protocol decoder %s not found.", decoder_id); return NULL; } if (!(di = g_try_malloc0(sizeof(*di)))) { srd_err("Failed to malloc instance."); return NULL; } instance_id = g_hash_table_lookup(options, "id"); di->decoder = dec; di->instance_id = g_strdup(instance_id ? instance_id : decoder_id); g_hash_table_remove(options, "id"); /* Prepare a default probe map, where samples come in the * order in which the decoder class defined them. */ di->dec_num_probes = g_slist_length(di->decoder->probes) + g_slist_length(di->decoder->extra_probes); if (di->dec_num_probes) { if (!(di->dec_probemap = g_try_malloc(sizeof(int) * di->dec_num_probes))) { srd_err("Failed to malloc probe map."); g_free(di); return NULL; } for (i = 0; i < di->dec_num_probes; i++) di->dec_probemap[i] = i; } /* Create a new instance of this decoder class. */ if (!(di->py_instance = PyObject_CallObject(dec->py_dec, NULL))) { if (PyErr_Occurred()) PyErr_Print(); g_free(di->dec_probemap); g_free(di); return NULL; } if (srd_instance_set_options(di, options) != SRD_OK) { g_free(di->dec_probemap); g_free(di); return NULL; } /* Instance takes input from a frontend by default. */ di_list = g_slist_append(di_list, di); return di; } int srd_instance_stack(struct srd_decoder_instance *di_from, struct srd_decoder_instance *di_to) { if (!di_from || !di_to) { srd_err("Invalid from/to instance pair."); return SRD_ERR_ARG; } if (!g_slist_find(di_list, di_from)) { srd_err("Unstacked instance not found."); return SRD_ERR_ARG; } /* Remove from the unstacked list. */ di_list = g_slist_remove(di_list, di_to); /* Stack on top of source di. */ di_from->next_di = g_slist_append(di_from->next_di, di_to); return SRD_OK; } /* TODO: this should go into the PD stack */ struct srd_decoder_instance *srd_instance_find(char *instance_id) { GSList *l; struct srd_decoder_instance *tmp, *di; di = NULL; for (l = di_list; l; l = l->next) { tmp = l->data; if (!strcmp(tmp->instance_id, instance_id)) { di = tmp; break; } } return di; } int srd_instance_start(struct srd_decoder_instance *di, PyObject *args) { PyObject *py_name, *py_res; srd_dbg("srd: calling start() method on protocol decoder instance %s", di->instance_id); if (!(py_name = PyUnicode_FromString("start"))) { srd_err("Unable to build python object for 'start'."); if (PyErr_Occurred()) PyErr_Print(); return SRD_ERR_PYTHON; } if (!(py_res = PyObject_CallMethodObjArgs(di->py_instance, py_name, args, NULL))) { if (PyErr_Occurred()) PyErr_Print(); return SRD_ERR_PYTHON; } Py_DecRef(py_res); Py_DecRef(py_name); return SRD_OK; } /** * Run the specified decoder function. * * @param start_samplenum The starting sample number for the buffer's sample * set, relative to the start of capture. * @param di The decoder instance to call. * @param inbuf The buffer to decode. * @param inbuflen Length of the buffer. * * @return SRD_OK upon success, a (negative) error code otherwise. */ int srd_instance_decode(uint64_t start_samplenum, struct srd_decoder_instance *di, uint8_t *inbuf, uint64_t inbuflen) { PyObject *py_res; srd_logic *logic; uint64_t end_samplenum; srd_dbg("srd: calling decode() on instance %s with %d bytes starting " "at sample %d", di->instance_id, inbuflen, start_samplenum); /* Return an error upon unusable input. */ if (di == NULL) { srd_dbg("srd: empty decoder instance"); return SRD_ERR_ARG; } if (inbuf == NULL) { srd_dbg("srd: NULL buffer pointer"); return SRD_ERR_ARG; } if (inbuflen == 0) { srd_dbg("srd: empty buffer"); return SRD_ERR_ARG; } /* Create new srd_logic object. Each iteration around the PD's loop * will fill one sample into this object. */ logic = PyObject_New(srd_logic, &srd_logic_type); Py_INCREF(logic); logic->di = di; logic->start_samplenum = start_samplenum; logic->itercnt = 0; logic->inbuf = inbuf; logic->inbuflen = inbuflen; logic->sample = PyList_New(2); Py_INCREF(logic->sample); Py_IncRef(di->py_instance); end_samplenum = start_samplenum + inbuflen / di->data_unitsize; if (!(py_res = PyObject_CallMethod(di->py_instance, "decode", "KKO", logic->start_samplenum, end_samplenum, logic))) { if (PyErr_Occurred()) PyErr_Print(); /* Returns void. */ return SRD_ERR_PYTHON; /* TODO: More specific error? */ } Py_DecRef(py_res); return SRD_OK; } int srd_session_start(int num_probes, int unitsize, uint64_t samplerate) { PyObject *args; GSList *d, *s; struct srd_decoder_instance *di; int ret; srd_dbg("srd: calling start() on all instances with %d probes, " "unitsize %d samplerate %d", num_probes, unitsize, samplerate); /* Currently only one item of metadata is passed along to decoders, * samplerate. This can be extended as needed. */ if (!(args = Py_BuildValue("{s:l}", "samplerate", (long)samplerate))) { srd_err("Unable to build python object for metadata."); return SRD_ERR_PYTHON; } /* Run the start() method on all decoders receiving frontend data. */ for (d = di_list; d; d = d->next) { di = d->data; di->data_num_probes = num_probes; di->data_unitsize = unitsize; di->data_samplerate = samplerate; if ((ret = srd_instance_start(di, args) != SRD_OK)) return ret; /* Run the start() method on all decoders up the stack from this one. */ for (s = di->next_di; s; s = s->next) { /* These don't need probes, unitsize and samplerate. */ di = s->data; if ((ret = srd_instance_start(di, args) != SRD_OK)) return ret; } } Py_DecRef(args); return SRD_OK; } /* Feed logic samples to decoder session. */ int srd_session_feed(uint64_t start_samplenum, uint8_t *inbuf, uint64_t inbuflen) { GSList *d; int ret; srd_dbg("srd: calling decode() on all instances with starting sample " "number %"PRIu64", %"PRIu64" bytes at 0x%p", start_samplenum, inbuflen, inbuf); for (d = di_list; d; d = d->next) { if ((ret = srd_instance_decode(start_samplenum, d->data, inbuf, inbuflen)) != SRD_OK) return ret; } return SRD_OK; } /* This is the backend function to python sigrokdecode.add() call. */ int pd_add(struct srd_decoder_instance *di, int output_type, char *proto_id) { struct srd_pd_output *pdo; srd_dbg("srd: instance %s creating new output type %d for %s", di->instance_id, output_type, proto_id); if (!(pdo = g_try_malloc(sizeof(struct srd_pd_output)))) return -1; /* pdo_id is just a simple index, nothing is deleted from this list anyway. */ pdo->pdo_id = g_slist_length(di->pd_output); pdo->output_type = output_type; pdo->decoder = di->decoder; pdo->proto_id = g_strdup(proto_id); di->pd_output = g_slist_append(di->pd_output, pdo); return pdo->pdo_id; } struct srd_decoder_instance *get_di_by_decobject(void *decobject) { GSList *l, *s; struct srd_decoder_instance *di; for (l = di_list; l; l = l->next) { di = l->data; if (decobject == di->py_instance) return di; /* Check decoders stacked on top of this one. */ for (s = di->next_di; s; s = s->next) { di = s->data; if (decobject == di->py_instance) return di; } } return NULL; } int srd_register_callback(int output_type, void *cb) { struct srd_pd_callback *pd_cb; srd_dbg("srd: registering new callback for output type %d", output_type); if (!(pd_cb = g_try_malloc(sizeof(struct srd_pd_callback)))) return SRD_ERR_MALLOC; pd_cb->output_type = output_type; pd_cb->callback = cb; callbacks = g_slist_append(callbacks, pd_cb); return SRD_OK; } void *srd_find_callback(int output_type) { GSList *l; struct srd_pd_callback *pd_cb; void *(cb); cb = NULL; for (l = callbacks; l; l = l->next) { pd_cb = l->data; if (pd_cb->output_type == output_type) { cb = pd_cb->callback; break; } } return cb; }