xref: /openbmc/libcper/cper-utils.c (revision fedd457d)
1 /**
2  * Describes utility functions for parsing CPER into JSON IR.
3  *
4  * Author: Lawrence.Tang@arm.com
5  **/
6 
7 #include <stdio.h>
8 #include <json.h>
9 #include "edk/Cper.h"
10 #include "cper-utils.h"
11 
12 //The available severity types for CPER.
13 const char *CPER_SEVERITY_TYPES[4] = { "Recoverable", "Fatal", "Corrected",
14 				       "Informational" };
15 
16 //Converts the given generic CPER error status to JSON IR.
17 json_object *
18 cper_generic_error_status_to_ir(EFI_GENERIC_ERROR_STATUS *error_status)
19 {
20 	json_object *error_status_ir = json_object_new_object();
21 
22 	//Error type.
23 	json_object_object_add(error_status_ir, "errorType",
24 			       integer_to_readable_pair_with_desc(
25 				       error_status->Type, 18,
26 				       CPER_GENERIC_ERROR_TYPES_KEYS,
27 				       CPER_GENERIC_ERROR_TYPES_VALUES,
28 				       CPER_GENERIC_ERROR_TYPES_DESCRIPTIONS,
29 				       "Unknown (Reserved)"));
30 
31 	//Boolean bit fields.
32 	json_object_object_add(
33 		error_status_ir, "addressSignal",
34 		json_object_new_boolean(error_status->AddressSignal));
35 	json_object_object_add(
36 		error_status_ir, "controlSignal",
37 		json_object_new_boolean(error_status->ControlSignal));
38 	json_object_object_add(
39 		error_status_ir, "dataSignal",
40 		json_object_new_boolean(error_status->DataSignal));
41 	json_object_object_add(
42 		error_status_ir, "detectedByResponder",
43 		json_object_new_boolean(error_status->DetectedByResponder));
44 	json_object_object_add(
45 		error_status_ir, "detectedByRequester",
46 		json_object_new_boolean(error_status->DetectedByRequester));
47 	json_object_object_add(
48 		error_status_ir, "firstError",
49 		json_object_new_boolean(error_status->FirstError));
50 	json_object_object_add(
51 		error_status_ir, "overflowDroppedLogs",
52 		json_object_new_boolean(error_status->OverflowNotLogged));
53 
54 	return error_status_ir;
55 }
56 
57 //Converts the given CPER-JSON generic error status into a CPER structure.
58 void ir_generic_error_status_to_cper(
59 	json_object *error_status, EFI_GENERIC_ERROR_STATUS *error_status_cper)
60 {
61 	error_status_cper->Type = readable_pair_to_integer(
62 		json_object_object_get(error_status, "errorType"));
63 	error_status_cper->AddressSignal = json_object_get_boolean(
64 		json_object_object_get(error_status, "addressSignal"));
65 	error_status_cper->ControlSignal = json_object_get_boolean(
66 		json_object_object_get(error_status, "controlSignal"));
67 	error_status_cper->DataSignal = json_object_get_boolean(
68 		json_object_object_get(error_status, "dataSignal"));
69 	error_status_cper->DetectedByResponder = json_object_get_boolean(
70 		json_object_object_get(error_status, "detectedByResponder"));
71 	error_status_cper->DetectedByRequester = json_object_get_boolean(
72 		json_object_object_get(error_status, "detectedByRequester"));
73 	error_status_cper->FirstError = json_object_get_boolean(
74 		json_object_object_get(error_status, "firstError"));
75 	error_status_cper->OverflowNotLogged = json_object_get_boolean(
76 		json_object_object_get(error_status, "overflowDroppedLogs"));
77 }
78 
79 //Converts a single uniform struct of UINT64s into intermediate JSON IR format, given names for each field in byte order.
80 json_object *uniform_struct64_to_ir(UINT64 *start, int len, const char *names[])
81 {
82 	json_object *result = json_object_new_object();
83 
84 	UINT64 *cur = start;
85 	for (int i = 0; i < len; i++) {
86 		json_object_object_add(result, names[i],
87 				       json_object_new_uint64(*cur));
88 		cur++;
89 	}
90 
91 	return result;
92 }
93 
94 //Converts a single uniform struct of UINT32s into intermediate JSON IR format, given names for each field in byte order.
95 json_object *uniform_struct_to_ir(UINT32 *start, int len, const char *names[])
96 {
97 	json_object *result = json_object_new_object();
98 
99 	UINT32 *cur = start;
100 	for (int i = 0; i < len; i++) {
101 		json_object_object_add(result, names[i],
102 				       json_object_new_uint64(*cur));
103 		cur++;
104 	}
105 
106 	return result;
107 }
108 
109 //Converts a single object containing UINT32s into a uniform struct.
110 void ir_to_uniform_struct64(json_object *ir, UINT64 *start, int len,
111 			    const char *names[])
112 {
113 	UINT64 *cur = start;
114 	for (int i = 0; i < len; i++) {
115 		*cur = json_object_get_uint64(
116 			json_object_object_get(ir, names[i]));
117 		cur++;
118 	}
119 }
120 
121 //Converts a single object containing UINT32s into a uniform struct.
122 void ir_to_uniform_struct(json_object *ir, UINT32 *start, int len,
123 			  const char *names[])
124 {
125 	UINT32 *cur = start;
126 	for (int i = 0; i < len; i++) {
127 		*cur = (UINT32)json_object_get_uint64(
128 			json_object_object_get(ir, names[i]));
129 		cur++;
130 	}
131 }
132 
133 //Converts a single integer value to an object containing a value, and a readable name if possible.
134 json_object *integer_to_readable_pair(UINT64 value, int len, const int keys[],
135 				      const char *values[],
136 				      const char *default_value)
137 {
138 	json_object *result = json_object_new_object();
139 	json_object_object_add(result, "value", json_object_new_uint64(value));
140 
141 	//Search for human readable name, add.
142 	const char *name = default_value;
143 	for (int i = 0; i < len; i++) {
144 		if ((UINT64)keys[i] == value) {
145 			name = values[i];
146 		}
147 	}
148 
149 	json_object_object_add(result, "name", json_object_new_string(name));
150 	return result;
151 }
152 
153 //Converts a single integer value to an object containing a value, readable name and description if possible.
154 json_object *integer_to_readable_pair_with_desc(int value, int len,
155 						const int keys[],
156 						const char *values[],
157 						const char *descriptions[],
158 						const char *default_value)
159 {
160 	json_object *result = json_object_new_object();
161 	json_object_object_add(result, "value", json_object_new_int(value));
162 
163 	//Search for human readable name, add.
164 	const char *name = default_value;
165 	for (int i = 0; i < len; i++) {
166 		if (keys[i] == value) {
167 			name = values[i];
168 			json_object_object_add(
169 				result, "description",
170 				json_object_new_string(descriptions[i]));
171 		}
172 	}
173 
174 	json_object_object_add(result, "name", json_object_new_string(name));
175 	return result;
176 }
177 
178 //Returns a single UINT64 value from the given readable pair object.
179 //Assumes the integer value is held in the "value" field.
180 UINT64 readable_pair_to_integer(json_object *pair)
181 {
182 	return json_object_get_uint64(json_object_object_get(pair, "value"));
183 }
184 
185 //Converts the given 64 bit bitfield to IR, assuming bit 0 starts on the left.
186 json_object *bitfield_to_ir(UINT64 bitfield, int num_fields,
187 			    const char *names[])
188 {
189 	json_object *result = json_object_new_object();
190 	for (int i = 0; i < num_fields; i++) {
191 		json_object_object_add(result, names[i],
192 				       json_object_new_boolean((bitfield >> i) &
193 							       0x1));
194 	}
195 
196 	return result;
197 }
198 
199 //Converts the given IR bitfield into a standard UINT64 bitfield, with fields beginning from bit 0.
200 UINT64 ir_to_bitfield(json_object *ir, int num_fields, const char *names[])
201 {
202 	UINT64 result = 0x0;
203 	for (int i = 0; i < num_fields; i++) {
204 		if (json_object_get_boolean(
205 			    json_object_object_get(ir, names[i]))) {
206 			result |= (0x1 << i);
207 		}
208 	}
209 
210 	return result;
211 }
212 
213 //Converts the given UINT64 array into a JSON IR array, given the length.
214 json_object *uint64_array_to_ir_array(UINT64 *array, int len)
215 {
216 	json_object *array_ir = json_object_new_array();
217 	for (int i = 0; i < len; i++) {
218 		json_object_array_add(array_ir,
219 				      json_object_new_uint64(array[i]));
220 	}
221 	return array_ir;
222 }
223 
224 //Converts a single UINT16 revision number into JSON IR representation.
225 json_object *revision_to_ir(UINT16 revision)
226 {
227 	json_object *revision_info = json_object_new_object();
228 	json_object_object_add(revision_info, "major",
229 			       json_object_new_int(revision >> 8));
230 	json_object_object_add(revision_info, "minor",
231 			       json_object_new_int(revision & 0xFF));
232 	return revision_info;
233 }
234 
235 //Returns the appropriate string for the given integer severity.
236 const char *severity_to_string(UINT32 severity)
237 {
238 	return severity < 4 ? CPER_SEVERITY_TYPES[severity] : "Unknown";
239 }
240 
241 //Converts a single EFI timestamp to string, at the given output.
242 //Output must be at least TIMESTAMP_LENGTH bytes long.
243 void timestamp_to_string(char *out, EFI_ERROR_TIME_STAMP *timestamp)
244 {
245 	sprintf(out, "%02hhu%02hhu-%02hhu-%02hhuT%02hhu:%02hhu:%02hhu.000",
246 		bcd_to_int(timestamp->Century) %
247 			100,			   //Cannot go to three digits.
248 		bcd_to_int(timestamp->Year) % 100, //Cannot go to three digits.
249 		bcd_to_int(timestamp->Month), bcd_to_int(timestamp->Day),
250 		bcd_to_int(timestamp->Hours), bcd_to_int(timestamp->Minutes),
251 		bcd_to_int(timestamp->Seconds));
252 }
253 
254 //Converts a single timestamp string to an EFI timestamp.
255 void string_to_timestamp(EFI_ERROR_TIME_STAMP *out, const char *timestamp)
256 {
257 	//Ignore invalid timestamps.
258 	if (timestamp == NULL) {
259 		return;
260 	}
261 
262 	sscanf(timestamp, "%2hhu%2hhu-%hhu-%hhuT%hhu:%hhu:%hhu.000",
263 	       &out->Century, &out->Year, &out->Month, &out->Day, &out->Hours,
264 	       &out->Minutes, &out->Seconds);
265 
266 	//Convert back to BCD.
267 	out->Century = int_to_bcd(out->Century);
268 	out->Year = int_to_bcd(out->Year);
269 	out->Month = int_to_bcd(out->Month);
270 	out->Day = int_to_bcd(out->Day);
271 	out->Hours = int_to_bcd(out->Hours);
272 	out->Minutes = int_to_bcd(out->Minutes);
273 	out->Seconds = int_to_bcd(out->Seconds);
274 }
275 
276 //Helper function to convert an EDK EFI GUID into a string for intermediate use.
277 void guid_to_string(char *out, EFI_GUID *guid)
278 {
279 	sprintf(out, "%08x-%04x-%04x-%02x%02x%02x%02x%02x%02x%02x%02x",
280 		guid->Data1, guid->Data2, guid->Data3, guid->Data4[0],
281 		guid->Data4[1], guid->Data4[2], guid->Data4[3], guid->Data4[4],
282 		guid->Data4[5], guid->Data4[6], guid->Data4[7]);
283 }
284 
285 //Helper function to convert a string into an EDK EFI GUID.
286 void string_to_guid(EFI_GUID *out, const char *guid)
287 {
288 	//Ignore invalid GUIDs.
289 	if (guid == NULL) {
290 		return;
291 	}
292 
293 	sscanf(guid,
294 	       "%08x-%04hx-%04hx-%02hhx%02hhx%02hhx%02hhx%02hhx%02hhx%02hhx%02hhx",
295 	       &out->Data1, &out->Data2, &out->Data3, out->Data4,
296 	       out->Data4 + 1, out->Data4 + 2, out->Data4 + 3, out->Data4 + 4,
297 	       out->Data4 + 5, out->Data4 + 6, out->Data4 + 7);
298 }
299 
300 //Returns one if two EFI GUIDs are equal, zero otherwise.
301 int guid_equal(EFI_GUID *a, EFI_GUID *b)
302 {
303 	//Check top base 3 components.
304 	if (a->Data1 != b->Data1 || a->Data2 != b->Data2 ||
305 	    a->Data3 != b->Data3) {
306 		return 0;
307 	}
308 
309 	//Check Data4 array for equality.
310 	for (int i = 0; i < 8; i++) {
311 		if (a->Data4[i] != b->Data4[i]) {
312 			return 0;
313 		}
314 	}
315 
316 	return 1;
317 }
318