ccv_nnc_micro_interpret.c

Bug Summary

File:	nnc/ccv_nnc_micro_interpret.c
Warning:	line 186, column 65 The left expression of the compound assignment is an uninitialized value. The computed value will also be garbage

Annotated Source Code

Press '?' to see keyboard shortcuts

Show analyzer invocation

clang -cc1 -cc1 -triple x86_64-unknown-linux-gnu -analyze -disable-free -clear-ast-before-backend -disable-llvm-verifier -discard-value-names -main-file-name ccv_nnc_micro_interpret.c -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model pic -pic-level 2 -pic-is-pie -mframe-pointer=none -fmath-errno -ffp-contract=on -fno-rounding-math -mconstructor-aliases -funwind-tables=2 -target-cpu x86-64 -target-feature +sse2 -tune-cpu generic -debugger-tuning=gdb -fdebug-compilation-dir=/home/liu/actions-runner/_work/ccv/ccv/lib/nnc -fcoverage-compilation-dir=/home/liu/actions-runner/_work/ccv/ccv/lib/nnc -resource-dir /usr/local/lib/clang/18 -I ../ -I /usr/local/cuda/include -D HAVE_CBLAS -D HAVE_LIBPNG -D HAVE_LIBJPEG -D HAVE_FFTW3 -D HAVE_PTHREAD -D HAVE_LIBLINEAR -D HAVE_TESSERACT -D HAVE_AVCODEC -D HAVE_AVFORMAT -D HAVE_AVUTIL -D HAVE_SWSCALE -D HAVE_SSE2 -D HAVE_GSL -D HAVE_CUDA -D HAVE_CUDNN -D HAVE_NCCL -D USE_SYSTEM_CUB -D HAVE_CUDA_SM80 -I /usr/local/include -internal-isystem /usr/local/lib/clang/18/include -internal-isystem /usr/local/include -internal-isystem /usr/lib/gcc/x86_64-linux-gnu/12/../../../../x86_64-linux-gnu/include -internal-externc-isystem /usr/include/x86_64-linux-gnu -internal-externc-isystem /include -internal-externc-isystem /usr/include -O3 -ferror-limit 19 -fgnuc-version=4.2.1 -fskip-odr-check-in-gmf -vectorize-loops -vectorize-slp -analyzer-output=html -faddrsig -D__GCC_HAVE_DWARF2_CFI_ASM=1 -o /home/liu/actions-runner/_work/ccv/ccv/_analyze/2024-09-13-173104-134319-1 -x c ccv_nnc_micro_interpret.c

1#include "ccv_nnc.h"
2#include "ccv_nnc_easy.h"
3#include "ccv_nnc_internal.h"
4#include "ccv_internal.h"
5#include "_ccv_nnc_micro.h"
6 
7// MARK - Level-1 API
8 
9static int _ccv_nnc_micro_index_interpret(const ccv_nnc_micro_loop_index_term_t index, const int* const loop_counter, const int* const shapes, const ccv_nnc_micro_scalar_t* const values, const int parameter_size)
10{
11	switch (index.type)
12	{
13		case CCV_NNC_MICRO_LOOP_INDEX_TYPE_VAL:
14			return index.immediate_value;
15		case CCV_NNC_MICRO_LOOP_INDEX_TYPE_ID:
16			switch (index.id.type)
17			{
18				case CCV_NNC_MICRO_AXIS_SIZE_ID:
19					return shapes[index.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + index.id.d];
20				case CCV_NNC_MICRO_LOOP_ID:
21					return loop_counter[index.id.id];
22				case CCV_NNC_MICRO_SCALAR_ID:
23					switch (values[index.id.id].type)
24					{
25						case CCV_8U:
26							return values[index.id.id].u8;
27						case CCV_32S:
28							return values[index.id.id].i32;
29						case CCV_64S:
30							return (int)values[index.id.id].i64;
31					}
32					break;
33			}
34			break;
35		case CCV_NNC_MICRO_LOOP_INDEX_TYPE_BINARY: {
36			const int left = _ccv_nnc_micro_index_interpret(index.binary->left, loop_counter, shapes, values, parameter_size);
37			const int right = _ccv_nnc_micro_index_interpret(index.binary->right, loop_counter, shapes, values, parameter_size);
38			switch (index.binary->op)
39			{
40				case CCV_NNC_MICRO_BINARY_OP_PLUS:
41					return left + right;
42				case CCV_NNC_MICRO_BINARY_OP_MINUS:
43					return left - right;
44				case CCV_NNC_MICRO_BINARY_OP_MUL:
45					return left * right;
46				case CCV_NNC_MICRO_BINARY_OP_DIV:
47					return left / right;
48				case CCV_NNC_MICRO_BINARY_OP_MAX:
49					return ccv_max(left, right)({ typeof (left) _a = (left); typeof (right) _b = (right); (_a
 > _b) ? _a : _b; });
50				case CCV_NNC_MICRO_BINARY_OP_MIN:
51					return ccv_min(left, right)({ typeof (left) _a = (left); typeof (right) _b = (right); (_a
 < _b) ? _a : _b; });
52			}
53			break;
54		}
55	}
56	return 0;
57}
58 
59static float _ccv_nnc_micro_expression_interpret(const ccv_nnc_micro_loop_expression_t* const expression, const int* const loop_counter, const ccv_nnc_micro_scalar_t* const carrieds, const int carried_count, float* const* const vars_mem, const int* const shapes, const ccv_nnc_micro_scalar_t* const values, const int parameter_size, int* const out_of_bound_ref)
60{
61	int i;
62	switch (expression->type)
63	{
64		case CCV_NNC_MICRO_LOOP_EXPR_TYPE_ID: {
65			assert(expression->id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID)((void) sizeof ((expression->id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID
) ? 1 : 0), __extension__ ({ if (expression->id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID
) ; else __assert_fail ("expression->id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID"
, "ccv_nnc_micro_interpret.c", 65, __extension__ __PRETTY_FUNCTION__
); }));
66			return carrieds[expression->id.id].f32;
67		}
68		case CCV_NNC_MICRO_LOOP_EXPR_TYPE_VAL: {
69			return expression->immediate_value.f32;
70		}
71		case CCV_NNC_MICRO_LOOP_EXPR_TYPE_VAR: {
72			const ccv_nnc_micro_loop_variable_t variable = expression->variable;
73			assert(variable.id.type == CCV_NNC_MICRO_TENSOR_ID)((void) sizeof ((variable.id.type == CCV_NNC_MICRO_TENSOR_ID)
 ? 1 : 0), __extension__ ({ if (variable.id.type == CCV_NNC_MICRO_TENSOR_ID
) ; else __assert_fail ("variable.id.type == CCV_NNC_MICRO_TENSOR_ID"
, "ccv_nnc_micro_interpret.c", 73, __extension__ __PRETTY_FUNCTION__
); }));
74			float* ptr = vars_mem[variable.id.id];
75			size_t size = 1;
76			int out_of_bound = 0;
77			for (i = variable.index_count - 1; !out_of_bound && i >= 0; i--)
78			{
79				const int index = _ccv_nnc_micro_index_interpret(variable.index[i], loop_counter, shapes, values, parameter_size);
80				if (!variable.no_check_bound[i] &&
81					(index < 0 || index >= shapes[variable.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + i]))
82					out_of_bound = 1;
83				ptr += index * size;
84				size *= shapes[variable.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + i];
85			}
86			if (out_of_bound)
87			{
88				*out_of_bound_ref = 1;
89				return 0;
90			}
91			return ptr[0];
92		}
93		case CCV_NNC_MICRO_LOOP_EXPR_TYPE_UNARY: {
94			const float left = _ccv_nnc_micro_expression_interpret(expression->unary.x, loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size, out_of_bound_ref);
95			if (*out_of_bound_ref)
96				return 0;
97			switch (expression->unary.unary_op)
98			{
99				case CCV_NNC_MICRO_UNARY_OP_EXP:
100					return exp(left);
101				case CCV_NNC_MICRO_UNARY_OP_LOG:
102					return log(left);
103			}
104			break;
105		}
106		case CCV_NNC_MICRO_LOOP_EXPR_TYPE_BINARY: {
107			const float left = _ccv_nnc_micro_expression_interpret(expression->binary.left, loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size, out_of_bound_ref);
108			if (*out_of_bound_ref)
109				return 0;
110			const float right = _ccv_nnc_micro_expression_interpret(expression->binary.right, loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size, out_of_bound_ref);
111			if (*out_of_bound_ref)
112				return 0;
113			switch (expression->binary.binary_op)
114			{
115				case CCV_NNC_MICRO_BINARY_OP_PLUS:
116					return left + right;
117				case CCV_NNC_MICRO_BINARY_OP_MINUS:
118					return left - right;
119				case CCV_NNC_MICRO_BINARY_OP_MUL:
120					return left * right;
121				case CCV_NNC_MICRO_BINARY_OP_DIV:
122					return left / right;
123				case CCV_NNC_MICRO_BINARY_OP_MAX:
124					return ccv_max(left, right)({ typeof (left) _a = (left); typeof (right) _b = (right); (_a
 > _b) ? _a : _b; });
125				case CCV_NNC_MICRO_BINARY_OP_MIN:
126					return ccv_min(left, right)({ typeof (left) _a = (left); typeof (right) _b = (right); (_a
 < _b) ? _a : _b; });
127			}
128			break;
129		}
130	}
131	return 0;
61
←
'Default' branch taken. Execution continues on line 131→
62
←
Returning without writing to '*out_of_bound_ref', which participates in a condition later→
132}
133 
134static void _ccv_nnc_micro_statement_interpret(const ccv_nnc_micro_loop_statement_t statement, const int* const loop_counter, ccv_nnc_micro_scalar_t* const carrieds, const int carried_count, float* const* const vars_mem, const int* const shapes, const ccv_nnc_micro_scalar_t* const values, const int parameter_size)
135{
136	int i;
137	switch (statement.type)
59
←
Control jumps to 'case CCV_NNC_MICRO_LOOP_STATEMENT_TYPE_COMPOUND_ASSIGNMENT:'  at line 162→
138	{
139		case CCV_NNC_MICRO_LOOP_STATEMENT_TYPE_ASSIGNMENT: {
140			assert(statement.assignment.lvalue.id.type == CCV_NNC_MICRO_TENSOR_ID)((void) sizeof ((statement.assignment.lvalue.id.type == CCV_NNC_MICRO_TENSOR_ID
) ? 1 : 0), __extension__ ({ if (statement.assignment.lvalue.
id.type == CCV_NNC_MICRO_TENSOR_ID) ; else __assert_fail ("statement.assignment.lvalue.id.type == CCV_NNC_MICRO_TENSOR_ID"
, "ccv_nnc_micro_interpret.c", 140, __extension__ __PRETTY_FUNCTION__
); }));
141			const ccv_nnc_micro_loop_variable_t variable = statement.assignment.lvalue;
142			float* ptr = vars_mem[variable.id.id];
143			size_t size = 1;
144			int out_of_bound = 0;
145			for (i = variable.index_count - 1; !out_of_bound && i >= 0; i--)
146			{
147				const int index = _ccv_nnc_micro_index_interpret(variable.index[i], loop_counter, shapes, values, parameter_size);
148				if (!variable.no_check_bound[i] &&
149					(index < 0 || index >= shapes[variable.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + i]))
150					out_of_bound = 1;
151				ptr += index * size;
152				size *= shapes[variable.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + i];
153			}
154			if (out_of_bound)
155				return;
156			const float val = _ccv_nnc_micro_expression_interpret(&statement.assignment.rvalue, loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size, &out_of_bound);
157			if (out_of_bound)
158				return;
159			ptr[0] = val;
160			break;
161		}
162		case CCV_NNC_MICRO_LOOP_STATEMENT_TYPE_COMPOUND_ASSIGNMENT: {
163			int out_of_bound = 0;
164			const float rvalue = _ccv_nnc_micro_expression_interpret(&statement.compound_assignment.rvalue, loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size, &out_of_bound);
60
←
Calling '_ccv_nnc_micro_expression_interpret'→
63
←
Returning from '_ccv_nnc_micro_expression_interpret'→
165			if (out_of_bound63.1
'out_of_bound' is 0
)
64
←
Taking false branch→
166				return;
167			switch (statement.compound_assignment.lvalue.type)
65
←
Control jumps to 'case CCV_NNC_MICRO_LOOP_EXPR_TYPE_ID:'  at line 169→
168			{
169				case CCV_NNC_MICRO_LOOP_EXPR_TYPE_ID: {
170					assert(statement.compound_assignment.lvalue.id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID)((void) sizeof ((statement.compound_assignment.lvalue.id.type
 == CCV_NNC_MICRO_LOOP_CARRIED_ID) ? 1 : 0), __extension__ ({
 if (statement.compound_assignment.lvalue.id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID
) ; else __assert_fail ("statement.compound_assignment.lvalue.id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID"
, "ccv_nnc_micro_interpret.c", 170, __extension__ __PRETTY_FUNCTION__
); }));
66
←
Assuming field 'type' is equal to CCV_NNC_MICRO_LOOP_CARRIED_ID→
67
←
Taking true branch→
171					switch (statement.compound_assignment.lvalue.id.d)
68
←
Control jumps to 'case CCV_NNC_MICRO_REDUCE_OP_MEAN:'  at line 185→
172					{
173						case CCV_NNC_MICRO_REDUCE_OP_MAX:
174							carrieds[statement.compound_assignment.lvalue.id.id].f32 = ccv_max(carrieds[statement.compound_assignment.lvalue.id.id].f32, rvalue)({ typeof (carrieds[statement.compound_assignment.lvalue.id.id
].f32) _a = (carrieds[statement.compound_assignment.lvalue.id
.id].f32); typeof (rvalue) _b = (rvalue); (_a > _b) ? _a :
 _b; });
175							break;
176						case CCV_NNC_MICRO_REDUCE_OP_MIN:
177							carrieds[statement.compound_assignment.lvalue.id.id].f32 = ccv_min(carrieds[statement.compound_assignment.lvalue.id.id].f32, rvalue)({ typeof (carrieds[statement.compound_assignment.lvalue.id.id
].f32) _a = (carrieds[statement.compound_assignment.lvalue.id
.id].f32); typeof (rvalue) _b = (rvalue); (_a < _b) ? _a :
 _b; });
178							break;
179						case CCV_NNC_MICRO_REDUCE_OP_ARGMAX:
180							assert(0)((void) sizeof ((0) ? 1 : 0), __extension__ ({ if (0) ; else __assert_fail
 ("0", "ccv_nnc_micro_interpret.c", 180, __extension__ __PRETTY_FUNCTION__
); }));
181							break;
182						case CCV_NNC_MICRO_REDUCE_OP_ARGMIN:
183							assert(0)((void) sizeof ((0) ? 1 : 0), __extension__ ({ if (0) ; else __assert_fail
 ("0", "ccv_nnc_micro_interpret.c", 183, __extension__ __PRETTY_FUNCTION__
); }));
184							break;
185						case CCV_NNC_MICRO_REDUCE_OP_MEAN:
186							carrieds[statement.compound_assignment.lvalue.id.id].f32 += rvalue;
69
←
The left expression of the compound assignment is an uninitialized value. The computed value will also be garbage
187							break;
188						case CCV_NNC_MICRO_REDUCE_OP_SUM:
189							carrieds[statement.compound_assignment.lvalue.id.id].f32 += rvalue;
190							break;
191						case CCV_NNC_MICRO_REDUCE_OP_PROD:
192							carrieds[statement.compound_assignment.lvalue.id.id].f32 *= rvalue;
193							break;
194					}
195					break;
196				}
197				case CCV_NNC_MICRO_LOOP_EXPR_TYPE_VAR: {
198					assert(statement.compound_assignment.lvalue.id.type == CCV_NNC_MICRO_TENSOR_ID)((void) sizeof ((statement.compound_assignment.lvalue.id.type
 == CCV_NNC_MICRO_TENSOR_ID) ? 1 : 0), __extension__ ({ if (statement
.compound_assignment.lvalue.id.type == CCV_NNC_MICRO_TENSOR_ID
) ; else __assert_fail ("statement.compound_assignment.lvalue.id.type == CCV_NNC_MICRO_TENSOR_ID"
, "ccv_nnc_micro_interpret.c", 198, __extension__ __PRETTY_FUNCTION__
); }));
199					const ccv_nnc_micro_loop_variable_t variable = statement.compound_assignment.lvalue.variable;
200					float* ptr = vars_mem[variable.id.id];
201					size_t size = 1;
202					for (i = variable.index_count - 1; !out_of_bound && i >= 0; i--)
203					{
204						const int index = _ccv_nnc_micro_index_interpret(variable.index[i], loop_counter, shapes, values, parameter_size);
205						if (!variable.no_check_bound[i] &&
206							(index < 0 || index >= shapes[variable.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + i]))
207							out_of_bound = 1;
208						ptr += index * size;
209						size *= shapes[variable.id.id * CCV_NNC_MAX_DIM_ALLOC(12) + i];
210					}
211					if (out_of_bound)
212						return;
213					ptr[0] += rvalue;
214					break;
215				}
216			}
217			break;
218		}
219	}
220}
221 
222static void _ccv_nnc_micro_loop_interpret(const ccv_nnc_micro_loop_t* const loops, const int loop_count, const int index, int* const loop_counter, ccv_nnc_micro_scalar_t* const carrieds, const int carried_count, float* const* const vars_mem, const int* const shapes, const ccv_nnc_micro_scalar_t* const values, const int parameter_size)
223{
224	if (index >= loop_count)
44
←
Assuming 'index' is < 'loop_count'→
45
←
Taking false branch→
51
←
Assuming 'index' is < 'loop_count'→
52
←
Taking false branch→
225		return;
226	const int start_index = _ccv_nnc_micro_index_interpret(loops[index].start_index, loop_counter, shapes, values, parameter_size);
227	const int end_index = _ccv_nnc_micro_index_interpret(loops[index].end_index, loop_counter, shapes, values, parameter_size);
228	int i, j;
229	const ccv_nnc_micro_loop_statement_t* const statements = loops[index].statements;
230	const int statement_count = loops[index].statement_count;
231	const ccv_nnc_micro_loop_carried_t* const carried_refs = loops[index].carrieds;
232	const int carried_ref_count = loops[index].carried_count;
233	for (i = start_index; i < end_index; i++)
46
←
Assuming 'i' is < 'end_index'→
47
←
Loop condition is true.  Entering loop body→
53
←
Assuming 'i' is >= 'end_index'→
54
←
Loop condition is false. Execution continues on line 233→
234	{
235		loop_counter[loops[index].id.id] = i;
236		for (j = 0; j < carried_ref_count; j++)
48
←
Assuming 'j' is >= 'carried_ref_count'→
49
←
Loop condition is false. Execution continues on line 265→
237		{
238			assert(carried_refs[j].id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID)((void) sizeof ((carried_refs[j].id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID
) ? 1 : 0), __extension__ ({ if (carried_refs[j].id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID
) ; else __assert_fail ("carried_refs[j].id.type == CCV_NNC_MICRO_LOOP_CARRIED_ID"
, "ccv_nnc_micro_interpret.c", 238, __extension__ __PRETTY_FUNCTION__
); }));
239			assert(carried_refs[j].id.id < carried_count)((void) sizeof ((carried_refs[j].id.id < carried_count) ? 1
 : 0), __extension__ ({ if (carried_refs[j].id.id < carried_count
) ; else __assert_fail ("carried_refs[j].id.id < carried_count"
, "ccv_nnc_micro_interpret.c", 239, __extension__ __PRETTY_FUNCTION__
); }));
240			switch (carried_refs[j].id.d)
241			{
242				case CCV_NNC_MICRO_REDUCE_OP_MAX:
243					carrieds[carried_refs[j].id.id].f32 = -FLT_MAX3.40282347e+38F;
244					break;
245				case CCV_NNC_MICRO_REDUCE_OP_MIN:
246					carrieds[carried_refs[j].id.id].f32 = FLT_MAX3.40282347e+38F;
247					break;
248				case CCV_NNC_MICRO_REDUCE_OP_ARGMAX:
249					carrieds[carried_refs[j].id.id].i32 = -1;
250					break;
251				case CCV_NNC_MICRO_REDUCE_OP_ARGMIN:
252					carrieds[carried_refs[j].id.id].i32 = -1;
253					break;
254				case CCV_NNC_MICRO_REDUCE_OP_MEAN:
255					carrieds[carried_refs[j].id.id].f32 = 0;
256					break;
257				case CCV_NNC_MICRO_REDUCE_OP_SUM:
258					carrieds[carried_refs[j].id.id].f32 = 0;
259					break;
260				case CCV_NNC_MICRO_REDUCE_OP_PROD:
261					carrieds[carried_refs[j].id.id].f32 = 1;
262					break;
263			}
264		}
265		_ccv_nnc_micro_loop_interpret(loops, loop_count, index + 1, loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size);
50
←
Calling '_ccv_nnc_micro_loop_interpret'→
55
←
Returning from '_ccv_nnc_micro_loop_interpret'→
266		for (j = 0; j < statement_count; j++)
56
←
Assuming 'j' is < 'statement_count'→
57
←
Loop condition is true.  Entering loop body→
267			_ccv_nnc_micro_statement_interpret(statements[j], loop_counter, carrieds, carried_count, vars_mem, shapes, values, parameter_size);
58
←
Calling '_ccv_nnc_micro_statement_interpret'→
268	}
269}
270 
271void ccv_nnc_micro_combine_interpret(ccv_nnc_micro_combine_t* const combine, const uint32_t cmd, ccv_nnc_tensor_t* const* const inputs, const int input_size, const ccv_nnc_micro_scalar_t* const values, const int parameter_size, ccv_nnc_tensor_t* const* const outputs, const int output_size)
272{
273	// We haven't optimized for emit_grad at the moment yet.
274	assert(cmd == CCV_NNC_CUSTOM_FORWARD || cmd == CCV_NNC_CUSTOM_BACKWARD)((void) sizeof ((cmd == CCV_NNC_CUSTOM_FORWARD || cmd == CCV_NNC_CUSTOM_BACKWARD
) ? 1 : 0), __extension__ ({ if (cmd == CCV_NNC_CUSTOM_FORWARD
 || cmd == CCV_NNC_CUSTOM_BACKWARD) ; else __assert_fail ("cmd == CCV_NNC_CUSTOM_FORWARD || cmd == CCV_NNC_CUSTOM_BACKWARD"
, "ccv_nnc_micro_interpret.c", 274, __extension__ __PRETTY_FUNCTION__
); }));
1
Assuming 'cmd' is not equal to CCV_NNC_CUSTOM_FORWARD→
2
←
Assuming 'cmd' is equal to CCV_NNC_CUSTOM_BACKWARD→
3
←
Taking true branch→
275	int i, j;
276	const ccv_nnc_micro_program_t* const program = cmd3.1
'cmd' is not equal to CCV_NNC_CUSTOM_FORWARD
 == CCV_NNC_CUSTOM_FORWARD ? &combine->forward : &combine->backward;
4
←
'?' condition is false→
277	const int var_count = program->var_count;
278	assert(input_size == program->input_size)((void) sizeof ((input_size == program->input_size) ? 1 : 0
), __extension__ ({ if (input_size == program->input_size)
 ; else __assert_fail ("input_size == program->input_size"
, "ccv_nnc_micro_interpret.c", 278, __extension__ __PRETTY_FUNCTION__
); }));
5
←
Assuming 'input_size' is equal to field 'input_size'→
6
←
Taking true branch→
279	assert(output_size == program->output_size)((void) sizeof ((output_size == program->output_size) ? 1 :
 0), __extension__ ({ if (output_size == program->output_size
) ; else __assert_fail ("output_size == program->output_size"
, "ccv_nnc_micro_interpret.c", 279, __extension__ __PRETTY_FUNCTION__
); }));
7
←
Assuming 'output_size' is equal to field 'output_size'→
8
←
Taking true branch→
280	assert(parameter_size == combine->parameter_size)((void) sizeof ((parameter_size == combine->parameter_size
) ? 1 : 0), __extension__ ({ if (parameter_size == combine->
parameter_size) ; else __assert_fail ("parameter_size == combine->parameter_size"
, "ccv_nnc_micro_interpret.c", 280, __extension__ __PRETTY_FUNCTION__
); }));
9
←
Assuming 'parameter_size' is equal to field 'parameter_size'→
10
←
Taking true branch→
281	int* const shapes = (int*)cccalloccalloc(var_count, sizeof(int) * CCV_NNC_MAX_DIM_ALLOC(12));
282	ccv_nnc_micro_tensor_t* const vars = program->vars;
283	for (i = 0; i < input_size; i++)
11
←
Assuming 'i' is >= 'input_size'→
12
←
Loop condition is false. Execution continues on line 285→
284		memcpy(shapes + program->inputs[i] * CCV_NNC_MAX_DIM_ALLOC(12), &inputs[i]->info.dim, sizeof(int) * CCV_NNC_MAX_DIM_ALLOC(12));
285	int loop_counter[CCV_NNC_MAX_DIM_ALLOC(12)];
286	for (i = 0; i < var_count; i++)
13
←
Assuming 'i' is >= 'var_count'→
14
←
Loop condition is false. Execution continues on line 300→
287	{
288		int flag = 0;
289		for (j = 0; !flag && j < input_size; j++)
290			flag = (program->inputs[j] == i);
291		if (flag)
292			continue;
293		if (vars[i].shape)
294		{
295			for (j = 0; j < vars[i].dimensions; j++)
296				shapes[i * CCV_NNC_MAX_DIM_ALLOC(12) + j] = _ccv_nnc_micro_index_interpret(vars[i].shape[j], loop_counter, shapes, values, parameter_size);
297		} else
298			memcpy(shapes + i * CCV_NNC_MAX_DIM_ALLOC(12), shapes + vars[i].input * CCV_NNC_MAX_DIM_ALLOC(12), sizeof(int) * CCV_NNC_MAX_DIM_ALLOC(12));
299	}
300	const ccv_array_t* const equal_assertions = combine->equal_assertions;
301	for (i = 0; i < equal_assertions->rnum; i++)
15
←
Assuming 'i' is >= field 'rnum'→
16
←
Loop condition is false. Execution continues on line 306→
302	{
303		ccv_nnc_micro_id_equal_assertion_t* const equal_assertion = ccv_array_get(equal_assertions, i)((void*)(((char*)((equal_assertions)->data)) + (size_t)(equal_assertions
)->rsize * (size_t)(i)));
304		assert(shapes[equal_assertion->left.id * CCV_NNC_MAX_DIM_ALLOC + equal_assertion->left.d] == shapes[equal_assertion->right.id * CCV_NNC_MAX_DIM_ALLOC + equal_assertion->right.d])((void) sizeof ((shapes[equal_assertion->left.id * (12) + equal_assertion
->left.d] == shapes[equal_assertion->right.id * (12) + equal_assertion
->right.d]) ? 1 : 0), __extension__ ({ if (shapes[equal_assertion
->left.id * (12) + equal_assertion->left.d] == shapes[equal_assertion
->right.id * (12) + equal_assertion->right.d]) ; else __assert_fail
 ("shapes[equal_assertion->left.id * CCV_NNC_MAX_DIM_ALLOC + equal_assertion->left.d] == shapes[equal_assertion->right.id * CCV_NNC_MAX_DIM_ALLOC + equal_assertion->right.d]"
, "ccv_nnc_micro_interpret.c", 304, __extension__ __PRETTY_FUNCTION__
); }));
305	}
306	size_t total_size = 0;
307	for (i = 0; i16.1
'i' is >= 'var_count'
 < var_count; i++)
17
←
Loop condition is false. Execution continues on line 324→
308	{
309		int flag = 0;
310		for (j = 0; !flag && j < input_size; j++)
311			flag = (program->inputs[j] == i);
312		for (j = 0; !flag && j < output_size; j++)
313			flag = (program->outputs[j] == i);
314		if (flag)
315			continue;
316		if (vars[i].no_alloc) // This is skipped.
317			continue;
318		// allocating memory for these.
319		size_t size = 1;
320		for (j = 0; j < vars[i].dimensions; j++)
321			size *= shapes[i * CCV_NNC_MAX_DIM_ALLOC(12) + j];
322		total_size += size;
323	}
324	float** const vars_mem = (float**)ccmallocmalloc(sizeof(float*) * var_count + sizeof(float) * total_size);
325	float* ptr = (float*)(vars_mem + var_count);
326	// Assuming these are not tensor_view_t.
327	for (i = 0; i < output_size; i++)
18
←
Assuming 'i' is >= 'output_size'→
19
←
Loop condition is false. Execution continues on line 332→
328	{
329		assert(CCV_IS_TENSOR_CONTIGUOUS(outputs[i]))((void) sizeof (((!((*(int*)(outputs[i])) & CCV_TENSOR_VIEW
) || (((ccv_nnc_tensor_view_t*)outputs[i])->contiguous == 1
))) ? 1 : 0), __extension__ ({ if ((!((*(int*)(outputs[i])) &
 CCV_TENSOR_VIEW) || (((ccv_nnc_tensor_view_t*)outputs[i])->
contiguous == 1))) ; else __assert_fail ("CCV_IS_TENSOR_CONTIGUOUS(outputs[i])"
, "ccv_nnc_micro_interpret.c", 329, __extension__ __PRETTY_FUNCTION__
); }));
330		vars_mem[program->outputs[i]] = outputs[i]->data.f32;
331	}
332	for (i = 0; i19.1
'i' is >= 'var_count'
 < var_count; i++)
20
←
Loop condition is false. Execution continues on line 353→
333	{
334		int flag = 0;
335		for (j = 0; !flag && j < input_size; j++)
336			flag = (program->inputs[j] == i);
337		for (j = 0; !flag && j < output_size; j++)
338			flag = (program->outputs[j] == i);
339		if (flag)
340			continue;
341		if (vars[i].no_alloc) // This is skipped.
342		{
343			vars_mem[i] = 0;
344			continue;
345		}
346		// allocating memory for these.
347		size_t size = 1;
348		for (j = 0; j < vars[i].dimensions; j++)
349			size *= shapes[i * CCV_NNC_MAX_DIM_ALLOC(12) + j];
350		vars_mem[i] = ptr;
351		ptr += size;
352	}
353	for (i = 0; i20.1
'i' is >= 'input_size'
 < input_size; i++)
21
←
Loop condition is false. Execution continues on line 358→
354	{
355		assert(CCV_IS_TENSOR_CONTIGUOUS(inputs[i]))((void) sizeof (((!((*(int*)(inputs[i])) & CCV_TENSOR_VIEW
) || (((ccv_nnc_tensor_view_t*)inputs[i])->contiguous == 1
))) ? 1 : 0), __extension__ ({ if ((!((*(int*)(inputs[i])) &
 CCV_TENSOR_VIEW) || (((ccv_nnc_tensor_view_t*)inputs[i])->
contiguous == 1))) ; else __assert_fail ("CCV_IS_TENSOR_CONTIGUOUS(inputs[i])"
, "ccv_nnc_micro_interpret.c", 355, __extension__ __PRETTY_FUNCTION__
); }));
356		vars_mem[program->inputs[i]] = inputs[i]->data.f32;
357	}
358	ccv_nnc_micro_function_t* const functions = program->functions;
359	const int function_count = program->function_count;
360	int max_carried_count = 0;
361	for (i = 0; i < function_count; i++)
22
←
Assuming 'i' is < 'function_count'→
23
←
Loop condition is true.  Entering loop body→
35
←
Assuming 'i' is >= 'function_count'→
362	{
363		const int block_count = functions[i].block_count;
364		ccv_nnc_micro_loop_block_t* const blocks = block_count == 1 ? &functions[i].one_block : functions[i].blocks;
24
←
Assuming 'block_count' is not equal to 1→
25
←
'?' condition is false→
365		for (j = 0; j29.1
'j' is < 'block_count'
 < block_count; j++)
26
←
Assuming 'j' is < 'block_count'→
27
←
Loop condition is true.  Entering loop body→
30
←
Loop condition is true.  Entering loop body→
33
←
Assuming 'j' is >= 'block_count'→
34
←
Loop condition is false. Execution continues on line 361→
366			max_carried_count = ccv_max(max_carried_count, blocks[j].carried_count)({ typeof (max_carried_count) _a = (max_carried_count); typeof
 (blocks[j].carried_count) _b = (blocks[j].carried_count); (_a
 > _b) ? _a : _b; });
28
←
Assuming '_a' is <= '_b'→
29
←
'?' condition is false→
31
←
Assuming '_a' is > '_b'→
32
←
'?' condition is true→
367	}
368	ccv_nnc_micro_scalar_t* const carrieds = max_carried_count > 0 ? (ccv_nnc_micro_scalar_t*)ccmallocmalloc(sizeof(ccv_nnc_micro_scalar_t) * max_carried_count) : 0;
36
←
Loop condition is false. Execution continues on line 368→
37
←
Assuming 'max_carried_count' is > 0→
38
←
'?' condition is true→
39
←
Uninitialized value stored to field 'f32'→
369	for (i = 0; i < function_count; i++)
40
←
Loop condition is true.  Entering loop body→
370	{
371		const int block_count = functions[i].block_count;
372		ccv_nnc_micro_loop_block_t* const blocks = block_count40.1
'block_count' is not equal to 1
 == 1 ? &functions[i].one_block : functions[i].blocks;
41
←
'?' condition is false→
373		for (j = 0; j < block_count; j++)
42
←
Loop condition is true.  Entering loop body→
374			_ccv_nnc_micro_loop_interpret(blocks[j].loops, blocks[j].loop_count, 0, loop_counter, carrieds, blocks[j].carried_count, vars_mem, shapes, values, parameter_size);
43
←
Calling '_ccv_nnc_micro_loop_interpret'→
375	}
376	if (carrieds)
377		ccfreefree(carrieds);
378	ccfreefree(vars_mem);
379	ccfreefree(shapes);
380}