/* Standalone program to test functionality of tvbuffs. * * tvbtest : tvbtest.o tvbuff.o except.o * * Copyright (c) 2000 by Gilbert Ramirez * * 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 2 * 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, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * */ #include "config.h" #include #include #include #include "tvbuff.h" #include "exceptions.h" #include "wsutil/pint.h" gboolean failed = FALSE; /* Tests a tvbuff against the expected pattern/length. * Returns TRUE if all tests succeeed, FALSE if any test fails */ gboolean test(tvbuff_t *tvb, const gchar* name, guint8* expected_data, guint expected_length, guint expected_reported_length) { guint length; guint reported_length; guint8 *ptr; volatile gboolean ex_thrown; volatile guint32 val32; guint32 expected32; guint incr, i; length = tvb_length(tvb); if (length != expected_length) { printf("01: Failed TVB=%s Length of tvb=%u while expected length=%u\n", name, length, expected_length); failed = TRUE; return FALSE; } reported_length = tvb_reported_length(tvb); if (reported_length != expected_reported_length) { printf("01: Failed TVB=%s Reported length of tvb=%u while expected reported length=%u\n", name, reported_length, expected_reported_length); failed = TRUE; return FALSE; } /* Test boundary case. A BoundsError exception should be thrown. */ ex_thrown = FALSE; TRY { tvb_get_ptr(tvb, 0, length + 1); } CATCH(BoundsError) { ex_thrown = TRUE; } CATCH(FragmentBoundsError) { printf("02: Caught wrong exception: FragmentBoundsError\n"); } CATCH(ReportedBoundsError) { printf("02: Caught wrong exception: ReportedBoundsError\n"); } CATCH_ALL { printf("02: Caught wrong exception: %lu\n", exc->except_id.except_code); } ENDTRY; if (!ex_thrown) { printf("02: Failed TVB=%s No BoundsError when retrieving %u bytes\n", name, length + 1); failed = TRUE; return FALSE; } /* Test boundary case with reported_length+1. A ReportedBoundsError exception should be thrown. */ ex_thrown = FALSE; TRY { tvb_get_ptr(tvb, 0, reported_length + 1); } CATCH(BoundsError) { printf("03: Caught wrong exception: BoundsError\n"); } CATCH(FragmentBoundsError) { printf("03: Caught wrong exception: FragmentBoundsError\n"); } CATCH(ReportedBoundsError) { ex_thrown = TRUE; } CATCH_ALL { printf("02: Caught wrong exception: %lu\n", exc->except_id.except_code); } ENDTRY; if (!ex_thrown) { printf("03: Failed TVB=%s No ReportedBoundsError when retrieving %u bytes\n", name, reported_length + 1); failed = TRUE; return FALSE; } /* Test boundary case. A BoundsError exception should be thrown. */ ex_thrown = FALSE; TRY { tvb_get_ptr(tvb, -1, 2); } CATCH(BoundsError) { ex_thrown = TRUE; } CATCH(FragmentBoundsError) { printf("04: Caught wrong exception: FragmentBoundsError\n"); } CATCH(ReportedBoundsError) { printf("04: Caught wrong exception: ReportedBoundsError\n"); } CATCH_ALL { printf("02: Caught wrong exception: %lu\n", exc->except_id.except_code); } ENDTRY; if (!ex_thrown) { printf("04: Failed TVB=%s No BoundsError when retrieving 2 bytes from" " offset -1\n", name); failed = TRUE; return FALSE; } /* Test boundary case. A BoundsError exception should not be thrown. */ ex_thrown = FALSE; TRY { tvb_get_ptr(tvb, 0, 1); } CATCH(BoundsError) { ex_thrown = TRUE; } CATCH(FragmentBoundsError) { printf("05: Caught wrong exception: FragmentBoundsError\n"); } CATCH(ReportedBoundsError) { printf("05: Caught wrong exception: ReportedBoundsError\n"); } CATCH_ALL { printf("02: Caught wrong exception: %lu\n", exc->except_id.except_code); } ENDTRY; if (ex_thrown) { printf("05: Failed TVB=%s BoundsError when retrieving 1 bytes from" " offset 0\n", name); failed = TRUE; return FALSE; } /* Test boundary case. A BoundsError exception should not be thrown. */ ex_thrown = FALSE; TRY { tvb_get_ptr(tvb, -1, 1); } CATCH(BoundsError) { ex_thrown = TRUE; } CATCH(FragmentBoundsError) { printf("06: Caught wrong exception: FragmentBoundsError\n"); } CATCH(ReportedBoundsError) { printf("06: Caught wrong exception: ReportedBoundsError\n"); } CATCH_ALL { printf("02: Caught wrong exception: %lu\n", exc->except_id.except_code); } ENDTRY; if (ex_thrown) { printf("06: Failed TVB=%s BoundsError when retrieving 1 bytes from" " offset -1\n", name); failed = TRUE; return FALSE; } /* Check data at boundary. An exception should not be thrown. */ if (length >= 4) { ex_thrown = FALSE; TRY { val32 = tvb_get_ntohl(tvb, 0); } CATCH_ALL { ex_thrown = TRUE; } ENDTRY; if (ex_thrown) { printf("07: Failed TVB=%s Exception when retrieving " "guint32 from offset 0\n", name); failed = TRUE; return FALSE; } expected32 = pntoh32(expected_data); if (val32 != expected32) { printf("08: Failed TVB=%s guint32 @ 0 %u != expected %u\n", name, val32, expected32); failed = TRUE; return FALSE; } } /* Check data at boundary. An exception should not be thrown. */ if (length >= 4) { ex_thrown = FALSE; TRY { val32 = tvb_get_ntohl(tvb, -4); } CATCH_ALL { ex_thrown = TRUE; } ENDTRY; if (ex_thrown) { printf("09: Failed TVB=%s Exception when retrieving " "guint32 from offset 0\n", name); failed = TRUE; return FALSE; } expected32 = pntoh32(&expected_data[length-4]); if (val32 != expected32) { printf("10: Failed TVB=%s guint32 @ -4 %u != expected %u\n", name, val32, expected32); failed = TRUE; return FALSE; } } /* Sweep across data in various sized increments checking * tvb_memdup() */ for (incr = 1; incr < length; incr++) { for (i = 0; i < length - incr; i += incr) { ptr = (guint8*)tvb_memdup(NULL, tvb, i, incr); if (memcmp(ptr, &expected_data[i], incr) != 0) { printf("11: Failed TVB=%s Offset=%d Length=%d " "Bad memdup\n", name, i, incr); failed = TRUE; wmem_free(NULL, ptr); return FALSE; } wmem_free(NULL, ptr); } } /* One big memdup */ ptr = (guint8*)tvb_memdup(NULL, tvb, 0, -1); if (memcmp(ptr, expected_data, length) != 0) { printf("12: Failed TVB=%s Offset=0 Length=-1 " "Bad memdup\n", name); failed = TRUE; wmem_free(NULL, ptr); return FALSE; } wmem_free(NULL, ptr); printf("Passed TVB=%s\n", name); return TRUE; } gboolean skip(tvbuff_t *tvb _U_, gchar* name, guint8* expected_data _U_, guint expected_length _U_) { printf("Skipping TVB=%s\n", name); return FALSE; } void run_tests(void) { int i, j; tvbuff_t *tvb_parent; tvbuff_t *tvb_small[3]; tvbuff_t *tvb_large[3]; tvbuff_t *tvb_subset[6]; guint8 *small[3]; guint small_length[3]; guint small_reported_length[3]; guint8 *large[3]; guint large_length[3]; guint large_reported_length[3]; guint8 *subset[6]; guint subset_length[6]; guint subset_reported_length[6]; guint8 temp; guint8 *comp[6]; tvbuff_t *tvb_comp[6]; guint comp_length[6]; guint comp_reported_length[6]; int len; tvb_parent = tvb_new_real_data("", 0, 0); for (i = 0; i < 3; i++) { small[i] = g_new(guint8, 16); temp = 16 * i; for (j = 0; j < 16; j++) { small[i][j] = temp + j; } small_length[i] = 16; small_reported_length[i] = 17; tvb_small[i] = tvb_new_child_real_data(tvb_parent, small[i], 16, 17); tvb_set_free_cb(tvb_small[i], g_free); } for (i = 0; i < 3; i++) { large[i] = g_new(guint8, 19); temp = 19 * i; for (j = 0; j < 19; j++) { large[i][j] = temp + j; } large_length[i] = 19; large_reported_length[i] = 20; tvb_large[i] = tvb_new_child_real_data(tvb_parent, large[i], 19, 20); tvb_set_free_cb(tvb_large[i], g_free); } /* Test the TVBUFF_REAL_DATA objects. */ test(tvb_small[0], "Small 0", small[0], small_length[0], small_reported_length[0]); test(tvb_small[1], "Small 1", small[1], small_length[1], small_reported_length[1]); test(tvb_small[2], "Small 2", small[2], small_length[2], small_reported_length[2]); test(tvb_large[0], "Large 0", large[0], large_length[0], large_reported_length[0]); test(tvb_large[1], "Large 1", large[1], large_length[1], large_reported_length[1]); test(tvb_large[2], "Large 2", large[2], large_length[2], large_reported_length[2]); subset_length[0] = 8; subset_reported_length[0] = 9; tvb_subset[0] = tvb_new_subset(tvb_small[0], 0, 8, 9); subset[0] = &small[0][0]; subset_length[1] = 10; subset_reported_length[1] = 11; tvb_subset[1] = tvb_new_subset(tvb_large[0], -10, 10, 11); subset[1] = &large[0][9]; subset_length[2] = 16; subset_reported_length[2] = 17; tvb_subset[2] = tvb_new_subset(tvb_small[1], -16, -1, 17); subset[2] = &small[1][0]; subset_length[3] = 3; subset_reported_length[3] = 4; tvb_subset[3] = tvb_new_subset(tvb_subset[0], 0, 3, 4); subset[3] = &small[0][0]; subset_length[4] = 5; subset_reported_length[4] = 6; tvb_subset[4] = tvb_new_subset(tvb_subset[1], -5, 5, 6); subset[4] = &large[0][14]; subset_length[5] = 8; subset_reported_length[5] = 9; tvb_subset[5] = tvb_new_subset(tvb_subset[2], 4, 8, 9); subset[5] = &small[1][4]; /* Test the TVBUFF_SUBSET objects. */ test(tvb_subset[0], "Subset 0", subset[0], subset_length[0], subset_reported_length[0]); test(tvb_subset[1], "Subset 1", subset[1], subset_length[1], subset_reported_length[1]); test(tvb_subset[2], "Subset 2", subset[2], subset_length[2], subset_reported_length[2]); test(tvb_subset[3], "Subset 3", subset[3], subset_length[3], subset_reported_length[3]); test(tvb_subset[4], "Subset 4", subset[4], subset_length[4], subset_reported_length[4]); test(tvb_subset[5], "Subset 5", subset[5], subset_length[5], subset_reported_length[5]); /* One Real */ printf("Making Composite 0\n"); tvb_comp[0] = tvb_new_composite(); comp_length[0] = small_length[0]; comp_reported_length[0] = small_reported_length[0]; comp[0] = small[0]; tvb_composite_append(tvb_comp[0], tvb_small[0]); tvb_composite_finalize(tvb_comp[0]); /* Two Reals */ printf("Making Composite 1\n"); tvb_comp[1] = tvb_new_composite(); comp_length[1] = small_length[0] + small_length[1]; comp_reported_length[1] = small_reported_length[0] + small_reported_length[1]; comp[1] = (guint8*)g_malloc(comp_length[1]); memcpy(comp[1], small[0], small_length[0]); memcpy(&comp[1][small_length[0]], small[1], small_length[1]); tvb_composite_append(tvb_comp[1], tvb_small[0]); tvb_composite_append(tvb_comp[1], tvb_small[1]); tvb_composite_finalize(tvb_comp[1]); /* One subset */ printf("Making Composite 2\n"); tvb_comp[2] = tvb_new_composite(); comp_length[2] = subset_length[1]; comp_reported_length[2] = subset_reported_length[1]; comp[2] = subset[1]; tvb_composite_append(tvb_comp[2], tvb_subset[1]); tvb_composite_finalize(tvb_comp[2]); /* Two subsets */ printf("Making Composite 3\n"); tvb_comp[3] = tvb_new_composite(); comp_length[3] = subset_length[4] + subset_length[5]; comp_reported_length[3] = subset_reported_length[4] + subset_reported_length[5]; comp[3] = (guint8*)g_malloc(comp_length[3]); memcpy(comp[3], subset[4], subset_length[4]); memcpy(&comp[3][subset_length[4]], subset[5], subset_length[5]); tvb_composite_append(tvb_comp[3], tvb_subset[4]); tvb_composite_append(tvb_comp[3], tvb_subset[5]); tvb_composite_finalize(tvb_comp[3]); /* One real, one subset */ printf("Making Composite 4\n"); tvb_comp[4] = tvb_new_composite(); comp_length[4] = small_length[0] + subset_length[1]; comp_reported_length[4] = small_reported_length[0] + subset_reported_length[1]; comp[4] = (guint8*)g_malloc(comp_length[4]); memcpy(&comp[4][0], small[0], small_length[0]); memcpy(&comp[4][small_length[0]], subset[1], subset_length[1]); tvb_composite_append(tvb_comp[4], tvb_small[0]); tvb_composite_append(tvb_comp[4], tvb_subset[1]); tvb_composite_finalize(tvb_comp[4]); /* 4 composites */ printf("Making Composite 5\n"); tvb_comp[5] = tvb_new_composite(); comp_length[5] = comp_length[0] + comp_length[1] + comp_length[2] + comp_length[3]; comp_reported_length[5] = comp_reported_length[0] + comp_reported_length[1] + comp_reported_length[2] + comp_reported_length[3]; comp[5] = (guint8*)g_malloc(comp_length[5]); len = 0; memcpy(&comp[5][len], comp[0], comp_length[0]); len += comp_length[0]; memcpy(&comp[5][len], comp[1], comp_length[1]); len += comp_length[1]; memcpy(&comp[5][len], comp[2], comp_length[2]); len += comp_length[2]; memcpy(&comp[5][len], comp[3], comp_length[3]); tvb_composite_append(tvb_comp[5], tvb_comp[0]); tvb_composite_append(tvb_comp[5], tvb_comp[1]); tvb_composite_append(tvb_comp[5], tvb_comp[2]); tvb_composite_append(tvb_comp[5], tvb_comp[3]); tvb_composite_finalize(tvb_comp[5]); /* Test the TVBUFF_COMPOSITE objects. */ test(tvb_comp[0], "Composite 0", comp[0], comp_length[0], comp_reported_length[0]); test(tvb_comp[1], "Composite 1", comp[1], comp_length[1], comp_reported_length[1]); test(tvb_comp[2], "Composite 2", comp[2], comp_length[2], comp_reported_length[2]); test(tvb_comp[3], "Composite 3", comp[3], comp_length[3], comp_reported_length[3]); test(tvb_comp[4], "Composite 4", comp[4], comp_length[4], comp_reported_length[4]); test(tvb_comp[5], "Composite 5", comp[5], comp_length[5], comp_reported_length[5]); /* free memory. */ /* Don't free: comp[0] */ g_free(comp[1]); /* Don't free: comp[2] */ g_free(comp[3]); g_free(comp[4]); g_free(comp[5]); tvb_free_chain(tvb_parent); /* should free all tvb's and associated data */ } /* Note: valgrind can be used to check for tvbuff memory leaks */ int main(void) { /* For valgrind: See GLib documentation: "Running GLib Applications" */ g_setenv("G_DEBUG", "gc-friendly", 1); g_setenv("G_SLICE", "always-malloc", 1); except_init(); run_tests(); except_deinit(); exit(failed?1:0); } /* * Editor modelines - http://www.wireshark.org/tools/modelines.html * * Local variables: * c-basic-offset: 8 * tab-width: 8 * indent-tabs-mode: t * End: * * vi: set shiftwidth=8 tabstop=8 noexpandtab: * :indentSize=8:tabSize=8:noTabs=false: */