/* * Tests for WIDL and RPC server/clients. * * Copyright (C) Google 2007 (Dan Hipschman) * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include "wine/test.h" #include "server.h" #include "server_defines.h" #include #include #include #define PORT "4114" #define PIPE "\\pipe\\wine_rpcrt4_test" #define INT_CODE 4198 static const char *progname; static HANDLE stop_event; void __RPC_FAR *__RPC_USER midl_user_allocate(size_t n) { return malloc(n); } void __RPC_USER midl_user_free(void __RPC_FAR *p) { free(p); } static char * xstrdup(const char *s) { char *d = HeapAlloc(GetProcessHeap(), 0, strlen(s) + 1); strcpy(d, s); return d; } int s_int_return(void) { return INT_CODE; } int s_square(int x) { return x * x; } int s_sum(int x, int y) { return x + y; } void s_square_out(int x, int *y) { *y = s_square(x); } void s_square_ref(int *x) { *x = s_square(*x); } int s_str_length(const char *s) { return strlen(s); } int s_cstr_length(const char *s, int n) { int len = 0; while (0 < n-- && *s++) ++len; return len; } int s_dot_self(vector_t *v) { return s_square(v->x) + s_square(v->y) + s_square(v->z); } double s_square_half(double x, double *y) { *y = x / 2.0; return x * x; } float s_square_half_float(float x, float *y) { *y = x / 2.0f; return x * x; } long s_square_half_long(long x, long *y) { *y = x / 2; return x * x; } int s_sum_fixed_array(int a[5]) { return a[0] + a[1] + a[2] + a[3] + a[4]; } int s_pints_sum(pints_t *pints) { return *pints->pi + **pints->ppi + ***pints->pppi; } double s_ptypes_sum(ptypes_t *pt) { return *pt->pc + *pt->ps + *pt->pl + *pt->pf + *pt->pd; } int s_dot_pvectors(pvectors_t *p) { return p->pu->x * (*p->pv)->x + p->pu->y * (*p->pv)->y + p->pu->z * (*p->pv)->z; } int s_sum_sp(sp_t *sp) { return sp->x + sp->s->x; } double s_square_sun(sun_t *su) { switch (su->s) { case SUN_I: return su->u.i * su->u.i; case SUN_F1: case SUN_F2: return su->u.f * su->u.f; case SUN_PI: return (*su->u.pi) * (*su->u.pi); default: return 0.0; } } int s_test_list_length(test_list_t *list) { return (list->t == TL_LIST ? 1 + s_test_list_length(list->u.tail) : 0); } int s_sum_fixed_int_3d(int m[2][3][4]) { int i, j, k; int sum = 0; for (i = 0; i < 2; ++i) for (j = 0; j < 3; ++j) for (k = 0; k < 4; ++k) sum += m[i][j][k]; return sum; } int s_sum_conf_array(int x[], int n) { int *p = x, *end = p + n; int sum = 0; while (p < end) sum += *p++; return sum; } int s_sum_unique_conf_array(int x[], int n) { return s_sum_conf_array(x, n); } int s_sum_unique_conf_ptr(int *x, int n) { return x ? s_sum_conf_array(x, n) : 0; } int s_sum_var_array(int x[20], int n) { ok(0 <= n, "RPC sum_var_array\n"); ok(n <= 20, "RPC sum_var_array\n"); return s_sum_conf_array(x, n); } int s_dot_two_vectors(vector_t vs[2]) { return vs[0].x * vs[1].x + vs[0].y * vs[1].y + vs[0].z * vs[1].z; } int s_sum_cs(cs_t *cs) { return s_sum_conf_array(cs->ca, cs->n); } int s_sum_cps(cps_t *cps) { int sum = 0; int i; for (i = 0; i < *cps->pn; ++i) sum += cps->ca1[i]; for (i = 0; i < 2 * cps->n; ++i) sum += cps->ca2[i]; return sum; } int s_sum_cpsc(cpsc_t *cpsc) { int sum = 0; int i; for (i = 0; i < (cpsc->c ? cpsc->a : cpsc->b); ++i) sum += cpsc->ca[i]; return sum; } int s_square_puint(puint_t p) { int n = atoi(p); return n * n; } int s_sum_puints(puints_t *p) { int sum = 0; int i; for (i = 0; i < p->n; ++i) sum += atoi(p->ps[i]); return sum; } int s_sum_cpuints(cpuints_t *p) { int sum = 0; int i; for (i = 0; i < p->n; ++i) sum += atoi(p->ps[i]); return sum; } int s_dot_copy_vectors(vector_t u, vector_t v) { return u.x * v.x + u.y * v.y + u.z * v.z; } int s_square_test_us(test_us_t *tus) { int n = atoi(tus->us.x); return n * n; } double s_square_encu(encu_t *eu) { switch (eu->t) { case ENCU_I: return eu->tagged_union.i * eu->tagged_union.i; case ENCU_F: return eu->tagged_union.f * eu->tagged_union.f; default: return 0.0; } } int s_sum_parr(int *a[3]) { return s_sum_pcarr(a, 3); } int s_sum_pcarr(int *a[], int n) { int i, s = 0; for (i = 0; i < n; ++i) s += *a[i]; return s; } int s_enum_ord(e_t e) { switch (e) { case E1: return 1; case E2: return 2; case E3: return 3; case E4: return 4; default: return 0; } } double s_square_encue(encue_t *eue) { switch (eue->t) { case E1: return eue->tagged_union.i1 * eue->tagged_union.i1; case E2: return eue->tagged_union.f2 * eue->tagged_union.f2; default: return 0.0; } } int s_sum_toplev_conf_2n(int *x, int n) { int sum = 0; int i; for (i = 0; i < 2 * n; ++i) sum += x[i]; return sum; } int s_sum_toplev_conf_cond(int *x, int a, int b, int c) { int sum = 0; int n = c ? a : b; int i; for (i = 0; i < n; ++i) sum += x[i]; return sum; } double s_sum_aligns(aligns_t *a) { return a->c + a->i + a->s + a->d; } int s_sum_padded(padded_t *p) { return p->i + p->c; } int s_sum_padded2(padded_t ps[2]) { return s_sum_padded(&ps[0]) + s_sum_padded(&ps[1]); } int s_sum_padded_conf(padded_t *ps, int n) { int sum = 0; int i; for (i = 0; i < n; ++i) sum += s_sum_padded(&ps[i]); return sum; } int s_sum_bogus(bogus_t *b) { return *b->h.p1 + *b->p2 + *b->p3 + b->c; } void s_check_null(int *null) { ok(!null, "RPC check_null\n"); } int s_str_struct_len(str_struct_t *s) { return lstrlenA(s->s); } int s_wstr_struct_len(wstr_struct_t *s) { return lstrlenW(s->s); } int s_sum_doub_carr(doub_carr_t *dc) { int i, j; int sum = 0; for (i = 0; i < dc->n; ++i) for (j = 0; j < dc->a[i]->n; ++j) sum += dc->a[i]->a[j]; return sum; } void s_make_pyramid_doub_carr(unsigned char n, doub_carr_t **dc) { doub_carr_t *t; int i, j; t = MIDL_user_allocate(FIELD_OFFSET(doub_carr_t, a[n])); t->n = n; for (i = 0; i < n; ++i) { int v = i + 1; t->a[i] = MIDL_user_allocate(FIELD_OFFSET(doub_carr_1_t, a[v])); t->a[i]->n = v; for (j = 0; j < v; ++j) t->a[i]->a[j] = j + 1; } *dc = t; } unsigned s_hash_bstr(bstr_t b) { short n = b[-1]; short *s = b; unsigned hash = 0; short i; for (i = 0; i < n; ++i) hash = 5 * hash + (unsigned) s[i]; return hash; } void s_stop(void) { ok(RPC_S_OK == RpcMgmtStopServerListening(NULL), "RpcMgmtStopServerListening\n"); ok(RPC_S_OK == RpcServerUnregisterIf(NULL, NULL, FALSE), "RpcServerUnregisterIf\n"); ok(SetEvent(stop_event), "SetEvent\n"); } static void make_cmdline(char buffer[MAX_PATH], const char *test) { sprintf(buffer, "%s server %s", progname, test); } static int run_client(const char *test) { char cmdline[MAX_PATH]; PROCESS_INFORMATION info; STARTUPINFOA startup; DWORD exitcode; memset(&startup, 0, sizeof startup); startup.cb = sizeof startup; make_cmdline(cmdline, test); ok(CreateProcessA(NULL, cmdline, NULL, NULL, FALSE, 0L, NULL, NULL, &startup, &info), "CreateProcess\n"); ok(WaitForSingleObject(info.hProcess, 30000) == WAIT_OBJECT_0, "Child process termination\n"); ok(GetExitCodeProcess(info.hProcess, &exitcode), "GetExitCodeProcess\n"); ok(CloseHandle(info.hProcess), "CloseHandle\n"); ok(CloseHandle(info.hThread), "CloseHandle\n"); return exitcode == 0; } static void basic_tests(void) { char string[] = "I am a string"; WCHAR wstring[] = {'I',' ','a','m',' ','a',' ','w','s','t','r','i','n','g', 0}; int f[5] = {1, 3, 0, -2, -4}; vector_t a = {1, 3, 7}; vector_t vec1 = {4, -2, 1}, vec2 = {-5, 2, 3}, *pvec2 = &vec2; pvectors_t pvecs = {&vec1, &pvec2}; sp_inner_t spi = {42}; sp_t sp = {-13, &spi}; aligns_t aligns = {3, 4, 5, 6.0}; pints_t pints; ptypes_t ptypes; padded_t padded; padded_t padded2[2]; bogus_t bogus; int i1, i2, i3, *pi2, *pi3, **ppi3; double u, v; float s, t; long q, r; short h; char c; int x; str_struct_t ss = {string}; wstr_struct_t ws = {wstring}; ok(int_return() == INT_CODE, "RPC int_return\n"); ok(square(7) == 49, "RPC square\n"); ok(sum(23, -4) == 19, "RPC sum\n"); x = 0; square_out(11, &x); ok(x == 121, "RPC square_out\n"); x = 5; square_ref(&x); ok(x == 25, "RPC square_ref\n"); ok(str_length(string) == strlen(string), "RPC str_length\n"); ok(dot_self(&a) == 59, "RPC dot_self\n"); ok(str_struct_len(&ss) == lstrlenA(string), "RPC str_struct_len\n"); ok(wstr_struct_len(&ws) == lstrlenW(wstring), "RPC str_struct_len\n"); v = 0.0; u = square_half(3.0, &v); ok(u == 9.0, "RPC square_half\n"); ok(v == 1.5, "RPC square_half\n"); t = 0.0f; s = square_half_float(3.0f, &t); ok(s == 9.0f, "RPC square_half_float\n"); ok(t == 1.5f, "RPC square_half_float\n"); r = 0; q = square_half_long(3, &r); ok(q == 9, "RPC square_half_long\n"); ok(r == 1, "RPC square_half_long\n"); i1 = 19; i2 = -3; i3 = -29; pi2 = &i2; pi3 = &i3; ppi3 = &pi3; pints.pi = &i1; pints.ppi = &pi2; pints.pppi = &ppi3; ok(pints_sum(&pints) == -13, "RPC pints_sum\n"); c = 10; h = 3; q = 14; s = -5.0f; u = 11.0; ptypes.pc = &c; ptypes.ps = &h; ptypes.pl = &q; ptypes.pf = &s; ptypes.pd = &u; ok(ptypes_sum(&ptypes) == 33.0, "RPC ptypes_sum\n"); ok(dot_pvectors(&pvecs) == -21, "RPC dot_pvectors\n"); ok(dot_copy_vectors(vec1, vec2) == -21, "RPC dot_copy_vectors\n"); ok(sum_fixed_array(f) == -2, "RPC sum_fixed_array\n"); ok(sum_sp(&sp) == 29, "RPC sum_sp\n"); ok(enum_ord(E1) == 1, "RPC enum_ord\n"); ok(enum_ord(E2) == 2, "RPC enum_ord\n"); ok(enum_ord(E3) == 3, "RPC enum_ord\n"); ok(enum_ord(E4) == 4, "RPC enum_ord\n"); ok(sum_aligns(&aligns) == 18.0, "RPC sum_aligns\n"); padded.i = -3; padded.c = 8; ok(sum_padded(&padded) == 5, "RPC sum_padded\n"); padded2[0].i = -5; padded2[0].c = 1; padded2[1].i = 3; padded2[1].c = 7; ok(sum_padded2(padded2) == 6, "RPC sum_padded2\n"); padded2[0].i = -5; padded2[0].c = 1; padded2[1].i = 3; padded2[1].c = 7; ok(sum_padded_conf(padded2, 2) == 6, "RPC sum_padded_conf\n"); i1 = 14; i2 = -7; i3 = -4; bogus.h.p1 = &i1; bogus.p2 = &i2; bogus.p3 = &i3; bogus.c = 9; ok(sum_bogus(&bogus) == 12, "RPC sum_bogus\n"); check_null(NULL); } static void union_tests(void) { encue_t eue; encu_t eu; sun_t su; int i; su.s = SUN_I; su.u.i = 9; ok(square_sun(&su) == 81.0, "RPC square_sun\n"); su.s = SUN_F1; su.u.f = 5.0; ok(square_sun(&su) == 25.0, "RPC square_sun\n"); su.s = SUN_F2; su.u.f = -2.0; ok(square_sun(&su) == 4.0, "RPC square_sun\n"); su.s = SUN_PI; su.u.pi = &i; i = 11; ok(square_sun(&su) == 121.0, "RPC square_sun\n"); eu.t = ENCU_I; eu.tagged_union.i = 7; ok(square_encu(&eu) == 49.0, "RPC square_encu\n"); eu.t = ENCU_F; eu.tagged_union.f = 3.0; ok(square_encu(&eu) == 9.0, "RPC square_encu\n"); eue.t = E1; eue.tagged_union.i1 = 8; ok(square_encue(&eue) == 64.0, "RPC square_encue\n"); eue.t = E2; eue.tagged_union.f2 = 10.0; ok(square_encue(&eue) == 100.0, "RPC square_encue\n"); } static test_list_t * null_list(void) { test_list_t *n = HeapAlloc(GetProcessHeap(), 0, sizeof *n); n->t = TL_NULL; return n; } static test_list_t * make_list(test_list_t *tail) { test_list_t *n = HeapAlloc(GetProcessHeap(), 0, sizeof *n); n->t = TL_LIST; n->u.tail = tail; return n; } static void free_list(test_list_t *list) { if (list->t == TL_LIST) free_list(list->u.tail); HeapFree(GetProcessHeap(), 0, list); } ULONG __RPC_USER puint_t_UserSize(ULONG *flags, ULONG start, puint_t *p) { return start + sizeof(int); } unsigned char * __RPC_USER puint_t_UserMarshal(ULONG *flags, unsigned char *buffer, puint_t *p) { int n = atoi(*p); memcpy(buffer, &n, sizeof n); return buffer + sizeof n; } unsigned char * __RPC_USER puint_t_UserUnmarshal(ULONG *flags, unsigned char *buffer, puint_t *p) { int n; memcpy(&n, buffer, sizeof n); *p = HeapAlloc(GetProcessHeap(), 0, 10); sprintf(*p, "%d", n); return buffer + sizeof n; } void __RPC_USER puint_t_UserFree(ULONG *flags, puint_t *p) { HeapFree(GetProcessHeap(), 0, *p); } ULONG __RPC_USER us_t_UserSize(ULONG *flags, ULONG start, us_t *pus) { return start + sizeof(struct wire_us); } unsigned char * __RPC_USER us_t_UserMarshal(ULONG *flags, unsigned char *buffer, us_t *pus) { struct wire_us wus; wus.x = atoi(pus->x); memcpy(buffer, &wus, sizeof wus); return buffer + sizeof wus; } unsigned char * __RPC_USER us_t_UserUnmarshal(ULONG *flags, unsigned char *buffer, us_t *pus) { struct wire_us wus; memcpy(&wus, buffer, sizeof wus); pus->x = HeapAlloc(GetProcessHeap(), 0, 10); sprintf(pus->x, "%d", wus.x); return buffer + sizeof wus; } void __RPC_USER us_t_UserFree(ULONG *flags, us_t *pus) { HeapFree(GetProcessHeap(), 0, pus->x); } ULONG __RPC_USER bstr_t_UserSize(ULONG *flags, ULONG start, bstr_t *b) { return start + FIELD_OFFSET(wire_bstr_t, data[(*b)[-1]]); } unsigned char * __RPC_USER bstr_t_UserMarshal(ULONG *flags, unsigned char *buffer, bstr_t *b) { wire_bstr_t *wb = (wire_bstr_t *) buffer; wb->n = (*b)[-1]; memcpy(&wb->data, *b, wb->n * sizeof wb->data[0]); return buffer + FIELD_OFFSET(wire_bstr_t, data[wb->n]); } unsigned char * __RPC_USER bstr_t_UserUnmarshal(ULONG *flags, unsigned char *buffer, bstr_t *b) { wire_bstr_t *wb = (wire_bstr_t *) buffer; short *data = HeapAlloc(GetProcessHeap(), 0, (wb->n + 1) * sizeof *data); data[0] = wb->n; memcpy(&data[1], wb->data, wb->n * sizeof data[1]); *b = &data[1]; return buffer + FIELD_OFFSET(wire_bstr_t, data[wb->n]); } void __RPC_USER bstr_t_UserFree(ULONG *flags, bstr_t *b) { HeapFree(GetProcessHeap(), 0, &((*b)[-1])); } static void pointer_tests(void) { int a[] = {1, 2, 3, 4}; char p1[] = "11"; test_list_t *list = make_list(make_list(make_list(null_list()))); test_us_t tus = {{p1}}; int *pa[4]; puints_t pus; cpuints_t cpus; short bstr_data[] = { 5, 'H', 'e', 'l', 'l', 'o' }; bstr_t bstr = &bstr_data[1]; ok(test_list_length(list) == 3, "RPC test_list_length\n"); ok(square_puint(p1) == 121, "RPC square_puint\n"); pus.n = 4; pus.ps = HeapAlloc(GetProcessHeap(), 0, pus.n * sizeof pus.ps[0]); pus.ps[0] = xstrdup("5"); pus.ps[1] = xstrdup("6"); pus.ps[2] = xstrdup("7"); pus.ps[3] = xstrdup("8"); ok(sum_puints(&pus) == 26, "RPC sum_puints\n"); HeapFree(GetProcessHeap(), 0, pus.ps[0]); HeapFree(GetProcessHeap(), 0, pus.ps[1]); HeapFree(GetProcessHeap(), 0, pus.ps[2]); HeapFree(GetProcessHeap(), 0, pus.ps[3]); HeapFree(GetProcessHeap(), 0, pus.ps); cpus.n = 4; cpus.ps = HeapAlloc(GetProcessHeap(), 0, cpus.n * sizeof cpus.ps[0]); cpus.ps[0] = xstrdup("5"); cpus.ps[1] = xstrdup("6"); cpus.ps[2] = xstrdup("7"); cpus.ps[3] = xstrdup("8"); ok(sum_cpuints(&cpus) == 26, "RPC sum_puints\n"); HeapFree(GetProcessHeap(), 0, cpus.ps[0]); HeapFree(GetProcessHeap(), 0, cpus.ps[1]); HeapFree(GetProcessHeap(), 0, cpus.ps[2]); HeapFree(GetProcessHeap(), 0, cpus.ps[3]); HeapFree(GetProcessHeap(), 0, cpus.ps); ok(square_test_us(&tus) == 121, "RPC square_test_us\n"); pa[0] = &a[0]; pa[1] = &a[1]; pa[2] = &a[2]; ok(sum_parr(pa) == 6, "RPC sum_parr\n"); pa[0] = &a[0]; pa[1] = &a[1]; pa[2] = &a[2]; pa[3] = &a[3]; ok(sum_pcarr(pa, 4) == 10, "RPC sum_pcarr\n"); ok(hash_bstr(bstr) == s_hash_bstr(bstr), "RPC hash_bstr_data\n"); free_list(list); } static int check_pyramid_doub_carr(doub_carr_t *dc) { int i, j; for (i = 0; i < dc->n; ++i) for (j = 0; j < dc->a[i]->n; ++j) if (dc->a[i]->a[j] != j + 1) return FALSE; return TRUE; } static void free_pyramid_doub_carr(doub_carr_t *dc) { int i; for (i = 0; i < dc->n; ++i) MIDL_user_free(dc->a[i]); MIDL_user_free(dc); } static void array_tests(void) { const char str1[25] = "Hello"; int m[2][3][4] = { {{1, 2, 3, 4}, {-1, -3, -5, -7}, {0, 2, 4, 6}}, {{1, -2, 3, -4}, {2, 3, 5, 7}, {-4, -1, -14, 4114}} }; int c[] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9}; vector_t vs[2] = {{1, -2, 3}, {4, -5, -6}}; cps_t cps; cpsc_t cpsc; cs_t *cs; int n; int ca[5] = {1, -2, 3, -4, 5}; doub_carr_t *dc; ok(cstr_length(str1, sizeof str1) == strlen(str1), "RPC cstr_length\n"); ok(sum_fixed_int_3d(m) == 4116, "RPC sum_fixed_int_3d\n"); ok(sum_conf_array(c, 10) == 45, "RPC sum_conf_array\n"); ok(sum_conf_array(&c[5], 2) == 11, "RPC sum_conf_array\n"); ok(sum_conf_array(&c[7], 1) == 7, "RPC sum_conf_array\n"); ok(sum_conf_array(&c[2], 0) == 0, "RPC sum_conf_array\n"); ok(sum_unique_conf_array(ca, 4) == -2, "RPC sum_unique_conf_array\n"); ok(sum_unique_conf_ptr(ca, 5) == 3, "RPC sum_unique_conf_array\n"); ok(sum_unique_conf_ptr(NULL, 10) == 0, "RPC sum_unique_conf_array\n"); ok(sum_var_array(c, 10) == 45, "RPC sum_conf_array\n"); ok(sum_var_array(&c[5], 2) == 11, "RPC sum_conf_array\n"); ok(sum_var_array(&c[7], 1) == 7, "RPC sum_conf_array\n"); ok(sum_var_array(&c[2], 0) == 0, "RPC sum_conf_array\n"); ok(dot_two_vectors(vs) == -4, "RPC dot_two_vectors\n"); cs = HeapAlloc(GetProcessHeap(), 0, FIELD_OFFSET(cs_t, ca[5])); cs->n = 5; cs->ca[0] = 3; cs->ca[1] = 5; cs->ca[2] = -2; cs->ca[3] = -1; cs->ca[4] = -4; ok(sum_cs(cs) == 1, "RPC sum_cs\n"); HeapFree(GetProcessHeap(), 0, cs); n = 5; cps.pn = &n; cps.ca1 = &c[2]; cps.n = 3; cps.ca2 = &c[3]; ok(sum_cps(&cps) == 53, "RPC sum_cps\n"); cpsc.a = 4; cpsc.b = 5; cpsc.c = 1; cpsc.ca = c; ok(sum_cpsc(&cpsc) == 6, "RPC sum_cpsc\n"); cpsc.a = 4; cpsc.b = 5; cpsc.c = 0; cpsc.ca = c; ok(sum_cpsc(&cpsc) == 10, "RPC sum_cpsc\n"); ok(sum_toplev_conf_2n(c, 3) == 15, "RPC sum_toplev_conf_2n\n"); ok(sum_toplev_conf_cond(c, 5, 6, 1) == 10, "RPC sum_toplev_conf_cond\n"); ok(sum_toplev_conf_cond(c, 5, 6, 0) == 15, "RPC sum_toplev_conf_cond\n"); dc = malloc(FIELD_OFFSET(doub_carr_t, a[2])); dc->n = 2; dc->a[0] = malloc(FIELD_OFFSET(doub_carr_1_t, a[3])); dc->a[0]->n = 3; dc->a[0]->a[0] = 5; dc->a[0]->a[1] = 1; dc->a[0]->a[2] = 8; dc->a[1] = malloc(FIELD_OFFSET(doub_carr_1_t, a[2])); dc->a[1]->n = 2; dc->a[1]->a[0] = 2; dc->a[1]->a[1] = 3; ok(sum_doub_carr(dc) == 19, "RPC sum_doub_carr\n"); free(dc->a[0]); free(dc->a[1]); free(dc); dc = NULL; make_pyramid_doub_carr(4, &dc); ok(check_pyramid_doub_carr(dc), "RPC make_pyramid_doub_carr\n"); free_pyramid_doub_carr(dc); } static void run_tests(void) { basic_tests(); union_tests(); pointer_tests(); array_tests(); } static void client(const char *test) { if (strcmp(test, "tcp_basic") == 0) { static unsigned char iptcp[] = "ncacn_ip_tcp"; static unsigned char address[] = "127.0.0.1"; static unsigned char port[] = PORT; unsigned char *binding; ok(RPC_S_OK == RpcStringBindingCompose(NULL, iptcp, address, port, NULL, &binding), "RpcStringBindingCompose\n"); ok(RPC_S_OK == RpcBindingFromStringBinding(binding, &IServer_IfHandle), "RpcBindingFromStringBinding\n"); run_tests(); ok(RPC_S_OK == RpcStringFree(&binding), "RpcStringFree\n"); ok(RPC_S_OK == RpcBindingFree(&IServer_IfHandle), "RpcBindingFree\n"); } else if (strcmp(test, "np_basic") == 0) { static unsigned char np[] = "ncacn_np"; static unsigned char address[] = "\\\\."; static unsigned char pipe[] = PIPE; unsigned char *binding; ok(RPC_S_OK == RpcStringBindingCompose(NULL, np, address, pipe, NULL, &binding), "RpcStringBindingCompose\n"); ok(RPC_S_OK == RpcBindingFromStringBinding(binding, &IServer_IfHandle), "RpcBindingFromStringBinding\n"); run_tests(); stop(); ok(RPC_S_OK == RpcStringFree(&binding), "RpcStringFree\n"); ok(RPC_S_OK == RpcBindingFree(&IServer_IfHandle), "RpcBindingFree\n"); } } static void server(void) { static unsigned char iptcp[] = "ncacn_ip_tcp"; static unsigned char port[] = PORT; static unsigned char np[] = "ncacn_np"; static unsigned char pipe[] = PIPE; ok(RPC_S_OK == RpcServerUseProtseqEp(iptcp, 20, port, NULL), "RpcServerUseProtseqEp\n"); ok(RPC_S_OK == RpcServerRegisterIf(s_IServer_v0_0_s_ifspec, NULL, NULL), "RpcServerRegisterIf\n"); ok(RPC_S_OK == RpcServerListen(1, 20, TRUE), "RpcServerListen\n"); stop_event = CreateEvent(NULL, FALSE, FALSE, NULL); ok(stop_event != NULL, "CreateEvent failed\n"); ok(run_client("tcp_basic"), "tcp_basic client test failed\n"); ok(RPC_S_OK == RpcServerUseProtseqEp(np, 0, pipe, NULL), "RpcServerUseProtseqEp\n"); ok(run_client("np_basic"), "np_basic client test failed\n"); ok(WAIT_OBJECT_0 == WaitForSingleObject(stop_event, 60000), "WaitForSingleObject\n"); todo_wine { ok(RPC_S_OK == RpcMgmtWaitServerListen(), "RpcMgmtWaitServerListening\n"); } } START_TEST(server) { int argc; char **argv; argc = winetest_get_mainargs(&argv); progname = argv[0]; if (argc == 3) { RpcTryExcept { client(argv[2]); } RpcExcept(TRUE) { trace("Exception %d\n", RpcExceptionCode()); } RpcEndExcept } else server(); }