13536213672

Committed 26 Feb 2025 03:22AM UTC coverage: 91.691% (-0.005%) from 91.696%

Build # 13536213672

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Merge pull request #4718 from randombit/jack/split-cpuid

Make cpuid module optional

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/src/tests/test_simd.cpp

/*
* (C) 2017 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/

#include "tests.h"

#if defined(BOTAN_HAS_SIMD_32)
   #include <botan/internal/bswap.h>
   #include <botan/internal/loadstor.h>
   #include <botan/internal/rotate.h>
   #include <botan/internal/simd_32.h>
   #include <botan/internal/stl_util.h>
#endif

#if defined(BOTAN_HAS_CPUID)
   #include <botan/internal/cpuid.h>
#endif

namespace Botan_Tests {

#if defined(BOTAN_HAS_SIMD_32)

class SIMD_32_Tests final : public Test {
   public:
      std::vector<Test::Result> run() override {
         Test::Result result("SIMD_4x32");

   #if defined(BOTAN_HAS_CPUID)
         if(Botan::CPUID::has_simd_32() == false) {
            result.test_note("Skipping SIMD_4x32 tests due to missing CPU support at runtime");
            return {result};
         }
   #endif

         const uint32_t pat1 = 0xAABBCCDD;
         const uint32_t pat2 = 0x87654321;
         const uint32_t pat3 = 0x01234567;
         const uint32_t pat4 = 0xC0D0E0F0;

         // pat1 + pat{1,2,3,4}
         // precomputed to avoid integer overflow warnings
         const uint32_t pat1_1 = 0x557799BA;
         const uint32_t pat1_2 = 0x32210FFE;
         const uint32_t pat1_3 = 0xABDF1244;
         const uint32_t pat1_4 = 0x6B8CADCD;

         test_eq(result, "default init", Botan::SIMD_4x32(), 0, 0, 0, 0);
         test_eq(result, "SIMD scalar constructor", Botan::SIMD_4x32(1, 2, 3, 4), 1, 2, 3, 4);

         const Botan::SIMD_4x32 splat = Botan::SIMD_4x32::splat(pat1);

         test_eq(result, "splat", splat, pat1, pat1, pat1, pat1);

         const Botan::SIMD_4x32 input(pat1, pat2, pat3, pat4);

         Botan::SIMD_4x32 rol = input.rotl<3>();

         test_eq(result,
                 "rotl",
                 rol,
                 Botan::rotl<3>(pat1),
                 Botan::rotl<3>(pat2),
                 Botan::rotl<3>(pat3),
                 Botan::rotl<3>(pat4));

         Botan::SIMD_4x32 ror = input.rotr<9>();

         test_eq(result,
                 "rotr",
                 ror,
                 Botan::rotr<9>(pat1),
                 Botan::rotr<9>(pat2),
                 Botan::rotr<9>(pat3),
                 Botan::rotr<9>(pat4));

         Botan::SIMD_4x32 add = input + splat;
         test_eq(result, "add +", add, pat1_1, pat1_2, pat1_3, pat1_4);

         add -= splat;
         test_eq(result, "sub -=", add, pat1, pat2, pat3, pat4);

         add += splat;
         test_eq(result, "add +=", add, pat1_1, pat1_2, pat1_3, pat1_4);

         test_eq(result, "xor", input ^ splat, 0, pat2 ^ pat1, pat3 ^ pat1, pat4 ^ pat1);
         test_eq(result, "or", input | splat, pat1, pat2 | pat1, pat3 | pat1, pat4 | pat1);
         test_eq(result, "and", input & splat, pat1, pat2 & pat1, pat3 & pat1, pat4 & pat1);

         Botan::SIMD_4x32 blender = input;
         blender |= splat;
         test_eq(result, "|=", blender, pat1, pat2 | pat1, pat3 | pat1, pat4 | pat1);
         blender &= splat;
         test_eq(result, "&=", blender, pat1, pat1, pat1, pat1);
         blender ^= splat;
         test_eq(result, "^=", blender, 0, 0, 0, 0);

         blender = ~blender;
         test_eq(result, "~", blender, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF);

         blender = blender.shr<23>();
         test_eq(result, ">>", blender, 0x1FF, 0x1FF, 0x1FF, 0x1FF);

         blender = blender.shl<27>();
         test_eq(result, "<<", blender, 0xF8000000, 0xF8000000, 0xF8000000, 0xF8000000);

         blender = ~blender;
         test_eq(result, "~", blender, 0x7FFFFFF, 0x7FFFFFF, 0x7FFFFFF, 0x7FFFFFF);

         blender = input.andc(~blender);
         test_eq(
            result, "andc", blender, ~pat1 & 0xF8000000, ~pat2 & 0xF8000000, ~pat3 & 0xF8000000, ~pat4 & 0xF8000000);

         test_eq(result,
                 "bswap",
                 input.bswap(),
                 Botan::reverse_bytes(pat1),
                 Botan::reverse_bytes(pat2),
                 Botan::reverse_bytes(pat3),
                 Botan::reverse_bytes(pat4));

         Botan::SIMD_4x32 t1(pat1, pat2, pat3, pat4);
         Botan::SIMD_4x32 t2(pat1 + 1, pat2 + 1, pat3 + 1, pat4 + 1);
         Botan::SIMD_4x32 t3(pat1 + 2, pat2 + 2, pat3 + 2, pat4 + 2);
         Botan::SIMD_4x32 t4(pat1 + 3, pat2 + 3, pat3 + 3, pat4 + 3);

         Botan::SIMD_4x32::transpose(t1, t2, t3, t4);

         test_eq(result, "transpose t1", t1, pat1, pat1 + 1, pat1 + 2, pat1 + 3);
         test_eq(result, "transpose t2", t2, pat2, pat2 + 1, pat2 + 2, pat2 + 3);
         test_eq(result, "transpose t3", t3, pat3, pat3 + 1, pat3 + 2, pat3 + 3);
         test_eq(result, "transpose t4", t4, pat4, pat4 + 1, pat4 + 2, pat4 + 3);

         test_eq(result, "shift left 1", input.shift_elems_left<1>(), 0, pat1, pat2, pat3);
         test_eq(result, "shift left 2", input.shift_elems_left<2>(), 0, 0, pat1, pat2);
         test_eq(result, "shift left 3", input.shift_elems_left<3>(), 0, 0, 0, pat1);

         test_eq(result, "shift right 1", input.shift_elems_right<1>(), pat2, pat3, pat4, 0);
         test_eq(result, "shift right 2", input.shift_elems_right<2>(), pat3, pat4, 0, 0);
         test_eq(result, "shift right 3", input.shift_elems_right<3>(), pat4, 0, 0, 0);

         // Test load/stores SIMD wrapper types
         const auto simd_le_in = Botan::hex_decode("ABCDEF01234567890123456789ABCDEF");
         const auto simd_be_in = Botan::hex_decode("0123456789ABCDEFABCDEF0123456789");
         const auto simd_le_array_in = Botan::concat(simd_le_in, simd_be_in);
         const auto simd_be_array_in = Botan::concat(simd_be_in, simd_le_in);

         auto simd_le = Botan::load_le<Botan::SIMD_4x32>(simd_le_in);
         auto simd_be = Botan::load_be<Botan::SIMD_4x32>(simd_be_in);
         auto simd_le_array = Botan::load_le<std::array<Botan::SIMD_4x32, 2>>(simd_le_array_in);
         auto simd_be_array = Botan::load_be<std::array<Botan::SIMD_4x32, 2>>(simd_be_array_in);

         auto simd_le_vec = Botan::store_le<std::vector<uint8_t>>(simd_le);
         auto simd_be_vec = Botan::store_be(simd_be);
         auto simd_le_array_vec = Botan::store_le<std::vector<uint8_t>>(simd_le_array);
         auto simd_be_array_vec = Botan::store_be(simd_be_array);

         result.test_is_eq("roundtrip SIMD little-endian", simd_le_vec, simd_le_in);
         result.test_is_eq(
            "roundtrip SIMD big-endian", std::vector(simd_be_vec.begin(), simd_be_vec.end()), simd_be_in);
         result.test_is_eq("roundtrip SIMD array little-endian", simd_le_array_vec, simd_le_array_in);
         result.test_is_eq("roundtrip SIMD array big-endian",
                           std::vector(simd_be_array_vec.begin(), simd_be_array_vec.end()),
                           simd_be_array_in);

         using StrongSIMD = Botan::Strong<Botan::SIMD_4x32, struct StrongSIMD_>;
         const auto simd_le_strong = Botan::load_le<StrongSIMD>(simd_le_in);
         const auto simd_be_strong = Botan::load_be<StrongSIMD>(simd_be_in);

         result.test_is_eq(
            "roundtrip SIMD strong little-endian", Botan::store_le<std::vector<uint8_t>>(simd_le_strong), simd_le_in);
         result.test_is_eq(
            "roundtrip SIMD strong big-endian", Botan::store_be<std::vector<uint8_t>>(simd_be_strong), simd_be_in);

         return {result};
      }

   private:
      static void test_eq(Test::Result& result,
                          const std::string& op,
                          const Botan::SIMD_4x32& simd,
                          uint32_t exp0,
                          uint32_t exp1,
                          uint32_t exp2,
                          uint32_t exp3) {
         uint8_t arr_be[16 + 15];
         uint8_t arr_be2[16 + 15];
         uint8_t arr_le[16 + 15];
         uint8_t arr_le2[16 + 15];

         for(size_t misalignment = 0; misalignment != 16; ++misalignment) {
            uint8_t* mem_be = arr_be + misalignment;
            uint8_t* mem_be2 = arr_be2 + misalignment;
            uint8_t* mem_le = arr_le + misalignment;
            uint8_t* mem_le2 = arr_le2 + misalignment;

            simd.store_be(mem_be);

            result.test_int_eq(
               "SIMD_4x32 " + op + " elem0 BE", Botan::make_uint32(mem_be[0], mem_be[1], mem_be[2], mem_be[3]), exp0);
            result.test_int_eq(
               "SIMD_4x32 " + op + " elem1 BE", Botan::make_uint32(mem_be[4], mem_be[5], mem_be[6], mem_be[7]), exp1);
            result.test_int_eq(
               "SIMD_4x32 " + op + " elem2 BE", Botan::make_uint32(mem_be[8], mem_be[9], mem_be[10], mem_be[11]), exp2);
            result.test_int_eq("SIMD_4x32 " + op + " elem3 BE",
                               Botan::make_uint32(mem_be[12], mem_be[13], mem_be[14], mem_be[15]),
                               exp3);

            // Check load_be+store_be results in same value
            const Botan::SIMD_4x32 reloaded_be = Botan::SIMD_4x32::load_be(mem_be);
            reloaded_be.store_be(mem_be2);
            result.test_eq(nullptr, "SIMD_4x32 load_be", mem_be, 16, mem_be2, 16);

            simd.store_le(mem_le);

            result.test_int_eq(
               "SIMD_4x32 " + op + " elem0 LE", Botan::make_uint32(mem_le[3], mem_le[2], mem_le[1], mem_le[0]), exp0);
            result.test_int_eq(
               "SIMD_4x32 " + op + " elem1 LE", Botan::make_uint32(mem_le[7], mem_le[6], mem_le[5], mem_le[4]), exp1);
            result.test_int_eq(
               "SIMD_4x32 " + op + " elem2 LE", Botan::make_uint32(mem_le[11], mem_le[10], mem_le[9], mem_le[8]), exp2);
            result.test_int_eq("SIMD_4x32 " + op + " elem3 LE",
                               Botan::make_uint32(mem_le[15], mem_le[14], mem_le[13], mem_le[12]),
                               exp3);

            // Check load_le+store_le results in same value
            const Botan::SIMD_4x32 reloaded_le = Botan::SIMD_4x32::load_le(mem_le);
            reloaded_le.store_le(mem_le2);
            result.test_eq(nullptr, "SIMD_4x32 load_le", mem_le, 16, mem_le2, 16);
         }
      }
};

BOTAN_REGISTER_TEST("utils", "simd_32", SIMD_32_Tests);
#endif

}  // namespace Botan_Tests

1	/*
2	* (C) 2017 Jack Lloyd
3	*
4	* Botan is released under the Simplified BSD License (see license.txt)
5	*/
6
7	#include "tests.h"
8
9	#if defined(BOTAN_HAS_SIMD_32)
10	#include <botan/internal/bswap.h>
11	#include <botan/internal/loadstor.h>
12	#include <botan/internal/rotate.h>
13	#include <botan/internal/simd_32.h>
14	#include <botan/internal/stl_util.h>
15	#endif
16
17	#if defined(BOTAN_HAS_CPUID)
18	#include <botan/internal/cpuid.h>
19	#endif
20
21	namespace Botan_Tests {
22
23	#if defined(BOTAN_HAS_SIMD_32)
24
25	class SIMD_32_Tests final : public Test {	×
26	public:
27	std::vector<Test::Result> run() override {	1✔
28	Test::Result result("SIMD_4x32");	1✔
29
30	#if defined(BOTAN_HAS_CPUID)
31	if(Botan::CPUID::has_simd_32() == false) {	1✔
32	result.test_note("Skipping SIMD_4x32 tests due to missing CPU support at runtime");	×
33	return {result};	×
34	}
35	#endif
36
37	const uint32_t pat1 = 0xAABBCCDD;	1✔
38	const uint32_t pat2 = 0x87654321;	1✔
39	const uint32_t pat3 = 0x01234567;	1✔
40	const uint32_t pat4 = 0xC0D0E0F0;	1✔
41
42	// pat1 + pat{1,2,3,4}
43	// precomputed to avoid integer overflow warnings
44	const uint32_t pat1_1 = 0x557799BA;	1✔
45	const uint32_t pat1_2 = 0x32210FFE;	1✔
46	const uint32_t pat1_3 = 0xABDF1244;	1✔
47	const uint32_t pat1_4 = 0x6B8CADCD;	1✔
48
49	test_eq(result, "default init", Botan::SIMD_4x32(), 0, 0, 0, 0);	1✔
50	test_eq(result, "SIMD scalar constructor", Botan::SIMD_4x32(1, 2, 3, 4), 1, 2, 3, 4);	1✔
51
52	const Botan::SIMD_4x32 splat = Botan::SIMD_4x32::splat(pat1);	1✔
53
54	test_eq(result, "splat", splat, pat1, pat1, pat1, pat1);	1✔
55
56	const Botan::SIMD_4x32 input(pat1, pat2, pat3, pat4);	1✔
57
58	Botan::SIMD_4x32 rol = input.rotl<3>();	1✔
59
60	test_eq(result,	1✔
61	"rotl",
62	rol,
63	Botan::rotl<3>(pat1),
64	Botan::rotl<3>(pat2),
65	Botan::rotl<3>(pat3),
66	Botan::rotl<3>(pat4));
67
68	Botan::SIMD_4x32 ror = input.rotr<9>();	1✔
69
70	test_eq(result,	1✔
71	"rotr",
72	ror,
73	Botan::rotr<9>(pat1),
74	Botan::rotr<9>(pat2),
75	Botan::rotr<9>(pat3),
76	Botan::rotr<9>(pat4));
77
78	Botan::SIMD_4x32 add = input + splat;	1✔
79	test_eq(result, "add +", add, pat1_1, pat1_2, pat1_3, pat1_4);	1✔
80
81	add -= splat;	1✔
82	test_eq(result, "sub -=", add, pat1, pat2, pat3, pat4);	1✔
83
84	add += splat;	1✔
85	test_eq(result, "add +=", add, pat1_1, pat1_2, pat1_3, pat1_4);	1✔
86
87	test_eq(result, "xor", input ^ splat, 0, pat2 ^ pat1, pat3 ^ pat1, pat4 ^ pat1);	1✔
88	test_eq(result, "or", input \| splat, pat1, pat2 \| pat1, pat3 \| pat1, pat4 \| pat1);	1✔
89	test_eq(result, "and", input & splat, pat1, pat2 & pat1, pat3 & pat1, pat4 & pat1);	1✔
90
91	Botan::SIMD_4x32 blender = input;	1✔
92	blender \|= splat;	1✔
93	test_eq(result, "\|=", blender, pat1, pat2 \| pat1, pat3 \| pat1, pat4 \| pat1);	1✔
94	blender &= splat;	1✔
95	test_eq(result, "&=", blender, pat1, pat1, pat1, pat1);	1✔
96	blender ^= splat;	1✔
97	test_eq(result, "^=", blender, 0, 0, 0, 0);	1✔
98
99	blender = ~blender;	1✔
100	test_eq(result, "~", blender, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF);	1✔
101
102	blender = blender.shr<23>();	1✔
103	test_eq(result, ">>", blender, 0x1FF, 0x1FF, 0x1FF, 0x1FF);	1✔
104
105	blender = blender.shl<27>();	1✔
106	test_eq(result, "<<", blender, 0xF8000000, 0xF8000000, 0xF8000000, 0xF8000000);	1✔
107
108	blender = ~blender;	1✔
109	test_eq(result, "~", blender, 0x7FFFFFF, 0x7FFFFFF, 0x7FFFFFF, 0x7FFFFFF);	1✔
110
111	blender = input.andc(~blender);	1✔
112	test_eq(	1✔
113	result, "andc", blender, ~pat1 & 0xF8000000, ~pat2 & 0xF8000000, ~pat3 & 0xF8000000, ~pat4 & 0xF8000000);
114
115	test_eq(result,	1✔
116	"bswap",
117	input.bswap(),	1✔
118	Botan::reverse_bytes(pat1),
119	Botan::reverse_bytes(pat2),
120	Botan::reverse_bytes(pat3),
121	Botan::reverse_bytes(pat4));
122
123	Botan::SIMD_4x32 t1(pat1, pat2, pat3, pat4);	1✔
124	Botan::SIMD_4x32 t2(pat1 + 1, pat2 + 1, pat3 + 1, pat4 + 1);	1✔
125	Botan::SIMD_4x32 t3(pat1 + 2, pat2 + 2, pat3 + 2, pat4 + 2);	1✔
126	Botan::SIMD_4x32 t4(pat1 + 3, pat2 + 3, pat3 + 3, pat4 + 3);	1✔
127
128	Botan::SIMD_4x32::transpose(t1, t2, t3, t4);	1✔
129
130	test_eq(result, "transpose t1", t1, pat1, pat1 + 1, pat1 + 2, pat1 + 3);	1✔
131	test_eq(result, "transpose t2", t2, pat2, pat2 + 1, pat2 + 2, pat2 + 3);	1✔
132	test_eq(result, "transpose t3", t3, pat3, pat3 + 1, pat3 + 2, pat3 + 3);	1✔
133	test_eq(result, "transpose t4", t4, pat4, pat4 + 1, pat4 + 2, pat4 + 3);	1✔
134
135	test_eq(result, "shift left 1", input.shift_elems_left<1>(), 0, pat1, pat2, pat3);	1✔
136	test_eq(result, "shift left 2", input.shift_elems_left<2>(), 0, 0, pat1, pat2);	1✔
137	test_eq(result, "shift left 3", input.shift_elems_left<3>(), 0, 0, 0, pat1);	1✔
138
139	test_eq(result, "shift right 1", input.shift_elems_right<1>(), pat2, pat3, pat4, 0);	1✔
140	test_eq(result, "shift right 2", input.shift_elems_right<2>(), pat3, pat4, 0, 0);	1✔
141	test_eq(result, "shift right 3", input.shift_elems_right<3>(), pat4, 0, 0, 0);	1✔
142
143	// Test load/stores SIMD wrapper types
144	const auto simd_le_in = Botan::hex_decode("ABCDEF01234567890123456789ABCDEF");	1✔
145	const auto simd_be_in = Botan::hex_decode("0123456789ABCDEFABCDEF0123456789");	1✔
146	const auto simd_le_array_in = Botan::concat(simd_le_in, simd_be_in);	1✔
147	const auto simd_be_array_in = Botan::concat(simd_be_in, simd_le_in);	1✔
148
149	auto simd_le = Botan::load_le<Botan::SIMD_4x32>(simd_le_in);	1✔
150	auto simd_be = Botan::load_be<Botan::SIMD_4x32>(simd_be_in);	1✔
151	auto simd_le_array = Botan::load_le<std::array<Botan::SIMD_4x32, 2>>(simd_le_array_in);	3✔
152	auto simd_be_array = Botan::load_be<std::array<Botan::SIMD_4x32, 2>>(simd_be_array_in);
153
154	auto simd_le_vec = Botan::store_le<std::vector<uint8_t>>(simd_le);	1✔
155	auto simd_be_vec = Botan::store_be(simd_be);	1✔
156	auto simd_le_array_vec = Botan::store_le<std::vector<uint8_t>>(simd_le_array);	1✔
157	auto simd_be_array_vec = Botan::store_be(simd_be_array);	1✔
158
159	result.test_is_eq("roundtrip SIMD little-endian", simd_le_vec, simd_le_in);	1✔
160	result.test_is_eq(	2✔
161	"roundtrip SIMD big-endian", std::vector(simd_be_vec.begin(), simd_be_vec.end()), simd_be_in);	1✔
162	result.test_is_eq("roundtrip SIMD array little-endian", simd_le_array_vec, simd_le_array_in);	1✔
163	result.test_is_eq("roundtrip SIMD array big-endian",	3✔
164	std::vector(simd_be_array_vec.begin(), simd_be_array_vec.end()),	1✔
165	simd_be_array_in);
166
167	using StrongSIMD = Botan::Strong<Botan::SIMD_4x32, struct StrongSIMD_>;	1✔
168	const auto simd_le_strong = Botan::load_le<StrongSIMD>(simd_le_in);	1✔
169	const auto simd_be_strong = Botan::load_be<StrongSIMD>(simd_be_in);	1✔
170
171	result.test_is_eq(	2✔
172	"roundtrip SIMD strong little-endian", Botan::store_le<std::vector<uint8_t>>(simd_le_strong), simd_le_in);	1✔
173	result.test_is_eq(	2✔
174	"roundtrip SIMD strong big-endian", Botan::store_be<std::vector<uint8_t>>(simd_be_strong), simd_be_in);	1✔
175
176	return {result};	2✔
177	}	7✔
178
179	private:
180	static void test_eq(Test::Result& result,	30✔
181	const std::string& op,
182	const Botan::SIMD_4x32& simd,
183	uint32_t exp0,
184	uint32_t exp1,
185	uint32_t exp2,
186	uint32_t exp3) {
187	uint8_t arr_be[16 + 15];	30✔
188	uint8_t arr_be2[16 + 15];	30✔
189	uint8_t arr_le[16 + 15];	30✔
190	uint8_t arr_le2[16 + 15];	30✔
191
192	for(size_t misalignment = 0; misalignment != 16; ++misalignment) {	510✔
193	uint8_t* mem_be = arr_be + misalignment;	480✔
194	uint8_t* mem_be2 = arr_be2 + misalignment;	480✔
195	uint8_t* mem_le = arr_le + misalignment;	480✔
196	uint8_t* mem_le2 = arr_le2 + misalignment;	480✔
197
198	simd.store_be(mem_be);	480✔
199
200	result.test_int_eq(	960✔
201	"SIMD_4x32 " + op + " elem0 BE", Botan::make_uint32(mem_be[0], mem_be[1], mem_be[2], mem_be[3]), exp0);	1,440✔
202	result.test_int_eq(	480✔
203	"SIMD_4x32 " + op + " elem1 BE", Botan::make_uint32(mem_be[4], mem_be[5], mem_be[6], mem_be[7]), exp1);	1,440✔
204	result.test_int_eq(	480✔
205	"SIMD_4x32 " + op + " elem2 BE", Botan::make_uint32(mem_be[8], mem_be[9], mem_be[10], mem_be[11]), exp2);	1,440✔
206	result.test_int_eq("SIMD_4x32 " + op + " elem3 BE",	480✔
207	Botan::make_uint32(mem_be[12], mem_be[13], mem_be[14], mem_be[15]),	480✔
208	exp3);
209
210	// Check load_be+store_be results in same value
211	const Botan::SIMD_4x32 reloaded_be = Botan::SIMD_4x32::load_be(mem_be);	480✔
212	reloaded_be.store_be(mem_be2);	480✔
213	result.test_eq(nullptr, "SIMD_4x32 load_be", mem_be, 16, mem_be2, 16);	480✔
214
215	simd.store_le(mem_le);	480✔
216
217	result.test_int_eq(	960✔
218	"SIMD_4x32 " + op + " elem0 LE", Botan::make_uint32(mem_le[3], mem_le[2], mem_le[1], mem_le[0]), exp0);	1,440✔
219	result.test_int_eq(	480✔
220	"SIMD_4x32 " + op + " elem1 LE", Botan::make_uint32(mem_le[7], mem_le[6], mem_le[5], mem_le[4]), exp1);	1,440✔
221	result.test_int_eq(	480✔
222	"SIMD_4x32 " + op + " elem2 LE", Botan::make_uint32(mem_le[11], mem_le[10], mem_le[9], mem_le[8]), exp2);	1,440✔
223	result.test_int_eq("SIMD_4x32 " + op + " elem3 LE",	480✔
224	Botan::make_uint32(mem_le[15], mem_le[14], mem_le[13], mem_le[12]),	480✔
225	exp3);
226
227	// Check load_le+store_le results in same value
228	const Botan::SIMD_4x32 reloaded_le = Botan::SIMD_4x32::load_le(mem_le);	480✔
229	reloaded_le.store_le(mem_le2);	480✔
230	result.test_eq(nullptr, "SIMD_4x32 load_le", mem_le, 16, mem_le2, 16);	960✔
231	}
232	}	30✔
233	};
234
235	BOTAN_REGISTER_TEST("utils", "simd_32", SIMD_32_Tests);
236	#endif
237
238	} // namespace Botan_Tests

randombit / botan / 13536213672

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