Modules/_hacl/Hacl_Hash_SHA1.c - platform/external/python/cpython3 - Git at Google

 /* MIT License
  *
  * Copyright (c) 2016-2022 INRIA, CMU and Microsoft Corporation
  * Copyright (c) 2022-2023 HACL* Contributors
  *
  * Permission is hereby granted, free of charge, to any person obtaining a copy
  * of this software and associated documentation files (the "Software"), to deal
  * in the Software without restriction, including without limitation the rights
  * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
  * copies of the Software, and to permit persons to whom the Software is
  * furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in all
  * copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
  * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
  * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
  * SOFTWARE.
  */


 #include "internal/Hacl_Hash_SHA1.h"

 static uint32_t _h0[5U] = { 0x67452301U, 0xefcdab89U, 0x98badcfeU, 0x10325476U, 0xc3d2e1f0U };

 void Hacl_Hash_SHA1_init(uint32_t *s)
 {
   KRML_MAYBE_FOR5(i, 0U, 5U, 1U, s[i] = _h0[i];);
 }

 static void update(uint32_t *h, uint8_t *l)
 {
   uint32_t ha = h[0U];
   uint32_t hb = h[1U];
   uint32_t hc = h[2U];
   uint32_t hd = h[3U];
   uint32_t he = h[4U];
   uint32_t _w[80U] = { 0U };
   for (uint32_t i = 0U; i < 80U; i++)
   {
     uint32_t v;
     if (i < 16U)
     {
       uint8_t *b = l + i * 4U;
       uint32_t u = load32_be(b);
       v = u;
     }
     else
     {
       uint32_t wmit3 = _w[i - 3U];
       uint32_t wmit8 = _w[i - 8U];
       uint32_t wmit14 = _w[i - 14U];
       uint32_t wmit16 = _w[i - 16U];
       v = (wmit3 ^ (wmit8 ^ (wmit14 ^ wmit16))) << 1U | (wmit3 ^ (wmit8 ^ (wmit14 ^ wmit16))) >> 31U;
     }
     _w[i] = v;
   }
   for (uint32_t i = 0U; i < 80U; i++)
   {
     uint32_t _a = h[0U];
     uint32_t _b = h[1U];
     uint32_t _c = h[2U];
     uint32_t _d = h[3U];
     uint32_t _e = h[4U];
     uint32_t wmit = _w[i];
     uint32_t ite0;
     if (i < 20U)
     {
       ite0 = (_b & _c) ^ (~_b & _d);
     }
     else if (39U < i && i < 60U)
     {
       ite0 = (_b & _c) ^ ((_b & _d) ^ (_c & _d));
     }
     else
     {
       ite0 = _b ^ (_c ^ _d);
     }
     uint32_t ite;
     if (i < 20U)
     {
       ite = 0x5a827999U;
     }
     else if (i < 40U)
     {
       ite = 0x6ed9eba1U;
     }
     else if (i < 60U)
     {
       ite = 0x8f1bbcdcU;
     }
     else
     {
       ite = 0xca62c1d6U;
     }
     uint32_t _T = (_a << 5U | _a >> 27U) + ite0 + _e + ite + wmit;
     h[0U] = _T;
     h[1U] = _a;
     h[2U] = _b << 30U | _b >> 2U;
     h[3U] = _c;
     h[4U] = _d;
   }
   for (uint32_t i = 0U; i < 80U; i++)
   {
     _w[i] = 0U;
   }
   uint32_t sta = h[0U];
   uint32_t stb = h[1U];
   uint32_t stc = h[2U];
   uint32_t std = h[3U];
   uint32_t ste = h[4U];
   h[0U] = sta + ha;
   h[1U] = stb + hb;
   h[2U] = stc + hc;
   h[3U] = std + hd;
   h[4U] = ste + he;
 }

 static void pad(uint64_t len, uint8_t *dst)
 {
   uint8_t *dst1 = dst;
   dst1[0U] = 0x80U;
   uint8_t *dst2 = dst + 1U;
   for (uint32_t i = 0U; i < (128U - (9U + (uint32_t)(len % (uint64_t)64U))) % 64U; i++)
   {
     dst2[i] = 0U;
   }
   uint8_t *dst3 = dst + 1U + (128U - (9U + (uint32_t)(len % (uint64_t)64U))) % 64U;
   store64_be(dst3, len << 3U);
 }

 void Hacl_Hash_SHA1_finish(uint32_t *s, uint8_t *dst)
 {
   KRML_MAYBE_FOR5(i, 0U, 5U, 1U, store32_be(dst + i * 4U, s[i]););
 }

 void Hacl_Hash_SHA1_update_multi(uint32_t *s, uint8_t *blocks, uint32_t n_blocks)
 {
   for (uint32_t i = 0U; i < n_blocks; i++)
   {
     uint32_t sz = 64U;
     uint8_t *block = blocks + sz * i;
     update(s, block);
   }
 }

 void
 Hacl_Hash_SHA1_update_last(uint32_t *s, uint64_t prev_len, uint8_t *input, uint32_t input_len)
 {
   uint32_t blocks_n = input_len / 64U;
   uint32_t blocks_len = blocks_n * 64U;
   uint8_t *blocks = input;
   uint32_t rest_len = input_len - blocks_len;
   uint8_t *rest = input + blocks_len;
   Hacl_Hash_SHA1_update_multi(s, blocks, blocks_n);
   uint64_t total_input_len = prev_len + (uint64_t)input_len;
   uint32_t pad_len = 1U + (128U - (9U + (uint32_t)(total_input_len % (uint64_t)64U))) % 64U + 8U;
   uint32_t tmp_len = rest_len + pad_len;
   uint8_t tmp_twoblocks[128U] = { 0U };
   uint8_t *tmp = tmp_twoblocks;
   uint8_t *tmp_rest = tmp;
   uint8_t *tmp_pad = tmp + rest_len;
   memcpy(tmp_rest, rest, rest_len * sizeof (uint8_t));
   pad(total_input_len, tmp_pad);
   Hacl_Hash_SHA1_update_multi(s, tmp, tmp_len / 64U);
 }

 void Hacl_Hash_SHA1_hash_oneshot(uint8_t *output, uint8_t *input, uint32_t input_len)
 {
   uint32_t s[5U] = { 0x67452301U, 0xefcdab89U, 0x98badcfeU, 0x10325476U, 0xc3d2e1f0U };
   uint32_t blocks_n0 = input_len / 64U;
   uint32_t blocks_n1;
   if (input_len % 64U == 0U && blocks_n0 > 0U)
   {
     blocks_n1 = blocks_n0 - 1U;
   }
   else
   {
     blocks_n1 = blocks_n0;
   }
   uint32_t blocks_len0 = blocks_n1 * 64U;
   uint8_t *blocks0 = input;
   uint32_t rest_len0 = input_len - blocks_len0;
   uint8_t *rest0 = input + blocks_len0;
   uint32_t blocks_n = blocks_n1;
   uint32_t blocks_len = blocks_len0;
   uint8_t *blocks = blocks0;
   uint32_t rest_len = rest_len0;
   uint8_t *rest = rest0;
   Hacl_Hash_SHA1_update_multi(s, blocks, blocks_n);
   Hacl_Hash_SHA1_update_last(s, (uint64_t)blocks_len, rest, rest_len);
   Hacl_Hash_SHA1_finish(s, output);
 }

 Hacl_Streaming_MD_state_32 *Hacl_Hash_SHA1_malloc(void)
 {
   uint8_t *buf = (uint8_t *)KRML_HOST_CALLOC(64U, sizeof (uint8_t));
   uint32_t *block_state = (uint32_t *)KRML_HOST_CALLOC(5U, sizeof (uint32_t));
   Hacl_Streaming_MD_state_32
   s = { .block_state = block_state, .buf = buf, .total_len = (uint64_t)0U };
   Hacl_Streaming_MD_state_32
   *p = (Hacl_Streaming_MD_state_32 *)KRML_HOST_MALLOC(sizeof (Hacl_Streaming_MD_state_32));
   p[0U] = s;
   Hacl_Hash_SHA1_init(block_state);
   return p;
 }

 void Hacl_Hash_SHA1_reset(Hacl_Streaming_MD_state_32 *state)
 {
   Hacl_Streaming_MD_state_32 scrut = *state;
   uint8_t *buf = scrut.buf;
   uint32_t *block_state = scrut.block_state;
   Hacl_Hash_SHA1_init(block_state);
   Hacl_Streaming_MD_state_32
   tmp = { .block_state = block_state, .buf = buf, .total_len = (uint64_t)0U };
   state[0U] = tmp;
 }

 /**
 0 = success, 1 = max length exceeded
 */
 Hacl_Streaming_Types_error_code
 Hacl_Hash_SHA1_update(Hacl_Streaming_MD_state_32 *state, uint8_t *chunk, uint32_t chunk_len)
 {
   Hacl_Streaming_MD_state_32 s = *state;
   uint64_t total_len = s.total_len;
   if ((uint64_t)chunk_len > 2305843009213693951ULL - total_len)
   {
     return Hacl_Streaming_Types_MaximumLengthExceeded;
   }
   uint32_t sz;
   if (total_len % (uint64_t)64U == 0ULL && total_len > 0ULL)
   {
     sz = 64U;
   }
   else
   {
     sz = (uint32_t)(total_len % (uint64_t)64U);
   }
   if (chunk_len <= 64U - sz)
   {
     Hacl_Streaming_MD_state_32 s1 = *state;
     uint32_t *block_state1 = s1.block_state;
     uint8_t *buf = s1.buf;
     uint64_t total_len1 = s1.total_len;
     uint32_t sz1;
     if (total_len1 % (uint64_t)64U == 0ULL && total_len1 > 0ULL)
     {
       sz1 = 64U;
     }
     else
     {
       sz1 = (uint32_t)(total_len1 % (uint64_t)64U);
     }
     uint8_t *buf2 = buf + sz1;
     memcpy(buf2, chunk, chunk_len * sizeof (uint8_t));
     uint64_t total_len2 = total_len1 + (uint64_t)chunk_len;
     *state
     =
       (
         (Hacl_Streaming_MD_state_32){
           .block_state = block_state1,
           .buf = buf,
           .total_len = total_len2
         }
       );
   }
   else if (sz == 0U)
   {
     Hacl_Streaming_MD_state_32 s1 = *state;
     uint32_t *block_state1 = s1.block_state;
     uint8_t *buf = s1.buf;
     uint64_t total_len1 = s1.total_len;
     uint32_t sz1;
     if (total_len1 % (uint64_t)64U == 0ULL && total_len1 > 0ULL)
     {
       sz1 = 64U;
     }
     else
     {
       sz1 = (uint32_t)(total_len1 % (uint64_t)64U);
     }
     if (!(sz1 == 0U))
     {
       Hacl_Hash_SHA1_update_multi(block_state1, buf, 1U);
     }
     uint32_t ite;
     if ((uint64_t)chunk_len % (uint64_t)64U == 0ULL && (uint64_t)chunk_len > 0ULL)
     {
       ite = 64U;
     }
     else
     {
       ite = (uint32_t)((uint64_t)chunk_len % (uint64_t)64U);
     }
     uint32_t n_blocks = (chunk_len - ite) / 64U;
     uint32_t data1_len = n_blocks * 64U;
     uint32_t data2_len = chunk_len - data1_len;
     uint8_t *data1 = chunk;
     uint8_t *data2 = chunk + data1_len;
     Hacl_Hash_SHA1_update_multi(block_state1, data1, data1_len / 64U);
     uint8_t *dst = buf;
     memcpy(dst, data2, data2_len * sizeof (uint8_t));
     *state
     =
       (
         (Hacl_Streaming_MD_state_32){
           .block_state = block_state1,
           .buf = buf,
           .total_len = total_len1 + (uint64_t)chunk_len
         }
       );
   }
   else
   {
     uint32_t diff = 64U - sz;
     uint8_t *chunk1 = chunk;
     uint8_t *chunk2 = chunk + diff;
     Hacl_Streaming_MD_state_32 s1 = *state;
     uint32_t *block_state10 = s1.block_state;
     uint8_t *buf0 = s1.buf;
     uint64_t total_len10 = s1.total_len;
     uint32_t sz10;
     if (total_len10 % (uint64_t)64U == 0ULL && total_len10 > 0ULL)
     {
       sz10 = 64U;
     }
     else
     {
       sz10 = (uint32_t)(total_len10 % (uint64_t)64U);
     }
     uint8_t *buf2 = buf0 + sz10;
     memcpy(buf2, chunk1, diff * sizeof (uint8_t));
     uint64_t total_len2 = total_len10 + (uint64_t)diff;
     *state
     =
       (
         (Hacl_Streaming_MD_state_32){
           .block_state = block_state10,
           .buf = buf0,
           .total_len = total_len2
         }
       );
     Hacl_Streaming_MD_state_32 s10 = *state;
     uint32_t *block_state1 = s10.block_state;
     uint8_t *buf = s10.buf;
     uint64_t total_len1 = s10.total_len;
     uint32_t sz1;
     if (total_len1 % (uint64_t)64U == 0ULL && total_len1 > 0ULL)
     {
       sz1 = 64U;
     }
     else
     {
       sz1 = (uint32_t)(total_len1 % (uint64_t)64U);
     }
     if (!(sz1 == 0U))
     {
       Hacl_Hash_SHA1_update_multi(block_state1, buf, 1U);
     }
     uint32_t ite;
     if
     ((uint64_t)(chunk_len - diff) % (uint64_t)64U == 0ULL && (uint64_t)(chunk_len - diff) > 0ULL)
     {
       ite = 64U;
     }
     else
     {
       ite = (uint32_t)((uint64_t)(chunk_len - diff) % (uint64_t)64U);
     }
     uint32_t n_blocks = (chunk_len - diff - ite) / 64U;
     uint32_t data1_len = n_blocks * 64U;
     uint32_t data2_len = chunk_len - diff - data1_len;
     uint8_t *data1 = chunk2;
     uint8_t *data2 = chunk2 + data1_len;
     Hacl_Hash_SHA1_update_multi(block_state1, data1, data1_len / 64U);
     uint8_t *dst = buf;
     memcpy(dst, data2, data2_len * sizeof (uint8_t));
     *state
     =
       (
         (Hacl_Streaming_MD_state_32){
           .block_state = block_state1,
           .buf = buf,
           .total_len = total_len1 + (uint64_t)(chunk_len - diff)
         }
       );
   }
   return Hacl_Streaming_Types_Success;
 }

 void Hacl_Hash_SHA1_digest(Hacl_Streaming_MD_state_32 *state, uint8_t *output)
 {
   Hacl_Streaming_MD_state_32 scrut = *state;
   uint32_t *block_state = scrut.block_state;
   uint8_t *buf_ = scrut.buf;
   uint64_t total_len = scrut.total_len;
   uint32_t r;
   if (total_len % (uint64_t)64U == 0ULL && total_len > 0ULL)
   {
     r = 64U;
   }
   else
   {
     r = (uint32_t)(total_len % (uint64_t)64U);
   }
   uint8_t *buf_1 = buf_;
   uint32_t tmp_block_state[5U] = { 0U };
   memcpy(tmp_block_state, block_state, 5U * sizeof (uint32_t));
   uint32_t ite;
   if (r % 64U == 0U && r > 0U)
   {
     ite = 64U;
   }
   else
   {
     ite = r % 64U;
   }
   uint8_t *buf_last = buf_1 + r - ite;
   uint8_t *buf_multi = buf_1;
   Hacl_Hash_SHA1_update_multi(tmp_block_state, buf_multi, 0U);
   uint64_t prev_len_last = total_len - (uint64_t)r;
   Hacl_Hash_SHA1_update_last(tmp_block_state, prev_len_last, buf_last, r);
   Hacl_Hash_SHA1_finish(tmp_block_state, output);
 }

 void Hacl_Hash_SHA1_free(Hacl_Streaming_MD_state_32 *state)
 {
   Hacl_Streaming_MD_state_32 scrut = *state;
   uint8_t *buf = scrut.buf;
   uint32_t *block_state = scrut.block_state;
   KRML_HOST_FREE(block_state);
   KRML_HOST_FREE(buf);
   KRML_HOST_FREE(state);
 }

 Hacl_Streaming_MD_state_32 *Hacl_Hash_SHA1_copy(Hacl_Streaming_MD_state_32 *state)
 {
   Hacl_Streaming_MD_state_32 scrut = *state;
   uint32_t *block_state0 = scrut.block_state;
   uint8_t *buf0 = scrut.buf;
   uint64_t total_len0 = scrut.total_len;
   uint8_t *buf = (uint8_t *)KRML_HOST_CALLOC(64U, sizeof (uint8_t));
   memcpy(buf, buf0, 64U * sizeof (uint8_t));
   uint32_t *block_state = (uint32_t *)KRML_HOST_CALLOC(5U, sizeof (uint32_t));
   memcpy(block_state, block_state0, 5U * sizeof (uint32_t));
   Hacl_Streaming_MD_state_32
   s = { .block_state = block_state, .buf = buf, .total_len = total_len0 };
   Hacl_Streaming_MD_state_32
   *p = (Hacl_Streaming_MD_state_32 *)KRML_HOST_MALLOC(sizeof (Hacl_Streaming_MD_state_32));
   p[0U] = s;
   return p;
 }

 void Hacl_Hash_SHA1_hash(uint8_t *output, uint8_t *input, uint32_t input_len)
 {
   Hacl_Hash_SHA1_hash_oneshot(output, input, input_len);
 }
	/* MIT License
	*
	* Copyright (c) 2016-2022 INRIA, CMU and Microsoft Corporation
	* Copyright (c) 2022-2023 HACL* Contributors
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to deal
	* in the Software without restriction, including without limitation the rights
	* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	* copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in all
	* copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
	* SOFTWARE.
	*/


	#include "internal/Hacl_Hash_SHA1.h"

	static uint32_t _h0[5U] = { 0x67452301U, 0xefcdab89U, 0x98badcfeU, 0x10325476U, 0xc3d2e1f0U };

	void Hacl_Hash_SHA1_init(uint32_t *s)
	{
	KRML_MAYBE_FOR5(i, 0U, 5U, 1U, s[i] = _h0[i];);
	}

	static void update(uint32_t h, uint8_t l)
	{
	uint32_t ha = h[0U];
	uint32_t hb = h[1U];
	uint32_t hc = h[2U];
	uint32_t hd = h[3U];
	uint32_t he = h[4U];
	uint32_t _w[80U] = { 0U };
	for (uint32_t i = 0U; i < 80U; i++)
	{
	uint32_t v;
	if (i < 16U)
	{
	uint8_t b = l + i 4U;
	uint32_t u = load32_be(b);
	v = u;
	}
	else
	{
	uint32_t wmit3 = _w[i - 3U];
	uint32_t wmit8 = _w[i - 8U];
	uint32_t wmit14 = _w[i - 14U];
	uint32_t wmit16 = _w[i - 16U];
	v = (wmit3 ^ (wmit8 ^ (wmit14 ^ wmit16))) << 1U \| (wmit3 ^ (wmit8 ^ (wmit14 ^ wmit16))) >> 31U;
	}
	_w[i] = v;
	}
	for (uint32_t i = 0U; i < 80U; i++)
	{
	uint32_t _a = h[0U];
	uint32_t _b = h[1U];
	uint32_t _c = h[2U];
	uint32_t _d = h[3U];
	uint32_t _e = h[4U];
	uint32_t wmit = _w[i];
	uint32_t ite0;
	if (i < 20U)
	{
	ite0 = (_b & _c) ^ (~_b & _d);
	}
	else if (39U < i && i < 60U)
	{
	ite0 = (_b & _c) ^ ((_b & _d) ^ (_c & _d));
	}
	else
	{
	ite0 = _b ^ (_c ^ _d);
	}
	uint32_t ite;
	if (i < 20U)
	{
	ite = 0x5a827999U;
	}
	else if (i < 40U)
	{
	ite = 0x6ed9eba1U;
	}
	else if (i < 60U)
	{
	ite = 0x8f1bbcdcU;
	}
	else
	{
	ite = 0xca62c1d6U;
	}
	uint32_t _T = (_a << 5U \| _a >> 27U) + ite0 + _e + ite + wmit;
	h[0U] = _T;
	h[1U] = _a;
	h[2U] = _b << 30U \| _b >> 2U;
	h[3U] = _c;
	h[4U] = _d;
	}
	for (uint32_t i = 0U; i < 80U; i++)
	{
	_w[i] = 0U;
	}
	uint32_t sta = h[0U];
	uint32_t stb = h[1U];
	uint32_t stc = h[2U];
	uint32_t std = h[3U];
	uint32_t ste = h[4U];
	h[0U] = sta + ha;
	h[1U] = stb + hb;
	h[2U] = stc + hc;
	h[3U] = std + hd;
	h[4U] = ste + he;
	}

	static void pad(uint64_t len, uint8_t *dst)
	{
	uint8_t *dst1 = dst;
	dst1[0U] = 0x80U;
	uint8_t *dst2 = dst + 1U;
	for (uint32_t i = 0U; i < (128U - (9U + (uint32_t)(len % (uint64_t)64U))) % 64U; i++)
	{
	dst2[i] = 0U;
	}
	uint8_t *dst3 = dst + 1U + (128U - (9U + (uint32_t)(len % (uint64_t)64U))) % 64U;
	store64_be(dst3, len << 3U);
	}

	void Hacl_Hash_SHA1_finish(uint32_t s, uint8_t dst)
	{
	KRML_MAYBE_FOR5(i, 0U, 5U, 1U, store32_be(dst + i * 4U, s[i]););
	}

	void Hacl_Hash_SHA1_update_multi(uint32_t s, uint8_t blocks, uint32_t n_blocks)
	{
	for (uint32_t i = 0U; i < n_blocks; i++)
	{
	uint32_t sz = 64U;
	uint8_t block = blocks + sz i;
	update(s, block);
	}
	}

	void
	Hacl_Hash_SHA1_update_last(uint32_t s, uint64_t prev_len, uint8_t input, uint32_t input_len)
	{
	uint32_t blocks_n = input_len / 64U;
	uint32_t blocks_len = blocks_n * 64U;
	uint8_t *blocks = input;
	uint32_t rest_len = input_len - blocks_len;
	uint8_t *rest = input + blocks_len;
	Hacl_Hash_SHA1_update_multi(s, blocks, blocks_n);
	uint64_t total_input_len = prev_len + (uint64_t)input_len;
	uint32_t pad_len = 1U + (128U - (9U + (uint32_t)(total_input_len % (uint64_t)64U))) % 64U + 8U;
	uint32_t tmp_len = rest_len + pad_len;
	uint8_t tmp_twoblocks[128U] = { 0U };
	uint8_t *tmp = tmp_twoblocks;
	uint8_t *tmp_rest = tmp;
	uint8_t *tmp_pad = tmp + rest_len;
	memcpy(tmp_rest, rest, rest_len * sizeof (uint8_t));
	pad(total_input_len, tmp_pad);
	Hacl_Hash_SHA1_update_multi(s, tmp, tmp_len / 64U);
	}

	void Hacl_Hash_SHA1_hash_oneshot(uint8_t output, uint8_t input, uint32_t input_len)
	{
	uint32_t s[5U] = { 0x67452301U, 0xefcdab89U, 0x98badcfeU, 0x10325476U, 0xc3d2e1f0U };
	uint32_t blocks_n0 = input_len / 64U;
	uint32_t blocks_n1;
	if (input_len % 64U == 0U && blocks_n0 > 0U)
	{
	blocks_n1 = blocks_n0 - 1U;
	}
	else
	{
	blocks_n1 = blocks_n0;
	}
	uint32_t blocks_len0 = blocks_n1 * 64U;
	uint8_t *blocks0 = input;
	uint32_t rest_len0 = input_len - blocks_len0;
	uint8_t *rest0 = input + blocks_len0;
	uint32_t blocks_n = blocks_n1;
	uint32_t blocks_len = blocks_len0;
	uint8_t *blocks = blocks0;
	uint32_t rest_len = rest_len0;
	uint8_t *rest = rest0;
	Hacl_Hash_SHA1_update_multi(s, blocks, blocks_n);
	Hacl_Hash_SHA1_update_last(s, (uint64_t)blocks_len, rest, rest_len);
	Hacl_Hash_SHA1_finish(s, output);
	}

	Hacl_Streaming_MD_state_32 *Hacl_Hash_SHA1_malloc(void)
	{
	uint8_t buf = (uint8_t )KRML_HOST_CALLOC(64U, sizeof (uint8_t));
	uint32_t block_state = (uint32_t )KRML_HOST_CALLOC(5U, sizeof (uint32_t));
	Hacl_Streaming_MD_state_32
	s = { .block_state = block_state, .buf = buf, .total_len = (uint64_t)0U };
	Hacl_Streaming_MD_state_32
	p = (Hacl_Streaming_MD_state_32 )KRML_HOST_MALLOC(sizeof (Hacl_Streaming_MD_state_32));
	p[0U] = s;
	Hacl_Hash_SHA1_init(block_state);
	return p;
	}

	void Hacl_Hash_SHA1_reset(Hacl_Streaming_MD_state_32 *state)
	{
	Hacl_Streaming_MD_state_32 scrut = *state;
	uint8_t *buf = scrut.buf;
	uint32_t *block_state = scrut.block_state;
	Hacl_Hash_SHA1_init(block_state);
	Hacl_Streaming_MD_state_32
	tmp = { .block_state = block_state, .buf = buf, .total_len = (uint64_t)0U };
	state[0U] = tmp;
	}

	/**
	0 = success, 1 = max length exceeded
	*/
	Hacl_Streaming_Types_error_code
	Hacl_Hash_SHA1_update(Hacl_Streaming_MD_state_32 state, uint8_t chunk, uint32_t chunk_len)
	{
	Hacl_Streaming_MD_state_32 s = *state;
	uint64_t total_len = s.total_len;
	if ((uint64_t)chunk_len > 2305843009213693951ULL - total_len)
	{
	return Hacl_Streaming_Types_MaximumLengthExceeded;
	}
	uint32_t sz;
	if (total_len % (uint64_t)64U == 0ULL && total_len > 0ULL)
	{
	sz = 64U;
	}
	else
	{
	sz = (uint32_t)(total_len % (uint64_t)64U);
	}
	if (chunk_len <= 64U - sz)
	{
	Hacl_Streaming_MD_state_32 s1 = *state;
	uint32_t *block_state1 = s1.block_state;
	uint8_t *buf = s1.buf;
	uint64_t total_len1 = s1.total_len;
	uint32_t sz1;
	if (total_len1 % (uint64_t)64U == 0ULL && total_len1 > 0ULL)
	{
	sz1 = 64U;
	}
	else
	{
	sz1 = (uint32_t)(total_len1 % (uint64_t)64U);
	}
	uint8_t *buf2 = buf + sz1;
	memcpy(buf2, chunk, chunk_len * sizeof (uint8_t));
	uint64_t total_len2 = total_len1 + (uint64_t)chunk_len;
	*state
	=
	(
	(Hacl_Streaming_MD_state_32){
	.block_state = block_state1,
	.buf = buf,
	.total_len = total_len2
	}
	);
	}
	else if (sz == 0U)
	{
	Hacl_Streaming_MD_state_32 s1 = *state;
	uint32_t *block_state1 = s1.block_state;
	uint8_t *buf = s1.buf;
	uint64_t total_len1 = s1.total_len;
	uint32_t sz1;
	if (total_len1 % (uint64_t)64U == 0ULL && total_len1 > 0ULL)
	{
	sz1 = 64U;
	}
	else
	{
	sz1 = (uint32_t)(total_len1 % (uint64_t)64U);
	}
	if (!(sz1 == 0U))
	{
	Hacl_Hash_SHA1_update_multi(block_state1, buf, 1U);
	}
	uint32_t ite;
	if ((uint64_t)chunk_len % (uint64_t)64U == 0ULL && (uint64_t)chunk_len > 0ULL)
	{
	ite = 64U;
	}
	else
	{
	ite = (uint32_t)((uint64_t)chunk_len % (uint64_t)64U);
	}
	uint32_t n_blocks = (chunk_len - ite) / 64U;
	uint32_t data1_len = n_blocks * 64U;
	uint32_t data2_len = chunk_len - data1_len;
	uint8_t *data1 = chunk;
	uint8_t *data2 = chunk + data1_len;
	Hacl_Hash_SHA1_update_multi(block_state1, data1, data1_len / 64U);
	uint8_t *dst = buf;
	memcpy(dst, data2, data2_len * sizeof (uint8_t));
	*state
	=
	(
	(Hacl_Streaming_MD_state_32){
	.block_state = block_state1,
	.buf = buf,
	.total_len = total_len1 + (uint64_t)chunk_len
	}
	);
	}
	else
	{
	uint32_t diff = 64U - sz;
	uint8_t *chunk1 = chunk;
	uint8_t *chunk2 = chunk + diff;
	Hacl_Streaming_MD_state_32 s1 = *state;
	uint32_t *block_state10 = s1.block_state;
	uint8_t *buf0 = s1.buf;
	uint64_t total_len10 = s1.total_len;
	uint32_t sz10;
	if (total_len10 % (uint64_t)64U == 0ULL && total_len10 > 0ULL)
	{
	sz10 = 64U;
	}
	else
	{
	sz10 = (uint32_t)(total_len10 % (uint64_t)64U);
	}
	uint8_t *buf2 = buf0 + sz10;
	memcpy(buf2, chunk1, diff * sizeof (uint8_t));
	uint64_t total_len2 = total_len10 + (uint64_t)diff;
	*state
	=
	(
	(Hacl_Streaming_MD_state_32){
	.block_state = block_state10,
	.buf = buf0,
	.total_len = total_len2
	}
	);
	Hacl_Streaming_MD_state_32 s10 = *state;
	uint32_t *block_state1 = s10.block_state;
	uint8_t *buf = s10.buf;
	uint64_t total_len1 = s10.total_len;
	uint32_t sz1;
	if (total_len1 % (uint64_t)64U == 0ULL && total_len1 > 0ULL)
	{
	sz1 = 64U;
	}
	else
	{
	sz1 = (uint32_t)(total_len1 % (uint64_t)64U);
	}
	if (!(sz1 == 0U))
	{
	Hacl_Hash_SHA1_update_multi(block_state1, buf, 1U);
	}
	uint32_t ite;
	if
	((uint64_t)(chunk_len - diff) % (uint64_t)64U == 0ULL && (uint64_t)(chunk_len - diff) > 0ULL)
	{
	ite = 64U;
	}
	else
	{
	ite = (uint32_t)((uint64_t)(chunk_len - diff) % (uint64_t)64U);
	}
	uint32_t n_blocks = (chunk_len - diff - ite) / 64U;
	uint32_t data1_len = n_blocks * 64U;
	uint32_t data2_len = chunk_len - diff - data1_len;
	uint8_t *data1 = chunk2;
	uint8_t *data2 = chunk2 + data1_len;
	Hacl_Hash_SHA1_update_multi(block_state1, data1, data1_len / 64U);
	uint8_t *dst = buf;
	memcpy(dst, data2, data2_len * sizeof (uint8_t));
	*state
	=
	(
	(Hacl_Streaming_MD_state_32){
	.block_state = block_state1,
	.buf = buf,
	.total_len = total_len1 + (uint64_t)(chunk_len - diff)
	}
	);
	}
	return Hacl_Streaming_Types_Success;
	}

	void Hacl_Hash_SHA1_digest(Hacl_Streaming_MD_state_32 state, uint8_t output)
	{
	Hacl_Streaming_MD_state_32 scrut = *state;
	uint32_t *block_state = scrut.block_state;
	uint8_t *buf_ = scrut.buf;
	uint64_t total_len = scrut.total_len;
	uint32_t r;
	if (total_len % (uint64_t)64U == 0ULL && total_len > 0ULL)
	{
	r = 64U;
	}
	else
	{
	r = (uint32_t)(total_len % (uint64_t)64U);
	}
	uint8_t *buf_1 = buf_;
	uint32_t tmp_block_state[5U] = { 0U };
	memcpy(tmp_block_state, block_state, 5U * sizeof (uint32_t));
	uint32_t ite;
	if (r % 64U == 0U && r > 0U)
	{
	ite = 64U;
	}
	else
	{
	ite = r % 64U;
	}
	uint8_t *buf_last = buf_1 + r - ite;
	uint8_t *buf_multi = buf_1;
	Hacl_Hash_SHA1_update_multi(tmp_block_state, buf_multi, 0U);
	uint64_t prev_len_last = total_len - (uint64_t)r;
	Hacl_Hash_SHA1_update_last(tmp_block_state, prev_len_last, buf_last, r);
	Hacl_Hash_SHA1_finish(tmp_block_state, output);
	}

	void Hacl_Hash_SHA1_free(Hacl_Streaming_MD_state_32 *state)
	{
	Hacl_Streaming_MD_state_32 scrut = *state;
	uint8_t *buf = scrut.buf;
	uint32_t *block_state = scrut.block_state;
	KRML_HOST_FREE(block_state);
	KRML_HOST_FREE(buf);
	KRML_HOST_FREE(state);
	}

	Hacl_Streaming_MD_state_32 Hacl_Hash_SHA1_copy(Hacl_Streaming_MD_state_32 state)
	{
	Hacl_Streaming_MD_state_32 scrut = *state;
	uint32_t *block_state0 = scrut.block_state;
	uint8_t *buf0 = scrut.buf;
	uint64_t total_len0 = scrut.total_len;
	uint8_t buf = (uint8_t )KRML_HOST_CALLOC(64U, sizeof (uint8_t));
	memcpy(buf, buf0, 64U * sizeof (uint8_t));
	uint32_t block_state = (uint32_t )KRML_HOST_CALLOC(5U, sizeof (uint32_t));
	memcpy(block_state, block_state0, 5U * sizeof (uint32_t));
	Hacl_Streaming_MD_state_32
	s = { .block_state = block_state, .buf = buf, .total_len = total_len0 };
	Hacl_Streaming_MD_state_32
	p = (Hacl_Streaming_MD_state_32 )KRML_HOST_MALLOC(sizeof (Hacl_Streaming_MD_state_32));
	p[0U] = s;
	return p;
	}

	void Hacl_Hash_SHA1_hash(uint8_t output, uint8_t input, uint32_t input_len)
	{
	Hacl_Hash_SHA1_hash_oneshot(output, input, input_len);
	}