dockerfile/examples/openssl/openssl-3.2.1-src/crypto/rand/rand_uniform.c

/*
 * Copyright 2023 The OpenSSL Project Authors. All Rights Reserved.
 *
 * Licensed under the Apache License 2.0 (the "License").  You may not use
 * this file except in compliance with the License.  You can obtain a copy
 * in the file LICENSE in the source distribution or at
 * https://www.openssl.org/source/license.html
 */

#include "crypto/rand.h"
#include "internal/common.h"

/*
 * Implementation an optimal random integer in a range function.
 *
 * Essentially it boils down to incrementally generating a fixed point
 * number on the interval [0, 1) and multiplying this number by the upper
 * range limit.  Once it is certain what the fractional part contributes to
 * the integral part of the product, the algorithm has produced a definitive
 * result.
 *
 * Refer: https://github.com/apple/swift/pull/39143 for a fuller description
 * of the algorithm.
 */
uint32_t ossl_rand_uniform_uint32(OSSL_LIB_CTX *ctx, uint32_t upper, int *err)
{
    uint32_t i, f;      /* integer and fractional parts */
    uint32_t f2, rand;  /* extra fractional part and random material */
    uint64_t prod;      /* temporary holding double width product */
    const int max_followup_iterations = 10;
    int j;

    if (!ossl_assert(upper > 0)) {
        *err = 0;
        return 0;
    }
    if (unlikely(upper == 1))
        return 0;

    /* Get 32 bits of entropy */
    if (RAND_bytes_ex(ctx, (unsigned char *)&rand, sizeof(rand), 0) <= 0) {
        *err = 1;
        return 0;
    }

    /*
     * We are generating a fixed point number on the interval [0, 1).
     * Multiplying this by the range gives us a number on [0, upper).
     * The high word of the multiplication result represents the integral
     * part we want.  The lower word is the fractional part.  We can early exit if
     * if the fractional part is small enough that no carry from the next lower
     * word can cause an overflow and carry into the integer part.  This
     * happens when the fractional part is bounded by 2^32 - upper which
     * can be simplified to just -upper (as an unsigned integer).
     */
    prod = (uint64_t)upper * rand;
    i = prod >> 32;
    f = prod & 0xffffffff;
    if (likely(f <= 1 + ~upper))    /* 1+~upper == -upper but compilers whine */
        return i;

    /*
     * We're in the position where the carry from the next word *might* cause
     * a carry to the integral part.  The process here is to generate the next
     * word, multiply it by the range and add that to the current word.  If
     * it overflows, the carry propagates to the integer part (return i+1).
     * If it can no longer overflow regardless of further lower order bits,
     * we are done (return i).  If there is still a chance of overflow, we
     * repeat the process with the next lower word.
     *
     * Each *bit* of randomness has a probability of one half of terminating
     * this process, so each each word beyond the first has a probability
     * of 2^-32 of not terminating the process.  That is, we're extremely
     * likely to stop very rapidly.
     */
    for (j = 0; j < max_followup_iterations; j++) {
        if (RAND_bytes_ex(ctx, (unsigned char *)&rand, sizeof(rand), 0) <= 0) {
            *err = 1;
            return 0;
        }
        prod = (uint64_t)upper * rand;
        f2 = prod >> 32;
        f += f2;
        /* On overflow, add the carry to our result */
        if (f < f2)
            return i + 1;
        /* For not all 1 bits, there is no carry so return the result */
        if (likely(f != 0xffffffff))
            return i;
        /* setup for the next word of randomness */
        f = prod & 0xffffffff;
    }
    /*
     * If we get here, we've consumed 32 * max_followup_iterations + 32 bits
     * with no firm decision, this gives a bias with probability < 2^-(32*n),
     * which is likely acceptable.
     */
    return i;
}

uint32_t ossl_rand_range_uint32(OSSL_LIB_CTX *ctx, uint32_t lower, uint32_t upper,
                                int *err)
{
    if (!ossl_assert(lower < upper)) {
        *err = 1;
        return 0;
    }
    return lower + ossl_rand_uniform_uint32(ctx, upper - lower, err);
}
更新构建openssl镜像相关文件 2024-03-22 14:58:37 +08:00			`/*`
			`* Copyright 2023 The OpenSSL Project Authors. All Rights Reserved.`
			`*`
			`* Licensed under the Apache License 2.0 (the "License"). You may not use`
			`* this file except in compliance with the License. You can obtain a copy`
			`* in the file LICENSE in the source distribution or at`
			`* https://www.openssl.org/source/license.html`
			`*/`

			`#include "crypto/rand.h"`
			`#include "internal/common.h"`

			`/*`
			`* Implementation an optimal random integer in a range function.`
			`*`
			`* Essentially it boils down to incrementally generating a fixed point`
			`* number on the interval [0, 1) and multiplying this number by the upper`
			`* range limit. Once it is certain what the fractional part contributes to`
			`* the integral part of the product, the algorithm has produced a definitive`
			`* result.`
			`*`
			`* Refer: https://github.com/apple/swift/pull/39143 for a fuller description`
			`* of the algorithm.`
			`*/`
			`uint32_t ossl_rand_uniform_uint32(OSSL_LIB_CTX ctx, uint32_t upper, int err)`
			`{`
			`uint32_t i, f; /* integer and fractional parts */`
			`uint32_t f2, rand; /* extra fractional part and random material */`
			`uint64_t prod; /* temporary holding double width product */`
			`const int max_followup_iterations = 10;`
			`int j;`

			`if (!ossl_assert(upper > 0)) {`
			`*err = 0;`
			`return 0;`
			`}`
			`if (unlikely(upper == 1))`
			`return 0;`

			`/* Get 32 bits of entropy */`
			`if (RAND_bytes_ex(ctx, (unsigned char *)&rand, sizeof(rand), 0) <= 0) {`
			`*err = 1;`
			`return 0;`
			`}`

			`/*`
			`* We are generating a fixed point number on the interval [0, 1).`
			`* Multiplying this by the range gives us a number on [0, upper).`
			`* The high word of the multiplication result represents the integral`
			`* part we want. The lower word is the fractional part. We can early exit if`
			`* if the fractional part is small enough that no carry from the next lower`
			`* word can cause an overflow and carry into the integer part. This`
			`* happens when the fractional part is bounded by 2^32 - upper which`
			`* can be simplified to just -upper (as an unsigned integer).`
			`*/`
			`prod = (uint64_t)upper * rand;`
			`i = prod >> 32;`
			`f = prod & 0xffffffff;`
			`if (likely(f <= 1 + ~upper)) /* 1+~upper == -upper but compilers whine */`
			`return i;`

			`/*`
			`* We're in the position where the carry from the next word might cause`
			`* a carry to the integral part. The process here is to generate the next`
			`* word, multiply it by the range and add that to the current word. If`
			`* it overflows, the carry propagates to the integer part (return i+1).`
			`* If it can no longer overflow regardless of further lower order bits,`
			`* we are done (return i). If there is still a chance of overflow, we`
			`* repeat the process with the next lower word.`
			`*`
			`* Each bit of randomness has a probability of one half of terminating`
			`* this process, so each each word beyond the first has a probability`
			`* of 2^-32 of not terminating the process. That is, we're extremely`
			`* likely to stop very rapidly.`
			`*/`
			`for (j = 0; j < max_followup_iterations; j++) {`
			`if (RAND_bytes_ex(ctx, (unsigned char *)&rand, sizeof(rand), 0) <= 0) {`
			`*err = 1;`
			`return 0;`
			`}`
			`prod = (uint64_t)upper * rand;`
			`f2 = prod >> 32;`
			`f += f2;`
			`/* On overflow, add the carry to our result */`
			`if (f < f2)`
			`return i + 1;`
			`/* For not all 1 bits, there is no carry so return the result */`
			`if (likely(f != 0xffffffff))`
			`return i;`
			`/* setup for the next word of randomness */`
			`f = prod & 0xffffffff;`
			`}`
			`/*`
			`* If we get here, we've consumed 32 * max_followup_iterations + 32 bits`
			`* with no firm decision, this gives a bias with probability < 2^-(32*n),`
			`* which is likely acceptable.`
			`*/`
			`return i;`
			`}`

			`uint32_t ossl_rand_range_uint32(OSSL_LIB_CTX *ctx, uint32_t lower, uint32_t upper,`
			`int *err)`
			`{`
			`if (!ossl_assert(lower < upper)) {`
			`*err = 1;`
			`return 0;`
			`}`
			`return lower + ossl_rand_uniform_uint32(ctx, upper - lower, err);`
			`}`