esp-idf/components/hal/hal_utils.c

/*
 * SPDX-FileCopyrightText: 2023-2024 Espressif Systems (Shanghai) CO LTD
 *
 * SPDX-License-Identifier: Apache-2.0
 */

#include "hal/hal_utils.h"
#include "hal/assert.h"

#ifndef BIT
#define BIT(n)          (1UL << (n))
#endif

#ifndef BIT_MASK
#define BIT_MASK(n)     (BIT(n) - 1)
#endif

__attribute__((always_inline))
static inline uint32_t _sub_abs(uint32_t a, uint32_t b)
{
    return a > b ? a - b : b - a;
}

uint32_t hal_utils_calc_clk_div_frac_fast(const hal_utils_clk_info_t *clk_info, hal_utils_clk_div_t *clk_div)
{
    HAL_ASSERT(clk_info->max_fract > 2);
    uint32_t div_denom = 2;
    uint32_t div_numer = 0;
    uint32_t div_integ = clk_info->src_freq_hz / clk_info->exp_freq_hz;
    uint32_t freq_error = clk_info->src_freq_hz % clk_info->exp_freq_hz;

    // fractional divider
    if (freq_error) {
        // Carry bit if the decimal is greater than 1.0 - 1.0 / ((max_fract - 1) * 2)
        if (freq_error < clk_info->exp_freq_hz - clk_info->exp_freq_hz / (clk_info->max_fract - 1) * 2) {
            // Calculate the Greatest Common Divisor, time complexity O(log n)
            uint32_t gcd = hal_utils_gcd(clk_info->exp_freq_hz, freq_error);
            // divide by the Greatest Common Divisor to get the accurate fraction before normalization
            div_denom = clk_info->exp_freq_hz / gcd;
            div_numer = freq_error / gcd;
            // normalize div_denom and div_numer
            uint32_t d = div_denom / clk_info->max_fract + 1;
            // divide by the normalization coefficient to get the denominator and numerator within range of clk_info->max_fract
            div_denom /= d;
            div_numer /= d;
        } else {
            div_integ++;
        }
    }

    // If the expect frequency is too high or too low to satisfy the integral division range, failed and return 0
    if (div_integ < clk_info->min_integ || div_integ >= clk_info->max_integ || div_integ == 0) {
        return 0;
    }

    // Assign result
    clk_div->integer     = div_integ;
    clk_div->denominator = div_denom;
    clk_div->numerator   = div_numer;

    // Return the actual frequency
    if (div_numer) {
        uint32_t temp = div_integ * div_denom + div_numer;
        return (uint32_t)(((uint64_t)clk_info->src_freq_hz * div_denom + temp / 2) / temp);
    }
    return clk_info->src_freq_hz / div_integ;
}

uint32_t hal_utils_calc_clk_div_frac_accurate(const hal_utils_clk_info_t *clk_info, hal_utils_clk_div_t *clk_div)
{
    HAL_ASSERT(clk_info->max_fract > 2);
    uint32_t div_denom = 2;
    uint32_t div_numer = 0;
    uint32_t div_integ = clk_info->src_freq_hz / clk_info->exp_freq_hz;
    uint32_t freq_error = clk_info->src_freq_hz % clk_info->exp_freq_hz;

    if (freq_error) {
        // Carry bit if the decimal is greater than 1.0 - 1.0 / ((max_fract - 1) * 2)
        if (freq_error < clk_info->exp_freq_hz - clk_info->exp_freq_hz / (clk_info->max_fract - 1) * 2) {
            // Search the closest fraction, time complexity O(n)
            for (uint32_t sub = 0, a = 2, b = 0, min = UINT32_MAX; min && a < clk_info->max_fract; a++) {
                b = (a * freq_error + clk_info->exp_freq_hz / 2) / clk_info->exp_freq_hz;
                sub = _sub_abs(clk_info->exp_freq_hz * b, freq_error * a);
                if (sub < min) {
                    div_denom = a;
                    div_numer = b;
                    min = sub;
                }
            }
        } else {
            div_integ++;
        }
    }

    // If the expect frequency is too high or too low to satisfy the integral division range, failed and return 0
    if (div_integ < clk_info->min_integ || div_integ >= clk_info->max_integ || div_integ == 0) {
        return 0;
    }

    // Assign result
    clk_div->integer     = div_integ;
    clk_div->denominator = div_denom;
    clk_div->numerator   = div_numer;

    // Return the actual frequency
    if (div_numer) {
        uint32_t temp = div_integ * div_denom + div_numer;
        return (uint32_t)(((uint64_t)clk_info->src_freq_hz * div_denom + temp / 2) / temp);
    }
    return clk_info->src_freq_hz / div_integ;
}

uint32_t hal_utils_calc_clk_div_integer(const hal_utils_clk_info_t *clk_info, uint32_t *int_div)
{
    uint32_t div_integ = clk_info->src_freq_hz / clk_info->exp_freq_hz;
    uint32_t freq_error = clk_info->src_freq_hz % clk_info->exp_freq_hz;

    /* If there is error and always round up,
       Or, do the normal rounding and error >= (src/n + src/(n+1)) / 2,
       then carry the bit */
    if ((freq_error && clk_info->round_opt == HAL_DIV_ROUND_UP) || (clk_info->round_opt == HAL_DIV_ROUND &&
        (freq_error >= clk_info->src_freq_hz / (2 * div_integ * (div_integ + 1))))) {
        div_integ++;
    }
    /* Check the integral division whether in range [min_integ, max_integ)  */
    /* If the result is less than the minimum, set the division to the minimum but return 0 */
    if (div_integ < clk_info->min_integ) {
        *int_div = clk_info->min_integ;
        return 0;
    }
    /* if the result is greater or equal to the maximum , set the division to the maximum but return 0 */
    if (div_integ >= clk_info->max_integ) {
        *int_div = clk_info->max_integ - 1;
        return 0;
    }

    // Assign result
    *int_div = div_integ;
    // Return the actual frequency
    return clk_info->src_freq_hz / div_integ;
}

typedef union {
    struct {
        uint32_t mantissa: 23;
        uint32_t exponent: 8;
        uint32_t sign: 1;
    };
    uint32_t val;
} hal_utils_ieee754_float_t;

int hal_utils_float_to_fixed_point_32b(float flt, const hal_utils_fixed_point_t *fp_cfg, uint32_t *fp_out)
{
    int ret = 0;
    uint32_t output = 0;
    const hal_utils_ieee754_float_t *f = (const hal_utils_ieee754_float_t *)&flt;
    if (fp_cfg->int_bit + fp_cfg->frac_bit > 31) {
        // Not supported
        return -3;
    }

    if (f->val == 0) {  // Zero case
        *fp_out = 0;
        return 0;
    }
    if (f->exponent != 0xFF) {  // Normal case
        int real_exp = (int)f->exponent - 127;
        uint32_t real_mant = f->mantissa | BIT(23);  // Add the hidden bit
        // Overflow check
        if (real_exp >= (int)fp_cfg->int_bit) {
            ret = -1;
        }
        // Determine sign
        output |= f->sign << (fp_cfg->int_bit + fp_cfg->frac_bit);
        // Determine integer and fraction part
        int shift = 23 - fp_cfg->frac_bit - real_exp;
        output |= shift >= 0 ? real_mant >> shift : real_mant << -shift;
    } else {
        if (f->mantissa && f->mantissa < BIT(23) - 1) {  // NaN (Not-a-Number) case
            return -2;
        } else {  // Infinity or Largest Number case
            output = f->sign ? ~(uint32_t)0 : BIT(31) - 1;
            ret = -1;
        }
    }

    if (ret != 0 && fp_cfg->saturation) {
        *fp_out = (f->sign << (fp_cfg->int_bit + fp_cfg->frac_bit)) |
                (BIT_MASK(fp_cfg->int_bit + fp_cfg->frac_bit));
    } else {
        *fp_out = output;
    }
    return ret;
}
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`/*`
fix(hal_utils): add division range check in integral algorithm 2024-01-12 07:09:51 +00:00			`* SPDX-FileCopyrightText: 2023-2024 Espressif Systems (Shanghai) CO LTD`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`*`
			`* SPDX-License-Identifier: Apache-2.0`
			`*/`

			`#include "hal/hal_utils.h"`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`#include "hal/assert.h"`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00
feat(hal_utils): added float to fixed point function 2024-05-31 17:48:40 +00:00			`#ifndef BIT`
			`#define BIT(n) (1UL << (n))`
			`#endif`

			`#ifndef BIT_MASK`
			`#define BIT_MASK(n) (BIT(n) - 1)`
			`#endif`

feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`__attribute__((always_inline))`
			`static inline uint32_t _sub_abs(uint32_t a, uint32_t b)`
			`{`
			`return a > b ? a - b : b - a;`
			`}`

refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`uint32_t hal_utils_calc_clk_div_frac_fast(const hal_utils_clk_info_t clk_info, hal_utils_clk_div_t clk_div)`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`{`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`HAL_ASSERT(clk_info->max_fract > 2);`
			`uint32_t div_denom = 2;`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`uint32_t div_numer = 0;`
			`uint32_t div_integ = clk_info->src_freq_hz / clk_info->exp_freq_hz;`
			`uint32_t freq_error = clk_info->src_freq_hz % clk_info->exp_freq_hz;`

			`// fractional divider`
			`if (freq_error) {`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`// Carry bit if the decimal is greater than 1.0 - 1.0 / ((max_fract - 1) * 2)`
			`if (freq_error < clk_info->exp_freq_hz - clk_info->exp_freq_hz / (clk_info->max_fract - 1) * 2) {`
			`// Calculate the Greatest Common Divisor, time complexity O(log n)`
feat(dma): refactor dma calloc function 2024-03-29 03:36:27 +00:00			`uint32_t gcd = hal_utils_gcd(clk_info->exp_freq_hz, freq_error);`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`// divide by the Greatest Common Divisor to get the accurate fraction before normalization`
			`div_denom = clk_info->exp_freq_hz / gcd;`
			`div_numer = freq_error / gcd;`
			`// normalize div_denom and div_numer`
			`uint32_t d = div_denom / clk_info->max_fract + 1;`
			`// divide by the normalization coefficient to get the denominator and numerator within range of clk_info->max_fract`
			`div_denom /= d;`
			`div_numer /= d;`
			`} else {`
			`div_integ++;`
			`}`
			`}`

			`// If the expect frequency is too high or too low to satisfy the integral division range, failed and return 0`
			`if (div_integ < clk_info->min_integ \|\| div_integ >= clk_info->max_integ \|\| div_integ == 0) {`
			`return 0;`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`}`

			`// Assign result`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`clk_div->integer = div_integ;`
			`clk_div->denominator = div_denom;`
			`clk_div->numerator = div_numer;`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00
			`// Return the actual frequency`
			`if (div_numer) {`
			`uint32_t temp = div_integ * div_denom + div_numer;`
			`return (uint32_t)(((uint64_t)clk_info->src_freq_hz * div_denom + temp / 2) / temp);`
			`}`
			`return clk_info->src_freq_hz / div_integ;`
			`}`

refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`uint32_t hal_utils_calc_clk_div_frac_accurate(const hal_utils_clk_info_t clk_info, hal_utils_clk_div_t clk_div)`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`{`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`HAL_ASSERT(clk_info->max_fract > 2);`
			`uint32_t div_denom = 2;`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`uint32_t div_numer = 0;`
			`uint32_t div_integ = clk_info->src_freq_hz / clk_info->exp_freq_hz;`
			`uint32_t freq_error = clk_info->src_freq_hz % clk_info->exp_freq_hz;`

			`if (freq_error) {`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`// Carry bit if the decimal is greater than 1.0 - 1.0 / ((max_fract - 1) * 2)`
			`if (freq_error < clk_info->exp_freq_hz - clk_info->exp_freq_hz / (clk_info->max_fract - 1) * 2) {`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`// Search the closest fraction, time complexity O(n)`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`for (uint32_t sub = 0, a = 2, b = 0, min = UINT32_MAX; min && a < clk_info->max_fract; a++) {`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`b = (a * freq_error + clk_info->exp_freq_hz / 2) / clk_info->exp_freq_hz;`
			`sub = _sub_abs(clk_info->exp_freq_hz * b, freq_error * a);`
			`if (sub < min) {`
			`div_denom = a;`
			`div_numer = b;`
			`min = sub;`
			`}`
			`}`
			`} else {`
			`div_integ++;`
			`}`
			`}`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00
			`// If the expect frequency is too high or too low to satisfy the integral division range, failed and return 0`
			`if (div_integ < clk_info->min_integ \|\| div_integ >= clk_info->max_integ \|\| div_integ == 0) {`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00			`return 0;`
			`}`

			`// Assign result`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00			`clk_div->integer = div_integ;`
			`clk_div->denominator = div_denom;`
			`clk_div->numerator = div_numer;`
feat(hal): add hal utils for clock divider calculation 2023-09-08 10:23:10 +00:00
			`// Return the actual frequency`
			`if (div_numer) {`
			`uint32_t temp = div_integ * div_denom + div_numer;`
			`return (uint32_t)(((uint64_t)clk_info->src_freq_hz * div_denom + temp / 2) / temp);`
			`}`
			`return clk_info->src_freq_hz / div_integ;`
			`}`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00
			`uint32_t hal_utils_calc_clk_div_integer(const hal_utils_clk_info_t clk_info, uint32_t int_div)`
			`{`
			`uint32_t div_integ = clk_info->src_freq_hz / clk_info->exp_freq_hz;`
			`uint32_t freq_error = clk_info->src_freq_hz % clk_info->exp_freq_hz;`

			`/* If there is error and always round up,`
			`Or, do the normal rounding and error >= (src/n + src/(n+1)) / 2,`
			`then carry the bit */`
			`if ((freq_error && clk_info->round_opt == HAL_DIV_ROUND_UP) \|\| (clk_info->round_opt == HAL_DIV_ROUND &&`
			`(freq_error >= clk_info->src_freq_hz / (2 * div_integ * (div_integ + 1))))) {`
			`div_integ++;`
			`}`
fix(hal_utils): add division range check in integral algorithm 2024-01-12 07:09:51 +00:00			`/* Check the integral division whether in range [min_integ, max_integ) */`
			`/* If the result is less than the minimum, set the division to the minimum but return 0 */`
			`if (div_integ < clk_info->min_integ) {`
			`*int_div = clk_info->min_integ;`
			`return 0;`
			`}`
			`/* if the result is greater or equal to the maximum , set the division to the maximum but return 0 */`
			`if (div_integ >= clk_info->max_integ) {`
			`*int_div = clk_info->max_integ - 1;`
			`return 0;`
			`}`
refactor(hal): use hal utils to calculate clock division 2023-09-11 04:58:38 +00:00
			`// Assign result`
			`*int_div = div_integ;`
			`// Return the actual frequency`
			`return clk_info->src_freq_hz / div_integ;`
			`}`
feat(hal_utils): added float to fixed point function 2024-05-31 17:48:40 +00:00
			`typedef union {`
			`struct {`
			`uint32_t mantissa: 23;`
			`uint32_t exponent: 8;`
			`uint32_t sign: 1;`
			`};`
			`uint32_t val;`
			`} hal_utils_ieee754_float_t;`

			`int hal_utils_float_to_fixed_point_32b(float flt, const hal_utils_fixed_point_t fp_cfg, uint32_t fp_out)`
			`{`
			`int ret = 0;`
			`uint32_t output = 0;`
			`const hal_utils_ieee754_float_t f = (const hal_utils_ieee754_float_t )&flt;`
			`if (fp_cfg->int_bit + fp_cfg->frac_bit > 31) {`
			`// Not supported`
			`return -3;`
			`}`

			`if (f->val == 0) { // Zero case`
			`*fp_out = 0;`
			`return 0;`
			`}`
			`if (f->exponent != 0xFF) { // Normal case`
			`int real_exp = (int)f->exponent - 127;`
			`uint32_t real_mant = f->mantissa \| BIT(23); // Add the hidden bit`
			`// Overflow check`
			`if (real_exp >= (int)fp_cfg->int_bit) {`
			`ret = -1;`
			`}`
			`// Determine sign`
			`output \|= f->sign << (fp_cfg->int_bit + fp_cfg->frac_bit);`
			`// Determine integer and fraction part`
			`int shift = 23 - fp_cfg->frac_bit - real_exp;`
			`output \|= shift >= 0 ? real_mant >> shift : real_mant << -shift;`
			`} else {`
			`if (f->mantissa && f->mantissa < BIT(23) - 1) { // NaN (Not-a-Number) case`
			`return -2;`
			`} else { // Infinity or Largest Number case`
			`output = f->sign ? ~(uint32_t)0 : BIT(31) - 1;`
			`ret = -1;`
			`}`
			`}`

			`if (ret != 0 && fp_cfg->saturation) {`
			`*fp_out = (f->sign << (fp_cfg->int_bit + fp_cfg->frac_bit)) \|`
			`(BIT_MASK(fp_cfg->int_bit + fp_cfg->frac_bit));`
			`} else {`
			`*fp_out = output;`
			`}`
			`return ret;`
			`}`