rustyfit 0.4.1

This project hosts the Rust implementation for The Flexible and Interoperable Data Transfer (FIT) Protocol
Documentation 
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// Code generated by fitgen/main.go. DO NOT EDIT.

// Copyright 2025 The RustyFIT Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

#![allow(unused, clippy::comparison_to_empty, clippy::manual_range_patterns)]

use crate::profile::{ProfileType, typedef};
use crate::proto::*;

#[derive(Debug, Clone)]
/// TrainingSettings is a TrainingSettings message.
pub struct TrainingSettings {
    /// Scale: 100; Units: m
    pub target_distance: u32,
    /// Scale: 1000; Units: m/s
    pub target_speed: u16,
    /// Units: s
    pub target_time: u32,
    /// Scale: 1e+06; Units: m/s; A more precise target speed field
    pub precise_target_speed: u32,
    /// unknown_fields are fields that are exist but they are not defined in Profile.xlsx
    pub unknown_fields: Vec<Field>,
    /// developer_fields are custom data fields (Added since protocol version 2.0)
    pub developer_fields: Vec<DeveloperField>,
}

impl TrainingSettings {
    /// Value's type: `u32`; Scale: `100`; Units: `m`
    pub const TARGET_DISTANCE: u8 = 31;
    /// Value's type: `u16`; Scale: `1000`; Units: `m/s`
    pub const TARGET_SPEED: u8 = 32;
    /// Value's type: `u32`; Units: `s`
    pub const TARGET_TIME: u8 = 33;
    /// Value's type: `u32`; Scale: `1e+06`; Units: `m/s`
    pub const PRECISE_TARGET_SPEED: u8 = 153;

    /// Create new TrainingSettings with all fields being set to its corresponding invalid value.
    pub const fn new() -> Self {
        Self {
            target_distance: u32::MAX,
            target_speed: u16::MAX,
            target_time: u32::MAX,
            precise_target_speed: u32::MAX,
            unknown_fields: Vec::new(),
            developer_fields: Vec::new(),
        }
    }

    /// Returns `target_distance` in its scaled value. It returns invalid f64 when value is valid.
    pub fn target_distance_scaled(&self) -> f64 {
        if self.target_distance == u32::MAX {
            return f64::from_bits(u64::MAX);
        }
        self.target_distance as f64 / 100.0 - 0.0
    }

    /// Set `target_distance` with scaled value, it will automatically be converted to its corresponding integer value.
    pub fn set_target_distance_scaled(&mut self, v: f64) -> &mut TrainingSettings {
        let unscaled = (v + 0.0) * 100.0;
        if unscaled.is_nan() || unscaled.is_infinite() || unscaled > u32::MAX as f64 {
            self.target_distance = u32::MAX;
            return self;
        }
        self.target_distance = unscaled as u32;
        self
    }

    /// Returns `target_speed` in its scaled value. It returns invalid f64 when value is valid.
    pub fn target_speed_scaled(&self) -> f64 {
        if self.target_speed == u16::MAX {
            return f64::from_bits(u64::MAX);
        }
        self.target_speed as f64 / 1000.0 - 0.0
    }

    /// Set `target_speed` with scaled value, it will automatically be converted to its corresponding integer value.
    pub fn set_target_speed_scaled(&mut self, v: f64) -> &mut TrainingSettings {
        let unscaled = (v + 0.0) * 1000.0;
        if unscaled.is_nan() || unscaled.is_infinite() || unscaled > u16::MAX as f64 {
            self.target_speed = u16::MAX;
            return self;
        }
        self.target_speed = unscaled as u16;
        self
    }

    /// Returns `precise_target_speed` in its scaled value. It returns invalid f64 when value is valid.
    pub fn precise_target_speed_scaled(&self) -> f64 {
        if self.precise_target_speed == u32::MAX {
            return f64::from_bits(u64::MAX);
        }
        self.precise_target_speed as f64 / 1000000.0 - 0.0
    }

    /// Set `precise_target_speed` with scaled value, it will automatically be converted to its corresponding integer value.
    pub fn set_precise_target_speed_scaled(&mut self, v: f64) -> &mut TrainingSettings {
        let unscaled = (v + 0.0) * 1000000.0;
        if unscaled.is_nan() || unscaled.is_infinite() || unscaled > u32::MAX as f64 {
            self.precise_target_speed = u32::MAX;
            return self;
        }
        self.precise_target_speed = unscaled as u32;
        self
    }
}

impl Default for TrainingSettings {
    fn default() -> Self {
        Self::new()
    }
}

impl From<&Message> for TrainingSettings {
    /// from creates new TrainingSettings struct based on given mesg.
    fn from(mesg: &Message) -> Self {
        let mut vals: [&Value; 154] = [const { &Value::Invalid }; 154];

        const KNOWN_NUMS: [u64; 4] = [15032385536, 0, 33554432, 0];
        let mut n = 0u64;
        for field in &mesg.fields {
            n += (KNOWN_NUMS[field.num as usize >> 6] >> (field.num & 63)) & 1 ^ 1
        }
        let mut unknown_fields: Vec<Field> = Vec::with_capacity(n as usize);

        for field in &mesg.fields {
            if (KNOWN_NUMS[field.num as usize >> 6] >> (field.num & 63)) & 1 == 0 {
                unknown_fields.push(field.clone());
                continue;
            }
            vals[field.num as usize] = &field.value;
        }

        Self {
            target_distance: vals[31].as_u32(),
            target_speed: vals[32].as_u16(),
            target_time: vals[33].as_u32(),
            precise_target_speed: vals[153].as_u32(),
            unknown_fields,
            developer_fields: mesg.developer_fields.clone(),
        }
    }
}

impl From<TrainingSettings> for Message {
    fn from(m: TrainingSettings) -> Self {
        let mut arr = [const {
            Field {
                num: 0,
                profile_type: ProfileType(0),
                value: Value::Invalid,
                is_expanded: false,
            }
        }; 4];
        let mut len = 0usize;

        if m.target_distance != u32::MAX {
            arr[len] = Field {
                num: 31,
                profile_type: ProfileType::UINT32,
                value: Value::Uint32(m.target_distance),
                is_expanded: false,
            };
            len += 1;
        }
        if m.target_speed != u16::MAX {
            arr[len] = Field {
                num: 32,
                profile_type: ProfileType::UINT16,
                value: Value::Uint16(m.target_speed),
                is_expanded: false,
            };
            len += 1;
        }
        if m.target_time != u32::MAX {
            arr[len] = Field {
                num: 33,
                profile_type: ProfileType::UINT32,
                value: Value::Uint32(m.target_time),
                is_expanded: false,
            };
            len += 1;
        }
        if m.precise_target_speed != u32::MAX {
            arr[len] = Field {
                num: 153,
                profile_type: ProfileType::UINT32,
                value: Value::Uint32(m.precise_target_speed),
                is_expanded: false,
            };
            len += 1;
        }

        Message {
            header: 0,
            num: typedef::MesgNum::TRAINING_SETTINGS,
            fields: {
                let mut fields: Vec<Field> = Vec::with_capacity(len + m.unknown_fields.len());
                fields.extend_from_slice(&arr[..len]);
                fields.extend_from_slice(&m.unknown_fields);
                fields
            },
            developer_fields: m.developer_fields,
        }
    }
}