/*
 * Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc.
 *
 * This file is part of PortaPack.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2, or (at your option)
 * any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.	See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; see the file COPYING.	If not, write to
 * the Free Software Foundation, Inc., 51 Franklin Street,
 * Boston, MA 02110-1301, USA.
 */

#ifndef __LPC43XX_CPP_H__
#define __LPC43XX_CPP_H__

#include <cstdint>

#include <hal.h>

#include "utility.hpp"

namespace lpc43xx {

#if defined(LPC43XX_M4)
namespace m4 {

static inline bool flag_saturation() {
    return __get_APSR() & (1U << 27);
}

static inline void clear_flag_saturation() {
    uint32_t flags = 1;
    __asm volatile("MSR APSR_nzcvqg, %0"
                   :
                   : "r"(flags));
}

} /* namespace m4 */
#endif

namespace creg {

static_assert(offsetof(LPC_CREG_Type, CREG0) == 0x004, "CREG0 offset wrong");
static_assert(offsetof(LPC_CREG_Type, M4MEMMAP) == 0x100, "M4MEMMAP offset wrong");
static_assert(offsetof(LPC_CREG_Type, CREG5) == 0x118, "CREG5 offset wrong");
static_assert(offsetof(LPC_CREG_Type, CHIPID) == 0x200, "CHIPID offset wrong");
static_assert(offsetof(LPC_CREG_Type, M0SUBMEMMAP) == 0x308, "M0SUBMEMMAP offset wrong");
static_assert(offsetof(LPC_CREG_Type, M0APPTXEVENT) == 0x400, "M0APPTXEVENT offset wrong");
static_assert(offsetof(LPC_CREG_Type, USB0FLADJ) == 0x500, "USB0FLADJ offset wrong");
static_assert(offsetof(LPC_CREG_Type, USB1FLADJ) == 0x600, "USB1FLADJ offset wrong");

namespace m4txevent {

#if defined(LPC43XX_M0)
inline void enable() {
    nvicEnableVector(M4CORE_IRQn, CORTEX_PRIORITY_MASK(LPC43XX_M4TXEVENT_IRQ_PRIORITY));
}

inline void disable() {
    nvicDisableVector(M4CORE_IRQn);
}
#endif

#if defined(LPC43XX_M4)
inline void assert_event() {
    __SEV();
}
#endif

inline void clear() {
    LPC_CREG->M4TXEVENT = 0;
}

} /* namespace m4txevent */

namespace m0apptxevent {

#if defined(LPC43XX_M4)
inline void enable() {
    nvicEnableVector(M0CORE_IRQn, CORTEX_PRIORITY_MASK(LPC43XX_M0APPTXEVENT_IRQ_PRIORITY));
}

inline void disable() {
    nvicDisableVector(M0CORE_IRQn);
}
#endif

#if defined(LPC43XX_M0)
inline void assert_event() {
    __SEV();
}
#endif

inline void clear() {
    LPC_CREG->M0APPTXEVENT = 0;
}

}  // namespace m0apptxevent

} /* namespace creg */

namespace cgu {

enum class CLK_SEL : uint8_t {
    RTC_32KHZ = 0x00,
    IRC = 0x01,
    ENET_RX_CLK = 0x02,
    ENET_TX_CLK = 0x03,
    GP_CLKIN = 0x04,
    XTAL = 0x06,
    PLL0USB = 0x07,
    PLL0AUDIO = 0x08,
    PLL1 = 0x09,
    IDIVA = 0x0c,
    IDIVB = 0x0d,
    IDIVC = 0x0e,
    IDIVD = 0x0f,
    IDIVE = 0x10,
};

struct IDIV_CTRL {
    uint32_t pd;
    uint32_t idiv;
    uint32_t autoblock;
    CLK_SEL clk_sel;

    constexpr operator uint32_t() const {
        return ((pd & 1) << 0) | ((idiv & 255) << 2) | ((autoblock & 1) << 11) | ((toUType(clk_sel) & 0x1f) << 24);
    }
};

namespace pll0audio {

struct CTRL {
    uint32_t pd;
    uint32_t bypass;
    uint32_t directi;
    uint32_t directo;
    uint32_t clken;
    uint32_t frm;
    uint32_t autoblock;
    uint32_t pllfract_req;
    uint32_t sel_ext;
    uint32_t mod_pd;
    CLK_SEL clk_sel;

    constexpr operator uint32_t() const {
        return ((pd & 1) << 0) | ((bypass & 1) << 1) | ((directi & 1) << 2) | ((directo & 1) << 3) | ((clken & 1) << 4) | ((frm & 1) << 6) | ((autoblock & 1) << 11) | ((pllfract_req & 1) << 12) | ((sel_ext & 1) << 13) | ((mod_pd & 1) << 14) | ((toUType(clk_sel) & 0x1f) << 24);
    }
};

struct MDIV {
    uint32_t mdec;

    constexpr operator uint32_t() const {
        return ((mdec & 0x1ffff) << 0);
    }
};

struct NP_DIV {
    uint32_t pdec;
    uint32_t ndec;

    constexpr operator uint32_t() const {
        return ((pdec & 0x7f) << 0) | ((ndec & 0x3ff) << 12);
    }
};

struct FRAC {
    uint32_t pllfract_ctrl;

    constexpr operator uint32_t() const {
        return ((pllfract_ctrl & 0x3fffff) << 0);
    }
};

inline void ctrl(const CTRL& value) {
    LPC_CGU->PLL0AUDIO_CTRL = value;
}

inline void mdiv(const MDIV& value) {
    LPC_CGU->PLL0AUDIO_MDIV = value;
}

inline void np_div(const NP_DIV& value) {
    LPC_CGU->PLL0AUDIO_NP_DIV = value;
}

inline void frac(const FRAC& value) {
    LPC_CGU->PLL0AUDIO_FRAC = value;
}

inline void power_up() {
    LPC_CGU->PLL0AUDIO_CTRL &= ~(1U << 0);
}

inline void power_down() {
    LPC_CGU->PLL0AUDIO_CTRL |= (1U << 0);
}

inline bool is_locked() {
    return LPC_CGU->PLL0AUDIO_STAT & (1U << 0);
}

inline void clock_enable() {
    LPC_CGU->PLL0AUDIO_CTRL |= (1U << 4);
}

inline void clock_disable() {
    LPC_CGU->PLL0AUDIO_CTRL &= ~(1U << 4);
}

} /* namespace pll0audio */

namespace pll1 {

struct CTRL {
    uint32_t pd;
    uint32_t bypass;
    uint32_t fbsel;
    uint32_t direct;
    uint32_t psel;
    uint32_t autoblock;
    uint32_t nsel;
    uint32_t msel;
    CLK_SEL clk_sel;

    constexpr operator uint32_t() const {
        return ((pd & 1) << 0) | ((bypass & 1) << 1) | ((fbsel & 1) << 6) | ((direct & 1) << 7) | ((psel & 3) << 8) | ((autoblock & 1) << 11) | ((nsel & 3) << 12) | ((msel & 0xff) << 16) | ((toUType(clk_sel) & 0x1f) << 24);
    }
};

inline void ctrl(const CTRL& value) {
    LPC_CGU->PLL1_CTRL = value;
}

inline void enable() {
    LPC_CGU->PLL1_CTRL &= ~(1U << 0);
}

inline void disable() {
    LPC_CGU->PLL1_CTRL |= (1U << 0);
}

inline void direct() {
    LPC_CGU->PLL1_CTRL |= (1U << 7);
}

inline bool is_locked() {
    return LPC_CGU->PLL1_STAT & (1U << 0);
}

} /* namespace pll1 */

} /* namespace cgu */

namespace ccu1 {

static_assert(offsetof(LPC_CCU1_Type, CLK_ADCHS_STAT) == 0xb04, "CLK_ADCHS_STAT offset wrong");

} /* namespace ccu1 */

namespace rgu {

enum class Reset {
    CORE = 0,
    PERIPH = 1,
    MASTER = 2,
    WWDT = 4,
    CREG = 5,
    BUS = 8,
    SCU = 9,
    M0_SUB = 12,
    M4_RST = 13,
    LCD = 16,
    USB0 = 17,
    USB1 = 18,
    DMA = 19,
    SDIO = 20,
    EMC = 21,
    ETHERNET = 22,
    FLASHA = 25,
    EEPROM = 27,
    GPIO = 28,
    FLASHB = 29,
    TIMER0 = 32,
    TIMER1 = 33,
    TIMER2 = 34,
    TIMER3 = 35,
    RITIMER = 36,
    SCT = 37,
    MOTOCONPWM = 38,
    QEI = 39,
    ADC0 = 40,
    ADC1 = 41,
    DAC = 42,
    UART0 = 44,
    UART1 = 45,
    UART2 = 46,
    UART3 = 47,
    I2C0 = 48,
    I2C1 = 49,
    SSP0 = 50,
    SSP1 = 51,
    I2S = 52,
    SPIFI = 53,
    CAN1 = 54,
    CAN0 = 55,
    M0APP = 56,
    SGPIO = 57,
    SPI = 58,
    ADCHS = 60,
};

enum class Status {
    NotActive = 0b00,
    ActivatedByRGUInput = 0b01,
    ActivatedBySoftware = 0b11,
};

inline void reset(const Reset reset) {
    LPC_RGU->RESET_CTRL[toUType(reset) >> 5] = (1U << (toUType(reset) & 0x1f));
}

inline void reset_mask(const uint64_t mask) {
    LPC_RGU->RESET_CTRL[0] = mask & 0xffffffffU;
    LPC_RGU->RESET_CTRL[1] = mask >> 32;
}

inline Status status(const Reset reset) {
    return static_cast<Status>(
        (LPC_RGU->RESET_STATUS[toUType(reset) >> 4] >> ((toUType(reset) & 0xf) * 2)) & 3);
}

inline bool active(const Reset reset) {
    return (LPC_RGU->RESET_ACTIVE_STATUS[toUType(reset) >> 5] >> (toUType(reset) & 0x1f)) & 1;
}

inline uint32_t external_status(const Reset reset) {
    return LPC_RGU->RESET_EXT_STAT[toUType(reset)];
}

inline uint64_t operator|(Reset r1, Reset r2) {
    return (1ULL << toUType(r1)) | (1ULL << toUType(r2));
}

inline uint64_t operator|(uint64_t m, Reset r) {
    return m | (1ULL << toUType(r));
}

static_assert(offsetof(LPC_RGU_Type, RESET_CTRL[0]) == 0x100, "RESET_CTRL[0] offset wrong");
static_assert(offsetof(LPC_RGU_Type, RESET_STATUS[0]) == 0x110, "RESET_STATUS[0] offset wrong");
static_assert(offsetof(LPC_RGU_Type, RESET_ACTIVE_STATUS[0]) == 0x150, "RESET_ACTIVE_STATUS[0] offset wrong");
static_assert(offsetof(LPC_RGU_Type, RESET_EXT_STAT[1]) == 0x404, "RESET_EXT_STAT[1] offset wrong");
static_assert(offsetof(LPC_RGU_Type, RESET_EXT_STAT[60]) == 0x4f0, "RESET_EXT_STAT[60] offset wrong");

} /* namespace rgu */

namespace scu {

struct SFS {
    uint32_t mode;
    uint32_t epd;
    uint32_t epun;
    uint32_t ehs;
    uint32_t ezi;
    uint32_t zif;

    constexpr operator uint32_t() const {
        return ((mode & 7) << 0) | ((epd & 1) << 3) | ((epun & 1) << 4) | ((ehs & 1) << 5) | ((ezi & 1) << 6) | ((zif & 1) << 7);
    }
};

static_assert(offsetof(LPC_SCU_Type, PINTSEL0) == 0xe00, "PINTSEL0 offset wrong");

} /* namespace scu */

namespace sgpio {

static_assert(offsetof(LPC_SGPIO_Type, MASK_A) == 0x0200, "SGPIO MASK_A offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, GPIO_OUTREG) == 0x0214, "SGPIO GPIO_OUTREG offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, CTRL_DISABLE) == 0x0220, "SGPIO CTRL_DISABLE offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, CLR_EN_0) == 0x0f00, "SGPIO CLR_EN_0 offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, CLR_EN_1) == 0x0f20, "SGPIO CLR_EN_1 offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, CLR_EN_2) == 0x0f40, "SGPIO CLR_EN_2 offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, CLR_EN_3) == 0x0f60, "SGPIO CLR_EN_3 offset wrong");
static_assert(offsetof(LPC_SGPIO_Type, SET_STATUS_3) == 0x0f74, "SGPIO SET_STATUS_3 offset wrong");
static_assert(sizeof(LPC_SGPIO_Type) == 0x0f78, "SGPIO type size wrong");

} /* namespace sgpio */

namespace gpdma {

static_assert(offsetof(LPC_GPDMA_Type, SYNC) == 0x034, "GPDMA SYNC offset wrong");
static_assert(offsetof(LPC_GPDMA_Type, CH[0]) == 0x100, "GPDMA CH[0] offset wrong");
static_assert(offsetof(LPC_GPDMA_Type, CH[7]) == 0x1e0, "GPDMA CH[7] offset wrong");

} /* namespace gpdma */

namespace sdmmc {

static_assert(offsetof(LPC_SDMMC_Type, RESP0) == 0x030, "SDMMC RESP0 offset wrong");
static_assert(offsetof(LPC_SDMMC_Type, TCBCNT) == 0x05c, "SDMMC TCBCNT offset wrong");
static_assert(offsetof(LPC_SDMMC_Type, RST_N) == 0x078, "SDMMC RST_N offset wrong");
static_assert(offsetof(LPC_SDMMC_Type, BMOD) == 0x080, "SDMMC BMOD offset wrong");
static_assert(offsetof(LPC_SDMMC_Type, DATA) == 0x100, "SDMMC DATA offset wrong");

} /* namespace sdmmc */

namespace spifi {

struct CTRL {
    uint32_t timeout;
    uint32_t cshigh;
    uint32_t d_prftch_dis;
    uint32_t inten;
    uint32_t mode3;
    uint32_t prftch_dis;
    uint32_t dual;
    uint32_t rfclk;
    uint32_t fbclk;
    uint32_t dmaen;

    constexpr operator uint32_t() const {
        return ((timeout & 0xffff) << 0) | ((cshigh & 1) << 16) | ((d_prftch_dis & 1) << 21) | ((inten & 1) << 22) | ((mode3 & 1) << 23) | ((prftch_dis & 1) << 27) | ((dual & 1) << 28) | ((rfclk & 1) << 29) | ((fbclk & 1) << 30) | ((dmaen & 1) << 31);
    }
};

static_assert(offsetof(LPC_SPIFI_Type, STAT) == 0x01c, "SPIFI STAT offset wrong");

} /* namespace spifi */

namespace timer {

static_assert(offsetof(LPC_TIMER_Type, MR[0]) == 0x018, "TIMER MR[0] offset wrong");
static_assert(offsetof(LPC_TIMER_Type, CCR) == 0x028, "TIMER CCR offset wrong");
static_assert(offsetof(LPC_TIMER_Type, EMR) == 0x03c, "TIMER EMR offset wrong");
static_assert(offsetof(LPC_TIMER_Type, CTCR) == 0x070, "TIMER CTCR offset wrong");

} /* namespace timer */

namespace rtc {

namespace interrupt {

inline void clear_all() {
    LPC_RTC->ILR = (1U << 1) | (1U << 0);
}

inline void enable_second_inc() {
    LPC_RTC->CIIR = (1U << 0);
}

}  // namespace interrupt

#if HAL_USE_RTC
struct RTC : public RTCTime {
    constexpr RTC(
        uint32_t year,
        uint32_t month,
        uint32_t day,
        uint32_t hour,
        uint32_t minute,
        uint32_t second)
        : RTCTime{
              (year << 16) | (month << 8) | (day << 0),
              (hour << 16) | (minute << 8) | (second << 0)} {
    }

    constexpr RTC()
        : RTCTime{0, 0} {
    }

    uint16_t year() const {
        return (tv_date >> 16) & 0xfff;
    }

    uint8_t month() const {
        return (tv_date >> 8) & 0x00f;
    }

    uint8_t day() const {
        return (tv_date >> 0) & 0x01f;
    }

    uint8_t hour() const {
        return (tv_time >> 16) & 0x01f;
    }

    uint8_t minute() const {
        return (tv_time >> 8) & 0x03f;
    }

    uint8_t second() const {
        return (tv_time >> 0) & 0x03f;
    }
};
#endif

static_assert(offsetof(LPC_RTC_Type, CCR) == 0x008, "RTC CCR offset wrong");
static_assert(offsetof(LPC_RTC_Type, ASEC) == 0x060, "RTC ASEC offset wrong");

} /* namespace rtc */

} /* namespace lpc43xx */

#endif /*__LPC43XX_CPP_H__*/