jLynx 033c4e9a5b
Formatted code (#1007)
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2023-05-19 08:16:05 +12:00

336 lines
8.1 KiB
C++

/*
* 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 __GPDMA_H__
#define __GPDMA_H__
#include <cstdint>
#include <cstddef>
#include <array>
#include "hal.h"
#include "utility.hpp"
namespace lpc43xx {
namespace gpdma {
/* LPC43xx DMA appears to be the ARM PrimeCell(R) DMA Controller, or very
* closely related.
* More here: http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0196g/Chdcdaeb.html
*/
constexpr size_t buffer_words(const size_t bytes, const size_t word_size) {
return (bytes + word_size - 1) / word_size;
}
using TCHandler = void (*)(void);
using ErrHandler = void (*)(void);
enum class FlowControl {
MemoryToMemory_DMAControl = 0x0,
MemoryToPeripheral_DMAControl = 0x1,
PeripheralToMemory_DMAControl = 0x2,
SourcePeripheralToDestinationPeripheral_DMAControl = 0x3,
SourcePeripheralToDestinationPeripheral_DestinationControl = 0x4,
MemoryToPeripheral_PeripheralControl = 0x5,
PeripheralToMemory_PeripheralControl = 0x6,
SourcePeripheralToDestinationPeripheral_SourceControl = 0x7,
};
static const uint_fast8_t flow_control_peripheral_source_map = 0b11011100;
constexpr uint_fast8_t source_endpoint_type(const FlowControl flow_control) {
return (flow_control_peripheral_source_map >> toUType(flow_control)) & 1;
}
static const uint_fast8_t flow_control_peripheral_destination_map = 0b11111010;
constexpr uint_fast8_t destination_endpoint_type(const FlowControl flow_control) {
return (flow_control_peripheral_destination_map >> toUType(flow_control)) & 1;
}
namespace mux {
enum class Peripheral0 {
SPIFI = 0,
SCT_CTOUT_2 = 1,
SGPIO14 = 2,
TIMER3_MATCH_1 = 3,
};
enum class Peripheral1 {
TIMER0_MATCH_0 = 0,
USART0_TX = 1,
};
enum class Peripheral2 {
TIMER0_MATCH_1 = 0,
USART0_RX = 1,
};
enum class Peripheral3 {
TIMER1_MATCH_0 = 0,
UART1_TX = 1,
I2S1_DMAREQ_1 = 2,
SSP1_TX = 3,
};
enum class Peripheral4 {
TIMER1_MATCH_1 = 0,
UART1_RX = 1,
I2S1_DMAREQ_2 = 2,
SSP1_RX = 3,
};
enum class Peripheral5 {
TIMER2_MATCH_0 = 0,
USART2_TX = 1,
SSP1_TX = 2,
SGPIO15 = 3,
};
enum class Peripheral6 {
TIMER2_MATCH_1 = 0,
USART2_RX = 1,
SSP1_RX = 2,
SGPIO14 = 3,
};
enum class Peripheral7 {
TIMER3_MATCH_0 = 0,
USART3_TX = 1,
SCT_DMAREQ_0 = 2,
ADCHS_WRITE = 3,
};
enum class Peripheral8 {
TIMER3_MATCH_1 = 0,
USART3_RX = 1,
SCT_DMAREQ_1 = 2,
ADCHS_READ = 3,
};
enum class Peripheral9 {
SSP0_RX = 0,
I2S0_DMAREQ_1 = 1,
SCT_DMAREQ_1 = 2,
};
enum class Peripheral10 {
SSP0_TX = 0,
I2S0_DMAREQ_2 = 1,
SCT_DMAREQ_0 = 2,
};
enum class Peripheral11 {
SSP1_RX = 0,
SGPIO14 = 1,
USART0_TX = 2,
};
enum class Peripheral12 {
SSP1_TX = 0,
SGPIO15 = 1,
USART0_RX = 2,
};
enum class Peripheral13 {
ADC0 = 0,
SSP1_RX = 2,
USART3_RX = 3,
};
enum class Peripheral14 {
ADC1 = 0,
SSP1_TX = 2,
USART3_TX = 3,
};
enum class Peripheral15 {
DAC = 0,
SCT_CTOUT_3 = 1,
SGPIO15 = 2,
TIMER3_MATCH_0 = 3,
};
struct MUX {
Peripheral0 peripheral_0;
Peripheral1 peripheral_1;
Peripheral2 peripheral_2;
Peripheral3 peripheral_3;
Peripheral4 peripheral_4;
Peripheral5 peripheral_5;
Peripheral6 peripheral_6;
Peripheral7 peripheral_7;
Peripheral8 peripheral_8;
Peripheral9 peripheral_9;
Peripheral10 peripheral_10;
Peripheral11 peripheral_11;
Peripheral12 peripheral_12;
Peripheral13 peripheral_13;
Peripheral14 peripheral_14;
Peripheral15 peripheral_15;
constexpr operator uint32_t() const {
return (toUType(peripheral_0) << 0) | (toUType(peripheral_1) << 2) | (toUType(peripheral_2) << 4) | (toUType(peripheral_3) << 6) | (toUType(peripheral_4) << 8) | (toUType(peripheral_5) << 10) | (toUType(peripheral_6) << 12) | (toUType(peripheral_7) << 14) | (toUType(peripheral_8) << 16) | (toUType(peripheral_9) << 18) | (toUType(peripheral_10) << 20) | (toUType(peripheral_11) << 22) | (toUType(peripheral_12) << 24) | (toUType(peripheral_13) << 26) | (toUType(peripheral_14) << 28) | (toUType(peripheral_15) << 30);
}
};
} /* namespace mux */
namespace channel {
struct LLI {
uint32_t srcaddr;
uint32_t destaddr;
uint32_t lli;
uint32_t control;
};
struct LLIPointer {
uint32_t lm;
uint32_t r;
uint32_t lli;
constexpr operator uint32_t() const {
return ((lm & 1) << 0) | ((r & 1) << 1) | (lli & 0xfffffffc);
}
};
struct Control {
uint32_t transfersize;
uint32_t sbsize;
uint32_t dbsize;
uint32_t swidth;
uint32_t dwidth;
uint32_t s;
uint32_t d;
uint32_t si;
uint32_t di;
uint32_t prot1;
uint32_t prot2;
uint32_t prot3;
uint32_t i;
constexpr operator uint32_t() const {
return ((transfersize & 0xfff) << 0) | ((sbsize & 7) << 12) | ((dbsize & 7) << 15) | ((swidth & 7) << 18) | ((dwidth & 7) << 21) | ((s & 1) << 24) | ((d & 1) << 25) | ((si & 1) << 26) | ((di & 1) << 27) | ((prot1 & 1) << 28) | ((prot2 & 1) << 29) | ((prot3 & 1) << 30) | ((i & 1) << 31);
}
};
struct Config {
uint32_t e;
uint32_t srcperipheral;
uint32_t destperipheral;
FlowControl flowcntrl;
uint32_t ie;
uint32_t itc;
uint32_t l;
uint32_t a;
uint32_t h;
constexpr operator uint32_t() const {
return ((e & 1) << 0) | ((srcperipheral & 0x1f) << 1) | ((destperipheral & 0x1f) << 6) | ((toUType(flowcntrl) & 7) << 11) | ((ie & 1) << 14) | ((itc & 1) << 15) | ((l & 1) << 16) | ((a & 1) << 17) | ((h & 1) << 18);
}
};
class Channel {
public:
constexpr Channel(
const size_t number)
: number(number) {
}
void enable() const {
LPC_GPDMA->CH[number].CONFIG |= (1U << 0);
}
bool is_enabled() const {
return LPC_GPDMA->CH[number].CONFIG & (1U << 0);
}
void disable() const {
LPC_GPDMA->CH[number].CONFIG &= ~(1U << 0);
}
void clear_interrupts() const {
LPC_GPDMA->INTTCCLR = (1U << number);
LPC_GPDMA->INTERRCLR = (1U << number);
}
void set_handlers(const TCHandler tc_handler, const ErrHandler err_handler) const;
void configure(const LLI& first_lli, const uint32_t config) const;
const LLI* next_lli() const {
return reinterpret_cast<LLI*>(LPC_GPDMA->CH[number].LLI);
}
private:
const size_t number;
};
} /* namespace channel */
constexpr std::array<channel::Channel, 8> channels{{
{0},
{1},
{2},
{3},
{4},
{5},
{6},
{7},
}};
static const gpdma_resources_t gpdma_resources = {
.base = {.clk = &LPC_CGU->BASE_M4_CLK, .stat = &LPC_CCU1->BASE_STAT, .stat_mask = (1 << 3)},
.branch = {.cfg = &LPC_CCU1->CLK_M4_DMA_CFG, .stat = &LPC_CCU1->CLK_M4_DMA_STAT},
.reset = {.output_index = 19},
};
class Controller {
public:
void enable() const {
base_clock_enable(&gpdma_resources.base);
branch_clock_enable(&gpdma_resources.branch);
peripheral_reset(&gpdma_resources.reset);
LPC_GPDMA->CONFIG |= (1U << 0);
}
void disable() const {
for (const auto& channel : channels) {
channel.disable();
}
LPC_GPDMA->CONFIG &= ~(1U << 0);
peripheral_reset(&gpdma_resources.reset);
branch_clock_disable(&gpdma_resources.branch);
base_clock_disable(&gpdma_resources.base);
}
};
constexpr Controller controller;
} /* namespace gpdma */
} /* namespace lpc43xx */
#endif /*__GPDMA_H__*/