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BALibrary_parasitstudio/src/BASpiMemory.h

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/**************************************************************************//**
* @file
* @author Steve Lascos
* @company Blackaddr Audio
*
* BASpiMemory is convenience class for accessing the optional SPI RAMs on
* the GTA Series boards.
*
* @copyright 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 3 of the License, 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. If not, see <http://www.gnu.org/licenses/>.
*****************************************************************************/
#ifndef __SRC_BASPIMEMORY_H
#define __SRC_BASPIMEMORY_H
#include <SPI.h>
#include <DmaSpi.h>
#include "BATypes.h"
#include "BAHardware.h"
namespace BAGuitar {
/**************************************************************************//**
* This wrapper class uses the Arduino SPI (Wire) library to access the SPI ram.
* @details The purpose of this class is primilary for functional testing since
* it currently support single-word access. High performance access should be
* done using DMA techniques in the Teensy library.
*****************************************************************************/
class BASpiMemory {
public:
BASpiMemory() = delete;
/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2).
/// @details default is 20 Mhz
/// @param memDeviceId specify which MEM to control with SpiDeviceId.
BASpiMemory(SpiDeviceId memDeviceId);
/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2)
/// @param memDeviceId specify which MEM to control with SpiDeviceId.
/// @param speedHz specify the desired speed in Hz.
BASpiMemory(SpiDeviceId memDeviceId, uint32_t speedHz);
virtual ~BASpiMemory();
virtual void begin();
/// write a single data word to the specified address
/// @param address the address in the SPI RAM to write to
/// @param data the value to write
void write(size_t address, uint8_t data);
virtual void write(size_t address, uint8_t *data, size_t numBytes);
virtual void zero(size_t address, size_t numBytes);
void write16(size_t address, uint16_t data);
virtual void write16(size_t address, uint16_t *data, size_t numWords);
virtual void zero16(size_t address, size_t numWords);
/// read a single 8-bit data word from the specified address
/// @param address the address in the SPI RAM to read from
/// @return the data that was read
uint8_t read(size_t address);
virtual void read(size_t address, uint8_t *data, size_t numBytes);
/// read a single 16-bit data word from the specified address
/// @param address the address in the SPI RAM to read from
/// @return the data that was read
uint16_t read16(size_t address);
/// read a block 16-bit data word from the specified address
/// @param address the address in the SPI RAM to read from
/// @param dest the pointer to the destination
/// @param numWords the number of 16-bit words to transfer
virtual void read16(size_t address, uint16_t *dest, size_t numWords);
bool isStarted() const { return m_started; }
protected:
SPIClass *m_spi = nullptr;
SpiDeviceId m_memDeviceId; // the MEM device being control with this instance
uint8_t m_csPin; // the IO pin number for the CS on the controlled SPI device
SPISettings m_settings; // the Wire settings for this SPI port
bool m_started = false;
};
//constexpr int MAX_DMA_XFERS = 4;
class BASpiMemoryDMA : public BASpiMemory {
BASpiMemoryDMA() = delete;
/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2).
/// @details default is 20 Mhz
/// @param memDeviceId specify which MEM to control with SpiDeviceId.
/// @param bufferSize size of buffer to store DMA transfers
BASpiMemoryDMA(SpiDeviceId memDeviceId, size_t bufferSizeBytes);
/// Create an object to control either MEM0 (via SPI1) or MEM1 (via SPI2)
/// @param memDeviceId specify which MEM to control with SpiDeviceId.
/// @param speedHz specify the desired speed in Hz.
/// @param bufferSize size of buffer to store DMA transfers
BASpiMemoryDMA(SpiDeviceId memDeviceId, uint32_t speedHz, size_t bufferSizeBytes);
virtual ~BASpiMemoryDMA();
void write(size_t address, uint8_t *data, size_t numBytes) override;
void zero(size_t address, size_t numBytes) override;
void write16(size_t address, uint16_t *data, size_t numWords) override;
void zero16(size_t address, size_t numWords) override;
/// read a single 8-bit data word from the specified address
/// @param address the address in the SPI RAM to read from
/// @return the data that was read
void read(size_t address, uint8_t *data, size_t numBytes) override;
/// read a block 16-bit data word from the specified address
/// @param address the address in the SPI RAM to read from
/// @param dest the pointer to the destination
/// @param numWords the number of 16-bit words to transfer
void read16(size_t address, uint16_t *dest, size_t numWords) override;
void begin() override;
void readBufferContents(size_t bufferOffset, uint8_t *dest, size_t numBytes);
private:
AbstractDmaSpi<DmaSpi0, SPIClass, SPI> *m_spiDma = nullptr;
ActiveLowChipSelect *m_cs = nullptr;
size_t m_bufferSize;
uint8_t *m_txBuffer = nullptr;
DmaSpi::Transfer *m_txTransfer;
uint8_t *m_rxBuffer = nullptr;
DmaSpi::Transfer *m_rxTransfer;
void m_setSpiCmdAddr(int command, size_t address, uint8_t *dest);
// RingBuffer<DmaSpi::Transfer> m_txFifo(MAX_DMA_XFERS);
// RingBuffer<DmaSpi::Transfer> m_rxFifo(MAX_DMA_XFERS);
};
} /* namespace BAGuitar */
#endif /* __SRC_BASPIMEMORY_H */