ardupilot/libraries/SITL/SIM_Invensense_v3.cpp

#include "SIM_Invensense_v3.h"

#include <stdio.h>

void SITL::InvensenseV3::update(const class Aircraft &aircraft)
{
    assert_storage_size<FIFOData, 16> _assert_fifo_size;
    (void)_assert_fifo_size;

    const SIM *sitl = AP::sitl();
    const int16_t xAccel = sitl->state.xAccel / accel_scale();
    const int16_t yAccel = sitl->state.yAccel / accel_scale();
    const int16_t zAccel = sitl->state.zAccel / accel_scale();

    const int16_t p = radians(sitl->state.rollRate) / gyro_scale();
    const int16_t q = radians(sitl->state.pitchRate) / gyro_scale();
    const int16_t r = radians(sitl->state.yawRate) / gyro_scale();

    struct FIFOData new_data  {
        0x68,
        { xAccel, yAccel, zAccel },
        { p, q, r },
        21,  // temperature
        AP_HAL::millis16()   // timestamp
    };

    for (uint8_t i=0; i<2; i++) {
        if (!write_to_fifo(InvensenseV3DevReg::FIFO_DATA, (uint8_t*)&new_data, sizeof(new_data))) {
            return;
        }
    }
    update_sample_count();
}

// assert_register_values ensures register states when we go to do
// various operations (e.g. reading from FIFO)
void SITL::InvensenseV3::assert_register_values()
{
    static const struct expected_register_values {
        uint8_t reg;
        uint8_t value;
    } expected[] {
        { InvensenseV3DevReg::FIFO_CONFIG, 0x80 },
        { InvensenseV3DevReg::FIFO_CONFIG1, 0x07 },
        { InvensenseV3DevReg::INTF_CONFIG0, 0xC0 },
        { InvensenseV3DevReg::SIGNAL_PATH_RESET, 2 },
        { InvensenseV3DevReg::PWR_MGMT0, 0x0f },
        { InvensenseV3DevReg::GYRO_CONFIG0, 0x05 },
        { InvensenseV3DevReg::ACCEL_CONFIG0, 0x05 },
    };
    for (const auto &stuff : expected) {
        assert_register_value(stuff.reg, stuff.value);
    }
}

int SITL::InvensenseV3::rdwr(I2C::i2c_rdwr_ioctl_data *&data)
{
    const uint8_t addr = data->msgs[0].buf[0];

    // see if it is a fifo...
    if (fifoname[addr] != nullptr) {
        return rdwr_fifo(data);
    }
    // see if it is a block...
    if (blockname[addr] != nullptr) {
        return rdwr_block(data);
    }

    return I2CRegisters_8Bit::rdwr(data);
}

int SITL::InvensenseV3::rdwr_fifo(I2C::i2c_rdwr_ioctl_data *&data)
{
    const uint8_t addr = data->msgs[0].buf[0];

    assert_register_values();

    // check for block/FIFO read/write bits and pieces
    if (data->nmsgs == 2) {
        if (data->msgs[0].flags != 0) {
            AP_HAL::panic("Unexpected flags");
        }
        if (data->msgs[1].flags != I2C_M_RD) {
            AP_HAL::panic("Unexpected flags");
        }

        const uint8_t len = data->msgs[1].len;
        if (len > value_lengths[addr]) {
            if (value_lengths[addr] != 0) {
                // we expect reads and writes into the fifo to be the same size
                AP_HAL::panic("Read of unexpected size");
            }
            return -1;
        }
        memcpy(data->msgs[1].buf, values[addr], len);
        memmove(values[addr], values[addr]+len, value_lengths[addr]-len);
        value_lengths[addr] -= len;
        if (addr == InvensenseV3DevReg::FIFO_DATA) {    // bit of a hack... callback?
            update_sample_count();
        }
        return 0;
    }
    return -1;
}

void SITL::InvensenseV3::add_fifo(const char *name, uint8_t reg, I2CRegisters::RegMode mode)
{
    // ::fprintf(stderr, "Adding fifo %u (0x%02x) (%s)\n", reg, reg, name);
    fifoname[reg] = name;
    if (mode == I2CRegisters::RegMode::RDONLY ||
        mode == I2CRegisters::RegMode::RDWR) {
        readable_fifos.set((uint8_t)reg);
    }
    if (mode == I2CRegisters::RegMode::WRONLY ||
        mode == I2CRegisters::RegMode::RDWR) {
        writable_fifos.set((uint8_t)reg);
    }

    values[reg] = (char*)malloc(fifo_len); // allocate the fifo...
    if (values[reg] == nullptr) {
        AP_HAL::panic("Failed to allocate FIFO...");
    }
}

void SITL::InvensenseV3::update_sample_count()
{
    if (value_lengths[InvensenseV3DevReg::FIFO_DATA] % sizeof(FIFOData)) {
        AP_HAL::panic("fifo data not multiple of sample size");
    }
    uint16_t samplecount = value_lengths[InvensenseV3DevReg::FIFO_DATA]/sizeof(FIFOData);
    set_block(InvensenseV3DevReg::FIFO_COUNTH, (uint8_t*)&samplecount, 2);
}

bool SITL::InvensenseV3::write_to_fifo(uint8_t fifo, uint8_t *value, uint8_t valuelen)
{
    if (fifoname[fifo] == nullptr) {
        AP_HAL::panic("Setting un-named fifo %u", fifo);
    }
    // ::fprintf(stderr, "Setting %u (0x%02x) (%s) to 0x%02x (%c)\n", (unsigned)reg, (unsigned)reg, regname[reg], (unsigned)value, value);
    if (valuelen == 0) {
        AP_HAL::panic("Zero-length values not permitted by spec");
    }
    if (values[fifo] == nullptr) {
        AP_HAL::panic("Write to unallocated FIFO");
    }
    if (value_lengths[fifo] + valuelen > fifo_len) {
        // ::fprintf(stderr, "dropped\n");  // this happens a lot at startup
        return false;  // just drop it
    }
    memcpy(&(values[fifo][value_lengths[fifo]]), value, valuelen);
    value_lengths[fifo] += valuelen;
    if (fifo == InvensenseV3DevReg::FIFO_DATA) {    // bit of a hack... callback?
        update_sample_count();
    }
    return true;
}


void SITL::InvensenseV3::add_block(const char *name, uint8_t addr, uint8_t len, I2CRegisters::RegMode mode)
{
    // ::fprintf(stderr, "Adding block %u (0x%02x) (%s)\n", addr, addr, name);
    blockname[addr] = name;
    block_values[addr] = (char*)malloc(len);
    block_value_lengths[addr] = len;
    if (block_values[addr] == nullptr) {
        AP_HAL::panic("Allocation failed for block (len=%u)", len);
    }
    if (mode == I2CRegisters::RegMode::RDONLY ||
        mode == I2CRegisters::RegMode::RDWR) {
        readable_blocks.set((uint8_t)addr);
    }
    if (mode == I2CRegisters::RegMode::WRONLY ||
        mode == I2CRegisters::RegMode::RDWR) {
        writable_blocks.set((uint8_t)addr);
    }
}

void SITL::InvensenseV3::set_block(uint8_t addr, uint8_t *value, uint8_t valuelen)
{
    if (blockname[addr] == nullptr) {
        AP_HAL::panic("Setting un-named block %u", addr);
    }
    if (valuelen != block_value_lengths[addr]) {
        AP_HAL::panic("Invalid block write got=%u want=%u", valuelen, block_value_lengths[addr]);
    }
    memcpy(block_values[addr], value, valuelen);
}

int SITL::InvensenseV3::rdwr_block(I2C::i2c_rdwr_ioctl_data *&data)
{
    const uint8_t addr = data->msgs[0].buf[0];

    // it is a block.
    if (data->nmsgs == 2) {
        // data read request
        if (data->msgs[0].flags != 0) {
            AP_HAL::panic("Unexpected flags");
        }
        if (data->msgs[1].flags != I2C_M_RD) {
            AP_HAL::panic("Unexpected flags");
        }

        if (data->msgs[1].len != block_value_lengths[addr]) {
            AP_HAL::panic("Block read length not equal to block length (got=%u want=%u)", data->msgs[1].len, block_value_lengths[addr]);
        }
        memcpy(&data->msgs[1].buf[0], block_values[addr], data->msgs[1].len);
        return 0;
    }

    if (data->nmsgs == 1) {
        // data write request
        if (data->msgs[0].flags != 0) {
            AP_HAL::panic("Unexpected flags");
        }
        AP_HAL::panic("block writes not implemented");
    }

    return -1;
}
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`#include "SIM_Invensense_v3.h"`

			`#include <stdio.h>`

			`void SITL::InvensenseV3::update(const class Aircraft &aircraft)`
			`{`
			`assert_storage_size<FIFOData, 16> _assert_fifo_size;`
			`(void)_assert_fifo_size;`

SITL: change class name from SITL::SITL to SITL::SIM 2021-07-30 07:17:35 -03:00			`const SIM *sitl = AP::sitl();`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`const int16_t xAccel = sitl->state.xAccel / accel_scale();`
			`const int16_t yAccel = sitl->state.yAccel / accel_scale();`
			`const int16_t zAccel = sitl->state.zAccel / accel_scale();`

			`const int16_t p = radians(sitl->state.rollRate) / gyro_scale();`
			`const int16_t q = radians(sitl->state.pitchRate) / gyro_scale();`
			`const int16_t r = radians(sitl->state.yawRate) / gyro_scale();`

			`struct FIFOData new_data {`
			`0x68,`
			`{ xAccel, yAccel, zAccel },`
			`{ p, q, r },`
			`21, // temperature`
			`AP_HAL::millis16() // timestamp`
			`};`

			`for (uint8_t i=0; i<2; i++) {`
			`if (!write_to_fifo(InvensenseV3DevReg::FIFO_DATA, (uint8_t*)&new_data, sizeof(new_data))) {`
			`return;`
			`}`
			`}`
			`update_sample_count();`
			`}`

			`// assert_register_values ensures register states when we go to do`
			`// various operations (e.g. reading from FIFO)`
			`void SITL::InvensenseV3::assert_register_values()`
			`{`
			`static const struct expected_register_values {`
			`uint8_t reg;`
			`uint8_t value;`
			`} expected[] {`
			`{ InvensenseV3DevReg::FIFO_CONFIG, 0x80 },`
			`{ InvensenseV3DevReg::FIFO_CONFIG1, 0x07 },`
			`{ InvensenseV3DevReg::INTF_CONFIG0, 0xC0 },`
			`{ InvensenseV3DevReg::SIGNAL_PATH_RESET, 2 },`
			`{ InvensenseV3DevReg::PWR_MGMT0, 0x0f },`
			`{ InvensenseV3DevReg::GYRO_CONFIG0, 0x05 },`
			`{ InvensenseV3DevReg::ACCEL_CONFIG0, 0x05 },`
			`};`
			`for (const auto &stuff : expected) {`
			`assert_register_value(stuff.reg, stuff.value);`
			`}`
			`}`

			`int SITL::InvensenseV3::rdwr(I2C::i2c_rdwr_ioctl_data *&data)`
			`{`
			`const uint8_t addr = data->msgs[0].buf[0];`

			`// see if it is a fifo...`
			`if (fifoname[addr] != nullptr) {`
			`return rdwr_fifo(data);`
			`}`
			`// see if it is a block...`
			`if (blockname[addr] != nullptr) {`
			`return rdwr_block(data);`
			`}`

			`return I2CRegisters_8Bit::rdwr(data);`
			`}`

			`int SITL::InvensenseV3::rdwr_fifo(I2C::i2c_rdwr_ioctl_data *&data)`
			`{`
			`const uint8_t addr = data->msgs[0].buf[0];`

			`assert_register_values();`

			`// check for block/FIFO read/write bits and pieces`
			`if (data->nmsgs == 2) {`
			`if (data->msgs[0].flags != 0) {`
			`AP_HAL::panic("Unexpected flags");`
			`}`
			`if (data->msgs[1].flags != I2C_M_RD) {`
			`AP_HAL::panic("Unexpected flags");`
			`}`

			`const uint8_t len = data->msgs[1].len;`
			`if (len > value_lengths[addr]) {`
			`if (value_lengths[addr] != 0) {`
			`// we expect reads and writes into the fifo to be the same size`
			`AP_HAL::panic("Read of unexpected size");`
			`}`
			`return -1;`
			`}`
			`memcpy(data->msgs[1].buf, values[addr], len);`
			`memmove(values[addr], values[addr]+len, value_lengths[addr]-len);`
			`value_lengths[addr] -= len;`
			`if (addr == InvensenseV3DevReg::FIFO_DATA) { // bit of a hack... callback?`
			`update_sample_count();`
			`}`
			`return 0;`
			`}`
			`return -1;`
			`}`

SITL: use enumeration in place of O_RDWR for I2C register defs 2021-10-11 02:04:21 -03:00			`void SITL::InvensenseV3::add_fifo(const char *name, uint8_t reg, I2CRegisters::RegMode mode)`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`{`
			`// ::fprintf(stderr, "Adding fifo %u (0x%02x) (%s)\n", reg, reg, name);`
			`fifoname[reg] = name;`
SITL: use enumeration in place of O_RDWR for I2C register defs 2021-10-11 02:04:21 -03:00			`if (mode == I2CRegisters::RegMode::RDONLY \|\|`
			`mode == I2CRegisters::RegMode::RDWR) {`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`readable_fifos.set((uint8_t)reg);`
			`}`
SITL: use enumeration in place of O_RDWR for I2C register defs 2021-10-11 02:04:21 -03:00			`if (mode == I2CRegisters::RegMode::WRONLY \|\|`
			`mode == I2CRegisters::RegMode::RDWR) {`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`writable_fifos.set((uint8_t)reg);`
			`}`

			`values[reg] = (char*)malloc(fifo_len); // allocate the fifo...`
			`if (values[reg] == nullptr) {`
			`AP_HAL::panic("Failed to allocate FIFO...");`
			`}`
			`}`

			`void SITL::InvensenseV3::update_sample_count()`
			`{`
			`if (value_lengths[InvensenseV3DevReg::FIFO_DATA] % sizeof(FIFOData)) {`
			`AP_HAL::panic("fifo data not multiple of sample size");`
			`}`
			`uint16_t samplecount = value_lengths[InvensenseV3DevReg::FIFO_DATA]/sizeof(FIFOData);`
			`set_block(InvensenseV3DevReg::FIFO_COUNTH, (uint8_t*)&samplecount, 2);`
			`}`

			`bool SITL::InvensenseV3::write_to_fifo(uint8_t fifo, uint8_t *value, uint8_t valuelen)`
			`{`
			`if (fifoname[fifo] == nullptr) {`
			`AP_HAL::panic("Setting un-named fifo %u", fifo);`
			`}`
			`// ::fprintf(stderr, "Setting %u (0x%02x) (%s) to 0x%02x (%c)\n", (unsigned)reg, (unsigned)reg, regname[reg], (unsigned)value, value);`
			`if (valuelen == 0) {`
			`AP_HAL::panic("Zero-length values not permitted by spec");`
			`}`
			`if (values[fifo] == nullptr) {`
			`AP_HAL::panic("Write to unallocated FIFO");`
			`}`
			`if (value_lengths[fifo] + valuelen > fifo_len) {`
			`// ::fprintf(stderr, "dropped\n"); // this happens a lot at startup`
			`return false; // just drop it`
			`}`
			`memcpy(&(values[fifo][value_lengths[fifo]]), value, valuelen);`
			`value_lengths[fifo] += valuelen;`
			`if (fifo == InvensenseV3DevReg::FIFO_DATA) { // bit of a hack... callback?`
			`update_sample_count();`
			`}`
			`return true;`
			`}`



SITL: use enumeration in place of O_RDWR for I2C register defs 2021-10-11 02:04:21 -03:00			`void SITL::InvensenseV3::add_block(const char *name, uint8_t addr, uint8_t len, I2CRegisters::RegMode mode)`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`{`
			`// ::fprintf(stderr, "Adding block %u (0x%02x) (%s)\n", addr, addr, name);`
			`blockname[addr] = name;`
			`block_values[addr] = (char*)malloc(len);`
			`block_value_lengths[addr] = len;`
			`if (block_values[addr] == nullptr) {`
			`AP_HAL::panic("Allocation failed for block (len=%u)", len);`
			`}`
SITL: use enumeration in place of O_RDWR for I2C register defs 2021-10-11 02:04:21 -03:00			`if (mode == I2CRegisters::RegMode::RDONLY \|\|`
			`mode == I2CRegisters::RegMode::RDWR) {`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`readable_blocks.set((uint8_t)addr);`
			`}`
SITL: use enumeration in place of O_RDWR for I2C register defs 2021-10-11 02:04:21 -03:00			`if (mode == I2CRegisters::RegMode::WRONLY \|\|`
			`mode == I2CRegisters::RegMode::RDWR) {`
SITL: add simulator for ICM40609 2021-01-10 20:10:01 -04:00			`writable_blocks.set((uint8_t)addr);`
			`}`
			`}`

			`void SITL::InvensenseV3::set_block(uint8_t addr, uint8_t *value, uint8_t valuelen)`
			`{`
			`if (blockname[addr] == nullptr) {`
			`AP_HAL::panic("Setting un-named block %u", addr);`
			`}`
			`if (valuelen != block_value_lengths[addr]) {`
			`AP_HAL::panic("Invalid block write got=%u want=%u", valuelen, block_value_lengths[addr]);`
			`}`
			`memcpy(block_values[addr], value, valuelen);`
			`}`

			`int SITL::InvensenseV3::rdwr_block(I2C::i2c_rdwr_ioctl_data *&data)`
			`{`
			`const uint8_t addr = data->msgs[0].buf[0];`

			`// it is a block.`
			`if (data->nmsgs == 2) {`
			`// data read request`
			`if (data->msgs[0].flags != 0) {`
			`AP_HAL::panic("Unexpected flags");`
			`}`
			`if (data->msgs[1].flags != I2C_M_RD) {`
			`AP_HAL::panic("Unexpected flags");`
			`}`

			`if (data->msgs[1].len != block_value_lengths[addr]) {`
			`AP_HAL::panic("Block read length not equal to block length (got=%u want=%u)", data->msgs[1].len, block_value_lengths[addr]);`
			`}`
			`memcpy(&data->msgs[1].buf[0], block_values[addr], data->msgs[1].len);`
			`return 0;`
			`}`

			`if (data->nmsgs == 1) {`
			`// data write request`
			`if (data->msgs[0].flags != 0) {`
			`AP_HAL::panic("Unexpected flags");`
			`}`
			`AP_HAL::panic("block writes not implemented");`
			`}`

			`return -1;`
			`}`