LIS3DH.
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Raw register accessors for the LIS3DH.
Each function reads or writes a single 8-bit register. Higher-level helpers
in LIS3DH and friends interpret the bytes as signed integers, scaled
physical quantities, or named bit-fields.
Register addresses, access modes and bit layouts are taken from LIS3DH Datasheet DocID17530 Rev 2 §7 Register mapping and §8 Registers description.
Summary
Functions
Read the contents of the act_dur register.
Read the contents of the act_ths register.
Read the contents of the click_cfg register.
Read the contents of the click_src register.
Read the contents of the click_ths register.
Read the contents of the ctrl_reg_0 register.
Read the contents of the ctrl_reg_1 register.
Read the contents of the ctrl_reg_2 register.
Read the contents of the ctrl_reg_3 register.
Read the contents of the ctrl_reg_4 register.
Read the contents of the ctrl_reg_5 register.
Read the contents of the ctrl_reg_6 register.
Read the contents of the fifo_ctrl_reg register.
Read the contents of the fifo_src_reg register.
Read the contents of the int1_cfg register.
Read the contents of the int1_duration register.
Read the contents of the int1_src register.
Read the contents of the int1_ths register.
Read the contents of the int2_cfg register.
Read the contents of the int2_duration register.
Read the contents of the int2_src register.
Read the contents of the int2_ths register.
Read the contents of the out_adc1_h register.
Read the contents of the out_adc1_l register.
Read the contents of the out_adc2_h register.
Read the contents of the out_adc2_l register.
Read the contents of the out_adc3_h register.
Read the contents of the out_adc3_l register.
Read the contents of the out_x_h register.
Read the contents of the out_x_l register.
Read the contents of the out_y_h register.
Read the contents of the out_y_l register.
Read the contents of the out_z_h register.
Read the contents of the out_z_l register.
Read the contents of the reference register.
Read the contents of the status_reg register.
Read the contents of the status_reg_aux register.
Read the contents of the temp_cfg_reg register.
Read the contents of the time_latency register.
Read the contents of the time_limit register.
Read the contents of the time_window register.
Read the contents of the who_am_i register.
Swap the contents of the act_dur register.
Swap the contents of the act_ths register.
Swap the contents of the click_cfg register.
Swap the contents of the click_ths register.
Swap the contents of the ctrl_reg_0 register.
Swap the contents of the ctrl_reg_1 register.
Swap the contents of the ctrl_reg_2 register.
Swap the contents of the ctrl_reg_3 register.
Swap the contents of the ctrl_reg_4 register.
Swap the contents of the ctrl_reg_5 register.
Swap the contents of the ctrl_reg_6 register.
Swap the contents of the fifo_ctrl_reg register.
Swap the contents of the int1_cfg register.
Swap the contents of the int1_duration register.
Swap the contents of the int1_ths register.
Swap the contents of the int2_cfg register.
Swap the contents of the int2_duration register.
Swap the contents of the int2_ths register.
Swap the contents of the reference register.
Swap the contents of the temp_cfg_reg register.
Swap the contents of the time_latency register.
Swap the contents of the time_limit register.
Swap the contents of the time_window register.
Update the contents of the act_dur register using a
transformation function.
Update the contents of the act_ths register using a
transformation function.
Update the contents of the click_cfg register using a
transformation function.
Update the contents of the click_ths register using a
transformation function.
Update the contents of the ctrl_reg_0 register using a
transformation function.
Update the contents of the ctrl_reg_1 register using a
transformation function.
Update the contents of the ctrl_reg_2 register using a
transformation function.
Update the contents of the ctrl_reg_3 register using a
transformation function.
Update the contents of the ctrl_reg_4 register using a
transformation function.
Update the contents of the ctrl_reg_5 register using a
transformation function.
Update the contents of the ctrl_reg_6 register using a
transformation function.
Update the contents of the fifo_ctrl_reg register using a
transformation function.
Update the contents of the int1_cfg register using a
transformation function.
Update the contents of the int1_duration register using a
transformation function.
Update the contents of the int1_ths register using a
transformation function.
Update the contents of the int2_cfg register using a
transformation function.
Update the contents of the int2_duration register using a
transformation function.
Update the contents of the int2_ths register using a
transformation function.
Update the contents of the reference register using a
transformation function.
Update the contents of the temp_cfg_reg register using a
transformation function.
Update the contents of the time_latency register using a
transformation function.
Update the contents of the time_limit register using a
transformation function.
Update the contents of the time_window register using a
transformation function.
Write new contents to the act_dur register.
Write new contents to the act_ths register.
Write new contents to the click_cfg register.
Write new contents to the click_ths register.
Write new contents to the ctrl_reg_0 register.
Write new contents to the ctrl_reg_1 register.
Write new contents to the ctrl_reg_2 register.
Write new contents to the ctrl_reg_3 register.
Write new contents to the ctrl_reg_4 register.
Write new contents to the ctrl_reg_5 register.
Write new contents to the ctrl_reg_6 register.
Write new contents to the fifo_ctrl_reg register.
Write new contents to the int1_cfg register.
Write new contents to the int1_duration register.
Write new contents to the int1_ths register.
Write new contents to the int2_cfg register.
Write new contents to the int2_duration register.
Write new contents to the int2_ths register.
Write new contents to the reference register.
Write new contents to the temp_cfg_reg register.
Write new contents to the time_latency register.
Write new contents to the time_limit register.
Write new contents to the time_window register.
Functions
@spec read_act_dur(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the act_dur register.
Example
iex> read_act_dur(conn)
{:ok, <<0>>}@spec read_act_ths(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the act_ths register.
Example
iex> read_act_ths(conn)
{:ok, <<0>>}@spec read_click_cfg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the click_cfg register.
Example
iex> read_click_cfg(conn)
{:ok, <<0>>}@spec read_click_src(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the click_src register.
Example
iex> read_click_src(conn)
{:ok, <<0>>}@spec read_click_ths(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the click_ths register.
Example
iex> read_click_ths(conn)
{:ok, <<0>>}@spec read_ctrl_reg_0(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_0 register.
Example
iex> read_ctrl_reg_0(conn)
{:ok, <<0>>}@spec read_ctrl_reg_1(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_1 register.
Example
iex> read_ctrl_reg_1(conn)
{:ok, <<0>>}@spec read_ctrl_reg_2(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_2 register.
Example
iex> read_ctrl_reg_2(conn)
{:ok, <<0>>}@spec read_ctrl_reg_3(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_3 register.
Example
iex> read_ctrl_reg_3(conn)
{:ok, <<0>>}@spec read_ctrl_reg_4(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_4 register.
Example
iex> read_ctrl_reg_4(conn)
{:ok, <<0>>}@spec read_ctrl_reg_5(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_5 register.
Example
iex> read_ctrl_reg_5(conn)
{:ok, <<0>>}@spec read_ctrl_reg_6(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the ctrl_reg_6 register.
Example
iex> read_ctrl_reg_6(conn)
{:ok, <<0>>}@spec read_fifo_ctrl_reg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the fifo_ctrl_reg register.
Example
iex> read_fifo_ctrl_reg(conn)
{:ok, <<0>>}@spec read_fifo_src_reg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the fifo_src_reg register.
Example
iex> read_fifo_src_reg(conn)
{:ok, <<0>>}@spec read_int1_cfg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int1_cfg register.
Example
iex> read_int1_cfg(conn)
{:ok, <<0>>}@spec read_int1_duration(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int1_duration register.
Example
iex> read_int1_duration(conn)
{:ok, <<0>>}@spec read_int1_src(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int1_src register.
Example
iex> read_int1_src(conn)
{:ok, <<0>>}@spec read_int1_ths(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int1_ths register.
Example
iex> read_int1_ths(conn)
{:ok, <<0>>}@spec read_int2_cfg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int2_cfg register.
Example
iex> read_int2_cfg(conn)
{:ok, <<0>>}@spec read_int2_duration(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int2_duration register.
Example
iex> read_int2_duration(conn)
{:ok, <<0>>}@spec read_int2_src(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int2_src register.
Example
iex> read_int2_src(conn)
{:ok, <<0>>}@spec read_int2_ths(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the int2_ths register.
Example
iex> read_int2_ths(conn)
{:ok, <<0>>}@spec read_out_adc1_h(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_adc1_h register.
Example
iex> read_out_adc1_h(conn)
{:ok, <<0>>}@spec read_out_adc1_l(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_adc1_l register.
Example
iex> read_out_adc1_l(conn)
{:ok, <<0>>}@spec read_out_adc2_h(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_adc2_h register.
Example
iex> read_out_adc2_h(conn)
{:ok, <<0>>}@spec read_out_adc2_l(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_adc2_l register.
Example
iex> read_out_adc2_l(conn)
{:ok, <<0>>}@spec read_out_adc3_h(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_adc3_h register.
Example
iex> read_out_adc3_h(conn)
{:ok, <<0>>}@spec read_out_adc3_l(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_adc3_l register.
Example
iex> read_out_adc3_l(conn)
{:ok, <<0>>}@spec read_out_x_h(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_x_h register.
Example
iex> read_out_x_h(conn)
{:ok, <<0>>}@spec read_out_x_l(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_x_l register.
Example
iex> read_out_x_l(conn)
{:ok, <<0>>}@spec read_out_y_h(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_y_h register.
Example
iex> read_out_y_h(conn)
{:ok, <<0>>}@spec read_out_y_l(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_y_l register.
Example
iex> read_out_y_l(conn)
{:ok, <<0>>}@spec read_out_z_h(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_z_h register.
Example
iex> read_out_z_h(conn)
{:ok, <<0>>}@spec read_out_z_l(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the out_z_l register.
Example
iex> read_out_z_l(conn)
{:ok, <<0>>}@spec read_reference(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the reference register.
Example
iex> read_reference(conn)
{:ok, <<0>>}@spec read_status_reg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the status_reg register.
Example
iex> read_status_reg(conn)
{:ok, <<0>>}@spec read_status_reg_aux(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the status_reg_aux register.
Example
iex> read_status_reg_aux(conn)
{:ok, <<0>>}@spec read_temp_cfg_reg(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the temp_cfg_reg register.
Example
iex> read_temp_cfg_reg(conn)
{:ok, <<0>>}@spec read_time_latency(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the time_latency register.
Example
iex> read_time_latency(conn)
{:ok, <<0>>}@spec read_time_limit(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the time_limit register.
Example
iex> read_time_limit(conn)
{:ok, <<0>>}@spec read_time_window(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the time_window register.
Example
iex> read_time_window(conn)
{:ok, <<0>>}@spec read_who_am_i(Wafer.Conn.t()) :: {:ok, binary()} | {:error, reason :: any()}
Read the contents of the who_am_i register.
Example
iex> read_who_am_i(conn)
{:ok, <<0>>}@spec swap_act_dur(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the act_dur register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_act_dur(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_act_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the act_ths register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_act_ths(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_click_cfg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the click_cfg register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_click_cfg(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_click_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the click_ths register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_click_ths(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_0(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_0 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_0(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_1(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_1 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_1(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_2(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_2 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_2(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_3(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_3 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_3(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_4(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_4 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_4(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_5(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_5 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_5(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_ctrl_reg_6(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the ctrl_reg_6 register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_ctrl_reg_6(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_fifo_ctrl_reg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the fifo_ctrl_reg register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_fifo_ctrl_reg(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_int1_cfg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the int1_cfg register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_int1_cfg(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_int1_duration(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the int1_duration register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_int1_duration(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_int1_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the int1_ths register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_int1_ths(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_int2_cfg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the int2_cfg register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_int2_cfg(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_int2_duration(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the int2_duration register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_int2_duration(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_int2_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the int2_ths register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_int2_ths(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_reference(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the reference register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_reference(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_temp_cfg_reg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the temp_cfg_reg register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_temp_cfg_reg(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_time_latency(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the time_latency register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_time_latency(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_time_limit(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the time_limit register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_time_limit(conn, <<0>>)
{:ok, <<0>>, _conn}@spec swap_time_window(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Swap the contents of the time_window register.
Reads the contents of the register, then replaces it, returning the previous contents. Some drivers may implement this atomically.
Example
iex> swap_time_window(conn, <<0>>)
{:ok, <<0>>, _conn}@spec update_act_dur(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the act_dur register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_act_dur(conn, transform)
{:ok, _conn}@spec update_act_ths(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the act_ths register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_act_ths(conn, transform)
{:ok, _conn}@spec update_click_cfg(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the click_cfg register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_click_cfg(conn, transform)
{:ok, _conn}@spec update_click_ths(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the click_ths register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_click_ths(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_0(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_0 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_0(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_1(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_1 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_1(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_2(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_2 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_2(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_3(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_3 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_3(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_4(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_4 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_4(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_5(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_5 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_5(conn, transform)
{:ok, _conn}@spec update_ctrl_reg_6(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the ctrl_reg_6 register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_ctrl_reg_6(conn, transform)
{:ok, _conn}@spec update_fifo_ctrl_reg(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the fifo_ctrl_reg register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_fifo_ctrl_reg(conn, transform)
{:ok, _conn}@spec update_int1_cfg(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the int1_cfg register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_int1_cfg(conn, transform)
{:ok, _conn}@spec update_int1_duration(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the int1_duration register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_int1_duration(conn, transform)
{:ok, _conn}@spec update_int1_ths(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the int1_ths register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_int1_ths(conn, transform)
{:ok, _conn}@spec update_int2_cfg(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the int2_cfg register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_int2_cfg(conn, transform)
{:ok, _conn}@spec update_int2_duration(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the int2_duration register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_int2_duration(conn, transform)
{:ok, _conn}@spec update_int2_ths(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the int2_ths register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_int2_ths(conn, transform)
{:ok, _conn}@spec update_reference(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the reference register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_reference(conn, transform)
{:ok, _conn}@spec update_temp_cfg_reg(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the temp_cfg_reg register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_temp_cfg_reg(conn, transform)
{:ok, _conn}@spec update_time_latency(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the time_latency register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_time_latency(conn, transform)
{:ok, _conn}@spec update_time_limit(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the time_limit register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_time_limit(conn, transform)
{:ok, _conn}@spec update_time_window(Wafer.Conn.t(), (<<_::_*8>> -> <<_::_*8>>)) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Update the contents of the time_window register using a
transformation function.
Example
iex> transform = fn <<data::size(8)>> -> <<(data * 2)::size(8)>> end
...> update_time_window(conn, transform)
{:ok, _conn}@spec write_act_dur(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the act_dur register.
Example
iex> write_act_dur(conn, <<0>>)
{:ok, _conn}@spec write_act_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the act_ths register.
Example
iex> write_act_ths(conn, <<0>>)
{:ok, _conn}@spec write_click_cfg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the click_cfg register.
Example
iex> write_click_cfg(conn, <<0>>)
{:ok, _conn}@spec write_click_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the click_ths register.
Example
iex> write_click_ths(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_0(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_0 register.
Example
iex> write_ctrl_reg_0(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_1(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_1 register.
Example
iex> write_ctrl_reg_1(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_2(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_2 register.
Example
iex> write_ctrl_reg_2(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_3(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_3 register.
Example
iex> write_ctrl_reg_3(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_4(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_4 register.
Example
iex> write_ctrl_reg_4(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_5(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_5 register.
Example
iex> write_ctrl_reg_5(conn, <<0>>)
{:ok, _conn}@spec write_ctrl_reg_6(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the ctrl_reg_6 register.
Example
iex> write_ctrl_reg_6(conn, <<0>>)
{:ok, _conn}@spec write_fifo_ctrl_reg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the fifo_ctrl_reg register.
Example
iex> write_fifo_ctrl_reg(conn, <<0>>)
{:ok, _conn}@spec write_int1_cfg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the int1_cfg register.
Example
iex> write_int1_cfg(conn, <<0>>)
{:ok, _conn}@spec write_int1_duration(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the int1_duration register.
Example
iex> write_int1_duration(conn, <<0>>)
{:ok, _conn}@spec write_int1_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the int1_ths register.
Example
iex> write_int1_ths(conn, <<0>>)
{:ok, _conn}@spec write_int2_cfg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the int2_cfg register.
Example
iex> write_int2_cfg(conn, <<0>>)
{:ok, _conn}@spec write_int2_duration(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the int2_duration register.
Example
iex> write_int2_duration(conn, <<0>>)
{:ok, _conn}@spec write_int2_ths(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the int2_ths register.
Example
iex> write_int2_ths(conn, <<0>>)
{:ok, _conn}@spec write_reference(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the reference register.
Example
iex> write_reference(conn, <<0>>)
{:ok, _conn}@spec write_temp_cfg_reg(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the temp_cfg_reg register.
Example
iex> write_temp_cfg_reg(conn, <<0>>)
{:ok, _conn}@spec write_time_latency(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the time_latency register.
Example
iex> write_time_latency(conn, <<0>>)
{:ok, _conn}@spec write_time_limit(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the time_limit register.
Example
iex> write_time_limit(conn, <<0>>)
{:ok, _conn}@spec write_time_window(Wafer.Conn.t(), data :: binary()) :: {:ok, Wafer.Conn.t()} | {:error, reason :: any()}
Write new contents to the time_window register.
Example
iex> write_time_window(conn, <<0>>)
{:ok, _conn}