portapack-mayhem/firmware/common/cpld_xilinx.cpp

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/*
* Copyright (C) 2016 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.
*/
#include "ch.h"
#include "cpld_xilinx.hpp"
namespace cpld {
namespace xilinx {
void XC2C64A::write_sram(const verify_blocks_t& blocks) {
tap.set_repeat(0);
tap.set_end_ir(state_t::run_test_idle);
tap.set_end_dr(state_t::run_test_idle);
reset();
enable();
shift_ir(instruction_t::ISC_WRITE);
for (const auto& block : blocks) {
tap.state(state_t::shift_dr);
tap.shift({block.data.data(), block_length}, false);
tap.shift({&block.id, block_id_length}, true);
tap.state(state_t::run_test_idle);
}
disable();
bypass();
tap.state(state_t::test_logic_reset);
}
bool XC2C64A::verify_sram(const verify_blocks_t& blocks) {
prepare_read_sram();
const jtag::tap::bits_t empty_row{block_length};
auto error = false;
for (const auto& block : blocks) {
tap.shift({&block.id, block_id_length}, true);
tap.state(state_t::run_test_idle);
tap.state(state_t::shift_dr);
error |= tap.shift(empty_row, {block.data.data(), block_length}, {block.mask.data(), block_length}, false, nullptr);
}
finalize_read_sram(blocks[0].id);
return !error;
}
void XC2C64A::prepare_read_sram() {
tap.set_repeat(0);
tap.set_end_ir(state_t::run_test_idle);
tap.set_end_dr(state_t::run_test_idle);
reset();
enable();
shift_ir(instruction_t::ISC_SRAM_READ);
// Prime the operation with a read of an empty row.
const jtag::tap::bits_t empty_row{block_length};
tap.state(state_t::shift_dr);
tap.shift(empty_row, false);
}
std::array<bool, 274> XC2C64A::read_block_sram(verify_block_t block) {
tap.shift({&block.id, block_id_length}, true);
tap.state(state_t::run_test_idle);
tap.state(state_t::shift_dr);
const jtag::tap::bits_t empty_row{block_length};
std::vector<bool> from_device;
tap.shift(empty_row, {block.data.data(), block_length}, {block.mask.data(), block_length}, false, &from_device);
std::array<bool, block_length> ret;
std::copy_n(std::make_move_iterator(from_device.begin()), block_length, ret.begin());
return ret;
}
void XC2C64A::finalize_read_sram(block_id_t id) {
tap.shift({&id, block_id_length}, true);
tap.state(state_t::run_test_idle);
tap.set_end_dr(state_t::run_test_idle);
disable();
bypass();
tap.state(state_t::test_logic_reset);
}
bool XC2C64A::verify_eeprom(const verify_blocks_t& blocks) {
tap.set_repeat(0);
tap.set_end_ir(state_t::run_test_idle);
tap.set_end_dr(state_t::run_test_idle);
reset();
bypass();
enable();
shift_ir(instruction_t::ISC_READ);
const jtag::tap::bits_t empty_row{block_length};
auto error = false;
for (const auto& block : blocks) {
tap.set_end_dr(state_t::pause_dr);
tap.shift_dr({&block.id, block_id_length});
tap.set_end_ir(state_t::run_test_idle);
tap.wait(state_t::pause_dr, state_t::pause_dr, 20);
tap.set_end_ir(state_t::run_test_idle);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 100);
error |= tap.shift_dr(empty_row, {block.data.data(), block_length}, {block.mask.data(), block_length});
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 100);
}
disable();
bypass();
tap.state(state_t::test_logic_reset);
return !error;
}
void XC2C64A::init_from_eeprom() {
tap.set_repeat(0);
tap.set_end_ir(state_t::run_test_idle);
tap.set_end_dr(state_t::run_test_idle);
reset();
enable();
discharge();
init();
disable();
bypass();
tap.state(state_t::test_logic_reset);
}
void XC2C64A::prepare_read_eeprom() {
tap.set_repeat(0);
tap.set_end_ir(state_t::run_test_idle);
tap.set_end_dr(state_t::run_test_idle);
reset();
bypass();
enable();
shift_ir(instruction_t::ISC_READ);
}
std::array<bool, 274> XC2C64A::read_block_eeprom(block_id_t id) {
const jtag::tap::bits_t empty_row{block_length};
tap.set_end_dr(state_t::pause_dr);
tap.shift_dr({&id, block_id_length});
tap.set_end_ir(state_t::run_test_idle);
tap.wait(state_t::pause_dr, state_t::pause_dr, 20);
tap.set_end_ir(state_t::run_test_idle);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 100);
std::vector<bool> from_device = tap.shift_dr_read(empty_row);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 100);
std::array<bool, block_length> ret;
std::copy_n(std::make_move_iterator(from_device.begin()), block_length, ret.begin());
return ret;
}
void XC2C64A::finalize_read_eeprom() {
disable();
bypass();
tap.state(state_t::test_logic_reset);
}
bool XC2C64A::shift_ir(const instruction_t instruction) {
const ir_t ir_buffer = toUType(instruction);
const jtag::tap::bits_t bits{&ir_buffer, ir_length};
return tap.shift_ir(bits);
}
void XC2C64A::reset() {
tap.state(state_t::test_logic_reset);
tap.state(state_t::run_test_idle);
}
void XC2C64A::enable() {
shift_ir(instruction_t::ISC_ENABLE);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 800);
}
void XC2C64A::enable_otf() {
shift_ir(instruction_t::ISC_ENABLE_OTF);
}
void XC2C64A::discharge() {
shift_ir(instruction_t::ISC_INIT);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 20);
}
void XC2C64A::init() {
tap.set_end_ir(state_t::update_ir);
shift_ir(instruction_t::ISC_INIT);
tap.set_end_ir(state_t::run_test_idle);
tap.state(state_t::capture_dr);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 800);
}
void XC2C64A::disable() {
shift_ir(instruction_t::ISC_DISABLE);
tap.wait(state_t::run_test_idle, state_t::run_test_idle, 100);
}
bool XC2C64A::bypass() {
return shift_ir(instruction_t::BYPASS);
}
} /* namespace xilinx */
} /* namespace cpld */