klipper-dgus/klippy/stepcompress.c

848 lines
29 KiB
C

// Stepper pulse schedule compression
//
// Copyright (C) 2016,2017 Kevin O'Connor <kevin@koconnor.net>
//
// This file may be distributed under the terms of the GNU GPLv3 license.
//
// The goal of this code is to take a series of scheduled stepper
// pulse times and compress them into a handful of commands that can
// be efficiently transmitted and executed on a microcontroller (mcu).
// The mcu accepts step pulse commands that take interval, count, and
// add parameters such that 'count' pulses occur, with each step event
// calculating the next step event time using:
// next_wake_time = last_wake_time + interval; interval += add
// This code is writtin in C (instead of python) for processing
// efficiency - the repetitive integer math is vastly faster in C.
#include <math.h> // sqrt
#include <stddef.h> // offsetof
#include <stdint.h> // uint32_t
#include <stdio.h> // fprintf
#include <stdlib.h> // malloc
#include <string.h> // memset
#include "pyhelper.h" // errorf
#include "serialqueue.h" // struct queue_message
#define CHECK_LINES 1
#define QUEUE_START_SIZE 1024
struct stepcompress {
// Buffer management
uint32_t *queue, *queue_end, *queue_pos, *queue_next;
// Internal tracking
uint32_t max_error;
double mcu_time_offset, mcu_freq;
// Message generation
uint64_t last_step_clock, homing_clock;
struct list_head msg_queue;
uint32_t queue_step_msgid, set_next_step_dir_msgid, oid;
int sdir, invert_sdir;
};
/****************************************************************
* Step compression
****************************************************************/
#define DIV_UP(n,d) (((n) + (d) - 1) / (d))
static inline int32_t
idiv_up(int32_t n, int32_t d)
{
return (n>=0) ? DIV_UP(n,d) : (n/d);
}
static inline int32_t
idiv_down(int32_t n, int32_t d)
{
return (n>=0) ? (n/d) : (n - d + 1) / d;
}
struct points {
int32_t minp, maxp;
};
// Given a requested step time, return the minimum and maximum
// acceptable times
static inline struct points
minmax_point(struct stepcompress *sc, uint32_t *pos)
{
uint32_t lsc = sc->last_step_clock, point = *pos - lsc;
uint32_t prevpoint = pos > sc->queue_pos ? *(pos-1) - lsc : 0;
uint32_t max_error = (point - prevpoint) / 2;
if (max_error > sc->max_error)
max_error = sc->max_error;
return (struct points){ point - max_error, point };
}
// The maximum add delta between two valid quadratic sequences of the
// form "add*count*(count-1)/2 + interval*count" is "(6 + 4*sqrt(2)) *
// maxerror / (count*count)". The "6 + 4*sqrt(2)" is 11.65685, but
// using 11 works well in practice.
#define QUADRATIC_DEV 11
struct step_move {
uint32_t interval;
uint16_t count;
int16_t add;
};
// Find a 'step_move' that covers a series of step times
static struct step_move
compress_bisect_add(struct stepcompress *sc)
{
uint32_t *qlast = sc->queue_next;
if (qlast > sc->queue_pos + 65535)
qlast = sc->queue_pos + 65535;
struct points point = minmax_point(sc, sc->queue_pos);
int32_t outer_mininterval = point.minp, outer_maxinterval = point.maxp;
int32_t add = 0, minadd = -0x8000, maxadd = 0x7fff;
int32_t bestinterval = 0, bestcount = 1, bestadd = 1, bestreach = INT32_MIN;
int32_t zerointerval = 0, zerocount = 0;
for (;;) {
// Find longest valid sequence with the given 'add'
struct points nextpoint;
int32_t nextmininterval = outer_mininterval;
int32_t nextmaxinterval = outer_maxinterval, interval = nextmaxinterval;
int32_t nextcount = 1;
for (;;) {
nextcount++;
if (&sc->queue_pos[nextcount-1] >= qlast) {
int32_t count = nextcount - 1;
return (struct step_move){ interval, count, add };
}
nextpoint = minmax_point(sc, sc->queue_pos + nextcount - 1);
int32_t nextaddfactor = nextcount*(nextcount-1)/2;
int32_t c = add*nextaddfactor;
if (nextmininterval*nextcount < nextpoint.minp - c)
nextmininterval = DIV_UP(nextpoint.minp - c, nextcount);
if (nextmaxinterval*nextcount > nextpoint.maxp - c)
nextmaxinterval = (nextpoint.maxp - c) / nextcount;
if (nextmininterval > nextmaxinterval)
break;
interval = nextmaxinterval;
}
// Check if this is the best sequence found so far
int32_t count = nextcount - 1, addfactor = count*(count-1)/2;
int32_t reach = add*addfactor + interval*count;
if (reach > bestreach
|| (reach == bestreach && interval > bestinterval)) {
bestinterval = interval;
bestcount = count;
bestadd = add;
bestreach = reach;
if (!add) {
zerointerval = interval;
zerocount = count;
}
if (count > 0x200)
// No 'add' will improve sequence; avoid integer overflow
break;
}
// Check if a greater or lesser add could extend the sequence
int32_t nextaddfactor = nextcount*(nextcount-1)/2;
int32_t nextreach = add*nextaddfactor + interval*nextcount;
if (nextreach < nextpoint.minp) {
minadd = add + 1;
outer_maxinterval = nextmaxinterval;
} else {
maxadd = add - 1;
outer_mininterval = nextmininterval;
}
// The maximum valid deviation between two quadratic sequences
// can be calculated and used to further limit the add range.
if (count > 1) {
int32_t errdelta = sc->max_error*QUADRATIC_DEV / (count*count);
if (minadd < add - errdelta)
minadd = add - errdelta;
if (maxadd > add + errdelta)
maxadd = add + errdelta;
}
// See if next point would further limit the add range
int32_t c = outer_maxinterval * nextcount;
if (minadd*nextaddfactor < nextpoint.minp - c)
minadd = idiv_up(nextpoint.minp - c, nextaddfactor);
c = outer_mininterval * nextcount;
if (maxadd*nextaddfactor > nextpoint.maxp - c)
maxadd = idiv_down(nextpoint.maxp - c, nextaddfactor);
// Bisect valid add range and try again with new 'add'
if (minadd > maxadd)
break;
add = maxadd - (maxadd - minadd) / 4;
}
if (zerocount + zerocount/16 >= bestcount)
// Prefer add=0 if it's similar to the best found sequence
return (struct step_move){ zerointerval, zerocount, 0 };
return (struct step_move){ bestinterval, bestcount, bestadd };
}
/****************************************************************
* Step compress checking
****************************************************************/
#define ERROR_RET -989898989
// Verify that a given 'step_move' matches the actual step times
static int
check_line(struct stepcompress *sc, struct step_move move)
{
if (!CHECK_LINES)
return 0;
if (!move.count || (!move.interval && !move.add && move.count > 1)
|| move.interval >= 0x80000000) {
errorf("stepcompress o=%d i=%d c=%d a=%d: Invalid sequence"
, sc->oid, move.interval, move.count, move.add);
return ERROR_RET;
}
uint32_t interval = move.interval, p = 0;
uint16_t i;
for (i=0; i<move.count; i++) {
struct points point = minmax_point(sc, sc->queue_pos + i);
p += interval;
if (p < point.minp || p > point.maxp) {
errorf("stepcompress o=%d i=%d c=%d a=%d: Point %d: %d not in %d:%d"
, sc->oid, move.interval, move.count, move.add
, i+1, p, point.minp, point.maxp);
return ERROR_RET;
}
if (interval >= 0x80000000) {
errorf("stepcompress o=%d i=%d c=%d a=%d:"
" Point %d: interval overflow %d"
, sc->oid, move.interval, move.count, move.add
, i+1, interval);
return ERROR_RET;
}
interval += move.add;
}
return 0;
}
/****************************************************************
* Step compress interface
****************************************************************/
// Allocate a new 'stepcompress' object
struct stepcompress *
stepcompress_alloc(uint32_t max_error, uint32_t queue_step_msgid
, uint32_t set_next_step_dir_msgid, uint32_t invert_sdir
, uint32_t oid)
{
struct stepcompress *sc = malloc(sizeof(*sc));
memset(sc, 0, sizeof(*sc));
sc->max_error = max_error;
list_init(&sc->msg_queue);
sc->queue_step_msgid = queue_step_msgid;
sc->set_next_step_dir_msgid = set_next_step_dir_msgid;
sc->oid = oid;
sc->sdir = -1;
sc->invert_sdir = !!invert_sdir;
return sc;
}
// Free memory associated with a 'stepcompress' object
void
stepcompress_free(struct stepcompress *sc)
{
if (!sc)
return;
free(sc->queue);
message_queue_free(&sc->msg_queue);
free(sc);
}
// Convert previously scheduled steps into commands for the mcu
static int
stepcompress_flush(struct stepcompress *sc, uint64_t move_clock)
{
if (sc->queue_pos >= sc->queue_next)
return 0;
while (sc->last_step_clock < move_clock) {
struct step_move move = compress_bisect_add(sc);
int ret = check_line(sc, move);
if (ret)
return ret;
uint32_t msg[5] = {
sc->queue_step_msgid, sc->oid, move.interval, move.count, move.add
};
struct queue_message *qm = message_alloc_and_encode(msg, 5);
qm->min_clock = qm->req_clock = sc->last_step_clock;
int32_t addfactor = move.count*(move.count-1)/2;
uint32_t ticks = move.add*addfactor + move.interval*move.count;
sc->last_step_clock += ticks;
if (sc->homing_clock)
// When homing, all steps should be sent prior to homing_clock
qm->min_clock = qm->req_clock = sc->homing_clock;
list_add_tail(&qm->node, &sc->msg_queue);
if (sc->queue_pos + move.count >= sc->queue_next) {
sc->queue_pos = sc->queue_next = sc->queue;
break;
}
sc->queue_pos += move.count;
}
return 0;
}
// Generate a queue_step for a step far in the future from the last step
static int
stepcompress_flush_far(struct stepcompress *sc, uint64_t abs_step_clock)
{
uint32_t msg[5] = {
sc->queue_step_msgid, sc->oid, abs_step_clock - sc->last_step_clock, 1, 0
};
struct queue_message *qm = message_alloc_and_encode(msg, 5);
qm->min_clock = sc->last_step_clock;
sc->last_step_clock = qm->req_clock = abs_step_clock;
if (sc->homing_clock)
// When homing, all steps should be sent prior to homing_clock
qm->min_clock = qm->req_clock = sc->homing_clock;
list_add_tail(&qm->node, &sc->msg_queue);
return 0;
}
// Send the set_next_step_dir command
static int
set_next_step_dir(struct stepcompress *sc, int sdir)
{
if (sc->sdir == sdir)
return 0;
sc->sdir = sdir;
int ret = stepcompress_flush(sc, UINT64_MAX);
if (ret)
return ret;
uint32_t msg[3] = {
sc->set_next_step_dir_msgid, sc->oid, sdir ^ sc->invert_sdir
};
struct queue_message *qm = message_alloc_and_encode(msg, 3);
qm->req_clock = sc->homing_clock ?: sc->last_step_clock;
list_add_tail(&qm->node, &sc->msg_queue);
return 0;
}
// Reset the internal state of the stepcompress object
int
stepcompress_reset(struct stepcompress *sc, uint64_t last_step_clock)
{
int ret = stepcompress_flush(sc, UINT64_MAX);
if (ret)
return ret;
sc->last_step_clock = last_step_clock;
sc->sdir = -1;
return 0;
}
// Indicate the stepper is in homing mode (or done homing if zero)
int
stepcompress_set_homing(struct stepcompress *sc, uint64_t homing_clock)
{
int ret = stepcompress_flush(sc, UINT64_MAX);
if (ret)
return ret;
sc->homing_clock = homing_clock;
return 0;
}
// Queue an mcu command to go out in order with stepper commands
int
stepcompress_queue_msg(struct stepcompress *sc, uint32_t *data, int len)
{
int ret = stepcompress_flush(sc, UINT64_MAX);
if (ret)
return ret;
struct queue_message *qm = message_alloc_and_encode(data, len);
qm->req_clock = sc->homing_clock ?: sc->last_step_clock;
list_add_tail(&qm->node, &sc->msg_queue);
return 0;
}
// Set the conversion rate of 'print_time' to mcu clock
static void
stepcompress_set_time(struct stepcompress *sc
, double time_offset, double mcu_freq)
{
sc->mcu_time_offset = time_offset;
sc->mcu_freq = mcu_freq;
}
/****************************************************************
* Queue management
****************************************************************/
struct queue_append {
struct stepcompress *sc;
uint32_t *qnext, *qend, last_step_clock_32;
double clock_offset;
};
// Maximium clock delta between messages in the queue
#define CLOCK_DIFF_MAX (3<<28)
// Create a cursor for inserting clock times into the queue
static inline struct queue_append
queue_append_start(struct stepcompress *sc, double print_time, double adjust)
{
double print_clock = (print_time - sc->mcu_time_offset) * sc->mcu_freq;
return (struct queue_append) {
.sc = sc, .qnext = sc->queue_next, .qend = sc->queue_end,
.last_step_clock_32 = sc->last_step_clock,
.clock_offset = (print_clock - (double)sc->last_step_clock) + adjust };
}
// Finalize a cursor created with queue_append_start()
static inline void
queue_append_finish(struct queue_append qa)
{
qa.sc->queue_next = qa.qnext;
}
// Slow path for queue_append()
static int
queue_append_slow(struct stepcompress *sc, double rel_sc)
{
uint64_t abs_step_clock = (uint64_t)rel_sc + sc->last_step_clock;
if (abs_step_clock >= sc->last_step_clock + CLOCK_DIFF_MAX) {
// Avoid integer overflow on steps far in the future
int ret = stepcompress_flush(sc, abs_step_clock - CLOCK_DIFF_MAX + 1);
if (ret)
return ret;
if (abs_step_clock >= sc->last_step_clock + CLOCK_DIFF_MAX)
return stepcompress_flush_far(sc, abs_step_clock);
}
if (sc->queue_next - sc->queue_pos > 65535 + 2000) {
// No point in keeping more than 64K steps in memory
int ret = stepcompress_flush(sc, *(sc->queue_next - 65535));
if (ret)
return ret;
}
int in_use = sc->queue_next - sc->queue_pos;
if (sc->queue_pos > sc->queue) {
// Shuffle the internal queue to avoid having to allocate more ram
memmove(sc->queue, sc->queue_pos, in_use * sizeof(*sc->queue));
} else {
// Expand the internal queue of step times
int alloc = sc->queue_end - sc->queue;
if (!alloc)
alloc = QUEUE_START_SIZE;
while (in_use >= alloc)
alloc *= 2;
sc->queue = realloc(sc->queue, alloc * sizeof(*sc->queue));
sc->queue_end = sc->queue + alloc;
}
sc->queue_pos = sc->queue;
sc->queue_next = sc->queue + in_use;
*sc->queue_next++ = abs_step_clock;
return 0;
}
// Add a clock time to the queue (flushing the queue if needed)
static inline int
queue_append(struct queue_append *qa, double step_clock)
{
double rel_sc = step_clock + qa->clock_offset;
if (likely(!(qa->qnext >= qa->qend || rel_sc >= (double)CLOCK_DIFF_MAX))) {
*qa->qnext++ = qa->last_step_clock_32 + (uint32_t)rel_sc;
return 0;
}
// Call queue_append_slow() to handle queue expansion and integer overflow
struct stepcompress *sc = qa->sc;
uint64_t old_last_step_clock = sc->last_step_clock;
sc->queue_next = qa->qnext;
int ret = queue_append_slow(sc, rel_sc);
if (ret)
return ret;
qa->qnext = sc->queue_next;
qa->qend = sc->queue_end;
qa->last_step_clock_32 = sc->last_step_clock;
qa->clock_offset -= sc->last_step_clock - old_last_step_clock;
return 0;
}
/****************************************************************
* Motion to step conversions
****************************************************************/
// Common suffixes: _sd is step distance (a unit length the same
// distance the stepper moves on each step), _sv is step velocity (in
// units of step distance per time), _sd2 is step distance squared, _r
// is ratio (scalar usually between 0.0 and 1.0). Times are in
// seconds and acceleration is in units of step distance per second
// squared.
// Wrapper around sqrt() to handle small negative numbers
static double
_safe_sqrt(double v)
{
// Due to floating point truncation, it's possible to get a small
// negative number - treat it as zero.
if (v < -0.001)
errorf("safe_sqrt of %.9f", v);
return 0.;
}
static inline double safe_sqrt(double v) {
return likely(v >= 0.) ? sqrt(v) : _safe_sqrt(v);
}
// Schedule a step event at the specified step_clock time
int32_t
stepcompress_push(struct stepcompress *sc, double print_time, int32_t sdir)
{
int ret = set_next_step_dir(sc, !!sdir);
if (ret)
return ret;
struct queue_append qa = queue_append_start(sc, print_time, 0.5);
ret = queue_append(&qa, 0.);
if (ret)
return ret;
queue_append_finish(qa);
return sdir ? 1 : -1;
}
// Schedule 'steps' number of steps at constant acceleration. If
// acceleration is zero (ie, constant velocity) it uses the formula:
// step_time = print_time + step_num/start_sv
// Otherwise it uses the formula:
// step_time = (print_time + sqrt(2*step_num/accel + (start_sv/accel)**2)
// - start_sv/accel)
int32_t
stepcompress_push_const(
struct stepcompress *sc, double print_time
, double step_offset, double steps, double start_sv, double accel)
{
// Calculate number of steps to take
int sdir = 1;
if (steps < 0) {
sdir = 0;
steps = -steps;
step_offset = -step_offset;
}
int count = steps + .5 - step_offset;
if (count <= 0 || count > 10000000) {
if (count && steps) {
errorf("push_const invalid count %d %f %f %f %f %f"
, sc->oid, print_time, step_offset, steps
, start_sv, accel);
return ERROR_RET;
}
return 0;
}
int ret = set_next_step_dir(sc, sdir);
if (ret)
return ret;
int res = sdir ? count : -count;
// Calculate each step time
if (!accel) {
// Move at constant velocity (zero acceleration)
struct queue_append qa = queue_append_start(sc, print_time, .5);
double inv_cruise_sv = sc->mcu_freq / start_sv;
double pos = (step_offset + .5) * inv_cruise_sv;
while (count--) {
ret = queue_append(&qa, pos);
if (ret)
return ret;
pos += inv_cruise_sv;
}
queue_append_finish(qa);
} else {
// Move with constant acceleration
double inv_accel = 1. / accel;
double accel_time = start_sv * inv_accel * sc->mcu_freq;
struct queue_append qa = queue_append_start(
sc, print_time, 0.5 - accel_time);
double accel_multiplier = 2. * inv_accel * sc->mcu_freq * sc->mcu_freq;
double pos = (step_offset + .5)*accel_multiplier + accel_time*accel_time;
while (count--) {
double v = safe_sqrt(pos);
int ret = queue_append(&qa, accel_multiplier >= 0. ? v : -v);
if (ret)
return ret;
pos += accel_multiplier;
}
queue_append_finish(qa);
}
return res;
}
// Schedule steps using delta kinematics
static int32_t
_stepcompress_push_delta(
struct stepcompress *sc, int sdir
, double print_time, double move_sd, double start_sv, double accel
, double height, double startxy_sd, double arm_sd, double movez_r)
{
// Calculate number of steps to take
double movexy_r = movez_r ? sqrt(1. - movez_r*movez_r) : 1.;
double arm_sd2 = arm_sd * arm_sd;
double endxy_sd = startxy_sd - movexy_r*move_sd;
double end_height = safe_sqrt(arm_sd2 - endxy_sd*endxy_sd);
int count = (end_height + movez_r*move_sd - height) * (sdir ? 1. : -1.) + .5;
if (count <= 0 || count > 10000000) {
if (count) {
errorf("push_delta invalid count %d %d %f %f %f %f %f %f %f %f"
, sc->oid, count, print_time, move_sd, start_sv, accel
, height, startxy_sd, arm_sd, movez_r);
return ERROR_RET;
}
return 0;
}
int ret = set_next_step_dir(sc, sdir);
if (ret)
return ret;
int res = sdir ? count : -count;
// Calculate each step time
height += (sdir ? .5 : -.5);
if (!accel) {
// Move at constant velocity (zero acceleration)
struct queue_append qa = queue_append_start(sc, print_time, .5);
double inv_cruise_sv = sc->mcu_freq / start_sv;
if (!movez_r) {
// Optimized case for common XY only moves (no Z movement)
while (count--) {
double v = safe_sqrt(arm_sd2 - height*height);
double pos = startxy_sd + (sdir ? -v : v);
int ret = queue_append(&qa, pos * inv_cruise_sv);
if (ret)
return ret;
height += (sdir ? 1. : -1.);
}
} else if (!movexy_r) {
// Optimized case for Z only moves
double pos = ((sdir ? height-end_height : end_height-height)
* inv_cruise_sv);
while (count--) {
int ret = queue_append(&qa, pos);
if (ret)
return ret;
pos += inv_cruise_sv;
}
} else {
// General case (handles XY+Z moves)
double start_pos = movexy_r*startxy_sd, zoffset = movez_r*startxy_sd;
while (count--) {
double relheight = movexy_r*height - zoffset;
double v = safe_sqrt(arm_sd2 - relheight*relheight);
double pos = start_pos + movez_r*height + (sdir ? -v : v);
int ret = queue_append(&qa, pos * inv_cruise_sv);
if (ret)
return ret;
height += (sdir ? 1. : -1.);
}
}
queue_append_finish(qa);
} else {
// Move with constant acceleration
double start_pos = movexy_r*startxy_sd, zoffset = movez_r*startxy_sd;
double inv_accel = 1. / accel;
start_pos += 0.5 * start_sv*start_sv * inv_accel;
struct queue_append qa = queue_append_start(
sc, print_time, 0.5 - start_sv * inv_accel * sc->mcu_freq);
double accel_multiplier = 2. * inv_accel * sc->mcu_freq * sc->mcu_freq;
while (count--) {
double relheight = movexy_r*height - zoffset;
double v = safe_sqrt(arm_sd2 - relheight*relheight);
double pos = start_pos + movez_r*height + (sdir ? -v : v);
v = safe_sqrt(pos * accel_multiplier);
int ret = queue_append(&qa, accel_multiplier >= 0. ? v : -v);
if (ret)
return ret;
height += (sdir ? 1. : -1.);
}
queue_append_finish(qa);
}
return res;
}
int32_t
stepcompress_push_delta(
struct stepcompress *sc, double print_time, double move_sd
, double start_sv, double accel
, double height, double startxy_sd, double arm_sd, double movez_r)
{
double reversexy_sd = startxy_sd + arm_sd*movez_r;
if (reversexy_sd <= 0.)
// All steps are in down direction
return _stepcompress_push_delta(
sc, 0, print_time, move_sd, start_sv, accel
, height, startxy_sd, arm_sd, movez_r);
double movexy_r = movez_r ? sqrt(1. - movez_r*movez_r) : 1.;
if (reversexy_sd >= move_sd * movexy_r)
// All steps are in up direction
return _stepcompress_push_delta(
sc, 1, print_time, move_sd, start_sv, accel
, height, startxy_sd, arm_sd, movez_r);
// Steps in both up and down direction
int res1 = _stepcompress_push_delta(
sc, 1, print_time, reversexy_sd / movexy_r, start_sv, accel
, height, startxy_sd, arm_sd, movez_r);
if (res1 == ERROR_RET)
return res1;
int res2 = _stepcompress_push_delta(
sc, 0, print_time, move_sd, start_sv, accel
, height + res1, startxy_sd, arm_sd, movez_r);
if (res2 == ERROR_RET)
return res2;
return res1 + res2;
}
/****************************************************************
* Step compress synchronization
****************************************************************/
// The steppersync object is used to synchronize the output of mcu
// step commands. The mcu can only queue a limited number of step
// commands - this code tracks when items on the mcu step queue become
// free so that new commands can be transmitted. It also ensures the
// mcu step queue is ordered between steppers so that no stepper
// starves the other steppers of space in the mcu step queue.
struct steppersync {
// Serial port
struct serialqueue *sq;
struct command_queue *cq;
// Storage for associated stepcompress objects
struct stepcompress **sc_list;
int sc_num;
// Storage for list of pending move clocks
uint64_t *move_clocks;
int num_move_clocks;
};
// Allocate a new 'steppersync' object
struct steppersync *
steppersync_alloc(struct serialqueue *sq, struct stepcompress **sc_list
, int sc_num, int move_num)
{
struct steppersync *ss = malloc(sizeof(*ss));
memset(ss, 0, sizeof(*ss));
ss->sq = sq;
ss->cq = serialqueue_alloc_commandqueue();
ss->sc_list = malloc(sizeof(*sc_list)*sc_num);
memcpy(ss->sc_list, sc_list, sizeof(*sc_list)*sc_num);
ss->sc_num = sc_num;
ss->move_clocks = malloc(sizeof(*ss->move_clocks)*move_num);
memset(ss->move_clocks, 0, sizeof(*ss->move_clocks)*move_num);
ss->num_move_clocks = move_num;
return ss;
}
// Free memory associated with a 'steppersync' object
void
steppersync_free(struct steppersync *ss)
{
if (!ss)
return;
free(ss->sc_list);
free(ss->move_clocks);
serialqueue_free_commandqueue(ss->cq);
free(ss);
}
// Set the conversion rate of 'print_time' to mcu clock
void
steppersync_set_time(struct steppersync *ss, double time_offset, double mcu_freq)
{
int i;
for (i=0; i<ss->sc_num; i++) {
struct stepcompress *sc = ss->sc_list[i];
stepcompress_set_time(sc, time_offset, mcu_freq);
}
}
// Implement a binary heap algorithm to track when the next available
// 'struct move' in the mcu will be available
static void
heap_replace(struct steppersync *ss, uint64_t req_clock)
{
uint64_t *mc = ss->move_clocks;
int nmc = ss->num_move_clocks, pos = 0;
for (;;) {
int child1_pos = 2*pos+1, child2_pos = 2*pos+2;
uint64_t child2_clock = child2_pos < nmc ? mc[child2_pos] : UINT64_MAX;
uint64_t child1_clock = child1_pos < nmc ? mc[child1_pos] : UINT64_MAX;
if (req_clock <= child1_clock && req_clock <= child2_clock) {
mc[pos] = req_clock;
break;
}
if (child1_clock < child2_clock) {
mc[pos] = child1_clock;
pos = child1_pos;
} else {
mc[pos] = child2_clock;
pos = child2_pos;
}
}
}
// Find and transmit any scheduled steps prior to the given 'move_clock'
int
steppersync_flush(struct steppersync *ss, uint64_t move_clock)
{
// Flush each stepcompress to the specified move_clock
int i;
for (i=0; i<ss->sc_num; i++) {
int ret = stepcompress_flush(ss->sc_list[i], move_clock);
if (ret)
return ret;
}
// Order commands by the reqclock of each pending command
struct list_head msgs;
list_init(&msgs);
for (;;) {
// Find message with lowest reqclock
uint64_t req_clock = MAX_CLOCK;
struct queue_message *qm = NULL;
for (i=0; i<ss->sc_num; i++) {
struct stepcompress *sc = ss->sc_list[i];
if (!list_empty(&sc->msg_queue)) {
struct queue_message *m = list_first_entry(
&sc->msg_queue, struct queue_message, node);
if (m->req_clock < req_clock) {
qm = m;
req_clock = m->req_clock;
}
}
}
if (!qm || (qm->min_clock && req_clock > move_clock))
break;
uint64_t next_avail = ss->move_clocks[0];
if (qm->min_clock)
// The qm->min_clock field is overloaded to indicate that
// the command uses the 'move queue' and to store the time
// that move queue item becomes available.
heap_replace(ss, qm->min_clock);
// Reset the min_clock to its normal meaning (minimum transmit time)
qm->min_clock = next_avail;
// Batch this command
list_del(&qm->node);
list_add_tail(&qm->node, &msgs);
}
// Transmit commands
if (!list_empty(&msgs))
serialqueue_send_batch(ss->sq, ss->cq, &msgs);
return 0;
}