Mercurial > hg
view mercurial/graphmod.py @ 51464:09782c097035
branchcache: move head writing in a `_write_heads` method
Same rational: this will help having format variants.
author | Pierre-Yves David <pierre-yves.david@octobus.net> |
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date | Mon, 26 Feb 2024 15:25:41 +0100 |
parents | d44e3c45f0e4 |
children | 493034cc3265 |
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# Revision graph generator for Mercurial # # Copyright 2008 Dirkjan Ochtman <dirkjan@ochtman.nl> # Copyright 2007 Joel Rosdahl <joel@rosdahl.net> # # This software may be used and distributed according to the terms of the # GNU General Public License version 2 or any later version. """supports walking the history as DAGs suitable for graphical output The most basic format we use is that of:: (id, type, data, [parentids]) The node and parent ids are arbitrary integers which identify a node in the context of the graph returned. Type is a constant specifying the node type. Data depends on type. """ from .node import nullrev from .thirdparty import attr from . import ( dagop, smartset, util, ) CHANGESET = b'C' PARENT = b'P' GRANDPARENT = b'G' MISSINGPARENT = b'M' # Style of line to draw. None signals a line that ends and is removed at this # point. A number prefix means only the last N characters of the current block # will use that style, the rest will use the PARENT style. Add a - sign # (so making N negative) and all but the first N characters use that style. EDGES = {PARENT: b'|', GRANDPARENT: b':', MISSINGPARENT: None} def dagwalker(repo, revs): """cset DAG generator yielding (id, CHANGESET, ctx, [parentinfo]) tuples This generator function walks through revisions (which should be ordered from bigger to lower). It returns a tuple for each node. Each parentinfo entry is a tuple with (edgetype, parentid), where edgetype is one of PARENT, GRANDPARENT or MISSINGPARENT. The node and parent ids are arbitrary integers which identify a node in the context of the graph returned. """ gpcache = {} for rev in revs: ctx = repo[rev] # partition into parents in the rev set and missing parents, then # augment the lists with markers, to inform graph drawing code about # what kind of edge to draw between nodes. pset = {p.rev() for p in ctx.parents() if p.rev() in revs} mpars = [ p.rev() for p in ctx.parents() if p.rev() != nullrev and p.rev() not in pset ] parents = [(PARENT, p) for p in sorted(pset)] for mpar in mpars: gp = gpcache.get(mpar) if gp is None: # precompute slow query as we know reachableroots() goes # through all revs (issue4782) if not isinstance(revs, smartset.baseset): revs = smartset.baseset(revs) gp = gpcache[mpar] = sorted( set(dagop.reachableroots(repo, revs, [mpar])) ) if not gp: parents.append((MISSINGPARENT, mpar)) pset.add(mpar) else: parents.extend((GRANDPARENT, g) for g in gp if g not in pset) pset.update(gp) yield (ctx.rev(), CHANGESET, ctx, parents) def nodes(repo, nodes): """cset DAG generator yielding (id, CHANGESET, ctx, [parentids]) tuples This generator function walks the given nodes. It only returns parents that are in nodes, too. """ include = set(nodes) for node in nodes: ctx = repo[node] parents = { (PARENT, p.rev()) for p in ctx.parents() if p.node() in include } yield (ctx.rev(), CHANGESET, ctx, sorted(parents)) def colored(dag, repo): """annotates a DAG with colored edge information For each DAG node this function emits tuples:: (id, type, data, (col, color), [(col, nextcol, color)]) with the following new elements: - Tuple (col, color) with column and color index for the current node - A list of tuples indicating the edges between the current node and its parents. """ seen = [] colors = {} newcolor = 1 config = {} for key, val in repo.ui.configitems(b'graph'): if b'.' in key: branch, setting = key.rsplit(b'.', 1) # Validation if setting == b"width" and val.isdigit(): config.setdefault(branch, {})[setting] = int(val) elif setting == b"color" and val.isalnum(): config.setdefault(branch, {})[setting] = val if config: getconf = util.lrucachefunc( lambda rev: config.get(repo[rev].branch(), {}) ) else: getconf = lambda rev: {} for (cur, type, data, parents) in dag: # Compute seen and next if cur not in seen: seen.append(cur) # new head colors[cur] = newcolor newcolor += 1 col = seen.index(cur) color = colors.pop(cur) next = seen[:] # Add parents to next addparents = [p for pt, p in parents if p not in next] next[col : col + 1] = addparents # Set colors for the parents for i, p in enumerate(addparents): if not i: colors[p] = color else: colors[p] = newcolor newcolor += 1 # Add edges to the graph edges = [] for ecol, eid in enumerate(seen): if eid in next: bconf = getconf(eid) edges.append( ( ecol, next.index(eid), colors[eid], bconf.get(b'width', -1), bconf.get(b'color', b''), ) ) elif eid == cur: for ptype, p in parents: bconf = getconf(p) edges.append( ( ecol, next.index(p), color, bconf.get(b'width', -1), bconf.get(b'color', b''), ) ) # Yield and move on yield (cur, type, data, (col, color), edges) seen = next def asciiedges(type, char, state, rev, parents): """adds edge info to changelog DAG walk suitable for ascii()""" seen = state.seen if rev not in seen: seen.append(rev) nodeidx = seen.index(rev) knownparents = [] newparents = [] for ptype, parent in parents: if parent == rev: # self reference (should only be seen in null rev) continue if parent in seen: knownparents.append(parent) else: newparents.append(parent) state.edges[parent] = state.styles.get(ptype, b'|') ncols = len(seen) width = 1 + ncols * 2 nextseen = seen[:] nextseen[nodeidx : nodeidx + 1] = newparents edges = [(nodeidx, nextseen.index(p)) for p in knownparents] seen[:] = nextseen while len(newparents) > 2: # ascii() only knows how to add or remove a single column between two # calls. Nodes with more than two parents break this constraint so we # introduce intermediate expansion lines to grow the active node list # slowly. edges.append((nodeidx, nodeidx)) edges.append((nodeidx, nodeidx + 1)) nmorecols = 1 width += 2 yield (type, char, width, (nodeidx, edges, ncols, nmorecols)) char = b'\\' nodeidx += 1 ncols += 1 edges = [] del newparents[0] if len(newparents) > 0: edges.append((nodeidx, nodeidx)) if len(newparents) > 1: edges.append((nodeidx, nodeidx + 1)) nmorecols = len(nextseen) - ncols if nmorecols > 0: width += 2 # remove current node from edge characters, no longer needed state.edges.pop(rev, None) yield (type, char, width, (nodeidx, edges, ncols, nmorecols)) def _fixlongrightedges(edges): for (i, (start, end)) in enumerate(edges): if end > start: edges[i] = (start, end + 1) def _getnodelineedgestail(echars, idx, pidx, ncols, coldiff, pdiff, fix_tail): if fix_tail and coldiff == pdiff and coldiff != 0: # Still going in the same non-vertical direction. if coldiff == -1: start = max(idx + 1, pidx) tail = echars[idx * 2 : (start - 1) * 2] tail.extend([b"/", b" "] * (ncols - start)) return tail else: return [b"\\", b" "] * (ncols - idx - 1) else: remainder = ncols - idx - 1 return echars[-(remainder * 2) :] if remainder > 0 else [] def _drawedges(echars, edges, nodeline, interline): for (start, end) in edges: if start == end + 1: interline[2 * end + 1] = b"/" elif start == end - 1: interline[2 * start + 1] = b"\\" elif start == end: interline[2 * start] = echars[2 * start] else: if 2 * end >= len(nodeline): continue nodeline[2 * end] = b"+" if start > end: (start, end) = (end, start) for i in range(2 * start + 1, 2 * end): if nodeline[i] != b"+": nodeline[i] = b"-" def _getpaddingline(echars, idx, ncols, edges): # all edges up to the current node line = echars[: idx * 2] # an edge for the current node, if there is one if (idx, idx - 1) in edges or (idx, idx) in edges: # (idx, idx - 1) (idx, idx) # | | | | | | | | # +---o | | o---+ # | | X | | X | | # | |/ / | |/ / # | | | | | | line.extend(echars[idx * 2 : (idx + 1) * 2]) else: line.extend([b' ', b' ']) # all edges to the right of the current node remainder = ncols - idx - 1 if remainder > 0: line.extend(echars[-(remainder * 2) :]) return line def _drawendinglines(lines, extra, edgemap, seen, state): """Draw ending lines for missing parent edges None indicates an edge that ends at between this node and the next Replace with a short line ending in ~ and add / lines to any edges to the right. """ if None not in edgemap.values(): return # Check for more edges to the right of our ending edges. # We need enough space to draw adjustment lines for these. edgechars = extra[::2] while edgechars and edgechars[-1] is None: edgechars.pop() shift_size = max((edgechars.count(None) * 2) - 1, 0) minlines = 3 if not state.graphshorten else 2 while len(lines) < minlines + shift_size: lines.append(extra[:]) if shift_size: empties = [] toshift = [] first_empty = extra.index(None) for i, c in enumerate(extra[first_empty::2], first_empty // 2): if c is None: empties.append(i * 2) else: toshift.append(i * 2) targets = list(range(first_empty, first_empty + len(toshift) * 2, 2)) positions = toshift[:] for line in lines[-shift_size:]: line[first_empty:] = [b' '] * (len(line) - first_empty) for i in range(len(positions)): pos = positions[i] - 1 positions[i] = max(pos, targets[i]) line[pos] = b'/' if pos > targets[i] else extra[toshift[i]] map = {1: b'|', 2: b'~'} if not state.graphshorten else {1: b'~'} for i, line in enumerate(lines): if None not in line: continue line[:] = [c or map.get(i, b' ') for c in line] # remove edges that ended remove = [p for p, c in edgemap.items() if c is None] for parent in remove: del edgemap[parent] seen.remove(parent) @attr.s class asciistate: """State of ascii() graph rendering""" seen = attr.ib(init=False, default=attr.Factory(list)) edges = attr.ib(init=False, default=attr.Factory(dict)) lastcoldiff = attr.ib(init=False, default=0) lastindex = attr.ib(init=False, default=0) styles = attr.ib(init=False, default=attr.Factory(EDGES.copy)) graphshorten = attr.ib(init=False, default=False) def outputgraph(ui, graph): """outputs an ASCII graph of a DAG this is a helper function for 'ascii' below. takes the following arguments: - ui to write to - graph data: list of { graph nodes/edges, text } this function can be monkey-patched by extensions to alter graph display without needing to mimic all of the edge-fixup logic in ascii() """ for (ln, logstr) in graph: ui.write((ln + logstr).rstrip() + b"\n") def ascii(ui, state, type, char, text, coldata): """prints an ASCII graph of the DAG takes the following arguments (one call per node in the graph): - ui to write to - Somewhere to keep the needed state in (init to asciistate()) - Column of the current node in the set of ongoing edges. - Type indicator of node data, usually 'C' for changesets. - Payload: (char, lines): - Character to use as node's symbol. - List of lines to display as the node's text. - Edges; a list of (col, next_col) indicating the edges between the current node and its parents. - Number of columns (ongoing edges) in the current revision. - The difference between the number of columns (ongoing edges) in the next revision and the number of columns (ongoing edges) in the current revision. That is: -1 means one column removed; 0 means no columns added or removed; 1 means one column added. """ idx, edges, ncols, coldiff = coldata assert -2 < coldiff < 2 edgemap, seen = state.edges, state.seen # Be tolerant of history issues; make sure we have at least ncols + coldiff # elements to work with. See test-glog.t for broken history test cases. echars = [c for p in seen for c in (edgemap.get(p, b'|'), b' ')] echars.extend((b'|', b' ') * max(ncols + coldiff - len(seen), 0)) if coldiff == -1: # Transform # # | | | | | | # o | | into o---+ # |X / |/ / # | | | | _fixlongrightedges(edges) # add_padding_line says whether to rewrite # # | | | | | | | | # | o---+ into | o---+ # | / / | | | # <--- padding line # o | | | / / # o | | add_padding_line = ( len(text) > 2 and coldiff == -1 and [x for (x, y) in edges if x + 1 < y] ) # fix_nodeline_tail says whether to rewrite # # | | o | | | | o | | # | | |/ / | | |/ / # | o | | into | o / / # <--- fixed nodeline tail # | |/ / | |/ / # o | | o | | fix_nodeline_tail = len(text) <= 2 and not add_padding_line # nodeline is the line containing the node character (typically o) nodeline = echars[: idx * 2] nodeline.extend([char, b" "]) nodeline.extend( _getnodelineedgestail( echars, idx, state.lastindex, ncols, coldiff, state.lastcoldiff, fix_nodeline_tail, ) ) # shift_interline is the line containing the non-vertical # edges between this entry and the next shift_interline = echars[: idx * 2] for i in range(2 + coldiff): shift_interline.append(b' ') count = ncols - idx - 1 if coldiff == -1: for i in range(count): shift_interline.extend([b'/', b' ']) elif coldiff == 0: shift_interline.extend(echars[(idx + 1) * 2 : ncols * 2]) else: for i in range(count): shift_interline.extend([b'\\', b' ']) # draw edges from the current node to its parents _drawedges(echars, edges, nodeline, shift_interline) # lines is the list of all graph lines to print lines = [nodeline] if add_padding_line: lines.append(_getpaddingline(echars, idx, ncols, edges)) # If 'graphshorten' config, only draw shift_interline # when there is any non vertical flow in graph. if state.graphshorten: if any(c in br'\/' for c in shift_interline if c): lines.append(shift_interline) # Else, no 'graphshorten' config so draw shift_interline. else: lines.append(shift_interline) # make sure that there are as many graph lines as there are # log strings extra_interline = echars[: (ncols + coldiff) * 2] if len(lines) < len(text): while len(lines) < len(text): lines.append(extra_interline[:]) _drawendinglines(lines, extra_interline, edgemap, seen, state) while len(text) < len(lines): text.append(b"") # print lines indentation_level = max(ncols, ncols + coldiff) lines = [ b"%-*s " % (2 * indentation_level, b"".join(line)) for line in lines ] outputgraph(ui, zip(lines, text)) # ... and start over state.lastcoldiff = coldiff state.lastindex = idx